AI Article Synopsis
- Huntington's disease is linked to a toxic increase in the HTT gene's function, prompting the development of therapies targeting HTT reduction in the liver.
- Chronic loss of HTT in mouse liver cells leads to significant physiological changes, such as increased bile acids, cholesterol, and altered liver gene expression patterns.
- Interestingly, the absence of HTT in liver cells also shows resistance to acetaminophen toxicity, suggesting HTT plays a critical role in liver zonation and possibly relates to impaired liver function mechanisms.
Article Abstract
Huntington's disease arises from a toxic gain of function in the () gene. As a result, many HTT-lowering therapies are being pursued in clinical studies, including those that reduce HTT RNA and protein expression in the liver. To investigate potential impacts, we characterized molecular, cellular, and metabolic impacts of chronic HTT lowering in mouse hepatocytes. Lifelong hepatocyte HTT loss is associated with multiple physiological changes, including increased circulating bile acids, cholesterol and urea, hypoglycemia, and impaired adhesion. HTT loss causes a clear shift in the normal zonal patterns of liver gene expression, such that pericentral gene expression is reduced. These alterations in liver zonation in livers lacking HTT are observed at the transcriptional, histological, and plasma metabolite levels. We have extended these phenotypes physiologically with a metabolic challenge of acetaminophen, for which the HTT loss results in toxicity resistance. Our data reveal an unexpected role for HTT in regulating hepatic zonation, and we find that loss of HTT in hepatocytes mimics the phenotypes caused by impaired hepatic β-catenin function.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10488683 | PMC |
| http://dx.doi.org/10.26508/lsa.202302098 | DOI Listing |
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