Coding region paraoxonase polymorphisms dictate accentuated neuronal reactions in chronic, sub-threshold pesticide exposure.

Organophosphate pesticides (OPs), known inhibitors of acetylcholinesterase (AChE), are used extensively throughout the world. Recent studies have focused on the ACHE/PON1 locus as a determinant of inherited susceptibility to environmental OP exposure. To explore the relationship of the corresponding gene-environment interactions with brain activity, we integrated neurophysiologic, neuropsychological, biochemical, and genetic methods. Importantly, we found that subthreshold OP exposure leads to discernible physiological consequences that are significantly influenced by inherited factors. Cortical EEG analyses by LORETA revealed significantly decreased theta activity in the hippocampus, parahippocampal regions, and the cingulate cortex, as well as increased beta activity in the prefrontal cortex of exposed individuals-areas known to play a role in cholinergic-associated cognitive functions. Through neuropsychological testing, we identified an appreciable deficit in the visual recall in exposed individuals. Other neuropsychological tests revealed no significant differences between exposed and non-exposed individuals, attesting to the specificity of our findings. Biochemical analyses of blood samples revealed increases in paraoxonase and arylesterase activities and reduced serum acetylcholinesterase activity in chronically exposed individuals. Notably, specific paraoxonase genotypes were found to be associated with these exposure-related changes in blood enzyme activities and abnormal EEG patterns. Thus, gene-environment interactions involving the ACHE/PON1 locus may be causally involved in determining the physiological response to OP exposure.

RNA-targeted suppression of stress-induced allostasis in primate spinal cord neurons.

Peripheral acetylcholine levels notably control the synthesis in macrophages of pro-inflammatory cytokines; however, it remains unclear whether this peripheral regulatory pathway affects central nervous system neurons. To explore the interrelationship between neuronal cholinergic homeostasis and peripheral inflammatory responses in primates, we used spinal cord sections from cynomolgus monkeys after 7 days oral or intravenous treatment with Monarsen oligonucleotide. Monarsen is an antisense oligonucleotide 3'-protected by 2'-oxymethylation, which was proved to induce selective destruction of the stress-induced acetylcholinesterase splice variant AChE-R mRNA. Handling stress predictably suppressed neuronal choline acetyl transferase (ChAT) and the vesicular acetylcholine transporter (VAChT) in all treated monkeys. In Monarsen-treated animals, we further observed suppression of stress-induced increases in plasma AChE activities. Corresponding decreases in AChE-R mRNA were seen in spinal cord neurons, associated with parallel decline patterns in the mRNA encoding for the splice factor SC35 (the levels of which co-increase with those of AChE-R) as well as in the neuronal pro-inflammatory interleukins IL-1beta and IL-6. The antisense effects showed direct dose dependence and were inversely associated with neuronal cell size. These findings suggest a causal association between neuronal cholinergic allostasis and inflammatory reactions in primates and support the peripheral use of RNA-targeted intervention with AChE-R accumulation for the management of both stress and inflammatory responses.