Overall Retention of Methyl Stereochemistry during B12-Dependent Radical SAM Methyl Transfer in Fosfomycin Biosynthesis

Methylcobalamin-dependent radical S-adenosylmethionine (SAM) enzymes methylate non-nucleophilic atoms in a range of substrates. The mechanism of the methyl transfer from cobalt to the receiving atom is still mostly unresolved. Here we determine the stereochemical course of this process at the methyl group during the biosynthesis of the clinically used antibiotic fosfomycin. In vitro reaction of the methyltransferase Fom3 using SAM labeled with 1H, 2H, and 3H in a stereochemically defined manner, followed by chemoenzymatic conversion of the Fom3 product to acetate and subsequent stereochemical analysis, shows that the overall reaction occurs with retention of configuration. This outcome is consistent with a double-inversion process, first in the SN2 reaction of cob(I)alamin with SAM to form methylcobalamin and again in a radical transfer of the methyl group from methylcobalamin to the substrate. The methods developed during this study allow high-yield in situ generation of labeled SAM and recombinant expression and purification of the malate synthase needed for chiral methyl analysis. These methods facilitate the broader use of in vitro chiral methyl analysis techniques to investigate the mechanisms of other novel enzymes.

Biosynthetic pathways and enzymes involved in the production of phosphonic acid natural products

Phosphonates are organophosphorus compounds possessing a characteristic C-P bond in which phosphorus is directly bonded to carbon. As phosphonates mimic the phosphates and carboxylates of biological molecules to potentially inhibit metabolic enzymes, they could be lead compounds for the development of a variety of drugs. Fosfomycin (FM) is a representative phosphonate natural product that is widely used as an antibacterial drug. Here, we review the biosynthesis of FM, which includes a recent breakthrough to find a missing link in the biosynthetic pathway that had been a mystery for a quarter-century. In addition, we describe the genome mining of phosphonate natural products using the biosynthetic gene encoding an enzyme that catalyzes C-P bond formation. We also introduce the chemoenzymatic synthesis of phosphonate derivatives. These studies expand the repertoires of phosphonates and the related biosynthetic machinery. This review mainly covers the years 2012-2020.

Stereochemical and Mechanistic Investigation of the Reaction Catalyzed by Fom3 from Streptomyces fradiae, a Cobalamin-Dependent Radical S-Adenosylmethionine Methylase

Fom3, a cobalamin-dependent radical S-adenosylmethionine (SAM) methylase, has recently been shown to catalyze the methylation of carbon 2″ of cytidylyl-2-hydroxyethylphosphonate (HEP-CMP) to form cytidylyl-2-hydroxypropylphosphonate (HPP-CMP) during the biosynthesis of fosfomycin, a broad-spectrum antibiotic. It has been hypothesized that a 5'-deoxyadenosyl 5'-radical (5'-dA•) generated from the reductive cleavage of SAM abstracts a hydrogen atom from HEP-CMP to prime the substrate for addition of a methyl group from methylcobalamin (MeCbl); however, the mechanistic details of this reaction remain elusive. Moreover, it has been reported that Fom3 catalyzes the methylation of HEP-CMP to give a mixture of the ( S)-HPP and ( R)-HPP stereoisomers, which is rare for an enzyme-catalyzed reaction. Herein, we describe a detailed biochemical investigation of a Fom3 that is purified with 1 equiv of its cobalamin cofactor bound, which is almost exclusively in the form of MeCbl. Electron paramagnetic resonance and Mössbauer spectroscopies confirm that Fom3 contains one [4Fe-4S] cluster. Using deuterated enantiomers of HEP-CMP, we demonstrate that the 5'-dA• generated by Fom3 abstracts the C2″- pro-R hydrogen of HEP-CMP and that methyl addition takes place with inversion of configuration to yield solely ( S)-HPP-CMP. Fom3 also sluggishly converts cytidylyl-ethylphosphonate to the corresponding methylated product but more readily acts on cytidylyl-2-fluoroethylphosphonate, which exhibits a lower C2″ homolytic bond-dissociation energy. Our studies suggest a mechanism in which the substrate C2″ radical, generated upon hydrogen atom abstraction by the 5'-dA•, directly attacks MeCbl to transfer a methyl radical (CH3•) rather than a methyl cation (CH3+), directly forming cob(II)alamin in the process.

Stereospecific Radical-Mediated B12-Dependent Methyl Transfer by the Fosfomycin Biosynthesis Enzyme Fom3

Fom3, the antepenultimate enzyme in the fosfomycin biosynthetic pathway in Streptomyces spp., is a class B cobalamin-dependent radical SAM methyltransferase that catalyzes methylation of (5'-cytidylyl)-2-hydroxyethylphosphonate (2-HEP-CMP) to form (5'-cytidylyl)-2-hydroxypropylphosphonate (2-HPP-CMP). Previously, the reaction of Fom3 with 2-HEP-CMP produced 2-HPP-CMP with mixed stereochemistry at C2. Mechanistic characterization has been challenging because of insoluble expression and poor cobalamin (B12) incorporation in Escherichia coli. Recently, soluble E. coli expression and incorporation of cobalamin into Fom3 were achieved by overexpression of the BtuCEDFB cobalamin uptake system. Herein, we use this new method to obtain Fom3 from Streptomyces wedmorensis. We show that the initiator 5'-deoxyadenosyl radical stereospecifically abstracts the pro- R hydrogen atom from the C2 position of 2-HEP-CMP and use the downstream enzymes FomD and Fom4 to demonstrate that our preparation of Fom3 produces only (2 S)-2-HPP-CMP. Additionally, we show that the added methyl group originates from SAM under multiple-turnover conditions, but the first turnover uses a methyl donor already present on the enzyme; furthermore, cobalamin isolated from Fom3 reaction mixtures contains methyl groups derived from SAM. These results are consistent with a model in which Fom3 catalyzes methyl transfer from SAM to cobalamin and the resulting methylcobalamin (MeCbl) is the ultimate methyl source for the reaction.

Mechanistic consequences of chiral radical clock probes: analysis of the mononuclear non-heme iron enzyme HppE with 2-hydroxy-3-methylenecyclopropyl radical clock substrates

(S)-2-Hydroxypropylphosphonic acid [(S)-HPP] epoxidase (HppE) is a mononuclear iron enzyme that catalyzes the last step in the biosynthesis of the antibiotic fosfomycin. HppE also processes the (R)-enantiomer of HPP but converts it to 2-oxo-propylphosphonic acid. In this study, all four stereoisomers of 3-methylenecyclopropyl-containing substrate analogues, (2R, 3R)-8, (2R, 3S)-8, (2S, 3R)-8, and (2S, 3S)-8, were synthesized and used as radical probes to investigate the mechanism of the HppE-catalyzed reaction. Upon treatment with HppE, (2S, 3R)-8 and (2S, 3S)-8 were converted via a C1 radical intermediate to the corresponding epoxide products, as anticipated. In contrast, incubation of HppE with (2R, 3R)-8 led to enzyme inactivation, and incubation of HppE with (2R, 3S)-8 yielded the 2-keto product. The former finding is consistent with the formation of a C2 radical intermediate, where the inactivation is likely triggered by radical-induced ring cleavage of the methylenecyclopropyl group. Reaction with (2R, 3S)-8 is predicted to also proceed via a C2 radical intermediate, but no enzyme inactivation and no ring-opened product were detected. These results strongly suggest that an internal electron transfer to the iron center subsequent to C-H homolysis competes with ring-opening in the processing of the C2 radical intermediate. The different outcomes of the reactions with (2R, 3R)-8 and (2R, 3S)-8 demonstrate the need to carefully consider the chirality of substituted cyclopropyl groups as radical reporting groups in studies of enzymatic mechanisms.

Initial characterization of Fom3 from Streptomyces wedmorensis: The methyltransferase in fosfomycin biosynthesis

Fosfomycin is a broad-spectrum antibiotic that is useful against multi-drug resistant bacteria. Although its biosynthesis was first studied over 40 years ago, characterization of the penultimate methyl transfer reaction has eluded investigators. The enzyme believed to catalyze this reaction, Fom3, has been identified as a radical S-adenosyl-L-methionine (SAM) superfamily member. Radical SAM enzymes use SAM and a four-iron, four-sulfur ([4Fe-4S]) cluster to catalyze complex chemical transformations. Fom3 also belongs to a family of radical SAM enzymes that contain a putative cobalamin-binding motif, suggesting that it uses cobalamin for methylation. Here we describe the first biochemical characterization of Fom3 from Streptomyces wedmorensis. Since recombinant Fom3 is insoluble, we developed a successful refolding and iron-sulfur cluster reconstitution procedure. Spectroscopic analyses demonstrate that Fom3 binds a [4Fe-4S] cluster which undergoes a transition between a +2 "resting" state and a +1 active state characteristic of radical SAM enzymes. Site-directed mutagenesis of the cysteine residues in the radical SAM CxxxCxxC motif indicates that each residue is essential for functional cluster formation. We also provide preliminary evidence that Fom3 adds a methyl group to 2-hydroxyethylphosphonate (2-HEP) to form 2-hydroxypropylphosphonate (2-HPP) in an apparently SAM-, sodium dithionite-, and methylcobalamin-dependent manner.

Evidence that the fosfomycin-producing epoxidase, HppE, is a non-heme-iron peroxidase

The iron-dependent epoxidase HppE converts (S)-2-hydroxypropyl-1-phosphonate (S-HPP) to the antibiotic fosfomycin [(1R,2S)-epoxypropylphosphonate] in an unusual 1,3-dehydrogenation of a secondary alcohol to an epoxide. HppE has been classified as an oxidase, with proposed mechanisms differing primarily in the identity of the O2-derived iron complex that abstracts hydrogen (H•) from C1 of S-HPP to initiate epoxide ring closure. We show here that the preferred cosubstrate is actually H2O2 and that HppE therefore almost certainly uses an iron(IV)-oxo complex as the H• abstractor. Reaction with H2O2 is accelerated by bound substrate and produces fosfomycin catalytically with a stoichiometry of unity. The ability of catalase to suppress the HppE activity previously attributed to its direct utilization of O2 implies that reduction of O2 and utilization of the resultant H2O2 were actually operant.

Cloning, expression, and biochemical characterization of Streptomyces rubellomurinus genes required for biosynthesis of antimalarial compound FR900098

The antibiotics fosmidomycin and FR900098 are members of a unique class of phosphonic acid natural products that inhibit the nonmevalonate pathway for isoprenoid biosynthesis. Both are potent antibacterial and antimalarial compounds, but despite their efficacy, little is known regarding their biosynthesis. Here we report the identification of the Streptomyces rubellomurinus genes required for the biosynthesis of FR900098. Expression of these genes in Streptomyces lividans results in production of FR900098, demonstrating their role in synthesis of the antibiotic. Analysis of the putative gene products suggests that FR900098 is synthesized by metabolic reactions analogous to portions of the tricarboxylic acid cycle. These data greatly expand our knowledge of phosphonate biosynthesis and enable efforts to overproduce this highly useful therapeutic agent.

Purification and characterization of the epoxidase catalyzing the formation of fosfomycin from Pseudomonas syringae

The final step in the biosynthesis of fosfomycin in Streptomyces wedmorensis is catalyzed by ( S)-2-hydroxypropylphosphonic acid (HPP) epoxidase ( Sw-HppE). A homologous enzyme from Pseudomonas syringae whose encoding gene ( orf3) shares a relatively low degree of sequence homology with the corresponding Sw-HppE gene has recently been isolated. This purified P. syringae protein was determined to catalyze the epoxidation of ( S)-HPP to fosfomycin and the oxidation of ( R)-HPP to 2-oxopropylphosphonic acid under the same conditions as Sw-HppE. Therefore, this protein is indeed a true HPP epoxidase and is termed Ps-HppE. Like Sw-HppE, Ps-HppE was determined to be post-translationally modified by the hydroxylation of a putative active site tyrosine (Tyr95). Analysis of the Fe(II) center by EPR spectroscopy using NO as a spin probe and molecular oxygen surrogate reveals that Ps-HppE's metal center is similar, but not identical, to that of Sw-HppE. The identity of the rate-determining step for the ( S)-HPP and ( R)-HPP reactions was determined by measuring primary deuterium kinetic effects, and the outcome of these results was correlated with density functional theory calculations. Interestingly, the reaction using the nonphysiological substrate ( R)-HPP was 1.9 times faster than that with ( S)-HPP for both Ps-HppE and Sw-HppE. This is likely due to the difference in bond dissociation energy of the abstracted hydrogen atom for each respective reaction. Thus, despite the low level of amino acid sequence identity, Ps-HppE is a close mimic of Sw-HppE, representing a second example of a non-heme iron-dependent enzyme capable of catalyzing dehydrogenation of a secondary alcohol to form a new C-O bond.

Heterologous production of fosfomycin and identification of the minimal biosynthetic gene cluster

Fosfomycin is a clinically utilized, highly effective antibiotic, which is active against methicillin- and vancomycin-resistant pathogens. Here we report the cloning and characterization of a complete fosfomycin biosynthetic cluster from Streptomyces fradiae and heterologous production of fosfomycin in S. lividans. Sequence analysis coupled with gene deletion and disruption revealed that the minimal cluster consists of fom1-4, fomA-D. A LuxR-type activator that was apparently required for heterologous fosfomycin production was also discovered approximately 13 kb away from the cluster and was named fomR. The genes fomE and fomF, previously thought to be involved in fosfomycin biosynthesis, were shown not to be essential by gene disruption. This work provides new insights into fosfomycin biosynthesis and opens the door for fosfomycin overproduction and creation of new analogs via biomolecular pathway engineering.

S-adenosylmethionine as an oxidant: the radical SAM superfamily

A recently discovered superfamily of enzymes function using chemically novel mechanisms, in which S-adenosylmethionine (SAM) serves as an oxidizing agent in DNA repair and the biosynthesis of vitamins, coenzymes and antibiotics. Members of this superfamily, the radical SAM enzymes, are related by the cysteine motif CxxxCxxC, which nucleates the [4Fe-4S] cluster found in each. A common thread in the novel chemistry of these proteins is the use of a strong reducing agent--a low-potential [4Fe-4S](1+) cluster--to generate a powerful oxidizing agent, the 5'-deoxyadenosyl radical, from SAM. Recent results are beginning to determine the unique biochemistry for some of the radical SAM enzymes, for example, lysine 2,3 aminomutase, pyruvate formate lyase activase and biotin synthase.

Rings, radicals, and regeneration: the early years of a bioorganic laboratory

This Perspective provides an overview of the progress in two of the original programs in my research group focused on the biosynthesis of the antibiotics nisin, lacticin 481, fosfomycin, and bialaphos. The path from start-up funds to tenure and beyond offers insights into the opportunities realized and missed along the road.

New insight into the mechanism of methyl transfer during the biosynthesis of fosfomycin

Hydroxyethylphosphonate is a required intermediate in fosfomycin biosynthesis.

Biosynthesis of fosfomycin, re-examination and re-confirmation of a unique Fe(II)- and NAD(P)H-dependent epoxidation reaction

(S)-2-Hydroxypropylphosphonic acid epoxidase (HppE) catalyzes the epoxide ring closure of (S)-HPP to form fosfomycin, a clinically useful antibiotic. Early investigation showed that its activity can be reconstituted with Fe(II), FMN, NADH, and O2 and identified HppE as a new type of mononuclear non-heme iron-dependent oxygenase involving high-valent iron-oxo species in the catalysis. However, a recent study showed that the Zn(II)-reconstituted HppE is active, and HppE exhibits modest affinity for FMN. Thus, a new mechanism is proposed in which the active site-bound Fe2+ or Zn2+ serves as a Lewis acid to activate the 2-OH group of (S)-HPP and the epoxide ring is formed by the attack of the 2-OH group at C-1 coupled with the transfer of the C-1 hydrogen as a hydride ion to the bound FMN. To distinguish between these mechanistic discrepancies, we re-examined the bioautography assay, the basis for the alternative mechanism, and showed that Zn(II) cannot replace Fe(II) in the HppE reaction and NADH is indispensable. Moreover, we demonstrated that the proposed role for FMN as a hydride acceptor is inconsistent with the finding that FMN cannot bind to HppE in the presence of substrate. In addition, using a newly developed HPLC assay, we showed that several non-flavin electron mediators could replace FMN in the HppE-catalyzed epoxidation. Taken together, these results do not support the newly proposed "nucleophilic displacement-hydride transfer" mechanism but are fully consistent with the previously proposed iron-redox mechanism for HppE catalysis, which is unique within the mononuclear non-heme iron enzyme superfamily.

Site-directed mutagenesis and spectroscopic studies of the iron-binding site of (S)-2-hydroxypropylphosphonic acid epoxidase

(S)-2-Hydroxylpropanylphosphonic acid epoxidase (HppE) is a novel type of mononuclear non-heme iron-dependent enzyme that catalyzes the O2 coupled, oxidative epoxide ring closure of HPP to form fosfomycin, which is a clinically useful antibiotic. Sequence alignment of the only two known HppE sequences led to the speculation that the conserved residues His138, Glu142, and His180 are the metal binding ligands of the Streptomyces wedmorensis enzyme. Substitution of these residues with alanine resulted in significant reduction of metal binding affinity, as indicated by EPR analysis of the enzyme-Fe(II)-substrate-nitrosyl complex and the spectral properties of the Cu(II)-reconstituted mutant proteins. The catalytic activities for both epoxidation and self-hydroxylation were also either eliminated or diminished in proportion to the iron content in these mutants. The complete loss of enzymatic activity for the E142A and H180A mutants in vivo and in vitro is consistent with the postulated roles of the altered residues in metal binding. The H138A mutant is also inactive in vivo, but in vitro it retains 27% of the active site iron and nearly 20% of the wild-type activity. Thus, it cannot be unequivocally stated whether H138 is an iron ligand or simply facilitates iron binding due to proximity. The results reported herein provide initial evidence implicating an unusual histidine/carboxylate iron ligation in HppE. By analogy with other well-characterized enzymes from the 2-His-1-carboxylate family, this type of iron core is consistent with a mechanism in which both oxygen and HPP bind to the iron as a first step in the in the conversion of HPP to fosfomycin.

Structure and reactivity of hydroxypropylphosphonic acid epoxidase in fosfomycin biosynthesis by a cation- and flavin-dependent mechanism

The biosynthesis of fosfomycin, an oxirane antibiotic in clinical use, involves a unique epoxidation catalyzed by (S)-2-hydroxypropylphosphonic acid epoxidase (HPPE). The reaction is essentially dehydrogenation of a secondary alcohol. A high-resolution crystallographic analysis reveals that the HPPE subunit displays a two-domain combination. The C-terminal or catalytic domain has the cupin fold that binds a divalent cation, whereas the N-terminal domain carries a helix-turn-helix motif with putative DNA-binding helices positioned 34 A apart. The structure of HPPE serves as a model for numerous proteins, of ill-defined function, predicted to be transcription factors but carrying a cupin domain at the C terminus. Structure-reactivity analyses reveal conformational changes near the catalytic center driven by the presence or absence of ligand, that HPPE is a Zn(2+)/Fe(2+)-dependent epoxidase, proof that flavin mononucleotide is required for catalysis, and allow us to propose a simple mechanism that is compatible with previous experimental data. The participation of the redox inert Zn(2+) in the mechanism is surprising and indicates that Lewis acid properties of the metal ions are sufficient to polarize the substrate and, aided by flavin mononucleotide reduction, facilitate the epoxidation.

Structural insight into antibiotic fosfomycin biosynthesis by a mononuclear iron enzyme

The biosynthetic pathway of the clinically important antibiotic fosfomycin uses enzymes that catalyse reactions without precedent in biology. Among these is hydroxypropylphosphonic acid epoxidase, which represents a new subfamily of non-haem mononuclear iron enzymes. Here we present six X-ray structures of this enzyme: the apoenzyme at 2.0 A resolution; a native Fe(II)-bound form at 2.4 A resolution; a tris(hydroxymethyl)aminomethane-Co(II)-enzyme complex structure at 1.8 A resolution; a substrate-Co(II)-enzyme complex structure at 2.5 A resolution; and two substrate-Fe(II)-enzyme complexes at 2.1 and 2.3 A resolution. These structural data lead us to suggest how this enzyme is able to recognize and respond to its substrate with a conformational change that protects the radical-based intermediates formed during catalysis. Comparisons with other family members suggest why substrate binding is able to prime iron for dioxygen binding in the absence of alpha-ketoglutarate (a co-substrate required by many mononuclear iron enzymes), and how the unique epoxidation reaction of hydroxypropylphosphonic acid epoxidase may occur.

Oxygenase activity in the self-hydroxylation of (s)-2-hydroxypropylphosphonic acid epoxidase involved in fosfomycin biosynthesis

The last step of the biosynthesis of fosfomycin is the conversion of (S)-2-hydroxypropylphosphonic acid (HPP) to fosfomycin by HPP epoxidase (HppE), which is a mononuclear non-heme iron-dependent enzyme. The apo-HppE from Streptomyces wedmorensis is colorless, but turns green with broad absorption bands at 430 and 680 nm after reconstitution with ferrous ion under aerobic conditions. Resonance Raman studies showed that this green chromophore arises from a bidentate iron(III)-catecholate (DOPA) complex, and the most likely site of modification is at Tyr105 on the basis of site-specific mutagenesis results. It was also found that reconstitution in the presence of ascorbate leads to the formation of additional DOPA that shows (18)O-incorporation from (18)O(2). Thus, HppE can act as an oxygenase via a putative high valent iron-oxo or an iron-hydroperoxo intermediate, just like other members of the family of non-heme iron enzymes. The oxygen activation mechanism for catalytic turnover is proposed to parallel that for self-hydroxylation.

On the transformation of (S)-2-hydroxypropylphosphonic acid into fosfomycin in Streptomyces fradiae--a unique method of epoxide ring formation

(1S,2S)- and (1R,2S)-2-hydroxy-[1-D(1)]propylphosphonic acid were synthesised from (1S,2S)-2-benzyloxy-[1-D(1)]propanol, which was obtained by horse liver alcohol dehydrogenase catalysed reduction of the corresponding aldehyde. When (1S,2S)-2-hydroxy-[1-D(1)]propylphosphonic acid was fed to Streptomyces fradiae, the deuterium was retained to the same extent in fosfomycin (cis-epoxide) and its co-metabolite trans-epoxide. Removal of the hydrogen (deuterium) atom from the C-1 atom of deuterated 2-hydroxypropylphosphonic acids is a stereospecific process (the hydrogen atom of (S)-2-hydroxypropylphosphonic acid is pro-R). The formation of the O--C-1 bond of fosfomycin occurs with net inversion of configuration, the formation of the O--C-1 bond of the trans-epoxide with net retention.

[The epoxidation of cis-propenylphophonic acid to fosfomycin by Pencillium sp]

One strain of Penicillium sp. F5, found from soil sample, was able to stereo-specific epoxidation of cis-propenylphosphonic acid(PPOH) to fosfomycin[(-)-(1R, 2S)-1, 2-epoxypropylphosphonic acid, FOM] during the cultivation. The product (FOM) was identified by thin layer chromatography and microbiological assay. Under the culture conditions of 28 degrees C pH7.5 and 280 r/min, 0.3% concentration of PPOH, reached a level of 2.2 mg/ml of FoM and the yield was 41%. When the PPOH concentration was 0.6%, the yield was 8%.

Characterization of the fomA and fomB gene products from Streptomyces wedmorensis, which confer fosfomycin resistance on Escherichia coli

Together, the fomA and fomB genes in the fosfomycin biosynthetic gene cluster of Streptomyces wedmorensis confer high-level fosfomycin resistance on Escherichia coli. To elucidate their functions, the fomA and fomB genes were overexpressed in E. coli and the gene products were characterized. The recombinant FomA protein converted fosfomycin to fosfomycin monophosphate, which was inactive on E. coli, in the presence of a magnesium ion and ATP. On the other hand, the recombinant FomB protein did not inactivate fosfomycin. However, a reaction mixture containing FomA and FomB proteins converted fosfomycin to fosfomycin monophosphate and fosfomycin diphosphate in the presence of ATP and a magnesium ion, indicating that FomA and FomB catalyzed phosphorylations of fosfomycin and fosfomycin monophosphate, respectively. These results suggest that the self-resistance mechanism of the fosfomycin-producing organism S. wedmorensis is mono- and diphosphorylation of the phosphonate function of fosfomycin catalyzed by FomA and FomB.

Cloning and expression in Escherichia coli of 2-hydroxypropylphosphonic acid epoxidase from the fosfomycin-producing organism, Pseudomonas syringae PB-5123

The fosfomycin resistance gene, fosC, has been cloned from the fosfomycin-producing organism, Pseudomonas syringae PB-5123. Sequence analysis upstream of this gene found a new ORF showing significant homology to 2-hydroxypropylphosphonic acid epoxidase from fosfomycin-producing Streptomyces wedmorensis. The purified recombinant protein of this ORF converted 2-hydroxypropylphosphonic acid to fosfomycin. This result clearly showed the ORF to encode 2-hydroxypropylphosphonic acid epoxidase in PB-5123.

Cloning and nucleotide sequence of fosfomycin biosynthetic genes of Streptomyces wedmorensis

The biosynthetic pathway for production of the antibiotic fosfomycin by Streptomyces wedmorensis consists of four steps including the formation of a C-P bond and an epoxide. Fosfomycin production genes were cloned from genomic DNA using S. wedmorensis mutants blocked at different steps of the biosynthetic pathway. Four genes corresponding to each of the biosynthetic steps were found to be clustered in a DNA fragment of about 5 kb. Nucleotide sequencing of a large fragment revealed the presence of ten open reading frames, including the four biosynthetic genes and six genes with unknown functions.

Optimum culture conditions for the epoxidation of cis-propenylphosphonate to fosfomycin by Cellvibrio gilvus

Approximately 470 strains of various microorganisms were tested for their ability to epoxidize cis-propenylphosphonate (PPOH) to (-)-cis-1,2-epoxypropylphosphonate (fosfomycin, FOM). Cellvibrio gilvus KY 3412 was selected as the best strain. To obtain higher activity, FOM-resistant strains were derived by N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. Mutant KY 3413, showing ten times higher FOM resistance, was selected. The conditions for the conversion of PPOH to FOM during the cultivation of the mutant were optimized. The addition of both cobalt and vanadium ions to the culture medium greatly stimulated the conversion. Furthermore, when the pH was maintained at pH 8.0 during cultivation, the highest conversion was attained. The molar conversion yield of FOM was inversely dependent on the initial concentration of PPOH, that is, conversions of 100% at less than 0.05% PPOH and of 40% at 0.5% PPOH were attained after 5 days cultivation.

Studies on new phosphonic acid antibiotics. I. FR-900098, isolation and characterization

A strain of Streptomyces, isolated from a soil sample and identified as Streptomyces rubellomurinus sp. nov., has been found to produce FR-900098, an interesting new antibiotic containing phosphorus in its molecule. The antibiotic, obtained as colorless crystals, was shown to inhibit a wide variety of Gram-negative bacteria including Pseudomonas, Proteus, and Escherichia coli. Its antibacterial action involves interference with bacterial cell wall synthesis as evidenced by the fact that it causes spheroplast formation by susceptible cells.