Abstract
Glycogen storage diseases (GSDs) belong to the group of inborn errors of carbohydrate metabolism. Hepatic GSDs predominantly involve the liver and most present with hepatomegaly. Biochemically they show known disturbances in glucose and fatty acids metabolism, namely fasting hypoglycaemia and increased triglycerides. Additionally, increased biotinidase (BTD) enzyme activity has been shown to be associated with many GSD types, whereas the mechanism by which BTD enzyme activity is altered remains unknown so far. We aimed to delineate changes in gluconeogenesis and fatty acid synthesis, potentially explaining raised BTD enzyme activity, by using liver (specimens from 2 patients) and serum samples of GSD Ia and GSD IV patients. By expression analysis of genes involved in gluconeogenesis, we ascertained increased levels of phosphoenolpyruvate carboxykinase and fructose‐1,6‐biphosphatase, indicating an increased flux through the gluconeogenic pathway. Additionally, we found increased gene expression of the biotin‐dependent pyruvate and acetyl‐CoA carboxylases, providing substrate for gluconeogenesis and increased fatty acid synthesis. We also observed a significant linear correlation between BTD enzyme activity and triglyceride levels in a cohort of GSD Ia patients. The results of this pilot study suggest that enhancement of BTD activity might serve the purpose of providing extra cofactor to the carboxylase enzymes as an adjustment to disturbed glucose and fatty acid metabolism. Future studies involving a higher number of samples should aim at confirming the here proposed mechanism, which extends the application of BTD enzyme activity measurement beyond its diagnostic purpose in suspected GSD, and opens up possibilities for its use as a sensor for increased gluconeogenesis and fatty acid synthesis.
Highlights
Glucose is the most important source of energy, which must be constantly available, and its level is meticulously controlled to maintain normoglycaemia
We investigated this phenomenon by analyzing liver and serum samples derived from Glycogen storage diseases (GSDs) IV and GSD Ia patients
Based on published findings and on our results, the four conditions are either linked to increased gluconeogenic flux or increased fatty acid synthesis as follows: (a) In GSD Ia glucose-6-phosphate accumulates and is shunted to glycolysis
Summary
Glucose is the most important source of energy, which must be constantly available, and its level is meticulously controlled to maintain normoglycaemia. Deficiencies of glycogen synthesis and breakdown cause glycogen storage disorders (GSDs), a heterogenous group of inherited disorders of carbohydrate metabolism.[4] In this work, we studied the following two hepatic forms of GSD: GSD Ia, caused by deficient glucose-6-phosphatase (G6PC; EC 3.1.3.9) and GSD IV, caused by deficiency of the 1,4-alpha-glucan-branching enzyme (GBE1; EC 2.4.1.18) The former is characterized by hepatomegaly, lactic acidosis, and hyperlipidaemia,[5] whereas the latter typically shows progressive liver disease, including hepatomegaly (accumulating polyglucosan), failure to thrive, and muscular hypotonia.[6] Hypoglycaemia is a cardinal symptom of GSD Ia, due to disrupted gluconeogenesis and impaired glycogen breakdown, whilst in GSD IV hypoglycaemia only occurs during end stage cirrhosis.[7]. Rstudio was used to plot graphs and calculate Pearson's correlation
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