Maternal Protein Deficiency Causes Hypermethylation of DNA in the Livers of Rat Fetuses

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(Journal of Nutrition. 2000;130:1821-1826.)
© 2000 The American Society for Nutritional Sciences

Article

Maternal Protein Deficiency Causes Hypermethylation of DNA in the Livers of Rat Fetuses¹

William D. Rees², Susan M. Hay, David S. Brown, Christos Antipatis and Robert M. Palmer

The Rowett Research Institute, Bucksburn, Aberdeen, AB21 9SB, Scotland

²To whom correspondence should be addressed.

Maternal protein deficiency during pregnancy is associated withchanges in glucose tolerance and hypertension in the offspringof rats. In this study the growth of rat fetuses was examinedwhen the dams were fed diets containing 18% casein, 9% caseinor 8% casein supplemented with threonine. The extra threoninewas added to reverse the decrease in circulating threonine concentrationsthat occurs when pregnant rats are fed protein-deficient diets.The fetuses of the group fed the low protein diet supplementedwith threonine were significantly smaller than those of thecontrol group and not significantly different from those fedlow protein. Homogenates prepared from the livers of dams fed thediet containing 9% casein oxidized threonine at approximately twicethe rate of homogenates prepared from dams fed the diet containing18% casein. We conclude that circulating levels of threoninefall as a consequence of an increase in the activity of the pathwaythat metabolizes homocysteine produced by the transulfuration ofmethionine. Serum homocysteine was unaffected in the dams fedlow protein diets compared with controls, but was significantlygreater in dams fed the low protein diet supplemented with threonine.Elevated levels of homocysteine are associated with changesin the methylation of DNA. The endogenous methylation of DNAwas greater than that of controls in the livers of fetuses fromdams fed the 9% protein diets and increased further when thediet was supplemented with threonine. Our results suggest thatchanges in methionine metabolism increase homocysteine production,which leads to changes in DNA methylation in the fetus. An increasein maternal homocysteine may compromise fetal development, leadingto the onset of glucose intolerance and hypertension in adultlife.

KEY WORDS: • rats • pregnancy • cysteine • methionine • threonine • homocysteine • folate

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Article

Maternal Protein Deficiency Causes Hypermethylation of DNA in the Livers of Rat Fetuses1

Maternal Protein Deficiency Causes Hypermethylation of DNA in the Livers of Rat Fetuses¹