Amelioration of insulin resistance by rosiglitazone is associated with increased adipose cell size in obese type 2 diabetic patients.

Early studies reported that the size of adipose cells positively correlates with insulin resistance, but recent evidence suggests that the relationship between adipose cell size and insulin resistance is more complex. We previously reported that among BMI-matched moderately obese subjects who were either insulin sensitive or resistant insulin resistance correlated with the proportion of small adipose cells, rather than the size of the large adipose cells, whereas the size of large adipose cells was found to be a predictor of insulin resistance in the first-degree relatives of type 2 diabetic (T2D) patients. The relationship between adipose cellularity and insulin resistance thus appears to depend on the metabolic state of the individual. We did a longitudinal study with T2D patients treated with the insulin-sensitizer rosiglitazone to test the hypothesis that improved insulin sensitivity is associated with increased adipocyte size. Eleven T2D patients were recruited and treated with rosiglitazone for 90 days. Blood samples and needle biopsies of abdominal subcutaneous fat were taken at six time points and analyzed for cell size distributions. Rosiglitazone treatment ameliorated insulin resistance as evidenced by significantly decreased fasting plasma glucose and increased index of insulin sensitivity, QUICKI. In association with this, we found significantly increased size of the large adipose cells and, with a weaker effect, increased proportion of small adipose cells. We conclude rosiglitazone treatment both enlarges existing large adipose cells and recruits new small adipose cells in T2D patients, improving fat storage capacity in adipose tissue and thus systemic insulin sensitivity.

Hypertrophy-driven adipocyte death overwhelms recruitment under prolonged weight gain.

Fat pads dynamically regulate energy storage capacity under energy excess and deficit. This remodeling process is not completely understood, with controversies regarding differences between fat depots and plasticity of adipose cell number. We examined changes of mouse adipose cell-size distributions in epididymal, inguinal, retroperitoneal, and mesenteric fat under both weight gain and loss. With mathematical modeling, we specifically analyzed the recruitment, growth/shrinkage, and loss of adipose cells, including the size dependence of these processes. We found a qualitatively universal adipose tissue remodeling process in all four fat depots: 1), There is continuous recruitment of new cells under weight gain; 2), the growth and shrinkage of larger cells (diameter >50 µm) is proportional to cell surface area; and 3), cell loss occurs under prolonged weight gain, with larger cells more susceptible. The mathematical model gives a predictive integrative picture of adipose tissue remodeling in obesity.

Hypertrophy and/or Hyperplasia: Dynamics of Adipose Tissue Growth.

Adipose tissue grows by two mechanisms: hyperplasia (cell number increase) and hypertrophy (cell size increase). Genetics and diet affect the relative contributions of these two mechanisms to the growth of adipose tissue in obesity. In this study, the size distributions of epididymal adipose cells from two mouse strains, obesity-resistant FVB/N and obesity-prone C57BL/6, were measured after 2, 4, and 12 weeks under regular and high-fat feeding conditions. The total cell number in the epididymal fat pad was estimated from the fat pad mass and the normalized cell-size distribution. The cell number and volume-weighted mean cell size increase as a function of fat pad mass. To address adipose tissue growth precisely, we developed a mathematical model describing the evolution of the adipose cell-size distributions as a function of the increasing fat pad mass, instead of the increasing chronological time. Our model describes the recruitment of new adipose cells and their subsequent development in different strains, and with different diet regimens, with common mechanisms, but with diet- and genetics-dependent model parameters. Compared to the FVB/N strain, the C57BL/6 strain has greater recruitment of small adipose cells. Hyperplasia is enhanced by high-fat diet in a strain-dependent way, suggesting a synergistic interaction between genetics and diet. Moreover, high-fat feeding increases the rate of adipose cell size growth, independent of strain, reflecting the increase in calories requiring storage. Additionally, high-fat diet leads to a dramatic spreading of the size distribution of adipose cells in both strains; this implies an increase in size fluctuations of adipose cells through lipid turnover.

Characterization of ryanodine receptor-mediated calcium release in human B cells: relevance to diagnostic testing for malignant hyperthermia.

BACKGROUND: Mutations in the ryanodine type 1 receptor (RyR1) are causative for malignant hyperthermia. Studies in human B lymphocytes have shown that measurement of RyR1-mediated intracellular Ca(2+) (Ca(2+)(i)) release can differentiate between normal and malignant hyperthermia-susceptible individuals. The authors have further developed the B-cell assay by pharmacologically characterizing RyR1-mediated Ca release in two normal human B-cell lines and demonstrating increased sensitivity of lymphocytes to the RyR1 agonist 4-chloro-m-cresol (4-CmC) in the porcine model of MH. METHODS: Ca(2+)(i) was measured fluorometrically using fura-2 in populations of cells in suspension or with fluo-4 in single cells using confocal microscopy. The Dakiki and PP normal human B cell lines were used, as well as lymphocytes obtained from normal and malignant hyperthermia-susceptible pigs. 4-CmC was used to elicit RyR1-mediated Ca release; all experiments were performed in the absence of external Ca(2+). RESULTS: EC(50) values for 4-CmC were 0.98 and 1.04 mm for Dakiki and PP cells, respectively, demonstrating reproducibility. The 4-CmC-induced increase in Ca(2+)(i) was eliminated by thapsigargin and was unaffected by xestospongin C. The Ca(2+)(i) increase was separable from mitochondrial stores and was inhibited by azumolene. Caffeine did not induce Ca(2+)(i) release, but ryanodine depleted intracellular stores by 50%. Lymphocytes from pigs carrying the Arg614Cys mutation in RyR1 showed increased sensitivity to 4-CmC (EC(50) = 0.47 vs. 0.81 mm for cells derived from normal animals). CONCLUSIONS: RyR1-mediated Ca(2+) signals can be pharmacologically distinguished from other intracellular sources in human B cells, and alterations of RyR1 function can be successfully detected using Ca(2+) release from intracellular stores as an end point.