Nuclear envelope phosphatase 1-regulatory subunit 1 (formerly TMEM188) is the metazoan Spo7p ortholog and functions in the lipin activation pathway

Lipin-1 catalyzes the formation of diacylglycerol from phosphatidic acid. Lipin-1 mutations cause lipodystrophy in mice and acute myopathy in humans. It is heavily phosphorylated, and the yeast ortholog Pah1p becomes membrane-associated and active upon dephosphorylation by the Nem1p-Spo7p membrane complex. A mammalian ortholog of Nem1p is the C-terminal domain nuclear envelope phosphatase 1 (CTDNEP1, formerly "dullard"), but its Spo7p-like partner is unknown, and the need for its existence is debated. Here, we identify the metazoan ortholog of Spo7p, TMEM188, renamed nuclear envelope phosphatase 1-regulatory subunit 1 (NEP1-R1). CTDNEP1 and NEP1-R1 together complement a nem1Δspo7Δ strain to block endoplasmic reticulum proliferation and restore triacylglycerol levels and lipid droplet number. The two human orthologs are in a complex in cells, and the amount of CTDNEP1 is increased in the presence of NEP1-R1. In the Caenorhabditis elegans embryo, expression of nematode CTDNEP1 and NEP1-R1, as well as lipin-1, is required for normal nuclear membrane breakdown after zygote formation. The expression pattern of NEP1-R1 and CTDNEP1 in human and mouse tissues closely mirrors that of lipin-1. CTDNEP1 can dephosphorylate lipins-1a, -1b, and -2 in human cells only in the presence of NEP1-R1. The nuclear fraction of lipin-1b is increased when CTDNEP1 and NEP1-R1 are co-expressed. Therefore, NEP1-R1 is functionally conserved from yeast to humans and functions in the lipin activation pathway.     

Interaction of SNF1 protein kinase with its activating kinase Sak1

The Saccharomyces cerevisiae SNF1 protein kinase, a member of the SNF1/AMP-activated protein kinase (AMPK) family, is activated by three kinases, Sak1, Tos3, and Elm1, which phosphorylate the Snf1 catalytic subunit on Thr-210 in response to glucose limitation and other stresses. Sak1 is the primary Snf1-activating kinase and is associated with Snf1 in a complex. Here we examine the interaction of Sak1 with SNF1. We report that Sak1 coimmunopurifies with the Snf1 catalytic subunit from extracts of both glucose-replete and glucose-limited cultures and that interaction occurs independently of the phosphorylation state of Snf1 Thr-210, Snf1 catalytic activity, and other SNF1 subunits. Sak1 interacts with the Snf1 kinase domain, and nonconserved sequences C terminal to the Sak1 kinase domain mediate interaction with Snf1 and augment the phosphorylation and activation of Snf1. The Sak1 C terminus is modified in response to glucose depletion, dependent on SNF1 activity. Replacement of the C terminus of Elm1 (or Tos3) with that of Sak1 enhanced the ability of the Elm1 kinase domain to interact with and phosphorylate Snf1. These findings indicate that the C terminus of Sak1 confers its function as the primary Snf1-activating kinase and suggest that the physical association of Sak1 with SNF1 facilitates responses to environmental change.     

Antagonistic interplay of Swi1 and Tup1 on filamentous growth of Candida albicans

Candida albicans is a polymorphic human opportunistic pathogen in which the Swi-Snf complex functions as an activator whereas Tup1 acts as a general repressor during the yeast-hyphae transition. In Saccharomyces cerevisiae, the interplay between the Swi-Snf complex and the Tup1-Ssn6 repressive complex regulates the balance between active and repressed chromatin structures of a number of genes. To study the interplay between Candida albicans Swi1 and Tup1 and their effects on morphogenesis, we analyzed phenotypes of swi1/swi1, tup1/tup1 and swi1/swi1 tup1/tup1 mutants under various growth conditions. The swi1/swi1 mutant failed to form true hyphae, whereas the tup1/tup1 mutant exhibited constitutive filamentous growth. Deletion of SWI1 in the tup1/tup1 mutant completely blocked hyphal growth under all the conditions examined. Under aerobic conditions, the swi1/swi1 tup1/tup1 mutant most resembled the swi1/swi1 mutant in phenotype, actin polarization and gene expression pattern. In invaded agar, the double mutant showed similar phenotypes as the swi1/swi1 mutant, while under embedded conditions, it grew as a pseudohypha-like form different from that of the wild-type strain, swi1/swi1 or tup1/tup1 mutants. These results suggest that Swi1 may play a dominant role by antagonizing the repressive effect of the Tup1 on hyphal development in C. albicans.     

Dual functional significance of calcineurin homologous protein 1 binding to Na(+)/H(+) exchanger isoform 1

Calcineurin homologous protein 1 (CHP1) binds to the hydrophilic tail of the Na(+)/H(+) exchanger isoform 1 (NHE1). Previous gene knockout of CHP1 revealed that the loss of CHP1 caused a decrease in the total amount of NHE1, suggesting the destabilization of NHE1 molecules without CHP1 (Matsushita et al., Am J Physiol Cell Physiol 293: C246-C254, 2007). However, Pang et al. (J Biol Chem 276: 17367-17372, 2001) reported that NHE1 without a CHP1 binding site was found in the plasma membrane, suggesting no requirement of CHP1 binding for plasma membrane localization of NHE1. Here, the functional significance of CHP1 binding to NHE1 was examined to resolve these contradictory results. In CV1 cells, which overexpressed wild-type NHE1, overexpression of CHP1 caused an increase in both the total amount of NHE1 and the colocalization of NHE1 and CHP1 at the plasma membrane. This provided new visual evidence of the localization of NHE1 from endoplasmic reticulum to the plasma membrane upon CHP1 binding. An immunoprecipitation assay showed that the expression of CHP1 reduced the ubiquitination of NHE1 and/or its associated proteins. Mutant NHE1s without CHP1 binding site exhibited a modest localization to the plasma membrane. After reaching the plasma membrane, these mutant NHE1s exhibited shorter half-lives than the wild-type NHE1 with CHP1. The results suggest a dual functional significance of CHP1 and its binding region: 1) binding of CHP1 stabilizes NHE1 and increases its plasma membrane localization by masking a NHE1 disposal signal, and 2) CHP1 binding is required for the antiporter activity.     

Glutathione S-transferase mu modulates the stress-activated signals by suppressing apoptosis signal-regulating kinase 1

Apoptosis signal-regulating kinase 1 (ASK1) is a mitogen-activated protein kinase kinase kinase that can activate the c-Jun N-terminal kinase and the p38 signaling pathways. It plays a critical role in cytokine- and stress-induced apoptosis. To further characterize the mechanism of the regulation of the ASK1 signal, we searched for ASK1-interacting proteins employing the yeast two-hybrid method. The yeast two-hybrid assay indicated that mouse glutathione S-transferase Mu 1-1 (mGSTM1-1), an enzyme involved in the metabolism of drugs and xenobiotics, interacted with ASK1. We subsequently confirmed that mGSTM1-1 physically associated with ASK1 both in vivo and in vitro. The in vitro binding assay indicated that the C-terminal portion of mGSTM1-1 and the N-terminal region of ASK1 were crucial for binding one another. Furthermore, mGSTM1-1 suppressed stress-stimulated ASK1 activity in cultured cells. mGSTM1-1 also blocked ASK1 oligomerization. The ASK1 inhibition by mGSTM1-1 occurred independently of the glutathione-conjugating activity of mGSTM1-1. Moreover, mGSTM1-1 repressed ASK1-dependent apoptotic cell death. Taken together, our findings suggest that mGSTM1-1 functions as an endogenous inhibitor of ASK1. This highlights a novel function for mGSTM1-1 insofar as mGSTM1-1 may modulate stress-mediated signals by repressing ASK1, and this activity occurs independently of its well-known catalytic activity in intracellular glutathione metabolism.     

Cytotoxicity and mutagenicity of dibenzo[a,l]pyrene and (+/-)-dibenzo[a,l]pyrene-11,12-dihydrodiol in V79MZ cells co-expressing either hCYP1A1 or hCYP1B1 together with human glutathione-S-transferase A1

We have used V79MZ hamster lung fibroblasts stably transfected with human cytochrome P450-1A1 (hCYP1A1; cell line designated V79MZh1A1) or P450-1B1 (hCYP1B1; cell line designated V79MZh1B1) alone, or in combination with human glutathione-S-transferase (GST) alpha-1 (hGSTA1), in order to examine GST protection against cytotoxicity and mutagenicity of dibenzo[a,l]pyrene (DBP) and the intermediate dihydrodiol metabolite (+/-)-DBP-11,12-dihydrodiol (DBPD). At comparable expression levels of hCYP1A1 and hCYP1B1, both DBP and DBPD were more cytotoxic in V79MZ1A1 (IC(50)=2.7 and 0.7nM, respectively) than in V79MZh1B1 (IC(50)=6.0 and 4.8nM, respectively). In contrast, both DBP and DBPD were two- to four-fold more mutagenic in V79MZh1B1 than in V79MZ1A1. Co-expression of hGSTA1 with hCYP1A1 decreased DBP cytotoxicity two-fold compared to V79MZh1A1 with hCYP1A1 alone, and provided a small, yet still statistically significant, 1.3-fold protection against DBPD. Protection against mutagenicity of these compounds was comparable to that for cytotoxicity in cells expressing hCYP1A1. In V79MZh1B1 cells, co-expression of hGSTA1 conferred up to five-fold protection against DBP cytotoxicity, and up to nine-fold protection against the (+/-)-DBP-dihydrodiol cytotoxicity relative to the cells expressing hCYP1B1 alone. Co-expression of hGSTA1 also reduced mutagenicity of DBP or its dihydrodiol to a lesser extent (1.3-1.8-fold) than the protection against cytotoxicity in cells expressing hCYP1B1. These findings demonstrate that the protective efficacy of hGSTA1 against DBP and DBPD toxicity is variable, depending on the compound or metabolite present, the specific cytochrome P450 isozyme expressed, and the specific cellular damage endpoint examined.     

Redox Factor-1 Activates Endothelial SIRTUIN1 through Reduction of Conserved Cysteine Sulfhydryls in Its Deacetylase Domain

Apurinic/Apyrmidinic Endonuclease 1/Redox Factor-1 (APE1/Ref-1) is a reductant which is important for vascular homeostasis. SIRTUIN1 (SIRT1) is a lysine deacetylase that also promotes endothelium-dependent vasorelaxation. We asked if APE1/Ref-1 governs the redox state and activity of SIRT1, and whether SIRT1 mediates the effect of APE1/Ref-1 on endothelium-dependent vascular function. APE1/Ref-1 maintains sulfhydryl (thiol) groups of cysteine residues in SIRT1 in the reduced form and promotes endothelial SIRT1 activity. APE1/Ref-1 stimulates SIRT1 activity by targeting highly conserved vicinal thiols 371 and 374 which form a zinc tetra-thiolate motif in the deacetylase domain of SIRT1. Cysteine residues in the N-terminal redox domain of APE1/Ref-1 are essential for reducing SIRT1 and stimulating its activity. APE1/Ref-1 protects endothelial SIRT1 from hydrogen peroxide-induced oxidation of sulfhydryls and from inactivation. APE1/Ref-1 also promotes lysine deacetylation of the SIRT1 target endothelial nitric oxide synthase (eNOS). SIRT1 mutated at cysteines 371 and 374, which renders it non-reducible by APE1/Ref-1, prevents lysine deacetylation of eNOS by APE1/Ref-1. SIRT1 free thiol (reduced sulfhydryl) content and deacetylase activity are diminished in all examined tissues of APE1/Ref-1^+/− mice, including the vasculature. Overexpression of SIRT1 in aortas of APE1/Ref-1^+/− mice restores endothelium-dependent vasorelaxation and bioavailable nitric oxide (NO) to levels similar to those observed in wild-type mice. Thus, APE1/Ref-1, by maintaining functionally important cysteine sulfhydryls in SIRT1 in the reduced form, promotes endothelial SIRT1 activity. This reductive activation of endothelial SIRT1 by APE1/Ref-1 mediates the effect of APE1/Ref-1 on eNOS acetylation, promoting endothelium-derived NO and endothelium-dependent vasorelaxation.     

Myosin heavy chain and cardiac troponin T damage is associated with impaired myofibrillar ATPase activity contributing to sarcomeric dysfunction in Ca<Superscript>2+</Superscript>-paradox rat hearts

C1ql-like (C1QL)-1 and -4 proteins are encoded by homologous genes that are highly expressed in brain and adipose tissues. However, functional properties of C1QL proteins outside of the brain and adipocytes remain unknown. Here, we report that the globular domain of C1ql1/Ctrp14 and C1ql4/Ctrp11 proteins directly stimulate the angiogenesis of endothelial cells. In this study, soluble C1ql1/CTRP14 and C1ql4/Ctrp11 proteins, produced in prokaryote expression system, are co-cultured with human umbilical vein endothelium cells (HUVECs), which phenotype is identified with von Willebrand factor antibody. C1ql1/Ctrp14 and C1ql4/Ctrp11 promote the migration and capillary tube formation of HUVECs in a dose-dependent manner. During this process, phosphorylation of c-Raf, MEK1/2, ERK1/2, and p90RSK are activated by C1ql1/Ctrp14 and C1ql4/Ctrp11. MEK1/2 inhibitor, U0126, blocks C1ql1/Ctrp14-, and C1ql4/Ctrp11-induced capillary tube formation and cell migration. Moreover, the immunoreactivity of the receptor of C1QL1-C1QL4, brain-specific angiogenesis inhibitor 3 (BAI3), is detected in HUVECs, suggesting that BAI3 may mediate C1QL1/CTRP14- and C1QL4/CTRP11-induced angiogenesis. Meanwhile, C1ql1/Ctrp14 and C1ql4/Ctrp11 exposure also causes a stimulatory response of angiogenesis in chick yolk sac membrane. These data demonstrate that C1ql1/Ctrp14 and C1ql4/Ctrp11 stimulate the new blood vessel growth by activation of ERK1/2 signal pathway. The proangiogenic activity of C1ql1/Ctrp14 and C1ql4/Ctrp11 provides novel insights into the new opportunities for therapeutic intervention by targeting C1QLs in tumorigenesis, tissue regeneration, and recovery of ischemic heart disease.     

Cloning, expression analysis and chromosome mapping of human casein kinase 1 gamma1 (CSNK1G1): identification of two types of cDNA encoding the kinase protein associated with heterologous carboxy-terminal sequences

Casein kinase 1 gamma1(CK1 gamma1) is known to be involved in the growth and morphogenesis of eukaryotic cells. We have isolated two types of cDNA for human casein kinase 1 gamma1 (hCK1 gamma1). One of them (hCK1 gamma1S) was found to encode a polypeptide consisting of 393 amino acids, which is highly homologous with already reported rat CK1 gamma1 (rCK1 gamma1). The other type of cDNA (hCK1 gamma1L) encodes a polypeptide consisting of 422 amino acids, which is quite identical in the kinase domain, but different in the C-terminal sequence from hCK1 gamma1S. Namely, hCK1 gamma1L has a characteristic sequence of 50 amino acids at the C-terminal end and this motif was shown to be shared by the casein kinase gamma2 and gamma3 from rat and human, suggesting that it is a signature sequence of the gamma-isoforms. In this sense, newly isolated hCK1 gamma1L might be the original form of CK1 gamma1 subspecies rather than rCK1 gamma1 and hCK1 gamma1S. RT-PCR analysis revealed that hCK1 gamma1S mRNA is predominantly present in the testis, whereas the abundance of hCK1 gamma1L mRNA was nearly the same in the twelve tissues examined. These results suggest that novel hCK1 gamma1L may have a unique functional role different from that of hCK1 gamma1S and rCK1 gamma1. The human hCK1 gamma1 gene (CSNK1G1) was mapped to chromosome 15q22.1-->q22.31 by fluorescence in situ hybridization.     

Ezetimibe restores biliary cholesterol excretion in mice expressing Niemann-Pick C1-Like 1 only in liver

Niemann-Pick C1-Like 1 (NPC1L1) is highly expressed in the small intestine across mammalian species and is the target of ezetimibe, a potent cholesterol absorption inhibitor. In humans, NPC1L1 is also expressed in the liver. We found that transgenic overexpression of NPC1L1 in the wild-type mouse liver inhibits biliary cholesterol secretion and raises blood cholesterol, which can be reversed by ezetimibe treatment. Unfortunately, the high expression of endogenous NPC1L1 in the intestine hampered a definitive establishment of the role of hepatic NPC1L1 in cholesterol metabolism and ezetimibe action in the liver because intestinal NPC1L1 dramatically influences cholesterol homeostasis and is a target of ezetimibe. To circumvent this obstacle, we crossed liver-specific NPC1L1 transgenic mice to NPC1L1 knockout (L1-KO) mice and created a mouse line expressing no endogenous NPC1L1, but human NPC1L1 in liver only (L1(LivOnly) mice). Compared to L1-KO mice, L1(LivOnly) mice on a 0.2% cholesterol diet showed significantly increased hepatic and plasma cholesterol, and despite a 90% reduction in biliary cholesterol excretion, their fecal cholesterol excretion remained completely unaltered. Remarkably, 4days of ezetimibe treatment significantly restored biliary cholesterol secretion in L1(LivOnly) mice. These findings demonstrated a direct role of hepatic NPC1L1 in regulating biliary cholesterol excretion and hepatic/blood cholesterol levels, and unequivocally established hepatic NPC1L1 as a target of ezetimibe.     

Novel mating type-dependent transcripts at the mating type locus in Magnaporthe oryzae

The mating type locus (MAT1) of Magnaporthe oryzae has similar structural organization to MAT in other ascomycetes and encodes the mating type genes MAT1-1-1 with an alpha-box motif and MAT1-2-1 with an HMG-box motif in the MAT1-1 and MAT1-2 idiomorphs, respectively. Sequence and expression analyses of the MAT1 locus indicated a second open reading frame (ORF), MAT1-1-2, in the MAT1-1 idiomorph, and novel mating-type dependent ORFs (MAT1-1-3 and MAT1-2-2) at the locus. The MAT1-1-3 ORF initiated within the MAT1-1 idiomorph while the MAT1-2-2 ORF initiated at the border of the MAT1-2 idiomorph with both ORFs sharing most of their reading frames in the MAT1 flanking region. This suggests that the encoded proteins (MAT1-1-3 and MAT1-2-2) should be similar in their primary structures but can be distinguished by distinct N-termini with amino acids of 1 and 32, respectively, in each mating type. A CT dinucleotide repeat, (CT)n, present in the upstream region of MAT1-1-3, was polymorphic among the isolates.     

Ca2+ binding properties and Ca2(+)-dependent interactions of the isolated NH2-terminal alpha fragments of human complement proteases C1-r and C1-s

The NH2-terminal alpha fragments of human complement proteases C1-r and C1-s were obtained by limited proteolysis of the native proteins with trypsin, and isolated. C1-r alpha extended from residues 1 to 208 of C1-r A chain, with at least two cleavage sites within disulfide loops, after lysine 134 and arginine 202. C1-s alpha comprised residues 1-192 of the C1-s A chain, with one cleavage site within a disulfide loop, after arginine 186. C1-r alpha was monomeric either in the presence or absence of Ca2+ but formed Ca2(+)-dependent dimers with native C1-s. C1-s alpha dimerized in the presence of Ca2+ and formed Ca2(+)-dependent tetramers (C1-s alpha-C1-r-C1-r-C1-s alpha) with native C1-r. C1-r alpha and C1-s alpha associated in the presence of Ca2+ to form C1-r alpha-C1-s alpha heterodimers. Equilibrium dialysis studies indicated that each alpha region binds Ca2+ with a dissociation constant ranging from 19 microM (native proteins) to 38 microM (fragments). C1-r alpha, C1-r alpha-C1-s alpha, and the native C1-s-C1-r-C1-r-C1-s tetramer bound 0.9, 1.9, and 4.0 Ca2+ atoms/mol, respectively, whereas dimers C1-s alpha-C1-s alpha and C1-s-C1-s incorporated 2.9 and 3.0 Ca2+ atoms/mol. It is concluded that each alpha region contains one high affinity Ca2+ binding site. This 1:1 stoichiometry is maintained upon heterologous (C1-r-C1-s) interaction, whereas the homologous (C1-s-C1-s) interaction provides one additional binding site.     

Role of Ndt80, Sum1, and Swe1 as targets of the meiotic recombination checkpoint that control exit from pachytene and spore formation in Saccharomyces cerevisiae

The meiotic recombination checkpoint, which is triggered by defects in recombination or chromosome synapsis, arrests sporulating cells of Saccharomyces cerevisiae at pachytene by preventing accumulation of active Clb-Cdc28. We compared the effects of manipulating the three known targets of the meiotic recombination checkpoint, NDT80, SWE1, and SUM1, in dmc1-arrested cells. Ndt80 is an activator of a set of middle sporulation-specific genes (MSGs), which includes CLB genes and genes involved in spore wall formation; Swe1 inhibits Clb-Cdc28 activity; and Sum1 is a repressor of NDT80 and some MSGs. Activation of the checkpoint leads to inhibition of Ndt80 activity and to stabilization of Swe1 and Sum1. Thus, dmc1-arrested cells fail to express MSGs, arrest at pachytene, and do not form spores. Our study shows that dmc1/dmc1 sum1/sum1 cells expressed MSGs prematurely and at high levels, entered the meiotic divisions efficiently, and in some cases formed asci containing mature spores. In contrast, dmc1/dmc1 swe1/swe1 cells expressed MSGs at a very low level, were inefficient and delayed in entry into the meiotic divisions, and never formed mature spores. We found that cells of dmc1/dmc1 sum1/sum1 ndt80/ndt80 and dmc1/dmc1 swe1/swe1 ndt80/ndt80 strains arrested at pachytene and that dmc1/dmc1 or dmc1/dmc1 swe1/swe1 cells overexpressing NDT80 were less efficient in bypassing checkpoint-mediated arrest than dmc1/dmc1 sum1/sum1 cells. Our results are consistent with previous suggestions that increased Clb-Cdc28 activity, caused by mutation of SWE1 or by an NDT80-dependent increase in CLB expression, allows dmc1/dmc1 cells to exit pachytene and that subsequent upregulation of Ndt80 activity by a feedback mechanism promotes entry into the meiotic divisions. Spore morphogenesis, however, requires efficient and timely activation of MSGs, which we speculate was achieved in dmc1/dmc1 sum1/sum1 cells by premature expression of NDT80.     

Isolation and characterization of gangliosides from Trypanosoma brucei

Gangliosides were isolated from Trypanosoma brucei and analyzed by thin-layer chromatography (TLC) and TLC immunostaining test. Four species of gangliosides, designated as G-1, G-2, G-3, and G-4, were separated by TLC. G-1 ganglioside had the same TLC migration rate as GM3. In contrast, G-2, G-3, and G-4 gangliosides migrated a little slower than GM1, GD1a, and GD1b, respectively. To characterize the molecular species of gangliosides from T. brucei, G-1, G-2, G-3, and G-4 gangliosides were purified and analyzed by TLC immunostaining test with monoclonal antibodies against gangliosides. G-1 ganglioside showed the reactivity to the monoclonal antibody against ganglioside GM3. G-2 was recognized by the anti-GM1 monoclonal antibody. G-3 showed reaction with the monoclonal antibody to GD1a. G-4 had the reactivity to anti-GD1b monoclonal antibody. Using 4 kinds of monoclonal antibodies, we also studied the expression of GM3, GM1, GD1a, and GD1b in T. brucei parasites. GM3, GM1, GD1a, and GD1b were detected on the cell surface of T. brucei. These results suggest that G-1, G-2, G-3, and G-4 gangliosides are GM3 (NeuAc alpha2-3Gal beta1-4Glc beta1-1Cer), GM1 (Gal beta1-3GalNAc beta1-4[NeuAc alpha2-3]Gal beta1-4Glc beta1-1Cer), GD1a (NeuAc alpha2-3Gal beta1-3GalNAc beta1-4[NeuAc alpha2-3]Gal beta1-4Glc beta1-1Cer), and GD1b (Gal beta1-3GalNAc beta1-4[NeuAc alpha2-8NeuAc alpha2-3]Gal beta1-4Glc beta1-1Cer), respectively, and also that they are expressed on the cell surface of T. brucei.