Utilization of Glyphosate as Phosphate Source: Biochemistry and Genetics of Bacterial Carbon-Phosphorus Lyase

SUMMARY

After several decades of use of glyphosate, the active ingredient in weed killers such as Roundup, in fields, forests, and gardens, the biochemical pathway of transformation of glyphosate phosphorus to a useful phosphorus source for microorganisms has been disclosed. Glyphosate is a member of a large group of chemicals, phosphonic acids or phosphonates, which are characterized by a carbon-phosphorus bond. This is in contrast to the general phosphorus compounds utilized and metabolized by microorganisms. Here phosphorus is found as phosphoric acid or phosphate ion, phosphoric acid esters, or phosphoric acid anhydrides. The latter compounds contain phosphorus that is bound only to oxygen. Hydrolytic, oxidative, and radical-based mechanisms for carbon-phosphorus bond cleavage have been described. This review deals with the radical-based mechanism employed by the carbon-phosphorus lyase of the carbon-phosphorus lyase pathway, which involves reactions for activation of phosphonate, carbon-phosphorus bond cleavage, and further chemical transformation before a useful phosphate ion is generated in a series of seven or eight enzyme-catalyzed reactions. The phn genes, encoding the enzymes for this pathway, are widespread among bacterial species. The processes are described with emphasis on glyphosate as a substrate. Additionally, the catabolism of glyphosate is intimately connected with that of aminomethylphosphonate, which is also treated in this review. Results of physiological and genetic analyses are combined with those of bioinformatics analyses.     

Topological analysis of tetraphosphorus oxides (P4O6+n (n = 0–4))

Quantum chemical calculations were used to analyze the chemical bonding and the reactivity of phosphorus oxides (P₄O_6+n (n?=?0–4)). The chemical bonding was studied using topological analysis such as atoms in molecules (AIM), electron localization function (ELF), and the reactivity using the Fukui function. A classification of the P-O bonds formed in all structures was done according to the coordination number in each P and O atoms. It was found that there are five P-O bond types and these are distributed among the five phosphorus oxides structures. Results showed that there is good agreement among the evaluated properties (length, bond order, density at the critical point, and disynaptic population) and each P-O bond type. It was found that regardless of the structure in which a P-O bond type is present the topological and geometric properties do not have a significant variation. The topological parameters electron density and Laplacian of electron density show excellent linear correlation with the average length of P-O bond in each bond type for each structure. From the Fukui function analysis it was possible to predict that from P₄O₆ until P₄O₈ the most reactive regions are basins over the P.     

Synthesis and X-ray crystal structures of organotri(2-furyl)phosphonium salts: effects of 2-furyl substituents at phosphorus on intramolecular nitrogen to phosphorus hypervalent coordinative interactions

The synthesis of tri(2-furyl)(8-quinolylmethyl)phosphonium bromide and 2-[2-tri(2-furyl)phosphoniophenyl]benzimidazole perchlorate is described, the latter involving a nickel(II)-catalysed displacement of bromine from 2-(2-bromophenyl)benzimidazole by tri(2-furyl)phosphine. X-ray structural studies of the phosphoniobenzimidazole salt reveals the existence of a significant hypervalent coordinative interaction between heterocyclic nitrogen and the phosphonium centre, which also appears to be retained in solution, the ³¹P NMR spectrum showing a significantly shielded phosphorus atom, δ³¹P=ca. 40 ppm in CDCl₃. The structure of the phosphoniophenylbenzimidazole cation reveals major distortion of bond angles about phosphorus away from the idealised tetrahedral angles expected for a tetraarylphosphonium salt, in the range 102-116°. Three of the angles are reduced below the tetrahedral angle and three are increased, the structure about phosphorus approaching that of a trigonal bipyramid, in which the heterocyclic imino nitrogen forms part of a five-membered ring spanning apical-equatorial positions. The apical axis of the trigonal bipyramid is formed by this nitrogen atom and one of the 2-furyl groups, the apical axial bond angle (N2-P-C14) being an average of 178°. The remaining 2-furyl groups occupy equatorial positions, along with the phenyl ring. Significantly, the nitrogen-phosphorus distance is an average of 2.67 Å (for two independent molecules in the unit cell), being the shortest observed in structures of this type, a consequence of the electron-withdrawing properties of the 2-furyl substituents at phosphorus. The structure also shows edge to face associations of 2-furyl substituents of one cation with the phenyl ring of the benzimidazole unit of another cation. The perchlorate anion is hydrogen-bonded to the nitrogen bearing the hydrogen atom in the benzimidazole ring system. In contrast, the N-P interaction in the quinolylmethylphosphonium salt is much less developed, with an N-P distance of 3.511 Å, although there is considerable deformation of bond angles at phosphorus. The crystal structure is dominated by the existence of hydrogen-bonded interactions between the cation, anion and a molecule of water, and by face to face interactions between cations. Both salts undergo loss of a 2-furyl group on treatment with hydroxide ion.     

Six-coordinate phosphorus compounds. Crystal structures and dynamic NMR studies of phosphoranes containing chelating ligands

Hexacoordination of the neutral phosphorus compounds 4–6 is evidenced by their high field ³¹P NMR chemical shifts and is further substantiated by the crystal structure of 5 and 6.5 contains the potentially bis-chelating ligand Ar = (C₆H₃(CH₂NMe₂)₂-2,6) and 6 the same ligand with a protonated amino group. In both cases the compounds exhibit slightly distorted octahedral geometry. In compound 5, only one NMe₂ group is coordinated to the phosphorus atom with an N → P bond of 2.063 Å. In compound 6, the NMe₂ group is coordinated to the phosphorus atom with an N → P bond of 2.007 Å while the dimethylammonium substituent is pointing away from the phosphorus atom forming a hydrogen bridge with two oxygen atoms. The fluxional behavior of these three novel six-coordinate phosphorus compounds was studied by dynamic ¹H NMR spectroscopy.     

Inhibition of human alpha-thrombin by a phosphonate tripeptide proceeds via a metastable pentacoordinated phosphorus intermediate

X-ray crystallographic studies of human alpha-thrombin with a novel synthetic inhibitor, an acyl (alpha-aminoalkyl)phosphonate, reveal the existence of a pentacovalent phosphorus intermediate state. Crystal structures of the complex of alpha-thrombin with the phosphonate compound were determined independently using crystals of different ages. The first structure, solved from a crystal less than seven days old, showed a pentacoordinated phosphorus moiety. The second structure, determined from a crystal that was 12 weeks old, showed a tetracoordinated phosphorus moiety. In the first structure, a water molecule, made nucleophilic by coordination to His57 of alpha-thrombin, is bonded to the pentacoordinated phosphorus atom. Its position is approximately equivalent to that occupied by the water molecule responsible for hydrolytic deacylation during normal hydrolysis. The pentacoordinated phosphorus adduct collapses to give the expected pseudo tetrahedral complex, where the phosphorus atom is covalently bonded to Ser195 O(gamma). The crystallographic data presented here therefore suggest that the covalent bond formed between the inhibitor's phosphorus atom and O(gamma) of Ser195 proceeds via an addition-elimination mechanism, which involves the formation of a pentacoordinate intermediate.     

Utilisation of structurally diverse organophosphonates by Streptomycetes

A group of streptomycete strains was found able to utilise a wide range of structurally diverse phosphonates as a sole phosphorus source. No relation could be observed between ability to synthesise compounds containing a direct carbon-to-phosphorus (C-P) bond and biodegradative potential towards phosphonates in the strains studied. Streptomyces morookaensis DSM 40565 could degrade 2-amino-4-phosphonobutyrate as a sole nitrogen and phosphorus source in a stereoselective-like manner. This result suggests the existence of a new metabolic pathway for C-P bond breakage.     

31P NMR and computational studies on stereochemistry of conversion of phosphoramidate diesters into the corresponding phosphotriesters

31P NMR spectroscopy was used to investigate a stereochemical course of a nitrite-promoted conversion of phosphoramidate diesters into the corresponding phosphotriesters. It was found that this reaction occurred with almost complete epimerization at the phosphorus center and at the C1 atom in the amine moiety. On the basis of the 31P NMR data, a plausible mechanism for the reaction was proposed. The density functional theory calculation of the key step of the reaction, i.e., breaking of the P-N bond and formation of the P-O bond, suggested a one-step S(N)2(P) process with retention of configuration at the phosphorus center.     

Stereochemistry of cleavage of internucleotide bonds by Serratia marcescens endonuclease.

Endonuclease from Serratia marcescens hydrolyzes internucleotide phosphorothioate linkages of R(P) configuration with inversion of configuration at P-atom. This observation supports a reported architecture of the active site, with 3'-bridging and pro-S(P) non-bridging oxygen atoms of the scissile phosphate group involved in direct contact with hydrated magnesium cation, while His-89 activates a water molecule which attacks the phosphorus atom according to a one-step in-line mechanism. The presence of a phosphorothioate bond of S(P) configuration downstream to that one being cleaved reduces the rate of hydrolysis. This suggests participation of the pro-S(P) oxygen atom of that phosphate bond in the mechanism of action of the enzyme, which was not detected in published crystallographic analyses.     

Review: Organophosphonates: occurrence, synthesis and biodegradation by microorganisms

The organophosphonates are biogenic and xenobiotic compounds characterized by the presence of a stable carbon to phosphorus (C-P) bond. The C-P bond imparts upon these molecules a relative resistance to (bio)degradation and fears have been expressed over their environmental recalcitrance and possible ecotoxicity, as more than 20×103 tonnes of these compounds enter the environment annually in the U.S.A. and western Europe alone (Egli, 1988). Biodegradation of organophosphonates is generally accepted to be dependent upon the phosphate status of the cell, with biodegradation occurring only under conditions of phosphate limitation. In recent years, however, several novel bacteria capable of completely mineralizing both natural and man-made organophosphonates have been isolated. These organisms represent a departure, both at a physiological and genetic level, from the accepted consensus that organophosphonates are utilized only phosphorus sources. This review covers all aspects of our knowledge of organophosphonate metabolism over the last 50 years, concentrating on the advances made in the last 10 years.     

Activities of native and tyrosine-69 mutant phospholipases A2 on phospholipid analogues. A reevaluation of the minimal substrate requirements

The role of Tyr-69 of porcine pancreatic phospholipase A2 in substrate binding was studied with the help of proteins modified by site-directed mutagenesis and phospholipid analogues with a changed head-group geometry. Two mutants were used containing Phe and Lys, respectively, at position 69. Modifications in the phospholipids included introduction of a sulfur at the phosphorus (thionophospholipids), removal of the negative charge at phosphorus (phosphatidic acid dimethyl ester), and reduction (phosphonolipids) or extension (diacylbutanetriol choline phosphate) of the distance between the phosphorus and the acyl ester bond. Replacement of Tyr-69 by Lys reduces enzymatic activity, but the mutant enzyme retains both the stereospecificity and positional specificity of native phospholipase A2. The Phe-69 mutant not only hydrolyzes the Rp isomer of thionophospholipids more efficiently than the wild-type enzyme, but the Sp thiono isomer is hydrolyzed too, although at a low (approximately 4%) rate. Phosphonolipids are hydrolyzed by native phospholipase A2 about 7 times more slowly than natural phospholipids, with retention of positional specificity and a (partial) loss of stereospecificity. The dimethyl ester of phosphatidic acid is degraded efficiently in a calcium-dependent and positional-specific way by native phospholipase A2 and by the mutants, indicating that a negative charge at phosphorus is not an absolute substrate requirement. The activities on the phosphatidic acid dimethyl ester of native enzyme and the Lys-69 mutant are lower than those on the corresponding lecithin, in contrast to the Phe-69 mutant, which has equal activities on both substrates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microbial metabolism of sulfurand phosphorus-containing xenobiotics

Abstract: The enzymes involved in the microbial metabolism of many important phosphorus- or sulfur-containing xenobiotics, including organophosphate insecticides and precursors to organosulfate and organosulfonate detergents and dyestuffs have been characterized. In several instances their genes have been cloned and analysed. For phosphonate xenobiotics, the enzyme system responsible for the cleavage of the carbon-phosphorus bond has not yet been observed in vitro, though much is understood on a genetic level about phosphonate degradation. Phosphonate metabolism is regulated as part of the Pho regulon, under phosphate starvation control. For organophosphorothionate pesticides the situation is not so clear, and the mode of regulation appears to depend on whether the compounds are utilized to provide phosphorus, carbon or sulfur for cell growth. The same is true for organosulfonate metabolism, where different (and differently regulated) enzymatic pathways are involved in the utilization of sulfonates as carbon and as sulfur sources, respectively. Observations at the protein level in a number of bacteria suggest that a regulatory system is present which responds to sulfate limitation and controls the synthesis of proteins involved in providing sulfur to the cell and which may reveal analogies between the regulation of phosphorus and sulfur metabolism.     

Syntheses and Degradation of Cyclic Phosphorus Esters Derived from Saligenin and Its Analogues

Some cyclic phosphorus esters were prepared from o-hydroxybenzyl alcohol and its analogues. They reacted with nucleophilic agents to open their heterocyclic ring at P-O-C (aryl) bond. Phosphate ion catalyzed the hydrolysis of the cyclic phosphorus esters under a mild condition. An intermediate hydrolysate was separated by paper electrophoresis.     

Alkylation reaction of phosphorus oxyacids.

Alkylation reactions of phosphorus oxyacids (i.e. phosphoric acid, phosphorous acid, hypophosphorous acid) were examined by means of several methods for the synthesis of the corresponding esters. These reactions were applied to the synthesis of oligonucleotide having phosphotriester bond or phosphonate diester bond.     

31P NMR and Computational Studies on Stereochemistry of Conversion of Phosphoramidate Diesters into the Corresponding Phosphotriesters

³¹P NMR spectroscopy was used to investigate a stereochemical course of a nitrite-promoted conversion of phosphoramidate diesters into the corresponding phosphotriesters. It was found that this reaction occurred with almost complete epimerization at the phosphorus center and at the C1 atom in the amine moiety. On the basis of the ³¹P NMR data, a plausible mechanism for the reaction was proposed. The density functional theory calculation of the key step of the reaction, i.e., breaking of the P–N bond and formation of the P–O bond, suggested a one-step S_N2(P) process with retention of configuration at the phosphorus center.     

Energetics of RNA cleavage: implications for the mechanism of action of ribozymes.

A new class of ribozymes produce 2',3'-cyclic phosphate upon self-catalyzed cleavage of RNA molecules, similar to those observed during enzymatic (RNase-catalyzed) as well as non-enzymatic hydrolyses of RNAs. This product suggests that the reaction intermediate/transition state is a pentacoordinated oxyphosphorane. In order to elucidate the energetics of these RNA cleaving reactions, the reaction coordinate has been simulated and a pentacoordinated intermediate has been characterized via ab initio molecular orbital calculations utilizing the dianionic hydrolysis-intermediate of methyl ethylene phosphate as a model compound. The calculated reaction coordinate indicates that the transition state for the P-O(2') bond cleavage is lower in energy than that for the P-O(5') bond cleavage under uncatalyzed conditions. Thus, the dianionic pentacoordinated phosphorus intermediate tends to revert back to the starting RNA by cleaving the P-O(2') bond rather than productively cleaving the P-O(5') bond. In order for ribozymes to effectively cleave RNA molecules, it is therefore mandatory to stabilize the leaving 5'-oxygen, e.g. by means of a divalent magnesium ion.     

cAMPS derivatives. A minireview over synthetic medicinal chemistry

Cyclic nucleosides belonging to the cAMPS system can exert antagonistic or agonistic effects on the cAMP/PKA type 1 inhibitory pathway affecting T-lymphocyte replications. The stereochemistry at the phosphorus atom in the phosphate group is important for the expressed selectivity. The two stereoisomers at the phosphorus atom in the phosphate arise by selective replacements of one of the oxygens pendant from the phosphorus atom by a sulfur atom. Methods for the preparation of cAMPS derivatives as stereochemical mixtures at the phosphorus atom and separation of stereoisomers have been developed into highly stereoselective syntheses. Methods for halogenation in the purine 8-position afford corresponding halides. Heteronucleophilic substitution of the halides afford corresponding amines, ethers or sulfides. Transition metal catalysis for carbylation of the 8-halides affords simple and efficient routes for the preparation of 8-aryl, 8-hetaryl or 8-alkyl cAMPS derivatives. Preparations of prodrugs for improved cell membrane penetration are described. The prodrugs are S-alkylated derivatives which are constructed for selective cleavage of the SP bond by an esterase to regenerate the bioactive cAMPS species at the site of the desired action.     

Stereochemical and positional specificity of the lipase/acyltransferase produced by Aeromonas hydrophila.

Aeromonas species secrete a glycerophospholipid-cholesterol acyltransferase (GCAT) which shares many properties with mammalian plasma lecithin-cholesterol acetyltransferase (LCAT). We have studied the stereochemical and positional specificity of GCAT against a variety of lipid substrates using NMR spectroscopy as well as other assay methods. The results show that both the primary and secondary acyl ester bonds of L-phosphatidylcholine can be hydrolyzed but only the sn-2 fatty acid can be transferred to cholesterol. The enzyme has an absolute requirement for the L configuration at the sn-2 position of phosphatidylcholine. The secondary ester bond of D-phosphatidylcholine cannot be hydrolyzed, and this lipid is not a substrate for acyl transfer. In contrast to the phospholipases, but similar to LCAT, the enzyme does not interact stereochemically with the phosphorus of phosphatidylcholine. In fact, the phosphorus is not required for enzyme activity, as GCAT will also hydrolyze monolayers of diglyceride, although at much lower rates.     

Utilization of organophosphonates by environmental micro-organisms

A survey of the utilization by environmental micro-organisms of a range of compounds containing the carbon–phosphorus (C–P) bond was carried out. Elective culture studies indicated that 15 of 19 alkylphosphonates tested served only as a sole source of phosphorus for microbial growth. Their metabolism did not lead to the extracellular release of inorganic phosphate. However, four organophosphonates—phosphonoacetate, phosphonoalanine, 2-aminoethylphosphonate and phosphonomycin—supported microbial growth when supplied as either a phosphorus source or as a carbon and energy source, with near-quantitative inorganic phosphate release. Four of five aminoalkylphosphonates tested were also utilized as a nitrogen source in the presence of 1 mmol l⁻¹ inorganic phosphate. In a subsequent screening programme, 99% of bacterial isolates tested were able to utilize 2-aminoethylphosphonate as a sole phosphorus source, 61% as a nitrogen source, 10% as a source of nitrogen and phosphorus, and 2% as a source of carbon, nitrogen and phosphorus ; 2% of isolates used phosphonoalanine as a nitrogen source. These results suggest that the uptake and metabolism of organophosphonates by bacteria is less `tightly' regulated by phosphorus starvation than has previously been supposed.     

Restrained molecular dynamics studies on complex of adriamycin with DNA hexamer sequence d-CGATCG

Adriamycin is an anthracycline anticancer drug used widely for solid tumors in spite of its adverse side effects. The solution structure of 2:1 adriamycin-d-(CGATCG)(2) complex has been studied by restrained molecular dynamics simulations. The restraint data set consists of several intramolecular and intermolecular nuclear Overhauser enhancement cross-peaks obtained from two-dimensional nuclear magnetic resonance spectroscopy data. The drug is found to intercalate between CG and GC base pairs at two d-CpG sites. The drug-DNA complex is stabilized via specific hydrogen bonding and van der Waal's interactions involving 4OCH(3), O5, 6OH, and NH(3)(+) moiety of daunosamine sugar, and rings A protons. The O-glycosidic bond C7-O7-C1'-C2' lies in the range 138 degrees -160 degrees during the course of simulations. The O6-H6...O5 hydrogen bond is stable while O11-H11...O12 hydrogen bond is not favored. The intercalating base pairs are buckled and minor groove is wider in the complex. The phosphate on one strand at intercalation site C1pG2 is in B(I) conformation and the phosphates directly lying on opposite strand is in B(II) conformation. The phosphorus on adjacent site G2pA3 is in B(II) conformation and hence a distinct pattern of B(I) and B(II) conformations is induced and stabilized. The role of various functional groups by which the molecular action is mediated has been discussed and correlated to the available biochemical evidence.     

Involvement of the phosphate regulon and the psiD locus in carbon-phosphorus lyase activity of Escherichia coli K-12.

Escherichia coli K-12 can readily mutate to use methylphosphonic acid as the sole phosphorus source by a direct carbon-to-phosphorus (C-P) bond cleavage activity that releases methane and Pi. The in vivo C-P lyase activity is both physiologically and genetically regulated as a member of the phosphate regulon. Since psiD::lacZ(Mu d1) mutants cannot metabolize methylphosphonic acid, psiD may be the structural gene(s) for C-P lyase.