Biological and Abiological Catalysis in Organic Synthesis (Tape 2)
- 1992
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Transcript
00:00:00 Well, where did we start?
00:00:08 Well, our group and the group of Richard Lerner started in 1986 by looking at the notion whether
00:00:13 antibodies could selectively stabilize a transition state.
00:00:17 So let's consider a simple reaction, a hydrolysis of an ester to the corresponding acid.
00:00:24 This reaction proceeds through a rate-limiting transition state, which is a tetrahedral negatively
00:00:28 charged species.
00:00:30 So if you're a chemist, you've learned back in sophomore organic chemistry that the solvent
00:00:35 one should run this reaction in is a polar solvent, because the transition state is a
00:00:40 charged compound, the substrate is a neutral compound.
00:00:44 If one runs this in a polar solvent, one selectively stabilizes the transition state relative to
00:00:50 the ground state.
00:00:51 Well, I'd like to make the argument, in fact, that the immune system is capable of producing
00:00:55 an ideal solvent for the transition state, because after all, the antibody-combining
00:01:00 site can be viewed as a heterogeneous microsolvent that's exactly complementary to the transition
00:01:08 state in terms of steric and its electronic properties.
00:01:12 So the prediction, then, is if one generated an antibody to a transition state, one would
00:01:17 have a very effective and selective catalyst.
00:01:20 In fact, this notion was first tested back in 86 by Richard and myself independently
00:01:26 by looking at a series of rather simple reactions, the hydrolysis of activated esters and activated
00:01:32 carbonates.
00:01:33 Let's consider, for example, the hydrolysis of this nitrophenylcholine carbonate.
00:01:38 This reaction, the hydroxide ion-dependent reaction, proceeds from a neutral sp2 substrate
00:01:43 to a tetrahedral negatively charged transition state.
00:01:47 So the theory, then, in theory, if one generated an antibody that's selectively bound to this
00:01:51 transition state, one would get a catalyst.
00:01:53 Well, in fact, you can't do that, because transition states don't lie in a free energy
00:01:57 well and, therefore, one can't immunize with them.
00:02:01 So we decided to use a well-known trick of medicinal chemistry, and that's the notion
00:02:05 of a transition state analog.
00:02:07 If one substitutes the carbon in this tetrahedral negatively charged species with a phosphorous,
00:02:13 one generates a stable analog of the transition states whose steric and electronic properties
00:02:18 mimic those of the unstable transition state.
00:02:22 So if antibodies are generated to transition state analogs, those antibodies should then
00:02:27 act as catalysts.
00:02:29 Now when we generated monoclonal antibodies against these transition state analogs, in
00:02:34 fact, we did get selective chemical catalysts.
00:02:37 And there are a number of properties of these antibodies I'd like to just overview.
00:02:41 First of all, they showed saturation kinetics.
00:02:43 What do I mean by this?
00:02:44 What I mean by this is the reaction's at least a two-step process.
00:02:47 The first step is a binding step of the substrate in the antibody combining site, followed by
00:02:52 an intramolecular reaction in which the substrate bound to the antibody is converted to product
00:02:58 and released.
00:02:59 Well, what's the significance of these kinetics?
00:03:01 Well, the significance is that we can trade antibody binding affinity for a reduction
00:03:06 in the free energy of activation of reaction.
00:03:08 Second of all, these antibodies show high specificity.
00:03:12 I'll give illustrations of those later in the talk.
00:03:15 They accelerate the rate of the reaction ten to the third to a million times over background.
00:03:20 And consistent with the idea that they're selectively stabilizing the transition state,
00:03:24 they bind to transition state analogs more tightly than substrate.
00:03:27 Well, what's going on in these antibody active sites?
00:03:30 Well, in one case, in the case of the antibodies that hydrolyze the nitrophenylcholine esters
00:03:36 and carbonates, we actually have a crystal structure of this catalytic antibody.
00:03:41 The structure was solved by Davies and co-workers at the NIH.
00:03:45 Shown here is the structure of the antibody binding the transition state analog.
00:03:49 The transition state analog is a species in yellow.
00:03:53 The tetrahedral phosphate is bound via electrostatic interaction with arginine 52H of the heavy
00:04:01 chain shown in red.
00:04:02 So you can see this antibody is, in fact, complementary to the transition state and
00:04:07 this complementarity involves an electrostatic interaction.
00:04:11 I should point out that the tyrosine shown here in green is disposable, plays no role
00:04:17 in the enzymatic reaction.
00:04:18 Therefore, we've used modern protein engineering techniques to substitute this tyrosine with
00:04:23 a histidine.
00:04:24 A histidine, we think, acts as a general base to accelerate this antibody catalyzed reaction
00:04:31 and the mutant protein actually is about tenfold more efficient than the parent antibody.
00:04:36 So you can see that we can use modern molecular biological methods to increase the efficiency
00:04:42 of our antibody catalyst.
00:04:45 Well, what's happened since these early studies?
00:04:48 Well, we've gone on, our group and others have gone on, to show that you can actually
00:04:52 use antibodies to catalyze the hydrolysis of unactivated alkyl esters, in fact, the
00:04:58 stereospecific hydrolysis of unactivated alkyl esters.
00:05:02 Why is this interesting?
00:05:03 Well, this is interesting for a number of reasons.
00:05:06 First of all, this reaction allows you to do a chiral resolution of an ester to form
00:05:11 the corresponding alcohol or acid.
00:05:13 This is a reaction that's of interest to process chemists to form pure chiral intermediate.
00:05:18 Now, given the fact that there is no general chemical solution for stereospecific ester
00:05:24 hydrolysis, process chemists today are starting to use lipases in these chemical processes.
00:05:29 Now, in the absence of a lipase, an enzyme that has the appropriate specificity, I'd
00:05:34 like to argue that you could, in fact, generate an antibody that carries out this reaction.
00:05:38 In fact, Kitazumi has shown recently that one can use antibodies to separate a mixture
00:05:44 of four diastereomeric esters, alkyl esters.
00:05:48 He generated four different catalytic antibodies, each specific for each of the four transition
00:05:53 states.
00:05:54 And using these antibodies, he produced each chiral alcohol with a DE of greater than 97%
00:06:02 and almost quantitative yield.
00:06:05 We've recently applied these notions of hydrolyzing alkyl esters to a problem in therapy, okay,
00:06:13 in cancer chemotherapy, to selective prodrug activation.
00:06:17 As many of you know, 5-fluorodeoxyuridine, shown on this slide, is a potent cytotoxic
00:06:23 agent used in the treatment of certain forms of cancer.
00:06:26 Interestingly, if you esterify the 5'-hydroxyl group, you reduce the toxicity of this reagent
00:06:33 significantly.
00:06:34 So the idea, then, is if one could generate a catalytic antibody that selectively converts
00:06:40 the 5'-ester to the 5'-alcohol at a cancer cell, you would selectively dose the
00:06:47 cancer cell relative to all of the other cells in the body, making a much better chemotherapeutic
00:06:53 regime.
00:06:54 Well, in fact, we've generated antibodies that catalyze the hydrolysis of the valial
00:06:59 5'-ester by generating antibodies to the corresponding phosphonate.
00:07:04 These antibodies actually are quite efficient.
00:07:07 Now we're asking the question whether we can, in fact, create a bifunctional antibody
00:07:11 where one end is specific for the tumor cell, one end is catalytic, localize this antibody
00:07:16 at the tumor cell, and generate a high local concentration of 5'-FU.
00:07:21 Now I should point out, an important design aspect of this chemistry is that there's no
00:07:26 known enzyme that'll cleave this D-valial ester.
00:07:30 We are not going to get a nonspecific activation of the prodrugs throughout the body, only
00:07:35 at the site where the antibody's localized.
00:07:38 Well, in fact, notions of transition state stabilization have been used to generate a
00:07:43 number of catalytic antibodies up for other reaction, including amide bond cleavage, selective
00:07:49 phosphoryl transfer reactions of interest in chemistry and biology, as well as in the
00:07:55 selective cleavage of ethers, activated ethers, and enol ethers.
00:08:01 We've shown, in fact, that antibodies to transition states act as catalysts.
00:08:04 What else do antibodies against transition state analogs teach us?
00:08:08 In fact, these antibodies can teach us something about mechanisms of biological catalysis.
00:08:14 Let's consider, for example, the enzyme ferrochelatase, which catalyzes the methylation of the planar
00:08:21 neutral porphyrin shown here to the corresponding metalloporphyrin.
00:08:26 Now this enzyme has been the subject of considerable mechanistic investigation because it's thought
00:08:32 to function via a unique mechanism, a mechanism not involving acidic catalysis or covalent
00:08:38 catalysis, but simply involving distortion of the substrate.
00:08:42 Why is that?
00:08:43 Well, it turns out enalkylporphyrins are incredibly potent inhibitors of this enzyme, binding
00:08:48 significantly more tightly than the planar porphyrin substrate.
00:08:52 And in fact, enalkylporphyrins are bent porphyrins.
00:08:56 They're non-planar porphyrins in which the nitrogen-loam pairs are distorted out of the
00:09:00 planar porphyrin ring.
00:09:03 So based on this, it's been proposed that the mechanism whereby the enzyme operates
00:09:07 is to bind the planar neutral porphyrin, distort it out of planarity, the nitrogen-loam
00:09:13 pairs can now access the metal, it's metallated, it snaps back shut, and we get the metallated
00:09:19 porphyrin.
00:09:20 Well, if that's true and the enzymes function via distortion, if we make antibodies to a
00:09:26 distorted hapten molecule, those antibodies should act like ferrochelatases.
00:09:33 And in fact, when we carry out this experiment, we do generate catalytic antibodies, and
00:09:38 in fact, those catalytic antibodies have kinetic properties and specificities that are very,
00:09:44 very similar to the enzymes that evolved over hundreds of millions of years.
00:09:49 Okay, well, where do we stand?
00:09:52 Well, what we've shown is that we can generate catalytic antibodies by generating antibodies
00:09:57 to transition state analog.
00:09:59 In fact, Pauling, over 40 years ago, proposed that enzymes have evolved through the process
00:10:04 of natural selection to bind transition state.
00:10:07 Well, in fact, we've verified this notion by showing that, in fact, if we carry out
00:10:13 the process of immunological selection against the transition state, we get catalyst.
00:10:18 Okay, what other kinds of strategies can we use for the generation of a catalytic antibody?
00:10:24 Well, another notion that one can apply to this problem is the notion of catalysis by
00:10:28 approximation or proximity effects.
00:10:31 What do I mean by this?
00:10:33 What I mean is to form the activated complex between two reacting groups, one has to overcome
00:10:39 a lot of rotational and translational barriers to form this complex.
00:10:44 The question is, is do enzymes catalyze reactions by using their binding energy to bind these
00:10:50 two reacting groups and hold them in a fixed reactive conformation?
00:10:54 And if that's true, then we ought to be able to use the binding affinity and specificity
00:10:59 of antibodies to do the same thing.
00:11:01 Well, in fact, Jenks and Koshland and Bruce and others have argued that, in fact, this
00:11:06 may be the main mechanism whereby enzymes catalyze chemical reactions.
00:11:11 So to test that notion and see whether we can use this as a rule for generating antibody
00:11:15 catalysts, we first looked at an intramolecular reaction, the conversion of carismic acid
00:11:21 to prefinic acid.
00:11:23 This reaction is of interest for a number of reasons.
00:11:26 First of all, it's involved in the biosynthesis of aromatic amino acids in plants and bacteria,
00:11:31 and as such is catalyzed by the enzyme carismate mutase, which accelerates the reaction roughly
00:11:37 a million-fold over the background rate.
00:11:40 Second of all, this enzyme is a rare example of what's formally a pericyclic reaction,
00:11:45 a 3,3-sigmatropic rearrangement of carismate to prefinate.
00:11:49 Now, this reaction is known both in the uncatalyzed and enzyme-catalyzed forms to proceed through
00:11:55 a chair-like conformationally restricted transition state, and it costs approximately minus 13
00:12:02 entropy units to form this transition state because we're restricting the conformations
00:12:07 of the carismate substrate.
00:12:09 So then the idea is if we could make an antibody that binds carismate, the substrate, and locks
00:12:15 it in this chair-like transition state, we should get a catalyst, and that should be
00:12:18 pretty good.
00:12:19 Well, in fact, we've generated antibodies to the bicyclic diacid transition state analog
00:12:24 shown here, and in fact, one such antibody accelerates this reaction 10 to the fourth
00:12:29 fold over background.
00:12:31 So that's about 100 times slower than the naturally occurring enzyme.
00:12:35 How's the antibody work?
00:12:36 We've in fact recently measured the activation parameters for this antibody-catalyzed reaction,
00:12:41 and in fact have shown that the delta S double dagger for the reaction is approximately zero.
00:12:47 So the antibody is in fact functioning as an entropy trap.
00:12:50 Well, given we can catalyze an intramolecular reaction using this strategy, the obvious
00:12:55 next step is to go to a bimolecular reaction, and we chose to look at the Diels-Alder reaction,
00:13:01 which is of interest for a number of reasons.
00:13:03 First of all, there's no known enzyme that catalyzes a Diels-Alder reaction, so it was
00:13:08 of interest to see if we could generate a catalytic antibody that does this.
00:13:11 Second of all, this is a very important reaction in chemistry for forming carbon-carbon bonds.
00:13:16 Two carbon-carbon bonds are formed in a single step.
00:13:19 And finally, this reaction is known to have a very large negative entropy of activation.
00:13:25 So to test whether we can make antibodies that catalyze a Diels-Alder reaction, we looked
00:13:29 at the model system shown here, a Diels-Alder condensation of this water-soluble diene with
00:13:35 a molybdenum dienophile to form the corresponding cyclohexane derivative product.
00:13:41 This reaction, again, proceeds through a very conformationally restricted transition state.
00:13:46 And the question, then, one has to think about is what molecule does one synthesize to instruct
00:13:52 the immune system to make a Diels-Alderase catalyst?
00:13:55 Well, we chose to form the carbon-carbon sigma bonds and lock our hapten into the Diels-Alder-like
00:14:04 transition state with an ethanol bridge.
00:14:07 So we generated antibodies to this 2, 2, 2 bicyclic system.
00:14:11 And in fact, when we made antibodies to this hapten, we found that they accelerated the
00:14:15 reaction roughly 10 to the 6th over background.
00:14:18 Now, the next obvious step in this series is to ask whether we can use the specificity
00:14:23 of antibodies to catalyze the formation of the exo, or the disfavored product, over the
00:14:29 more favored endoproduct, something that's relatively difficult to do with chemical reagents.
00:14:36 We've also looked at another bimolecular reaction, a transesterification reaction shown here.
00:14:41 This reaction involves a transfer of an acyl group to a secondary alcohol of the climidine.
00:14:48 This reaction is a tough reaction for a number of reasons.
00:14:52 First of all, we're going to carry out this reaction in water.
00:14:54 So although we'd like to transfer the acyl group to a secondary alcohol, we have a lot
00:14:59 better nucleophile present in the reaction mixture.
00:15:02 Moreover, there's 10 to the 5th times more of this better nucleophile of water than the
00:15:07 secondary alcohol.
00:15:09 So you need a pretty good catalyst to transfer the acyl group to the thymidine versus water
00:15:14 itself, which would be just a simple hydrolytic reaction.
00:15:17 To do this, we generated antibodies against the hapten shown here, this phosphonate diester
00:15:24 which incorporates elements of both substrates and the leaving group in the appropriate configuration.
00:15:29 In fact, when we generated antibodies to this phosphonate diester, we isolated one and accelerated
00:15:36 the reaction roughly a billion times over the background rate.
00:15:40 Now that's the rate you see in highly evolved enzymes.
00:15:43 Moreover, there was absolutely no hydrolysis of the ester catalyzed by the antibody.
00:15:51 So the antibody has such high specificity that it selectively transferred the acyl group
00:15:55 to the secondary alcohol versus ubiquitous water.
00:15:59 Again, this is the kind of specificity one sees in a highly evolved enzyme.
00:16:04 I should point out Richard Lerner has also generated antibodies that carry out a similar
00:16:08 transesterification reaction using similar substrate.
00:16:12 But in his case, the antibodies function via a completely different mechanism.
00:16:16 He showed, in fact, that his antibodies, which accelerate the reaction again about
00:16:20 a billion fold, his mechanism involves an acyl antibody intermediate.
00:16:26 Our mechanism simply involves binding of the two substrates in a reactive configuration
00:16:31 in the antibody combining site.
00:16:34 So nature can use multiple mechanistic solutions for a single catalytic problem.
00:16:39 This is again reflected in enzymes in the serine, aspartyl, and metalloproteases.
00:16:45 What other kinds of reactions can you do using this idea of entropy and entropic restriction?
00:16:51 Well, one can imagine generating antibodies that catalyze macrocyclic lactinization reactions.
00:16:57 One can make a peptide ligase that pastes together peptides to make protein.
00:17:01 One could make an aldolase.
00:17:04 One could perhaps make catalysts that generate stereoregular polymers.
00:17:08 All of these issues are currently under investigation.
00:17:11 I think I should point out also that this exercise has taught us an important thing.
00:17:15 In fact, the simple notion of proximity effects or entropic restriction can lead to very,
00:17:22 very large rate accelerations in enzymatic catalysis.
00:17:25 And in fact, as Jens pointed out, this is probably one of the most important mechanisms
00:17:30 whereby enzymes operate.
00:17:32 So what other strategies can we use to generate catalytic antibodies?
00:17:36 We've seen two.
00:17:37 The third possible strategy is the notion of general acid, general base catalysis.
00:17:41 Let's consider for a minute the reaction shown here, the isomerization of this alpha-hydroxy
00:17:47 ketone to the corresponding aldehyde, alpha-hydroxy aldehyde.
00:17:53 What's interesting about this reaction is that it's catalyzed by an enzyme, and the
00:17:56 enzyme accelerates this reaction roughly 10 to the 8th of a background.
00:18:01 But the enzyme accelerates this reaction to such a degree that the rate-limiting step
00:18:05 in the enzymatic reaction is diffusion of the substrates into the active site.
00:18:10 Not chemistry, but simple physical phenomena.
00:18:13 So clearly we'd love for all our catalysts to have this kind of catalytic efficiency.
00:18:18 So how are we going to make antibodies if it functions this effectively?
00:18:21 Well, you've got to realize that this enzyme, tri-SPSM erase, does two things.
00:18:25 First of all, it stabilizes the negatively charged transition state, something we know
00:18:29 how to do already.
00:18:31 But it also has a general base in the active site that deprotonates the C-alpha position.
00:18:37 And by using these two things together, TS stabilization and a general base, it achieves
00:18:41 a very large rate acceleration.
00:18:44 So we'd clearly love to know how to generate general bases in the antibody-combining site.
00:18:48 So how do we do that?
00:18:49 We looked again at a deprotonation reaction, but when we deprotonate in this case, we're
00:18:54 carrying out the elimination of fluoride from a beta-fluoroketone to give the corresponding
00:18:59 enone.
00:19:00 So to catalyze this reaction with a general base, you'd like a base positioned such that
00:19:05 it can abstract a C-alpha proton to initiate the reaction.
00:19:08 Well, how do we get that base in the appropriate position?
00:19:11 Well, we take advantage of the complementarity of the antibody to the hapten against which
00:19:16 it's generated.
00:19:17 If we want a negatively charged carboxylate acting as a base in the combining site, what
00:19:21 we do is we make the antibody to a positively charged hapten.
00:19:26 In fact, we did that, generated antibodies to these benzylammonium haptens, and in fact
00:19:30 found antibodies that catalyze this elimination reaction roughly 10 to the fifth over the
00:19:34 background rate.
00:19:37 We've characterized these antibodies extensively, shown that there's a carboxylate, identified
00:19:42 the carboxylate, determined the rate-limiting step, and actually determined the stereochemistry.
00:19:48 Another interesting illustration of this notion of generating general acid and general basic
00:19:52 groups in antibody combining sites is a recent reaction published by Richard Lerner and Kim
00:19:58 Janda and co-worker.
00:20:00 This reaction involves the hydrolysis of an enol ether to the corresponding aldehyde.
00:20:06 What you need to carry out this reaction is an acidic group, such as a glutamate or aspartate
00:20:10 in the antibody combining site, and Lerner and Janda and others reason that if they generated
00:20:16 antibodies to a positively charged hapten, they might get an acidic residue in the combining
00:20:21 site.
00:20:23 In fact, that's exactly what happened.
00:20:24 They did isolate catalytic antibodies, and interestingly, these antibodies catalyzed
00:20:29 the conversion of the enol ether to the chiral aldehyde, and gave the chiral aldehyde a greater
00:20:35 than 98% EE.
00:20:37 These are extremely selective catalysts delivering a proton to only one face of the enol ether,
00:20:42 something that's very difficult for chemists to do.
00:20:46 What other kinds of reactions can you do using this strategy?
00:20:49 You can imagine generating antibodies that have a general base that catalyze RNA cleavage,
00:20:55 or antibodies that catalyze an oxy-cope rearrangement via an anionic substituent effect.
00:21:01 So that's a third strategy one can use to generate antibodies.
00:21:05 A fourth approach one can take involves exploiting chemical cofactors to carry out antibody catalyzed
00:21:12 reactions.
00:21:13 What do I mean by this?
00:21:14 Now, enzymes, when faced with a difficult chemical reaction, such as an oxidative reaction
00:21:19 or the hydrolysis of an amide or a glycosidic linkage, often recruit cofactors.
00:21:27 The natural cofactors are metal ions, pyridoxal, flavins, hemes, and so forth.
00:21:34 Question is, can we also generate antibodies that use cofactors?
00:21:37 Now with antibodies, we should not only be able to use the natural cofactors, but because
00:21:42 we can basically dial in any specificity we'd like, we should be able to use a huge
00:21:47 range of unnatural synthetic cofactors.
00:21:50 For instance, metal hydrides could be used in redox reactions, transition metals, rhodium
00:21:56 phosphine complexes, photosensitizers, and so forth.
00:22:00 As a demonstration of this idea, we asked whether we could generate antibodies that
00:22:05 catalyze a stereospecific reduction of an alpha-keto amide.
00:22:10 Now, if you were an enzyme and you were going to carry out this reaction, you would probably
00:22:13 choose nicotinamide as a cofactor.
00:22:15 If you look up the price of nicotinamides and borohydrides in Aldrich, you find out
00:22:20 nicotinamides cost about a thousand times more than a borohydride.
00:22:23 Borohydrides are more powerful reagents.
00:22:26 So we asked whether we could generate an antibody that uses borohydrides as a catalytic auxiliary
00:22:30 to carry out this reaction.
00:22:31 Well, in fact, in this case, we generated antibodies to a phosphonate, which we thought
00:22:36 might be a reasonable mimic of a hydride attack on a carbonyl.
00:22:39 And those antibodies actually did carry out the reaction, and they gave the corresponding
00:22:44 2S product with a DE of greater than 98%.
00:22:48 That's interesting since the background reaction gives the other diastereomer, the 2R diastereomer,
00:22:53 with a 56% DE.
00:22:57 More recently, we've begun to look at the stereospecific reduction of unactivated ketones.
00:23:02 For example, we've looked at the reduction of the nitrobenzyl ketone shown on this slide.
00:23:08 Now, in this case, we've used antibodies not to a phosphonate, but to an anoxide hapten.
00:23:14 And, in fact, we've isolated an antibody that catalyzes the reduction of this carbonyl group
00:23:19 in this benzylic system with the corresponding alcohol with an EE of greater than 98%.
00:23:26 More recently, we've gone on to look at the issue of regiospecificity.
00:23:29 So we've asked whether we can generate an antibody that catalyzes the reduction, say,
00:23:33 of the nitrobenzyl carbonyl versus a methoxybenzyl carbonyl group.
00:23:37 And, in fact, we've isolated one such antibody that does do this, that selectively reduces
00:23:42 the nitrobenzyl carbonyl.
00:23:45 So we don't have to use protecting groups to achieve selective reduction in this system.
00:23:50 We're also looking at natural cofactors, such as hemes, and our hope here is to use hemes
00:23:57 to catalyze the regiospecific hydroxylation of substrates, for example, a steroid.
00:24:02 We've, in fact, shown that antibodies elicited to an enalkylporphyrin will, in fact, bind
00:24:08 the ferricene and, in the presence of hydrogen peroxide as the oxidant, catalyze the oxidation
00:24:14 of a number of aromatic chromogenic substrates.
00:24:17 We now, the problem with these antibodies, although the rate is pretty good, 200 per
00:24:21 molar per second, the specificity for substrate is low.
00:24:25 In an attempt to build in a substrate binding site, we're making antibodies now to enalkylporphyrins
00:24:31 in which the substrate of interest, say a steroid, is linked to one of the pyrrol nitrogens
00:24:37 of the porphyrin ring.
00:24:38 This should give us two binding sites, one for the heme and one for the substrate.
00:24:44 Other kinds of cofactors that have been looked at are pyridoxals and flavins.
00:24:49 Other potential cofactors include metal ligand complexes, which Lerner and coworkers have
00:24:55 used to generate antibodies that catalyze the cleavage of a peptide bond.
00:25:00 Light has also been used as a cofactor in antibody catalyzed reactions in a 2 plus 2
00:25:05 cycloreversion reaction, again showing that, in fact, all of the rich excited state photochemistry
00:25:10 that's available to synthetic chemists is also available to catalytic antibodies.
00:25:15 So where are we going?
00:25:17 What are we going to see in the next few years in the area of catalytic antibodies?
00:25:20 Well, one thing we're going to see is exploiting combinatorial libraries for the generation
00:25:26 of catalytic antibodies.
00:25:28 Combinatorial technology is going to allow us to assay, rather than 50 antibodies for
00:25:32 catalytic activity, 100,000 antibodies for catalytic activity.
00:25:37 So we're very likely to see increased catalytic rates from this technology.
00:25:42 Also, the process of natural selection is going to be brought to bear on the design
00:25:46 of catalytic antibodies.
00:25:50 Many reactions, hydrolytic reactions of amides, esters, phosphodiesters, and sugars, can be
00:25:56 coupled to the survival of a living cell.
00:25:59 And by coupling a catalytic antibody reaction to the life of E. coli, we can bring the process
00:26:05 of natural selection to bear on the evolutions of these catalysts and increase the rates
00:26:09 dramatically this way as well.
00:26:11 Finally, a third important strategy that's currently being examined is to combine the
00:26:16 concepts we've talked about during this talk, combine transition state stabilization with
00:26:21 entropic reduction with a general base, bring all of these catalytic concepts to bear on
00:26:26 the design of a single catalytic antibody for a single reaction.
00:26:31 And this idea has been actually nicely illustrated by Richard Lerner in a relatively spectacular
00:26:35 reaction shown on the next slide.
00:26:38 Richard asked whether he could generate antibodies that catalyze an intramolecular ring opening
00:26:43 of an epoxide to give the corresponding cyclic ether.
00:26:47 Now, how are you going to generate an antibody that does this reaction?
00:26:51 Well, Richard made antibodies to a cyclic N-oxide.
00:26:55 The N-oxide functionality was thought to reflect the dipolar nature of the transition state
00:27:00 for CO bond cleaving.
00:27:02 The six-membered ring is thought to reflect the cyclic six-membered ring transition state
00:27:06 in this reaction.
00:27:07 So we're achieving two effects in this hapten.
00:27:10 Well, in fact, this reaction, this antibody catalyzed reaction, actually goes to give
00:27:15 the disfavored product.
00:27:17 The six-membered ring product is a major reaction.
00:27:20 Now, if you carry out this reaction in solution, what you get is a five-membered ring favored
00:27:26 cyclic ether, which is favored by Baldwin's rules.
00:27:29 So what we see here is an example where the specificity and affinity of the antibody have
00:27:34 been used to selectively stabilize a disfavored over a favored transition state.
00:27:40 So what have we learned over the past six years by looking at catalytic antibodies?
00:27:44 Well, one thing we've learned is that, in fact, one can generate catalytic antibodies
00:27:48 via a number of approaches, stabilizing transition states, reducing entropy of activation, general
00:27:54 acid-base catalysis, covalent catalysis, or many of these features simultaneously.
00:28:01 Antibodies can catalyze a large number of different reactions.
00:28:04 They can catalyze hydrolytic reactions, amide bond cleavage, paracyclic reactions, a Diels-Alder
00:28:10 reaction, substitution reactions, a cyclization of an epoxide, isomerization reactions, and
00:28:16 redox reactions.
00:28:18 Antibody catalyzed reactions are characterized also by high specificity and, in many cases,
00:28:23 very high rates rivaling those of the corresponding enzymes.
00:28:27 And finally, the characterization of these catalytic antibodies has, in fact, given
00:28:32 us greater insight into the mechanisms of biological catalysis, and I think we'll continue
00:28:37 to do so.
00:28:42 The final speaker is Dr. George M. Whitesides.
00:28:46 He is professor of chemistry at Harvard University, where his research interests include biochemistry,
00:28:52 material science, rational drug design, and molecular recognition.
00:28:57 Dr. Whitesides' presentation will focus on what reactions can be accomplished by enzymes
00:29:03 and how and where to use these reactions.
00:29:06 Dr. Whitesides' topic today is organic synthesis using enzymes.
00:29:12 I'd like to talk to you about enzymes.
00:29:16 Enzymes are proteins that are catalytic.
00:29:20 They're obtained from natural sources, and they offer the chemist unique opportunities
00:29:26 to bring selectivity and, in some cases, rate acceleration to certain types of reactions
00:29:33 that are very difficult to accomplish otherwise.
00:29:37 In the past, enzymes have not been a very important part of the catalytic repertoire
00:29:43 of synthetic chemists, at least in part because they were not very readily obtainable.
00:29:50 The advent of recombinant DNA technology has made it possible to produce almost any enzyme
00:29:56 now in substantial quantities.
00:29:59 So the availability of these species is no longer a limiting factor in their use in synthesis.
00:30:07 What I would propose to do is to discuss three topics with you.
00:30:12 First, I'd like to outline the characteristics of enzymes as catalysts.
00:30:18 What makes them interesting?
00:30:19 Why are they different from other kinds of catalysts?
00:30:22 Second, I'd like to give you a little sense for how they're used in the laboratory.
00:30:28 And third, and taking most of the time, I want to show you applications in which enzymes
00:30:34 provide unique solutions to problems in chemical catalysis.
00:30:40 Let's begin by thinking about some of the characteristics of enzymes broadly.
00:30:50 Enzymes are proteins.
00:30:52 They can be obtained either from microorganisms with the advantage of large-scale production
00:30:58 using recombinant techniques, or they can be obtained from animal or plant tissue.
00:31:06 Their characteristics as a catalyst are primarily that they are selective, but secondarily that
00:31:13 they give rate accelerations.
00:31:16 When you have a problem that requires selectivity, think about enzymes.
00:31:21 They also have the characteristic that they are regulated, that is to say their capability
00:31:27 to accelerate a reaction depends upon what other compounds are present in solution.
00:31:34 This capability for regulation is sometimes useful, but it is more often a nuisance.
00:31:40 So I'll point out one occasion in which regulation is important, but in general we will ignore
00:31:48 this part of enzymatic catalysis.
00:31:52 Where have enzymes actually been used?
00:31:54 There are three applications in which they have clearly established their value.
00:32:01 The first is in chiral synthesis, particularly the synthesis of small chiral fragments for
00:32:08 use in pharmaceutical synthesis.
00:32:11 The second is industrial chemistry, where their ability to work in room temperature
00:32:17 aqueous solution offers solutions to environmental problems and sometimes substantially interesting
00:32:24 solutions to problems in purification.
00:32:28 They have also begun to revolutionize the synthesis of sugars.
00:32:33 Glycobiology is one of the most exciting areas of sugar chemistry, and enzymes are providing
00:32:38 one of the key technologies for making sugars and their derivatives.
00:32:43 What about cost?
00:32:45 The tradition has it that enzymes are expensive as catalysts.
00:32:51 Is this true?
00:32:54 In fact, in some circumstances they can be quite economical as catalysts because they
00:32:59 have very high catalytic efficiency.
00:33:01 Let's look at a typical set of numbers.
00:33:07 For an enzyme operating under optimal conditions, it should be possible to achieve turnover
00:33:13 numbers, that is moles of product per mole of enzyme, in the order of 10 to the 6th to
00:33:20 10 to the 8th.
00:33:21 These are very high numbers for a catalytic process.
00:33:28 If one takes a typical cost of $10 per gram for an industrial enzyme, the cost of a mole
00:33:35 of enzyme would be in the order of a million dollars, admittedly expensive.
00:33:41 On the other hand, for a turnover number of 10 to the 6th to 10 to the 8th, the contribution
00:33:47 to the cost of the product based on the enzyme will be only in the order of a dollar to a
00:33:54 penny per mole.
00:33:55 Thus, under some circumstances at least, enzymes need not be expensive as catalysts.
00:34:02 One can take advantage of their very high turnover numbers to lower their contributed
00:34:08 cost to the product to the point where it may not even be significant.
00:34:12 How are enzymes manipulated in solution?
00:34:16 One of their virtues is that they're easy to use.
00:34:21 Probably the simplest thing to do with them is simply to add an enzyme to a solution containing
00:34:26 the reactant.
00:34:28 This is a common procedure with lipases and with certain amidases in which the enzymes
00:34:33 are quite inexpensive and very sturdy in solution.
00:34:38 In some circumstances, it's necessary to immobilize the enzymes or to somehow contain them either
00:34:45 to preserve their activity or to enable them to be recovered or sometimes to make it easy
00:34:51 to separate them from the products.
00:34:55 Let me show you several simple pieces of apparatus that we use in our laboratory when we're using
00:35:01 enzymes in catalysis.
00:35:07 A common procedure is to use the enzymes in a mobilized form.
00:35:14 Here I show you an enzyme system contained behind a dialysis membrane.
00:35:22 This technique called MEEC, M-E-E-C, for membrane enclosed enzymatic catalysis, provides a very
00:35:31 simple method of keeping the enzyme separated from the products and allowing it to be recovered.
00:35:38 In this kind of procedure, one adds the enzyme to the dialysis membrane, carries out the
00:35:44 reaction, the reactants diffuse in to the compartment, react, and then diffuse out.
00:35:51 At the end of the reaction, to separate the enzyme, one simply pulls out the dialysis
00:35:55 tubing.
00:35:56 It can be stored in a refrigerator and frequently reused on many occasions.
00:36:02 A second procedure for using an enzyme is to immobilize it on a solid support.
00:36:09 Glass beads are commonly used and glutaraldehyde is perhaps the most useful cross-linking agent.
00:36:15 A third procedure is to immobilize the enzyme by covalent reaction in a polyacrylamide gel
00:36:24 or some other soft diffusible substrate.
00:36:28 We have employed extensively a gel based on a polymer called PAN, and I show you here
00:36:36 a typical enzyme preparation.
00:36:38 The suspended particles are the polyacrylamide gel containing immobilized enzyme.
00:36:45 This kind of procedure can be used to recover the enzyme by centrifugation or filtration
00:36:51 at the conclusion of the process.
00:36:55 It's useful to mention two other aspects of enzymatic catalysis.
00:37:00 First, all enzymes are temperature sensitive, most are pH sensitive, and many are sensitive
00:37:07 to oxygen.
00:37:09 It is, therefore, useful to set up reactions in such a fashion that one can control pH
00:37:17 and control access of oxygen.
00:37:21 Here I show you a common apparatus that we use in the laboratory for this purpose.
00:37:26 It's simply a round bottom flask and it has attached to it a pH controller and a pH sensor.
00:37:33 Very simple system and one that is accessible in any laboratory on a small scale.
00:37:39 The final point that I would emphasize about enzymes is that they are proteins and hence
00:37:46 are subject to biodegradation by microorganisms.
00:37:50 It is annoying to carry out a reaction on Friday afternoon, come back on Monday, and
00:37:56 find that a yeast is eating your catalyst.
00:37:59 The procedures for preventing such biodegradation are straightforward, but they're a little
00:38:03 unfamiliar to many chemists.
00:38:06 Basically, one adds a fungicide or a material like azide that prevents the growth of most
00:38:14 microorganisms.
00:38:16 Let's turn now to examples of the uses of enzymes in organic synthesis.
00:38:23 I want to talk about three types of applications.
00:38:28 Simple applications in which we are concerned with hydrolysis or isomerization, more complex
00:38:36 systems, and then very complicated systems involving multiple enzymes.
00:38:44 The most important simple enzymatic reactions are those based on esterases or amidases for
00:38:52 hydrolysis of esters and amides or on simple isomerization reactions.
00:38:58 These are also the basis for the largest scale reactions.
00:39:03 The reactions of intermediate complexity either involve unusual enzyme systems, for example,
00:39:12 the use of aldolases for forming sugars, or cofactors.
00:39:18 Cofactors are reagents that are required by many enzymes to achieve phosphorylation or
00:39:23 to donate or accept hydrides in oxoreductase catalyzed systems.
00:39:30 Probably the most complex type of multi-enzyme system now used are those that are involved
00:39:37 in the Loire pathway for sugar biosynthesis.
00:39:40 And I will mention those at the end of the talk.
00:39:45 Let's begin by simple examples focused on hydrolases.
00:39:51 These are reactions that can be carried out in very large scale and are operationally
00:39:56 very straightforward.
00:40:01 Probably the ideal enzyme in many circumstances is acylase I.
00:40:08 Acylase is an enzyme that hydrolyzes acetylamino acids.
00:40:13 It has the characteristic that it will accept a very wide variety of amino acids, both natural
00:40:19 ones and unnatural ones.
00:40:21 It is effectively enantiospecific.
00:40:26 So acylase I has the characteristic that it combines two attractive characteristics,
00:40:32 very broad substrate specificity and very high enantioselectivity.
00:40:37 It also is very inexpensive and very sturdy.
00:40:43 Lipase is a representative of another very important class of enzymes.
00:40:48 Lipase hydrolyzes esters enantioselectively.
00:40:53 The example that I show here is the hydrolysis of glycidylbutyrate.
00:41:01 Let me give you an example in which I can sketch the procedure.
00:41:06 What one does in this hydrolysis is to take a beaker.
00:41:11 You fill it a quarter full with water and then another quarter full with glycidylbutyrate.
00:41:18 Lipase is added as a crude powder.
00:41:21 The reaction is stirred until it stops and what is left in the insoluble organic phase
00:41:27 is one enantiomer of unhydrolyzed glycidylbutyrate.
00:41:33 Separation involves simply pouring off the upper layer.
00:41:36 It's difficult to find anything easier.
00:41:39 What about large scale processes?
00:41:42 Enzymes have actually found several important applications in very large scale chemistry,
00:41:48 chemistry that qualifies as full industrial scale.
00:41:52 The value of these applications is either environmental friendliness, enantioselectivity,
00:41:58 or compatibility with food products.
00:42:02 The first example is the isomerization of glucose to fructose.
00:42:06 This is a process used in making high fructose corn syrup and is practiced in the United
00:42:12 States on a scale of approximately 10 to the 9th pounds per year.
00:42:18 A second interesting and surprising example is the hydrolysis of acrylonitrile to acrylamide.
00:42:27 In older industrial practice, this reaction was carried out using a copper chromite catalyst
00:42:33 in steam and there was a strong feeling that it would be difficult to find anything much
00:42:38 simpler.
00:42:39 In fact, overall, the enzyme catalyzed process developed by NITO has proved to be better.
00:42:49 The productivity of the enzyme and the stability of the enzyme are excellent and the purity
00:42:55 of the product is such that purification costs in this process are substantially lower than
00:43:02 they are in the steam hydrolysis.
00:43:05 Overall, it now seems that the enzyme catalyzed hydrolysis of acrylonitrile to acrylamide
00:43:12 is the best method of carrying out this process.
00:43:16 The third example is the hydrolysis of penicillin G to 6-amino penicillinic acid, 6-APA.
00:43:24 6-APA is used as an intermediate in the synthesis of semi-synthetic penicillins.
00:43:31 And the value of enzymatic catalysis in this case is the selective hydrolysis of the more
00:43:38 stable amide group in the presence of a more reactive amide group.
00:43:44 A final example is the enantiospecific addition of ammonia to fumaric acid to make optically
00:43:51 active aspartic acid.
00:43:53 This is one representative of a class of reactions in which enzymes are used to make optically
00:44:00 pure amino acids for food and parenteral use.
00:44:06 Let's consider more complicated reactions involving cofactors.
00:44:11 There are two classes of cofactors that are commonly used in current enzymatic synthesis.
00:44:18 One is based on ATP.
00:44:20 The second is based on the nicotinamide cofactors NAD, NADH, and their derivatives.
00:44:28 ATP is used in biological systems as the equivalent of tosyl chloride for oxygen activation.
00:44:36 Where you would use tosyl chloride, nature phosphorylates an oxygen to make it a better
00:44:41 leaving group.
00:44:44 The nicotinamide cofactors are used as hydride donors and hydride acceptors.
00:44:49 They are, in a sense, the equivalent of borohydride or lithium aluminum hydride for reductions
00:44:57 and of chromium trioxide or Swern reagent for oxidations.
00:45:04 These materials are too expensive to be used stoichiometrically, so it's necessary to recycle
00:45:09 them in situ in order to make a number of moles of product per starting mole of cofactor.
00:45:18 Let me show you a simple example of the use of NADH as a cofactor in an enzyme catalyzed
00:45:27 reaction leading to a chiral useful piece.
00:45:32 The reaction here is based on lactate dehydrogenase.
00:45:36 This is a widely available enzyme that has excellent enantioselectivity in the conversion
00:45:42 of pyruvate and its analogs to lactic acid and its analogs.
00:45:48 The reaction proceeds with conversion of NADH to NAD+.
00:45:54 The reconversion of NAD plus to NADH can be accomplished using a number of systems.
00:46:02 The one that is most widely used involves formate dehydrogenase as the catalyst and
00:46:07 formate as the hydride donor.
00:46:10 One can also find excellent systems based on glucose as the hydride donor and glucose
00:46:15 dehydrogenase as catalyst or, in some cases, glucose 6-phosphate dehydrogenase as the catalyst
00:46:22 and glucose 6-phosphate as the donor.
00:46:26 The example here is the conversion of chloropyruvate to optically active epoxy acrylic acid through
00:46:35 optically active chlorolactic acid.
00:46:38 The reaction proceeds very smoothly and has been carried out on scales approaching a mole.
00:46:46 What does enantioselectivity mean in this type of process?
00:46:50 Let me show you an example of a reduction using a deuterium label to provide an optically
00:46:59 pure labeled product.
00:47:04 This reaction is the conversion of trifluoroacetaldehyde to monoduterated trifluoroethanol.
00:47:12 Examination of the signals in the NMR spectrum labeled R and S give an indication of the
00:47:20 enantioselectivity of this process.
00:47:24 The use of enzymes in preparing labeled compounds is one of their widest specialty uses.
00:47:32 The use of enzymes for oxidation reactions is, for a number of reasons, somewhat more
00:47:39 complicated technically than reductions.
00:47:42 There are, nonetheless, some very valuable cases in which it is possible to make chiral
00:47:48 intermediates using enzymatic oxidations.
00:47:52 The example that I show here is one that represents work of Brian Jones, who has been one of the
00:48:00 pioneers in this area.
00:48:02 It is the conversion of a diol to an optically active lactone based on a NAD catalyzed oxidation.
00:48:13 The enzyme used here is alcohol dehydrogenase.
00:48:17 The NADH is reconverted to NAD using glutamate dehydrogenase.
00:48:24 Jones has also explored systems in which oxygen is the final oxidant using a system in which
00:48:33 there is an intermediate di-methylene blue as an electron transfer catalyst and an additional
00:48:40 enzyme, diaphorese, to accelerate the rates of these reactions.
00:48:47 The difficulty with oxidation reactions is that the product is typically more hydrophobic
00:48:52 than the starting material and tends to stick in the active site of the enzyme.
00:48:57 Hence, these reactions are often regulated, that is to say, inhibited by product.
00:49:04 Let's turn now to the use of ATP in organic synthesis.
00:49:09 A simple example is based on the enzyme glycerol kinase, which phosphorylates enantiospecifically
00:49:17 a wide variety of analogs of glycerol.
00:49:23 Glycerol kinase will take derivatives of glycerol as substrates that have small polar functionalities
00:49:31 in the 3 position, a variety of groups in the 2 position, and a limited number of substituents
00:49:37 in the 1 position.
00:49:39 These optically active glycerol phosphate analogs are useful in the synthesis of phospholipids,
00:49:46 phospholipid analogs, and related compounds.
00:49:50 In carrying out the types of reactions that require ATP regeneration, what are the best
00:49:59 phosphate donors to use?
00:50:02 There are now 2 very well developed systems for the synthesis of phosphates that can be
00:50:11 donated to ADP in situ for use in ATP cofactor recycling.
00:50:19 The first of these is acetyl phosphate.
00:50:22 Acetyl phosphate is easily prepared in very large quantities if needed by acetylation
00:50:28 of phosphoric acid with acetic anhydride.
00:50:34 Probably the more useful reagent is phosphoenolpyruvate.
00:50:39 There are 2 types of syntheses of phosphoenolpyruvate.
00:50:43 One involves starting with pyruvate, bromination, reaction with a phosphate, and hydrolysis
00:50:51 following a classical chemical procedure.
00:50:55 The second is based on enzymology.
00:51:00 This is a procedure that begins with 3-phosphoglyceric acid and uses 2 enzymes to convert 3-PGA to
00:51:10 phosphoenolpyruvate, PEP, in situ.
00:51:15 A reaction that utilizes the PEP, and one that I'm going to talk about in a moment,
00:51:22 the conversion of dihydroxyacetone to dihydroxyacetone phosphate, proceeds then in situ using 4 enzymes
00:51:34 overall, 2 to convert 3-PGA to PEP, 1 to recycle ADP into ATP, and the 4th to convert
00:51:46 the organic reactant, the dihydroxyacetone, to the product, dihydroxyacetone phosphate.
00:51:54 This set of reactions gives a hint of the extent to which enzymes can be coupled in
00:52:01 in situ reactions.
00:52:04 Let me turn now to a somewhat more sophisticated example of organic synthesis.
00:52:09 This is the synthesis of a sugar, KDO, keto-deoxy-octanoic acid.
00:52:18 This compound is important as a constituent in microbial cell walls.
00:52:22 It is a potential target for new types of antibiotics, and there is substantial interest
00:52:28 in KDO as a substrate in reactions in which inhibitors are being tested.
00:52:38 The synthesis proceeds in 3 steps.
00:52:43 The first involves phosphorylation of arabinose using hexokinase to give arabinose 5-phosphate.
00:52:52 There's an important lesson from this step.
00:52:56 The biochemical literature reports that arabinose is not a substrate for hexokinase.
00:53:03 In fact, in many circumstances, one should not be too closely guided by the biochemical
00:53:10 literature, because activities of enzymatic catalysts that are too low to be significant
00:53:16 in biochemical circumstances may, in fact, be very useful in chemistry.
00:53:22 In this particular instance, the activity of arabinose is less than 1% of the activity
00:53:28 of the natural substrate for hexokinase, which is glucose.
00:53:33 Nonetheless, by putting in a substantial excess of hexokinase, it is possible to get a smooth
00:53:40 conversion of arabinose to arabinose 5-phosphate without the use of protecting groups.
00:53:46 The ATP in this reaction is recycled by reaction with PEP catalyzed by pyruvate kinase.
00:53:58 The second step in the reaction is the carbon-carbon bond formation between arabinose 5-phosphate
00:54:05 and phosphoenolpyruvate catalyzed by KDO 8-phosphate synthetase.
00:54:12 This is a reaction that proceeds stereospecifically and provides a complex sugar skeleton, again
00:54:21 without the use in protecting groups.
00:54:24 The final step in the reaction is dephosphorylation using acid phosphatase, and once again illustrates
00:54:31 the use of enzymes in sugar chemistry to avoid protection and deprotection steps.
00:54:37 Let me talk now about another enzyme that has proved particularly useful in carbohydrate synthesis.
00:54:45 This is rabbit muscle aldolase, Rama, R-A-M-A.
00:54:50 This enzyme catalyzes the stereospecific reaction between the enol of dihydroxyacetone phosphate
00:54:58 and the aldehyde group of a variety of aldehydes.
00:55:02 It has been used extensively in forming carbon skeletons in sugars.
00:55:09 The example that I give here is one developed by Wong, leading to the compounds deoxynoduramicin
00:55:19 and deoxymanonoduramicin.
00:55:22 These are compounds which are useful as inhibitors in certain steps in the processing of oligosaccharides
00:55:31 in biochemical systems.
00:55:34 The crucial element in this synthesis is the carbon-carbon bond formation between dihydroxyacetone
00:55:43 phosphate and the aldehyde containing nitrogen protected in the form of an azide.
00:55:50 The reaction proceeds under very mild conditions and proceeds stereospecifically.
00:55:56 The final step of the reaction, the conversion of the azido compound to the aza sugar,
00:56:04 uses two steps, dephosphorylation using an enzyme and the catalytic heterogeneous reduction
00:56:13 of azide to amine.
00:56:16 A further and increasingly important application of enzymes in carbohydrate synthesis
00:56:23 is to the preparation of oligosaccharides.
00:56:28 The formation of glycosidic links remains one of the real challenges in carbohydrate chemistry.
00:56:35 And the enzymes of the so-called Loire pathway have proved enormously useful in preparing
00:56:42 glycosidic bonds without the use of protecting groups.
00:56:47 The example shown here is one of the first and simplest.
00:56:54 The overall process involves a number of steps.
00:56:58 Conversion of glucose to glucose-6-phosphate enzymatically, isomerization of glucose-6-phosphate
00:57:06 to glucose-1-phosphate, reaction of glucose-1-phosphate with UTP to make UDP-glucose.
00:57:18 UDP-glucose epimerase is then used to change the configuration of one of the hydroxyl groups.
00:57:26 And a glycosyltransferase is used to form the glycosidic bond that connects the glucose
00:57:33 moiety to N-acetylglucosamine.
00:57:38 The UDP that is produced in this final step is reconverted to UTP by phosphorylation using
00:57:46 phosphoenolpyruvate.
00:57:49 The overall process involves six enzymes working cooperatively in the same solution,
00:57:56 converting three starting materials into one complex final product without intermediate
00:58:04 protecting groups.
00:58:06 The final process that I want to talk about is one that integrates many of the steps that
00:58:12 we've talked about.
00:58:13 This is the conversion of glucose to ribulose diphosphate.
00:58:19 Ribulose diphosphate is an important intermediate in the fixation of carbon dioxide by plants.
00:58:28 This compound is a very unstable substance, and its availability has limited certain kinds
00:58:34 of studies in this important enzymatic system.
00:58:40 The process shown is one involving several steps with coordinated cofactor regeneration.
00:58:49 The initial conversion of glucose to glucose 6-phosphate requires ATP regeneration.
00:58:55 The oxidation of glucose 6-phosphate at C1 can be accomplished using bromine, but it
00:59:03 can also be accomplished using a nicotinamide cofactor and cofactor regeneration.
00:59:09 The oxidation of 6-phosphogluconic acid at C3 and decarboxylation to give ribulose 5-phosphate
00:59:20 requires another cycle of nicotinamide cofactor regeneration.
00:59:24 And the final step, the conversion of ribulose 5-phosphate to ribulose diphosphate, is again
00:59:31 ATP requiring.
00:59:33 Hence, overall, this is a process that requires four cofactor regeneration cycles to work
00:59:41 at the same time.
00:59:43 Let me conclude by making several remarks about the capabilities and future application
00:59:51 of enzymes.
00:59:54 Enzymes have not been commonly used in organic synthesis because they have not been readily
00:59:58 available and because many of the important targets, steroids, terpenes, and related compounds
01:00:05 are much better made using other methods.
01:00:08 As chemistry turns increasingly to products that are water-soluble, nucleic acids, peptides,
01:00:17 sugars, or to processes in which environmental impact is crucial, enzymes have a unique role
01:00:25 to play.
01:00:27 The availability of enzymes is no longer an issue.
01:00:31 It is possible to make almost any enzyme that one wants given sufficient effort by recombinant
01:00:37 techniques.
01:00:39 There are, however, a substantial number of technologies which must be learned in order
01:00:45 to use these enzymes effectively as catalysts in organic synthetic procedures.
01:00:51 I propose that the future of organic synthesis will require a substantially larger investment
01:00:59 in the technology of enzymology and in other applications involving biological catalysts
01:01:07 perhaps used or generated in situ.
01:01:11 The opportunities for chemists who understand how to use these classes of biological candidates
01:01:18 in real processes is enormous.
01:01:22 Thank you, gentlemen.
01:01:23 Our telephone lines are again open, so hop to it.
01:01:26 Go to your phones and give us a call.
01:01:27 The telephone numbers are 800-368-5781 and 5782 or in the Washington, D.C. area, 202-463-3170.
01:01:37 We have about 25 minutes to take your calls, so get them in now because we have this captive
01:01:42 audience of fine chemists here who are happy to answer your questions.
01:01:46 Now, if you get a busy signal, please hang up and try again.
01:01:49 Okay?
01:01:50 Now is the time to call.
01:01:51 You got those numbers in front of me or they should be all over me somewhere another year.
01:01:55 We have a question here which we could plumb the depths of probably for a long time to
01:01:59 speculate on it, but I'm going to throw it out to each of you, and I'd like each of you
01:02:02 to answer it in turn shortly if you can.
01:02:05 And that is, what is the future of non-biological versus biological catalysis?
01:02:11 In 25,000 words or less, right?
01:02:14 Who should start?
01:02:15 Okay, let's do it clockwise.
01:02:16 We'll go with Peter.
01:02:17 You go ahead.
01:02:18 Well, I don't think it's an issue of biological versus a biological.
01:02:22 I think it's an issue of what's the best approach for the specific transformation one's interested in.
01:02:28 If you're talking about a general reaction for small molecules and epoxidation that's
01:02:32 applicable to a wide class of substrates, then I think you want to go with an a-biological catalyst.
01:02:39 If you're looking at a large molecule and you want to do a transformation on a specific piece of it,
01:02:45 if you're going to selectively recognize a large molecule with many functional groups,
01:02:49 you're almost compelled to use a larger molecule such as protein to achieve that degree of recognition.
01:02:55 So I think what's going to happen is there's going to become an increasing appreciation
01:02:59 of what a-biological catalysis is good for and what biological catalysis is not.
01:03:04 So they're not necessarily at odds with one another.
01:03:06 No, they're complementary.
01:03:07 They're just how they use one another.
01:03:08 Yes, George.
01:03:09 There is going to be one place in which there is a real competition,
01:03:12 and that is in the area of biologically useful processes which have low environmental impact.
01:03:19 There are going to be many reactions, I believe,
01:03:21 in which the biological process enzyme catalyzed or catalytic monoclonal or whatever may actually be more expensive.
01:03:28 But in which environmental constraints will force an effort to remove organic solvents,
01:03:33 to limit byproducts, and to do related kinds of downstream optimization to lower overall systems cost.
01:03:41 So I think there may emerge a regulated aspect to this kind of catalysis
01:03:46 which may not make direct sense economically but which has value
01:03:49 because if you look at the overall relations with the community,
01:03:53 the impact on the environment, waste, purification cost,
01:03:57 where it might be simpler to use and less expensive to use a biological catalyst
01:04:01 than a non-biological catalyst in directly competitive reactions.
01:04:05 Okay. Do you disagree, though, with his basic theory?
01:04:08 Aside from the-
01:04:09 I absolutely agree with what he says.
01:04:11 It's just a question of how one does the calculation.
01:04:14 All right. Okay. Barry Sharpless?
01:04:16 Okay. I agree with my two colleagues here.
01:04:20 A bad sign.
01:04:22 But I guess the thing that George brought up earlier about water being such a friendly thing for life on this planet,
01:04:30 the more we're forced to use things like water,
01:04:33 the more than the enzyme approach to doing even the small molecule transformations
01:04:38 that Peter said were probably good candidates for a biological catalyst
01:04:42 will start to be more efficient with the enzymes.
01:04:47 But I guess there is a real problem right now.
01:04:50 If we're going to use water as a solvent, we do have a lot of reactions in organic chemistry
01:04:55 which are going to have to be totally revamped, and it's hard to see how we can do that.
01:04:59 So on the timescale of the next 30, 40 years, it's hard to imagine we're not going to be doing a lot of organic chemistry
01:05:07 and organic solvents.
01:05:09 But I do think right now the technologies are complementary because, for example,
01:05:14 Chi-Wei Wang's example I gave in my lecture where the alvalase chemistry, well, you started that.
01:05:20 And there is a case where the sugars are really, really beautifully handled.
01:05:25 It's hard to imagine any non-enzyme catalyst that could deal with that.
01:05:28 And so right now I see a clear advantage in that system, and the sugar area is huge and growing.
01:05:34 But I guess I like to think that we can do the propylene oxide with a non-enzyme catalyst.
01:05:40 Okay. Barry Trost?
01:05:42 I would tend to agree very much with the comments that have been made.
01:05:45 I think that Peter's comments regarding what are some of the special aspects of biological catalysis
01:05:53 are ones where we will see an ever-growing importance of the use of these things in a practical sense.
01:05:59 I also agree that the issue of environmental concerns is going to grow,
01:06:03 and in that sense both biological and abiological catalysis have a role to play,
01:06:09 especially from the point of view of trying to develop reactions where potentially
01:06:16 you could have the feature that the only thing that will be generated is the product and nothing else.
01:06:22 And that's one of the nice things that could come out of trying to invent some reactions
01:06:27 which will most likely be, at least in the future that I see,
01:06:31 probably going to be abiologically developed rather than biologically developed.
01:06:35 Okay, good. Some good comments there.
01:06:37 Once again, let me exhort you to call 800-368-5781 or 5782
01:06:42 in the Metropolitan, Washington, D.C. area, 202-463-3170.
01:06:47 Our first call is from South Seattle Community College in Seattle, Washington.
01:06:51 Go ahead, please.
01:06:53 Yes, I have questions for all four gentlemen.
01:06:56 Okay.
01:06:57 The first question is for the two Barrys.
01:07:00 At what point does it become practical to recycle used metal catalysts,
01:07:05 such as palladium, probably less so osmium, on a research scale?
01:07:10 And, for example, what does the Trost Group do?
01:07:14 Should I go on to the other questions?
01:07:16 No, hold up on them, and we'll get this out of the way.
01:07:18 Then we'll come back with the other ones. Go ahead.
01:07:21 On a research scale, especially the kind of research scale that we operate at,
01:07:25 the amounts of palladium are sufficiently small
01:07:28 that it doesn't make sense for us to involve ourselves in the actual recycling process.
01:07:34 So we would work with one of the major processors of palladium
01:07:39 and simply send them the spent waste, and they would then recycle the metal itself.
01:07:44 So we don't involve ourselves in it.
01:07:46 The methodology, the technology for recycling palladium is well worked out,
01:07:51 and it's something that can be done on a very large scale, if desirable,
01:07:54 but on a research, especially an academic research scale,
01:07:57 you rely on the commercial vendors, and you just send them the spent waste.
01:08:01 Okay. Was that same question for Barry Sharpless, too, or do you have a separate one for him?
01:08:05 Same question.
01:08:07 Okay.
01:08:08 The osmium catalyst is used in a very low amount, or can be.
01:08:13 One part in 50,000 is enough if you're going to be patient,
01:08:17 so you don't have too much in there.
01:08:19 But normally we use 0.2 percent in the lab, and sometimes 1 percent if we really want a fast reaction.
01:08:25 And we don't recover the osmium in small amounts,
01:08:30 but back 10, 15 years ago we worked with osmium stoichiometrically,
01:08:34 and we used to go through 200, 300 grams over a couple-year period,
01:08:39 and that we kept because there was a lot of osmium there,
01:08:42 and we gave it to a friend who was an osmium inorganic, organic metallic chemist,
01:08:47 and she recovered it in the traditional way, just oxidized with bleach and steamed to still.
01:08:52 And it's really an easy element to keep track of.
01:08:55 It's a little bit too volatile for some people's likes.
01:08:59 All right. Seattle, your questions for Peter and George. Go ahead, please.
01:09:03 Okay. For Professor Whitesides, you showed a pH controller there.
01:09:09 Can you tell us a little bit more about which of these enzymatic processes require such automatic control
01:09:15 and what it would cost for a small lab to set up such an apparatus?
01:09:20 Whenever the process is producing an acid or a base, in general, one has to have pH control.
01:09:26 A simple pH controller is a few hundred dollars.
01:09:29 They're quite inexpensive.
01:09:31 But if that's something which you don't want to do,
01:09:34 then we often simply run reactions by adding a little bit of an indicator
01:09:38 and dripping an acid and base from a burette.
01:09:41 It's not a very complicated issue.
01:09:43 The enzymes will tolerate a few pH units in swing with some loss in kinetic activity but no long-term damage.
01:09:50 So it's not a critical issue in most cases to keep track of the pH.
01:09:54 Okay.
01:09:56 Okay. Last question for Professor Schultz.
01:09:59 Could you just give us some idea of what kind of resources and time are needed
01:10:04 to do the kinds of catalytic antibody research that you do?
01:10:09 To do what we do, right now we do everything with hybridoma technology to produce the monoclonal antibodies.
01:10:15 So one has to synthesize the haptens, so you need a conventional organic chemistry lab,
01:10:20 and then one needs a cell culture facility and some animals to make the hybridomas.
01:10:26 That whole process takes about four months from start to finish,
01:10:30 and one has to be experienced in cell culture technique.
01:10:34 Currently there are recombinant methods coming online to produce these libraries of antibody monoclonal antibodies,
01:10:41 and once the system is working well, right now the levels of expression aren't quite what they have to be
01:10:48 to make this an everyday technique.
01:10:52 But once the expression levels get a little higher,
01:10:54 then all one has to do is be able to pour an agar plate and grow bacteria,
01:10:58 so you need a 37-degree room and an incubator, something like that, and that's it,
01:11:02 in addition to your own organic chemistry lab.
01:11:05 Okay, thank you. A caller from Seattle.
01:11:07 You've taken up our questions here from all the guys here.
01:11:11 Now we go back to Atlanta, Georgia, to the ACS local section in Georgia.
01:11:15 Go ahead, please.
01:11:17 The question is for Professor Whiteside.
01:11:21 Considering the important aspects of the cost of enzymes in enzymatic processes,
01:11:27 my question is what is your opinion of the current experimentation of use of enzymes in organic solvents?
01:11:34 There are places where enzymes are certainly valuable in what I will call mixed organic aqueous media.
01:11:41 I think there's no such thing as an enzyme that works in truly non-aqueous solution.
01:11:47 The non-aqueous enzymology, so-called, is enzymology that's carried out in an organic solvent
01:11:54 that contains enough water to coat the protein with a hydration shell or a number of layers of water.
01:12:01 But those are great media for certain types of reactions that involve, let's say, transesterification or dehydrations
01:12:08 or types of reactions in which one wants to manipulate the thermodynamic activity of water in the system.
01:12:14 I think there's no doubt that they're useful.
01:12:16 One has to be a little careful at this point about taking some of the information that's in the literature
01:12:22 about activities in non-aqueous solvents and really trying to use them in practical organic synthesis
01:12:27 because it turns out that some of those processes are more complicated
01:12:32 and the rates are lower than you can read from the literature.
01:12:35 But they're interesting. Just be a little cautious in getting into that kind of work.
01:12:39 All right. Our next call is from the South Texas local section ACS in Corpus Christi. Go ahead, please.
01:12:46 This is to Sharpless.
01:12:49 I was wondering whether sulfonamide is helping to increase the turnover number.
01:12:53 Is there any precedence in the literature or any rationale for using this?
01:13:03 That is actually described briefly in our publication in JOC, the most recent one,
01:13:11 where we had the thalazine ligands and also the sulfonamide improvement.
01:13:15 And the sulfonamide, it can be an aromatic sulfonamide or methyl sulfonamide
01:13:20 just happens to be one of the ones that work as well as any.
01:13:23 And what it does is it makes the anion in the carbonate phase, gets the sulfonamide anion,
01:13:28 it travels presumably to the interface or slightly into someplace near the interface
01:13:32 and helps to strip the glycol off the osmium.
01:13:35 That can be a slow step with many of these glycolates.
01:13:38 They're just too hindered and the osmium all hangs up at the osmate ester stage in those cases.
01:13:44 Normal olefins like styrene don't do that, so they're turning over at the rate of addition,
01:13:49 but the others need some help.
01:13:51 So we hydrolyte, we found this trick of adding sulfonamide,
01:13:55 and the idea came from earlier work we had done where we took hydroxide and phase transferred it,
01:14:00 but we couldn't do that here for various reasons because we phase transferred the oxidant.
01:14:04 And we had to transfer the anion by another means, which was to make it more lipophilic,
01:14:10 and that seems to work well.
01:14:12 It may not be the final solution, but it really makes it go up to 50 or 100 times faster than without it.
01:14:18 All right.
01:14:19 Our next call is from the King of Prussia, Pennsylvania, and SmithKline, Beecham.
01:14:23 Go ahead, please.
01:14:24 This is for Dr. Schultz.
01:14:25 What is your experience with mixed organic solvents and catalytic antibodies?
01:14:30 We've only done one experiment ourselves with reverse micelles,
01:14:36 and it was a hydrolytic reaction of an ester, and that worked very well.
01:14:41 Richard Lerner's group has done some work with putting these on solid supports
01:14:46 and trying to run these reactions with high percentages of organic solvents,
01:14:52 and those have actually worked quite well, too.
01:14:55 We've recently collaborated with a chemical engineering group
01:14:58 who has put these catalytic antibodies onto solid support,
01:15:01 and they've done a variety of biophysical measurements
01:15:04 to show that actually the active site is not perturbed at all
01:15:08 and the antibodies retain their full level of function.
01:15:12 All right.
01:15:13 Our next call is from the University of Wisconsin in Milwaukee.
01:15:16 Go ahead, please.
01:15:17 Hello.
01:15:18 I have two questions, one for the white slide, Professor, and one for Dr. Schultz.
01:15:23 I'll start with Professor George's white slide, please.
01:15:27 We understand the basic understanding of a reaction is important
01:15:31 to improve the method of scientific application.
01:15:36 So what about enzyme?
01:15:37 You can give any insight, understanding of the mechanism,
01:15:41 how it is giving a kind of asymmetric induction, something like that?
01:15:47 It's a very good question.
01:15:48 I think that one of the advantages to enzymology
01:15:51 is that in terms of a well-defined catalytic site,
01:15:55 you probably have as much information in an enzyme as you do in any catalyst
01:15:59 that we can work with, so that there are real opportunities with enzymology
01:16:03 to measure mechanisms, to measure kinetic constants,
01:16:06 and to use that information in designing the optimum conditions
01:16:10 for the enzymatic process.
01:16:13 In some of the other kinds of reactions that one works with,
01:16:16 for example, some of Barry's titanium or osmium catalyzed systems,
01:16:20 although the molecules are smaller,
01:16:22 the catalytic systems I think in some ways are actually more complicated.
01:16:26 So one of the keys in using enzymology is, in fact,
01:16:29 to take advantage of the mechanistic information
01:16:32 and the kinetic information that is relatively readily available.
01:16:36 All right.
01:16:37 My next question is for Barry Sharpless.
01:16:40 I know that you are working with designing a new catalyst with titanium.
01:16:45 You haven't talked about that in this presentation.
01:16:48 Do you have anything to add with that respect?
01:16:51 A new catalyst with titanium?
01:16:54 No, designing a new catalyst on the basis of your results
01:16:59 with your successful results with titanium catalyst.
01:17:04 Well, we're always screening for new reactions with metals and ligands these days,
01:17:09 but currently we don't have anything happening at all in the lab with titanium.
01:17:16 It would be better to improve that catalyst.
01:17:18 The catalyst is inadequate in its turnovers.
01:17:21 It's turned over 20 times, and that's not enough for a really good catalyst,
01:17:25 and we'd like to have some way of getting that system to turn over better.
01:17:30 The problem with it is it produces its own toxins.
01:17:33 It's one of the epoxy alcohols or suicide substrates for the catalyst.
01:17:38 The catalyst is very active in the first few seconds or minutes,
01:17:41 and it's dying constantly, and it doesn't help to add more catalyst
01:17:44 because there's something deadly produced in there
01:17:47 that just nails the catalyst faster than anything you can do to compensate.
01:17:51 So if anybody can improve this catalyst system,
01:17:55 they'd have a nice contribution to this process.
01:17:58 All right, there's your quest out there.
01:18:00 You can be famous, right?
01:18:02 All right, we'll go to St. Louis now, University of Missouri.
01:18:05 Yes, my question goes to all four gentlemen there.
01:18:09 For the design of non-biologic catalysts and empirical lures
01:18:13 to keep ligands to be C2 symmetry,
01:18:16 the enzyme or natural peptides, they usually don't have a C2 symmetry.
01:18:20 So according to you, why we need this C2 symmetry ligand
01:18:24 in making a good catalyst?
01:18:26 Do we really need it?
01:18:28 Okay.
01:18:30 Go ahead.
01:18:31 I've thought about this myself quite a bit
01:18:33 because the first C2 ligand ever made intentionally and used
01:18:38 in beautiful work and very original was by Henri Cagan-Diop,
01:18:43 is today still a very dominant concept in design.
01:18:48 Noyori's BINAP and Diop, BINAP.
01:18:52 The tartrate system is C2.
01:18:54 And I think that these things are coincidence to some extent.
01:18:58 C2 does simplify the mechanism, so you have a better chance of winning.
01:19:02 But let's face it, nature's catalysts are almost all C1
01:19:05 unless you have a dimeric subunit.
01:19:07 And the new osmium catalyst is C1, completely C1.
01:19:12 That system.
01:19:13 So I think there's more probability that you'll see more C1 systems
01:19:17 in the end than C2 or C3 or C4.
01:19:21 Okay.
01:19:22 That was directed to any and all.
01:19:23 Anybody else have a follow-up comment on that?
01:19:25 I would agree with Barry that a major component
01:19:28 in the early evolution of C2 catalyst was simply the fact
01:19:33 that if you're going to put two of something on that's asymmetric,
01:19:36 it's easy to do in the C2 system.
01:19:38 So there's an element of coincidence, simplicity,
01:19:41 and ease of synthesis that have come into those.
01:19:43 They're not necessarily deeply appropriate for these kinds of problems,
01:19:47 but they do work.
01:19:49 Okay.
01:19:50 Just a follow-up.
01:19:51 Obviously, in the enzymatic system, you're creating a chiral space
01:19:53 which is much, much larger than you are doing in a simple,
01:19:57 let's say, non-enzymatic-type reaction.
01:19:59 And so you're trying to simplify the chiral environment,
01:20:03 this much smaller chiral environment,
01:20:05 so that it is less ambiguous in the way that the substrate is going to dock
01:20:10 onto the metal.
01:20:12 Obviously, to the extent that you would build larger chiral space
01:20:15 in non-biological methods,
01:20:17 you would also have the opportunities for much more expansive types of molecules,
01:20:23 and C2 symmetry is not going to be a prerequisite.
01:20:26 All right.
01:20:28 We go now to Virginia Commonwealth University in Richmond
01:20:31 for our next question.
01:20:32 Go ahead, please.
01:20:33 Yeah, my question is to Barry Sharpless.
01:20:36 In your asymmetric dehydroxylation,
01:20:39 you have used osmium tetroxide and dihydroquinidine ligand.
01:20:43 Now my question is,
01:20:45 have you carried out this reaction using ruthenium tetroxide or any such compound?
01:20:51 And if so, what was the enantiomeric excess obtained?
01:20:55 Yes, we tried with ruthenium tetroxide.
01:20:58 The usual thing that we try to do is we screen around that part of the periodic table
01:21:02 where the catalyst metal shows its best activity
01:21:05 just to make sure we haven't missed something.
01:21:07 With ruthenium tetroxide, of course,
01:21:09 you have to accept the fact that it's going to cleave right through the double bond.
01:21:12 So we tried kinetic resolutions of chiral olefins in the presence of the alkaloid.
01:21:18 But frankly, I think the problem is that there the redox potential is so great
01:21:23 that it just oxidizes the quinucleidine nitrogen to the N-oxide
01:21:29 and it destroys the ligand as a potential ligand for the D0 ruthenium.
01:21:36 So you don't see any induction, or at least we don't see any induction.
01:21:40 We don't know if that's the explanation.
01:21:42 But there's technetium oxo's which work well.
01:21:45 Alan Davison's shown that.
01:21:47 You can make glycolates with those.
01:21:49 And that could be an interesting system because it has different geometry and ligands,
01:21:53 although people might not like working with technetium if they had a choice.
01:21:57 Then rhenium is showing some interesting reactions from several labs that are unpublished right now.
01:22:03 But osmium, unfortunately, is really the star element here for doing this hydroxylation chemistry.
01:22:11 And I think we're stuck with that unless there's a real surprise out there that I'm not betting on.
01:22:17 Okay, you have only a few more minutes now to get your call in.
01:22:20 So now's the time to do it.
01:22:21 800-368-5781 or 5782 in the D.C. area.
01:22:26 202-463-3170.
01:22:29 Our next question is from Allegheny College in Needville, Pennsylvania.
01:22:33 Go ahead, please.
01:22:34 Yes.
01:22:35 My question is for Peter Schultz.
01:22:38 As an organic chemist, if I designed what I think is a molecule for a transition state,
01:22:46 do you see in the future that we could send this away to be custom made for these antibodies?
01:22:55 Or will a wide variety of them be available?
01:23:00 If you have a transition state analog, I think in the near future it's going to be fairly straightforward
01:23:05 for you to make the monoclonal yourself if that's what you're asking about.
01:23:10 Right now there's a huge gap between,
01:23:12 and there's historically been a large gap between chemistry and immunology
01:23:16 because of the language barriers between the two fields.
01:23:19 But hybrid ELMA methods aren't that hard to learn.
01:23:23 They need special facilities that are available in any biology department.
01:23:28 Pretty soon the whole idea behind these phage displays of antibodies and so forth and so on
01:23:35 is to basically put the whole immune system of a mouse into a small test tube
01:23:40 that any lab can use for very low cost.
01:23:44 I think that technology is probably three years away
01:23:48 from perhaps replacing a lot of conventional hybrid ELMA methodology.
01:23:52 We have time for one more question, and I'll direct this to George Whitesides.
01:23:56 Is chiral synthesis really important in organic or pharmaceutical synthesis, and if so, why?
01:24:02 The argument for chiral synthesis I think is now overwhelming,
01:24:06 which is that the FDA is increasingly insisting on the testing and production of chirally pure compounds.
01:24:16 So I think all technology, whether it's biological or abiological,
01:24:20 that leads to improved methods of making chiral pieces
01:24:23 to go into the primary consumer of chiral pieces,
01:24:26 which is the pharmaceutical and the agricultural industries, is clearly going to be useful.
01:24:31 Okay, good. Before we close, we have some final comments right now
01:24:34 from Barry Trost, who organized this wonderful event today. Barry?
01:24:38 I'd like to say that we are trying to present to you the overview of what catalysis can do,
01:24:46 not from the point of view that we're discussing competition,
01:24:49 but from the point of view that these offer opportunities that are going to be complementary.
01:24:53 I really would like to take this opportunity of thanking publicly George Whitesides,
01:24:58 Peter Schultz, and Barry Sharpless in taking the amount of time
01:25:02 that all of us had to do to present both the tape and the live session here.
01:25:09 So to these three gentlemen, I am very thankful,
01:25:11 and I hope that you all have found this a useful session.
01:25:14 Thank you very much, Dr. Trost.
01:25:16 Well, we've come to the end of today's program,
01:25:18 the 10th American Chemical Society Satellite Television Seminar.
01:25:21 And thanks to our speakers, Peter Schultz, Barry Sharpless, George Whitesides,
01:25:25 for making this an interesting and informative program.
01:25:28 And a special thanks again to Barry Trost for organizing the program.
01:25:32 On behalf of the American Chemical Society Continuing Education Department,
01:25:35 I want to thank all of you for joining us today, too.
01:25:38 So please don't forget to complete and return your seminar evaluation forms.
01:25:42 We need your comments and suggestions.
01:25:44 Let us know if there are any particular topics that you'd like us to cover in future programs.
01:25:48 Our next program is on March 16, 1993,
01:25:52 on molecular modeling and the discovery of new drugs.
01:25:56 Please call the ACS Continuing Education Department for details.
01:25:59 Until then, I am Paul Anthony.
01:26:01 Have a very good day, and thank you.