Glycogen is an important component of whole-body glucose metabolism. MGSKO mice lack skeletal muscle glycogen due to disruption of the GYS1 gene, which encodes muscle glycogen synthase. MGSKO mice were 5-10% smaller than wild-type littermates with less body fat. They have more oxidative muscle fibers and, based on the activation state of AMP-activated protein kinase, more capacity to oxidize fatty acids. Blood glucose in fed and fasted MGSKO mice was comparable to wild-type littermates. Serum insulin was lower in fed but not in fasted MGSKO animals. In a glucose tolerance test, MGSKO mice disposed of glucose more effectively than wild-type animals and had a more sustained elevation of serum insulin. This result was not explained by increased conversion to serum lactate or by enhanced storage of glucose in the liver. However, glucose infusion rate in a euglycemic-hyperinsulinemic clamp was normal in MGSKO mice despite diminished muscle glucose uptake. During the clamp, MGSKO animals accumulated significantly higher levels of liver glycogen as compared with wild-type littermates. Although disruption of the GYS1 gene negatively affects muscle glucose uptake, overall glucose tolerance is actually improved, possibly because of a role for GYS1 in tissues other than muscle. Diabetes 54: 3466 -3473, 2005 A fter a meal, glucose is distributed into various tissues of the body where it can be utilized as an energy source or stored as glycogen (1). Glycogen is a branched polymer of glucose residues connected by ␣-1,4-glycosidic linkages formed by the enzyme glycogen synthase (EC 2.4.1.11) and branchpoints formed via ␣-1,6-glycosidic linkages, introduced by the branching enzyme (EC 2.4.1.18). There are two mammalian isoforms of glycogen synthase. One, encoded by the GYS2 gene, appears to be expressed only in liver (2) while a second gene, GYS1, is expressed in skeletal and cardiac muscle as well as adipose tissue, kidney, and brain (3).Estimates of the contribution of skeletal muscle glycogen to glucose disposal after ingestion of carbohydrate vary. In humans, reports of ingested glucose conversion to muscle glycogen range from ϳ40% (4) up to 90% (5). It is widely accepted that muscle is an important site for glucose disposal and one might hypothesize that, in the absence of muscle glycogen, glucose clearance would be impaired. Consistent with this hypothesis, mutations in the GYS1 gene in humans have been implicated in certain diabetic populations with, for example, the Pro442Ala mutation resulting in decreased muscle glycogen synthase activity (6).We recently described the MGSKO mouse, in which the GYS1 gene is disrupted (7). Analysis of MGSKO mice confirmed the long-held supposition that glycogen synthase is required for glycogen synthesis since these animals were devoid of glycogen in cardiac and skeletal muscle (7). In the present study, we analyzed a number of metabolic parameters in the MGSKO mouse, including whole-body glucose metabolism, with an initial hypothesis that mice lacking the ability to synthesize muscl...
FSH is a critical hormone regulator of gonadal function that is secreted from the pituitary gonadotrope cell. Human patients and animal models with mutations in the LHX3 LIM-homeodomain transcription factor gene exhibit complex endocrine diseases, including reproductive disorders with loss of FSH. We demonstrate that in both heterologous and pituitary gonadotrope cells, specific LHX3 isoforms activate the FSH beta-subunit promoter, but not the proximal LHbeta promoter. The related LHX4 mammalian transcription factor can also induce FSHbeta promoter transcription, but the homologous Drosophila protein LIM3 cannot. The actions of LHX3 are specifically blocked by a dominant negative LHX3 protein containing a Kruppel-associated box domain. Six LHX3-binding sites were characterized within the FSHbeta promoter, including three within a proximal region that also mediates gene regulation by other transcription factors and activin. Mutations of the proximal binding sites demonstrate their importance for LHX3 induction of the FSHbeta promoter and basal promoter activity in gonadotrope cells. Using quantitative methods, we show that the responses of the FSHbeta promoter to activin do not require induction of the LHX3 gene. By comparative genomics using the human FSHbeta promoter, we demonstrate structural and functional conservation of promoter induction by LHX3. We conclude that the LHX3 LIM homeodomain transcription factor is involved in activation of the FSH beta-subunit gene in the pituitary gonadotrope cell.
LIM homeodomain transcription factors regulate development in complex organisms. To characterize the molecular signals required for the nuclear localization of these proteins, we examined the Lhx3 factor. Lhx3 is essential for pituitary organogenesis and motor neuron specification. By using functional fluorescent derivatives, we demonstrate that Lhx3 is found in both the nucleoplasm and nuclear matrix. Three nuclear localization signals were mapped within the homeodomain, and one was located in the carboxyl terminus.
The mechanisms underlying the coupling of type I collagen and matrix metalloproteinase (MMP) expression to cell structure and adhesion are poorly understood. We propose that nuclear matrix architectural transcription factors link cell structure and transcription via their association with nuclear matrix subdomains and by their capacity for altering promoter geometry. NP/NMP4 are nuclear matrix proteins that contain from five to eight Cys(2)His(2) zinc fingers. Some NP/NMP4 isoforms bind to the rat type I collagen alpha1(I) polypeptide chain promoter in the manner of architectural transcription factors and alter basal transcription in osteoblast-like cells (Thunyakitpisal et al. in review). Certain isoforms of NP/NMP4 are identical to CIZ, Cas-interacting zinc finger protein, a nucleocytoplasmic shuttling protein that associates with focal adhesions and regulates MMP expression [Nakamoto et al. (2000): Mol Cell Biol 20:1649-1658]. To better understand the role of subnuclear architecture in collagen and MMP expression, we mapped the osteoblast nuclear distribution of NP/NMP4 proteins and identified the functional motifs necessary for nuclear localization and nuclear matrix targeting. Immunofluorescence microscopy was used to determine the cellular and subnuclear distribution of native NP/NMP4 proteins and green fluorescent protein (GFP)-NP/NMP4 fusion proteins in osteoblast-like cells. All GFP-NP/NMP4 fusion proteins localized to the nucleus, but accumulated in distinct nuclear matrix subdomains. The zinc finger domain was necessary and sufficient for nuclear import and matrix targeting. We conclude that the arrangement of the NP/NMP4 zinc fingers largely determines the subnuclear location of these isoforms.
A6 model renal epithelial cells were stably transfected with enhanced green fluorescent protein (EGFP)-tagged alpha- or beta-subunits of the epithelial Na(+) channel (ENaC). Transfected RNA and proteins were both expressed in low abundance, similar to the endogenous levels of ENaC in native cells. In living cells, laser scanning confocal microscopy revealed a predominantly subapical distribution of EGFP-labeled subunits, suggesting a readily accessible pool of subunits available to participate in Na(+) transport. The basal level of Na(+) transport in the clonal lines was enhanced two- to fourfold relative to the parent line. Natriferic responses to insulin or aldosterone were similar in magnitude to the parent line, while forskolin-stimulated Na(+) transport was 64% greater than control in both the alpha- and beta-transfected lines. In response to forskolin, EGFP-labeled channel subunits traffic to the apical membrane. These data suggest that channel regulators, not the channel per se, form the rate-limiting step in response to insulin or aldosterone stimulation, while the number of channel subunits is important for basal as well as cAMP-stimulated Na(+) transport.
Glycogen, a branched polymer of glucose, forms an energy re-serve in numerous organisms. In mammals, the two largest glyco-gen stores are in skeletal muscle and liver, which express tissue-specific glycogen synthase isoforms. MGSKO mice, in which mGys1 (mouse glycogen synthase) is disrupted, are devoid of muscle glycogen [Pederson, Chen, Schroeder, Shou, DePaoli-Roach and Roach (2004) Mol. Cell. Biol. 24, 7179-7187]. The GSL30 mouse line hyper-accumulates glycogen in muscle [Manchester, Skurat, Roach, Hauschka and Lawrence (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 10707-10711]. We performed a microarray analysis of mRNA from the anterior tibialis, medial gastrocnemius and liver of MGSKO mice, and from the gastroc-nemius of GSL30 mice. In MGSKO mice, transcripts of 79 genes varied in their expression in the same direction in both the anterior tibialis and gastrocnemius. These included several genes encoding proteins proximally involved in glycogen metabolism. The Ppp1r1a [protein phosphatase 1 regulatory (inhibitor) sub-unit 1A] gene underwent the greatest amount of downregulation. In muscle, the downregulation of Pfkfb1 and Pfkfb3, encoding isoforms of 6-phosphofructo-2-kinase/fructose-2,6-bisphospha-tase, is consistent with decreased glycolysis. Pathways for branched-chain amino acid, and ketone body utilization appear to be downregulated, as is the capacity to form the gluconeogenic precursors alanine, lactate and glutamine. Expression changes among several members of the Wnt signalling pathway were identified, suggesting an as yet unexplained role in glycogen meta-bolism. In liver, the upregulation of Pfkfb1 and Pfkfb3 expression is consistent with increased glycolysis, perhaps as an adaptation to altered muscle metabolism. By comparing changes in muscle expression between MGSKO and GSL30 mice, we found a subset of 44 genes, the expression of which varied as a function of muscle glycogen content. These genes are candidates for regulation by glycogen levels. Particularly interesting is the observation that 11 of these genes encode cardiac or slow-twitch isoforms of muscle contractile proteins, and are upregulated in muscle that has a greater oxidative capacity in MGSKO mice.
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