Abstract
Abnormalities in tactile perception, such as sensory defensiveness, are common features in autism spectrum disorder (ASD). While not a diagnostic criterion for ASD, deficits in tactile perception contribute to the observed lack of social communication skills. However, the influence of tactile perception deficits on the development of social behaviors remains uncertain, as do the effects on neuronal circuits related to the emotional regulation of social interactions. In neonatal rodents, whiskers are the most important tactile apparatus, so bilateral whisker trimming is used as a model of early tactile deprivation. To address the influence of tactile deprivation on adult behavior, we performed bilateral whisker trimming in mice for 10 days after birth (BWT10 mice) and examined social behaviors, tactile discrimination, and c-Fos expression, a marker of neural activation, in adults after full whisker regrowth. Adult BWT10 mice exhibited significantly shorter crossable distances in the gap-crossing test than age-matched controls, indicating persistent deficits in whisker-dependent tactile perception. In contrast to controls, BWT10 mice exhibited no preference for the social compartment containing a conspecific in the three-chamber test. Furthermore, the development of amygdala circuitry was severely affected in BWT10 mice. Based on the c-Fos expression pattern, hyperactivity was found in BWT10 amygdala circuits for processing fear/anxiety-related responses to height stress but not in circuits for processing reward stimuli during whisker-dependent cued learning. These results demonstrate that neonatal whisker trimming and concomitant whisker-dependent tactile discrimination impairment severely disturbs the development of amygdala-dependent emotional regulation.
Highlights
Sensory defensiveness is a negative reaction to one or more types of sensation and is often associated with neurodevelopmental disorders such as autism spectrum disorder (ASD) and fragile X syndrome [1]
Neonatal whisker trimming resulted in adult social behavior deficits To examine the effect of neonatal whisker trimming (P1–P10) on adult whisker function, we compared the control mice to the BWT10 mice in the gap-crossing test, which requires the mice to evaluate a gap and make a decision based on tactile information from the whiskers
To evaluate if neonatal whisker trimming affects the development of the emotional system, we examined stress-induced neural activation in several brain regions associated with emotional processing, the basolateral amygdala, paraventricular nucleus (PVN), and prefrontal cortex [medial orbital (MO), ventral orbital (VO), and prelimbic cortex (PrL)] following exposure to elevated platform stress
Summary
Sensory defensiveness is a negative reaction to one or more types of sensation and is often associated with neurodevelopmental disorders such as autism spectrum disorder (ASD) and fragile X syndrome [1]. Emotional memories associated with tactile perception are important for attachment in infancy, defined in rodent studies as seeking proximity to and maintaining contact with the dam when pups are upset or threatened [3, 4]. This attachment is an early primitive social behavior; early tactile sensory defensiveness is likely to influence the development of neural circuits related to emotional and social behaviors, but this remains to be determined. Tactile perception from whiskers, during the neonatal period, might be critical for the development of social behaviors in rodents
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