VACM-1, a cul-5 gene, inhibits cellular growth by a mechanism that involves MAPK and p53 signaling pathways.

Vasopressin-activated Ca2+-mobilizing (VACM)-1 gene product is a 780-amino acid membrane protein that shares sequence homology with cullins, a family of genes involved in the regulation of cell cycle. However, when expressed in vitro, VACM-1 attenuates basal and vasopressin- and forskolin-induced cAMP production. Mutating the PKA-dependent phosphorylation site in the VACM-1 sequence (S730AVACM-1) prevents this inhibitory effect. To further examine the biological role of VACM-1, we studied the effect of VACM-1 and S730AVACM-1 proteins on cellular proliferation and gene expression in Chinese hamster ovary and COS-1 cells. Cellular proliferation of VACM-1-expressing cell lines was significantly lower compared with that of the vector-transfected cells, whereas it was significantly increased in S730AVACM-1-derived cell lines. Furthermore, expression of VACM-1 but not S730AVACM-1 protein retarded cytokinesis and prevented MAPK phosphorylation. Screening with the Human PathwayFinder-1 GEArray system and subsequent Western blot analysis demonstrated that VACM-1 induces p53 mRNA and protein expression. In summary, VACM-1 inhibits cellular growth by a mechanism that involves cAMP, MAPK phosphorylation, and p53 expression.

Membrane topology of the murine fatty acid transport protein 1.

The murine fatty acid transport protein (FATP1) was identified in an expression cloning screen for proteins that facilitate transport of fatty acids across the plasma membranes of mammalian cells. Hydropathy analysis of this protein suggests a model in which FATP1 has multiple membrane-spanning domains. To test this model, we inserted a hemagglutinin epitope tag at the amino terminus or a FLAG tag at the carboxyl terminus of the FATP1 cDNA and expressed these constructs in NIH 3T3 cells. Both tagged constructs produce proteins of the expected molecular masses and are functional in fatty acid import assays. Indirect immunofluorescence studies with selective permeabilization conditions and protease protection studies of sealed membrane vesicles from cells expressing epitope-tagged FATP1 were performed. These experiments show that the extreme amino terminus of tagged FATP1 is oriented toward the extracellular space, whereas the carboxyl terminus faces the cytosol. Additionally, enhanced green fluorescent protein fusion constructs containing predicted membrane-associated or soluble portions of FATP1 were expressed in Cos7 cells and analyzed by immunofluorescence and subcellular fractionation. These experiments demonstrate that amino acids 1-51, 52-100, and 101-190 contain signals for integral association with the membrane, whereas residues 258-313 and 314-475 are only peripherally membrane-associated. Amino acid residues 191-257 and 476-646 do not direct membrane association and likely face the cytosol. Taken together, these data support a model of FATP1 as a polytopic membrane protein with at least one transmembrane and multiple membrane-associated domains. This study provides the first experimental evidence for topology of a member of the family of plasma membrane fatty acid transport proteins.

Palmitate-induced apoptosis can occur through a ceramide-independent pathway.

Cytotoxic accumulation of long chain fatty acids has been proposed to play an important role in the pathogenesis of diabetes mellitus and heart disease. To explore the mechanism of cellular lipotoxicity, we cultured Chinese hamster ovary cells in the presence of media supplemented with fatty acid. The saturated fatty acid palmitate, but not the monounsaturated fatty acid oleate, induced programmed cell death as determined by annexin V positivity, caspase 3 activity, and DNA laddering. De novo ceramide synthesis increased 2.4-fold with palmitate supplementation; however, this was not required for palmitate-induced apoptosis. Neither biochemical nor genetic inhibition of de novo ceramide synthesis arrested apoptosis in Chinese hamster ovary cells in response to palmitate supplementation. Rather, our data suggest that palmitate-induced apoptosis occurs through the generation of reactive oxygen species. Fluorescence of an oxidant-sensitive probe was increased 3.5-fold with palmitate supplementation indicating that production of reactive intermediates increased. In addition, palmitate-induced apoptosis was blocked by pyrrolidine dithiocarbamate and 4,5-dihydroxy-1,3-benzene-disulfonic acid, two compounds that scavenge reactive intermediates. These studies suggest that generation of reactive oxygen species, independent of ceramide synthesis, is important for the lipotoxic response and may contribute to the pathogenesis of diseases involving intracellular lipid accumulation.

VACM-1, a cullin gene family member, regulates cellular signaling.

Vasopressin-activated Ca(2+)-mobilizing (VACM-1) receptor binds arginine vasopressin (AVP) but does not have amino acid sequence homology with the traditional AVP receptors. VACM-1, however, is homologous with a newly discovered cullin family of proteins that has been implicated in the regulation of cell cycle through the ubiquitin-mediated degradation of cyclin-dependent kinase inhibitors. Because cell cycle processes can be regulated by the transmembrane signal transduction systems, the effects of VACM-1 expression on the Ca(2+) and cAMP-dependent signaling pathway were examined in a stable cell line expressing VACM-1 in VACM-1 transfected COS-1 cells and in cells cotransfected with VACM-1 and the adenylyl cyclase-linked V(2) AVP receptor cDNAs. Expression of the VACM-1 gene reduced basal as well as forskolin- and AVP-stimulated cAMP production. In cells cotransfected with VACM-1 and the V(2) receptor, the AVP- and forskolin-induced increases in adenylyl cyclase activity and cAMP production were inhibited. The inhibitory effect of VACM-1 on cAMP production could be reversed by pretreating cells with staurosporin, a protein kinase A (PKA) inhibitor, or by mutating S730A, the PKA-dependent phosphorylation site in the VACM-1 sequence. The protein kinase C specific inhibitor Gö-6983 further enhanced the inhibitory effect of VACM-1 on AVP-stimulated cAMP production. Finally, AVP stimulated D-myo-inositol 1,4, 5-trisphosphate production both in the transiently transfected COS-1 cells and in the stable cell line expressing VACM-1, but not in the control COS-1 and Chinese hamster ovary cells. Our data demonstrate that VACM-1, the first mammalian cullin protein to be characterized, is involved in the regulation of signaling.

VACM-1 receptor is specifically expressed in rabbit vascular endothelium and renal collecting tubule.

The vasopressin-activated calcium-mobilizing (VACM-1) protein is a novel arginine vasopressin (AVP) receptor that shares sequence homology with a cullin multigene family but not with the AVP receptors. To characterize the VACM-1 receptor, we examined its tissue-specific expression using Northern blot, RT-PCR, and immunostaining analyses. Northern blot hybridization identified a 6. 4-kb cRNA species that was expressed in the rabbit kidney medulla, brain, heart, and ovaries. In human tissue, VACM-1 mRNA is a larger (7.5 kb) cRNA found in the kidney, brain, heart, placenta, and skeletal muscle. VACM-1-specific RT-PCR products were detected in mRNA from rabbit kidney medulla, brain, heart, and mesenteric arteries. No expression of VACM-1 could be detected in rabbit aorta, gastrointestinal tract, or liver. Coimmunostaining with anti-VACM-1 antibodies (Ab) and a specific vascular endothelial cell marker, CD31 monoclonal Ab, localized VACM-1 expression to the vasculature in specific tissues. We identified the kidney cells expressing VACM-1 receptor by coimmunostaining with the following monoclonal Ab, which recognize epitopes in specific segments of the nephron: rct-30 Ab, reactive against the cortical and medullary collecting tubule (CT) cells; mr-omct Ab, reactive against the mitochondria-rich cells of the outer medullary CT; and an Ab specific against the loop of Henle segment. These studies indicated that the VACM-1 receptor is expressed only in the medullary CT. Kidney coimmunostaining with anti-VACM-1 and CD31 Ab identified VACM-1-receptor expression in glomeruli and medullary vascular bundles. These results demonstrate that the novel VACM-1 receptor, expressed in many organs, is localized to the endothelial cells. In the kidney, it is also expressed in the medullary CT cells. Thus VACM-1 may be involved in the regulation of endothelial permeability and water transport in the CT.