Your search keyword '"Reduced energy expenditure"' showing total 3 results

1. In vivo structure-function studies of human hepatic lipase: the catalytic function rescues the lean phenotype of HL-deficient ( hl−/−) mice.

Author

Chen, Jeffrey, Kaiyala, Karl J., Lam, Jennifer, Agrawal, Nalini, Nguyen, Lisa, Ogimoto, Kayoko, Spencer, Dean, Morton, Gregory J., Schwartz, Michael W., and Dichek, Helén L.

Subjects

*GENETIC pleiotropy, *GENOTYPE-environment interaction, *GENOTYPES, *GENETICS, *LIPASES

Abstract

The lean body weight phenotype of hepatic lipase ( HL)-deficient mice ( hl−/−) suggests that HL is required for normal weight gain, but the underlying mechanisms are unknown. HL plays a unique role in lipoprotein metabolism performing bridging as well as catalytic functions, either of which could participate in energy homeostasis. To determine if both the catalytic and bridging functions or the catalytic function alone are required for the effect of HL on body weight, we studied ( hl−/−) mice that transgenically express physiologic levels of human (h) HL (with catalytic and bridging functions) or a catalytically-inactive (ci) HL variant (with bridging function only) in which the catalytic Serine 145 was mutated to Alanine. As expected, HL activity in postheparin plasma was restored to physiologic levels only in hHL-transgenic mice ( hl−/− hHL). During high-fat diet feeding, hHL-transgenic mice exhibited increased body weight gain and body adiposity relative to hl−/− ci HL mice. A similar, albeit less robust effect was observed in female hHL-transgenic relative to hl−/− ci HL mice. To delineate the basis for this effect, we determined cumulative food intake and measured energy expenditure using calorimetry. Interestingly, in both genders, food intake was 5-10% higher in hl−/− hHL mice relative to hl−/− ci HL controls. Similarly, energy expenditure was ~10% lower in HL-transgenic mice after adjusting for differences in total body weight. Our results demonstrate that (1) the catalytic function of HL is required to rescue the lean body weight phenotype of hl−/− mice; (2) this effect involves complementary changes in both sides of the energy balance equation; and (3) the bridging function alone is insufficient to rescue the lean phenotype of hl−/− ci HL mice. [ABSTRACT FROM AUTHOR]

Published

2015

2. In vivo structure-function studies of human hepatic lipase: the catalytic function rescues the lean phenotype of HL-deficient (hl-/-) mice

Author

Helén L. Dichek, Karl J. Kaiyala, Jeffrey Chen, Jennifer Lam, Dean Spencer, Michael W. Schwartz, Gregory J. Morton, Kayoko Ogimoto, Lisa Nguyen, and Nalini Agrawal

Subjects

medicine.medical_specialty, Physiology, 030204 cardiovascular system & hematology, reduced energy expenditure, Energy homeostasis, Serine, 03 medical and health sciences, 0302 clinical medicine, In vivo, Physiology (medical), Internal medicine, medicine, 030304 developmental biology, Original Research, 2. Zero hunger, Alanine, 0303 health sciences, Chemistry, weight gain, Phenotype, hepatic lipase, Endocrinology, Lean body mass, Hepatic lipase, Catalytic function, medicine.symptom, Weight gain

Abstract

The lean body weight phenotype of hepatic lipase (HL)-deficient mice (hl(-/-)) suggests that HL is required for normal weight gain, but the underlying mechanisms are unknown. HL plays a unique role in lipoprotein metabolism performing bridging as well as catalytic functions, either of which could participate in energy homeostasis. To determine if both the catalytic and bridging functions or the catalytic function alone are required for the effect of HL on body weight, we studied (hl(-/-)) mice that transgenically express physiologic levels of human (h)HL (with catalytic and bridging functions) or a catalytically-inactive (ci)HL variant (with bridging function only) in which the catalytic Serine 145 was mutated to Alanine. As expected, HL activity in postheparin plasma was restored to physiologic levels only in hHL-transgenic mice (hl(-/-)hHL). During high-fat diet feeding, hHL-transgenic mice exhibited increased body weight gain and body adiposity relative to hl(-/-)ciHL mice. A similar, albeit less robust effect was observed in female hHL-transgenic relative to hl(-/-)ciHL mice. To delineate the basis for this effect, we determined cumulative food intake and measured energy expenditure using calorimetry. Interestingly, in both genders, food intake was 5-10% higher in hl(-/-)hHL mice relative to hl(-/-)ciHL controls. Similarly, energy expenditure was ~10% lower in HL-transgenic mice after adjusting for differences in total body weight. Our results demonstrate that (1) the catalytic function of HL is required to rescue the lean body weight phenotype of hl(-/-) mice; (2) this effect involves complementary changes in both sides of the energy balance equation; and (3) the bridging function alone is insufficient to rescue the lean phenotype of hl(-/-)ciHL mice.

Published

2015

3. In vivo structure-function studies of human hepatic lipase: the catalytic function rescues the lean phenotype of HL-deficient (hl-/-) mice.

Author

Chen J, Kaiyala KJ, Lam J, Agrawal N, Nguyen L, Ogimoto K, Spencer D, Morton GJ, Schwartz MW, and Dichek HL

Abstract

The lean body weight phenotype of hepatic lipase (HL)-deficient mice (hl(-/-)) suggests that HL is required for normal weight gain, but the underlying mechanisms are unknown. HL plays a unique role in lipoprotein metabolism performing bridging as well as catalytic functions, either of which could participate in energy homeostasis. To determine if both the catalytic and bridging functions or the catalytic function alone are required for the effect of HL on body weight, we studied (hl(-/-)) mice that transgenically express physiologic levels of human (h)HL (with catalytic and bridging functions) or a catalytically-inactive (ci)HL variant (with bridging function only) in which the catalytic Serine 145 was mutated to Alanine. As expected, HL activity in postheparin plasma was restored to physiologic levels only in hHL-transgenic mice (hl(-/-)hHL). During high-fat diet feeding, hHL-transgenic mice exhibited increased body weight gain and body adiposity relative to hl(-/-)ciHL mice. A similar, albeit less robust effect was observed in female hHL-transgenic relative to hl(-/-)ciHL mice. To delineate the basis for this effect, we determined cumulative food intake and measured energy expenditure using calorimetry. Interestingly, in both genders, food intake was 5-10% higher in hl(-/-)hHL mice relative to hl(-/-)ciHL controls. Similarly, energy expenditure was ~10% lower in HL-transgenic mice after adjusting for differences in total body weight. Our results demonstrate that (1) the catalytic function of HL is required to rescue the lean body weight phenotype of hl(-/-) mice; (2) this effect involves complementary changes in both sides of the energy balance equation; and (3) the bridging function alone is insufficient to rescue the lean phenotype of hl(-/-)ciHL mice., (© 2015 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of the American Physiological Society and the Physiological Society.)

Published

2015