A highly convergent synthesis of myristoyl-carba(dethia)-coenzyme A.

Co-translational myristoylation of the N-terminal glycine residue of diverse signaling proteins is required for membrane attachment and proper function of these molecules. The transfer of myristate from myristoyl-coenzyme A (myr-CoA) is catalyzed by the enzyme N-myristoyltransferase (Nmt). Nmt has been implicated in a number of human diseases, including cancer and epilepsy, as well as pathogenic mechanisms such as fungal and virus infections, including HIV and Hepatitis B. Rational design has led to the development of potent competitive inhibitors, including several non-hydrolysable acyl-CoA substrate analogues. However, linear synthetic strategies, following the route of the original CoA synthesis, generate such analogues in very low over all yields that typically are not sufficient for in vivo studies. Here, we present a new, highly convergent synthesis of myristoyl-carba(dethia)-coenzyme A 1 that allows to obtain this substrate analogue in 11-fold increased yield compared to the reported linear synthesis. In addition, enzymatic cleavage of the adenosine-2',3'-cyclophosphate in the last step of the synthesis proved to be an efficient way to obtain the isomerically pure 3'-phosphate 1.

But-3-ene-1,2-diol: a mechanism-based active site inhibitor for coenzyme B12-dependent glycerol dehydratase.

Coenzyme B(12)-dependent glycerol dehydratase is a radical enzyme that catalyses the conversion of glycerol into 3-hydroxypropanal and propane-1,2-diol into propanal via enzyme-bound intermediate radicals. The substrate analogue but-3-ene-1,2-diol was studied in the expectation that it would lead to the 4,4-dihydroxylbut-2-en-1-yl radical, which is stabilised (allylic) and not reactive enough to retrieve a hydrogen atom from 5'-deoxyadenosine, thereby interrupting the catalytic cycle. Racemic and enantiomerically pure but-3-ene-1,2-diols and their [1,1-(2)H(2)], [2-(2)H] and [4,4-(2)H(2)] isotopomers were synthesised and characterised by NMR spectroscopy. (S)-[4-(14)C]but-3-ene-1,2-diol was also prepared. Kinetic measurements showed but-3-ene-1,2-diol to be a competitive inhibitor of glycerol dehydratase (K(i)=0.21 mM, k(i)=5.0x10(-2) s(-1)). With [4-(14)C]but-3-ene-1,2-diol it was demonstrated that species derived from the diol become tightly bound to the enzyme's active site, but not covalently bound, because the radioactivity could be removed upon denaturation of the enzyme. EPR measurements with propane-1,2-diol as substrate generated sharp signals after 10 s that disappeared after about 1 min. In contrast, EPR resonances appeared and disappeared more slowly when but-3-ene-1,2-diol was incubated with the enzyme. Among the deuterated isotopomers, only [1,1-(2)H(2)]but-3-ene-1,2-diol showed a significantly different EPR spectrum from that of the unlabelled diol; this indicated that coupling between the unpaired electron and a deuterium at C-1 was stronger than with deuterium at C-2 or C-4. The experiments suggest the formation of the 1,2-dihydroxybut-3-en-1-yl radical, which decomposes to unidentified product(s).

The putative coenzyme B12-dependent methylmalonyl-CoA mutase from potatoes is a phosphatase.

The reported presence of a coenzyme B12-dependent methylmalonyl-CoA mutase in potatoes has been reexamined. The enzyme converting methylmalonyl-CoA was purified to electrophoretic homogeneity. Examination of the reaction product by 1H, 31P NMR and mass spectrometry revealed that it was methylmalonyl-3'-dephospho-CoA. The phosphatase enzyme needs neither coenzyme B12 nor S-adenosylmethionine as a cofactor.

The essential tyrosine-containing loop conformation and the role of the C-terminal multi-helix region in eukaryotic phenylalanine ammonia-lyases.

Besides the post-translationally cyclizing catalytic Ala-Ser-Gly triad, Tyr110 and its equivalents are of the most conserved residues in the active site of phenylalanine ammonia-lyase (PAL, EC 4.3.1.5), histidine ammonia-lyase (HAL, EC 4.3.1.3) and other related enzymes. The Tyr110Phe mutation results in the most pronounced inactivation of PAL indicating the importance of this residue. The recently published X-ray structures of PAL revealed that the Tyr110-loop was either missing (for Rhodospridium toruloides) or far from the active site (for Petroselinum crispum). In bacterial HAL ( approximately 500 amino acids) and plant and fungal PALs ( approximately 710 amino acids), a core PAL/HAL domain ( approximately 480 amino acids) with >or= 30% sequence identity along the different species is common. In plant and fungal PAL a approximately 100-residue long C-terminal multi-helix domain is present. The ancestor bacterial HAL is thermostable and, in all of its known X-ray structures, a Tyr83-loop-in arrangement has been found. Based on the HAL structures, a Tyr110-loop-in conformation of the P. crispum PAL structure was constructed by partial homology modeling, and the static and dynamic behavior of the loop-in/loop-out structures were compared. To study the role of the C-terminal multi-helix domain, Tyr-loop-in/loop-out model structures of two bacterial PALs (Streptomyces maritimus, 523 amino acids and Photorhabdus luminescens, 532 amino acids) lacking this C-terminal domain were also built. Molecular dynamics studies indicated that the Tyr-loop-in conformation was more rigid without the C-terminal multi-helix domain. On this basis it is hypothesized that a role of this C-terminal extension is to decrease the lifetime of eukaryotic PAL by destabilization, which might be important for the rapid responses in the regulation of phenylpropanoid biosynthesis.

Inhibition of histidine ammonia lyase by heteroaryl-alanines and acrylates.

Histidine ammonia lyase (HAL) catalyzes the elimination of ammonia from the substrate to form (E)-urocanate. The interaction between HAL and acrylic acids or alanines substituted with heteroaryl groups in the beta-position was investigated. These proved to be strong competitive inhibitors when the heteroaryl groups were furanyl, thiophenyl, benzofuranyl, and benzothiophenyl, carrying the alanyl or acrylic side chains either in 2 or 3 positions, with K(i) values between 18 and 139 microM. The exception was (furan-3-yl)alanine which was found to be inert. Tryptophan and 1-methyltryptophan, as well as the corresponding acrylates (=prop-2-enoates), are strong mixed inhibitors of HAL. Theoretically, L-histidine can be dissected into 4-methyl-1H-imidazole and glycine. Whereas these two compounds separately are only very weak inhibitors of HAL, equimolar amounts of both show a K(i) value of 1.7+/-0.09 mM which is to be compared with the K(m) value of 15.6 mM for the normal reaction. We conclude that 5-methyl-1H-imidazole and glycine mimic the substrate and occupy the active site of HAL in a similar orientation.

Discovery and role of methylidene imidazolone, a highly electrophilic prosthetic group.

The elimination of ammonia from alpha-amino acids is a chemically difficult process. While the non-acidic beta-proton has to be abstracted, the much more acidic ammonium protons must remain untouched to maintain the leaving group ability of this positively charged group. Histidine and phenylalanine ammonia-lyases (HAL and PAL) possess a catalytically essential electrophilic group which has been believed to be dehydroalanine for 30 years. Recently, the X-ray structure of HAL has been solved. The electron density was not consistent with dehydroalanine but showed the presence of methylidene imidazolone (MIO) instead. The high electrophilicity of this prosthetic group as well as the geometry at the active site support a previously proposed mechanism involving a Friedel-Crafts-type attack at the aromatic ring of the substrate. Further biochemical evidence for this unprecedented electrophile-assisted ammonia elimination is also presented. Although no X-ray structure of PAL has been published as yet, spectrophotometrical evidence for the presence of MIO has been provided. Finally, a chemical model for the PAL reaction is described.

Friedel-Crafts-type mechanism for the enzymatic elimination of ammonia from histidine and phenylalanine.

The surprisingly high catalytic activity and selectivity of enzymes stem from their ability to both accelerate the target reaction and suppress competitive reaction pathways that may even be dominant in the absence of enzymes. For example, histidine and phenylalanine ammonia-lyases (HAL and PAL) trigger the abstraction of the nonacidic beta protons of these amino acids while leaving the much more acidic ammonium hydrogen atoms untouched. Both ammonia-lyases have a catalytically important electrophilic group, which was believed to be dehydroalanine for 30 years but has now been revealed by X-ray crystallography and UV spectroscopy to be a highly electrophilic 5-methylene-3,5-dihydroimidazol-4-one (MIO) group. Experiments suggest that the reaction is initiated by the electrophilic attack of MIO on the aromatic ring of the substrate. This incomplete Friedel-Crafts-type reaction leads to the activation of a beta proton and its stereospecific abstraction, followed by the elimination of ammonia and regeneration of the MIO group. The plausibility of such a mechanism is supported by a synthetic model. The application of the PAL reaction in the biocatalytic synthesis of enantiomerically pure alpha-amino beta-aryl propionates from aryl acrylates is also discussed.

Structure and action of urocanase.

Urocanase (EC 4.2.1.49) from Pseudomonas putida was crystallized after removing one of the seven free thiol groups. The crystal structure was solved by multiwavelength anomalous diffraction (MAD) using a seleno-methionine derivative and then refined at 1.14 A resolution. The enzyme is a symmetric homodimer of 2 x 557 amino acid residues with tightly bound NAD+ cofactors. Each subunit consists of a typical NAD-binding domain inserted into a larger core domain that forms the dimer interface. The core domain has a novel chain fold and accommodates the substrate urocanate in a surface depression. The NAD domain sits like a lid on the core domain depression and points with the nicotinamide group to the substrate. Substrate, nicotinamide and five water molecules are completely sequestered in a cavity. Most likely, one of these water molecules hydrates the substrate during catalysis. This cavity has to open for substrate passage, which probably means lifting the NAD domain. The observed atomic arrangement at the active center gives rise to a detailed proposal for the catalytic mechanism that is consistent with published chemical data. As expected, the variability of the residues involved is low, as derived from a family of 58 proteins annotated as urocanases in the data banks. However, one well-embedded member of this family showed a significant deviation at the active center indicating an incorrect annotation.

Kinetic analysis of the reactions catalyzed by histidine and phenylalanine ammonia lyases.

Although both the structures and the reactions of histidine and phenylalanine ammonia lyases (HAL and PAL) are very similar, the former shows a primary kinetic deuterium (D) isotope effect, while the latter does not. In the HAL reaction, the release of ammonia is partially rate-determining and is slower than the release of the product (E)-urocanate (4), whereas in the PAL reaction, the release of (E)-cinnamate (2) is the rate-limiting step. With (2S,3S)-[3-(2)H1]phenylalanine (1a), we determined the kinetic D isotope effects with the PAL mutants Q487A, Y350F, L137 H, and the double mutant L137 H/Q487E. The kH/kD values for the former two were of the same magnitude as with wild-type PAL (1.20+/-0.07), while the exchange of L137 to H almost doubled the effect (kH/kD=2.32+/-0.01). We conclude that L137 is part of the hydrophobic pocket harboring the phenyl group of the substrate/product and is responsible for its strong binding. The stability of the HAL ammonia complex was demonstrated 40 years ago. Here, we show that, in contrast to the former assumption, ammonia in the complex is not covalently bound to the prosthetic electrophile, 3,5-dihydro-5-methylidene-4H-imidazol-4-one (MIO; 5). We carried out experiments with a mutant enzyme lacking MIO and exhibiting ca. 10(3) times less activity. Nevertheless, the enzyme-ammonia complex was formed, and the mutant behaved upon addition of (E)-[14C]urocanate (4a) like wild-type HAL. We conclude, therefore, that ammonia is bound in the complex by Coulomb forces as ammonium ion and can be released only after (E)-urocanate (4).

Synthesis and In Vitro Evaluation of the Ras Farnesyltransferase Inhibitor Pepticinnamin E.

A modularly built bisubstrate inhibitor, the natural product pepticinnamin E (shown on the right) was sythesized for the first time. In the case of in vitro assays it inhibits the enzyme farnesyltransferase with respect to both the peptide substrate and farnesylpyrophosphate (KI = 30 and 8 µM, respectively). The inhibitory activity is decisively influenced by the central tripeptide unit and the absolute configuration of the non-proteinogenic amino acid incorporated therein.

Dioldehydratase Binds Coenzyme B12 in the "Base-On" Mode: ESR Investigations on Cob(II)alamin.

Even in the enzyme-bound state the dimethylbenzimidazole ligand in the dioldehydratase from Salmonella typhimurium remains bound to the cobalt ion in contrast to some coenzyme B12 -dependent enzymes. Direct, ESR spectroscopic proof for this "base-on" binding mode was obtained by using a coenzyme in which one of the nitrogen atoms of the dimethylbenzimidazole ligand was 15 N labeled (see schematic representation on the right).

Ethylmalonyl-CoA mutase from Rhodobacter sphaeroides defines a new subclade of coenzyme B12-dependent acyl-CoA mutases.

Coenzyme B(12)-dependent mutases are radical enzymes that catalyze reversible carbon skeleton rearrangement reactions. Here we describe Rhodobacter sphaeroides ethylmalonyl-CoA mutase (Ecm), a novel member of the family of coenzyme B(12)-dependent acyl-CoA mutases, that operates in the recently discovered ethylmalonyl-CoA pathway for acetate assimilation. Ecm is involved in the central reaction sequence of this novel pathway and catalyzes the transformation of ethylmalonyl-CoA to methylsuccinyl-CoA in combination with a second enzyme that was further identified as promiscuous ethylmalonyl-CoA/methylmalonyl-CoA epimerase. In contrast to the epimerase, Ecm is highly specific for its substrate, ethylmalonyl-CoA, and accepts methylmalonyl-CoA only at 0.2% relative activity. Sequence analysis revealed that Ecm is distinct from (2R)-methylmalonyl-CoA mutase as well as isobutyryl-CoA mutase and defines a new subfamily of coenzyme B(12)-dependent acyl-CoA mutases. In combination with molecular modeling, two signature sequences were identified that presumably contribute to the substrate specificity of these enzymes.

Investigation of the mechanism of action of pyrogallol-phloroglucinol transhydroxylase by using putative intermediates.

Pyrogallol-phloroglucinol transhydroxylase from Pelobacter acidigallici, a molybdopterin-containing enzyme, catalyzes a key reaction in the anaerobic degradation of aromatic compounds. In vitro, the enzymatic reaction requires 1,2,3,5-tetrahydroxybenzene as a cocatalyst and the transhydroxylation occurs without exchange with hydroxy groups from water. To test our previous proposal that the transfer of the hydroxy group occurs via 2,4,6,3',4',5'-hexahydroxydiphenyl ether as an intermediate, we synthesized this compound and investigated its properties. We also describe the synthesis and characterization of 3,4,5,3',4',5'-hexahydroxydiphenyl ether. Both compounds could substitute for the cocatalyst in vitro. This indicates that the diphenyl ethers can intrude into the active site and initiate the catalytic cycle. Recently, the X-ray crystal structure of the transhydroxylase (TH) was published16 and it supports the proposed mechanism of hydroxy-group transfer.

The interaction of heteroaryl-acrylates and alanines with phenylalanine ammonia-lyase from parsley.

Acrylic acids and alanines substituted with heteroaryl groups at the beta-position were synthesized and spectroscopically characterized (UV, HRMS, (1)H NMR, and (13)C NMR spectroscopy). The heteroaryl groups were furanyl, thiophenyl, benzofuranyl, and benzothiophenyl and contained the alanyl side chains either at the 2- or 3-positions. While the former are good substrates for phenylalanine ammonia-lyase (PAL), the latter compounds are inhibitors. Exceptions are thiophen-3-yl-alanine, a moderate substrate and furan-3-yl-alanine, which is inert. Possible reasons for these exceptions are discussed. Starting from racemic heteroaryl-2-alanines their D-enantiomers were prepared by using a stereodestructive procedure. From the heteroaryl-2-acrylates, the L-enantiomers of the heteroaryl-2-alanines were prepared at high ammonia concentration. These results can be best explained by a Friedel-Crafts-type electrophilic attack at the aromatic part of the substrates as the initial step of the PAL reaction.

Structural and functional comparison of HemN to other radical SAM enzymes.

Radical SAM enzymes have only recently been recognized as an ancient family sharing an unusual radical-based reaction mechanism. This late appreciation is due to the extreme oxygen sensitivity of most radical SAM enzymes, making their characterization particularly arduous. Nevertheless, realization that the novel apposition of the established cofactors S-adenosylmethionine and [4Fe-4S] cluster creates an explosive source of catalytic radicals, the appreciation of the sheer size of this previously neglected family, and the rapid succession of three successfully solved crystal structures within a year have ensured that this family has belatedly been noted. In this review, we report the characterization of two enzymes: the established radical SAM enzyme, HemN or oxygen-independent coproporphyrinogen III oxidase from Escherichia coli, and littorine mutase, a presumed radical SAM enzyme, responsible for the conversion of littorine to hyoscyamine in plants. The enzymes are compared to other radical SAM enzymes and in particular the three reported crystal structures from this family, HemN, biotin synthase and MoaA, are discussed.

Synthesis of enantiomerically-pure [13C]aristeromycylcobalamin and its reactivity in dioldehydratase, glyceroldehydratase, ethanolamine ammonia-lyase and methylmalonyl-CoA mutase reactions.

We describe a novel enantioselective synthesis of aristeromycin, the carbocyclic analogue of adenosine. The seven-step synthesis is also suitable for the preparation of specifically-labelled [6'-(13)C]aristeromycin. Both the unlabelled and (13)C-labelled product was coupled to vitamin B(12) to form aristeromycylcobalamin. This carbocyclic analogue of coenzyme B(12) was examined for its coenzymic activity with several adenosylcobalamin-dependent enzymes. For glyceroldehydratase and dioldehydratase, the reaction rate (k(cat)) was 38 and 44 % of that measured with adenosylcobalamin as coenzyme. In contrast, aristeromycylcobalamin showed no detectable activity with methylmalonyl-CoA mutase and ethanolamine ammonia-lyase. Instead, it was a weak inhibitor of the former and a strong inhibitor of the latter enzyme. The slower turnover rate with glyceroldehydratase raised the hope of detecting the 6'-deoxyaristeromycyl radical intermediate. Comparison of the EPR spectra of the intermediates in the glyceroldehydratase reaction, which used adenosyl- and aristeromycylcobalamines, respectively, as coenzyme, revealed a significant shift and this suggests a different geometric position of these cofactors at the binding site during the cleavage of the carbon-cobalt bond. However, we found no evidence for the existence of a 6'-deoxyaristeromycyl radical during the reaction with [6'-(13)C]aristeromycylcobalamin. We conclude that the lifetime of this radical is still too short to be observed.

An active site homology model of phenylalanine ammonia-lyase from Petroselinum crispum.

The plant enzyme phenylalanine ammonia-lyase (PAL, EC 4.3.1.5) shows homology to histidine ammonia-lyase (HAL) whose structure has been solved by X-ray crystallography. Based on amino-acid sequence alignment of the two enzymes, mutagenesis was performed on amino-acid residues that were identical or similar to the active site residues in HAL to gain insight into the importance of this residues in PAL for substrate binding or catalysis. We mutated the following amino-acid residues: S203, R354, Y110, Y351, N260, Q348, F400, Q488 and L138. Determination of the kinetic constants of the overexpressed and purified enzymes revealed that mutagenesis led in each case to diminished activity. Mutants S203A, R354A and Y351F showed a decrease in kcat by factors of 435, 130 and 235, respectively. Mutants F400A, Q488A and L138H showed a 345-, 615- and 14-fold lower kcat, respectively. The greatest loss of activity occurred in the PAL mutants N260A, Q348A and Y110F, which were 2700, 2370 and 75 000 times less active than wild-type PAL. To elucidate the possible function of the mutated amino-acid residues in PAL we built a homology model of PAL based on structural data of HAL and mutagenesis experiments with PAL. The homology model of PAL showed that the active site of PAL resembles the active site of HAL. This allowed us to propose possible roles for the corresponding residues in PAL catalysis.