NEUROTOXIC MECHANISMS OF ELECTROPHILIC TYPE-2 ALKENES: SOFT-SOFT INTERACTIONS DESCRIBED BY QUANTUM MECHANICAL PARAMETERS

doi:10.1093/toxsci/kfm127

ToxSci Advance Access published online on May 22, 2007
Toxicological Sciences, doi:10.1093/toxsci/kfm127

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NEUROTOXIC MECHANISMS OF ELECTROPHILIC TYPE-2 ALKENES: SOFT-SOFT INTERACTIONS DESCRIBED BY QUANTUM MECHANICAL PARAMETERS

Richard M. LoPachin¹, Terrence Gavin², Brian C. Geohagen¹ and Soma Das¹

¹ Department of Anesthesiology, Albert Einstein College of Medicine, Montefiore Medical Center, 111 E. 210^th St., Bronx, NY 10467 ² Department of Chemistry, Iona College, New Rochelle, NY 10804

Corresponding author: Richard M. LoPachin, Ph.D., Montefiore Medical Center, Moses Research Tower – 7, 111 E. 210^th St., Bronx, NY 10467, (718) 920-5054 (telephone), (718) 515-4903 (fax), lopachin{at}aecom.yu.edu (e-mail)

Received March 7, 2007; revision received May 7, 2007; accepted May 7, 2007

Abstract

Conjugated Type-2 alkenes, such as acrylamide (ACR), are softelectrophiles that produce neurotoxicity by forming adductswith soft nucleophilic sulfhydryl groups on proteins. Soft-softinteractions are governed by frontier molecular orbital characteristicsand can be defined by quantum mechanical parameters such assoftness ( ${sigma}$ ) and chemical potential (µ). The neurotoxicpotency of ACR is likely related to the rate of adduct formation,which is reflected in values of ${sigma}$ . Correspondingly, differencesin µ, the ability of a nucleophile to transfer electronsto an electrophile, could determine protein targets of thesechemicals. Here, ${sigma}$ and µ were calculated for a series ofstructurally similar Type-2 alkenes and their potential sulfhydryltargets. Results show that N-ethylmaleimide, acrolein and methylvinylketone were softer electrophiles than methyl acrylate or ACR.Softness ( ${sigma}$ ) was closely correlated to corresponding second-orderrate constants (k₂) for electrophile reactions with sulfhydrylgroups on N-acetyl-L-cysteine (NAC). The rank order of softnesswas also directly related to neurotoxic potency as determinedby impairment of synaptosomal function and sulfhydryl loss.Calculations of µ, showed that the thiolate-state of severalcysteine analogs was the preferred nucleophilic target of alkeneelectrophiles. In addition, µ was directly related tothe thiolate rate constant (k) for the reaction of the Type-2alkenes with the cysteine compounds. Finally, in accordancewith respective µ values, we found that NAC, but not N-acetyl-L-lysine,protected synaptosomes from toxicity. These findings suggestthat the neurotoxicity of ACR and its conjugated alkene analogsis related to electrophilic softness and that the thiolate-stateof cysteine residues is the corresponding adduct target.

Key Words: distal axonopathy; acrylamide; acrolein; Type-2 alkenes; adduct formation; nerve terminal; neurotoxicity.

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