Structure-efficiency relationships of cyclodextrin scavengers in the hydrolytic degradation of organophosphorus compounds.

New derivatives of cyclodextrins were prepared in order to determine the relative importance of the structural key elements involved in the degradation of organophosphorus nerve agents. To avoid a competitive inclusion between the organophosphorus substrate and the iodosobenzoate group, responsible for its degradation, the latter group had to be covalently bound to the cyclodextrin scaffold. Although the presence of the α nucleophile iodosobenzoate was a determinant in the hydrolysis process, an imidazole group was added to get a synergistic effect towards the degradation of the agents. The degradation efficiency was found to be dependent on the relative position of the heterocycle towards the reactive group as well as on the nature of the organophosphorus derivative.

Effects of acetylcholinesterase and butyrylcholinesterase inhibition on breathing in mice adapted or not to reduced acetylcholinesterase.

We investigated the contributions of acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) inhibition to the respiratory dysfunction produced by organophosphates in mice which were adapted or not to low AChE activity. Effects of acute selective inhibition of AChE and BChE on ventilation measured by whole-body plethysmography were compared in mice with either normal AChE activity (wild-type), or mice adapted to a null AChE activity (homozygotes for AChE gene deletion) or adapted to an intermediate level of activity (heterozygotes). In wild-type mice acute reduction of AChE by Huperzine A (1 mg/kg) to the level found in asymptomatic heterozygotes, induced tremors but no respiratory depression, whereas the same dose of Huperzine in heterozygote animals further reduced AChE activity, increased tidal volume (V(T)) and decreased breathing frequency (f(R)). A lethal dose of Huperzine in wild-type mice augmented these respiratory effects, but was ineffective in homozygotes. BChE inhibition by bambuterol was ineffective in wild-type mice and heterozygotes, decreased V(T) in homozygotes adapted to null AChE activity but increased V(T) in wild-type mice acutely treated with Huperzine, also aggravating the cholinergic syndrome. We conclude that: (1) Huperzine does not perturb respiration at a dose inhibiting 40% of AChE, and at a lethal dose does not affect any other enzyme important for respiration; (2) Respiratory function is more sensitive to anticholinesterases in heterozygotes than in wild-type mice; (3) BChE may play distinct roles in respiratory function, because its inhibition has opposite effects on tidal volume depending on whether the mouse has adapted to null AChE or whether AChE has been lowered acutely; (4) BChE inhibition may contribute to the respiratory toxicity of organophosphates.

Inhibition of caspase-dependent mitochondrial permeability transition protects airway epithelial cells against mustard-induced apoptosis.

In the present study, the toxicity of yperite, SM, and its structural analogue mechlorethamine, HN2, was investigated in a human bronchial epithelial cell line 16HBE. Cell detachment was initiated by caspase-2 activation, down-regulation of Bcl-2 and loss of mitochondrial membrane potential. Only in detached cells, mustards induced apoptosis associated with increase in p53 expression, Bax activation, decrease in Bcl-2 expression, opening of the mitochondrial permeability transition pore, release of cytochrome c, caspase-2, -3, -8, -9 and -13 activation and DNA fragmentation. Apoptosis, occurring only in detached cells, could be recognized as anoikis and the mitochondrion, involved both in cell detachment and subsequent cell death, appears to be a crucial checkpoint. Based on our understanding of the apoptotic pathway triggered by mustards, we demonstrated that inhibition of the mitochondrial pathway by ebselen, melatonin and cyclosporine A markedly prevented mustard-induced anoikis, pointing to these drugs as interesting candidates for the treatment of mustard-induced airway epithelial lesions.

Respiratory survival mechanisms in acetylcholinesterase knockout mouse.

Cholinergic neurotransmission ensures muscle contraction and plays a role in the regulation of respiratory pattern in the brainstem. Inactivation of acetylcholinesterase (AChE) by organophosphates produces respiratory failure but AChE knockout mice survive to adulthood. Respiratory adaptation mechanisms which ensure survival of these mice were examined in vivo by whole body plethysmography and in vitro in the neonatal isolated brainstem preparation. AChE-/- mice presented no AChE activity but unaffected butyrylcholinesterase (BChE) activity. In vivo, bambuterol (50-500 microg/kg s.c.) decreased BChE activity peripherally but not in brain tissue and induced apnea and death in adult and neonate AChE-/- mice without affecting littermate AChE+/+ and +/- animals. In vitro, bath-applied bambuterol (1-100 microm) and tetraisopropylpyrophosphoramide (10-100 microm) decreased BChE activity in the brainstem but did not perturb central respiratory activity recorded from spinal nerve rootlets. In vitro, the cholinergic agonists muscarine (50-100 microm) and nicotine (0.5-10 microm) induced tonic activity in respiratory motoneurons and increased the frequency of inspiratory bursts in AChE+/+ and +/- animals. These effects were greatly attenuated in AChE-/- animals. The results suggest that, in mice lacking AChE, (i) BChE becomes essential for survival peripherally but plays no critical role in central rhythm-generating structures and (ii) a major adaptive mechanism for respiratory survival is the down-regulated response of central respiratory-related neurons and motoneurons to muscarinic and nicotinic agonists.