Resolving pathobiological mechanisms relating to Huntington disease: Gait, balance, and involuntary movements in mice with targeted ablation of striatal D1 dopamine receptor cells

HA Kim; L Jiang; H Madsen; CL Parish; J Massalas; A Smardencas; C O'Leary; I Gantois; C O'Tuathaigh; JL Waddington; ME Ehrlich; AJ Lawrence; J Drago

Journal article

Resolving pathobiological mechanisms relating to Huntington disease: Gait, balance, and involuntary movements in mice with targeted ablation of striatal D1 dopamine receptor cells

HA Kim, L Jiang, H Madsen, CL Parish, J Massalas, A Smardencas, C O'Leary, I Gantois, C O'Tuathaigh, JL Waddington, ME Ehrlich, AJ Lawrence, J Drago

Neurobiology of Disease | Published : 2014

DOI: 10.1016/j.nbd.2013.09.015

Abstract

Progressive cell loss is observed in the striatum, cerebral cortex, thalamus, hypothalamus, subthalamic nucleus and hippocampus in Huntington disease. In the striatum, dopamine-responsive medium spiny neurons are preferentially lost. Clinical features include involuntary movements, gait and orofacial impairments in addition to cognitive deficits and psychosis, anxiety and mood disorders. We utilized the Cre-LoxP system to generate mutant mice with selective postnatal ablation of D1 dopamine receptor-expressing striatal neurons to determine which elements of the complex Huntington disease phenotype relate to loss of this neuronal subpopulation.Mutant mice had reduced body weight, locomotor sl..

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University of Melbourne Researchers

Clare Parish Author

Andrew Lawrence Author

John Drago Author

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Grants

Awarded by Science Foundation Ireland

Funding Acknowledgements

This work was supported by project grants from the National Health & Medical Research Council (NHMRC) of Australia [509072] and [628680], the Victorian Government's Operational Infrastructure Support Program and by the Science Foundation Ireland Principal Investigator grant 07/IN.1/B960. JD and AJL are Fellows of the NHMRC.