Altered Cerebellar Response to Somatosensory Stimuli in the Cntnap2 Mouse Model of Autism.

Atypical sensory processing is currently included within the diagnostic criteria of autism. The cerebellum is known to integrate sensory inputs of different modalities through its connectivity to the cerebral cortex. Interestingly, cerebellar malformations are among the most replicated features found in postmortem brain of individuals with autism. We studied sensory processing in the cerebellum in a mouse model of autism, knock-out (KO) for the Cntnap2 gene. Cntnap2 is widely expressed in Purkinje cells (PCs) and has been recently reported to regulate their morphology. Further, individuals with CNTNAP2 mutations display cerebellar malformations and CNTNAP2 antibodies are associated with a mild form of cerebellar ataxia. Previous studies in the Cntnap2 mouse model show an altered cerebellar sensory learning. However, a physiological analysis of cerebellar function has not been performed yet. We studied sensory evoked potentials in cerebellar Crus I/II region on electrical stimulation of the whisker pad in alert mice and found striking differences between wild-type and Cntnap2 KO mice. In addition, single-cell recordings identified alterations in both sensory-evoked and spontaneous firing patterns of PCs. These changes were accompanied by altered intrinsic properties and morphologic features of these neurons. Together, these results indicate that the Cntnap2 mouse model could provide novel insight into the pathophysiological mechanisms of autism core sensory deficits.

Neurobiological Mechanisms of Autism Spectrum Disorder and Epilepsy, Insights from Animal Models.

Autism Spectrum Disorder (ASD) and epilepsy are two neurodevelopmental disorders that have a high comorbidity rate, suggesting that a common neurodevelopmental mechanism exists. However, to date there is no conclusive way to predict whether a child will develop either syndrome or both and to what degree associated phenotypes will be affected. Failure to consistently identify predictive patterns of ASD and/or epilepsy diagnosis stems from the fact that they are etiologically heterogeneous conditions and research into their neuropathological mechanisms becomes challenging. Whole genome/exome sequencing has advanced our understanding of the genetic causes of ASD and epilepsy to an extent that currently about half of all ASD as well as epilepsy cases are known to have a genetic basis. In fact, a picture is emerging of both conditions as a collection of distinct genetically defined disorders, although the role of environmental factors has also been established. A plethora of animal models, most of them based on identified human genetic mutations and a few on known environmental causes, have been developed. Animal models provide a major experimental avenue for studying the underlying cellular and molecular mechanisms of human disorders. They also provide invaluable preclinical tools that can be used to test therapeutic approaches. In this review, we first summarize the methods for validating mouse models of ASD and epilepsy. Second, we present the current models validated for the comorbidity and finally, we recapitulate the common pathomechanisms identified in these models with special emphasis on synaptic plasticity.