Abstract
Chronic hyperphenylalaninemia maintained with the aid of a suppressor of phenylalamine hydroxylase, α-methylphenylalanine, increases the glycine concentration and the phosphoserine phosphatase activity of the developing rat brain but not that of liver or kidney. Similar increases occur after daily injections with large doses of phenylalanine alone, while tyrosine, isoleucine, alanine, proline, and threonine, were without effect. Treatment with methionine, which increases the phosphoserine phosphatase activity of the brain and lowered that of liver and kidney, left the cerebral glycine level unchanged. When varying the degrees of gestational or early postnatal hyperphenylalaninemia, a significant linear correlation was found between the developing brains' phosphoserine phosphatase and glycine concentration. Observations on the uptake of injected glycine and its decline further indicate that coordinated rises in the brain's phosphoserine phosphatase and glycine content associated with experimental hyperphenylalaninemia denote a direct impact of phenylalanine on the intracellular pathway of glycine synthesis in immature animals.
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McChesney, R., Isaacs, C.E. & Greengard, O. Cerebral glycine content and phosphoserine phosphatase activity in hyperaminoacidemias. Neurochem Res 12, 289–295 (1987). https://doi.org/10.1007/BF00972139
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DOI: https://doi.org/10.1007/BF00972139