Lipolysis defect in people with obesity who undergo metabolic surgery

OBJECTIVE Cross-sectional studies demonstrate that catecholamine stimulation of fat cell lipolysis is blunted in obesity. We investigated whether this defect persists after substantial weight loss has been induced by metabolic surgery, and whether it is related to the outcome. DESIGN/METHODS Patients with obesity not able to successfully reduce body weight by conventional means (n = 126) were investigated before and 5 years after Roux-en-Y gastric bypass surgery (RYGB). They were compared with propensity-score matched subjects selected from a control group (n = 1017), and with the entire group after adjustment for age, sex, body mass index (BMI), fat cell volume and other clinical parameters. Catecholamine-stimulated lipolysis (glycerol release) was investigated in isolated fat cells using noradrenaline (natural hormone) or isoprenaline (synthetic beta-adrenoceptor agonist). RESULTS Following RYGB, BMI was reduced from 39.9 (37.5-43.5) (median and interquartile range) to 29.5 (26.7-31.9) kg/m2 (p < 0.0001). The post-RYGB patients had about 50% lower lipolysis rates compared with the matched and total series of controls (p < 0.0005). Nordrenaline activation of lipolysis at baseline was associated with the RYGB effect; those with high lipolysis activation (upper tertile) lost 30%-45% more in body weight, BMI or fat mass than those with low (bottom tertile) initial lipolysis activation (p < 0.0007). CONCLUSION Patients with obesity requiring metabolic surgery have impaired ability of catecholamines to stimulate lipolysis, which remains despite long-term normalization of body weight by RYGB. Furthermore, preoperative variations in the ability of catecholamines to activate lipolysis may predict the long-term reduction in body weight and fat mass.

[1]  P. Arner,et al.  A longitudinal study of the antilipolytic effect of insulin in women following bariatric surgery , 2021, International Journal of Obesity.

[2]  C. Daub,et al.  Human White Adipose Tissue Displays Selective Insulin Resistance in the Obese State , 2021, Diabetes.

[3]  C. Lindgren,et al.  Genome-wide association study of adipocyte lipolysis in the GENetics of adipocyte lipolysis (GENiAL) cohort , 2020, Molecular metabolism.

[4]  S. Bernard,et al.  Adipose lipid turnover and long-term changes in body weight , 2019, Nature Medicine.

[5]  P. Mancuso,et al.  The Impact of Aging on Adipose Function and Adipokine Synthesis , 2019, Front. Endocrinol..

[6]  Y. Böttcher,et al.  Genetics and epigenetics in obesity. , 2019, Metabolism: clinical and experimental.

[7]  E. Mariman,et al.  Mechanisms of weight regain after weight loss — the role of adipose tissue , 2019, Nature Reviews Endocrinology.

[8]  I. Shimomura,et al.  Fat cell lipolysis and future weight gain , 2018, Journal of Diabetes Investigation.

[9]  N. Hübner,et al.  An Integrated Understanding of the Molecular Mechanisms of How Adipose Tissue Metabolism Affects Long-term Body Weight Maintenance , 2018, Diabetes.

[10]  K. Stenkula,et al.  Adipose cell size: importance in health and disease. , 2018, American journal of physiology. Regulatory, integrative and comparative physiology.

[11]  P. Arner,et al.  Weight Gain and Impaired Glucose Metabolism in Women Are Predicted by Inefficient Subcutaneous Fat Cell Lipolysis. , 2018, Cell metabolism.

[12]  A. Drewnowski,et al.  Obesity Pathogenesis: An Endocrine Society Scientific Statement. , 2017, Endocrine reviews.

[13]  J. Krakoff,et al.  In Vitro lipolysis is associated with whole‐body lipid oxidation and weight gain in humans , 2017, Obesity.

[14]  P. Arner,et al.  Long-term Protective Changes in Adipose Tissue After Gastric Bypass , 2016, Diabetes Care.

[15]  D. Langin,et al.  Adipocyte lipolysis and insulin resistance. , 2016, Biochimie.

[16]  A. Xu,et al.  Heterogeneity of white adipose tissue: molecular basis and clinical implications , 2016, Experimental & Molecular Medicine.

[17]  F. Karpe,et al.  Biology of upper-body and lower-body adipose tissue—link to whole-body phenotypes , 2015, Nature Reviews Endocrinology.

[18]  A. Greenberg,et al.  Sex differences in human adipose tissues – the biology of pear shape , 2012, Biology of Sex Differences.

[19]  Abhi Shelat,et al.  One‐to‐many propensity score matching in cohort studies , 2012, Pharmacoepidemiology and drug safety.

[20]  P. Austin Balance diagnostics for comparing the distribution of baseline covariates between treatment groups in propensity-score matched samples , 2009, Statistics in medicine.

[21]  Tom Britton,et al.  Dynamics of fat cell turnover in humans , 2008, Nature.

[22]  P. Arner Human fat cell lipolysis: biochemistry, regulation and clinical role. , 2005, Best practice & research. Clinical endocrinology & metabolism.

[23]  P. Arner,et al.  Prospective and controlled studies of the actions of insulin and catecholamine in fat cells of obese women following weight reduction , 2005, Diabetologia.

[24]  B. Nicklas,et al.  Effects of hypocaloric diet and exercise training on inflammation and adipocyte lipolysis in obese postmenopausal women. , 2004, The Journal of clinical endocrinology and metabolism.

[25]  D. Allison,et al.  Years of life lost due to obesity. , 2003, JAMA.

[26]  Peter Arner,et al.  Major gender differences in the lipolytic capacity of abdominal subcutaneous fat cells in obesity observed before and after long-term weight reduction. , 2002, The Journal of clinical endocrinology and metabolism.

[27]  M. Uusitupa,et al.  Concordance of in vivo microdialysis and in vitro techniques in the studies of adipose tissue metabolism , 2000, International Journal of Obesity.

[28]  P. Arner,et al.  Metabolism of mono- and diacylglycerols in subcutaneous adipose tissue of obese and normal-weight subjects. , 2009, Acta medica Scandinavica.