The gill microbiota of invasive and indigenous Spondylus oysters from the Mediterranean Sea and northern Red Sea.

The gill tissue of bivalve mollusks hosts rich symbiotic microbial communities that may contribute to the animal's metabolism. Spondylus spinosus is an invasive oyster that has become highly abundant along the eastern Mediterranean Sea (EMS) coastline, but is scarce in the northern Red Sea (NRS), its indigenous region. The composition and seasonal dynamics of the gill microbial communities of S. spinosus were examined in both regions, using 16S rRNA gene amplicon sequencing. Additionally, two Red Sea Spondylus species, S. avramsingeri and S. pickeringae, were investigated using the same approach. Significant differences were found between microbial communities of the EMS S. spinosus and the three NRS species. Bacteria from the family Hahellaceae dominated the communities of the EMS S. spinosus and the NRS S. avramsingeri, oysters that are dominant in their habitat, yet were rare in the NRS S. spinosus and S. pickeringae, which are only seldom encountered. Bacterial communities of EMS S. spinosus were more similar to those of NRS S. spinosus than to those of other NRS Spondylus species, indicating that either part of the microbiota had co-invaded with their host into the Mediterranean Sea, or that there are species-specific selective constraints on microbial composition.

Phosphoenolpyruvate carboxykinase (Pck1) helps regulate the triglyceride/fatty acid cycle and development of insulin resistance in mice.

The aim of this study was to investigate the role of the cytosolic form of phosphoenolpyruvate carboxykinase (Pck1) in the development of insulin resistance. Previous studies have shown that the roles of Pck1 in white adipose tissue (WAT) in glyceroneogenesis and reesterification of free fatty acids (FFA) to generate triglyceride are vital for the prevention of diabetes. We hypothesized that insulin resistance develops when dysregulation of Pck1 occurs in the triglyceride/fatty acid cycle, which regulates lipid synthesis and transport between adipose tissue and the liver. We examined this by analyzing mice with a deletion of the PPARgamma binding site in the promoter of Pck1 (PPARE(-/-)). This mutation reduced the fasting Pck1 mRNA expression in WAT in brown adipose tissue (BAT). To analyze insulin resistance, we performed hyperinsulinemic-euglycemic glucose clamp analyses. PPARE(-/-) mice were profoundly insulin resistant and had more FFA and glycerol released during the hyperinsulinemic-euglycemic clamp compared with wild-type mice (WT). Finally, we analyzed insulin secretion in isolated islets. We found a 2-fold increase in insulin secretion in the PPARE(-/-) mice at 16.7 mM glucose. Thus, the PPARE site in the Pck1 promoter is essential for maintenance of lipid metabolism and glucose homeostasis and disease prevention.

Glyceroneogenesis, the pathway that almost wasn't.

"What seest thou else in the dark, backward abysm of time." Prospero in The Tempest As is true in all aspects of human endeavor, a scientific concept can appear before its time and remain unappreciated before events catch up with the concept. Such was the case of the discovery of glyceroneogenesis and the establishment of its biological importance; it took almost 40 years before the significance of this pathway became apparent and the concept of triglyceride recycling was understood by the scientific establishment. Even that may be stretching a point, because today glyceroneogenesis is hardly a household word. In this essay, we will tell the story of the discovery of glyceroneogenesis and the thought processes that led us to propose this pathway. We will also speculate on why the pathway was not more widely embraced by scientists working in lipid metabolism and why that may finally be changing. The reader is warned, however, that this story is a reconstruction of past events and, like all such attempts, suffers from the patina of nostalgia that inevitably covers all things resurrected from memory. Others may view things differently, but this is our story as we remember it.

Phosphoenolpyruvate carboxykinase and the critical role of cataplerosis in the control of hepatic metabolism.

BACKGROUND: The metabolic function of PEPCK-C is not fully understood; deletion of the gene for the enzyme in mice provides an opportunity to fully assess its function. METHODS: The gene for the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) (EC 4.1.1.32) (PEPCK-C) was deleted in mice by homologous recombination (PEPCK-C-/- mice) and the metabolic consequences assessed. RESULTS: PEPCK-C-/- mice became severely hypoglycemic by day two after birth and then died with profound hypoglycemia (12 mg/dl). The mice had milk in their stomachs at day two after birth and the administration of glucose raised the concentration of blood glucose in the mice but did not result in an increased survival. PEPCK-C-/- mice have two to three times the hepatic triglyceride content as control littermates on the second day after birth. These mice also had an elevation of lactate (2.5 times), beta-hydroxybutyrate (3 times) and triglyceride (50%) in their blood, as compared to control animals. On day two after birth, alanine, glycine, glutamine, glutamate, aspartate and asparagine were elevated in the blood of the PEPCK-C-/- mice and the blood urea nitrogen concentration was increased by 2-fold. The rate of oxidation of [2-14C]-acetate, and [5-14C]-glutamate to 14CO2 by liver slices from PEPCK-C-/- mice at two days of age was greatly reduced, as was the rate of fatty acid synthesis from acetate and glucose. As predicted by the lack of PEPCK-C, the concentration of malate in the livers of the PEPCK-C-/- mice was 10 times that of controls. CONCLUSION: We conclude that PEPCK-C is required not only for gluconeogenesis and glyceroneogenesis but also for cataplerosis (i.e. the removal of citric acid cycle anions) and that the failure of this process in the livers of PEPCK-C-/- mice results in a marked reduction in citric acid cycle flux and the shunting of hepatic lipid into triglyceride, resulting in a fatty liver.

Glucocorticoids regulate transcription of the gene for phosphoenolpyruvate carboxykinase in the liver via an extended glucocorticoid regulatory unit.

The hepatic transcriptional regulation by glucocorticoids of the cytosolic form of phosphoenolpyruvate carboxykinase (PEPCK-C) gene is coordinated by interactions of specific transcription factors at the glucocorticoid regulatory unit (GRU). We propose an extended GRU that consists of four accessory sites, two proximal AF1 and AF2 sites and their distal counterpart dAF1 (-993) and a new site, dAF2 (-1365); together, these four sites form a palindrome. Sequencing and gel shift binding assays of hepatic nuclear proteins interacting with these sites indicated similarity of dAF1 and dAF2 sites to the GRU proximal AF1 and AF2 sites. Chromatin immunoprecipitation assays demonstrated that glucocorticoids enhanced the binding of FOXO1 and peroxisome proliferator-activated receptor-alpha to AF2 and dAF2 sites and not to dAF1 site but enhanced the binding of hepatic nuclear transcription factor-4alpha only to the dAF1 site. Insulin inhibited the binding of these factors to their respective sites but intensified the binding of phosphorylated FOXO1. Transient transfections in HepG2 human hepatoma cells showed that glucocorticoid receptor interacts with several non-steroid nuclear receptors, yielding a synergistic response of the PEPCK-C gene promoter to glucocorticoids. The synergistic stimulation by glucocorticoid receptor together with peroxisome proliferator-activated receptor-alpha or hepatic nuclear transcription factor-4alpha requires all four accessory sites, i.e. a mutation of each of these markedly affects the synergistic response. Mice with a targeted mutation of the dAF1 site confirmed this requirement. This mutation inhibited the full response of hepatic PEPCK-C gene to diabetes by reducing PEPCK-C mRNA level by 3.5-fold and the level of circulating glucose by 25%.

Factors that control the tissue-specific transcription of the gene for phosphoenolpyruvate carboxykinase-C.

Transcription of the gene for PEPCK-C occurs in a number of mammalian tissues, with highest expression occurring in the liver, kidney cortex, and white and brown adipose tissue. Several hormones and other factors, including glucagon, epinephrine, insulin, glucocorticoids and metabolic acidosis, control this process in three responsive tissues, liver, adipose tissue, and kidney cortex. Expression of the gene in these three tissues in regulated in a different manner, responding to the specific physiological role of the tissue. The PEPCK-C gene promoter has been extensively studied and a number of regulatory regions identified that bind key transcription factors and render the gene responsive to hormonal and dietary stimuli. This review will focus on the control of transcription for the gene, with special emphasis on our current understanding of the transcription factors that are involved in the response of PEPCK-C gene in specific tissues. We have also reviewed the biological function of PEPCK-C in each of the tissues discussed in this review, in order to place the control of PEPCK-C gene transcription in the appropriate physiological context. Because of its extraordinary importance in mammalian metabolism and its broad pattern of tissue-specific expression, the PEPCK-C gene has become a model for studying the biological basis of the control of gene transcription.

The transcriptional regulation of phosphoenolpyruvate carboxykinase gene in the kidney requires the HNF-1 binding site of the gene.

The transcription of the cytosolic form of phosphoenolpyruvate carboxykinase (PEPCK-C) gene is differentially regulated in each of the several PEPCK-C-expressing tissues. In the kidney, it is regulated by glucocorticoids and acidosis. Previously, we reported that in LLC-PK1 and derived kidney cell lines, mutation of the hepatic nuclear factor 1 (HNF-1) binding site in PEPCK-C gene promoter markedly reduced both the basal activity of the gene promoter and its response to acidic pH. Using the same kidney cell line, we now report that nuclear receptors robustly stimulate transcription from the PEPCK-C gene promoter. This stimulation is markedly reduced by mutation of the accessory factor 1 (AF1) site in the glucocorticoid responsive unit (GRU) residing within the glucocorticoid-responsive domain. The stimulation is likewise reduced by mutation of the HNF-1 site, residing outside the nuclear receptor-responsive domain of the PEPCK-C gene promoter. There is no binding similarity between HNF-1 and AF1 binding sites, as is evident from gel shift assays showing a lack of competition of either site for the binding of renal nuclear proteins to the other. We further assessed that the regulation of PEPCK-C gene transcription by acidosis is not mediated by nuclear receptors. This became evident from studies of transgenic mice harboring a rat PEPCK-C transgene driven by truncated 5' flanking region of the gene, which contains the HNF-1 site but lacks the glucocorticoid responsive domain. The full transcriptional response of this transgene to acidosis establishes that the truncated 5' flanking region (362 bp) of the PEPCK-C gene contains the information required for the acidosis-mediated regulation independent of the glucocorticoid domain. Taking together the previous and present results, it appears that acidosis and nuclear receptors regulate the renal transcription of the PEPCK-C gene via two independent domains in the 5' flanking region of the gene. These two modulations, as well as the basal activity of the gene, require intact HNF-1 binding site in the gene promoter.

Glucocorticoids repress transcription of phosphoenolpyruvate carboxykinase (GTP) gene in adipocytes by inhibiting its C/EBP-mediated activation.

The cytosolic form of the phosphoenolpyruvate carboxykinase (PEPCK-C) gene is selectively expressed in several tissues, primarily in the liver, kidney, and adipose tissue. The transcription of the gene is reciprocally regulated by glucocorticoids in these tissues. It is induced in the liver and kidney but repressed in the white adipose tissue. To elucidate which adipocyte-specific transcription factors participate in the repression of the gene, DNase I footprinting analyses of nuclear proteins from 3T3-F442A adipocytes and transient transfection experiments in NIH3T3 cells were utilized. Glucocorticoid treatment slightly reduced the nuclear C/EBP alpha concentration but prominently diminished the binding of adipocyte-derived nuclear proteins to CCAAT/enhancer-binding protein (C/EBP) recognition sites, without affecting the binding to nuclear receptor sites in the PEPCK-C gene promoter. Of members of the C/EBP family of transcription factors, C/EBP alpha was the strongest trans-activator of the PEPCK-C gene promoter in the NIH3T3 cell line. The glucocorticoid receptor (GR), in the presence of its hormone ligand, inhibited the activation of the PEPCK-C gene promoter by C/EBP alpha or C/EBP beta but not by the adipocyte-specific peroxisome proliferator-activated receptor gamma 2. This inhibition effect was similar using the wild type or mutant GR and did not depend on GR binding to the DNA. The glucocorticoid response unit (GRU) in the PEPCK-C gene promoter (-2000 to +73) restrained C/EBP alpha-mediated trans-activation, because mutation of each single GRU element increased this activation by 3-4-fold. This series of GRU mutations were repressed by wild type GR to the same percent as was the nonmutated PEPCK-C gene promoter. In contrast, the repression by mutant GR depended on the intact AF1 site in the gene promoter, whereby mutation of the AF1 element abolished the repression.

Glyceroneogenesis revisited.

Glyceroneogenesis is the synthesis of 3-glycerol phosphate by an abbreviated version of gluconeogenesis. The research that led to the discovery of glyceroneogenesis in white adipose tissue is presented. This pathway is active during fasting in white and brown adipose tissue and in the liver as part of the triglyceride/fatty acid cycle. Glyceroneogenesis is critical for the extensive recycling of free fatty acid (FFA) back to triglyceride that occurs in mammals, including humans, after lipolysis, when up to 65% of the fatty acids are re-esterified back to triglyceride. The rate-limiting enzyme in this pathway is the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) (4.1.1.32) (PEPCK-C). Transcription of this gene is induced in adipose tissue and liver during fasting. Ablation of expression of the gene for PEPCK-C in white adipose tissue of mice results in lipodsytrophy, while overexpression of the gene for this enzyme in adipose tissue causes obesity. The critical role of glyceroneogenesis in diabetes was suggested by experiments in which the gene for PEPCK-C is induced in white adipose tissue by rosiglitazone, a drug used to control diabetes in humans. This was accompanied by a marked decrease in FFA release from adipose tissue due to an induction in glyceroneogenesis in the tissue. Since the chronic release of FFA by adipose tissue is a critical factor in the development Type 2 diabetes, it is likely that rosiglitazone acts in part by stimulating transcription of the gene for PEPCK-C, thereby increasing rate of glyceroneogenesis and lowering the rate of FFA release from adipose tissue.

A mutation in the peroxisome proliferator-activated receptor gamma-binding site in the gene for the cytosolic form of phosphoenolpyruvate carboxykinase reduces adipose tissue size and fat content in mice.

Regulation of the turnover of triglycerides in adipose tissue requires the continuous provision of 3-glycerophosphate, which may be supplied by the metabolism of glucose or by glyceroneogenesis, the de novo synthesis of 3-glycerophosphate from sources other than hexoses or glycerol. The importance of glyceroneogenesis in adipose tissue was assessed in mice by specifically eliminating the expression of the cytosolic form of phosphoenolpyruvate carboxykinase (PEPCK-C), an enzyme that plays a pivotal role in the pathway. To accomplish this, we mutated the binding site for the peroxisome proliferator-activated receptor gamma (PPAR gamma) called the peroxisome proliferator-activated receptor element (PPARE), in the 5' flanking region of the PEPCK-C gene in the mouse by homologous recombination. The mutation abolished expression of the gene in white adipose tissue and considerably reduced its expression in brown adipose tissue, whereas the level of PEPCK-C mRNA in liver and kidney remained normal. Epididymal white adipose tissue from these mice had a reduced triglyceride deposition, with 25% of the animals displaying lipodystrophy. There was also a greatly reduced level of lipid accumulation in brown adipose tissue. A strong correlation between the hepatic content of triglycerides and the size of the epididymal fat pad in PPARE(-/-) mice suggests that hepatic triglyceride synthesis predominantly utilizes free fatty acids derived from the adipose tissue. Unlike other models, PPARE(-/-) mice with lipodystrophy did not exhibit the lipodystrophy-associated features of diabetes and displayed only moderate hyperglycemia. These studies establish the importance of the PPARE site for PEPCK-C gene expression in adipose tissue and the role of PEPCK-C in the regulation of glyceroneogenesis, a pathway critical for maintaining the deposition of triglycerides in adipose tissue.