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Grade of adiposity affects the impact of fat mass on resting energy expenditure in women

Published online by Cambridge University Press:  19 August 2008

Anja Bosy-Westphal*
Affiliation:
Institut für Humanernährung und Lebensmittelkunde, Agrar- und Ernährungswissenschaftliche Fakultät, Christian-Albrechts-Universität zu Kiel, Düsternbrooker Weg 17-19, D-24105Kiel, Germany
Manfred J. Müller
Affiliation:
Institut für Humanernährung und Lebensmittelkunde, Agrar- und Ernährungswissenschaftliche Fakultät, Christian-Albrechts-Universität zu Kiel, Düsternbrooker Weg 17-19, D-24105Kiel, Germany
Michael Boschmann
Affiliation:
Charité Campus Buch, Franz-Volhard-Centrum für Klinische Forschung, D-13122Berlin, Germany
Susanne Klaus
Affiliation:
Deutsches Institut für Ernährungsforschung, Abteilung Biochemie und Physiologie der Ernährung, D-14558Potsdam-Rehbrücke, Germany
Georg Kreymann
Affiliation:
Medizinische Klinik, Universitätskrankenhaus Eppendorf, D-20251Hamburg, Germany
Petra M. Lührmann
Affiliation:
Institut für Ernährungswissenschaft, Justus-Liebig-Universität, D-35390Giessen, Germany
Monika Neuhäuser-Berthold
Affiliation:
Institut für Ernährungswissenschaft, Justus-Liebig-Universität, D-35390Giessen, Germany
Rudolf Noack
Affiliation:
Deutsches Institut für Ernährungsforschung, Abteilung Biochemie und Physiologie der Ernährung, D-14558Potsdam-Rehbrücke, Germany
Karl M. Pirke
Affiliation:
Forschungszentrum für Psychobiologie und Psychosomatik, Universität Trier, D-54286Trier, Germany
Petra Platte
Affiliation:
Biologische und Klinische Psychologie, D-97070 Universität Würzburg, Germany
Oliver Selberg
Affiliation:
Institut für Mikrobiologie, Immunologie und Krankenhaushygiene, Städtisches Klinikum, D-38114Braunschweig, Germany
Jochen Steiniger
Affiliation:
Klinikum Berlin-Buch, Herbert-Krauß-Klinik, D-13122Berlin, Germany
*
*Corresponding author: Dr Anja Bosy-Westphal, fax +49 0431 8805679, email [email protected]
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Abstract

Body fat mass (FM) adds to the variance in resting energy expenditure (REE). However, the nature and extent of this relationship remains unclear. Using a database of 1306 women and a linear regression model, we systematically analysed the contribution of FM to the total variance in REE at different grades of adiposity (ranges of body %FM). After adjusting for age, the relative contribution of FM on REE variance increased from low ( ≤ 10 %FM) to normal (>10– ≤ 30 %FM) and moderately elevated (>30– ≤ 40 %FM) grades of adiposity but decreased sharply at high (>40– ≤ 50 %FM) and very high (>50 %FM) grades of adiposity according to the ratio between regression coefficients. These data suggest that the specific metabolic rate of fat tissue is reduced at high adiposity. This should be considered when REE is normalized for FM in obesity.

Type
Short Communication
Copyright
Copyright © The Authors 2008

Understanding the determinants of interindividual variance in resting energy expenditure (REE) is indispensable for interpreting (i.e. normalizing) or even predicting metabolic rate. Fat-free mass (FFM) explains 70–80 % of variance in REE. This is plausible because in a two-compartment model FFM is viewed as a surrogate for the metabolically active, oxygen-consuming body cell mass. By contrast, fat mass (FM) resembles the metabolically inert lipid compartment of the body. However, a number of studies also showed an independent contribution of FM (in kg) to the variance in REE(Reference Lazzer, Agosti, Silvestri, Derumeaux-Burel and Sartorio1Reference Müller, Bosy-Westphal and Klaus9). The contribution of FM to REE is generally explained by the energy requirement of adipose tissue. When compared with the specific metabolic rate of lean tissue (ranging from 54 kJ/kg for skeletal muscle to 1841 kJ/kg for heart and kidney, respectively(Reference Elia, Kinney and Tucker10)), the specific metabolic rate of adipose tissue is low (11·3–14·3 kJ/kg lipid(Reference Hallgren, Sjöström, Hedlund, Lundell and Olbe11)). In contrast to these in vitro results, regression equations from population analyses reveal different relationships between the effect of either FFM or FM on REE, i.e. the ratio between the regression coefficients of FFM and FM on REE ranged between 1·5:1(Reference Lazzer, Agosti, Silvestri, Derumeaux-Burel and Sartorio1) and 7:1(Reference Nelson, Weinsier, Long and Schutz4), suggesting that each kg of lean tissue exerts a 1·5–7 times greater effect on REE than did each kg of fat tissue. These discrepant results might be caused by differences in (1) age between study populations and/or (2) the degree of adiposity which might affect the secretion of metabolically active adipose tissue-derived hormones such as leptin, resitine or adiponectin. The contribution of the grade of adiposity on the relationship between REE and FM is currently unknown. The present study offers a systematic analysis of the relationship between REE, FFM, FM and age using data of a large population of healthy women with a wide BMI range stratified by degree of adiposity.

Subjects and methods

A detailed description of the study population recruited in seven German research centres as well as the assessment of body composition and REE have been published previously(Reference Müller, Bosy-Westphal and Klaus9). Children and adolescents were excluded because of the impact of growth and maturity status on body composition and energy expenditure. In addition, men were omitted because of insufficient sample sizes in low and very high BMI groups. Finally, a subgroup of 1306 non-pregnant and non-lactating Caucasian women, with large range in age (18·0–91·2 years) and BMI (12·4–67·1 kg/m2) served as the basis of the study. All subjects were investigated under clinically stable conditions and no subject took medications known to influence REE. Smoking was not considered as an exclusion criteria. Written informed consent was obtained from each subject at the beginning of the study, which was approved by the responsible local Ethic Committees.

Anthropometric data and body composition

Body weight was measured in underwear to the nearest 0·1 kg and standing height without shoes to the nearest 0·5 cm. Body composition was assessed by either bioelectrical impedance analysis (n 1079 subjects) or skinfold measurements (n 227 subjects). A single tetrapolar bioelectrical impedance analysis measurement of resistance and reactance was taken between the right wrist and ankle while in a supine position. Bioelectrical impedance analysis devices and algorithms are reported elsewhere(Reference Müller, Bosy-Westphal and Klaus9). Triceps, subscapular and supraileacal skinfolds were measured on the right side of the body to the nearest 0·5 mm by a Lange Skinfold Caliper as a mean of three measurements taken by the same investigator (see Müller et al. (Reference Müller, Bosy-Westphal and Klaus9) for respective equations).

Assessment of resting energy expenditure

REE was obtained by indirect calorimetry using different ventilated hood systems, or a respiratory chamber (see Müller et al. (Reference Müller, Bosy-Westphal and Klaus9) for description of the individual measurement procedures, technical devices and calibration). Continuous gas exchange measurements were taken in the morning after an overnight fast. REE (kJ) was calculated by using the Weir equation (ventilated hood) or by 16·18 VO2+5·02 VCO2 − 5·99 Nexcretion (respiratory chamber).

Statistics

Stepwise linear regression analysis (SPSS version 13.0; SPSS Inc., Chicago, IL, USA) was used to model the relationship between REE and body composition at varying grades of adiposity. Study centre was not a significant covariate in these models. REE was adjusted for age and body composition using linear regression analysis. Adjustment for age was performed because of the age-dependent decrease in the relative contribution of high metabolic rate organ mass to FFM(Reference Petersen, Befroy, Dufour, Dziura, Ariyan, Rothman, DiPietro, Cline and Shulman12) and mitochondrial dysfunction in the elderly(Reference Bosy-Westphal, Eichhorn, Kutzner, Illner, Heller and Müller13) that both contribute to a lower REE per FFM with age. Differences between categories of %FM are analysed by ANOVA with Bonferoni's post hoc test.

Results

Subject characteristics for the total study population are shown in Table 1 stratified into five subgroups according to the grade of adiposity (defined by %FM). REE as well as REE adjusted for age and FFM increased with increasing %FM. These differences disappeared after further adjustment for FM in a range between >10 and ≤ 50 %FM. By contrast, REE adjusted for age, FFM and FM was significantly lower at ≤ 10 %FM and >50 %FM.

Table 1 Characteristics of the study population by grade of adiposity (percentage fat mass)

(Mean values and standard deviations)

FFM, fat-free mass; FM, fat mass; REE, resting energy expenditure; REEadj1, REE adjusted for age and FFM; REEadj2, REE adjusted for age, FFM and FM.

a,b Mean values within a column with a common superscript letter were not significantly different.

Multivariate linear regression models with measured REE as dependent variable, and age, FFM and FM as independent variables as well as regression coefficients (K1 and K2) are shown in Table 2. At both a very low ( ≤ 10 %FM) and a very high grade of adiposity (>50 %FM) the variance in REE was mainly (46·5 and 64·5 %) explained by FM in kg whereas at intermediate %FM categories it was 3·4, 12·4 and 1·4 %. The ratio between K1 and K2 decreased with increasing adiposity from ≤ 10 %FM to >10– ≤ 30 %FM and >30– ≤ 40 %FM. Thus, the relative impact of FM on REE variance increased with increasing %FM with a concomitant decrease in the relative contribution of FFM. By contrast, at high (>40– ≤ 50 %FM) as well as at very high (>50 %FM) grade of adiposity, the K1/K2 ratio sharply increased to values >1, suggesting a lower impact of FM v. FFM in obese subjects.

Table 2 Age-adjusted covariate effects of fat-free mass (FFM) and fat mass (FM) on resting energy expenditure (REE) by grade of adiposity (%FM)*

K1, K2, regression coefficients; R 2, covariate variance; see, standard error of the estimate.

* REE (kcal/d) = K1 × FFM (kg) + K2 × FM (kg) + intercept.

All regression coefficients were significant: P < 0·001.

Discussion

We have shown that the effect of absolute FM on the variance in REE depends on the grade of adiposity. Up to a FM of 40 % it increased with increasing adiposity, but decreased with a further increase in %FM. There may be at least two explanations for this finding. First, a lower specific metabolic rate of adipose tissue in obesity may be explained by greater adipocytes and obesity-associated mitochondrial dysfunction and degeneration. This phenomenon has been shown in human skeletal muscle(Reference Kelley, He, Menshikova and Ritov14) and also occurs in adipocytes of obese db/db mice(Reference Choo, Kim, Kwon, Lee, Mun, Han, Yoon, Yoon, Choi and Ko15). Moreover, in vitro the specific metabolic rate of adipose tissue decreased with increasing grade of obesity(Reference Hallgren, Sjöström, Hedlund, Lundell and Olbe11). Alternatively, a lower relative contribution of FM to REE may be explained by a higher specific metabolic rate of FFM. In obesity, metabolic alterations associated with insulin resistance have been shown to correlate with an elevated REE(Reference Weyer, Bogardus and Pratley16). The latter explanation is contradicted by our finding of a significantly lower REE adjusted for age, FFM and FM in subjects with >50 %FM (Table 1). The present observation indicates an overestimation of the specific metabolic rate of adipose tissue rather than an underestimation of the energy requirement of FFM. Although both effects may be present simultaneously, an underestimation of the specific metabolic rate of FFM only partly compensates the overestimation in the energy requirement of adipose tissue.

In severely obese subjects (>50 %FM) FM explained the main variance in REE (see Results). This is in line with other studies showing a higher ‘impact’ of FM on REE in obese populations(Reference Lazzer, Agosti, Silvestri, Derumeaux-Burel and Sartorio1, Reference Bernstein, Thornton, Yang, Wang, Redmond, Pierson, Pi-Sunyer and Van Itallie2, Reference Nelson, Weinsier, Long and Schutz4, Reference Svendsen, Hassager and Christiansen5, Reference Hoffmans, Pfeifer, Gundlach, Nijkrake, Oude Ophuis and Hautvast8) but a lower or even absent effect in lean subjects(Reference Cunningham17). These earlier findings were explained by the low specific metabolic rate of adipose tissue because adipose tissue mass has to become large before significantly contributing to REE(Reference Nelson, Weinsier, Long and Schutz4). However, this interpretation may be misleading because the coefficient of determination for FM was also higher at a very low FM (see Results). A steep relationship between REE and FM in underweight females with anorexia nervosa has been observed previously in our group(Reference Haas, Onur, Paul, Nutzinger, Bosy-Westphal, Hauer, Brabant, Klein and Müller18). This relationship is lost after weight gain (i.e. gain in FM) of about 8–10 kg body weight. Although in the underweight patients the relationship was confirmed for REE v. serum leptin levels, it was unlikely to be explained by leptin secretion, because it remained no longer significant after adjusting FM for leptin levels (V Haas et al., unpublished results).

The present finding of a lower impact of FM on REE at high adiposity (>40 %FM) remains causally enigmatic, but may be consistent with the finding that (1) the coefficient of FM in the REE prediction equation was even negative in severely obese subjects(Reference Huang, Kormas, Steinbeck, Loughnan and Caterson19) and (2) REE is systematically overestimated in obese subjects by standard prediction equations(Reference Heshka, Feld, Yang, Allison and Heymsfield20Reference Horgan and Stubbs22). Part of the ‘thermic effect’ of FM may be explained by adipocyte secretory activity (e.g. leptin was considered a thermogenic hormone(Reference Pelleymounter, Cullen, Baker, Hecht, Winters, Boone and Collins23)). However, human data are equivocal and future studies are needed to investigate the impact of adipokine secretion on the ‘thermic effect’ of FM in lean v. obese subjects. Low sample sizes in the lowest and highest category of FM are a limitation of the present study. Further studies in the extremes of body composition are needed to confirm the present results.

In conclusion, the impact of FM on the variance in REE depends on the grade of adiposity. The impact of FM on REE increased up to 40 %FM. At higher grades of adiposity the impact of FM on REE was reduced. This decrease cannot be sufficiently explained by the metabolic rate of adipose tissue. Adjusting REE for FM by an equation derived from lean or overweight subjects may lead to spurious conclusions in obesity.

Acknowledgements

Data collection was performed by A. B. W., M. B., S. K., G. K., P. M. L., M. N.-B., R. N., K. M. P., P. P., O. S. and J. S. The data were analysed by A. B. W. and M. J. M. The manuscript was written by A. B. W., M. B. and M. J. M. There are no conflicts of interest.

References

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Figure 0

Table 1 Characteristics of the study population by grade of adiposity (percentage fat mass)(Mean values and standard deviations)

Figure 1

Table 2 Age-adjusted covariate effects of fat-free mass (FFM) and fat mass (FM) on resting energy expenditure (REE) by grade of adiposity (%FM)*