Single treatment of VX poisoned guinea pigs with the phosphotriesterase mutant C23AL: Intraosseous versus intravenous injection.

The recent attacks with the nerve agent sarin in Syria reveal the necessity of effective countermeasures against highly toxic organophosphorus compounds. Multiple studies provide evidence that a rapid onset of antidotal therapy might be life-saving but current standard antidotal protocols comprising reactivators and competitive muscarinic antagonists show a limited efficacy for several nerve agents. We here set out to test the newly developed phosphotriesterase (PTE) mutant C23AL by intravenous (i.v.), intramuscular (i.m.; model for autoinjector) and intraosseous (i.o.; model for intraosseous insertion device) application in an in vivo guinea pig model after VX challenge (∼2LD50). C23AL showed a Cmax of 0.63µmolL(-1) after i.o. and i.v. administration of 2mgkg(-1) providing a stable plasma profile up to 180min experimental duration with 0.41 and 0.37µmolL(-1) respectively. The i.m. application of C23AL did not result in detectable plasma levels. All animals challenged with VX and subsequent i.o. or i.v. C23AL therapy survived although an in part substantial inhibition of erythrocyte, brain and diaphragm AChE was detected. Theoretical calculation of the time required to hydrolyze in vivo 96.75% of the toxic VX enantiomer is consistent with previous studies wherein similar activity of plasma containing catalytic scavengers of OPs resulted in non-lethal protection although accompanied with a variable severity of cholinergic symptoms. The relatively low C23AL plasma level observed immediately after its i.v. or i.o load, point at a possible volume of distribution greater than the guinea pig plasma content, and thus underlines the necessity of in vivo experiments in antidote research. In conclusion the i.o. application of PTE is efficient and resulted in comparable plasma levels to the i.v. application at a given time. Thus, i.o. vascular access systems could improve the post-exposure PTE therapy of nerve agent poisoning.

Computational redesign of a mononuclear zinc metalloenzyme for organophosphate hydrolysis.

The ability to redesign enzymes to catalyze noncognate chemical transformations would have wide-ranging applications. We developed a computational method for repurposing the reactivity of metalloenzyme active site functional groups to catalyze new reactions. Using this method, we engineered a zinc-containing mouse adenosine deaminase to catalyze the hydrolysis of a model organophosphate with a catalytic efficiency (k(cat)/K(m)) of ~10(4) M(-1) s(-1) after directed evolution. In the high-resolution crystal structure of the enzyme, all but one of the designed residues adopt the designed conformation. The designed enzyme efficiently catalyzes the hydrolysis of the R(P) isomer of a coumarinyl analog of the nerve agent cyclosarin, and it shows marked substrate selectivity for coumarinyl leaving groups. Computational redesign of native enzyme active sites complements directed evolution methods and offers a general approach for exploring their untapped catalytic potential for new reactivities.

Stabilization of Torpedo californica acetylcholinesterase by reversible inhibitors.

The dimeric form of Torpedo californica acetylcholinesterase provides a valuable experimental system for studying transitions between native, partially unfolded, and unfolded states since long-lived partially unfolded states can be generated by chemical modification of a nonconserved buried cysteine residue, Cys 231, by denaturing agents, by oxidative stress, and by thermal inactivation. Elucidation of the 3D structures of complexes of Torpedo californica acetylcholinesterase with a repertoire of reversible inhibitors permits their classification into three categories: (a) active-site directed inhibitors, which interact with the catalytic anionic subsite, at the bottom of the active-site gorge, such as edrophonium and tacrine; (b) peripheral anionic site inhibitors, which interact with a site at the entrance to the gorge, such as propidium and d-tubocurarine; and (c) elongated gorge-spanning inhibitors, which bridge the two sites, such as BW284c51 and decamethonium. The effects of these three categories of reversible inhibitors on the stability of Torpedo californica acetylcholinesterase were investigated using spectroscopic techniques and differential scanning calorimetry. Thermodynamic parameters obtained calorimetrically permitted quantitative comparison of the effects of the inhibitors on the enzyme's thermal stability. Peripheral site inhibitors had a relatively small effect, while gorge-spanning ligands and those binding at the catalytic anionic site, had a much larger stabilizing effect. The strongest effect was, however, observed with the polypeptide toxin, fasciculin II (FasII), even though, in terms of its binding site, it belongs to the category of peripheral site ligands. The stabilizing effect of the ligands binding at the anionic subsite of the active site, like that of the gorge-spanning ligands, may be ascribed to their capacity to stabilize the interaction between the two subdomains of the enzyme. The effect of fasciculin II may be ascribed to the large surface area of interaction (>2000 A(2)) between the two proteins. Stabilization of Torpedo californica acetylcholinesterase by both divalent cations and chemical chaperones was earlier shown to be due to a shift in equilibrium between the native state and a partially unfolded state ( Millard et al. ( 2003 ) Protein Sci. 12 , 2337 - 2347 ). The low molecular weight inhibitors used in the present study may act similarly and can thus be considered as pharmacological chaperones for stabilizing the fully folded native form of the enzyme.