Rotavirus nonstructural protein 4 (NSP4) is known to function as an intracellular receptor at the endoplasmic reticulum (ER) critical to viral morphogenesis and is the first characterized viral enterotoxin.Exogenously added NSP4 induces diarrhea in rodent pups and stimulates secretory chloride currents across intestinal segments as measured in Ussing chambers. Circular dichroism studies further reveal that intact NSP4 and the enterotoxic peptide (NSP4 114-135 ) that is located within the extended, C-terminal amphipathic helix preferentially interact with caveola-like model membranes. We now show colocalization of NSP4 and caveolin-1 in NSP4-transfected and rotavirus-infected mammalian cells in reticular structures surrounding the nucleus (likely ER), in the cytosol, and at the cell periphery by laser scanning confocal microscopy. A direct interaction between NSP4 residues 112 to 140 and caveolin-1 was determined by the Pro-Quest yeast twohybrid system with full-length NSP4 and seven overlapping deletion mutants as bait, caveolin-1 as prey, and vice versa. Coimmunoprecipitation of NSP4-caveolin-1 complexes from rotavirus-infected mammalian cells demonstrated that the interaction occurs during viral infection. Finally, binding of caveolin-1 from mammalian cell lysates to Sepharose-bound, NSP4-specific synthetic peptides confirmed the yeast two-hybrid data and further delineated the binding domain to amino acids 114 to 135. We propose that the association of NSP4 and caveolin-1 contributes to NSP4 intracellular trafficking from the ER to the cell surface and speculate that exogenously added NSP4 stimulates signaling molecules located in caveola microdomains.Rotaviruses (RV) cause severe, life-threatening gastroenteritis in children and animals worldwide and in immunocompromised and elderly adults (46). The RV genome is composed of 11 segments of double-stranded RNA that encodes five nonstructural and six structural proteins (17). Nonstructural protein 4 (NSP4), encoded by RV gene 10, initially was identified as an endoplasmic reticulum (ER) transmembrane glycoprotein essential to RV morphogenesis by serving as an intracellular receptor to double-layered particles (DLPs) (5,44,67,66). NSP4 residues 161 to 175 bind the outer coat protein (VP6) of the DLPs, which facilitates translocation into the ER and the addition of two viral proteins, VP7 and VP4, and a transient ER membrane (40,66,67); NSP4 is sufficient for the budding of DLPs into the ER lumen (33). The ER transient viral envelope is eventually removed by an unknown mechanism prior to virus release (40,44). Because the NSP4 sequence lacks classical ER retention signals and does not appear to be retrieved by retrograde transport and the two N-linked, high-mannose glycosylation sites remain sensitive to endoglycosidase H (endo H) digestion, the current tenet is that NSP4 does not enter or traffic through the Golgi (5, 16).In addition to facilitating RV maturation at the ER, NSP4 functions as the first described viral enterotoxin that induces diarrhea in neonatal...
HDL-mediated reverse-cholesterol transport as well as phosphoinositide signaling are mediated through plasma membrane microdomains termed caveolae/lipid rafts. However, relatively little is known regarding mechanism(s) whereby these lipids traffic to or are targeted to caveolae/lipid rafts. Since sterol carrier protein-2 (SCP-2) binds both cholesterol and phosphatidylinositol, the possibility that SCP-2 might interact with caveolin-1 and caveolae was examined. Double immunolabeling and laser scanning fluorescence microscopy showed that a small but significant portion of SCP-2 colocalized with caveolin-1 primarily at the plasma membrane of L-cells and more so within intracellular punctuate structures in hepatoma cells. In SCP-2 overexpressing L-cells, SCP-2 was detected in close proximity to caveolin, 48 +/- 4 A, as determined by fluorescence resonance energy transfer (FRET) and immunogold electron microscopy. Cell fractionation of SCP-2 overexpressing L-cells and Western blotting detected SCP-2 in purified plasma membranes, especially in caveolae/ lipid rafts as compared to the nonraft fraction. SCP-2 and caveolin-1 were coimmunoprecipitated from cell lysates by anti-caveolin-1 and anti-SCP-2. Finally, a yeast two-hybrid assay demonstrated that SCP-2 directly interacts with caveolin-1 in vivo. These interactions of SCP-2 with caveolin-1 were specific since a functionally related protein, phosphatidyinositol transfer protein (PITP), colocalized much less well with caveolin-1, was not in close proximity to caveolin-1 (i.e., >120 A), and was not coimmunoprecipitated by anti-caveolin-1 from cell lysates. In summary, it was shown for the first time that SCP-2 (but not PITP) selectively interacted with caveolin-1, both within the cytoplasm and at the plasma membrane. These data contribute significantly to our understanding of the role of SCP-2 in cholesterol and phosphatidylinositol targeted from intracellular sites of synthesis in the endoplasmic reticulum to caveolae/lipid rafts at the cell surface plasma membrane.
Over 20 years ago, it was reported that liver cytosol contains at least two distinct proteins that transfer phosphatidylinositol in vitro, phosphatidylinositol transfer protein (PITP) and a pH 5.1 supernatant fraction containing sterol carrier protein-2 (SCP-2). In contrast to PITP, there has been minimal progress on the structural and functional significance of SCP-2 in phosphatidylinositol transport. As shown herein, highly purified, recombinant SCP-2 stimulated up to 13-fold the rapid (s) transfer of radiolabeled phosphatidylinositol (PI) from microsomal donor membranes to highly curved acceptor membranes. SCP-2 bound to microsomes in vitro and overexpression of SCP-2 in transfected L-cells resulted in the following: (i) redistribution of phosphatidylinositols from intracellular membranes (mitochondria and microsomes) to the plasma membrane; (ii) enhancement of insulin-mediated inositol-triphosphate production; and (iii) 5.5-fold down regulation of PITP. Like PITP, SCP-2 binds two ligands required for vesicle budding from the Golgi, PI, and fatty acyl CoA. Double immunolabeling confocal microscopy showed SCP-2 significantly colocalized with caveolin-1 in the cytoplasm (punctate) and plasma membrane of SCP-2 overexpressing hepatoma cells (72%), HT-29 cells (58%), and SCP-2 overexpressing L-cells (37%). Taken together, these data show for the first time that SCP-2 plays a hitherto unrecognized role in intracellular phosphatidylinositol transfer, distribution, and signaling.
The infectious bronchitis virus (IBV) nucleocapsid protein was expressed as a bacterial fusion protein which differed from the native protein only in the addition of six amino terminus histidine residues. Using RNA overlay protein blot assays, the recombinant protein was shown to bind to RNA fragments specific for the positive sense 3' noncoding end of the IBV genome. At greater concentrations of sodium chloride, the native and fusion nucleocapsid proteins similarly bound to G RNA, representing the terminal 1805 3' nt of the genome, whereas bovine serum albumin and allantoic fluid protein did not bind to labeled G RNA. Competitive gel shift assays with labeled G RNA indicated that the protein interacted with several unlabeled RNA representing sequences at the 3' noncoding end of the IBV genome. Cache Valley virus (a bunyavirus) mRNA transcribed from the small segment cDNA also inhibited the interaction with IBV G RNA to approximately the same extent as homologous unlabeled G RNA, whereas reactions with bovine liver RNA and yeast tRNA were considerably weaker. Whereas yeast tRNA did not inhibit the interaction with the labeled large G RNA, interactions of the fusion protein with EF, a region from 78 to 217 nt from the 3' terminus of the IBV genome, were also apparently weaker than interactions with fragment CD which consisted of the 3' terminal 155 nt. On a molar basis, the latter interacted in an identical nature to a RNA consisting of CD and an additional 1053 nt of plasmid sequences. Compared to bovine liver RNA, unlabeled G specifically inhibited binding to the two smaller labeled IBV fragments in gel shift assays. The binding of IBV nucleocapsid protein with RNA probably requires specific sequences and/or structures that are present on the genome, and may represent a common mechanism used by similar viral nucleoproteins whose functions depend on binding to RNA.
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