The 8-amino-7-oxopelargonate synthase from Bacillus sphaericus. Purification and preliminary characterization of the cloned enzyme overproduced in Escherichia coli

Structural and mechanistic investigations on CC bond forming α-oxoamine synthase allowing L-glutamate as substrate

Carbon‑carbon (C-C) bonds serve as the fundamental structural backbone of organic molecules. As a critical CC bond forming enzyme, α-oxoamine synthase is responsible for the synthesis of α-amino ketones by performing the condensation reaction between amino acids and acyl-CoAs. We previously identified an α-oxoamine synthase (AOS), named as Alb29, involved in albogrisin biosynthesis in Streptomyces albogriseolus MGR072. This enzyme belongs to the α-oxoamine synthase family, a subfamily under the pyridoxal 5'-phosphate (PLP) dependent enzyme superfamily. In this study, we report the crystal structures of Alb29 bound to PLP and L-Glu, which provide the atomic-level structural insights into the substrate recognition by Alb29. We discover that Alb29 can catalyze the amino transformation from L-Gln to L-Glu, besides the condensation of L-Glu with β-methylcrotonyl coenzyme A. Subsequent structural analysis has revealed that one flexible loop in Alb29 plays an important role in both amino transformation and condensation. Based on the crystal structure of the S87G mutant in the loop region, we capture two distinct conformations of the flexible loop in the active site, compared with the wild-type Alb29. Our study offers valuable insights into the catalytic mechanism underlying substrate recognition of Alb29.

The Biotin Biosynthetic Pathway in Mycobacterium tuberculosis is a Validated Target for the Development of Antibacterial Agents

Mycobacterium tuberculosis, responsible for Tuberculosis (TB), remains the leading cause of mortality among infectious diseases worldwide from a single infectious agent, with an estimated 1.7 million deaths in 2016. Biotin is an essential cofactor in M. tuberculosis that is required for lipid biosynthesis and gluconeogenesis. M. tuberculosis relies on de novo biotin biosynthesis to obtain this vital cofactor since it cannot scavenge sufficient biotin from a mammalian host. The biotin biosynthetic pathway in M. tuberculosis has been well studied and rigorously genetically validated providing a solid foundation for medicinal chemistry efforts. This review examines the mechanism and structure of the enzymes involved in biotin biosynthesis and ligation, summarizes the reported genetic validation studies of the pathway, and then analyzes the most promising inhibitors and natural products obtained from structure-based drug design and phenotypic screening.

A Canonical Biotin Synthesis Enzyme, 8-Amino-7-Oxononanoate Synthase (BioF), Utilizes Different Acyl Chain Donors in Bacillus subtilis and Escherichia coli

BioF (8-amino-7-oxononanoate synthase) is a strictly conserved enzyme that catalyzes the first step in assembly of the fused heterocyclic rings of biotin. The BioF acyl chain donor has long been thought to be pimeloyl-CoA. Indeed, in vitro the Escherichia coli and Bacillus sphaericus enzymes have been shown to condense pimeloyl-CoA with l-alanine in a pyridoxal 5'-phosphate-dependent reaction with concomitant CoA release and decarboxylation of l-alanine. However, recent in vivo studies of E. coli and Bacillus subtilis suggested that the BioF proteins of the two bacteria could have different specificities for pimelate thioesters in that E. coli BioF may utilize either pimeloyl coenzyme A (CoA) or the pimelate thioester of the acyl carrier protein (ACP) of fatty acid synthesis. In contrast, B. subtilis BioF seemed likely to be specific for pimeloyl-CoA and unable to utilize pimeloyl-ACP. We now report genetic and in vitro data demonstrating that B. subtilis BioF specifically utilizes pimeloyl-CoA.IMPORTANCE Biotin is an essential vitamin required by mammals and birds because, unlike bacteria, plants, and some fungi, these organisms cannot make biotin. Currently, the biotin included in vitamin tablets and animal feeds is made by chemical synthesis. This is partly because the biosynthetic pathways in bacteria are incompletely understood. This paper defines an enzyme of the Bacillus subtilis pathway and shows that it differs from that of Escherichia coli in the ability to utilize specific precursors. These bacteria have been used in biotin production and these data may aid in making biotin produced by biotechnology commercially competitive with that produced by chemical synthesis.

Using the pimeloyl-CoA synthetase adenylation fold to synthesize fatty acid thioesters

Biotin is an essential vitamin in plants and mammals, functioning as the carbon dioxide carrier within central lipid metabolism. Bacterial pimeloyl-CoA synthetase (BioW) acts as a highly specific substrate-selection gate, ensuring the integrity of the carbon chain in biotin synthesis. BioW catalyzes the condensation of pimelic acid (C7 dicarboxylic acid) with CoASH in an ATP-dependent manner to form pimeloyl-CoA, the first dedicated biotin building block. Multiple structures of Bacillus subtilis BioW together capture all three substrates, as well as the intermediate pimeloyl-adenylate and product pyrophosphate (PP_i), indicating that the enzyme uses an internal ruler to select the correct dicarboxylic acid substrate. Both the catalytic mechanism and the surprising stability of the adenylate intermediate were rationalized through site-directed mutagenesis. Building on this understanding, BioW was engineered to synthesize high-value heptanoyl (C7) and octanoyl (C8) monocarboxylic acid-CoA and C8 dicarboxylic-CoA products, highlighting the enzyme's synthetic potential.

Detection and characterization of a thermophilic biotin biosynthetic enzyme, 7-keto-8-aminopelargonic acid synthase, from various thermophiles

By detailed BLAST searches of the genome database of various thermophiles, five ORFs with similarity to the bioF gene, which encodes 7-keto-8-aminopelargonic acid synthase (BioF) involved in biotin biosynthesis, of Escherichia coli were found: AqbioF, CltbioF, GkbioF, SytbioF, and TsebioF, from Aquifex aeolicus VF5, Clostridium thermocellum ATCC27405, Geobacillus kaustophilus JCM12893, Symbiobacterium thermophilum IAM14863, and Thermosynechococcus elongatus BP-1 respectively. The five purified recombinant bioF gene products, which were overexpressed in E. coli, had the enzyme activity of BioF. The optimum temperature range and thermostability of five BioFs, AqBioF, CltBioF, GkBioF, SytBioF, and TseBioF, were higher than those of E. coli BioF. In particular, AqBioF was found to show the highest thermostability of the α-oxoamine synthase family enzymes reported to date. Substrate specificity experiments revealed that SytBioF was also able to catalyze the reaction of 2-amino-3-ketobutyrate CoA ligase, a member of the α-oxoamine synthase family, and that it used acetyl-CoA and glycine as substrates, like the TTHA1582 protein of Thermus thermophilus. The other purified BioFs, AqBioF and GkBioF, did not show any activity with acyl-CoAs and amino acids other than pimeloyl-CoA and L-alanine as substrates.

Biotin synthase: insights into radical-mediated carbon-sulfur bond formation

The enzyme cofactor and essential vitamin biotin is biosynthesized in bacteria, fungi, and plants through a pathway that culminates with the addition of a sulfur atom to generate the five-membered thiophane ring. The immediate precursor, dethiobiotin, has methylene and methyl groups at the C6 and C9 positions, respectively, and formation of a thioether bridging these carbon atoms requires cleavage of unactivated CH bonds. Biotin synthase is an S-adenosyl-l-methionine (SAM or AdoMet) radical enzyme that catalyzes reduction of the AdoMet sulfonium to produce 5'-deoxyadenosyl radicals, high-energy carbon radicals that can directly abstract hydrogen atoms from dethiobiotin. The available experimental and structural data suggest that a [2Fe-2S](2+) cluster bound deep within biotin synthase provides a sulfur atom that is added to dethiobiotin in a stepwise reaction, first at the C9 position to generate 9-mercaptodethiobiotin, and then at the C6 position to close the thiophane ring. The formation of sulfur-containing biomolecules through a radical reaction involving an iron-sulfur cluster is an unprecedented reaction in biochemistry; however, recent enzyme discoveries suggest that radical sulfur insertion reactions may be a distinct subgroup within the burgeoning Radical SAM superfamily. This article is part of a Special Issue entitled: Radical SAM enzymes and Radical Enzymology.

Peroxisomes are involved in biotin biosynthesis in Aspergillus and Arabidopsis

Among the eukaryotes only plants and a number of fungi are able to synthesize biotin. Although initial events leading to the biosynthesis of biotin remain largely unknown, the final steps are known to occur in the mitochondria. Here we deleted the Aopex5 and Aopex7 genes encoding the receptors for peroxisomal targeting signals PTS1 and PTS2, respectively, in the filamentous fungus Aspergillus oryzae. In addition to exhibiting defects in the peroxisomal targeting of either PTS1 or PTS2 proteins, the deletion strains also displayed growth defects on minimal medium containing oleic acid as the sole carbon source. Unexpectedly, these peroxisomal transport-deficient strains also exhibited growth defects on minimal medium containing glucose as the sole carbon source that were remediated by the addition of biotin and its precursors, including 7-keto-8-aminopelargonic acid (KAPA). Genome database searches in fungi and plants revealed that BioF protein/KAPA synthase, one of the biotin biosynthetic enzymes, has a PTS1 sequence at the C terminus. Fungal ΔbioF strains expressing the fungal and plant BioF proteins lacking PTS1 still exhibited growth defects in the absence of biotin, indicating that peroxisomal targeting of KAPA synthase is crucial for the biotin biosynthesis. Furthermore, in the plant Arabidopsis thaliana, AtBioF localized to the peroxisomes through recognition of its PTS1 sequence, suggesting involvement of peroxisomes in biotin biosynthesis in plants. Taken together we demonstrate a novel role for peroxisomes in biotin biosynthesis and suggest the presence of as yet unidentified peroxisomal proteins that function in the earlier steps of biotin biosynthesis.

Functional asymmetry for the active sites of linked 5-aminolevulinate synthase and 8-amino-7-oxononanoate synthase

5-Aminolevulinate synthase (ALAS) and 8-amino-7-oxononanoate synthase (AONS) are homodimeric members of the α-oxoamine synthase family of pyridoxal 5'-phosphate (PLP)-dependent enzymes. Previously, linking two ALAS subunits into a single polypeptide chain dimer yielded an enzyme (ALAS/ALAS) with a significantly greater turnover number than that of wild-type ALAS. To examine the contribution of each active site to the enzymatic activity of ALAS/ALAS, the catalytic lysine, which also covalently binds the PLP cofactor, was substituted with alanine in one of the active sites. Albeit the chemical rate for the pre-steady-state burst of ALA formation was identical in both active sites of ALAS/ALAS, the k(cat) values of the variants differed significantly (4.4±0.2 vs. 21.6±0.7 min(-1)) depending on which of the two active sites harbored the mutation. We propose that the functional asymmetry for the active sites of ALAS/ALAS stems from linking the enzyme subunits and the introduced intermolecular strain alters the protein conformational flexibility and rates of product release. Moreover, active site functional asymmetry extends to chimeric ALAS/AONS proteins, which while having a different oligomeric state, exhibit different rates of product release from the two ALAS and two AONS active sites due to the created intermolecular strain.

Pyridoxal-5'-phosphate-dependent enzymes involved in biotin biosynthesis: structure, reaction mechanism and inhibition

The four last steps of biotin biosynthesis, starting from pimeloyl-CoA, are conserved among all the biotin-producing microorganisms. Two enzymes of this pathway, the 8-amino-7-oxononanoate synthase (AONS) and the 7,8-diaminopelargonic acid aminotransferase (DAPA AT) are dependent on pyridoxal-5'-phosphate (PLP). This review summarizes our current understanding of the structure, reaction mechanism and inhibition on these two interesting enzymes. Mechanistic studies as well as the determination of the crystal structure of AONS have revealed a complex mechanism involving an acylation with inversion of configuration and a decarboxylation with retention of configuration. This reaction mechanism is shared by the homologous 5-aminolevulinate synthase and serine palmitoyltransferase. While the reaction catalyzed by DAPA AT is a classical PLP-dependent transamination, the inactivation of this enzyme by amiclenomycin, a natural antibiotic that is active against Mycobacterium tuberculosis, involves the irreversible formation of an adduct between PLP and amiclenomycin. Mechanistic and structural studies allowed the complete description of this unique inactivation mechanism. Several potent inhibitors of these two PLP-dependent enzymes have been prepared and might be useful as starting points for the design of herbicides or antibiotics. This article is part of a Special Issue entitled: Pyridoxal Phospate Enzymology.

Anaerobic Metabolism of Cyclohex-1-Ene-1-Carboxylate, a Proposed Intermediate of Benzoate Degradation, by Rhodopseudomonas palustris

Anaerobic benzoate degradation by the phototrophic bacterium Rhodopseudomonas palustris has been proposed to proceed via aromatic ring reduction reactions leading to cyclohex-1-ene-1-carboxyl-coenzyme A (CoA) formation. The alicyclic product is then proposed to undergo three beta-oxidation-like modifications resulting in ring cleavage. Illuminated suspensions of benzoate-grown cells converted [7-C]cyclohex-1-ene-1-carboxylate to intermediates that comigrated with cyclohex-1-ene-1-carboxyl-CoA, 2-hydroxycyclohexanecar-boxyl-CoA, 2-ketocyclohexanecarboxyl-CoA, and pimelyl-CoA by thin-layer chromatography. This set of intermediates was also formed by cells grown anaerobically or aerobically on cyclohex-1-ene-1-carboxylate, indicating that benzoate-grown and cyclohex-1-ene-1-carboxylate-grown cells degrade this alicyclic acid by the same catabolic route. Four enzymatic activities proposed to be required for conversion of cyclohex-1-ene-1-carboxylate to pimelyl-CoA were detected at 3- to 10-fold-higher levels in benzoate-grown cells than in succinate-grown cells. These were cyclohex-1-ene-1-carboxylate-CoA ligase, cyclohex-1-ene-1-carboxyl-CoA hydratase, 2-hydroxycyclohexanecarboxyl-CoA dehydrogenase, and 2-ketocyclohexanecarboxyl-CoA hydrolase (ring cleaving). Pimelyl-CoA was identified in hydrolase reaction mixtures as the product of alicyclic ring cleavage. The results provide a first demonstration of an alicyclic ring cleavage activity.

Inhibition of 7,8-diaminopelargonic acid aminotransferase from Mycobacterium tuberculosis by chiral and achiral anologs of its substrate: biological implications

7,8-Diaminopelargonic acid aminotransferase (DAPA AT), a potential drug target in Mycobacterium tuberculosis, transforms 8-amino-7-oxononanoic acid (KAPA) into DAPA. We have designed an analytical method to measure the enantiomeric excess of KAPA, based on the derivatization of its amine function, by ortho-phtalaldehyde and N-acetyl-l-cysteine, followed by high pressure liquid chromatography separation. Using this methodology and enantiopure samples of KAPA it appeared that racemization of KAPA occurs rapidly (half-lives from 1 to 8 h) not only in 4 M HCl but more importantly in the usual pH range, from 7 to 9. Furthermore, we showed that racemic KAPA, and not enantiopure KAPA, was used in all previous studies. The only valid enantioselective synthesis of KAPA is that reported by Lucet et al. (1996) Tetrahedron: Asymmetry 7, 985-988. KAPA is produced as a pure (S)-enantiomer by KAPA synthase and by microbial production and DAPA AT only uses (S)-KAPA as substrate. However, (R)-KAPA is an inhibitor of this enzyme. It binds to the pyridoxal 5'-phosphate form (K(i1) = 5.9 +/- 0.2 microM) and to the pyridoxamine 5'-phosphate form (K(i2) = 1.7 +/- 0.2 microM) of M. tuberculosis DAPA AT. Molecular modeling showed that (R)-KAPA forms specific hydrogen bonds with T309 and the phosphate group of the cofactor of DAPA AT. Desmethyl-KAPA (8-amino-7-oxooctanoic acid), an achiral analog of KAPA, is also a potent inhibitor of M. tuberculosis DAPA AT. This molecule binds to the enzyme in a similar way than (R)-KAPA with the following constants: K(i1) = 4.2 +/- 0.2 microM, and K(i2) = 0.9 +/- 0.2 microM. These findings pave the way to the design of new antimycobacterial drugs.

Biotin synthesis in plants. The first committed step of the pathway is catalyzed by a cytosolic 7-keto-8-aminopelargonic acid synthase

Biochemical and molecular characterization of the biotin biosynthetic pathway in plants has dealt primarily with biotin synthase. This enzyme catalyzing the last step of the pathway is localized in mitochondria. Other enzymes of the pathway are however largely unknown. In this study, a genomic-based approach allowed us to clone an Arabidopsis (Arabidopsis thaliana) cDNA coding 7-keto-8-aminopelargonic acid (KAPA) synthase, the first committed enzyme of the biotin synthesis pathway, which we named AtbioF. The function of the enzyme was demonstrated by functional complementation of an Escherichia coli mutant deficient in KAPA synthase reaction, and by measuring in vitro activity. Overproduction and purification of recombinant AtbioF protein enabled a thorough characterization of the kinetic properties of the enzyme and a spectroscopic study of the enzyme interaction with its substrates and product. This is the first characterization of a KAPA synthase reaction in eukaryotes. Finally, both green fluorescent protein-targeting experiments and western-blot analyses showed that the Arabidopsis KAPA synthase is present in cytosol, thus revealing a unique compartmentation of the plant biotin synthesis, split between cytosol and mitochondria. The significance of the complex compartmentation of biotin synthesis and utilization in the plant cell and its potential importance in the regulation of biotin metabolism are also discussed.

Removing a bottleneck in the Bacillus subtilis biotin pathway: bioA utilizes lysine rather than S-adenosylmethionine as the amino donor in the KAPA-to-DAPA reaction

In biotin biosynthesis, DAPA aminotransferase encoded by the bioA gene catalyzes the formation of the intermediate 7,8-diaminopelargonic acid (DAPA) from 7-keto-8-aminopelargonic acid (KAPA). DAPA aminotransferases from Escherichia coli, Serratia marcescens, and Bacillus sphaericus use S-adenosylmethionine (SAM) as the amino donor. Our observation that SAM is not an amino donor for B. subtilis DAPA aminotransferase led to a search for an alternative amino donor for this enzyme. Testing of 26 possible amino acids in a cell-free extract assay revealed that only l-lysine was able to dramatically stimulate the in vitro conversion of KAPA to DAPA by the B. subtilis DAPA aminotransferase. The K(m) for lysine and KAPA was estimated to be between 2 and 25 mM, which is significantly higher than the K(m) of purified E. coli BioA for SAM (0.15 mM). This higher requirement for lysine resulted in accumulation of KAPA during fermentation of B. subtilis biotin producing strains. However, this pathway bottleneck could be relieved by either addition of exogenous lysine to the medium or by introduction of lysine deregulated mutations into the production strains.

5-Aminolevulinic acid synthase: mechanism, mutations and medicine

5-Aminolevulinic acid synthase (ALAS), the first enzyme of the heme biosynthesis pathway, catalyses the pyridoxal 5'-phosphate-dependent condensation between glycine and succinyl-CoA to yield 5-aminolevulinic acid (5-amino-4-oxopentanoate). A three-dimensional structural model of Rhodobacter spheroides ALAS has been constructed and used to identify amino acid residues at the active site that are likely to be important for the recognition of glycine, the only amino acid substrate. Several residues have been investigated by site-directed mutagenesis and enzyme variants have been generated that are able to use alanine, serine or threonine. A three-dimensional structure model of 5-aminolevulinic acid synthase from human erythrocytes (ALAS 2) has also been constructed and used to map a range of naturally occurring human mutants that give rise to X-linked sideroblastic anemia. A number of these anemias respond favourably to vitamin B(6) (pyridoxine) therapy, whereas others are either partially responsive or completely refractory. Detailed investigations with selected human mutants have highlighted the importance of arginine-517 that is implicated in glycine carboxyl group binding.

Analysis of the prodiginine biosynthesis gene cluster of Streptomyces coelicolor A3(2): new mechanisms for chain initiation and termination in modular multienzymes

BACKGROUND

Prodiginines are a large family of pigmented oligopyrrole antibiotics with medicinal potential as immunosuppressants and antitumour agents that are produced by several actinomycetes and other eubacteria. Recently, a gene cluster in Streptomyces coelicolor encoding the biosynthesis of undecylprodiginine and butyl-meta-cycloheptylprodiginine has been sequenced.

RESULTS

Using sequence comparisons, functions have been assigned to the majority of the genes in the cluster, several of which encode homologues of enzymes involved in polyketide, non-ribosomal peptide, and fatty acid biosynthesis. Based on these assignments, a complete pathway for undecylprodiginine and butyl-meta-cycloheptylprodiginine biosynthesis in S. coelicolor has been deduced. Gene knockout experiments have confirmed the deduced roles of some of the genes in the cluster.

CONCLUSIONS

The analysis presented provides a framework for a general understanding of the genetics and biochemistry of prodiginine biosynthesis, which should stimulate rational approaches to the engineered biosynthesis of novel prodiginines with improved immunosuppressant or antitumour activities. In addition, new mechanisms for chain initiation and termination catalysed by hitherto unobserved domains in modular multienzyme systems have been deduced.

A water-soluble homodimeric serine palmitoyltransferase from Sphingomonas paucimobilis EY2395T strain. Purification, characterization, cloning, and overproduction

Serine palmitoyltransferase (SPT, EC ) is a key enzyme in sphingolipid biosynthesis and catalyzes the decarboxylative condensation of l-serine and palmitoyl-coenzyme A to 3-ketodihydrosphingosine. We found that the Gram-negative obligatory aerobic bacteria Sphingomonas paucimobilis EY2395(T) have significant SPT activity and purified SPT to homogeneity. This enzyme is a water-soluble homodimeric protein unlike eukaryotic enzymes, known as heterodimers composed of tightly membrane-bound subunits, named LCB1 and LCB2. The purified SPT shows an absorption spectrum characteristic of a pyridoxal 5'-phosphate-dependent enzyme. The substrate specificity of the Sphingomonas SPT is less strict than the SPT complex from Chinese hamster ovary cells. We isolated the SPT gene encoding 420 amino acid residues (M(r) 45,041) and succeeded in overproducing the SPT protein in Escherichia coli, in which the product amounted to about 10-20% of the total protein of the cell extract. Sphingomonas SPT shows about 30% homology with the enzymes of the alpha-oxamine synthase family, and amino acid residues supposed to be involved in catalysis are conserved. The recombinant SPT was catalytically and spectrophotometrically indistinguishable from the native enzyme. This is the first successful overproduction of an active enzyme in the sphingolipid biosynthetic pathway. Sphingomonas SPT is a prototype of the eukaryotic enzyme and would be a useful model to elucidate the reaction mechanism of SPT.

Mechanism of 8-amino-7-oxononanoate synthase: spectroscopic, kinetic, and crystallographic studies

8-Amino-7-oxononanoate synthase (also known as 7-keto-8-aminopelargonate synthase, EC 2.3.1.47) is a pyridoxal 5'-phosphate-dependent enzyme which catalyzes the decarboxylative condensation of L-alanine with pimeloyl-CoA in a stereospecific manner to form 8(S)-amino-7-oxononanoate. This is the first committed step in biotin biosynthesis. The mechanism of Escherichia coli AONS has been investigated by spectroscopic, kinetic, and crystallographic techniques. The X-ray structure of the holoenzyme has been refined at a resolution of 1.7 A (R = 18.6%, R(free) = 21. 2%) and shows that the plane of the imine bond of the internal aldimine deviates from the pyridine plane. The structure of the enzyme-product external aldimine complex has been refined at a resolution of 2.0 A (R = 21.2%, R(free) = 27.8%) and shows a rotation of the pyridine ring with respect to that in the internal aldimine, together with a significant conformational change of the C-terminal domain and subtle rearrangement of the active site hydrogen bonding. The first step in the reaction, L-alanine external aldimine formation, is rapid (k(1) = 2 x 10(4) M(-)(1) s(-)(1)). Formation of an external aldimine with D-alanine, which is not a substrate, is significantly slower (k(1) = 125 M(-)(1) s(-)(1)). Binding of D-alanine to AONS is enhanced approximately 2-fold in the presence of pimeloyl-CoA. Significant substrate quinonoid formation only occurs upon addition of pimeloyl-CoA to the preformed L-alanine external aldimine complex and is preceded by a distinct lag phase ( approximately 30 ms) which suggests that binding of the pimeloyl-CoA causes a conformational transition of the enzyme external aldimine complex. This transition, which is inferred by modeling to require a rotation around the Calpha-N bond of the external aldimine complex, promotes abstraction of the Calpha proton by Lys236. These results have been combined to form a detailed mechanistic pathway for AONS catalysis which may be applied to the other members of the alpha-oxoamine synthase subfamily.

Slow-binding and competitive inhibition of 8-amino-7-oxopelargonate synthase, a pyridoxal-5'-phosphate-dependent enzyme involved in biotin biosynthesis, by substrate and intermediate analogs. Kinetic and binding studies

8-Amino-7-oxopelargonate synthase catalyzes the first committed step of biotin biosynthesis in micro-organisms and plants. Because inhibitors of this pathway might lead to antibacterials or herbicides, we have undertaken an inhibition study on 8-amino-7-oxopelargonate synthase using six different compounds. d-Alanine, the enantiomer of the substrate of this pyridoxal-5'-phosphate-dependent enzyme was found to be a competitive inhibitor with respect to l-alanine with a Ki of 0.59 mm. The fact that this inhibition constant was four times lower than the Km for l-alanine was interpreted as the consequence of the inversion-retention stereochemistry of the catalyzed reaction. Schiff base formation between l or d-alanine and pyridoxal-5'-phosphate, in the active site of the enzyme, was studied using ultraviolet/visible spectroscopy. It was found that l and d-alanine form an external aldimine with equilibrium constants K = 4.1 mm and K = 37.8 mm, respectively. However, the equilibrium constant for d-alanine aldimine formation dramatically decreased to 1.3 mm in the presence of saturating concentration of pimeloyl-CoA, the second substrate. This result strongly suggests that the binding of pimeloyl-CoA induces a conformational change in the active site, and we propose that this new topology is complementary to d-alanine and to the putative reaction intermediate since they both have the same configuration. (+/-)-8-Amino-7-oxo-8-phosphonononaoic acid (1), the phosphonate derivative of the intermediate formed during the reaction, was our most potent inhibitor with a Ki of 7 microm. This compound behaved as a reversible slow-binding inhibitor, competitive with respect to l-alanine. Kinetic investigation showed that this slow process was best described by a one-step mechanism (mechanism A) with the following rate constants: k1 = 0.27 x 103 m-1.s-1, k2 = 1.8 s-1 and half-life for dissociation t1/2 = 6.3 min. The binding of compound 1 to the enzyme was also studied using ultraviolet/visible spectroscopy, and the data were consistent with the kinetic data (K = 4.2 microm). Among the other compounds tested, two potential transition state analogs, 4-carboxybutyl(1-amino-1-carboxyethyl)phosphonate (4) and 2-amino-3-hydroxy-2-methylnonadioic acid (5) were found to be competitive inhibitors with respect to l-alanine with Ki of 68 microm and 80 microm, respectively.

The crystal structure of 8-amino-7-oxononanoate synthase: a bacterial PLP-dependent, acyl-CoA-condensing enzyme

8-Amino-7-oxononanoate synthase (or 8-amino-7-ketopelargonate synthase; EC 2.3.1.47; AONS) catalyses the decarboxylative condensation of l-alanine and pimeloyl-CoA in the first committed step of biotin biosynthesis. We have cloned, over-expressed and purified AONS from Escherichia coli and determined the crystal structures of the apo and PLP-bound forms of the enzyme. The protein is a symmetrical homodimer with a tertiary structure and active site organisation similar to, but distinct from, those of other PLP-dependent enzymes whose three-dimensional structures are known. The critical PLP-binding lysine of AONS is located at the end of a deep cleft that allows access of the pantothenate arm of pimeloyl-CoA. A cluster of positively charged residues at the entrance to this cleft forms a putative diphosphate binding site for CoA. The structure of E. coli AONS enables identification of the key residues of the PLP-binding site and thus provides a framework with which to understand the biochemical mechanism, which is similar to that catalysed by 5-aminolevulinate synthase and two other alpha-oxoamine synthases. Although AONS has a low overall sequence similarity with the catalytic domains of other alpha-oxoamine synthases, the structure reveals the regions of significant identity to be functionally important. This suggests that the organisation of the conserved catalytic residues in the active site is similar for all enzymes of this sub-class of PLP-dependent enzymes and they share a common mechanism. Knowledge of the three-dimensional structure of AONS will enable characterisation of the structural features of this enzyme sub-family that are responsible for this important type of reaction.

An embryo-defective mutant of arabidopsis disrupted in the final step of biotin synthesis

Auxotrophic mutants have played an important role in the genetic dissection of biosynthetic pathways in microorganisms. Equivalent mutants have been more difficult to identify in plants. The bio1 auxotroph of Arabidopsis thaliana was shown previously to be defective in the synthesis of the biotin precursor 7, 8-diaminopelargonic acid. A second biotin auxotroph of A. thaliana has now been identified. Arrested embryos from this bio2 mutant are defective in the final step of biotin synthesis, the conversion of dethiobiotin to biotin. This enzymatic reaction, catalyzed by the bioB product (biotin synthase) in Escherichia coli, has been studied extensively in plants and bacteria because it involves the unusual addition of sulfur to form a thiophene ring. Three lines of evidence indicate that bio2 is defective in biotin synthase production: mutant embryos are rescued by biotin but not dethiobiotin, the mutant allele maps to the same chromosomal location as the cloned biotin synthase gene, and gel-blot hybridizations and polymerase chain reaction amplifications revealed that homozygous mutant plants contain a deletion spanning the entire BIO2-coding region. Here we describe how the isolation and characterization of this null allele have provided valuable insights into biotin synthesis, auxotrophy, and gene redundancy in plants.

Isolation and chemistry of the mixed anhydride intermediate in the reaction catalyzed by dethiobiotin synthetase

Dethiobiotin synthetase (DTBS) catalyzes the formation of the cyclic urea, dethiobiotin (DTB), from (7R,8S)-diaminononanoic acid (DAPA), CO2, and ATP; the other products of the reaction are ADP and Pi. The first intermediate in the reaction sequence is the 7-carbamate of DAPA [Huang, W., et al. (1995) Biochemistry 34, 10985-10995; Gibson, K. J., et al. (1995) Biochemistry 34, 10976-10984; Alexeev, D., et al. (1995) Structure 3, 1207-1215]. The existence of the second postulated intermediate, a mixed carbamic-phosphoric anhydride formed when the carbamate is phosphorylated by ATP, is consistent with the cleavage of the gamma-phosphoryl group of ATP seen in DTBS reaction mixtures [Baxter, R. L., & Baxter, H. C. (1994) J. Chem. Soc., Chem. Commun., 759-760]. Two more direct lines of evidence for the mixed anhydride intermediate have now been obtained. First, a DTBS reaction mixture containing [18O]CO2 produced 18O-enriched DTB and Pi, as the existence of such an intermediate would require. Second, a moderately stable intermediate that could be labeled with either 14CO2, [gamma-33P]ATP, [9-3H]DAPA, or [1,7-14C]DAPA was trapped by quenching DTBS reactions at pH 4 and isolated by thin-layer chromatography. As expected for the proposed mixed anhydride, this species underwent acid hydrolysis to DAPA, CO2, and Pi; under basic conditions, the intermediate cyclized, yielding DTB and Pi. When returned to fresh enzyme at pH 7.5, the intermediate underwent cyclization at a rate comparable to that of normal turnover.

Cloning, sequencing, and characterization of the Bacillus subtilis biotin biosynthetic operon

A 10-kb region of the Bacillus subtilis genome that contains genes involved in biotin-biosynthesis was cloned and sequenced. DNA sequence analysis indicated that B. subtilis contains homologs of the Escherichia coli and Bacillus sphaericus bioA, bioB, bioD, and bioF genes. These four genes and a homolog of the B. sphaericus bioW gene are arranged in a single operon in the order bioWAFDR and are followed by two additional genes, bioI and orf2. bioI and orf2 show no similarity to any other known biotin biosynthetic genes. The bioI gene encodes a protein with similarity to cytochrome P-450s and was able to complement mutations in either bioC or bioH of E. coli. Mutations in bioI caused B. subtilis to grow poorly in the absence of biotin. The bradytroph phenotype of bioI mutants was overcome by pimelic acid, suggesting that the product of bioI functions at a step prior to pimelic acid synthesis. The B. subtilis bio operon is preceded by a putative vegetative promoter sequence and contains just downstream a region of dyad symmetry with homology to the bio regulatory region of B. sphaericus. Analysis of a bioW-lacZ translational fusion indicated that expression of the biotin operon is regulated by biotin and the B. subtilis birA gene.

Mechanistic studies on the 8-amino-7-oxopelargonate synthase, a pyridoxal-5'-phosphate-dependent enzyme involved in biotin biosynthesis

The reaction mechanism of 8-amino-7-oxopelargonate (8-amino-7-oxononoate) synthase from Bacillus sphaericus, an enzyme dependent on pyridoxal 5'-phosphate (pyridoxal-P), which catalyzes the condensation of L-alanine with pimeloyl-CoA, the second step of biotin biosynthesis, has been studied. To facilitate mechanistic studies, an improved over-expression system in Escherichia coli, and a new continuous spectrophotometric assay for 8-amino-7-oxopelargonate synthase were designed. In order to discriminate between the two plausible basic mechanisms that can be put forth for this enzyme, that is: (a) formation of the pyridoxal-P-stabilized carbanion by abstraction of the C2-H proton of the alanine-pyridoxal-P aldimine, followed by acylation and decarboxylation, and (b) formation of the carbanion by decarboxylation followed by acylation, the fate of the C2-H proton of alanine during the course of the reaction has been examined using 1H NMR. Spectra of the 8-amino-7-oxopelargonate formed using either L-[2-2H]alanine in H2O or L-alanine in D2O, showed that the C2-H proton of alanine is lost during the reaction and that the C8-H proton of 8-amino-7-oxopelargonate is derived from the solvent, a result that is only consistent with mechanism (a). Furthermore 8-amino-7-oxopelargonate synthase catalyzes, in the absence of pimeloyl-CoA, the stereospecific exchange, with retention of configuration, of the C2-H proton of L-alanine with the solvent protons. Similarly, 8-amino-7-oxopelargonate synthase catalyzes the exchange of the C8-H proton of 8-amino-7-oxopelargonate. In addition to these exchange reactions, 8-amino-7-oxopelargonate synthase catalyzes an abortive transamination yielding an inactive pyridoxamine 5'-phosphate (pyridoxamine-P) form of 8-amino-7-oxopelargonate synthase and pyruvate. Kinetic analysis gave a rate constant of kexch. = 1.8 min-1 for the exchange reaction which is 10 times lower than the catalytic constant and a rate constant of ktrans. = 0.11 h-1 for the transamination. Finally deuterium kinetic isotope effects (KIE) were measured at position 2 of L-alanine (DV = 1.3) and in D2O (D2OV = 4.0). The magnitudes of the KIE are consistent with a partially rate-limiting abstraction of the C2-H proton of alanine and a partially rate-limiting reprotonation step. Taken together, all these results show that 8-amino-7-oxopelargonate synthase utilizes mechanism (a). 8-Amino-7-oxopelargonate synthase and 5-aminolevulinate synthase, which has also been shown to use mechanism (a), belong to a class of pyridoxal-P-dependent enzymes that catalyze the formation of alpha-oxoamines. Based on the fact that all these alpha-oxoamine synthases share strong sequence similarities, we postulate that they also share the same reaction mechanism.

Mechanistic implications and family relationships from the structure of dethiobiotin synthetase

BACKGROUND

Biotin is the vitamin essential for many biological carboxylation reactions, such as the conversion of acetyl-coenzyme A (CoA) to malonyl-CoA in fatty acid biosynthesis. Dethiobiotin synthetase (DTBS) facilitates the penultimate, ureido ring closure in biotin synthesis, which is a non-biotin-dependent carboxylation. DTBS displays no sequence similarity to any other protein in the database. Structural studies provide a molecular insight into the reaction mechanism of DTBS.

RESULTS

We present the structure of DTBS refined to 1.80 A resolution with an R-factor of 17.2% for all terms plus unrefined data on the binding of the substrate, 7,8-diaminopelargonic acid and the product, dethiobiotin. These studies confirm that the protein forms a homodimer with each subunit folded as a single globular alpha/beta domain. The presence of sulphate ions in the crystals and comparisons with the related Ha-ras-p21 oncogene product are used to infer the ATP-binding site, corroborated by the difference electron density for the ATP analogue AMP-PNP.

CONCLUSIONS

This study establishes that the enzyme active site is situated at the dimer interface, with the substrate binding to one monomer and ATP to the other. The overall fold of DTBS closely resembles that of three other enzymes, adenylosuccinate synthetase (purA), Ha-ras-p21, and nitrogenase iron protein, that are unrelated by sequence or function, indicating that DTBS is a member of a diverse family of enzymes.

Biotin biosynthesis in higher plant cells. Identification of intermediates

Biotin biosynthesis was investigated in lavender cell cultures (Lavandula vera L.). Two different biological assays and two different HPLC procedures were used to identify all the intermediates involved in biotin biosynthesis. The pathway for biotin biosynthesis could be analyzed starting with [3H]pimelic acid as precursor, leading to labelled biotin and even to labelled biotinylated enzymes. Intermediates known from the bacterial pathway (7-oxo-8-amino-pelargonic acid, 7,8-diamino-pelargonic acid, dethiobiotin) were present in detectable amounts. Pimelic acid activation to pimeloyl-CoA could be observed. In contrast to bacterial cells, an unknown stable labelled intermediate, named compound A, accumulated. This compound coeluted with an authentic sample of 9-mercaptodethiobiotin from HPLC with an anion-exchange column and was as effective as biotin in supporting the growth of the strain bioB105 of Escherichia coli. When 3H-labelled compound A was added to the growth medium of the lavender cells it was incorporated in an acidomycin-sensitive manner into biotin. [3H]Dethiobiotin was incorporated into both compound A and biotin. These results strongly suggest that, in higher plant cells, the reaction catalysed by biotin synthase may proceed in two distinct steps involving mercaptodethiobiotin (9-mercaptodethiobiotin?) as an intermediate.

Genomic organization of the biotin biosynthetic genes of coryneform bacteria: cloning and sequencing of the bioA-bioD genes from Brevibacterium flavum

Three coryneform bacteria, Brevibacterium flavum, Brevibacterium lactofermentum and Corynebacterium glutamicum have been shown to be able to convert 7-keto-8-aminopelargonic acid to biotin through a biotin synthetic pathway identical to that from Escherichia coli (Hatakeyama et al., DNA Sequence, in press, 1993). We report in this paper the cloning and sequencing of the biotin biosynthetic genes encoding the 7,8-diaminopelargonic acid aminotransferase (bioA) and the dethiobiotin synthetase (bioD) of B. flavum MJ233, by complementation of E. coli bioA and bioD mutants. Both bioA and bioD genes from B. flavum were located on a 4.0-kb SalI DNA fragment. Nucleotide sequence analysis of this fragment revealed that these genes consist of a 1272 bp and a 675 bp open reading frame, respectively. The deduced amino acid sequence of the 7,8-diaminopelargonic acid aminotransferase (BioA) is 51.3% and 31.9% identical to that of the E. coli and Bacillus spaericus bioA gene products, respectively. The deduced amino acid sequence of the dethiobiotin synthetase (BioD) is 25.9% and 32.7% identical to that of the E. coli and B. sphaericus bioD gene products, respectively. In addition, the genomic organization of the bioA, bioB and bioD genes in B. flavum has been shown to be different from that in E. coli and B. sphaericus.

Analysis of the biotin biosynthesis pathway in coryneform bacteria: cloning and sequencing of the bioB gene from Brevibacterium flavum

The biotin biosynthetic pathway of three coryneform bacteria, Brevibacterium flavum, Brevibacterium lactofermentum, and Corynebacterium glutamicum were analysed by cross-feeding experiments using several Escherichia coli biotin-requiring mutants. The three strains of coryneform bacteria tested were able to convert 7-keto-8-aminopelargonic acid to biotin, through a biotin synthetic pathway identical to that from E. coli. The biotin biosynthetic gene, bioB, of B. flavum was cloned by phenotypic complementation of E. coli bioB mutants. The bioB gene was located on a 1.7 kb HindIII-SacI DNA fragment. Nucleotide sequence analysis of this fragment revealed that the bioB gene of B. flavum consists of a 1005 bp open reading frame. Its deduced amino acid sequence is 35.7% and 31.5% identical to that of the E. coli and Bacillus sphaericus bioB gene products, respectively. B. flavum mutants obtained by in vivo disruption of the bioB gene lost their ability to grow on minimal medium containing dethiobiotin, indicating that the bioB gene product is necessary for the conversion of dethiobiotin to biotin.

Investigation of the first step of biotin biosynthesis in Bacillus sphaericus. Purification and characterization of the pimeloyl-CoA synthase, and uptake of pimelate

The pimeloyl-CoA synthase from Bacillus sphaericus has been purified to homogeneity from an overproducing strain of Escherichia coli. The purification yielded milligram quantities of the synthase with a specific activity of 1 unit/mg of protein. Analysis of the products showed that this enzyme catalysed the transformation of pimelate into pimeloyl-CoA with concomitant hydrolysis of ATP to AMP. Using a continuous spectrophotometric assay, we have examined the catalytic properties of the pure enzyme. The pH profile under Vmax. conditions showed a maximum around 8.5. Apparent Km values for pimelate, CoASH, ATP.Mg2- and Mg2+ were respectively 145 microM, 33 microM, 170 microM and 2.3 mM. The enzyme was inhibited by Mg2+ above 10 mM. This acid-CoA ligase exhibited a very sharp substrate specificity, e.g. neither GTP nor pimelate analogues (di- or mono-carboxylic acids) were processed. The bivalent metal ion requirement was also investigated: Mn2+ (73%) and Co2+ (32%) but not Ca2+ could replace Mg2+. The enzyme was inhibited by metal chelators such as 1,10-phenanthroline and EDTA. The synthase was a homodimer with a 28,000-M(r) subunit. N-Terminal sequencing definitely proved that this enzyme was encoded by the bioW gene. A careful study of pimelate uptake by B. sphaericus, E. coli and Pseudomonas dentrificans showed that this metabolite crossed the membrane of these microorganisms by passive diffusion, ruling out the involvement of the bioX gene product as pimelate carrier.