Abstract
Huntington's disease (HD) affects two major brain areas - the striatum and cerebral cortex - in ways that differ in timing, severity, and gene-expression changes. For these reasons, and because many cortical neurons project axons to the affected striatal neurons, striatal and cortical atrophy have long been proposed to have distinct mechanisms, with one potentially a secondary consequence of the other. In the striatum, we recently found that neurons degenerate asynchronously as their own huntingtin (HTT) gene CAG-repeat tracts, typically inherited at 40-50 CAGs, expand somatically beyond 150 CAGs. To ask whether a similar or different dynamic affects the cerebral cortex, we analyzed HTT CAG repeats and genome-wide RNA expression together in more than 130,000 nuclei from 12 cortical areas of brain donors with HD. The resulting data revealed that cortical and striatal neurodegeneration in fact result from analogous sequences of cell-autonomous events, each instructed by somatic expansion of a neuron's own HTT CAG repeat. Analyses revealed that somatic expansion beyond a high toxicity threshold (of about 150 CAGs) is necessary and sufficient to initiate pathological changes; that this pathogenicity length threshold is shared by striatal and cortical projection neurons of all types; and that cortical area, cortical layer, and axonal projections play only incidental roles, as proxies for the true driver: profound (up to 50-fold) variation among types and subtypes of pyramidal neurons in the likelihood of reaching the 150-CAG toxicity threshold in a human lifetime. These results also suggest that containing somatic DNA-repeat expansion below this high toxicity threshold would protect both brain areas in HD.