Identification and characterization of novel catalytic bioscavengers of organophosphorus nerve agents.

In an effort to discover novel catalytic bioscavengers of organophosphorus (OP) nerve agents, cell lysates from a diverse set of bacterial strains were screened for their capacity to hydrolyze the OP nerve agents VX, VR, and soman (GD). The library of bacterial strains was identified using both random and rational approaches. Specifically, two representative strains from eight categories of extremophiles were chosen at random. For the rational approach, the protein sequence of organophosphorus hydrolase (OPH) from Brevundimonas diminuta was searched against a non-redundant protein database using the Basic Local Alignment Search Tool to find regions of local similarity between sequences. Over 15 protein sequences with significant sequence similarity to OPH were identified from a variety of bacterial strains. Some of these matches were based on predicted protein structures derived from bacterial genome sequences rather than from bona fide proteins isolated from bacteria. Of the 25 strains selected for nerve agent testing, three bacterial strains had measurable levels of OP hydrolase activity. These strains are Ammoniphilus oxalaticus, Haloarcula sp., and Micromonospora aurantiaca. Lysates from A. oxalaticus had detectable hydrolysis of VR; Haloarcula sp. had appreciable hydrolysis of VX and VR, whereas lysates from M. aurantiaca had detectable hydrolysis of VR and GD.

Organophosphorus acid anhydrolase in slime mold, duckweed and mung bean: a continuing search for a physiological role and a natural substrate.

Recently, and for the first time, a diisopropylphosphorofluoridate (DFP)-hydrolyzing enzyme, i.e. an organophosphorus acid anhydrolase (OPAA), has been reported in a plant-source. Based on this and other suggestive evidence, the ability of three plant sources and a protist to hydrolyze DFP and 1,2,2-trimethylpropyl methylphosphonofluoridate (Soman) were tested, and the effects of Mn2+ and ethylenediamine tetraacetate (EDTA) on this activity. The plants are duckweed (Lemna minor), giant duckweed (Spirodela oligorhiza), and germinated mung bean (Vigna radiata); the protist is a slime mold (Dictyostelium discoidium). The tests are based on a crude classification of OPAAs as 'squid type' (DFP hydrolyzed more rapidly than Soman) and all of the others termed by us, with questionable justification, as 'Mazur type' (Soman hydrolyzed more rapidly than DFP). Of the two duckweeds, Spirodela oligorhiza hydrolyzes Soman but not DFP, and Lemna minor does not hydrolyze either substrate. In contrast to the report of Yu and Sakurai, mung bean does not hydrolyze DFP and hydrolyzes Soman with a 5-fold stimulation by Mn2+ and a marked inhibition by EDTA. The slime mold hydrolyzes Soman more rapidly than DFP (but does hydrolyze DFP) and the hydrolysis is Mn2+ stimulated. The failure of these plant sources to hydrolyze DFP is similar to the behavior of OPAA from Bacillus stearothermophilus.

Exploring the active center of human acetylcholinesterase with stereomers of an organophosphorus inhibitor with two chiral centers.

The stereoselectivity of the phosphonylation reaction and the effects of adduct configuration on the aging process were examined for human acetylcholinesterase (HuAChE) and its selected active center mutants, using the four stereomers of 1,2,2-trimethylpropyl methylphosphonofluoridate (soman). The reactivity of wild type HuAChE toward the PS-soman diastereomers was 4.0-7.5 x 10(4)-fold higher than that toward the PR-diastereomers. Aging of the PSCS-somanyl-HuAChE conjugate was also >1.6 x 10(4)-fold faster than that of the corresponding PRCS-somanyl adduct, as shown by both reactivation and electrospray mass spectrometry (ESI/MS) experiments. On the other hand, both processes exhibited very limited sensitivity to the chirality of the alkoxy group Calpha of either PS- or PR-diastereomers. These stereoselectivities presumably reflect the relative participation of the enzyme in stabilization of the Michaelis complexes and in dealkylation of the respective covalent conjugates, and therefore could be utilized for further probing of the HuAChE active center functional architecture. Reactivities of HuAChE enzymes carrying replacements at the acyl pocket (F295A, F297A, and F295L/F297V) indicate that stereoselectivity with respect to the soman phosphorus chirality depends on the structure of this binding subsite, but this stereoselectivity cannot be explained only by limitation in the capacity to accommodate the PR-diastereomers. In addition, these acyl pocket enzyme mutants display some (5-10-fold) preference for the PRCR-soman over the PRCS-stereomer, while reactivity of the hydrophobic pocket mutant enzyme W86F toward the PRCS-soman resembles that of the wild type HuAChE. Residue substitutions in the H-bond network (E202Q, E450A, Y133F, and Y133A) and the hydrophobic pocket (F338A, W86A, W86F, and Y337A) result in a limited stereoselectivity for the PSCS- over the PSCR-stereomer. Aging of the PS-somanyl conjugates with all the HuAChE mutant enzymes tested practically lacked stereoselectivity with respect to the Calpha of the alkoxy moiety. Thus, the inherent asymmetry of the active center does not seem to affect the rate-determining step of the dealkylation process, possibly because both the PSCS- and the PSCR-somanyl moieties yield the same carbocationic intermediate.

Distribution of [3H]diisopropylfluorophosphate, [3H]soman, [3H]sarin, and their metabolites in mouse brain.

The brain area distribution of [3H]diisopropylfluorophosphate, [3H]soman, and [3H]sarin and their metabolites in mice was studied after iv administration of sublethal doses. At the appropriate time after the injection of the radiolabeled organophosphate, the mice were decapitated and their brains were dissected into seven areas. There was a relatively even distribution of the parent compounds and their metabolites in all brain areas except the hypothalamus, which contained concentrations of parent compounds the metabolites that were 2-5 times greater than those in other brain areas. Concentrations of the parent compounds and free metabolites declined steadily throughout the time course, whereas concentrations of the bound metabolites remained relatively constant between 6 and 24 hr. There was no correlation between the disposition of soman, and its metabolites, and cholinesterase inhibition in brain areas, which implicates other central mechanisms in the production of organophosphate effects. However, the higher concentrations of organophosphates and their metabolites in the hypothalamus suggest that this area might be important with respect to the pharmacological effects or the toxicity of these compounds.

Two enzymes for the detoxication of organophosphorus compounds--sources, similarities, and significance.

An enzyme in E. coli that hydrolyzes diisopropylphosphorofluoridate (DFP) has now been found to hydrolyze the nerve gas 1,2,2- trimethylpropylmethylphosphonofluoridate (soman) many times faster. With either substrate the E. coli enzyme is stimulated manyfold by 10(-3) M Mn2+. These criteria are combined and applied to this, and to a superficially similar but distinctly different, enzyme found in squid nerve. The results suggest that while several tissues of the squid contain only this second kind of DFP hydrolyzing enzyme, termed squid type DFPase , many other sources including E. coli contain a mixture of squid type DFPase (the name not strictly indicative of source) and the other DFP hydrolyzing enzyme, now termed Mazur type DFPase . Procedures for the purification of Mazur type DFPase from hog kidney, while increasing the specific activity for DFP hydrolysis may actually have been enriching the purified material in the squid type DFPase . Because E. coli has the highest soman hydrolyzing capacity of any source so far examined, this organism is a promising source for the development of new purification procedures for Mazur type DFPase .