Serotonin transporter deficient mice are vulnerable to escape deficits following inescapable shocks

Modulation of serotonin transporter (5-HTT) function causes changes in affective behavior, both in humans and rodents. Stressful life events likewise affect emotional behavior. In humans, a low-expressing genetic 5-htt variant, the s allele of the 5-htt linked promoter region, has been associated with increased risk for depression only where there was a history of stressful life events. To investigate this gene by environment interaction in mice, we compared the effects of inescapable shocks on the behavior of wild-type (5-htt+/+), heterozygote (5-htt+/-) and serotonin transporter deficient (5-htt-/-) mice. Inescapable shocks induce behavioral changes including a shock escape deficit, in a subsequent test when escape is possible. Confirming a gene by environment interaction, we found that stress increases escape latencies in a gene-dose dependent manner (5-htt-/->5-htt+/->5-htt +/+), where as there were no differences among the genotypes in the unstressed condition. The vulnerability to increased escape latency could not be accounted for by enhanced fear learning, as 5-htt-/- mice did not show heightened fear conditioning. The interaction of 5-htt genotype and stress appeared to produce a selective behavioral vulnerability, because no interaction of 5-htt genotype and stress was observed in other measures of anxiety and depression-linked behavior, including the open field, novelty suppressed feeding, and forced swim tests. We replicated prior findings that the 5-htt-/- displays heightened anxiety and depression-like behavior at baseline (unstressed condition). In conclusion, our data offer the possibility for future investigation of the neural basis underlying 5-htt genotype-by-stress interaction shown here.