Biological characterization of a simian immunodeficiency virus-like retrovirus (HTLV-IV): evidence for CD4-associated molecules required for infection

We have analyzed a number of biological features of HTLV-IV, a retrovirus indistinguishable from a macaque isolate of simian immunodeficiency virus (SIV), and compared this virus with several strains of human immunodeficiency virus type 1 (HIV-1). Although HTLV-IV was found to be similar to HIV-1 in its tropism for CD4+ lymphocytes, its effects on CD4 expression and the ability of its externalized envelope molecule to form a complex directly with the CD4 molecule, a number of striking differences were noted. Unlike with HIV-1, the range of cells susceptible to HTLV-IV infection and syncytia formation was restricted to a subset of CD4+ cell lines, particularly those that coexpressed CD4 with human leukocyte antigen (HLA) class II antigens. An analysis of the patterns of HTLV-IV infection with B x T somatic cell hybrids indicated that for this virus, molecules in addition to CD4 were probably required to facilitate infection and cell fusion. Additional studies of HTLV-IV infection of Sup-T1 cells, which are exquisitely sensitive to cytopathic effects induced by HIV-1, demonstrated that HTLV-IV infection could occur in the absence of cytopathic effects and, remarkably, with minimal or no downmodulation of the CD4 molecule from the cell surface. The failure of HTLV-IV infection to reduce the expression of several CD4 epitopes suggested that the HTLV-IV envelope produced by Sup-T1 cells was altered in its ability to interact with or bind to CD4. Additional differences were also noted in the size of the transmembrane envelope molecule of HTLV-IV produced by Sup-T1 cells, indicating that cell-specific alterations in processing of the HTLV-IV envelope occurred during the production of virus in this cell line. Understanding the basis for these biological differences between HTLV-IV and the HIV-1 viruses may help to elucidate more general mechanisms for pathogenesis of other members of the SIV and HIV families of retroviruses.     

Chromatographic Study of Spirosin by Use of Monoclonal Antibodies to Spirosin of Yersinia enterocolitica

Two monoclonal antibodies (MAbs) reacting with spirosins from Enterobacteriaceae were obtained in a course of screening MAbs to spirosin from Yersinia enterocolitica SYT-11-72 (YE72). The antibodies were designated MAbs-S44 and S50. They were IgG_2b and IgG_2a, respectively, both with k light chains. On Western blotting after limited proteolysis of YE72 spirosin with Staphylococcus aureus V8 protease, they reacted markedly with peptide fragments of 27 and 35 kDa, suggesting the presence of an antigenic determinant on the fragments. When supernatant cell lysate from Escherichia coli K12 was chromatographed on DEAE-cellulose and Sepharose CL-6B columns successively, a 96-kDa protein with alcohol dehydrogenase (ADH) activity was always associated with reactivity to MAb-S50. These findings combined with N-terminal amino acid sequences clearly indicate the identity of spirosin to ADH in E. coli.     

Ribonucleoprotein Y-box-binding protein-1 regulates mitochondrial oxidative phosphorylation (OXPHOS) protein expression after serum stimulation through binding to OXPHOS mRNA

Mitochondria play key roles in essential cellular functions, such as energy production, metabolic pathways and aging. Growth factor-mediated expression of the mitochondrial OXPHOS (oxidative phosphorylation) complex proteins has been proposed to play a fundamental role in metabolic homoeostasis. Although protein translation is affected by general RNA-binding proteins, very little is known about the mechanism involved in mitochondrial OXPHOS protein translation. In the present study, serum stimulation induced nuclear-encoded OXPHOS protein expression, such as NDUFA9 [NADH dehydrogenase (ubiquinone) 1α subcomplex, 9, 39 kDa], NDUFB8 [NADH dehydrogenase (ubiquinone) 1β subcomplex, 8, 19 kDa], SDHB [succinate dehydrogenase complex, subunit B, iron sulfur (Ip)] and UQCRFS1 (ubiquinol-cytochrome c reductase, Rieske iron-sulfur polypeptide 1), and mitochondrial ATP production, in a translation-dependent manner. We also observed that the major ribonucleoprotein YB-1 (Y-box-binding protein-1) preferentially bound to these OXPHOS mRNAs and regulated the recruitment of mRNAs from inactive mRNPs (messenger ribonucleoprotein particles) to active polysomes. YB-1 depletion led to up-regulation of mitochondrial function through induction of OXPHOS protein translation from inactive mRNP release. In contrast, YB-1 overexpression suppressed the translation of these OXPHOS mRNAs through reduced polysome formation, suggesting that YB-1 regulated the translation of mitochondrial OXPHOS mRNAs through mRNA binding. Taken together, our findings suggest that YB-1 is a critical factor for translation that may control OXPHOS activity.     

Comparison between Holstein cow's milk and Japanese-Saanen goat's milk in fatty acid composition, lipid digestibility and protein profile

The fatty acid composition, the lipid digestibility and protein profile of Japanese-Saanen goat's milk were characterized. Caprine milk contained substantial quantities of C(4:0) to C(10:0) fatty acids as compared with Holstein cow's milk. The lipids of the former showed significantly higher digestibility in vitro by porcine lipase than those of the latter (P<0.05). As determined by SDS-PAGE, the respective contents of alpha(s1)-casein, one of the major allergens, were 3.9% and 33.7% in caprine and bovine milk.     

Involvement of the Escherichia coli folate-binding protein YgfZ in RNA modification and regulation of chromosomal replication initiation

The Escherichia coli hda gene codes for a DnaA-related protein that is essential for the regulatory inactivation of DnaA (RIDA), a system that controls the initiation of chromosomal replication. We have identified the ygfZ gene, which encodes a folate-binding protein, as a suppressor of hda mutations. The ygfZ null mutation suppresses an hda null mutation. The over-initiation and abortive elongation phenotypes conferred by the hda mutations are partially suppressed in an hda ygfZ background. The accumulation of the active form of DnaA, ATP-DnaA, in the hda mutant is suppressed by the disruption of the ygfZ gene, indicating that YgfZ is involved in regulating the level of ATP-DnaA. Although ygfZ is not an essential gene, the ygfZ disruptant grows slowly, especially at low temperature, demonstrating that this gene is important for cellular proliferation. We have identified mnmE (trmE) as a suppressor of the ygfZ disruption. This gene encodes a GTPase involved in tRNA modification. Examination of RNA modification in the ygfZ mutant reveals reduced levels of 2-methylthio N(6)-isopentenyladenosine [corrected] indicating that YgfZ participates in the methylthio-group formation of this modified nucleoside in some tRNAs. These results suggest that YgfZ is a key factor in regulatory networks that act via tRNA modification.     

A structural requirement for processing the cardiac K+ channel KCNQ1

Normal membrane protein function requires trafficking from the endoplasmic reticulum. Here, we studied processing of the KCNQ1 channel mutated in LQT1, the commonest form of the long QT syndrome. Serial C terminus truncations identified a small region (amino acids (aa) 610-620) required for normal cell surface expression. Non-trafficked truncations assembled as tetramers but were nevertheless retained in the endoplasmic reticulum. Further mutagenesis did not identify specific residues mediating channel processing; cell surface expression was preserved with the mutation of known trafficking motifs in the channel and with alanine scanning across aa 610-620. Structural prediction algorithms place aa 610-620 at the C-terminal end of an alpha-helix (aa 586-618) that includes a leucine zipper and is part of a coiled coil. Mutants disrupting the leucine zipper but preserving the predicted coiled coil reached the cell surface, whereas those disrupting the coil did not. These data suggest that specific protein-protein interactions are required for normal channel processing. Further biochemical studies ruled out three candidate proteins, namely KCNE1, yotiao, and KCNQ1 itself, as effectors of this coiled coil-mediated trafficking. Four LQT1 mutations within this helix generated little or no current and were not expressed on the cell surface, whereas LQT1 mutations in adjacent residues, which produce a milder clinical phenotype, generate only slightly reduced current and are expressed on the cell surface. These data suggest that mutations within this domain cause human disease by interfering with normal channel processing. More generally, we have identified a domain whose structural integrity is required for normal surface expression of the KCNQ1 channel.