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.

Degradation of nerve gases by CLECS and cells: kinetics of heterogenous systems.

We have reported the enzymatic hydrolysis of phosphoro- and phosphonofluoridates and phosphoro- and phosphonothiolates and -thionates by an organophosphorus hydrolase (OPH) from Pseudomonas diminuta. In screening for other microbial sources of nerve gas hydrolyzing enzymes, it would be convenient, indeed essential, to be able to determine such hydrolyses on intact cells. As a preliminary step to such screening we have measured the hydrolysis of O,O-diisopropyl S-(2-diisopropylaminoethyl) phosphorothiolate (Tetriso) and O,O-diethyl S-(2-ethylthioethyl) phosphorothiolate (Demeton-S; formerly Isosystox) by intact cells and sonicates. The purified OPH has also been cross-linked to itself (CLEC = cross-linked enzyme crystals) and this has also been tested for its ability to hydrolyze Tetriso and Demeton-S. The testing of such heterogenous systems by a spectrophotometric assay (Ellman) has required novel modifications. Our findings are that both Tetriso and Demeton-S are subject to intact-cell assay, that both are readily hydrolyzed by the CLEC-ed OPH without marked change in kinetics, but that at any given substrate concentration Tetriso is hydrolyzed much more rapidly. However, since Demeton-S is commercially available, this appears to be the substrate most suitable for screening for our final goal in a search for sources of enzymes to detoxify O-ethyl S-(2-diisopropylaminoethyl) methylphosphonothiolate (VX).

Hydrolysis of tetriso by an enzyme derived from Pseudomonas diminuta as a model for the detoxication of O-ethyl S-(2-diisopropylaminoethyl) methylphosphonothiolate (VX).

An enzyme termed organophosphorus hydrolase (OPH), derived from Pseudomonas diminuta, had been found previously to hydrolyze the powerful acetylcholinesterase (AChE) inhibitor O-ethyl S-(2-diisopropylaminoethyl) methylphosphonothiolate (VX). This enzyme has now been shown to be correlated with the loss of AChE inhibitory potency (detoxication). OPH also hydrolyzed and detoxified the VX analogue, O,O-diisopropyl S-(2-diisopropylaminoethyl) phosphorothiolate (Tetriso), also a potent AChE inhibitor, about five times faster than VX. The Km for the hydrolysis of the P-S bond of Tetriso was 6.7 x 10(-3) M. OPH also hydrolyzed diisopropylphosphorofluoridate (DFP) 50-60 times faster than Tetriso, and 1,2,2-trimethylpropyl methylphosphonofluoridate (Soman) about seven times faster than Tetriso. DFP was a non-competitive inhibitor of Tetriso hydrolysis, Ki = 8.7 x 10(-4) M. The DFP hydrolysis product, diisopropyl phosphate, was a competitive inhibitor, Ki = 2.3 x 10(-4) M. The rate of detoxication of Tetriso compared with the rate of hydrolysis suggests that OPH may not be totally specific for P-S bond cleavage. OPH was inhibited completely by 1.5 x 10(-4) M 8-hydroxyquinoline-5-sulfonate or 1,10-phenanthroline, both transition element chelators, but inhibited only partially by EDTA, a much more potent chelator.

Polyclonal antibody generation in rabbit by administration of an organophosphorus acid anhydrolase (OPAA) from squid.

When a nerve gas hydrolyzing enzyme [organophosphorus acid anhydrolase (OPAA), formerly DFPase] purified from squid hepatopancreas was injected into rabbits, the resulting sera (RAS) inhibited OPAA purified from either squid hepatopancreas or squid optic ganglia. The inhibition was non-competitive, with 50% inhibition at a 1:1,000 serum dilution, and with the limit of inhibition (in effect, a "titer") at approximately 1:10,000. This RAS did not inhibit the distinctly different OPAAs from a mammalian and two bacterial sources. The hepatopancreas-generated RAS also reacted positively to the appropriate enzyme-linked immunosorbent assay (ELISA) at a titer of 1:100,000. In marked contrast, when OPAA purified from squid optic ganglion was injected into rabbits, the resulting sera did not inhibit squid OPAA, and did not give a positive ELISA. Control sera taken from the same rabbits prior to any injection (RS) did not inhibit the OPAAs. These results show another major difference between squid type OPAAs and the OPAAs from other sources, sometimes termed "Mazur type" OPAAs.

Biopolymer metal catalysts for the hydrolysis of nerve gases.

Glucosamine oligomers--monomer through tetramer--form complexes with Cu2+ that catalyse the hydrolysis of the 'nerve gas' 1,2,2-trimethylpropyl- methylphosphonofluroidate (soman) by cleaving the P-F bond. A 1/1 glucosamine/Cu2+ ratio whether as glucosamine or glucosamine units, gives the highest hydrolytic rate over the 11.5/1 to 1/1 range. This trend also appears to hold for a glucosamine polymer, chitosan, which, when complexed with Cu2+ also hydrolyzes soman. The relatively low rate of hydrolysis by this polymer-Cu2+ complex, while not yet explainable, is consistent with an extrapolation of the monomer-through-tetramer series. The question may be raised as to whether these biopolymer metal complexes provide any clues to the involvement of Mn2+ in the functioning of one class of P-F cleaving enzymes.

Stereoselectivity of soman detoxication by organophosphorus acid anhydrases from Escherichia coli.

Three organophosphorus acid anhydrases have been isolated from E. coli by gel filtration and ion exchange column procedures, and further identified by gel electrophoresis. All three have molecular weights in the 120,000-140,000 range. Two of them hydrolyze racemic 1,2,2-trimethylpropylmethylphosphonofluoridate (soman) to completion at a single rate and, in parallel with this, detoxify soman at a comparable rate. The third enzyme appears to show stereoselectivity with respect to the two pairs of isomers of soman in that it hydrolyzes the racemic mixture at a fast and a slow rate, the latter approaching the non-enzymatic rate, and detoxifies soman only at the slower rate. In the past, organophosphorus acid anhydrases from bacterial and mammalian sources have been assayed either as crude sonicates or homogenates, or as cold ethanol precipitated fractions. Major discrepancies among laboratories have probably been due either to the assay of mixtures of varying proportions of these three enzymes depending on the various organs or organisms used as the source, or to the purification of one of the enzymes at the expense of the others. For E. coli, a fourth organophosphorus acid anhydrase is also present but at a considerably lower activity.

Genetic and biochemical evidence for the lack of significant hydrolysis of soman by a Flavobacterium parathion hydrolase.

Pure recombinant Flavobacterium parathion hydrolase (an organophosphorus acid anhydrase) from Streptomyces lividans was found to hydrolyze the toxic nerve agent soman at only 0.1% of the rate observed with parathion as substrate. Studies with wild-type and recombinant strains of S. lividans support the lack of significant soman breakdown by the hydrolase and also indicate the presence in S. lividans of other significant hydrolytic enzymatic activity towards soman.

Soman-hydrolyzing and -detoxifying properties of an enzyme from a thermophilic bacterium.

An enzyme that hydrolyzes soman (1,2,2-trimethylpropyl methylphosphonofluoridate) and two other phosphonofluoridates, but does not hydrolyze DFP (diisopropylphosphorofluoridate), has been partially purified from a rod-shaped spore-forming gram-positive OT (obligate thermophilic) bacterium. The enzyme shows a marked Mn2+ stimulation, and in this and its substrate preference does not resemble the organophosphorus acid anhydrolase (sometimes termed DFPase) found in squid. Like the squid enzyme, it is not inhibited by mipafox (N,N'-diisopropylphosphordiamidofluoridate), is not inactivated by ammonium sulfate, and does hydrolyze the acetylcholinesterase-inhibitory pair of diastereoisomers of soman as well as the relatively noninhibitory pair, thus detoxifying soman. In these three properties the OT enzyme does not resemble the ubiquitous organophosphorus acid anhydrolase often purified from mammalian and bacterial sources by cold ethanol fractionation. Thus this phosphono-specific OT enzyme may have a natural substrate and a physiological role distinct from other organophosphorus acid anhydrolases.

An organofluorophosphate-hydrolyzing activity in Tetrahymena thermophila.

An enzymatic activity that hydrolyzes O,O-diisoproplyphosphofluoridate (DFP) and O-1,2,2-trimethylpropylmethylphosphonofluoridate (Soman) was discovered in the ciliate protozoan Tetrahymena thermophila. The enzymatic activity classifies the protein as Mazur-type similar to that found in hog kidney and Escherichia coli. The rate of hydrolysis of Soman by the Tetrahymena-extract is the highest, on a per gram of extract basis, of any eucaryote. The molecular weight is approximately 75,400 as determined by Sephacryl column chromatography. A maximum fifteen-fold purification has been achieved. Potential exists for the detoxification and one-step detection of common organofluorophosphate pollutants. Additionally, Tetrahymena should prove an easier subject for manipulation than mammalian or squid sources. Protozoa may be a potentially important source of detoxification and degradation enzymes for other environmental contaminants.

Inhibition of a soman- and diisopropyl phosphorofluoridate (DFP)-detoxifying enzyme by Mipafox.

Mipafox, N,N'-diisopropylphosphordiamidofluoridate, has been found to be a reversible competitive inhibitor of a diisopropyl phosphorofluoridate hydrolyzing enzyme (DFPase) isolated from hog kidney and Escherichia coli. Heretofore, this DFPase was characterized by its more rapid hydrolysis of Soman (1,2,2-trimethylpropyl methylphosphonofluoridate), its stimulation by Mn2+, and its wide distribution. In sharp contrast, Mipafox did not inhibit the DFPase found only in cephalopod nerve, hepatopancreas, and saliva, and further characterized by its more rapid hydrolysis of DFP than of Soman, and its indifference to Mn2+. Neither of these two DFPases hydrolyzed Mipafox.

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 .

Characterization of a DFP-hydrolyzing enzyme in squid posterior salivary gland by use of Soman, DFP and manganous ion.

1. A phosphorus-fluorine splitting enzyme (DFPase) from squid nerve hydrolyzes DFP 5-10 times faster than it hydrolyzes another P-F compound, Soman, whereas a superficially similar enzyme from rat kidney hydrolyzes Soman 20-40 times faster than it hydrolyzes DFP, all under comparable conditions. 2. The DFPase from rat kidney is stimulated 2- to 3-fold by 4 X 10(-4) M Mn2+, whereas the DFPase from squid nerve is unaffected or slightly inhibited by 4 X 10(-4) M Mn2+. 3. These observations form the basis for distinguishing between a squid type DFPase and a mammalian DFPase, the names not being rigorously indicative of enzyme source or substrate. 4. When these criteria are applied to a P-F splitting enzyme found in squid saliva, the enzyme is identifiable as squid type DFPase. There is a significantly higher level of this enzyme in whole saliva from female squids than in whole saliva from male squids. This squid type DFPase is different from the proteinous toxin also found in squid saliva.

Hydrolysis of nerve gas by squid-type diisopropyl phosphorofluoridate hydrolyzing enzyme on agarose resin.

An enzyme purified from squid nerve that hydrolyzes the cholinesterase inhibitor diisopropyl phosphorofluoridate (DFP) has now been coupled to agarose beads. A column of this agarose-DFPase hydrolyzes the nerve gas 1,2,2-trimethylpropyl methylphosphonofluoridate (Soman). Although the more inhibitory of the four diastereoisomers of Soman are hydrolyzed least rapidly, a column of sufficient length will accomplish 95 percent hydrolysis whether measured by fluoride release or loss of cholinesterase-inhibiting power. The results suggest a means for detoxifying unwanted chemical warfare agents.