Paradoxical resistance to diet-induced obesity in UCP1-deficient mice

Liu, Xiaotuan; Rossmeisl, Martin; McClaine, Jennifer W.; Kozak, Leslie P.

doi:10.1172/jci200315737

Cited by 262 publications

(137 citation statements)

References 45 publications

(18 reference statements)

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“…A large body of literature links increased dietary fat intake with obesity and cancer progression [59], but it is becoming clear that factors affecting obesity are altered at ST. For example, a UCP-1 knockout mouse model showed deficits in coldinduced non-shivering thermogenesis as expected, but failed to develop the expected obesity phenotype [60,61]. Several groups have now shown that this unexpected lack of the predicted phenotype was because the mice were housed at ST, and when these mice are housed at TT (and are not burning energy through adaptive thermogenesis) they do become obese [61][62][63][64]. This effect of ST on obesity has been observed in other models as well [65][66][67], and it is clear that precise data on the linkage between diet, obesity, and cancer should be re-examined in the context of absence of cold stress.…”

mentioning

confidence: 63%

Thermoneutrality, Mice, and Cancer: A Heated Opinion

Hylander

Repasky

2016

Trends in Cancer

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mentioning

confidence: 63%

Thermoneutrality, Mice, and Cancer: A Heated Opinion

Hylander

Repasky

2016

Trends in Cancer

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“…It is speculated that the absence of adequate amounts of BAT could lead to a severe overweight condition (Vijgen et al 2011;van der Lans et al 2013). However, mice with an inactive Ucp1 gene do not have increased susceptibility to DIO (Liu et al 2003), leading to an alternative interpretation that overall, metabolic efficiency is reduced in individuals with lower levels of UCP1-based thermogenesis (Butler and Kozak 2010). Other studies, with both genetic and surgically generated models of classical BAT insufficiency (Myf5-BMPR1A-KO), suggest the existence of a physiological mechanism to ensure thermoregulation by compensatory browning in WAT (Schulz et al 2013).…”

Section: Brown Adipose Tissuementioning

confidence: 99%

“…Schulz et al (2013) showed that classical BAT is crucial during acute cold challenges, but compensatory brown cells induced in WAT in Myf5-BMPR1A-KO mice (with severe insufficiency of classical BAT) had a critical role in normal body temperature maintenance, particularly in long-term cold exposure (Schulz et al 2013). The induction of brown adipocytes in the inguinal fat of mice with a deficiency in UCP1-based thermogenesis was originally shown by Liu et al (Liu et al 2003). The idea that brown adipocytes, which can be induced in white fat depots by adrenergic signaling, constitute a mechanism for reducing or preventing obesity is still not settled.…”

Section: Brown Adipose Tissuementioning

confidence: 99%

Obesity and related consequences to ageing

Jura

Kozak

2016

AGE

333

203

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Obesity has become a major public health problem. Given the current increase in life expectancy, the prevalence of obesity also raises steadily among older age groups. The increase in life expectancy is often accompanied with additional years of susceptibility to chronic ill health associated with obesity in the elderly. Both obesity and ageing are conditions leading to serious health problems and increased risk for disease and death. Ageing is associated with an increase in abdominal obesity, a major contributor to insulin resistance and the metabolic syndrome. Obesity in the elderly is thus a serious concern and comprehension of the key mechanisms of ageing and age-related diseases has become a necessary matter. Here, we aimed to identify similarities underlying mechanisms related to both obesity and ageing. We bring together evidence that age-related changes in body fat distribution and metabolism might be key factors of a vicious cycle that can accelerate the ageing process and onset of age-related diseases.

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“…As emphasized by Williams and Wagner [92], unexpected consequences of genomic modifications are frequent, and the phenotype or lack of phenotype observed in any transgenic experiment is a function of both the planned genetic modification and of secondary responses of the organism to that perturbation. An example of this principle was demonstrated in the case of UCP1-knockout mice, which when reared at 22 8C (but not at 278C) are more resistant to obesity during high-fat feeding than their wild types [93]; the authors attribute this paradox to alternative, calorically more costly pathways of metabolism for maintaining body temperature in the absence of UCP1-mediated nonshivering thermogenesis. Thus, since the knocking out of genes for reasonably well-established functions often fail to reveal the expected impairment in these functions because of compensatory mechanisms (known or unknown), the failure of UCP2 or UCP3-knockout mice to reveal major impairments in weight regulation via thermogenesis or substrate metabolism is not sufficient to reject the hypothesis that these UCP1-homologues play a role in thermogenesis or lipid metabolism.…”

Section: Is There a Role For Uncoupling Proteins In Fat Metabolism Anmentioning

confidence: 99%

Adaptive thermogenesis and uncoupling proteins: a reappraisal of their roles in fat metabolism and energy balance

Dulloo

Seydoux

Jacquet

2004

Physiology & Behavior

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After decades of controversies about the quantitative importance of autoregulatory adjustments in energy expenditure in weight regulation, there is now increasing recognition that even subtle variations in thermogenesis could, in dynamic systems and over the long term, be important in determining weight maintenance in some and obesity in others. The main challenge nowadays is to provide a mechanistic explanation for the role of adaptive thermogenesis in attenuating and correcting deviations of body weight and body composition, and in the identification of molecular mechanisms that constitute its effector systems. This workshop paper reconsiders what constitutes adaptive changes in thermogenesis and reassesses the role of the sympathetic nervous system (SNS) and uncoupling proteins (UCP1, UCP2, UCP3, UCP5/BMCP1) as the efferent and effector components of the classical one-control system for adaptive thermogenesis and fat oxidation. It then reviews the evidence suggesting that there are in fact two distinct control systems for adaptive thermogenesis, the biological significance of which is to satisfy-in a lifestyle of famine-and-feast-the needs to suppress thermogenesis for energy conservation during weight loss and weight recovery even under environmental stresses (e.g., cold, infection, nutrient imbalance) when sympathetic activation of thermogenesis has equally important survival value.Keywords: Obesity; Diabetes; Cachexia; Catecholamines; UCP Resistance to obesity in an obesigenic environmentOne of the greatest challenges towards understanding the aetiology of human obesity is to explain how in environments that promote overeating of high-fat foods and discourage physical activity, there is always a section of the population who, apparently without conscious effort, do not become obese. How do they resist obesity? How is constancy of body weight achieved over decades in these individuals? In addressing the issue of human susceptibility to leanness and fatness, there are three cardinal features of body weight regulation that need to be underlined: (i) Humans cannot escape the laws of thermodynamics.Whatever theory is put forward to explain body weight and body composition regulation, it is undeniable that changes in body energy stores (and ultimately body weight) cannot occur unless there is a difference between energy intake and energy expenditure. (ii) Subtle perturbations in energy balance can lead to obesity. To put it another way, long-term constancy of body weight can only be achieved if the matching between energy intake and energy expenditure is extremely precise, since an error of only 1% between input and output of energy, if persistent, will lead to a gain or loss of 1 kg per year or some 40 kg between the age of 20 to 60 years. Yet, a difference of 5% between energy intake and energy expenditure is hardly measurable with available techniques. (iii) Body weight is a fluctuating and oscillatory phenomenon. Even in individuals that maintain a relatively stable lean body weight over decades, the...

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Paradoxical resistance to diet-induced obesity in UCP1-deficient mice

Cited by 262 publications

References 45 publications

Thermoneutrality, Mice, and Cancer: A Heated Opinion

Thermoneutrality, Mice, and Cancer: A Heated Opinion

Obesity and related consequences to ageing

Adaptive thermogenesis and uncoupling proteins: a reappraisal of their roles in fat metabolism and energy balance

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