Little is known about the role of islet delta cells in regulating blood glucose homeostasis in vivo. Delta cells are important paracrine regulators of beta cell and alpha cell secretory activity, however the structural basis underlying this regulation has yet to be determined. Most delta cells are elongated and have a well-defined cell soma and a filopodia-like structure. Using in vivo optogenetics and high-speed Ca 2+ imaging, we show that these filopodia are dynamic structures that contain a secretory machinery, enabling the delta cell to reach a large number of beta cells within the islet. This provides for efficient regulation of beta cell activity and is modulated by endogenous IGF-1/VEGF-A signaling. In pre-diabetes, delta cells undergo morphological changes that may be a compensation to maintain paracrine regulation of the beta cell. Our data provides an integrated picture of how delta cells can modulate beta cell activity under physiological conditions.
Identifying the mechanisms behind the β-cell adaptation-to-failure is important to develop strategies to manage type 2 diabetes (T2D). Using db/db mice at early stages of the disease process, we took advantage of unbiased RNAseq to identify genes/pathways regulated by insulin resistance in β-cells. We demonstrate herein that islets from 4-week-old non-obese and non-diabetic leptin-receptor deficient db/db mice exhibited downregulation of several genes involved in cell-cycle regulation and DNA repair. We identified the transcription factor Yin Yang 1 (YY1) as a common gene between both pathways. The expression of YY1 and its targeted genes was decreased in the db/db islets. We confirmed the reduction in YY1 expression in β-cells from diabetic db/db mice, mice fed high fat diet (HFD) and individuals with T2D. ChIP-seq profiling in EndocBH1 cells, a human pancreatic β-cell line, indicated that YY1 binding regions regulate cell-cycle control, DNA damage recognition and repair. We then generated mouse models with constitutive and inducible YY1 deficiency in β-cells. YY1 deficient mice developed diabetes early in life due to β-cell loss. β-cells from these mice exhibited higher DNA damage, cell cycle arrest and cell death as well as decreased maturation markers. Tamoxifen-induced YY1 deficiency in mature β-cells impaired β-cell function and induced DNA damage. In summary, we identified YY1 as a critical factor for β-cell DNA repair and cell-cycle progression.
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Uncoupling proteins (UCP) are able to increase H(+) leakage across the inner mitochondrial membrane, thus dissipating the membrane potential and increasing oxygen consumption. Despite the identification of several UCP orthologs in birds, reptiles, amphibians and fish, little is known about their functional properties in fish. The aim of this work was to identify and characterize a UCP in mitochondria found in goldfish white skeletal muscle. Western blot analysis, using a polyclonal antibody raised against mammalian UCP3, showed a single band at approximately 32 kDa. During non-phosphorylating respiration, we observed that palmitate promoted a dose-dependent increase in oxygen consumption that is abolished by addition of BSA (fatty acid chelator). Interestingly, this palmitate-induced increase in oxygen consumption was not inhibited by GDP, a well-known UCP inhibitor. In phosphorylating mitochondria, palmitate lowered both ADP/O ratio (number of atoms of phosphorus incorporated as ATP per molecule of O2 consumed) and the respiratory control ratio. Moreover, we found that different fatty acids can modulate mitochondrial membrane potential. In conclusion, our results suggest that goldfish UCP is functionally similar to the UCP found in other species, including mammals.
The thyroid hormones (THs), triiodothyronine (T3) and thyroxine (T4), are very important in organism metabolism and regulate glucose utilization. Hexokinase (HK) is responsible for the first step of glycolysis, catalyzing the conversion of glucose to glucose 6-phosphate. HK has been found in different cellular compartments, and new functions have been attributed to this enzyme. The effects of hyperthyroidism on subcellular glucose phosphorylation in mouse tissues were examined. Tissues were removed, subcellular fractions were isolated from eu- and hyperthyroid (T3, 0.25 µg/g, i.p. during 21 days) mice and HK activity was assayed. Glucose phosphorylation was increased in the particulate fraction in soleus (312.4% ± 67.1, n = 10), gastrocnemius (369.2% ± 112.4, n = 10) and heart (142.2% ± 13.6, n = 10) muscle in the hyperthyroid group compared to the control group. Hexokinase activity was not affected in brain or liver. No relevant changes were observed in HK activity in the soluble fraction for all tissues investigated. Acute T3 administration (single dose of T3, 1.25 µg/g, i.p.) did not modulate HK activity. Interestingly, HK mRNA levels remained unchanged and HK bound to mitochondria was increased by T3 treatment, suggesting a posttranscriptional mechanism. Analysis of the AKT pathway showed a 2.5-fold increase in AKT and GSK3B phosphorylation in the gastrocnemius muscle in the hyperthyroid group compared to the euthyroid group. Taken together, we show for the first time that THs modulate HK activity specifically in particulate fractions and that this action seems to be under the control of the AKT and GSK3B pathways.
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