Abstract
Electrophysiological studies indicate that cat visual cortical critical period neuronal plasticity peaks around 5 weeks and largely disappears by 20 weeks. Dark rearing slows this time course. Normal cats are more plastic than dark-reared cats at 5 weeks, but the opposite is true at 20 weeks. Thus, a stringent criterion for identifying genes controlling neuronal plasticity is that normal and dark rearing produce opposite direction differences in expression between young and older animals. Differential display polymerase chain reaction identified Abelson interacting protein 2 (Abi-2) as a candidate plasticity gene regulated according to this criterion. Western blotting showed bidirectional regulation of Abi-2 protein levels in cats and mice that was specific to visual cortex and did not occur in frontal cortex. Immunohistochemistry indicated developmental changes in Abi-2 laminar expression in cat visual cortex. Dark rearing altered laminar expression such that at 5 weeks, dark-reared cats were similar to 1-week normally reared cats, and at 20 weeks, dark-reared cats were similar to 5–10-week normally reared animals. The effect of dark rearing on both Abi-2 expression levels and laminar expression patterns was to slow the normal developmental process, the same effect seen on physiologically assessed plasticity in visual cortex.
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This work was supported by NIH R01 016724.
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Yang, C.B., Kiser, P.J., Zheng, Y.T. et al. Age and Dark Rearing Bidirectionally Regulate the Level and Laminar Pattern of Expression of Abelson Interacting Protein 2 (Abi-2): a Novel Candidate Visual Cortical Plasticity Gene. J Mol Neurosci 51, 647–654 (2013). https://doi.org/10.1007/s12031-013-0037-1
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DOI: https://doi.org/10.1007/s12031-013-0037-1