Effect of BMI and age on adipose tissue cellularity and differentiation capacity in women.

OBJECTIVE: To study the relation between body mass index (BMI) and age on the one hand and total number of human (pre-) adipocytes and preadipocyte differentiation capacity on the other hand. SUBJECTS: In total, 189 women undergoing surgical mammary reduction, age range 16-73 y, BMI range 19.7-39.7 kg/m(2). MEASUREMENTS: Differentiation of preadipocytes in primary culture was assessed by morphological criteria, and determination of glycerol-3-phosphate dehydrogenase after stimulation of the cells by standardized adipogenic conditions containing isobutyl-methylxanthine, troglitazone or both compounds. The total number of stromal cells (ie preadipocytes) and fat cells per gram of adipose tissue and per body as well as mature fat cell volume were calculated from isolated stromal cells and adipocytes, respectively, and anthropometric measures. RESULTS: BMI correlated positively to age, mature fat cell size and total number of adipocytes and stromal cells per body (r varying from 0.22 to 0.54, each P<0.05). In contrast, BMI correlated negatively to the number of adipocytes and stromal cells per gram of adipose tissue and the capacity of preadipocytes to differentiate (r varying from -0.20 to -0.37, each P<0.05). No significant correlation was observed between BMI and the ratio of stromal cells to adipocytes. The sample was also divided into three groups: BMI <25 kg/m(2) (lean), BMI 25-29.9 kg/m(2) (overweight) and BMI >/=30 kg/m(2) (obese). The overweight group showed a larger fat cell size but no increase in total fat cell or stromal cell number when compared to the lean subjects. The obese subjects showed larger stromal and fat cell numbers when compared to the lean subjects. Age did not independently correlate to the number of stromal cells or adipocytes per gram of adipose tissue or total body, nor with the capacity of preadipocytes to undergo differentiation and the ratio of stromal cells to adipocytes. CONCLUSION: There seems to be a constant ratio between the number of adipose tissue stromal cells and adipocytes independently of BMI and age in humans. During adipose tissue expansion, there seems to be both a continuous increase in fat cell size, and in stromal cell and adipocyte number, but the increase in fat cell size apparently precedes the increase in fat cell number. The differentiation capacity of the stromal cells appears to decrease with increasing BMI.

Calorie restriction increases light-dependent photoreceptor cell loss in the neural retina of fischer 344 rats.

We investigated the effect of > or = 8 months of 40% caloric restriction (CR) on photoreceptor cell loss in 12, 18, and 24 month-old Fischer 344 rats (N = 154). Rats were reared at the NIA Biomarkers Program, National Center for Toxicological Research. Photoreceptor cell density, assessed histologically, declined with age in both the CR-fed and ad lib (AL)-fed cohorts (P < 0.000), but declines were more pronounced in the CR cohort (P < 0.0005). The deleterious effect of CR was most pronounced in the central as opposed to the peripheral retina (P = 0.008), suggesting a light-dependent mechanism. Photoreceptor cell density was inversely associated with rearing under bright light (300-750 lux) as compared with rearing under lower illuminance (< or = 200 lux) (P < 0.0005). However, the deleterious effect of bright light on photoreceptor cell density was more pronounced in the CR cohort (P = 0.04). Effects of CR on circadian activity are likely to increase the actual light exposure of the CR cohort and may explain the apparent inability of CR to delay retinal aging in albino rats.

Calorie restriction modulates age-dependent changes in the retinas of Brown Norway rats.

The present study examined the effect of a 40% reduction in caloric intake (CR) versus ad libitum (AL) feeding on retinal aging. CR- and AL-fed Brown Norway (BN) rats were obtained at 12, 24 and 30 months of age from the National Center for Toxicological Research (NCTR). Age-dependent declines in outer nuclear layer (ONL=photoreceptor) cell densities, ONL height, inner nuclear layer (INL) cell densities, and thicknesses of the inner retina and whole retina were quantified in thick sections at six loci across the circumference of the sensory retina (four peripheral, two central). Data were analyzed by repeated measures, general linear models. Aging in both diet groups was associated with declines in ONL cell density, ONL height, peripheral INL cell density and total retinal thickness (P< or =0.05). However, ONL cell densities, ONL height and retinal thickness were significantly greater in the CR versus AL diet group at all three ages (P< or =0.005). CR was also associated with a trend for greater peripheral INL cell density (P=0.06) and with greater INL thickness at 30 months (Bonferroni P=0.03). Elevated ONL cell densities in the CR-12 cohort relative to the AL-12 cohort could be explained by diet-associated differences in retinal length, i.e. delayed retinal growth in response to CR. Enhanced ONL cell density, ONL height, INL cell density, INL thickness and total retinal thickness in the CR-30 cohort appear to be as a result of reduced rates of retinal cell loss between 24 and 30 months. However, the protective effect of CR in retinas of older animals may also reflect the initial growth-associated enhancements which were observed in 12 month-old animals. The rat retina may provide a useful model for elucidating the neuroprotective mechanism(s) of CR.