{"title":"Concept of fat balance in human obesity revisited with particular reference to de novo lipogenesis.","authors":"Y Schutz","doi":"10.1038/sj.ijo.0802852","DOIUrl":null,"url":null,"abstract":"<p><p>The measurement of fat balance (fat input minus fat output) involves the accurate estimation of both metabolizable fat intake and total fat oxidation. This is possible mostly under laboratory conditions and not yet in free-living conditions. In the latter situation, net fat retention/mobilization can be estimated based on precise and accurate sequential body composition measurements. In case of positive balance, lipids stored in adipose tissue can originate from dietary (exogenous) lipids or from nonlipid precursors, mainly from carbohydrates (CHOs) but also from ethanol, through a process known as de novo lipogenesis (DNL). Basic equations are provided in this review to facilitate the interpretation of the different subcomponents of fat balance (endogenous vs exogenous) under different nutritional circumstances. One difficulty is methodological: total DNL is difficult to measure quantitatively in man; for example, indirect calorimetry only tracks net DNL, not total DNL. Although the numerous factors (mostly exogenous) influencing DNL have been studied, in particular the effect of CHO overfeeding, there is little information on the rate of DNL in habitual conditions of life, that is, large day-to-day fluctuations of CHO intakes, different types of CHO ingested with different glycemic indexes, alcohol combined with excess CHO intakes, etc. Three issues, which are still controversial today, will be addressed: (1) Is the increase of fat mass induced by CHO overfeeding explained by DNL only, or by decreased endogenous fat oxidation, or both? (2) Is DNL different in overweight and obese individuals as compared to their lean counterparts? (3) Does DNL occur both in the liver and in adipose tissue? Recent studies have demonstrated that acute CHO overfeeding influences adipose tissue lipogenic gene expression and that CHO may stimulate DNL in skeletal muscles, at least in vitro. The role of DNL and its importance in health and disease remain to be further clarified, in particular the putative effect of DNL on the control of energy intake and energy expenditure, as well as the occurrence of DNL in other tissues (such as in myocytes) in addition to hepatocytes and adipocytes.</p>","PeriodicalId":14227,"journal":{"name":"International journal of obesity and related metabolic disorders : journal of the International Association for the Study of Obesity","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2004-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1038/sj.ijo.0802852","citationCount":"58","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International journal of obesity and related metabolic disorders : journal of the International Association for the Study of Obesity","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1038/sj.ijo.0802852","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 58
Abstract
The measurement of fat balance (fat input minus fat output) involves the accurate estimation of both metabolizable fat intake and total fat oxidation. This is possible mostly under laboratory conditions and not yet in free-living conditions. In the latter situation, net fat retention/mobilization can be estimated based on precise and accurate sequential body composition measurements. In case of positive balance, lipids stored in adipose tissue can originate from dietary (exogenous) lipids or from nonlipid precursors, mainly from carbohydrates (CHOs) but also from ethanol, through a process known as de novo lipogenesis (DNL). Basic equations are provided in this review to facilitate the interpretation of the different subcomponents of fat balance (endogenous vs exogenous) under different nutritional circumstances. One difficulty is methodological: total DNL is difficult to measure quantitatively in man; for example, indirect calorimetry only tracks net DNL, not total DNL. Although the numerous factors (mostly exogenous) influencing DNL have been studied, in particular the effect of CHO overfeeding, there is little information on the rate of DNL in habitual conditions of life, that is, large day-to-day fluctuations of CHO intakes, different types of CHO ingested with different glycemic indexes, alcohol combined with excess CHO intakes, etc. Three issues, which are still controversial today, will be addressed: (1) Is the increase of fat mass induced by CHO overfeeding explained by DNL only, or by decreased endogenous fat oxidation, or both? (2) Is DNL different in overweight and obese individuals as compared to their lean counterparts? (3) Does DNL occur both in the liver and in adipose tissue? Recent studies have demonstrated that acute CHO overfeeding influences adipose tissue lipogenic gene expression and that CHO may stimulate DNL in skeletal muscles, at least in vitro. The role of DNL and its importance in health and disease remain to be further clarified, in particular the putative effect of DNL on the control of energy intake and energy expenditure, as well as the occurrence of DNL in other tissues (such as in myocytes) in addition to hepatocytes and adipocytes.
脂肪平衡(脂肪输入减去脂肪输出)的测量包括对可代谢脂肪摄入量和总脂肪氧化的准确估计。这在实验室条件下是可能的,但在自由生活的条件下还不行。在后一种情况下,可以根据精确和准确的连续身体成分测量来估计净脂肪保留/动员。在正平衡的情况下,储存在脂肪组织中的脂质可以来自膳食(外源性)脂质或非脂质前体,主要来自碳水化合物(CHOs),也来自乙醇,通过称为de novo lipogenesis (DNL)的过程。在这篇综述中提供了基本方程,以方便解释不同营养情况下脂肪平衡的不同子成分(内源性与外源性)。一个困难是方法上的:人类的总DNL很难定量测量;例如,间接量热法只能追踪净无氮含量,而不能追踪总无氮含量。虽然已经研究了影响DNL的众多因素(主要是外源性因素),特别是CHO过度摄食的影响,但关于生活习惯条件下DNL发生率的信息很少,即CHO摄入量的日常波动大,不同类型的CHO摄入不同的血糖指数,酒精合并过量的CHO摄入等。本文将解决三个至今仍有争议的问题:(1)CHO过度喂养引起的脂肪量增加是否仅由DNL解释,还是由内源性脂肪氧化减少解释,还是两者兼而有之?(2)超重和肥胖个体的DNL与瘦个体相比是否不同?(3) DNL是否同时发生在肝脏和脂肪组织中?最近的研究表明,急性CHO过度喂养会影响脂肪组织的脂质基因表达,CHO可能会刺激骨骼肌的DNL,至少在体外是这样。DNL的作用及其在健康和疾病中的重要性仍有待进一步阐明,特别是DNL在控制能量摄入和能量消耗方面的假定作用,以及DNL在肝细胞和脂肪细胞以外的其他组织(如肌细胞)中的发生。