De novo lipogenesis in humans: metabolic and regulatory aspects

De novo lipogenesis in humans: metabolic and regulatory aspects

The enzymatic pathway for converting dietary carbohydrate (CHO) into fat, or de novo lipogenesis (DNL), is present in humans, whereas the capacity to convert fats into CHO does not exist. Here, the quantitative importance of DNL in humans is reviewed, focusing on the response to increased intake of...

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Bibliographic Details
Published in:European journal of clinical nutrition Vol. 53 Suppl 1; no. S1; pp. S53 - s65
Main Author: Hellerstein, M K
Format: Journal Article
Language:English
Published: England Nature Publishing Group 01-04-1999
Subjects:
Absorptivity
Adaptation
Adipose tissue
Body Composition - physiology
Body fat
Calorimetry, Indirect
Carbohydrates
Currencies
Diet
Dietary Carbohydrates - adverse effects
Dietary Carbohydrates - metabolism
Dietary intake
Energy expenditure
Energy intake
Energy Intake - physiology
Energy Metabolism - physiology
Energy sources
Enzymes
Female
Fuel mixtures
Genetics
Gluconeogenesis
Homeostasis - physiology
Humans
Insulin
Lipid Metabolism
Lipids - biosynthesis
Lipogenesis
Liver
Male
Metabolism
Oxidation
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Summary:The enzymatic pathway for converting dietary carbohydrate (CHO) into fat, or de novo lipogenesis (DNL), is present in humans, whereas the capacity to convert fats into CHO does not exist. Here, the quantitative importance of DNL in humans is reviewed, focusing on the response to increased intake of dietary CHO. Eucaloric replacement of dietary fat by CHO does not induce hepatic DNL to any substantial degree. Similarly, addition of CHO to a mixed diet does not increase hepatic DNL to quantitatively important levels, as long as CHO energy intake remains less than total energy expenditure (TEE). Instead, dietary CHO replaces fat in the whole-body fuel mixture, even in the post-absorptive state. Body fat is thereby accrued, but the pathway of DNL is not traversed; instead, a coordinated set of metabolic adaptations, including resistance of hepatic glucose production to suppression by insulin, occurs that allows CHO oxidation to increase and match CHO intake. Only when CHO energy intake exceeds TEE does DNL in liver or adipose tissue contribute significantly to the whole-body energy economy. It is concluded that DNL is not the pathway of first resort for added dietary CHO, in humans. Under most dietary conditions, the two major macronutrient energy sources (CHO and fat) are therefore not interconvertible currencies; CHO and fat have independent, though interacting, economies and independent regulation. The metabolic mechanisms and physiologic implications of the functional block between CHO and fat in humans are discussed, but require further investigation.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-3
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ObjectType-Review-1
ISSN:0954-3007
1476-5640
DOI:10.1038/sj.ejcn.1600744