Novel pentameric structure of the diarrhea-inducing region of the rotavirus enterotoxigenic protein NSP4

A novel pentameric structure which differs from the previously reported tetrameric form of the diarrhea-inducing region of the rotavirus enterotoxin NSP4 is reported here. A significant feature of this pentameric form is the absence of the calcium ion located in the core region of the tetrameric structures. The lysis of cells, the crystallization of the region spanning residues 95 to 146 of NSP4 (NSP4(95-146)) of strain ST3 (ST3:NSP4(95-146)) at acidic pH, and comparative studies of the recombinant purified peptide under different conditions by size-exclusion chromatography (SEC) and of the crystal structures suggested pH-, Ca(2+)-, and protein concentration-dependent oligomeric transitions in the peptide. Since the NSP4(95-146) mutant lacks the N-terminal amphipathic domain (AD) and most of the C-terminal flexible region (FR), to demonstrate that the pentameric transition is not a consequence of the lack of the N- and C-terminal regions, glutaraldehyde cross-linking of the ΔN72 and ΔN94 mutant proteins, which contain or lack the AD, respectively, but possess the complete C-terminal FR, was carried out. The results indicate the presence of pentamers in preparations of these longer mutants. Detailed SEC analyses of ΔN94 prepared under different conditions, however, revealed protein concentration-dependent but metal ion- and pH-independent pentamer accumulation at high concentrations which dissociated into tetramers and lower oligomers at low protein concentrations. While calcium appeared to stabilize the tetramer, magnesium in particular stabilized the dimer. ΔN72 existed primarily in the multimeric form under all conditions. These findings of a calcium-free NSP4 pentamer and its concentration-dependent and largely calcium-independent oligomeric transitions open up a new dimension in an understanding of the structural basis of its multitude of functions.     

Antigenic analysis of nonstructural protein (NSP) 4 of group A avian rotavirus strain PO-13

In order to analyze the antigenic structure of nonstructural protein (NSP) 4 of group A avian rotavirus strain PO-13, 25 monoclonal antibodies (MAbs) against NSP4 expressed in Escherichia coli were produced. All MAbs reacted with NSP4 on Western blotting, indicating that they recognized sequential epitopes. To determine the antigenic sites (ASs) recognized by the produced MAbs, seven truncated NSP4s were expressed in E. coli. Western blotting analysis showed that there are at least four major ASs on PO-13 NSP4, designated as AS I located in amino acids (aa) 151 to 169, AS II (aa 136 to 150), AS III (aa 112 to 133) and AS IV (aa 1 to 24). Two MAbs reacted exclusively with AS III encompassing the region that has been reported to be an enterotoxin domain. MAbs against ASs II, III and IV reacted with all avian rotaviruses tested by indirect immunofluorescent antibody assays. MAbs against AS I reacted with turkey strains, Ty-1 and Ty-3, but not with a chicken strain, Ch-1. Nine of 11 MAbs against AS II cross-reacted with NSP4 of mammalian rotavirus strains with different NSP4 genotypes. These results suggest that AS II on NSP4 is widely conserved among a variety of rotaviruses.     

Molecular characterization of two strains of porcine group C rotavirus

Group C rotaviruses are an important cause of acute gastroenteritis in humans and animals. Fecal samples were collected from a porcine herd in July, 2009. Group C rotavirus RNA was detected using RT-PCR for the VP6 gene. The identified strain was further characterized by sequencing and phylogenetic analysis of the partial VP4, and complete VP6 and VP7 gene sequences. The partial VP4 and complete VP6 gene sequences of the CUK-5 strain were most closely related to those of the CUK-6 strain of group C rotaviruses. Phylogenetic analysis of the VP7 gene of the 2 strains (CUK-5 and CUK-6) and reference strains of group G rotavirus by the neighbor-joining method also confirmed that CUK-5 and CUK-6 belonged to type G5 and G1 strains, respectively. This study provides useful data for the prediction of newly appearing variants of porcine group C rotaviruses in neighboring countries through comparisons with GCRVs and fundamental research for vaccine development.     

Attenuation of a human rotavirus vaccine candidate did not correlate with mutations in the NSP4 protein gene.

The NSP4 protein of a simian rotavirus was reported to induce diarrhea following inoculation of mice. If NSP4 is responsible for rotavirus diarrhea in humans, attenuation of a human rotavirus may be reflected in concomitant mutations in the NSP4 gene. After 33 passages in cultured monkey kidney cells, a virulent human rotavirus (strain 89-12) was found to be attenuated in adults, children, and infants. Nucleotide sequence analysis of the NSP4 protein gene revealed only one base pair change between the virulent (unpassaged) and attenuated 89-12 viruses, which resulted from a substitution of alanine for threonine at amino acid 45 of the encoded NSP4 protein. Because both threonine and alanine have been found at position 45 of NSP4 in symptomatic and asymptomatic human rotaviruses, neither amino acid in this position could be established as a marker of virulence. Therefore, attenuation of rotavirus strain 89-12 appears to be unrelated to mutations in the NSP4 gene.     

Comparative molecular characterization of gene segment 11-derived NSP6 from lamb rotavirus LLR strain used as a human vaccine in China

Sequence-length polymorphism is known for rotavirus genetic segment 11 (encodes non-structural protein, NSP6). With the exception of 11 strains that have the coding potential for a 98-residue NSP6, majority of the strains have the potential for a 92-residue NSP6. In nine strains, the coding potential for this protein is even shorter. This report focuses on the NSP6 gene nucleotide sequence of Lanzhou Lamb Rotavirus (LLR) strain and its comparative molecular characterization. The LLR strain is a G10 P12 type, which is in use as a licensed human vaccine in China. The LLR NSP6 was compared with 56 other rotaviral NSP6 sequences including a rhesus strain (RRV) available in the database. Analyses indicate that while RRV-NSP6 belongs to the majority (92-residue) group, the LLR NSP6 belongs to the 98-residue group. When the rotavirus NSP6 protein was expressed in cells as GFP fusion protein from human, simian and the LLR strains, they all demonstrated punctate cytoplasmic distribution and, contrary to the computer-aided prediction, the NSP6 did not undergo phosphorylation, which in itself is a novel observation for the rotavirus NSP6.     

Diarrhea-inducing activity of avian rotavirus NSP4 glycoproteins, which differ greatly from mammalian rotavirus NSP4 glycoproteins in deduced amino acid sequence in suckling mice

Avian rotavirus NSP4 glycoproteins expressed in Escherichia coli acted as enterotoxins in suckling mice, as did mammalian rotavirus NSP4 glycoproteins, despite great differences in the amino acid sequences. The enterotoxin domain of PO-13 NSP4 exists in amino acid residues 109 to 135, a region similar to that reported in SA11 NSP4.     

婴幼儿腹泻A群轮状病毒G和P的基因分型研究

目的研究浙江萧山医院婴幼儿童腹泻标本中人轮状病毒（Human Rotavims）毒株的感染情况及G和P基因型流行特点。方法收集该院2009年8月至2010年8月腹泻儿童15233份粪便标本采用酶联免疫吸附试验、逆转录-巢式聚合酶链反应进行轮状病毒病原检测,将128份阳性标本进行VP7和VP4基本分型。结果15233份婴幼儿腹泻标本中有2706份标本为轮状病毒阳性,阳性率17．8％;男孩和女孩检出率差异无统计学意义,以6-12月龄段检出率最高;对128份阳性标本进行G血清分型和P基因分型,G1型53份（41．4％）、G3型38份（29．7％）、G1G3型17份（13．3％）、G未分型20份（15．6％）;P[8]型72份（56．3％）、P[4]型16份（12．5％）、P[8]P[4]型3份（2．3％）、P未分型37份（28．9％）,G血清型和P基因型的组合以G1P[8]为主,占29．7％（38／128）。结论浙江萧山医院A群轮状病毒G血清以G1型为主,其次为G3型,P基因型以P[8]型为主。     

Identification and characterization of the helix-destabilizing activity of rotavirus nonstructural protein NSP2

The rotavirus nonstructural protein NSP2 self-assembles into homomultimers, binds single-stranded RNA nonspecifically, possesses a Mg2+-dependent nucleoside triphosphatase (NTPase) activity, and is a component of replication intermediates. Because these properties are characteristics of known viral helicases, we examined the possibility that this was also an activity of NSP2 by using a strand displacement assay and purified bacterially expressed protein. The results revealed that, under saturating concentrations, NSP2 disrupted both DNA-RNA and RNA-RNA duplexes; hence, the protein possesses helix-destabilizing activity. However, unlike typical helicases, NSP2 required neither a divalent cation nor a nucleotide energy source for helix destabilization. Further characterization showed that NSP2 displayed no polarity in destabilizing a partial duplex. In addition, helix destabilization by NSP2 was found to proceed cooperatively and rapidly. The presence of Mg2+ and other divalent cations inhibited by approximately one-half the activity of NSP2, probably due to the increased stability of the duplex substrate brought on by the cations. In contrast, under conditions where NSP2 functions as an NTPase, its helix-destabilizing activity was less sensitive to the presence of Mg2+, suggesting that in the cellular environment the two activities associated with the protein, helix destabilization and NTPase, may function together. Although distinct from typical helicases, the helix-destabilizing activity of NSP2 is quite similar to that of the sigmaNS protein of reovirus and to the single-stranded DNA-binding proteins (SSBs) involved in double-stranded DNA replication. The presence of SSB-like nonstructural proteins in two members of the family Reoviridae suggests a common mechanism of unwinding viral mRNA prior to packaging and subsequent minus-strand RNA synthesis.     

The rotavirus nonstructural glycoprotein NSP4 mobilizes Ca2+ from the endoplasmic reticulum.

We previously reported that expression of rotavirus nonstructural glycoprotein NSP4 is responsible for an increase in cytosolic free Ca2+ concentration ([Ca2+]i) in Spodoptera frugiperda (Sf9) insect cells (P. Tian, Y. Hu, W. P. Schilling, D. A. Lindsay, J. Eiden, and M. K. Estes, J. Virol. 68:251-257, 1994). The purpose of the present study was to determine the mechanism by which NSP4 causes an increase in [Ca2+]i by measuring the permeability of the cytoplasmic and endoplasmic reticulum (ER) membranes in recombinant-baculovirus-infected Sf9 cells. No obvious change in plasmalemma permeability to divalent cations was observed in cells expressing NSP4 compared with that in cells expressing another rotaviral glycoprotein (VP7) when the influx of Ba2+, a Ca2+ surrogate, was monitored. The basal Ca2+ permeability of the internal Ca2+ store was evaluated by measuring the release of Ca2+ induced by ionomycin, a Ca2+ ionophore, or thapsigargin, an inhibitor of the ER Ca(2+)-ATPase pump, following suspension of the cells in Ca(2+)-free extracellular buffer. Releasable Ca2+ decreased with time to a greater extent in cells expressing NSP4 compared with that in cells expressing VP7, suggesting that NSP4 increases the basal Ca2+ permeability of the ER membrane. To determine the possible mechanism by which NSP4 increases ER permeability, purified NSP4 protein or a 22-amino-acid synthetic peptide consisting of residues 114 to 135 (NSP4(114-135) was added exogenously to noninfected Sf9 cells during measurement of [Ca2+]i. Both NSP4 and the NSP4(114-135 peptide produced a time-dependent increase in [Ca2+]i that was attenuated by prior inhibition of phospholipase C with U-73122. Pretreatment of the cells with thapsigargin completely blocked the increase in [Ca2+]i produced by NSP4(114-135, but the peptide only partially reduced the change in [Ca2+]i produced by thapsigargin. No changes in [Ca2+]i were seen in cells treated with control peptides. These results suggest that (i) exogenous NSP4 increases [Ca2+]i through the activation of phospholipase C, (ii) Ca2+ release by exogenous NSP4 is from a store that is a subset of the thapsigargin-sensitive compartment, and (iii) amino acid residues 114 to 135 of NSP4 are sufficient for this activity. In contrast to exogenous NSP4, the mechanism by which endogenously expressed NSP4 increases [Ca2+]1 appears to be unrelated to phospholipase C, since no effect of U-73122 was seen on the elevated [Ca2+]1 in cells expressing NSP4 and exogenously applied NSP4(114-135) caused a further increase in [Ca2+]1 in cells expressing NSP4 protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Crystal structure of the oligomerization domain of NSP4 from rotavirus reveals a core metal-binding site

During the maturation of rotaviral particles, non-structural protein 4 (NSP4) plays a critical role in the translocation of the immature capsid into the lumen of the endoplasmic reticulum. Full-length NSP4 and a 22 amino acid peptide (NSP4(114-135)) derived from this protein have been shown to induce diarrhea in young mice in an age-dependent manner, and may therefore be the agent responsible for rotavirally-induced symptoms. We have determined the crystal structure of the oligomerization domain of NSP4 which spans residues 95 to 137 (NSP4(95-137)). NSP4(95-137) self-associates into a parallel, tetrameric coiled-coil, with the hydrophobic core interrupted by three polar layers occupying a and d-heptad positions. Side-chains from two consecutive polar layers, consisting of four Gln123 and two of the four Glu120 residues, coordinate a divalent cation. Two independent structures built from MAD-phased data indicated the presence of a strontium and calcium ion bound at this site, respectively. This metal-binding site appears to play an important role in stabilizing the homo-tetramer, which has implications for the engagement of NSP4 as an enterotoxin.     

Molecular characterization of human T-cell lymphotropic virus coinfecting human immunodeficiency virus 1 infected patients in the Amazon region of Brazil

The present work evaluated the epidemiology of human immunodeficiency virus 1/human T-cell lymphotropic virus (HIV-1/HTLV) coinfection in patients living in Belém (state of Pará) and Macapá (state of Amapá), two cities located in the Amazon region of Brazil. A total of 169 blood samples were collected. The sera were tested by enzyme-linked immunosorbent assay to determine the presence of antibodies anti-HTLV-1/2. Confirmation of infection and discrimination of HTLV types and subtypes was performed using a nested polymerase chain reaction targeting the pX and 5' LTR regions, followed by restriction fragment length polymorphism and sequencing analysis. The presence of anti-HTLV1/2 was detected in six patients from Belém. The amplification of the pX region followed by RFLP analysis, demonstrated the presence of HTLV-1 and HTLV-2 infections among two and four patients, respectively. Sequencing HTLV-1 5' LTR indicated that the virus is a member of the Cosmopolitan Group, Transcontinental subgroup. HTLV-2 strains isolated revealed a molecular profile of subtype HTLV-2c. These results are a reflex of the epidemiological features of HIV-1/HTLV-1/2 coinfection in the North region of Brazil, which is distinct from other Brazilian regions, as reported by previous studies.     

Porcine rotavirus bearing an aberrant gene stemming from an intergenic recombination of the NSP2 and NSP5 genes is defective and interfering

Serial undiluted passage of a porcine rotavirus in MA104 cells yielded three distinct virus populations, each of which bore different rearranged genes. Sequencing revealed that each of two populations bore a distinct intragenic recombinant NSP3 gene consisting of a partial duplication in a head-to-tail orientation without altering the NSP3 open reading frame and the third population carried both an intragenic recombinant NSP3 gene and an intergenic recombinant gene (1,647 nucleotides in length) which contained a truncated NSP2 gene inserted into the NSP5 gene at residue 332. The former two populations were viable, whereas the latter population was defective and interfering.     

Molecular epidemiology and clinical characterization of group A rotavirus infections in Tunisian children with acute gastroenteritis

Rotaviruses are the most common cause of severe viral gastroenteritis in early childhood worldwide. Thus, the objectives of our study were to determine the molecular epidemiology and the clinical features of rotavirus gastroenteritis in Tunisia. Between January 2003 and April 2007, a prospective study was conducted on 788 stool samples collected from children under 12 years of age who were suffering from acute gastroenteritis. Rotavirus was detected by multiplex RT-PCR in 27% (n = 213) of samples, among them 79.3% (n = 169) cases were monoinfections. The frequency of rotavirus infections was significantly higher among inpatients (29%) than among outpatients (13%) (P < 0.001). The seasonal distribution of rotavirus diarrhea showed a winter peak, with an unusual peak from June to September. The mean duration of hospitalization was 6.5 ± 8.1 days and the mean age was 15.8 ± 22.8 months for rotavirus monoinfections. Fever, vomiting, abdominal pain, and dehydration were observed in 88, 98, 13, and 80 cases, respectively, in children with rotavirus monoinfections. G3P[8] (45.6%) and G1P[8] (23.9%) were the most common genotypes found in our study. The determination of rotavirus infection prevalence and the characterization of the rotavirus strains circulating will help us to better understand the molecular biology and epidemiology of the disease in our country.