Objective:

Investigation of the motor super-performance conferring downstream mechanisms in mice with a Rif1^I107T/I107T  mutation.

Background:

Although motor impairment represents a common phenotype in many neurological disorders, treatment options for motor recovery remain limited. Using a previously identified gain-of-function mutation (Rif1^I107T/I107T, Jakkamsetti et. al., J. Physiology 2024) linked to superior motor performance, we employed a top-down approach, spanning behavior, function, and molecular mechanisms, to uncover targetable pathways underlying motor control. 

Design/Methods:

Mice with a CRISPR-induced Rif1^I107T/I107T mutation prior identified via a forward genetics rotarod motor screen  and their littermate controls were assayed for other motor and non-motor behaviors. In vivo anesthetized recordings were obtained from cerebellar purkinje single-units in lobule IV-V. RNA-seq and immunohistochemistry assays were done for forebrain, cerebellum and spinal cord. Further cerebellar work included qPCR and western blot assays. Photothrombotic stroke was induced under anesthesia on the right side, 1.7 mm lateral to bregma in the putative forelimb representation.

Results:

Rif1^I107T/I107T  enhanced performance that extended to other motor but not non-motor behaviors. Cerebellum purkinje cells showed more regular firing and diminished oscillation frequencies associated with recurrent inhibition. Rif1^I107T/I107T enhanced binding to guanosine-rich G-quadruplex (G4) RNA structures. While forebrain and spinal cord RNA expression did not change, for cerebellar RNAs with higher expression in Rif1^I107T/I107T  mice, more had G4 structures, and gene enrichment assays showed strong association with motor coordination, cerebellar lobule IV-V, synaptic transmission, and serine-threonine kinase activity. Among these RNAs, Nab2, Kif5c and Kcnma1 satisfied the criteria of possible downstream effectors and showed increased cerebellar expression in Rif1^I107T/I107T mice. Increasing lobule IV-V expression of Nab2 in wild-type mice conferred temporary superior motor performance. Rif1^I107T/I107T mice recovered faster and to a greater extent after cortical photothrombotic stroke. 

Conclusions: