Abstract

Perturbation to the cerebellum can lead to deficits in motor function, cognition, and behavioral flexibility. Here we report that a cerebellum-specific transgenic mouse autism model with disrupted Purkinje cell function shows unexpectedly accelerated learning on a sensory evidence-accumulation task, as well as enhanced sensory reactivity to touch and auditory cues. Computational latent-state analysis of behavior revealed that accelerated learning was associated with enhanced focus on current over past trials. In on-task states, a subset of Purkinje cells in crus I produced more complex spikes to sensory stimuli. Learning was accelerated by providing cue-locked optogenetic stimulation of Purkinje cells, but unaffected by continuous optogenetic interference with Purkinje cell activity. Complex spikes fired in response to both correct and incorrect choices, but less so when mice were on-task. Both transgenic mice and mice receiving cue-locked optogenetic stimulation showed prolonged sensory responses in Purkinje-cell complex spikes and anterior cingulate cortex. We suggest that cerebellar activity may shape evidence-accumulation learning by enhancing task focus and neocortical processing of current experience. HighlightsO_LIFaster learning and enhanced sensory salience with cerebellar manipulations in mice C_LIO_LIAccelerated learning arises from prolonged occupancy in an on-task behavioral state C_LIO_LICerebellar manipulations can influence neocortex via altered complex spike activity C_LIO_LICerebellum findings consistent with a weak global coherence account of autism C_LI eTOC blurbIn a cerebellum-based mouse autism model, perturbed function leads to faster learning of a working-memory task, mediated by higher focus on current trials. The effects are emulated by optogenetic perturbation of Purkinje cells, and both perturbations drive enhanced neocortical activity. Results are consistent with a weak coherence model for autism.