Biological and Abiological Catalysis in Organic Synthesis (Tape 1)
- 1992
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Transcript
00:01:19 Hello and welcome to the 10th American Chemical Society
00:01:23 satellite television seminar. I'm your moderator, Paul Anthony.
00:01:27 Today we're lucky to have four of the leading American experts in organic synthesis here
00:01:31 to discuss the latest developments in catalytic techniques.
00:01:35 Barry Trost of Stanford University is the seminar coordinator who organized this program.
00:01:41 Joining him are Peter Schultz of the University of California at Berkeley,
00:01:46 Barry Sharpless of the Scripps Research Institute,
00:01:50 and George Whitesides of Harvard University.
00:01:54 You'll be seeing formal presentations by each of them that were videotaped in advance at their home institutions,
00:02:00 and they will be here in the studio throughout the program to answer your questions during the telephone call-in segments.
00:02:06 Now, each of you should have received a copy of the seminar notes prepared by the speakers.
00:02:11 The printed notes contain copies of most of the material that will be shown on your television screen
00:02:16 to make it easier for you to take notes, so please keep this printed material handy during the program.
00:02:21 Our telephone lines will be open during two question-and-answer sessions.
00:02:25 The detailed schedule in your seminar notes gives an approximate time when each Q&A session will start.
00:02:31 I will announce when you can begin calling in, and the telephone number to call will be shown on the screen at that time.
00:02:37 Your seminar notes contain a page for you to use to write down your questions,
00:02:41 and we look forward to hearing from many of you during the program today.
00:02:45 We begin the formal presentations with the lectures by Barry Trost and Barry Sharpless on abiological catalysis.
00:02:53 Our first Q&A period will immediately follow Dr. Sharpless' presentation.
00:03:00 Our first speaker is the seminar coordinator, Dr. Barry M. Trost.
00:03:04 He is Tamaki Professor of Humanities and Sciences at Stanford University.
00:03:10 His interest in organic chemistry research encompasses many new synthetic methods and a wide variety of applications,
00:03:17 ranging from organometallic chemistry to natural product synthesis and structure determination.
00:03:23 Dr. Trost's topic is abiological catalysis for synthetic efficiency.
00:03:30 The requirement for increasingly sophisticated materials and substances
00:03:35 represents both a challenge and an opportunity for the chemist.
00:03:39 It is no longer sufficient to design and synthesize molecules that have a particular set of properties.
00:03:45 The molecules must also be of minimum hazard or risk, and they must also be environmentally friendly.
00:03:53 In trying to design such molecules, we rely on the synthetic strategies that we have available
00:04:01 in going from easily accessible starting materials to that target.
00:04:08 How can we design such synthetic strategies?
00:04:11 Clearly, it is intimately tied to the tools, the reactions, and reagents that we have available to us.
00:04:18 And when we think about these reactions and reagents, a prime concern is synthetic efficiency.
00:04:25 What are the problems of synthetic efficiency?
00:04:29 We can break them into two major themes, the first being selectivity.
00:04:34 When we think about selectivity, the first thought that comes to mind
00:04:39 is the issue of being able to differentiate among various functional groups
00:04:43 or among several functional groups of the same kind, a problem of chemoselectivity.
00:04:49 We must also worry about how reacting molecules will approach one another, a problem of regioselectivity.
00:04:56 And then we must concern ourselves with the important general area of stereochemistry,
00:05:01 be it of relative stereochemistry or diastereoselectivity or absolute stereochemistry or an antioselectivity.
00:05:09 But while we worry about the problems of selectivity,
00:05:13 this cannot be at the expense of a second major component of synthetic efficiency.
00:05:19 Crudely put, how much of what we put into our pot ends up into our product?
00:05:26 For want of a better name, a concept that I refer to as atom economy.
00:05:32 What are the technologies that we have available to approach the problems of synthetic efficiency in our reactions and reagents?
00:05:42 Of these, perhaps one of the most important, certainly one of the ones that is growing most importantly,
00:05:48 is that based on the concept of catalysis.
00:05:52 We can think of catalysis in two worlds.
00:05:55 The world of abiological catalysis, largely revolving around transition metals and their complexes,
00:06:02 and the world of biological catalysis.
00:06:06 This is not to say that these worlds are in competition with one another,
00:06:10 but indeed they will be complementary.
00:06:13 For some applications, clearly the abiological catalysis will be the methods of choice,
00:06:19 whereas for other applications, the biological methods may be the preferred ones.
00:06:25 In trying to deal with this question of abiological catalysis,
00:06:31 in this first section, I am going to outline some of the concepts that evolve from the world of transition metal complexes,
00:06:39 and how they can approach the problems of synthetic efficiency.
00:06:44 To begin with, we can consider the very important problem of carbon-carbon bond formation,
00:06:50 using such transition metals.
00:06:53 When we generally think of organometallic complexes, we don't think of these as being chemoselective,
00:06:59 the idea largely coming from our experiences with the main group metals, especially that of magnesium.
00:07:07 On the other hand, when we transfer to the transition metals, these concepts change dramatically.
00:07:14 If we take an organic electrophile, an RX species, and react that with an organic nucleophile,
00:07:22 some R' metal species, where the metal might be boron, tin, aluminum, silicon,
00:07:29 these can undergo a carbon-carbon bond forming process,
00:07:34 initiated by the reaction of the low-valent metal, frequently palladium, with the organic electrophile,
00:07:41 generating an RPdX, which, because the palladium is being converted from a low-valent state, 0,
00:07:49 to a plus-2 state, is referred to as oxidative addition.
00:07:53 The reaction then proceeds by substitution of the X group, using the R' coming from the organic nucleophile,
00:08:02 generating an RPdR'.
00:08:06 This primes the organometallic complex to extrude the product RR' with simultaneous bond formation,
00:08:16 regenerating palladium 0 to initiate another cycle.
00:08:20 Since palladium goes from plus-2 to 0, we refer to this process as reductive elimination.
00:08:28 Indeed, this cross-coupling reaction is highly chemoselective.
00:08:34 Let's consider an example coming from the application towards the rather interesting marine toxin, caliculin.
00:08:44 In this approach, an organic electrophile, a vinyl iodide, possesses in that same molecule an aldehyde,
00:08:52 a functional group which clearly would not be compatible with traditional organometallics.
00:08:57 It is coupled with an organostannane, a molecule which also contains a functional group, cyanide in this case,
00:09:05 which traditionally does not have a compatibility with organometallics.
00:09:10 Nevertheless, when we expose these two substrates to bis-triphenylphosphine palladium chloride,
00:09:17 they undergo a remarkably efficient carbon-carbon bond formation to give an important fragment of the final molecule.
00:09:27 These reactions can be highly chemoselective even in generating the organometallic species using main group metals,
00:09:35 if we choose the metal appropriately.
00:09:38 Zinc in particular has shown itself to be a highly chemoselective organometallic entity.
00:09:46 We can generate an organozinc by, for example, taking an organic iodide, in this case an aniodoalanine derivative,
00:09:56 and react that with just zinc metal, where we do require activation of the zinc by using ultrasound.
00:10:04 The resulting organozinc species is not only compatible with the carbonyl functionality that is present,
00:10:12 but is sufficiently non-basic that it doesn't even undergo a deprotonation reaction.
00:10:18 The resulting organozinc species, while relatively unreactive,
00:10:23 will combine, however, with the organic electrophiles, such as organic iodides, bromides, triplates,
00:10:33 in the presence of the same palladium zero species generated from bis-triphenylphosphine palladium chloride.
00:10:43 In this way, we can couple this with an acid chloride to generate a ketone in a highly chemoselective fashion.
00:10:54 We can take these transition metal reactions one step further in terms of their ability to be chemoselective
00:11:01 if we choose as our organic electrophile an allyl X entity.
00:11:08 In this case, we are taking advantage of the high coordination affinity of transition metals for carbon-carbon pi bonds.
00:11:17 In the process, the palladium coordinates with the olefin and then affects ionization in a pseudo-intramolecular fashion
00:11:28 to generate a reactive electrophile, a pi-allyl palladium cationic intermediate.
00:11:35 This species is sufficiently reactive towards nucleophiles that even relatively stabilized anions,
00:11:43 such as that derived from malonate, will undergo addition,
00:11:48 initially to generate the product still bound to the transition metal.
00:11:54 Dissociation of the product then liberates the metal to affect another catalytic cycle.
00:12:02 The organic substrate, because you now involve coordination to the transition metal,
00:12:10 is capable of ionizing groups which normally would not participate in displacement reactions,
00:12:16 X groups such as carboxylates, nitro groups, or even sulfones.
00:12:23 The advantage of this method is that it will in fact select for the allyl X species
00:12:29 even in the presence of a more traditional type of leaving group, such as an organic bromide.
00:12:36 Thus, if we have a substrate which bears both an alkyl bromide and an allylic acetate,
00:12:43 in the presence of the palladium zero, smooth substitution will occur of the allylic acetate
00:12:49 in tetrahydropurian as solvent without affecting the organic bromide at all.
00:12:54 Of course, one expects and does indeed observe that in a dipolar aprotic solvent,
00:12:59 such as dimethyl formamide, in the absence of the palladium zero,
00:13:03 the substitution would occur at the organic bromide.
00:13:08 This particular example also raises a second issue in that of regioselectivity.
00:13:15 Since the reaction involves a pi-allyl metal intermediate,
00:13:19 we don't anticipate and normally don't observe that the product regiochemistry
00:13:24 derives from the regiochemistry of the starting material.
00:13:28 And in the particular example, the reaction proceeded to form the new carbon-carbon bond
00:13:33 at the sterically more accessible terminal position of the pi-allyl intermediate.
00:13:38 One of the advantages of transition metals is our ability of choosing
00:13:42 which terminal position we wish to form the new bond by simply changing the metal.
00:13:48 If we take a similarly substituted bromoallylic acetate,
00:13:53 but now subjected to a molybdenum catalyst rather than palladium,
00:13:57 again chemoselective substitution of the allylic acetate occurs,
00:14:01 but this time with new carbon-carbon bond formation exclusively
00:14:06 to the more substituted end of the pi-allyl intermediate.
00:14:12 Now these reactions of regioselectivity become particularly important
00:14:17 when we're considering intramolecular processes,
00:14:20 for the regioselectivity will determine the size of the ring that we are forming.
00:14:26 When we compete a reaction whereby attack at one terminus would generate a six-membered ring,
00:14:33 whereas attack at the other terminus would generate an eight-membered ring,
00:14:37 our expectation based on our knowledge of simple cyclization reactions
00:14:42 would be that six-membered ring formation would dominate,
00:14:46 since there generally is somewhere in the order of a 5 to 6 power of 10 rate preference
00:14:52 for cyclization to six-membered rings over eight.
00:14:56 Thus it was not surprising that when a vinyl epoxide bearing an endogenous epoxide ring
00:15:03 using triisopropyl phosphite as the ligand for the palladium zero
00:15:08 underwent cyclization to generate exclusively the six-membered ring product.
00:15:14 On the other hand, unlike non-transition metal catalyzed reactions,
00:15:19 the differences in energies between the possible competing pathways is not nearly so large.
00:15:24 A minor change in substrate where the epoxide then is placed exogenous to the forming ring
00:15:31 and a change in the ligand to make it sterically smaller,
00:15:35 that is to design a bidentate version of triisopropyl phosphite,
00:15:40 allows us to carry out a cyclization reaction,
00:15:44 but this time with exclusive formation of the eight-membered ring rather than the six-membered ring.
00:15:51 Our ability of directing regioselectivity is not limited to these types of palladium catalyzed reactions
00:15:59 with soft nucleophiles.
00:16:01 We can control reactions with much more reactive hard nucleophiles
00:16:08 in their allylic coupling reactions.
00:16:11 For example, utilizing an allyl phosphate and Grignard reagents
00:16:17 coupled in the presence of a copper catalyst,
00:16:20 in particular that derived from copper cyanide,
00:16:23 gives us clean SN2 prime-like substitution.
00:16:28 Similar reactions, but simply changing the catalyst from copper to that based on iron,
00:16:36 in this case coming from iron acetyl acetinoate,
00:16:39 changes the regioselectivity to give you that derived from direct SN2 substitution.
00:16:46 This latter example also illustrates the fact
00:16:50 that the double bond, which is cis, is fully retained in the product,
00:16:54 which means that these reactions, in contrast to that based on palladium and molybdenum,
00:16:59 do not proceed through pi-allyl intermediates.
00:17:05 Can we extend our ability of controlling regioselectivity to other types of reactions,
00:17:12 such as that for heterocyclic ring formation?
00:17:17 Let us consider the very important cyclizations to nitrogen heterocycles.
00:17:22 And among the recently developed methods,
00:17:25 those initiated by the use of iminium ions have been particularly fruitful.
00:17:32 In these processes, one would generate an iminium cation in the presence of some pi systems,
00:17:39 such as an acetylene, whereby attack occurs regioselectively.
00:17:45 Thus, if one takes an enamide and treats it with formic acid as an acid catalyst to generate the iminium ion,
00:17:54 the cyclization generates the six-membered ring vinyl cation,
00:17:58 which then is captured by some oxygen electrophile, most likely formate,
00:18:03 which during workup hydrolyzes to give the quinolizidine product.
00:18:09 Could we redirect this process so that the ring formation would occur to generate a five-membered ring rather than a six-membered ring?
00:18:20 A way to perhaps achieve this goal would be to attach that proton to a transition metal,
00:18:28 and we might envision the following cycle.
00:18:31 We take our substrate, an alpha omega enine,
00:18:36 and allow it to interact with some H metal species, such as HPDX.
00:18:43 Because of the high affinity of the transition metal for pi coordination,
00:18:48 the initial step would be complexation to the two pi unsaturations,
00:18:54 this complexation directing the chemo and regioselectivity to generate a vinyl palladium species,
00:19:03 which is well known to be able to undergo carbometalations.
00:19:08 Once again, the complexation geometry dictates the regioselectivity of that intramolecular carbometalation
00:19:16 to occur in an exo mode to generate a sigma carbon palladium bond.
00:19:23 That sigma bond, once being formed, then undergoes a beta hydrogen insertion reaction,
00:19:31 a very common process for transition metals,
00:19:34 thereby generating a product, in this case a dialkylidene cycloalkane,
00:19:40 and reforming HPDX to initiate another cycle.
00:19:46 If we take acetic acid as our carboxylic acid,
00:19:52 but now in the presence of a palladium zero catalyst,
00:19:55 generated from dibenzylidene acetone palladium zero,
00:19:59 and a ligand, NN'-bisbenzylidene ethylenediamine,
00:20:06 one now finds that the same substrate which generated the quinolizidene ring by six-membered ring formation
00:20:13 undergoes clean regioselective cyclization to generate a five-membered ring.
00:20:20 The carbon palladium sigma bonded intermediate is not capable of inserting into the bridgehead hydrogen
00:20:28 because that hydrogen is trans to the palladium.
00:20:32 These cis beta hydrogen insertion reactions require the hydrogen to be cis to the palladium,
00:20:39 and therefore, in this case, insertion can occur only away from the bridgehead position
00:20:44 to generate, instead of a 1,3-diene, a 1,4-diene.
00:20:50 It is also interesting to note that these reactions control the stereochemistry of the double bonds.
00:21:00 If we examine the regiochemistry and stereochemistry of the hydropalladation reaction,
00:21:09 we can see that this is a cis addition, meaning that with a disubstituted acetylene,
00:21:18 the substituent that is on the acetylene will end up in the diene product in the E configuration.
00:21:28 Thus, an enine from a disubstituted acetylene would generate the E dialkylidene cycloalkane.
00:21:38 In the particular example that is shown, that E olefin geometry ultimately translates into the stereochemistry at sp3 carbon,
00:21:48 which is then introduced in a highly diastereoselective fashion by cycloaddition with a dienophile,
00:21:56 ultimately leading to the interesting isolactoruparins sterepilide and merlediol.
00:22:05 It is curious to ask whether we could take this chemistry one step further.
00:22:12 Can we, instead of generating an E dialkylidene cycloalkane,
00:22:17 can we find a way of using this concept to generate a Z dialkylidene cycloalkane?
00:22:23 Perhaps examination of the process would give us a clue as to how that might be done.
00:22:29 We note that the E olefin geometry stems from the fact that the substituent is on the acetylene
00:22:36 and we are carrying out the addition in a cis-sin fashion of an HPD bond.
00:22:43 What would happen if we would invert those two substituents?
00:22:47 We would place the hydrogen on the acetylene, thereby using a terminal acetylene,
00:22:52 and the substituent we wish to introduce on the metal, thereby generating a cis-sin addition of the RPD species.
00:23:02 The result then should be a Z dialkylidene cycloalkane.
00:23:08 Now remember that the RPD X species can be easily generated
00:23:13 by the oxidative addition of palladium zero into some RX entity.
00:23:21 The reaction that we are going to consider is utilizing a vinyl bromide,
00:23:26 which comes from an olefination of a very well-known ketone, the so-called Grunemann's ketone.
00:23:32 When we take this vinyl bromide and a 1,7-enine and utilize a palladium zero complex,
00:23:39 dibenzylidene acetone palladium, and a one-to-one mixture of toluene and triethylamine
00:23:44 in the presence of triphenylphosphine, we undergo this alkylative cyclization,
00:23:50 in this case to generate the very important vitamin D metabolites.
00:23:57 In this one step, we not only attach the CD ring to the subsequent parts of the molecule,
00:24:04 but we simultaneously form the A ring with the proper geometry of the dialkylidene cycloalkane.
00:24:13 The ability to affect diastereoselectivity, or relative stereochemistry,
00:24:19 using these transition metals is not limited to olefin geometry.
00:24:23 We also can obtain some astounding results in controlling stereochemistry of displacement reactions.
00:24:30 Let us return to the pi-allyl palladium substitution reactions,
00:24:36 since this offers an examination of the stereochemical complementarity that we can achieve
00:24:42 in transition metal reactions compared to non-transition metal reactions.
00:24:47 In this process, the palladium coordinates to the olefin, but on the face opposite that of the X substituent.
00:24:55 It then initiates the ionization of that X group, generating the pi-allyl palladium species,
00:25:02 a process that occurs with inversion of configuration.
00:25:06 The nucleophile then approaches in a fashion in the microscopic reverse of the ionization reaction.
00:25:13 This therefore means that it attacks on the face of the pi-allyl palladium,
00:25:18 also opposite that of the palladium, to give you the product.
00:25:22 The two inversions then translate into a net substitution with retention of configuration.
00:25:31 Remember that these processes proceed independent of the regiochemistry of the starting material.
00:25:39 That means that if we take a substrate, such as the mono-epoxide of cyclopentadiene,
00:25:45 or an allylically related substrate, such as a mono-carboxylate from 3,5-dihydroxycyclopentene,
00:25:53 in both cases, these will react with some nucleophile,
00:25:58 and in the case chosen, the nucleophile is a purine base,
00:26:02 using palladium zero catalysis to give you the identical product,
00:26:07 whereby the nucleophile is introduced to give you only the 1,4 substitution product,
00:26:14 and most importantly, with clean retention of stereochemistry.
00:26:21 Can we now extend our ability of controlling stereochemistry in such processes to an antioselectivity?
00:26:32 This becomes much more daunting, because as I've already indicated,
00:26:38 bond breaking and bond making occur on the face of the pi-allyl palladium moiety,
00:26:45 opposite that of the metal.
00:26:48 That means that any stereochemistry associated with ligands coordinated to the metal
00:26:55 will have little effect in the region of space where that bond making and bond breaking are occurring.
00:27:02 We therefore need to find some way to project the chiral environment around the substrate.
00:27:11 One way that we might be able to achieve that is to use a ligand,
00:27:16 whereby the chiral scaffold is inducing chirality around the coordinating phosphine groups
00:27:24 that embrace our substrate.
00:27:28 In this way, we are going to increase the phosphorus-palladium-phosphorus bond angle,
00:27:37 the so-called bite angle,
00:27:39 and by so doing, that bite angle hopefully will propel this chiral environment towards the substrate.
00:27:49 A way to achieve that is in a modular design for ligands,
00:27:55 whereby we would take some C2 symmetric diol,
00:27:59 or better yet, a C2 symmetric diamine,
00:28:03 such as the RR12 diamino cyclohexane,
00:28:08 and attach some binding posts by an acylation reaction,
00:28:14 an acylation with 2-diphenylphosphenobenzoic acid.
00:28:18 The resultant complex that is generated by first coordinating palladium
00:28:24 and then the substrate,
00:28:27 and in the case shown, the substrate is a diester of 3,5-dihydroxycyclopentene.
00:28:37 Indeed, a molecular modeling based on the CASH system
00:28:42 shows that we indeed create exactly the kind of shallow pocket that we require.
00:28:50 In the particular example,
00:28:52 we treat this dibenzoate of 3,5-dihydroxycyclopentene
00:28:57 with 2-methylcyclohexane dione.
00:29:01 The reaction proceeds to lead to preferential ionization of the pro-R leaving group
00:29:08 to give you the alkylated product in an astounding 95% chemical yield
00:29:15 and a 91% enantiomeric excess.
00:29:19 Now it should be remembered that the minor product of this reaction,
00:29:23 where the pro-S leaving group was preferentially substituted,
00:29:28 still retains the pro-R leaving group,
00:29:32 a group which would ionize more readily with this particular enantiomeric catalyst
00:29:39 than a pro-S group.
00:29:41 Thus we would anticipate that we could carry out some dialkylation
00:29:48 whereby the minor monoalkylated product would react more rapidly
00:29:53 than the major monoalkylated product.
00:29:57 Indeed, if we simply use 1.2 equivalents of our nucleophile,
00:30:04 then one can reduce the yield slightly to 84%,
00:30:09 but the enantiomeric excess of the monoalkylated product is now 98%,
00:30:16 meaning that we have 99% of one enantiomer
00:30:19 and only 1% of its mirror image isomer.
00:30:24 We see here an example of a student carrying out the asymmetric addition
00:30:28 of a nucleophile to a palladium allyl species
00:30:32 using a C2 symmetric diamine as the chiral ligand.
00:30:36 Into the first test tube is added the nucleophile,
00:30:39 and it is diluted with dichloromethane.
00:30:42 In a separate test tube, the palladium catalyst is added,
00:30:46 followed by the chiral diamine.
00:30:48 This solid reaction mixture is diluted with dichloromethane,
00:30:52 and the solution becomes light yellow and homogeneous.
00:31:06 This mixture is immediately added to the previously prepared solution
00:31:10 containing the nucleophile.
00:31:14 After one minute, the allyl acetate substrate is added to the test tube dropwise,
00:31:20 and the solution is stirred at room temperature.
00:31:23 The reaction mixture remains slightly heterogeneous
00:31:26 as the nucleophile is partially insoluble under these conditions.
00:31:30 After stirring for three hours, the product is isolated by column chromatography
00:31:35 and the chemical yield and the optical purity are determined.
00:31:40 So far, we have focused only on the important aspect of selectivity,
00:31:45 but as I said at the outset,
00:31:47 we should not forget the very important concept of atom economy.
00:31:52 And here, transition metals also can play a very important role
00:31:56 in helping to improve our processing.
00:31:59 In the optimum process, what we'd like to be able to do
00:32:03 is to take simple building blocks,
00:32:06 such as a building block A and a building block B,
00:32:10 and in some ways cement them together to build our edifice C,
00:32:15 where anything else that's going to be required
00:32:17 would only be required in a catalytic sense.
00:32:21 When we think about trying to do so,
00:32:24 we already have very many beautiful illustrations
00:32:28 of how powerful some of the methods that we have available are.
00:32:32 Let's consider a process being developed by Curare and Arco
00:32:36 for the commercial synthesis of 1,4-butanediol.
00:32:41 In this process, propylene oxide is first isomerized
00:32:46 while at high temperature using a lithium phosphate catalyst to aloe alcohol.
00:32:52 The aloe alcohol then participates in a series of simple addition reactions,
00:32:58 the first being a rhodium-catalyzed hydroformylation
00:33:02 to generate 4-hydroxybutanol,
00:33:05 and the second addition of molecular hydrogen
00:33:08 to generate the final product using a rainy nickel catalyst.
00:33:13 In this process, then, we are taking propylene oxide,
00:33:18 two molecules of molecular hydrogen,
00:33:21 one molecule of carbon monoxide,
00:33:23 and simply adding them to each other to generate our final target.
00:33:29 We can take the concept of simple additions
00:33:33 one step further in allylic alkylations.
00:33:38 In this case, we replace our allylic X partner with simply a diene,
00:33:45 and we can take our active methylene compound
00:33:48 and add it to a diene using a palladium catalyst
00:33:52 generated from pi-allopalladium chloride
00:33:55 and a special ligand, 1,3-bis-diphenylphosphenopropane.
00:34:01 Thus, when one takes myrcene and methyl acetoacetate,
00:34:05 one obtains the one-to-one addition product,
00:34:09 the major product of which is an important intermediate
00:34:14 for the synthesis of vitamin A and vitamin E.
00:34:19 Palladium is not unique in being able to promote such one-to-one addition products.
00:34:24 Using a water-soluble rhodium catalyst,
00:34:28 the Rhone-Poulenc Company has now initiated a plant
00:34:33 to produce this intermediate from commercial myrcene and methyl acetoacetate.
00:34:39 Now, in their process, they do not involve pi-allopalladium intermediates.
00:34:44 It proceeds by a different mechanism.
00:34:46 Fortunately, the products that are being formed
00:34:49 are only isomeric in the sense of olefin geometries
00:34:53 and the positions of the double bond.
00:34:56 Fortunately, in this particular process,
00:35:00 the products can all be ultimately converted to a single material,
00:35:05 pseudoionone, which is indeed the commercial intermediate
00:35:09 for the synthesis of both vitamin A and vitamin E.
00:35:14 We can take this notion of atom-economical reactions
00:35:19 and extend it to cyclization processes.
00:35:22 In fact, the enyne cyclizations that we saw previously
00:35:26 are excellent illustrations since they are cycloisomerizations.
00:35:30 We can build our enyne substrates by a series of simple additions
00:35:35 of, for example, acetaldehyde and hydrogen to a suitable diene.
00:35:40 The enyne then may participate in a cycloisomerization
00:35:45 to generate the dialkylidene cycloalkane,
00:35:48 which then can undergo an addition reaction,
00:35:52 the very, very famous and important Diels-Alder reaction,
00:35:56 to generate a tricyclic product.
00:35:59 Thus, by simple series of additions and isomerizations,
00:36:05 acyclic building blocks can be joined together
00:36:09 to generate a tricyclic nucleus with high diastereoselectivity.
00:36:16 The idea of forming rings is particularly important and useful
00:36:22 by using transition metals,
00:36:24 because processes which are not conceivable
00:36:27 in the absence of transition metals
00:36:29 are now not only conceivable, but have already been developed.
00:36:35 Let's consider a 2 plus 2 plus 2 cyclooligomerization reaction.
00:36:42 If one takes C triple bond C or C triple bond N species,
00:36:49 we can affect cyclooligomerization reactions using a cobalt catalyst.
00:36:55 Thus, if you take acetylenes and nitriles,
00:36:58 you can generate a very practical synthesis of pyridines.
00:37:04 Even utilizing acrylonitrile,
00:37:07 a species which is generally thought to be reactive
00:37:10 at the carbon-carbon double bond,
00:37:12 occurs by participation of the carbon-nitrogen triple bond
00:37:16 and forms a practical synthesis of two vinyl pyridine.
00:37:23 We can extend our ability of affecting bimolecular additions
00:37:29 from the thermally allowed 4N plus 2
00:37:33 to the normally not achievable 4N variety
00:37:36 by using transition metals.
00:37:39 Thus, 4 plus 4 cycloadditions to generate 8-membered rings
00:37:45 is now possible by using a nickel-zero catalyst.
00:37:50 The intramolecular version of that process is particularly useful
00:37:54 and formed a key step in a very simple and direct synthesis
00:38:01 of the novel terpenoid asteroscanolide.
00:38:07 In concluding our discussion,
00:38:09 I'd like to address the issue as to whether we can rationally design
00:38:13 new reactions that can solve problems of synthetic efficiency.
00:38:18 In trying to approach this question,
00:38:21 we can ask what types of novel intermediates
00:38:25 might be generated using transition metals.
00:38:30 We can learn one aspect by taking advantage of the fact
00:38:34 that transition metals interact with acetylenes particularly well,
00:38:38 and they can do that in a number of ways.
00:38:41 If we take a terminal acetylene,
00:38:43 one thing they can undergo is insertion into the acetylenic C-H bond
00:38:47 and thereby generate a metal acetylide
00:38:49 suitable to undergo some type of catalytic reaction.
00:38:54 One process that that metal acetylide can undergo
00:38:57 is a further reaction, this time with a proton,
00:39:00 to generate yet another kind of novel reactive intermediate,
00:39:04 a vinylidene metal species.
00:39:08 Can we use that vinylidene metal species to invent a catalytic cycle?
00:39:13 Well, once again, we're going to begin with a metal
00:39:15 and allow it to interact with a terminal acetylene,
00:39:17 and just imagine that it generates this vinylidene metal intermediate.
00:39:22 By taking advantage of the ability of transition metals
00:39:25 to coordinate with carbon-carbon pi unsaturation,
00:39:29 we can allow that transition metal complex
00:39:32 to interact with an allyl alcohol
00:39:35 by first coordinating to the pi bond,
00:39:38 and by so doing, allowing the alcohol
00:39:41 to undergo attack onto the vinylidene metal species.
00:39:47 The resultant product is an alkylidene metal species
00:39:52 that possesses the elements of a 1,5-diene.
00:39:57 Now we know that 1,5-dienes are capable of
00:40:00 undergoing the so-called Cope rearrangement.
00:40:04 Even though one of the atoms of the 1,5-diene is a metal,
00:40:08 that should make little difference.
00:40:11 And indeed, one would anticipate that that Cope rearrangement
00:40:16 would generate an acyl pi-allyl metal species,
00:40:20 which might then undergo a reductive elimination,
00:40:23 regenerating the metal to initiate another catalytic cycle,
00:40:26 and giving us a product, in this case,
00:40:29 a beta-gamma unsaturated ketone.
00:40:32 So the reaction that we've invented
00:40:34 is a process whereby allyl alcohol and terminal acetylene
00:40:39 undergo a simple addition,
00:40:42 forming a new carbon-carbon bond,
00:40:44 and readjusting the oxidation pattern
00:40:47 to give a very useful beta-gamma unsaturated ketone.
00:40:53 In practice, we could take a terminal acetylene,
00:40:56 such as that derived from a steroid,
00:40:59 even a steroid possessing functionalities
00:41:01 such as an alpha-beta unsaturated ketone,
00:41:04 dissolve it in allyl alcohol,
00:41:06 to which is added a catalytic amount
00:41:09 of cyclopentadienyl bis-triphenylphosphine ruthenium chloride,
00:41:13 and a catalytic amount of a mild acid catalyst,
00:41:16 such as ammonium hexafluorophosphate.
00:41:19 Heating this mixture to 100 degrees
00:41:22 gives rise to the beta-gamma unsaturated ketone.
00:41:27 If we prolong the heating,
00:41:30 we can take advantage of the fact
00:41:32 that transition metals are also capable
00:41:34 of isomerizing double bonds.
00:41:37 The beta-gamma unsaturated ketone
00:41:40 then can be isomerized
00:41:43 to a thermodynamically more stable alpha-beta unsaturated isomer,
00:41:47 thereby setting the stage for conjugate additions.
00:41:51 Conjugate addition of cyanide ion and hydrolysis
00:41:54 then generates a functionalized steroid side chain
00:41:58 that corresponds to the steroid side chain
00:42:01 of the novel class of ACE inhibitors
00:42:05 known as ganaderic acid.
00:42:08 What I have tried to do today
00:42:10 is to give you a simple tasting
00:42:12 of some of the things that are possible using transition metals.
00:42:15 By no means should this be considered
00:42:17 to be a comprehensive list of what is possible.
00:42:20 There are many, many other exciting opportunities
00:42:23 that have already been developed.
00:42:25 Nor is it meant to imply
00:42:27 that these are the only things that one can do
00:42:29 using transition metals.
00:42:31 By any yardstick,
00:42:33 we are simply at the very beginning
00:42:35 of being able to invent new types of organic reactivity.
00:42:39 Among the areas that has received the most attention
00:42:42 has been the area approaching the problem
00:42:45 of enantioselectivity.
00:42:47 There has been great strides made in abiological catalysis.
00:42:51 And as a result,
00:42:53 the next section of this ACS teleconference
00:42:56 will deal with this theme in quite some detail.
00:43:02 The next speaker is Dr. K. Barry Sharpless.
00:43:05 He is Keck Professor of Chemistry
00:43:07 at the Scripps Research Institute.
00:43:09 He has devoted his entire academic career
00:43:12 to finding new selective organic transformations
00:43:15 using inorganic catalysts.
00:43:17 He discovered asymmetric epoxidation
00:43:20 and dihydroxylation.
00:43:22 Dr. Sharpless' topic today
00:43:24 is asymmetric catalysis.
00:43:29 Our subject today is catalysis.
00:43:31 This is a very large field.
00:43:34 But we are fortunately going to focus on a small section,
00:43:37 namely that catalysis which impinges on organic synthesis.
00:43:41 Everyone needs to make organic molecules
00:43:45 in the fields of practical uses for mankind.
00:43:51 Drugs and pharmaceuticals are obvious points.
00:43:55 But we need to have better and more selective ways.
00:43:59 The biological catalysts are notorious
00:44:03 for their great selectivity.
00:44:05 These are the enzymes.
00:44:07 And things that aren't enzymes,
00:44:09 essentially everything else, is the abiological.
00:44:12 This is the area I specialize in.
00:44:15 And it has a lot of novelty right now.
00:44:21 It's underdeveloped,
00:44:23 and it's just a new field in the last 20 years.
00:44:26 But it's developing to the point of practicality,
00:44:29 and I'll try to emphasize that today.
00:44:32 An interesting, slightly humorous way
00:44:35 to look at the dichotomy between biological catalysis
00:44:39 or biological chemistry and the rest of the world
00:44:42 is shown in this model of the universe,
00:44:45 where you have a great white space
00:44:47 which is all of chemistry contained,
00:44:50 and then a small little dot down the corner
00:44:53 is biological chemistry.
00:44:55 This may upset some people,
00:44:57 but the point is that biological chemistry
00:45:00 is the most important for man to understand and work on.
00:45:04 Nobody doubts that, and I certainly don't.
00:45:09 The question I have is,
00:45:11 are we perhaps missing some really nice chemistry out there
00:45:14 in the unknown provinces that could be imported back
00:45:17 to help us do our job,
00:45:19 make life processes better and healthier on this planet?
00:45:25 And this is my main point about the catalysis I'll talk in today.
00:45:29 I'll try to find catalysts that nature doesn't use
00:45:33 that are useful for these practical uses
00:45:37 to make asymmetric materials.
00:45:40 So this is the main focus of our talk,
00:45:42 asymmetric catalysis.
00:45:45 Nature's catalyst shown here
00:45:48 is the clear winner in terms of selectivity.
00:45:53 We have always been in awe of enzymes.
00:45:55 They are something we're made of,
00:45:58 and we never cease to be amazed by their selectivity.
00:46:01 The most interesting selectivity of all
00:46:04 is they take prochiral substrates
00:46:06 and transform them with seemingly perfect selectivity
00:46:11 into pure enantiomers.
00:46:13 This is something that we have never been able to do
00:46:16 with the same fidelity,
00:46:18 and we have been trying to mimic this process
00:46:21 for the last 20 or more years.
00:46:24 Today I talk about our successes in this area,
00:46:27 and you'll see that they're not insubstantial,
00:46:30 but they're still not perfect.
00:46:36 The periodic table is our garden.
00:46:38 We try to use it for a wide-ranging selection
00:46:42 of possible reactivities.
00:46:44 In the middle of the periodic table
00:46:46 stand the transition elements,
00:46:48 which are our special actors
00:46:51 because they have such versatile chemistry.
00:46:53 Most of the best catalysts are constituted
00:46:56 with this type of metal at the core.
00:46:59 My talk today is on titanium in the upper left,
00:47:04 on manganese in the middle top,
00:47:09 and on osmium in the bottom central part
00:47:12 of the transition metals.
00:47:14 Today we'll concentrate on the oxidation of olefins.
00:47:19 You see here the paradigm
00:47:21 for selective oxidation of olefins,
00:47:24 an olefin being transformed into its epoxides.
00:47:28 This is at the top of every chemist's wish list
00:47:32 for a biological selective catalyst.
00:47:36 The top epoxide, the SS epoxide,
00:47:40 is the result of attachment of an oxygen atom
00:47:43 to the top face of the 2-butene, shown here.
00:47:48 The bottom face is attacked by an oxygen
00:47:51 to produce the enantiomer, the RR epoxide,
00:47:54 shown on the lower right.
00:47:56 This simple operation, if you can achieve it,
00:48:00 would have tremendous importance
00:48:03 for the pharmaceutical industry
00:48:05 and other allied industries,
00:48:08 since epoxides are very versatile synthetic intermediates
00:48:12 and we need to find better ways to make them.
00:48:16 Enzymes come in one-handed form.
00:48:20 Nature gives us enzymes made of L-amino acids.
00:48:23 They're readily available,
00:48:25 and especially so thanks to modern molecular biology.
00:48:29 This representation of an enzyme,
00:48:32 you see the natural one on the left,
00:48:34 and on the right is a photographic flop
00:48:37 of what you see on the left,
00:48:38 and it's the unnatural, the mirror image by definition.
00:48:41 This we cannot get easily.
00:48:44 Interestingly, that Scripps, Stephen Kent's group,
00:48:48 has just succeeded in synthesizing
00:48:50 the first mirror image enzyme made out of D-amino acids.
00:48:54 HIV protease is the enzyme,
00:48:57 and it has the enantiomeric substrate preferences as it must.
00:49:03 This is a useful and interesting event,
00:49:07 but it doesn't help provide enantiomeric enzymes
00:49:11 for use in catalysis.
00:49:13 We are basically stuck with the left-handed enzyme
00:49:18 on this representation.
00:49:22 We must work with this,
00:49:24 and it's a limitation that abiological catalysts
00:49:28 generally don't have.
00:49:30 I should add, though, at this point,
00:49:32 that these two enzymes happen to be antibodies,
00:49:36 and my colleague at Scripps,
00:49:39 Richard Lerner and Peter Schultz of this panel,
00:49:44 are created catalytic antibodies,
00:49:47 and they are in some way a mixture
00:49:50 of abiological and biological catalysts,
00:49:53 and catalytic antibodies can be made
00:49:55 to make either enantiomer in a catalytic process.
00:50:01 Unlike enzymes,
00:50:03 the man-made catalysts usually come in both-handed forms.
00:50:07 We can have the left-handed and the right-handed catalyst.
00:50:11 Here you see the reaction discovered in my laboratory
00:50:15 by Tsutomu Katsuki in 1980,
00:50:18 the asymmetric epoxidation.
00:50:20 This reaction starts with an allylic alcohol,
00:50:23 shown on the left,
00:50:25 and the simple difference of adding minus-diethyltartrate,
00:50:31 which comes together and makes a complex
00:50:33 with the titanium shown over the arrow,
00:50:36 produces a catalyst which takes the oxygen atom
00:50:39 out of the peroxide, also shown over the arrow,
00:50:42 and delivers it to the top face of the olefin.
00:50:46 This gives almost pure enantiomers of epoxy alcohols.
00:50:51 If we wish, the other enantiomer,
00:50:53 attacked from the bottom face,
00:50:54 is achieved by taking the other diethyltartrate
00:50:58 and using it as the only change in the recipe.
00:51:02 Such simple either-or chemistry
00:51:05 really helps the planning in organic synthesis,
00:51:09 and chemists have found this reaction to be very useful
00:51:12 because of its generality.
00:51:14 This is also worth emphasizing.
00:51:17 Here was a lesson we did not learn from nature.
00:51:20 Nature had taught us that we should bind
00:51:23 in a very intimate lock-and-key way,
00:51:25 originally proposed by Emil Fischer,
00:51:28 the great German sugar chemist,
00:51:30 to our substrates,
00:51:32 that this is the way to achieve selectivity.
00:51:35 Well, this paradigm for selectivity
00:51:37 did not enable us to foresee that one catalyst
00:51:40 would be able to take an allylic alcohol
00:51:43 with many types of R groups.
00:51:45 I've shown R1, R2, R3.
00:51:49 Almost any combination of groups
00:51:51 can work in this chemistry,
00:51:53 and this is what I think most surprised people
00:51:56 about the asymmetric epoxidation today
00:51:59 and at the time it was discovered
00:52:01 it's still its most unusual feature.
00:52:05 Now we turn to biological catalysis for a moment
00:52:09 in the oxidation arena,
00:52:11 and we'll talk about squalene monooxygenase.
00:52:13 This is an enzyme that's very important.
00:52:16 It's in our livers working right now,
00:52:18 and what it accomplishes
00:52:20 is the epoxidation of squalene.
00:52:22 Squalene has six double bonds,
00:52:25 and it's shown at the second structure
00:52:27 from the bottom,
00:52:29 and the enzyme takes an oxygen atom
00:52:31 and adds it very handily
00:52:33 to one of those double bonds
00:52:35 and only from one face.
00:52:37 It gives the S epoxide as shown.
00:52:40 In the liver, at the same time,
00:52:42 we have a number of other olefins,
00:52:45 including the precursors of squalene.
00:52:48 These are the little C5, C10, and C15 parental alcohols,
00:52:53 and you see them 1, 2, and 3 at the top left.
00:52:57 They are not substrates
00:53:00 for squalene monooxygenase, apparently.
00:53:03 The enzyme can recognize them
00:53:05 as not interesting candidates for epoxidation,
00:53:09 and so the enzyme can coexist
00:53:12 and do its job without trouble
00:53:15 from these imposters.
00:53:17 Now let us present the same group of olefins
00:53:21 to an abiological catalyst,
00:53:23 the titanium tartrate asymmetric epoxidation catalyst.
00:53:27 What you'll see now
00:53:29 is that we have quite a different situation.
00:53:33 There are four olefins in this flask
00:53:36 that we've artificially set up,
00:53:38 and they are the three precursor alcohols
00:53:42 to squalene and squalene itself.
00:53:44 Squalene, lying at the bottom,
00:53:46 is totally rejected by our man-made catalyst.
00:53:49 It simply can't find a place to get a hold of it.
00:53:52 It needs a hydroxyl to bind itself to the substrate.
00:53:58 The other three candidates
00:54:00 are all quite interesting to titanium tartrate.
00:54:03 They all have an alcohol handle,
00:54:06 and they all will be very happy substrates for this system.
00:54:09 And in fact, if you then introduce the catalyst,
00:54:13 what you'll see is simultaneous
00:54:16 and complete oxidation of all three double bonds
00:54:20 that are approximate to the hydroxyl,
00:54:23 producing the three products on the right,
00:54:25 which are now going to be a trouble,
00:54:28 a problem for the synthetic chemists
00:54:30 because we don't like mixtures.
00:54:32 We'd have to separate them.
00:54:33 We don't know how to do that easily usually.
00:54:35 But this, of course, is not a real problem
00:54:38 because synthetic chemists aren't trying to prove
00:54:41 their catalyst is a macho catalyst
00:54:44 and can do what an enzyme does.
00:54:46 We only put one thing in the flask at a time,
00:54:49 and therefore we overcome this lack of substrate specificity
00:54:53 by just being selective in the way we run our reactions.
00:54:59 I just showed you that titanium tartrate
00:55:02 was not interested in an olefin without a hydroxyl group.
00:55:06 Now let's look a little more closely
00:55:08 at the titanium tartrate catalyst as it actually works.
00:55:11 There are two titaniums and two tartrates.
00:55:14 They bind alkoxides reversibly,
00:55:18 and one of the alkoxides they get a hold of once in a while
00:55:20 is the substrate, shown here bound on the upper right
00:55:24 as the aloxy group.
00:55:26 This group is poised now to receive its oxygen atom
00:55:30 from the peroxide group, which is also bound nicely
00:55:34 and ready to go in the lower right.
00:55:38 This tight little package makes a pretty picture
00:55:42 and provides us with our best understanding
00:55:44 of the mechanism of the asymmetric epoxidation,
00:55:47 but it's an unfortunate requirement in reality
00:55:50 from a synthetic point of view.
00:55:52 A lot of olefins don't have a hydroxyl group.
00:55:55 This hydroxyl group is an absolute requirement here.
00:55:58 So what we would like to accomplish
00:56:01 is the same epoxidation, phase selective epoxidation,
00:56:05 without any hydroxyl group.
00:56:08 Here you see the WISH reaction shown as a question mark.
00:56:12 Can we remove the hydroxyl group shown in the bottom reaction
00:56:16 where there's a check?
00:56:17 Yes, we know we can do asymmetric epoxidation now
00:56:20 using the hydroxyl-bearing olefin,
00:56:22 but can we do it without that hydroxyl?
00:56:25 This has been a long-sought objective
00:56:28 of synthetic organic chemists,
00:56:31 and progress has been made suddenly.
00:56:34 There was a breakthrough at Illinois in Eric Jacobson's lab
00:56:37 a few years ago now,
00:56:39 and this is a real important lead for us
00:56:44 to achieve epoxidation of isolated olefins.
00:56:48 The Jacobson catalyst is shown here.
00:56:51 It's a manganese-based system
00:56:54 with an oxo group shown projecting up towards you,
00:56:58 and it consists of a plate of ligands
00:57:01 which are very inexpensive and easy to make.
00:57:04 It's a saline ligand,
00:57:06 and the stereogenic centers are embedded in the back
00:57:11 by the cyclohexane ring.
00:57:13 The other ingenious part of the design
00:57:16 are the bulky t-butyl groups.
00:57:19 These are positioned so as to completely preclude attack
00:57:23 from quadrants A, B, and C
00:57:26 so that the olefin is constrained to approach
00:57:29 from quadrant D.
00:57:31 And this brings it right over
00:57:33 the influencing asymmetric area in the catalyst,
00:57:36 and the result is that with cis-olefins,
00:57:38 it gives outstanding EEs,
00:57:41 and it's been successful
00:57:45 for a wide range of cis-olefins.
00:57:48 The process is limited in its scope
00:57:52 because cis-olefins are preferred,
00:57:55 but it's an exciting beginning for this difficult challenge.
00:57:59 The importance of the Jacobson epoxidation
00:58:03 is underscored by its practicality.
00:58:07 The oxidant is actually bleach, sodium hypochlorite.
00:58:11 This is the source of the oxygen atom
00:58:13 which continuously recharges the manganese
00:58:16 with an oxo group.
00:58:18 Here you see a transformation
00:58:22 of a pharmaceutically important intermediate,
00:58:25 a material called a chromine,
00:58:27 on the upper left.
00:58:29 The catalyst epoxidizes this chromine
00:58:32 with unbelievable effectiveness.
00:58:34 If you look at the right,
00:58:35 you see the yield is 96%,
00:58:37 and the enantiomeric excess is 97%.
00:58:41 This is as good as one could hope for,
00:58:46 and maybe not perfect enzymic selectivity,
00:58:49 but usually you take such materials
00:58:51 and crystallize them up to 100% EE.
00:58:55 The great effectiveness of the Jacobson epoxidation
00:58:58 for chromines is extremely fortunate
00:59:02 because it falls right into an application
00:59:05 for the synthesis of a pharmaceutical compound,
00:59:08 chromicalin,
00:59:09 which is directly available from this epoxide.
00:59:13 My group at MIT and now at Scripps
00:59:16 has also been able to meet the challenge
00:59:18 of asymmetrically oxidizing isolated olefins
00:59:23 if you will grant us that we can make diols
00:59:27 rather than epoxides.
00:59:29 The process involves osmolation of olefins.
00:59:32 As shown, you start with an olefin such as stilbene,
00:59:37 and if you use a chiral ligand
00:59:39 of one-handed character, dihydroquinidine,
00:59:42 you take the top channel to produce the RR diol
00:59:46 in almost perfect EE,
00:59:48 and if instead you take the pseudo-enantiomeric ligand,
00:59:53 dihydroquinine,
00:59:55 you obtain the SS diol
00:59:58 in also extremely high enantiomeric excess.
01:00:02 We first need to demonstrate the many advantages
01:00:06 which accrue when one can deal
01:00:09 with an isolated functional group
01:00:11 such as an olefin with no auxiliary needed
01:00:14 to tether the reacting species to the catalyst.
01:00:18 The table shown is a direct comparison
01:00:24 of the earlier described asymmetric epoxidation, AE,
01:00:29 and the new AD process.
01:00:32 For a family of olefins which are closely related,
01:00:37 we have an ethylene unit disubstituted
01:00:40 with a phenyl on the left side
01:00:43 and a carbon of some ilk on the right,
01:00:46 starting with the first hydrocarbon species,
01:00:50 the propenyl benzene,
01:00:52 and then being decorated successively
01:00:55 with functional groups,
01:00:58 an alcohol, a protected alcohol in several ways,
01:01:03 the azide, the chloride derivative,
01:01:06 and then oxidizing the alcohol to the aldehyde
01:01:09 and having a protected derivative of that,
01:01:11 or oxidizing formally up to the acid
01:01:14 and having the ester or an amide.
01:01:17 You notice that all results in the AD column
01:01:21 are greater than 95% EE,
01:01:24 except, ironically, for the allylic alcohol.
01:01:27 This is 80%,
01:01:29 and the alcohol-hydrogen bond disrupts the AE process.
01:01:35 The asymmetric epoxidation finds this to be, of course,
01:01:38 its only target substrate,
01:01:41 and it does a very good job on synamal alcohol,
01:01:45 but no other successful entries in the AE column.
01:01:50 The asymmetric ligand used to achieve
01:01:52 the excellent EEs just shown
01:01:55 is a new ligand for us.
01:01:58 It is an unusual ligand.
01:02:00 It has two alkaloids in one package.
01:02:03 They're each connected symmetrically
01:02:05 to a central heterocyclic core of thalazine.
01:02:08 We found these after much experimentation,
01:02:12 more or less empirical.
01:02:13 We went through 270 different synchona ligands
01:02:16 over the last four years,
01:02:18 and these are our best ligands to date.
01:02:22 This X-ray structure gives you an idea
01:02:24 of how the osmium tetroxide is bound to the synchona alkaloid.
01:02:29 It's not the thalazine ligand that it's binding to.
01:02:32 It's an earlier, simpler ligand,
01:02:34 which has only one nucleus of the alkaloid in it.
01:02:38 But you see that the osmium is very clearly bound
01:02:41 to the quinucleidine nitrogen.
01:02:44 How this achieves the high asymmetric induction
01:02:47 in this system is still a mystery to us,
01:02:52 but we are working hard on the mechanism.
01:02:55 I can't talk about that today.
01:02:57 It's still uncertain.
01:02:58 I can only tell you that when these three creatures
01:03:01 come together, the osmium, tetroxide,
01:03:04 the chiral ligand, and the olefin,
01:03:07 the result is a very enantioselective process
01:03:10 which we can map empirically.
01:03:13 And we have over 200 olefins
01:03:16 that have been used to make this map.
01:03:20 As you see in this scheme,
01:03:22 we have an empirically derived mnemonic device
01:03:26 for explaining the enantioselectivity.
01:03:29 It appears as if there is a large blocking wall
01:03:32 in the lower right quadrant,
01:03:34 a somewhat smaller blocking wall in the upper left,
01:03:37 an open valley lying in between
01:03:40 with exits on the lower left and upper right
01:03:43 that are more or less free of encumbrance.
01:03:46 The large group should be on the lower left
01:03:48 and the next sized medium group should be on the upper right.
01:03:53 And then you can have a smallish group in the upper left.
01:03:56 A hydrogen is preferred in the quadrant facing
01:03:59 the steep blocking wall.
01:04:02 Placing the olefin as required in the scheme
01:04:05 by the mnemonic,
01:04:08 one obtains either the beta-diol,
01:04:11 if you use quinidine,
01:04:13 the hydroxyls are delivered very selectively from the top,
01:04:16 and if you switch your ligand to the quinine-based
01:04:20 thalazine ligand, the hydroxyls come in
01:04:23 very selectively from the bottom.
01:04:25 This is noted here as admix beta channel
01:04:29 and admix alpha channel.
01:04:32 This we'll describe momentarily.
01:04:35 AD means asymmetric dihydroxylation.
01:04:38 This is a formulation that we've put together
01:04:41 which is a ready-made mix.
01:04:44 Olefins are extremely common starting materials
01:04:47 in organic synthesis.
01:04:49 They are produced industrially,
01:04:51 and they are ubiquitous in nature.
01:04:54 The substitution patterns of olefins are varied.
01:04:58 There are six types of substitution pattern,
01:05:01 and you see that as represented here,
01:05:05 the six types are substituted
01:05:08 with great complete flexibility,
01:05:10 so that this would represent all the olefins in the universe.
01:05:13 We don't think that all olefins are candidates
01:05:16 for the asymmetric dihydroxylation,
01:05:18 but most of them are.
01:05:20 The four groups on the left,
01:05:23 mono, gem-di, trans-di, and tri,
01:05:26 all have given results with the AD system
01:05:31 of greater than 95% EE.
01:05:33 The trans-di are by far the most reliable category
01:05:37 for working in almost every case.
01:05:41 Going to the two on the right,
01:05:43 the cis-olefin and the tetra-substituted olefin,
01:05:47 they are probably never going to be
01:05:52 great substrates for the process,
01:05:54 but we have a new ligand which won't be described today
01:05:57 in a manuscript to be appearing in JSCS
01:06:00 for cis-olefins.
01:06:02 They go up to 80% EE,
01:06:04 and tetra-substituted olefins have recently worked, too,
01:06:07 if you allow that one of the R groups
01:06:09 be an alkoxy group.
01:06:11 Therefore, we're dealing with highly substituted
01:06:13 enol ethers as the substrates.
01:06:16 An easy way to show the simplicity of the AD process
01:06:20 is a demonstration.
01:06:22 Before going to the demonstration,
01:06:24 you need to have some information about the admixes.
01:06:29 Admix beta is formulated as follows.
01:06:33 The bulk ingredient is ferric cyanide
01:06:35 followed by carbonate.
01:06:37 These are 99.5% of the total mass,
01:06:41 and then the precious active ingredients,
01:06:45 the alkaloid DHQ-squared thal
01:06:48 and the potassium ozomate salt.
01:06:52 These constitute less than half,
01:06:54 about a half a percent of the mixture.
01:06:57 And of course, admix alpha is exactly the same
01:07:00 except for the substitution
01:07:02 of the quinine-based thalazine ligand.
01:07:05 These admixes are yellow powders
01:07:08 when they're ground into their active form.
01:07:12 They have the yellow color due to the ferric cyanide.
01:07:16 We will now use admix beta and admix alpha
01:07:20 to do a right-handed and a left-handed
01:07:23 asymmetric dihydroxylation of stilbene.
01:07:26 There will be two essentially identical experiments.
01:07:29 The only difference will be admix alpha in one flask
01:07:33 and admix beta in the other flask.
01:07:36 The first ingredient to be added is the admix.
01:07:41 This is followed by a small amount of methane sulfonamide.
01:07:46 Now, I don't have time to discuss this today,
01:07:48 but this helps the turnover of the osmium catalysis.
01:07:52 Then we add 30 milliliters of solvent,
01:07:55 which is a one-to-one mixture of t-butanol and water.
01:07:59 These are stirred together,
01:08:01 and you will obtain a homogeneous solution,
01:08:04 but it's two phases now
01:08:06 because the salts have forced the phase separation
01:08:10 of the water and t-butanol.
01:08:13 Now, the olefin is added,
01:08:16 and stirring continues for as long as necessary
01:08:20 to complete the reaction.
01:08:24 The ferric cyanide is soluble under these conditions,
01:08:28 but as the reaction proceeds,
01:08:30 its progress is apparent from the salt
01:08:33 coming out of solution, which is ferrocyanide.
01:08:36 Also, there are other color changes which occur.
01:08:40 The admix alpha reaction is set up identically,
01:08:44 and both reactions were started at the same time,
01:08:48 and now you can see that they are both well along
01:08:52 because much precipitate has formed.
01:08:55 In these simple reactions,
01:08:57 one obtains almost a gram of pure RR still being diol
01:09:03 and pure SS still being diol.
01:09:05 It's the either-or aspect of a biological asymmetric catalysis
01:09:10 which makes it appealing for use in organic synthesis.
01:09:14 We have tried to find interesting applications
01:09:17 for the AD process in the real world,
01:09:21 and some drugs are especially attractive candidates
01:09:25 for this transformation.
01:09:27 Propranolol, for example,
01:09:29 was easily obtained in several steps
01:09:33 from owl naphthyl ether in very high EE.
01:09:39 The vitamin BT, which is L-carnitine,
01:09:43 was produced in several steps
01:09:46 by asymmetric dihydroxylation of owl bromide.
01:09:51 The biologically active S enantiomer of ibuprofen or Advil
01:09:56 has been made using the AD
01:09:59 of the corresponding alpha-methyl styrene as the key step.
01:10:04 Taxol side chain is an attractive candidate for AD
01:10:09 and has been produced in four steps in our laboratory
01:10:15 using cinnamate ester as the starting point.
01:10:21 We have become accustomed to the effectiveness and reliability
01:10:27 of the AD with a range of olefinic substrates.
01:10:31 However, even we were not prepared for a surprising result,
01:10:36 which is the multiple asymmetric dihydroxylation of a polyene, squalene.
01:10:43 This is olefin we have talked about before,
01:10:47 but now you see it being hydroxylated exhaustively
01:10:51 by the AD procedure.
01:10:54 The upper arrow shows AD beta
01:10:58 going to give a dodecahydroxy squalene
01:11:01 where all the hydroxyls are in place
01:11:04 very specifically on the top of the olefin.
01:11:07 Correspondingly, the AD alpha
01:11:11 places the 12 hydroxyls exclusively on the bottom of the molecule.
01:11:18 These two dodecaols are enantiomers of each other.
01:11:22 They are pure by NMR and by rotation.
01:11:26 They are clearly enantiomers.
01:11:28 In order to be certain that these structural assignments are correct,
01:11:32 the x-ray structure of the hexaacetinide
01:11:35 of one of the polyols was obtained
01:11:39 and it shows that the structure is as we thought it was.
01:11:44 In order to explain why this result was surprising to me,
01:11:49 I'd like to share with you an experience
01:11:52 while I was a graduate student at Stanford.
01:11:55 Professor Ireland's book on organic synthesis,
01:11:58 a little monograph had just come out,
01:12:00 and I was just learning how to do organic synthesis.
01:12:03 There were chapters in it
01:12:06 that had to do with the different problems
01:12:08 of planning a multi-step synthesis.
01:12:11 One was attractively titled
01:12:14 Stereochemistry Rears Its Ugly Head.
01:12:18 Then there was a chapter on logistics and practicality,
01:12:22 and this had to do with the arithmetic demon.
01:12:26 When a chemist runs 10 reactions in sequence
01:12:30 and each reaction depends on the previous one
01:12:33 for the starting material,
01:12:35 we have a problem in numbers.
01:12:38 Each yield has to be multiplied by each previous yield,
01:12:43 and then you end up with the overall yield,
01:12:46 which drops precipitously
01:12:48 if you don't have nearly 100% yields.
01:12:51 This is why the result with squalene is interesting.
01:12:57 If we turn to the squalene molecule,
01:13:00 we see there are six sites for oxidation.
01:13:03 These are the six double bonds arrayed along the backbone.
01:13:07 Each of these is attacked in a separate event
01:13:10 by one of the catalyst species,
01:13:13 and it can be either attacked from the top or the bottom.
01:13:16 That's one of the points.
01:13:18 The other point, of course, is
01:13:20 regardless of which site it's attacked from,
01:13:23 it has to be attacked in a certain overall successfulness,
01:13:28 which is the chemical yield.
01:13:31 Now, the analysis shown is that there are 12 events.
01:13:36 Let's try to factor these events out.
01:13:39 For each molecule, there are six chemical reactions.
01:13:43 Each double bond has to react at some point
01:13:45 if we're going to get a product.
01:13:47 Then we have the stereochemical aspects of these events.
01:13:52 We have one which is enantioselective,
01:13:55 and five subsequent ones after the first.
01:13:58 Wherever the first oxidation occurs,
01:14:00 it's enantioselective.
01:14:02 That's the nature of our definitions.
01:14:04 The rest become diastereoselective.
01:14:09 They all add up to a total of 12 events.
01:14:13 Each has a yield.
01:14:15 The chemical yields are obvious ones,
01:14:19 and then there are the stereo yields.
01:14:22 Each double bond has a preference for top and bottom,
01:14:26 and it's adding up then to multiplying these events
01:14:31 in their selectivity times each other.
01:14:34 We obtain, and this is the fact that we observe,
01:14:37 a single diastereomer in 78% overall yield.
01:14:42 This was determined in several ways.
01:14:44 The most precise was to use isotope dilution,
01:14:47 and this number is accurate within a percent.
01:14:52 The average yield then for each of these 12 steps,
01:14:56 which are linked inevitably together,
01:15:00 is 98%, which is the 12th root of 78%.
01:15:07 An average yield of 98% for each of the six yield steps
01:15:12 and stereo steps is on the verge of being believable.
01:15:18 The data seems to require it,
01:15:22 and if it were 99% for each step,
01:15:26 it would become unlikely,
01:15:29 but 98% is just on the verge of believable.
01:15:31 We know the terminal double bond of squalene,
01:15:34 when we take a monohydroxylation and isolate the terminal,
01:15:38 it's 96% EE,
01:15:40 and we feel that the internal double bonds
01:15:42 will be more selective,
01:15:44 so they can make up for that deficit.
01:15:47 The question of comparing biological
01:15:52 and abiological oxidations of squalene
01:15:54 introduced earlier is worth coming back to.
01:15:59 The enzyme that would do this type of perhydroxylation
01:16:04 of a polyene isn't known.
01:16:06 One could conceive of an enzyme that would take squalene
01:16:11 through its active site like peeling off rosary beads
01:16:15 and do this job, the same as the osmium catalyst has done.
01:16:21 But the only point I could make is that
01:16:26 it would be difficult for such an enzyme,
01:16:29 well, impossible for that same enzyme to make the enantiomer.
01:16:33 The nice thing is we can make, as usual,
01:16:35 an abiological catalysis, either enantiomer.
01:16:39 I would like to close now
01:16:41 with a particularly interesting example
01:16:44 of biological catalysis
01:16:47 from the laboratory of my colleague Chi-Huei Wang at Scripps.
01:16:51 Chi-Huei is an expert on the use of enzymes
01:16:54 for selective organic transformations.
01:16:57 One of the most interesting areas for this type of work
01:17:01 is sugar chemistry.
01:17:03 Sugar compounds are particularly hard to manipulate
01:17:07 because of the many functional groups,
01:17:09 and synthetic organic chemistry traditionally
01:17:12 manipulates these by protecting them.
01:17:15 In the case of using enzymes, you don't need to do this,
01:17:19 as Wang has demonstrated.
01:17:21 The synthesis of fructose L and D
01:17:26 using different enzymes is shown,
01:17:28 and the starting material for the L-fructose
01:17:32 is glyceraldehyde, L-glyceraldehyde.
01:17:37 It is condensed with dihydroxyacetone phosphate,
01:17:41 the enzyme utilizes rhamnose 1-phosphate aldolase.
01:17:46 The process is highly selective
01:17:48 and gives a good yield of L-fructose.
01:17:51 The opposite enantiomer, D-fructose,
01:17:55 can be obtained from the D-glyceraldehyde,
01:17:59 which is more readily available,
01:18:01 and another enzyme, fructose 1,6-diphosphate aldolase.
01:18:06 Again, dihydroxyacetone phosphate is annealed to it.
01:18:11 This is called enantiocomplementary asymmetric synthesis.
01:18:15 If you are clever enough to find the right enzymes,
01:18:18 this is what you can accomplish.
01:18:21 I should add that the diols that were used
01:18:25 were glyceraldehyde was obtained
01:18:28 from a compound we had in our lab made by A.D.
01:18:31 The diol setonide shown was,
01:18:36 we had 100 grams or so,
01:18:38 and Professor Wang's student used this
01:18:42 to make L-glyceraldehyde.
01:18:44 D-glyceraldehyde also made from the other diol we had,
01:18:47 but it's more readily available.
01:18:50 This could be a nice example
01:18:52 of where abiological and biological
01:18:56 asymmetric synthesis could come together.
01:19:00 The simple diol starting material that we've made
01:19:04 and that Wang's group has used to make the fructoses
01:19:09 is an example of the simple type of asymmetric transformation
01:19:14 which abiological catalysts do well.
01:19:17 We come to the enzymic step,
01:19:19 and we see a tremendous challenge here
01:19:21 because we have the free hydroxyls,
01:19:24 which are a real nightmare in organic catalysis,
01:19:29 and we have the problem of water solubility,
01:19:32 and it's a fairly large reading domain
01:19:34 for the selectivity involved.
01:19:36 This is where I see an enzyme as ideal
01:19:39 and almost impossible to imagine dealing with such a problem
01:19:43 unless you have in your kit bag a collection of enzymes.
01:19:47 So this then is the type of message I leave at the conclusion
01:19:54 that biological catalysis is basically
01:20:00 complementary to the abiological,
01:20:03 and both areas are growing at a rapid rate.
01:20:06 I show for your amusement a New Yorker cartoon,
01:20:10 which is self-explanatory.
01:20:13 My point is that we have been so enamored of enzymic catalysis
01:20:18 and its great fidelity and reliability
01:20:22 that I think we have used it too much as a paradigm
01:20:26 of what we can expect when we make non-enzymic catalysts,
01:20:30 and there are some nice features of non-enzymic catalysts
01:20:34 that weren't taught to us by the enzymes.
01:20:39 This is the example of you might find a nice,
01:20:44 exciting target to work with and bring back to biological uses
01:20:49 by looking over your shoulder.
01:20:52 Thank you, Barry and Barry, as we say.
01:20:55 We are ready now to start taking your telephone calls.
01:20:58 This is your part of the show.
01:21:00 At this time, you should see the telephone numbers
01:21:02 displayed on the screen.
01:21:04 The numbers are 800-368-5781 and 5782
01:21:08 and 202-463-3170.
01:21:12 Now when you call, an operator will answer
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01:21:18 You'll be put on hold and will hear the program audio
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01:21:21 Now I will call on you by the name of your location,
01:21:23 so when you hear Can Kiki, that's you, okay?
01:21:26 When you hear your location called,
01:21:27 talk right into your telephone handset
01:21:29 and tell us your name, who your question is for,
01:21:32 if you want to direct it to a specific person,
01:21:34 and, of course, your question.
01:21:36 We have several telephone lines available,
01:21:37 but if you should get a busy signal,
01:21:39 by all means, please hang up and try again.
01:21:44 The phone number again is 368-5781 or 5782.
01:21:50 That's an 800 number, okay?
01:21:52 And you can call them and call right now.
01:21:54 Don't be bashful.
01:21:55 This is your part of the program.
01:21:56 You've heard two very fine presentations,
01:21:58 but because this is the kind of technology it is,
01:22:01 there must be a million questions out there,
01:22:02 so let's get to it and ask our panelists here
01:22:05 something about those things.
01:22:07 We'd like to start off by asking Barry Troster, first of all,
01:22:09 are these reactions involving homogeneous catalysts
01:22:12 really practical or of just academic interest here?
01:22:16 I believe that these have a great practicality.
01:22:19 As I tried to illustrate in some of the examples
01:22:21 that I chose, that these were processes
01:22:25 that have been developed quite far along
01:22:28 in terms of applying some of them
01:22:30 for industrial commodity chemicals.
01:22:33 And certainly in the area of specialty chemicals,
01:22:35 people are finding that they can indeed do these
01:22:38 on realistic scales.
01:22:40 Although academic laboratories don't pay attention
01:22:42 to what is really necessary to make them practical,
01:22:45 in many instances, what looks like at first glance
01:22:49 to be an academic reaction can, in fact,
01:22:53 be turned into a very practical industrial process.
01:22:56 All right.
01:22:57 Once again, those telephone numbers,
01:22:58 800-368-5781 or 5782,
01:23:01 or if you're in the metropolitan Washington, D.C. area,
01:23:04 where we are right now, 202-463-3170.
01:23:08 Now, many times, different complexes of different metals
01:23:10 perform seemingly the same reaction, Barry.
01:23:13 How does one choose the right metal
01:23:15 for any specific application?
01:23:17 Oh, that's a harder one to give you a simple answer to.
01:23:20 When you talk about various reactions,
01:23:22 it's going to take in part some intuition
01:23:25 and obviously a good knowledge of the literature
01:23:28 in trying to decide whether, for example,
01:23:30 a nickel or a palladium catalyst or an iron catalyst
01:23:32 may be the best one for a particular cross-coupling reaction.
01:23:36 You're going to have to do a lot of experimentation.
01:23:39 Unfortunately, unlike many mainstream reactions
01:23:42 where you have a single recipe in catalytic reactions,
01:23:45 you're going to have to expend the effort
01:23:48 to find what is the proper metal
01:23:50 and, in many instances, further fine-tuning
01:23:52 in terms of the kind of ligands that you might employ.
01:23:55 All right.
01:23:56 Barry Sharpless, what precautions are necessary
01:23:58 to work with osmium tetroxide?
01:24:00 Isn't that very toxic?
01:24:02 Well, everybody thinks osmium tetroxide is very toxic
01:24:06 because the story goes that if it gets in your eyes,
01:24:09 you will be blinded,
01:24:11 and that apparently is a bit of an old wives' tale
01:24:14 because if you get the dark osmate ester on your cornea,
01:24:20 it will be sloughed off in a few days,
01:24:22 so it's not an irreversible thing,
01:24:24 and apparently there's no evidence for chronic toxicity for osmium
01:24:29 anywhere in the literature,
01:24:31 so that surprised even me.
01:24:33 I would tell you, too,
01:24:35 that the actual injection of osmium tetroxide into joints
01:24:41 is practiced in Europe
01:24:43 for treatment of a severe rheumatoid arthritic knee.
01:24:47 One gram of osmium tetroxide is injected into each joint
01:24:50 in aqueous solutions,
01:24:52 so one has to wonder how toxic this material really is.
01:24:56 This does raise a question.
01:24:57 Yes?
01:24:58 One of the differences,
01:24:59 raising several questions,
01:25:00 but one of the differences between the biological
01:25:02 and the nonbiological forms of catalysis in principle
01:25:06 is this issue of environmental friendliness.
01:25:09 In the biological systems, the catalysts,
01:25:11 you can eat them if you want to.
01:25:13 Now, do you all have a sense for the downstream costs
01:25:16 of working with reactions that involve palladium and osmium,
01:25:19 and how does that work out in a real systems analysis?
01:25:23 I can answer in the case of palladium
01:25:25 that from a downstream analysis,
01:25:27 it does appear that the recovery of the palladium
01:25:30 is sufficiently good that, in fact,
01:25:32 you're not simply liberating it into the environment,
01:25:35 but you, in fact, are recovering it and recycling it.
01:25:38 So it is a fully recoverable thing.
01:25:40 In terms of toxicity,
01:25:42 the true toxicity of palladium hasn't really been established,
01:25:45 and the issue associated with what is going to be allowed
01:25:49 in terms of, for example, making a pharmaceutical,
01:25:51 what is going to be the residue that would be permitted
01:25:54 is something that is yet to be fully defined
01:25:58 and clearly is going to be an issue
01:26:01 that must be defined more precisely
01:26:03 when you're trying to employ these things.
01:26:05 At the moment, it's in the parts-per-million range,
01:26:07 and it's very easy to, in fact,
01:26:09 bring you down to the parts-per-million range.
01:26:11 All right. We have our first call.
01:26:13 Yes, go ahead.
01:26:15 This is the osmium question.
01:26:17 Upjohn practices this to make the last step
01:26:19 or the next to the last step in a steroid synthesis,
01:26:22 and it's an osmolation.
01:26:24 They've done it catalytically for about 20 years,
01:26:26 and the content of osmium in the product,
01:26:30 presumably, is not detectable
01:26:32 because heavy metals aren't allowed in,
01:26:34 and I think at parts-per-billion, they can do it.
01:26:36 And what's done with the waste osmium?
01:26:38 They recover it, in their case,
01:26:40 up to 97% of their osmium is recovered,
01:26:43 and they've worked over the years to get better
01:26:45 because the price of osmium has gone up.
01:26:48 Okay. Is that acceptable, 97%?
01:26:50 I'm happy.
01:26:51 Okay.
01:26:52 We go to our first call to Bethlehem, Pennsylvania,
01:26:54 and Lehigh University.
01:26:55 Go ahead, caller.
01:26:57 Yes, I'd like to know,
01:26:58 does the ASD tolerate substrates containing nitrogen,
01:27:01 such as vinyl pyridines, for example?
01:27:05 That's a good question.
01:27:07 We tried vinyl pyridine itself, 2-vinyl pyridine,
01:27:10 and if we use the asymmetric dihydroxylation mix
01:27:14 that's very highly, well, has a lot of osmium in it,
01:27:19 0.1% instead of the 0.2 that I discussed in the talk,
01:27:24 then you can do even vinyl pyridine.
01:27:27 It tends to chelate to the osmium catalyst
01:27:29 and kill the catalysis.
01:27:31 But nitrogen, there are a lot of basic nitrogens
01:27:34 that we've been able to have in the molecule
01:27:37 as long as they are not easily oxidized
01:27:42 or good chelators
01:27:44 because they would also cause acceleration
01:27:46 and they would give racemic material.
01:27:48 But it can work with sulfur.
01:27:50 That's an interesting thing we just found.
01:27:52 Allylic sulfides are very happy to be hydroxylated
01:27:56 with no oxidation of the sulfur.
01:27:59 I think that's about as much as I can say right now.
01:28:02 Okay.
01:28:03 Our next call is from South Texas local section
01:28:05 in Corpus Christi.
01:28:06 Go ahead, Texas.
01:28:08 My name is Sam Kota.
01:28:10 I would like to ask a question to Barry Sharpless.
01:28:15 This is about can we use a solvent
01:28:18 other than dichloromethane in Sharpless epoxidation?
01:28:23 You can, but it's the best rate,
01:28:26 and that's one that George Whiteside's raised.
01:28:29 I mean, we're being taken,
01:28:31 our solvents are being taken away from us one at a time,
01:28:34 and methylene chloride is one that I find it hard to live without.
01:28:37 Obviously, best to do everything in water,
01:28:39 but we can't do the AD in water.
01:28:41 I mean, the AE, that's obvious.
01:28:43 We can use things like ethyl acetate we've used.
01:28:46 Benzene is fine.
01:28:47 That's not fine anymore.
01:28:48 Toluene is fine.
01:28:50 You can, but you take a rate loss.
01:28:53 You can't go to hydrocarbon solvents,
01:28:54 and you can't go to ether solvents
01:28:56 like ether or tetrahydrofuran.
01:28:59 That plays havoc with the catalyst.
01:29:03 But there are solvents other than methylene chloride.
01:29:05 Chloroform, of course, that also isn't really a happy solvent.
01:29:08 There is a problem with that reaction.
01:29:10 It does like methylene chloride best.
01:29:12 Okay, any other comments here?
01:29:14 Any further comment from Texas?
01:29:17 I have another question.
01:29:19 I know it is a substrate epoxidation is used in industry.
01:29:22 What is the largest scale that it was done in ARCO
01:29:25 or some other industry?
01:29:27 ARCO is doing it now on glycitol at a pretty large scale.
01:29:31 I don't really know what that is, actually,
01:29:34 but Upjohn and Eli Lilly have run it on, I think,
01:29:38 50 kilograms of allylic alcohol per run.
01:29:42 Maybe 100 kilograms of alcohol
01:29:44 is what ARCO has in their reactor right now.
01:29:47 That's just a guess, though.
01:29:49 It's not in the huge category.
01:29:52 Okay, we have many sites around the country.
01:29:54 We've heard from two now.
01:29:55 We have a long way to go here.
01:29:56 We have two question-and-answer periods,
01:29:58 about 20 minutes left in this one,
01:29:59 another 25-minute period a little later on.
01:30:02 This is the time when you can have these guys captive
01:30:05 in your own television set to answer your questions,
01:30:08 free of charge, as a matter of fact.
01:30:10 800-368-5781 or 5782 in the Washington, D.C. area,
01:30:15 202-463-3170.
01:30:17 Barry Trost, a quite noticeable aspect
01:30:20 of transition metal chemistry
01:30:21 is the myriad of ligands that are used.
01:30:23 Is there a universal ligand?
01:30:26 This is commonly a question that I am asked
01:30:29 when I am giving a lecture as to
01:30:31 why did I use a particular ligand
01:30:32 for a particular reaction?
01:30:34 And the answer is many-fold.
01:30:37 Sometimes it is a rational design
01:30:39 in trying to change some of the electronic properties
01:30:42 of a ligand.
01:30:43 In many instances, you are also, however,
01:30:46 relying on trial-and-error.
01:30:48 So it's going to be a combination of,
01:30:50 say, a directed trial-and-error process
01:30:52 in trying to define the right steric
01:30:55 and electronic properties
01:30:56 in order to tune the selectivity that you require.
01:30:59 All right.
01:31:00 We go now to Piscataway.
01:31:02 Sinatra must have gone through Piscataway
01:31:04 on his way from Holmboken,
01:31:05 as you saw last night on television.
01:31:07 Rutgers University.
01:31:08 Hello.
01:31:09 We have a question for Professor Sharpless.
01:31:12 We would like you to explain again on your slide
01:31:15 Ks-9, the mechanism of the slide.
01:31:19 Ks-9?
01:31:21 Is that the asymmetric epoxidation?
01:31:23 Or...
01:31:25 I don't have a copy of the slides.
01:31:29 Yes.
01:31:30 She said yes.
01:31:31 Okay.
01:31:32 The mechanism of the asymmetric epoxidation
01:31:35 is still not rigorously known,
01:31:39 just as no mechanism is ever known with certainty.
01:31:43 In this case, it's a little trickier
01:31:44 because the catalyst is fluxional,
01:31:47 and we see that's one of the catalysts
01:31:49 in the reaction mixture.
01:31:51 We know it's there for various spectroscopy ways,
01:31:54 but there are also other catalysts in there
01:31:56 with only one tartrate and two titaniums
01:31:59 and some with three tartrates and two titaniums
01:32:02 and various things, maybe a hundred other catalysts.
01:32:05 So if you're asking about how well we know the mechanism,
01:32:10 maybe you're asking about how we know
01:32:13 we predict the selectivity, the enantioselectivity.
01:32:16 Is that more the question that you're asking?
01:32:21 She's off the line, Barry,
01:32:22 so we'll just have to speculate and move on.
01:32:24 Okay, well, then the thing is,
01:32:25 the way I explain this is the tartrate
01:32:28 if I'm the titanium center,
01:32:30 then the tartrate blocks quadrants
01:32:33 that are like this in the back.
01:32:35 I like that.
01:32:36 And if you can visualize this,
01:32:38 there's an ester group here and here blocking.
01:32:41 The allylic alcohol binds to my front
01:32:43 and comes out in an arm like this,
01:32:46 and it looks for the oxygen atom,
01:32:48 which is down around my waist,
01:32:49 bound to my waist,
01:32:50 getting activated from the peroxide,
01:32:52 and it attacks it like this,
01:32:54 and that's a forehand.
01:32:56 It's like a forehand antennas,
01:32:57 and it likes that forehand,
01:32:59 but it doesn't like the backhand.
01:33:01 It looks more difficult here, too,
01:33:03 but it is,
01:33:05 because the centering isn't good
01:33:06 on the shot on the O-O bond.
01:33:08 So it's a forehand system.
01:33:10 Now, that doesn't solve the problem.
01:33:12 Also, it shows you I can have anything on this.
01:33:14 All it's looking at is the chirality of my arm.
01:33:16 But if we go to the other catalyst,
01:33:18 see, the other catalyst has the blocking here,
01:33:20 and now the aloxyl group has to load this way,
01:33:23 and it does this forehand and not the backhand.
01:33:25 So that's how you get the enantioselectivity
01:33:27 in the AE process,
01:33:29 in a very simplified description.
01:33:32 Do you lead an aerobics class?
01:33:34 I don't know.
01:33:36 Very good.
01:33:38 But very pictorial and very good.
01:33:41 Okay, any other comments?
01:33:42 We have another comment follow-up.
01:33:44 Barry, there have been some discussions
01:33:46 between you and my colleague,
01:33:47 Professor Corey,
01:33:48 on the subject of the mechanism.
01:33:49 Would you like to comment
01:33:50 on that interesting subject?
01:33:51 Well, yes.
01:33:52 I guess a number of people
01:33:54 have found fault with our mechanism
01:33:57 over the years,
01:33:59 and as far as we can tell,
01:34:01 ours best fits the data and the kinetics.
01:34:04 And Professor Corey had an ingenious
01:34:07 alternative mechanism,
01:34:09 but unfortunately,
01:34:10 it doesn't fit the kinetics,
01:34:12 and that's a starting point
01:34:13 for most mechanistic discussion.
01:34:15 And if Professor Corey were here,
01:34:17 he might have...
01:34:18 He might have a different opinion.
01:34:19 A different opinion.
01:34:20 That's right, exactly.
01:34:21 Okay, so I will leave that go.
01:34:23 We'll move down to St. Louis, Missouri,
01:34:25 and the University of Missouri
01:34:26 for our next question.
01:34:27 Yeah, my question goes to Dr. Barry Charles.
01:34:30 And for the atom efficiency,
01:34:33 why we need it
01:34:34 if all the starting material are cheap?
01:34:36 Well, you need it for a lot of other reasons
01:34:38 besides the cost of the starting material.
01:34:40 You need it in terms of,
01:34:42 not the least of which,
01:34:43 what you're going to have to get rid of
01:34:45 when you're finishing your chemical processing.
01:34:47 There's not going to be any issue
01:34:49 of a waste disposal
01:34:51 that's going to be less costly.
01:34:54 Just from our own experiences recently,
01:34:57 the cost of disposing of solvents
01:35:00 is more than the cost of buying them.
01:35:02 And I think you're going to find
01:35:03 that how you're going to get rid of
01:35:05 any byproducts of a reaction
01:35:07 is not going to be a trivial issue.
01:35:09 So that this concept
01:35:11 that one needs to develop
01:35:13 simple addition reactions
01:35:15 is going to grow in importance
01:35:16 rather than decrease.
01:35:19 All right.
01:35:20 We go next to my hometown
01:35:21 of Rochester, New York
01:35:22 in Eastman Kodak.
01:35:23 Go ahead, please.
01:35:25 Yes, I'd just like
01:35:27 I'd just like to comment to Dr. Trost
01:35:30 if he considers himself
01:35:32 to be an organic chemist.
01:35:37 I don't know what you are referring to
01:35:41 by pronunciation perhaps in some words.
01:35:44 What does that mean, sir?
01:35:45 Chemotherapy is used
01:35:47 when I would consider it chemotherapy.
01:35:52 Sorry to be a nitpicker.
01:35:54 My main question was to
01:35:57 My main question is to
01:36:00 Professor Sharpless.
01:36:02 I'm getting a little bit of a delay here
01:36:04 so it's confusing my
01:36:05 You have to turn your monitor down.
01:36:07 We can't.
01:36:08 The rest of the people won't hear it then.
01:36:09 So I'll turn away from it and plug my ear.
01:36:12 You mentioned a couple of real buzzwords.
01:36:15 You mentioned liver, squalene, hydroxylation.
01:36:19 And I'm wondering how much
01:36:21 and maybe it just comes out I'm out of date
01:36:23 is known about the synthesis
01:36:25 of cholesterol in the liver.
01:36:27 And clearly pharmaceutical companies
01:36:29 are really busting their chops
01:36:31 to find ways to interrupt this synthesis.
01:36:34 And does any of your work
01:36:36 being addressed today
01:36:38 speak to this question?
01:36:42 Yes.
01:36:43 They're trying to block the
01:36:45 sterol biosynthesis pathway,
01:36:47 the endogenous one,
01:36:49 for the obvious reasons
01:36:50 to cut down cholesterol
01:36:52 in people who have too much.
01:36:54 And they're trying to inhibit the
01:36:57 One of the key enzymes that's a target
01:36:59 is the one that couples
01:37:01 two farnesols to make squalene.
01:37:03 And I guess the epoxidation reaction
01:37:05 is also a target.
01:37:08 I'm not really that familiar with that area
01:37:10 although Shikey Schechter and Tom Spencer
01:37:13 people I do know are working in that area.
01:37:16 I'm sure a lot of others are too
01:37:18 in the pharmaceutical companies.
01:37:20 I'm not an expert.
01:37:21 And I did my Ph.D. thesis
01:37:22 on sterol biosynthesis.
01:37:24 That's why I often choose
01:37:26 sterile terpenes for demonstration purposes
01:37:29 in oxidation catalysis.
01:37:32 All right.
01:37:33 Our next call is from Midland, Michigan
01:37:35 and Dow Chemical.
01:37:36 Go ahead, please.
01:37:38 Hello.
01:37:39 My question is for Barry Sharpless.
01:37:41 Or rather, I'm sorry,
01:37:42 is for Barry Trost.
01:37:44 Too many Barrys.
01:37:47 It's on the question in general
01:37:48 of palladium and platinum chemistry.
01:37:50 Normally, the mechanisms all start
01:37:53 with a palladium zero species.
01:37:55 But in my experience,
01:37:56 the reagents that I typically use
01:37:58 are palladium two or palladium four.
01:38:01 And I just would like to know
01:38:02 if there's any mechanism,
01:38:04 a theory by which the palladium two
01:38:07 or palladium four goes to palladium zero
01:38:09 or if we just invoke, say,
01:38:11 the adventitious presence of palladium zero
01:38:14 to do the reactions.
01:38:16 No.
01:38:17 Yes, in fact, there are many mechanisms
01:38:18 by which the oxidation state of palladium
01:38:20 is being changed under the conditions
01:38:22 of the reaction that it is very common
01:38:24 that you're putting in palladium two.
01:38:26 But in fact, the active species
01:38:28 is palladium zero where the palladium zero
01:38:30 has been generated specifically
01:38:33 by a reduction typically
01:38:35 by one of the reactants
01:38:36 or some other exogenous reagent
01:38:38 that is being added.
01:38:39 For example, if you add triethylamine
01:38:41 as a base and carry out some reactions,
01:38:44 that is also reductant
01:38:45 as far as palladium two is concerned,
01:38:47 giving you palladium zero.
01:38:49 Your choice of palladium salt also matters,
01:38:51 palladium chloride versus palladium acetate
01:38:53 because you find that the reduction potential
01:38:55 of these are dependent on the counter ion.
01:38:57 So yes, in fact, it is very important
01:38:59 to choose the right palladium species at times
01:39:01 to get you into an active catalyst.
01:39:04 All right, comments.
01:39:05 We move on to Canton, New York
01:39:07 and Clarkson, St. Lawrence University.
01:39:09 Go ahead, please.
01:39:10 Thank you.
01:39:11 My question is for Professor Trost.
01:39:13 One can't help but be impressed
01:39:15 with regards to the number of phosphine ligands
01:39:18 that are used in the various syntheses.
01:39:21 And I wonder if there's an a priori type of method
01:39:25 by which one chooses triphenylphosphine
01:39:28 or the bis-triphenylphosphine-propyl
01:39:30 or butyl types of compounds as the ligands.
01:39:34 What rationale does one use
01:39:36 to choose a ligand of this type?
01:39:39 There is some rationale
01:39:40 depending on the particular application.
01:39:42 For example, if you're going to go
01:39:44 from triphenylphosphine to a bidentate ligand,
01:39:48 there can be two reasons
01:39:49 why you might choose to go in that direction.
01:39:51 First has to deal with steric effects.
01:39:53 And here you can measure it by, for example,
01:39:55 the cone angles.
01:39:56 The cone angles is a way to estimate
01:39:58 the steric bulk of a ligand.
01:40:00 And what you find is that, obviously,
01:40:02 for certain reactions,
01:40:03 you might want sterically less demanding ligands.
01:40:06 And frequently going from a monodentate
01:40:08 to a bidentate ligand
01:40:09 provides you the opportunity of doing that.
01:40:11 Of course, this also will affect geometry
01:40:14 around the metal.
01:40:16 By having a bidentate ligand,
01:40:17 those two ligands are forced to be cis,
01:40:19 and meaning that it's going to open up
01:40:21 coordination sites that will also be cis.
01:40:23 You also have some choice
01:40:24 in terms of electronic nature
01:40:26 going from a phosphine ligand, for example.
01:40:29 Or let's stay within phosphines
01:40:30 from an alkyl to an aryl phosphine.
01:40:33 Alkyl phosphines are more donor ligands.
01:40:35 They're more electron-rich
01:40:37 in making the palladium,
01:40:38 then less electrophilic.
01:40:40 And aryl phosphines are the opposite.
01:40:42 And you can, of course,
01:40:43 begin to fine-tune that even further
01:40:45 by going, for example,
01:40:46 from phosphines to phosphites.
01:40:49 So there is this issue
01:40:51 of trying to tune the steric
01:40:54 and electronic properties
01:40:56 in terms of the particular reaction
01:40:58 that you are trying to affect.
01:41:01 Okay, does that answer your question,
01:41:02 St. Lawrence University?
01:41:03 Do you have a follow-up or anything?
01:41:04 Thank you. That's all. Thank you.
01:41:05 Okay, good enough.
01:41:07 And we're moving on.
01:41:08 I think we're going back to
01:41:10 Piscataway, New Jersey, again.
01:41:12 And Rutgers, go ahead, please.
01:41:14 This is for Barry Sharpless.
01:41:16 For the asymmetric hydroxylation,
01:41:19 is it necessary that the olefin
01:41:21 be soluble in the
01:41:23 t-butanol water solution?
01:41:25 And if so, what can be done
01:41:27 if the olefin is not soluble?
01:41:29 Can you suggest a solvent or reagent?
01:41:31 It's a problem that's important
01:41:33 because the t-butanol water system,
01:41:36 well, it's really,
01:41:37 t-butanol water are miscible one-to-one,
01:41:39 but the salt splits out the top phase,
01:41:41 which has mostly t-butanol,
01:41:42 but also water.
01:41:44 And we've found this problem ourselves,
01:41:46 and we use toluene.
01:41:48 Toluene can be used alone,
01:41:49 but the turnover rates go down,
01:41:51 or toluene mixed into the t-butanol.
01:41:54 We also use t-butyl methyl ether,
01:41:57 and that works.
01:42:00 That's a pretty nice solvent.
01:42:02 Like t-butanol,
01:42:04 it's an environmentally friendly solvent,
01:42:06 and it's very common these days
01:42:07 as a gasoline additive,
01:42:08 so it's cheap.
01:42:10 And we like that solvent
01:42:12 for perhaps large-scale work.
01:42:15 A company is trying to scale this up
01:42:17 electrochemically,
01:42:18 and they're using that solvent
01:42:19 as one of the prime candidates.
01:42:22 So it isn't,
01:42:23 you can go to other solvents.
01:42:25 This reaction is not that,
01:42:26 you shouldn't go to methanol or ethanol.
01:42:29 Somehow that, of course, won't phase separate.
01:42:31 You need something to get a phase separation
01:42:33 because you want to keep the oxidant
01:42:35 in the aqueous phase.
01:42:36 Otherwise, you can tinker with the solvents
01:42:38 to your heart's content, I think.
01:42:40 All right.
01:42:41 Barry Trost,
01:42:42 can new reactions involving homogeneous catalysts
01:42:45 be naturally invented,
01:42:46 or are they always kind of a serendipitous discovery?
01:42:49 Well, one can, I believe,
01:42:51 make some attempts
01:42:52 at rationally trying to design new reactions.
01:42:55 And this obviously comes from
01:42:57 trying to understand mechanistically
01:43:00 what might one expect
01:43:03 if you take a particular type of a metal
01:43:05 in a certain environment
01:43:06 and hopefully be able to translate that
01:43:09 into a sequence of events
01:43:12 that will give you a different chemical change
01:43:14 than you otherwise might have had.
01:43:16 So I do believe that we are reaching the stage
01:43:18 where you can hopefully rationally invent reactions
01:43:22 and not just discover them serendipitously.
01:43:25 There's no question that serendipity
01:43:27 will continue to play a very major role in discovery,
01:43:30 and the rationally invented procedures
01:43:34 may, in fact, give you the key,
01:43:37 or maybe the entry into
01:43:39 some of the serendipitous discoveries
01:43:41 that you will hopefully make.
01:43:42 Okay.
01:43:43 Before we close out this portion of the Q&A,
01:43:46 any observations here?
01:43:47 We are not eliminating your questions
01:43:50 from the next question-and-answer period.
01:43:52 So you out there,
01:43:53 if another question occurs to you,
01:43:54 even in the light of the other two gentlemen
01:43:56 on my left's presentations
01:43:58 in the not-too-distant future,
01:43:59 by all means, they're available here
01:44:01 to answer your questions.
01:44:02 Any other observations
01:44:03 before we ring down the curtain?
01:44:05 Okay, good.
01:44:06 Then we have to conclude the discussion for now.
01:44:09 We'll have one more question-and-answer segment
01:44:11 at the end of the program,
01:44:12 so please hold your questions until then.
01:44:14 Today's program is just one of the many
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01:44:31 It's time now for a stretch break.
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01:45:45 introduces the four-step philosophy
01:45:47 of chemical safety.
01:45:51 Safe Laboratory Procedures,
01:45:53 the third tape in the series,
01:45:55 covers safe techniques for such things
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01:47:12 Music
01:53:03 Welcome back again.
01:53:05 In this portion of the program, the speakers Peter Schultz and George Whitesides
01:53:09 focus on biological catalysis and organic synthesis.
01:53:13 The final Q&A period will immediately follow Dr. Whitesides' presentation.
01:53:17 So hang in there.
01:53:19 Our third speaker today is Dr. Peter G. Schultz.
01:53:23 He is professor of chemistry at the University of California at Berkeley.
01:53:29 His research interests include molecular recognition and catalysis and biological systems,
01:53:35 as well as catalytic antibodies.
01:53:37 Dr. Schultz's topic is catalytic antibodies.
01:53:42 What I'd like to do today is overview catalytic antibodies,
01:53:45 a relative newcomer to the field of selective chemical catalysis.
01:53:49 I'd like to ask a number of questions.
01:53:51 First of all, why are we interested in catalytic antibodies?
01:53:54 Second of all, what progress has been made over the last six or so years in the area of catalytic antibodies
01:54:00 with respect to generating catalytic antibodies,
01:54:03 the types of reactions that can be catalyzed by catalytic antibodies,
01:54:07 what we've learned from generating and characterizing these catalytic antibodies.
01:54:11 Then I'd finally like to give you an idea of where I think the future lies
01:54:15 over the next three to five years in this field.
01:54:18 So let's start out by asking why are we interested in catalytic antibodies.
01:54:23 Well, there are two reasons.
01:54:24 The first is a practical reason, and that's to ask the question
01:54:27 whether we can in fact tailor-make enzyme-like catalysts of virtually any given specificity
01:54:33 for reactions of interest in biology, chemistry, and medicine.
01:54:37 Second of all, and a little more theoretical,
01:54:41 is to ask if we generate and characterize these antibodies,
01:54:44 what can they teach us about fundamental notions of biological catalysis?
01:54:49 What are the roles of transition state stabilization, entropy,
01:54:53 general acid, general base, and covalent catalysis in enzymatic reactions?
01:54:58 Well, as you all know, enzymes, which are the catalyst that nature has evolved
01:55:06 over hundreds of millions of years, very sophisticated catalysts,
01:55:09 have two dominant features.
01:55:11 First of all, they accelerate the rate of a reaction many times over the background rate.
01:55:17 Second of all, and perhaps more germane to the present topic,
01:55:22 is the fact that they're exquisitely specific.
01:55:25 For example, the specificity of the restriction enzymes,
01:55:28 that is the ability of restriction enzymes to cleave a large DNA molecule at a single site,
01:55:34 make possible all of modern molecular biology.
01:55:37 And that's something to say for one given class of catalysts
01:55:40 that they make possible a whole field of science.
01:55:44 Also, these enzymes have been used in therapeutic applications.
01:55:48 For example, the ability of TPA to selectively activate blood clot dissolution
01:55:54 is important in the medicinal chemistry field.
01:55:58 Finally, there are enzymes that are being used in commercial processes,
01:56:02 such as penicillin acylase for the production of semisynthetic penicillin,
01:56:07 and glucose isomerase in a commercial process as well.
01:56:12 Well, why, if enzymes are so great, do we want to create new enzymes?
01:56:16 Well, nature generated enzymes for reactions nature was interested in catalyzing,
01:56:21 and there are many reactions we're interested in catalyzing for which no known enzyme exists.
01:56:27 For example, can we generate enzymes that, like the restriction enzymes which cleave DNA,
01:56:33 allow us to cleave two other major classes of biopolymers, proteins, and oligosaccharides?
01:56:39 Can we generate catalysts that allow us to selectively cleave viral coat proteins?
01:56:44 Those might have important therapeutic applications as antiviral agents.
01:56:48 Can we generate, rather than a penicillin acylase, a cephalosporin acylase?
01:56:53 Or can we generate enzymes that allow us to detoxify environmental man-made pollutants?
01:57:00 Well, if we want to generate enzymes for any of these reactions, where do we start?
01:57:05 Well, we have to overcome two problems.
01:57:07 First of all, we have to figure out how we're going to reduce the free energy of activation of a reaction.
01:57:13 Okay, lower delta G double dagger.
01:57:15 This is a chemical problem. It involves breaking and making covalent bonds,
01:57:19 something chemists have studied for a long time.
01:57:21 And, in fact, for simple reactions, we can even calculate the structures of transition states.
01:57:26 So we can use chemistry to solve this problem.
01:57:28 The other problem, perhaps the harder problem, is a problem of selectivity.
01:57:32 How do we generate a receptor, a catalyst, with the specificity of an enzyme?
01:57:36 That's because binding interactions, the binding of a ligand to a receptor,
01:57:40 involves many small interactions on the order of half a kcal to 4 kcal.
01:57:45 And it's the additive effect of these interactions that gives us the specificity and affinity.
01:57:50 Now, we can't very much predict or understand these effects,
01:57:53 more or less generate a receptor with a specificity that's characteristic of enzyme.
01:57:59 So how do we solve this problem?
01:58:01 Well, in fact, if we turn to nature, nature has solved this problem in a spectacular way
01:58:06 in the form of the humoral immune system.
01:58:08 When a foreign substance invades an organism, an organism is able to produce antibody molecules,
01:58:15 which are proteins of about 150,000 molecular weight,
01:58:19 that bind that foreign molecule, virtually any foreign molecule,
01:58:23 with exquisite specificity and high affinity, up to 10 to the 14th per molar binding affinity.
01:58:29 In fact, shown on this slide is the antibody combining site binding a large protein.
01:58:33 The protein is shown in white.
01:58:35 In fact, this protein is about 20,000 molecular weight.
01:58:39 So you can see that antibodies can use large binding surfaces to bind a ligand,
01:58:44 800 square angstrom,
01:58:46 but antibodies can also bind small molecules on the order of 100 molecular weight.
01:58:51 So there's a huge diversity in the immune response.
01:58:55 Moreover, the structure of an antibody combining site is extremely complementary to the ligand it's binding.
01:59:02 For instance, there's not one water molecule between the two surfaces shown on this slide,
01:59:07 the surface of the enzyme and the surface of the antibody.
01:59:11 And in fact, over the last few years, our group and the groups of Lerner and others
01:59:16 have developed a number of rules for generating catalytic antibodies.
01:59:20 These include the notion of transition state stabilization.
01:59:24 Using antibody binding affinity and specificity to selectively stabilize transition states or strain substrates.
01:59:31 Catalysis by approximation.
01:59:34 Using antibodies to overcome the entropy barrier to reaction.
01:59:37 General acid, general base catalysis and covalent catalysis.
01:59:41 What I'd like to do today then is I'd like to overview each of these strategies
01:59:46 to in a sense teach you how to make a catalytic antibody
01:59:49 and illustrate each of these strategies with a number of different reactions
01:59:53 to give you an idea of scope of antibody catalysis.
01:59:57 Finally, I'd like to overview or in fact point out
02:00:01 what the generation and characterization of catalytic antibodies
02:00:05 has taught us about each of these notions.