Streptolysin S induces pronounced calcium-ion influx-dependent expression of immediate early genes encoding transcription factors.

Anginosus group streptococci (AGS) are opportunistic human pathogens of the oral cavity. The ß-hemolytic subgroup of Streptococcus anginosus subsp. anginosus secretes streptolysin S (SLS) and exhibits not only hemolytic activity but also cytotoxicity toward cultured human cell lines. However, the detailed mechanism of action of SLS and the cellular responses of host cells have not yet been fully clarified. To determine the pathogenic potential of SLS-producing ß-hemolytic S. anginosus subsp. anginosus, the SLS-dependent response induced in the human oral squamous cell carcinoma HSC-2 cells was investigated to determine the pathogenic potential of SLS-producing ß-hemolytic S. anginosus subsp. anginosus. This study revealed that the Ca2+ influx and the expression of immediate early genes (IEGs) encoding transcription factors such as early growth responses (EGRs) and activator protein-1 (AP-1) were greatly increased in HSC-2 cells incubated with the culture supernatant of SLS-producing ß-hemolytic S. anginosus subsp. anginosus. Moreover, this SLS-dependent increase in expression was significantly suppressed by Ca2+ chelation, except for jun. These results suggest that SLS caused Ca2+ influx into the cells following greatly enhanced expression of IEG-encoding transcription factors. The results of this study may help in understanding the pathogenicity of SLS-producing AGS.

Supercompetitor status of Drosophila Myc cells requires p53 as a fitness sensor to reprogram metabolism and promote viability.

In growing tissues, cell fitness disparities can provoke interactions that promote stronger cells at the expense of the weaker in a process called cell competition. The mechanistic definition of cell fitness is not understood, nor is it understood how fitness differences are recognized. Drosophila cells with extra Myc activity acquire "supercompetitor" status upon confrontation with wild-type (WT) cells, prompting the latter's elimination via apoptosis. Here we show that such confrontation enhances glycolytic flux in Myc cells and promotes their fitness and proliferation in a p53-dependent manner. Whereas p53 loss in noncompeting Myc cells is inconsequential, its loss impairs metabolism, reduces viability, and prevents the killing activity of Myc supercompetitor cells. We propose that p53 acts as a general sensor of competitive confrontation to enhance the fitness of the "winner" population. Our findings suggest that the initial confrontation between precancerous and WT cells could enhance cancer cell fitness and promote tumor progression.

HIF-1α induction suppresses excessive lipid accumulation in alcoholic fatty liver in mice.

BACKGROUND & AIMS: Chronic alcohol intake stimulates hepatic oxygen consumption and subsequently causes liver hypoxia, leading to activation of hypoxia inducible factor-1 (HIF-1). Although HIF-1 plays a crucial role in the metabolic switch from aerobic to anaerobic metabolism in response to hypoxia, its roles in the regulation of lipid metabolism in alcoholic fatty liver remain unknown. METHODS: Wild-type and hepatocyte-specific HIF-1α-null mice were subjected to a 6% ethanol-containing liquid diet for 4 weeks, and functional effects of loss of the HIF-1α gene on lipid metabolism were examined in the liver. RESULTS: Hepatocyte-specific HIF-1α-null mice developed severe hypertriglyceridemia with enhanced accumulation of lipids in the liver of mice exposed to a 6% ethanol-containing liquid diet for 4 weeks. Sterol regulatory element-binding protein 1c (SREBP-1c) and its downstream target acetyl-CoA carboxylase were greatly activated as the hepatic steatosis progressed, and these alterations were inversely correlated with the expression of the HIF-1-regulated gene DEC1. Overexpression of DEC1 in the mutant liver abrogated the detrimental effects of loss of HIF-1α gene on ethanol-induced fatty liver with reduced SREBP-1c expression. Conversely, co-administration of the HIF hydroxylase inhibitor dimethyloxalylglycine for the last 2 weeks improved markedly the ethanol-induced fatty liver in mice. CONCLUSIONS: The current results provide direct evidence for protective roles of HIF-1 induction in the development of ethanol-induced fatty liver via activation of the HIF-1-regulated transcriptional repressor DEC1.

Disruption of HIF-1α in hepatocytes impairs glucose metabolism in diet-induced obesity mice.

The liver plays a central role in glucose homeostasis in the whole-body by responding to environmental factors including nutrients, hormones, and oxygen. In conditions of metabolic overload such as diabetes mellitus and obesity, coordinated regulation between oxygen supply and consumption has been reported to be disrupted and subsequently cause tissue hypoxia, although pathological significance of the disease-related hypoxia remains elusive. To investigate the role of tissue hypoxia in the liver on systemic glucose homeostasis, mice lacking HIF-1α gene, a critical component of a master regulator of hypoxic response, in hepatocytes were exposed to high fat/sucrose diet (HFSD). Exposure to HFSD for 5 weeks elicited liver hypoxia with a transient increase in HIF-1α protein expression in the liver of control mice. Glucose disposal was marginally impaired in control mice when challenged oral glucose tolerance test, but such impairment was enhanced in the mutant mice. This alteration was accompanied by a complete inhibition of glucokinase induction with a significant reduction of hepatic glucose uptake. Mice fed HFSD for 20 weeks exhibited fasting hyperglycemia and glucose intolerance, whereas these metabolic phenotypes deteriorated considerably with severe insulin resistance in skeletal muscles and adipose tissues in the mutant mice. These findings suggest that HIF-1 in hepatocytes plays protective roles against the progression of diabetes mellitus.

HIF-1alpha is necessary to support gluconeogenesis during liver regeneration.

Coordinated recovery of hepatic glucose metabolism is prerequisite for normal liver regeneration. To examine roles of hypoxia inducible factor-1alpha (HIF-1alpha) for hepatic glucose homeostasis during the reparative process, we inactivated the gene in hepatocytes in vivo. Following partial hepatectomy (PH), recovery of residual liver weight was initially retarded in the mutant mice by down-regulation of hepatocyte proliferation, but occurred comparably between the mutant and control mice at 72h after PH. At this time point, the mutant mice showed lowered blood glucose levels with enhanced accumulation of glycogen in the liver. The mutant mice exhibited impairment of hepatic gluconeogenesis as assessed by alanine tolerance test. This appeared to result from reduced expression of PGK-1 and PEPCK since 3-PG, PEP and malate were accumulated to greater extents in the regenerated liver. In conclusion, these findings provide evidence for roles of HIF-1alpha in the regulation of gluconeogenesis under liver regeneration.

Soluble factors mediate competitive and cooperative interactions between cells expressing different levels of Drosophila Myc.

When neighboring cells in the developing Drosophila wing express different levels of the transcription factor, dMyc, competitive interactions can occur. Cells with more dMyc proliferate and ultimately overpopulate the wing, whereas cells with less dMyc die, thereby preventing wing overgrowth. How cells sense dMyc activity differences between themselves and the nature of the process leading to changes in growth and survival during competition remain unknown. We have developed a cell culture-based assay by using Drosophila S2 cells to investigate the mechanism of cell competition. We find that in vitro coculture of S2 cells that express different levels of dMyc leads to cellular interactions that recapitulate many aspects of cell competition in the developing wing. Our data indicate that both cell populations in the cocultures participate in and are required for the competitive process by releasing soluble factors into the medium. We demonstrate that the response of naive cells to medium conditioned with competitive cocultures depends on their potential to express dMyc: Cells that can express high levels of dMyc gain a survival advantage and proliferate faster, whereas cells with lower dMyc levels are instructed to die. We suggest that the ability of cells to perceive and respond to local differences in Myc activity is a cooperative mechanism that could contribute to growth regulation and developmental plasticity in organs and tissues during normal development and regeneration.

DRONC coordinates cell death and compensatory proliferation.

Accidental cell death often leads to compensatory proliferation. In Drosophila imaginal discs, for example, gamma-irradiation induces extensive cell death, which is rapidly compensated by elevated proliferation. Excessive compensatory proliferation can be artificially induced by "undead cells" that are kept alive by inhibition of effector caspases in the presence of apoptotic stimuli. This suggests that compensatory proliferation is induced by dying cells as part of the apoptosis program. Here, we provide genetic evidence that the Drosophila initiator caspase DRONC governs both apoptosis execution and subsequent compensatory proliferation. We examined mutants of five Drosophila caspases and identified the initiator caspase DRONC and the effector caspase DRICE as crucial executioners of apoptosis. Artificial compensatory proliferation induced by coexpression of Reaper and p35 was completely suppressed in dronc mutants. Moreover, compensatory proliferation after gamma-irradiation was enhanced in drice mutants, in which DRONC is activated but the cells remain alive. These results show that the apoptotic pathway bifurcates at DRONC and that DRONC coordinates the execution of cell death and compensatory proliferation.

Bax-like protein Drob-1 protects neurons from expanded polyglutamine-induced toxicity in Drosophila.

Bcl-2 family proteins regulate cell death through the mitochondrial apoptotic pathway. Here, we show that the Drosophila Bax-like Bcl-2 family protein Drob-1 maintains mitochondrial function to protect cells from neurodegeneration. A pan-neuronal knockdown of Drob-1 results in lower locomotor activity and a shorter lifespan in adult flies. Either the RNAi-mediated downregulation of Drob-1 or overexpression of Drob-1 antagonist Buffy strongly enhances the polyglutamine-induced accumulation of ubiquitinated proteins and subsequent neurodegeneration. Furthermore, ectopic expression of Drob-1 suppresses the neurodegeneration and premature death of flies caused by expanded polyglutamine. Drob-1 knockdown decreases cellular ATP levels, and enhances respiratory inhibitor-induced mitochondrial defects such as loss of membrane potential (Deltapsim), morphological abnormalities, and reductions in activities of complex I+III and complex II+III, as well as cell death. Taken together, these results suggest that Drob-1 is essential for neuronal cell function, and that Drob-1 protects neurons from expanded polyglutamine-mediated neurodegeneration through the regulation of mitochondrial homeostasis.

Effect of oxidative stress on translocation of DAF-16 in oxygen-sensitive mutants, mev-1 and gas-1 of Caenorhabditis elegans.

Mutations in the mev-1 and gas-1 genes of the nematode Caenorhabditis elegans render animals hypersensitive to oxygen and paraquat, and lead to premature aging. We show that both mutants overproduce superoxide anion in isolated sub-mitochondrial particles, which probably explains their hypersensitivity to oxidative stress. The daf-16 gene encodes a fork-head transcription factor that is negatively regulated by an insulin-signaling pathway. In wild-type animals, the DAF-16 protein normally resides in the cytoplasm and only becomes translocated to nuclei upon activating stimuli such as oxidative stress. Conversely, DAF-16 resides constitutively in the nuclei of mev-1 and gas-1 mutants even under normal growth conditions. Supplementation of the antioxidant coenzyme Q(10) reversed this nuclear translocation of DAF-16. Since both gas-1 and mev-1 encode subunits of electron transport chain complexes, these data illustrate how mitochondrial perturbations can impact signal transduction pathways.

Coenzyme Q10 can prolong C. elegans lifespan by lowering oxidative stress.

The mev-1 gene encodes cytochrome b, a large subunit of the Complex II enzyme succinate-CoQ oxidoreductase. The mev-1(kn1) mutants are hypersensitive to oxidative stress and age precociously, probably because of elevated superoxide anion production in mitochondria. Coenzyme Q (CoQ) is essential for the mitochondrial respiratory chain. Here, we show that CoQ(10) and Vitamin E extended the life span of wild-type Caenorhabditis elegans. Conversely, only CoQ(10) recovered the life shortening effects seen in mev-1. We also show that CoQ(10) but not Vitamin E reduced superoxide anion levels in wild type and mev-1. Another previously described phenotype of mev-1 animals is the presence of supernumerary apoptotic cells. We now demonstrate that CoQ(10) (but not Vitamin E) suppressed these supernumerary apoptoses. Collectively these data suggest that exogenously supplied CoQ(10) can play a significant anti-aging function. It may do so either by acting as an antioxidant to dismutate the free radical superoxide anion or by reducing the uncoupling of reactions during election transport that could otherwise result in superoxide anion production. The latter activity has not been ascribed to CoQ(10); however, it is known that conditions that uncouple electron transport reactions can lead to elevated superoxide anion production.

A complex II defect affects mitochondrial structure, leading to ced-3- and ced-4-dependent apoptosis and aging.

The mev-1(kn1) mutation of Caenorhabditis elegans is in Cyt-1, which encodes a subunit of succinate-coenzyme Q oxidoreductase in the mitochondrial electron transport chain. Mutants are hypersensitive to oxidative stress and age precociously in part because of increased superoxide anion production. Here, we show that mev-1 mutants are defective in succinate-coenzyme Q oxidoreductase, possess ultrastructural mitochondrial abnormalities (especially in muscle cells), show a loss of membrane potential, have altered CED-9 and Cyt-1 protein levels under hyperoxia, and contain ced-3-and ced-4-dependent supernumerary apoptotic cells. These defects likely explain the failure of mev-1 to complete embryonic development under hyperoxia as well as its reduced life span.