Analysis of YFP(J16)-R6/2 reporter mice and postmortem brains reveals early pathology and increased vulnerability of callosal axons in Huntington's disease.
posted on 2016-09-21, 00:00authored byRG Gatto, Y. Chu, AQ Ye, SD Price, E. Tavassoli, A. Buenaventura, ST Brady, RL Magin, JH Kordower, GA Morfini
Cumulative evidence indicates that the onset and severity of Huntington’s disease (HD) symptoms correlate with connectivity
deficits involving specific neuronal populations within cortical and basal ganglia circuits. Brain imaging studies and
pathological reports further associated these deficits with alterations in cerebral white matter structure and axonal pathology.
However, whether axonopathy represents an early pathogenic event or an epiphenomenon in HD remains unknown, nor is
clear the identity of specific neuronal populations affected. To directly evaluate early axonal abnormalities in the context of
HD in vivo, we bred transgenic YFP(J16) with R6/2 mice, a widely used HD model. Diffusion tensor imaging and fluorescence
microscopy studies revealed a marked degeneration of callosal axons long before the onset of motor symptoms. Accordingly,
a significant fraction of YFP-positive cortical neurons in YFP(J16) mice cortex were identified as callosal projection neurons.
Callosal axon pathology progressively worsened with age and was influenced by polyglutamine tract length in mutant
huntingtin (mhtt). Degenerating axons were dissociated from microscopically visible mhtt aggregates and did not result from
loss of cortical neurons. Interestingly, other axonal populations were mildly or not affected, suggesting differential vulnerability
to mhtt toxicity. Validating these results, increased vulnerability of callosal axons was documented in the brains of HD patients.
Observations here provide a structural basis for the alterations in cerebral white matter structure widely reported in HD patients.
Collectively, our data demonstrate a dying-back pattern of degeneration for cortical projection neurons affected in HD, suggesting
that axons represent an early and potentially critical target for mhtt toxicity.
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Publisher Statement
This is a pre-copy-editing, author-produced PDF of an article accepted for publication in[insert journal title] following peer review. The definitive publisher-authenticated version Gatto, R. G., Chu, Y., Ye, A. Q., Price, S. D., Tavassoli, E., Buenaventura, A., Brady, S. T., Magin, R. L., Kordower, J. H. and Morfini, G. A. Analysis of YFP(J16)-R6/2 reporter mice and postmortem brains reveals early pathology and increased vulnerability of callosal axons in Huntington's disease. Human Molecular Genetics. 2015. 24(18): 5285-5298. DOI: 10.1093/hmg/ddv248, is available online in: Human Molecular Genetics.