Increased thirst and drinking in Huntington's disease and the R6/2 mouse

While Huntington's disease (HD) is a condition that primarily involves the basal ganglia, there is evidence to suggest that the hypothalamus is also affected. Because the osmoreceptors regulating thirst are situated in the circumventricular region of the hypothalamus, we were interested in whether altered thirst is a part of the HD phenotype. We used the LABORAS behavioural monitoring system and water consumption to show that drinking behaviour was abnormal in R6/2 mice. By 10 weeks of age, R6/2 mice spent significantly more time drinking and drank a greater volume than their wild-type (WT) littermates. The numbers of immunoreactive vasopressin neurons in the paraventricular nucleus (PVN) of the hypothalamus in R6/2 mice were significantly decreased from 8 weeks of age, suggesting that the change in drinking behaviour may be the result of hypothalamic dysfunction. We gave a xerostomia (dry mouth) questionnaire to HD patients and control subjects, and also measured their urine osmolality and serum vasopressin. The mean total xerostomia score was significantly higher in HD patients than in controls, indicating greater thirst in HD patients. Urine osmolality was unaffected in HD patients up to clinical stage III, and none of the patients had diabetes. However, serum vasopressin was increased, suggesting a dysregulation in the control of hypothalamic vasopressin release. A dry mouth can affect taste, mastication and swallowing, all of which may contribute to the significant weight loss seen in both HD patients and R6/2 mice, as can dehydration. We suggest that increased thirst may be an important and clinically relevant biomarker for the study of disease progression in HD.     

Retinal dysfunction, photoreceptor protein dysregulation and neuronal remodelling in the R6/1 mouse model of Huntington's disease

Huntington's disease (HD) is a progressive neurological disease characterised by motor dysfunction, cognitive impairment and personality changes. Previous work in HD patients and animal models of the disease has also highlighted retinal involvement. This study characterised the changes in retinal structure and function early within the progression of disease using the R6/1 mouse model of HD. The retinal phenotype was observed to occur at the same time in the disease process as other neurological deficits such as motor dysfunction (by 13 weeks of age). There was a specific functional deficit in cone response to the electroretinogram and using immunocytochemical techniques, this dysfunction was found to be likely due to a progressive and complete loss of cone opsin and transducin protein expression by 20 weeks of age. In addition, there was an increase in Müller cell gliosis and the presence of ectopic rod photoreceptor terminals. This retinal remodelling is also observed in downstream neurons, namely the rod and cone bipolar cells. While R6/1 mice exhibit significant retinal pathology simultaneously with other more classical HD alterations, this doesn't lead to extensive cell loss. These findings suggest that in HD, cone photoreceptors are initially targeted, possibly via dysregulation of protein expression or trafficking and that this process is subsequently accompanied by increased retinal stress and neuronal remodelling also involving the rod pathway. As retinal structure and connectivity are well characterised, the retina may provide a useful model tissue in which to characterise the mechanisms important in the development of neuronal pathology in HD.