GP96 Interacts with HHV-6 during Viral Entry and Directs It for Cellular Degradation

CD46 and CD134 mediate attachment of Human Herpesvirus 6A (HHV-6A) and HHV-6B to host cell, respectively. But many cell types interfere with viral infection through rapid degradation of viral DNA. Hence, not all cells expressing these receptors are permissive to HHV-6 DNA replication and production of infective virions suggesting the involvement of additional factors that influence HHV-6 propagation. Here, we used a proteomics approach to identify other host cell proteins necessary for HHV-6 binding and entry. We found host cell chaperone protein GP96 to interact with HHV-6A and HHV-6B and to interfere with virus propagation within the host cell. In human peripheral blood mononuclear cells (PBMCs), GP96 is transported to the cell surface upon infection with HHV-6 and interacts with HHV-6A and -6B through its C-terminal end. Suppression of GP96 expression decreased initial viral binding but increased viral DNA replication. Transient expression of human GP96 allowed HHV-6 entry into CHO-K1 cells even in the absence of CD46. Thus, our results suggest an important role for GP96 during HHV-6 infection, which possibly supports the cellular degradation of the virus.     

Development and evaluation of human T‐cell leukemia virus‐1 and ‐2 multiplex quantitative PCR

The diagnosis of human T ‐cell leukemia virus type 1 (HTLV‐1) infection in Japan is usually performed by serological testing, but the high rate of indeterminate results from western blotting makes it difficult to assess the infection accurately. Nucleic acid tests for HTLV‐1 and/or HTLV‐2 are used to confirm infection with HTLV‐1 and/or HTLV‐2 and are also used for the follow‐up of HTLV‐1 related diseases. To prepare a highly sensitive method that can discern infection with HTLV‐1 and HTLV‐2, a multiplex quantitative polymerase chain reaction (qPCR) by large‐scale primer screening was developed. Sensitivity and specificity were evaluated by serial dilution of cell lines and by testing with known clinical samples. The resulting multiplex qPCR can detect about four copies of HTLV‐1 provirus per 10⁵ cells. Moreover, HTLV‐1 provirus could be detected in 97.2% (205 of 211) of HTLV‐1 seropositive clinical samples. These sensitivities were sufficiently high compared with the methods reported previously. Also, all the HTLV‐2 seropositive clinical samples tested were found to be positive by this method (three of three). In conclusion, this method can successfully and simultaneously detect both types of HTLV‐1 and HTLV‐2 provirus with extremely high sensitivity.     

The Effects of Temperature and pH on the Growth of Eight Enteric and Nine Glucose Non-Fermenting Species of Gram-Negative Rods

We studied the heat resistance and the range of growth temperature o gram-negative rods to find one of the bacterial factors governing their infectivity in exogenous and endogenous infections in predisposed patients. Escherichia coli, Klebsiella pneumoniae, Serratia marcescens, Pseudomonas aeruginosa, and Acinetobacter calcoaceticus grew equally well at 25, 30, 37, and 42 C. Among other sugar non-fermenting gram-negative rods, six species showed suppressed growth at either or both ends of the incubation temperature range. All the bacterial species tested were killed within 30 min at 60 or 70 C. At 10 C, none of the bacterial strains multiplied, but all survived for 6 hr. Of 17 bacterial species tested, E. coli had the widest range of growth temperature (18–47 C), and also the shortest time necessary for growth to a certain population. Among the sugar non-fermenting rods, A. calcoaceticus had the widest range of growth temperature (20–45 C) and also multiplied rapidly. Pseudomonas strains exhibited slower growth at all temperatures and also had a narrower range of growth temperature than Enterobacteriaceae. Among Pseudomonas species, P. aeruginosa had the widest range of growth temperature (25–42 C) and also showed rapid growth. Pseudomonas cepacia, Achromobacter xylosoxidans, and Alcaligenes faecalis had a narrow range of growth temperature (28–37 C), and Pseudomonas fluorescens, Flavobacterium meningosepticum, and Moraxella grew most rapidly at 30 C. The above results are correlated fairly well with the incidence of clinical cases of infection. The growth attitude of a species of bacteria in response to temperature was considered to be one of the factors affecting the establishment of infection.     

Involvement of anti-Ig-activated serine protease in the generation of cytoplasmic factor(s) that are responsible for the transmission of Ig-receptor-mediated signals.

Involvement of serine protease-activation in the generation of cytoplasmic factor(s) that induced NHP-specific protein kinase activity in nuclei in anti-Ig-stimulated cells was described. DFP or PMSF with anti-Ig inhibited the induction of cytoplasmic factor(s), whereas pretreatment of cells with DFP or PMSF without anti-Ig did not show any inhibitory effect on anti-Ig-induced generation of cytoplasmic factor(s). TAME or BAME with anti-Ig inhibited the generation of cytoplasmic factor(s) and the simultaneous addition of TAME or BAME with DFP protected the generation of cytoplasmic factor(s) against the inhibitory effect of DFP, showing the involvement of trypsin-like, arginine-type serine protease in anti-Ig-induced generation of cytoplasmic factor(s). Anti-Ig-stimulated membrane preparations induced cytoplasmic factor(s) in normal cytoplasm. The m.w. of precursor proteins present in resting B cells and active cytoplasmic factor(s) were approximately 150,000 and 45,000, respectively. These results showed that anti-Ig-activated membrane-bound serine protease split precursor proteins in resting B cells into active cytoplasmic factor(s) responsible for signal transmission.     

A hepatic soluble cyclic nucleotide-independent protein kinase. Stimulation by basic polypeptides.

Enzymatic phosphorylation of cytoplasmic proteins by a cyclic nucleotide-independent protein kinase (casein kinase of a classical type) in rat liver is stimulated greatly, sometimes more than 10-fold, by polycations, particularly by basic polypeptides such as polylysine, histone, and protamine. These basic polypeptides themselves do not serve as phosphate acceptors but act as stimulators for the reaction by interacting with cytoplasmic proteins rather than with enzyme. The stimulatory effect varies with substrates employed; with casein and phosvitin the stimulation does not exceed 2- to 3-fold. The cytoplasmic endogenous phosphate acceptor proteins measurable in the presence of basic polypeptides are abundant for this species of protein kinase.