Hypoxia regulates VEGF expression and cellular proliferation by osteoblasts in vitro.

Numerous studies have demonstrated the critical role of angiogenesis for successful osteogenesis during endochondral ossification and fracture repair. Vascular endothelial growth factor (VEGF), a potent endothelial cell-specific cytokine, has been shown to be mitogenic and chemotactic for endothelial cells in vitro and angiogenic in many in vivo models. Based on previous work that (1) VEGF is up-regulated during membranous fracture healing, (2) the fracture site contains a hypoxic gradient, (3) VEGF is up-regulated in a variety of cells in response to hypoxia, and (4) VEGF is expressed by isolated osteoblasts in vitro stimulated by other fracture cytokines, the hypothesis that hypoxia may regulate the expression of VEGF by osteoblasts was formulated. This hypothesis was tested in a series of in vitro studies in which VEGF mRNA and protein expression was assessed after exposure of osteoblast-like cells to hypoxic stimuli. In addition, the effects of a hypoxic microenvironment on osteoblast proliferation and differentiation in vitro was analyzed. These results demonstrate that hypoxia does, indeed, regulate expression of VEGF in osteoblast-like cells in a dose-dependent fashion. In addition, it is demonstrated that hypoxia results in decreased cellular proliferation, decreased expression of proliferating cell nuclear antigen, and increased alkaline phosphatase (a marker of osteoblast differentiation). Taken together, these data suggest that osteoblasts, through the expression of VEGF, may be in part responsible for angiogenesis and the resultant increased blood flow to fractured bone segments. In addition, these data provide evidence that osteoblasts have oxygen-sensing mechanisms and that decreased oxygen tension can regulate gene expression, cellular proliferation, and cellular differentiation.     

TNF regulates cellular NAD+ metabolism in primary macrophages

The inflammatory cytokine TNF is known to affect glucose and lipid metabolism, where its action leads to a cachexic state. Despite a well-established connection of TNF to metabolism, the relationship between TNF and NAD(+) metabolism remains unclear. In this report, we evaluated the effects of TNF on NAD(+) metabolism in cells that are TNF's primary autocrine target-macrophages. We designed real-time PCR primers to all NAD(+) metabolic enzymes, which we used to examine TNF-induced changes over time. We found that TNF paradoxically up-regulated enzymes that served to increase NAD(+) levels, such as IDO and PBEF, as well as enzymes that decrease NAD(+) levels, such as CD38 and CD157. The significance of these mRNA changes was evaluated by examining TNF-mediated changes in cellular NAD(+) levels. Treatment of macrophages with TNF decreased NAD(+) levels over time, suggesting that increases in NAD(+)-degrading enzymes were dominant. To evaluate whether this was the case, we measured TNF-mediated changes in NAD(+) levels in animals where CD38 was genetically deleted. In CD38-/- macrophages, the effects of TNF were reversed, with TNF increasing NAD(+) levels over time. The significance of our findings is threefold: (1) we establish that TNF affects NAD(+) metabolism by regulating the expression of major NAD(+) metabolic enzymes, (2) TNF-induced decreases in cellular NAD(+) levels were carried out through the up-regulation of extracellularly situated enzymes, and (3) we provide a mechanism for the observed clinical connection of TNF-dependent diseases to tissue reductions in NAD(+) content.     

Hypoxia regulates glutamate metabolism and membrane transport in rat PC12 cells

We investigated the effect of hypoxia on glutamate metabolism and uptake in rat pheochromocytoma (PC12) cells. Various key enzymes relevant to glutamate production, metabolism and transport were coordinately regulated by hypoxia. PC12 cells express two glutamate-metabolizing enzymes, glutamine synthetase (GS) and glutamate decarboxylase (GAD), as well as the glutamate-producing enzyme, phosphate-activated glutaminase (PAG). Exposure to hypoxia (1% O(2)) for 6 h or longer increased expression of GS mRNA and protein and enhanced GS enzymatic activity. In contrast, hypoxia caused a significant decrease in expression of PAG mRNA and protein, and also decreased PAG activity. In addition, hypoxia led to an increase in GAD65 and GAD67 protein levels and GAD enzymatic activity. PC12 cells express three Na(+)-dependent glutamate transporters; EAAC1, GLT-1 and GLAST. Hypoxia increased EAAC1 and GLT-1 protein levels, but had no effect on GLAST. Chronic hypoxia significantly enhanced the Na(+)-dependent component of glutamate transport. Furthermore, chronic hypoxia decreased cellular content of glutamate, but increased that of glutamine. Taken together, the hypoxia-induced changes in enzymes related to glutamate metabolism and transport are consistent with a decrease in the extracellular concentration of glutamate. This may have a role in protecting PC12 cells from the cytotoxic effects of glutamate during chronic hypoxia.     

ORP2, a homolog of oxysterol binding protein, regulates cellular cholesterol metabolism

Oxysterol binding protein (OSBP) related proteins (ORPs) constitute a family that has at least 12 members in humans. In the present study we characterize one of the novel OSBP homologs, ORP2, which we show to be expressed ubiquitously in mammalian tissues. The ORP2 cDNA encodes a deduced 55 kDa protein that lacks a pleckstrin homology (PH) domain, a feature found in the other family members. Sucrose gradient centrifugation analysis of Chinese hamster ovary (CHO) cell post-nuclear supernatant demonstrated that ORP2 is distributed in soluble and membrane-bound fractions. Immunofluorescence microscopy of the endogenous and overexpressed ORP2 in CHO cells suggested that the membrane-bound fraction of the protein localizes to the Golgi apparatus. Stably transfected CHO cells that overexpress ORP2 showed an increase in [14C]cholesterol efflux to serum, apolipoprotein A-I (apoA-I), and phosphatidyl choline vesicles. The proportion of cellular [14C]cholesterol that is esterified and the ACAT activity measured as [14C]oleyl-CoA conversion into cholesteryl [14C]oleate by the cellular membranes, were markedly decreased in the ORP2 expressing cells. Transient high level overexpression of ORP2 interfered with the clearance of a secretory pathway protein marker from the Golgi complex. The results implicate ORP2 as a novel regulator of cellular sterol homeostasis and intracellular membrane trafficking.     

Modulation of cellular metabolism by protein crotonylation regulates pancreatic cancer progression

1. Download : Download high-res image (199KB)
2. Download : Download full-size image

     

Temporal and fluoride control of secondary metabolism regulates cellular organofluorine biosynthesis

Elucidating mechanisms of natural organofluorine biosynthesis is essential for a basic understanding of fluorine biochemistry in living systems as well as for expanding biological methods for fluorine incorporation into small molecules of interest. To meet this goal we have combined massively parallel sequencing technologies, genetic knockout, and in vitro biochemical approaches to investigate the fluoride response of the only known genetic host of an organofluorine-producing pathway, Streptomyces cattleya. Interestingly, we have discovered that the major mode of S. cattleya's resistance to the fluorinated toxin it produces, fluoroacetate, may be due to temporal control of production rather than the ability of the host's metabolic machinery to discriminate between fluorinated and non-fluorinated molecules. Indeed, neither the acetate kinase/phosphotransacetylase acetate assimilation pathway nor the TCA cycle enzymes (citrate synthase and aconitase) exclude fluorinated substrates based on in vitro biochemical characterization. Furthermore, disruption of the fluoroacetate resistance gene encoding a fluoroacetyl-CoA thioesterase (FlK) does not appear to lead to an observable growth defect related to organofluorine production. By showing that a switch in central metabolism can mediate and control molecular fluorine incorporation, our findings reveal a new potential strategy toward diversifying simple fluorinated building blocks into more complex products.     

Hypoxia regulates macrophage functions in inflammation

The presence of areas of hypoxia is a prominent feature of various inflamed, diseased tissues, including malignant tumors, atherosclerotic plaques, myocardial infarcts, the synovia of joints with rheumatoid arthritis, healing wounds, and sites of bacterial infection. These areas form when the blood supply is occluded and/or unable to keep pace with the growth and/or infiltration of inflammatory cells in a given area. Macrophages are present in all tissues of the body where they normally assist in guarding against invading pathogens and regulate normal cell turnover and tissue remodeling. However, they are also known to accumulate in large numbers in such ischemic/hypoxic sites. Recent studies show that macrophages then respond rapidly to the hypoxia present by altering their expression of a wide array of genes. In the present study, we outline and compare the phenotypic responses of macrophages to hypoxia in different diseased states and the implications of these for their progression and treatment.     

The protein phosphatases involved in cellular regulation. 2. Glycogen metabolism

The nature of protein phosphatases that are active against the phosphorylated proteins of glycogen metabolism was investigated in rabbit skeletal muscle and liver. Six 32P-labelled substrates corresponding to the major phosphorylation sites on glycogen phosphorylase, phosphorylase kinase, glycogen synthase and inhibitor-1 were used in these studies. The results showed that the four protein phosphatases defined in the preceding paper, namely protein phosphatases-1, 2A, 2B and 2C [Ingebritsen, T. S. and Cohen, P. (1983) Eur. J. Biochem. 132, 255-261] were the only significant enzymes acting on these substrates. The four enzymes can be conveniently separated and identified by a combination of ion-exchange chromatography and gel filtration and by the use of specific inhibitors. Three species of protein phosphatase-2A were resolved on DEAE-cellulose, termed protein phosphatases-2Ao (0.12 M NaCl), 2A1 (0.2 M NaCl) and 2A2 (0.28 M NaCl) that had apparent molecular weights of 210000, 210000 and 150000 respectively. Protein phosphatase-2Ao was a completely inactive enzyme whose activity was only expressed after dissociation to a 34000-Mr(app) catalytic subunit by freezing and thawing in 0.2 M 2-mercaptoethanol. This treatment also dissociated protein phosphatases 2A1 and 2A2 to more active 34000-Mr(app) catalytic subunits. The catalytic subunits derived from protein phosphatases-2Ao, 2A1 and 2A2 possessed identical substrate specificities, preferentially dephosphorylated the alpha-subunit of phosphorylase kinase, were unaffected by inhibitor-1 and inhibitor-2 and were inhibited by similar concentrations of ATP. The properties of protein phosphatases-2A1 and 2A2 were very similar to those of the catalytic subunits, except that they were less sensitive to inhibition by ATP. Protein phosphatase-2B was eluted from DEAE-cellulose in the same fraction as protein phosphatase-2Ao. These activities were resolved by gel filtration, the Mr(app) of protein phosphatase-2B being 98000. Protein phosphatase-2B was completely inhibited by 100 microM trifluoperazine, which did not affect the activity of protein phosphatase-2Ao or any other protein phosphatase. Freezing and thawing in 0.2 M 2-mercaptoethanol resulted in partial inactivation of protein phosphatase-2B. Protein phosphatase-2C was eluted from DEAE-cellulose at the leading edge of the peak of protein phosphatase-2A1. These activities were completely resolved by gel filtration, since the Mr(app) of protein phosphatase-2C was 46000. Two forms of protein phosphatase-1 can be identified by chromatography on DEAE-cellulose, namely protein phosphatase-1 itself and the Mg X ATP-dependent protein phosphatase. Both these species were eluted at 0.16 M NaCl just ahead of protein phosphatases-2C and 2A1. These enzymes did not interfere with measurements of type-2 protein phosphatases, since it was possible to block their activity with inhibitor-2...     

Hypoxia differentially regulates muscle oxidative fiber type and metabolism in a HIF-1α-dependent manner

Loss of skeletal muscle oxidative fiber types and mitochondrial capacity is a hallmark of chronic obstructive pulmonary disease and chronic heart failure. Based on in vivo human and animal studies, tissue hypoxia has been hypothesized as determinant, but the direct effect of hypoxia on muscle oxidative phenotype remains to be established. Hence, we determined the effect of hypoxia on in vitro cultured muscle cells, including gene and protein expression levels of mitochondrial components, myosin isoforms (reflecting slow-oxidative versus fast-glycolytic fibers), and the involvement of the regulatory PPAR/PGC-1α pathway. We found that hypoxia inhibits the PPAR/PGC-1α pathway and the expression of mitochondrial components through HIF-1α. However, in contrast to our hypothesis, hypoxia stimulated the expression of slow-oxidative type I myosin via HIF-1α. Collectively, this study shows that hypoxia differentially regulates contractile and metabolic components of muscle oxidative phenotype in a HIF-1α-dependent manner.     

Hypoxia and cancer cell metabolism

The past decade has witnessed a rapid accumulation of evi- dence showing that hypoxic microenvironment, which is typical during cancer development, plays key roles in regu- lating cancer cell metabolism. In this review, we will focus on the role of hypoxic response, particularly, its master regulator hypoxia-inducible factor-I, in regulating glucose, lipid, as well as amino acid metabolism in cancer cells. We will also discuss the therapeutic opportunities by targeting specific pathways that facilitate metabolic reprogramming in cancer cells.     

Hypoxia and mitochondrial oxidative metabolism

It is now clear that mitochondrial defects are associated with a large variety of clinical phenotypes. This is the result of the mitochondria's central role in energy production, reactive oxygen species homeostasis, and cell death. These processes are interdependent and may occur under various stressing conditions, among which low oxygen levels (hypoxia) are certainly prominent. Cells exposed to hypoxia respond acutely with endogenous metabolites and proteins promptly regulating metabolic pathways, but if low oxygen levels are prolonged, cells activate adapting mechanisms, the master switch being the hypoxia-inducible factor 1 (HIF-1). Activation of this factor is strictly bound to the mitochondrial function, which in turn is related with the oxygen level. Therefore in hypoxia, mitochondria act as [O₂] sensors, convey signals to HIF-1directly or indirectly, and contribute to the cell redox potential, ion homeostasis, and energy production. Although over the last two decades cellular responses to low oxygen tension have been studied extensively, mechanisms underlying these functions are still indefinite. Here we review current knowledge of the mitochondrial role in hypoxia, focusing mainly on their role in cellular energy and reactive oxygen species homeostasis in relation with HIF-1 stabilization. In addition, we address the involvement of HIF-1 and the inhibitor protein of F₁F₀ ATPase in the hypoxia-induced mitochondrial autophagy.     

Akt2 regulates cardiac metabolism and cardiomyocyte survival

The Akt family of serine-threonine kinases participates in diverse cellular processes, including the promotion of cell survival, glucose metabolism, and cellular protein synthesis. All three known Akt family members, Akt1, Akt2 and Akt3, are expressed in the myocardium, although Akt1 and Akt2 are most abundant. Previous studies demonstrated that Akt1 and Akt3 overexpression results in enhanced myocardial size and function. Yet, little is known about the role of Akt2 in modulating cardiac metabolism, survival, and growth. Here, we utilize murine models with targeted disruption of the akt2 or the akt1 genes to demonstrate that Akt2, but not Akt1, is required for insulin-stimulated 2-[(3)H]deoxyglucose uptake and metabolism. In contrast, akt2(-/-) mice displayed normal cardiac growth responses to provocative stimulation, including ligand stimulation of cultured cardiomyocytes, pressure overload by transverse aortic constriction, and myocardial infarction. However, akt2(-/-) mice were found to be sensitized to cardiomyocyte apoptosis in response to ischemic injury, and apoptosis was significantly increased in the peri-infarct zone of akt2(-/-) hearts 7 days after occlusion of the left coronary artery. These results implicate Akt2 in the regulation of cardiomyocyte metabolism and survival.     

CLE2 regulates light-dependent carbohydrate metabolism in Arabidopsis shoots

Plant Molecular Biology - This study focused on the role of CLE1-CLE7 peptides as environmental mediators and indicated that root-induced CLE2 functions systemically in light-dependent carbohydrate...