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

Comparison of NSP4 protein between group A and B human rotaviruses: detection of novel diarrhea-causing sequences in group B NSP4

The human group B rotavirus is a causative agent of severe adult diarrhea. In this study, we analyzed the NSP4 structure of a group B rotavirus strain, CAL-1, and determined whether enterotoxin activity was present in CAL-1 NSP4. CAL-1 NSP4 was comprised of 219 amino acids which was longer than group A and C rotavirus NSP4, and the primary structures of their sequences differed considerably. However, CAL-1 NSP4 had an enterotoxin-like sequence (residues 106-127) that was only 27% identical to the enterotoxin region of NSP4 of KUN (a group A rotavirus strain) at residues 114-135. Interestingly, both of the synthetic peptides, one (residues 99-128) containing the enterotoxin-like sequence and the other (residues 191-219) containing 29 C-terminal amino acids of CAL-1 NSP4, induced diarrhea in 5.5-day-old mice, but not in 17.5-day-old mice, when administered parenterally. Thus, rotavirus "enterotoxin" sequences could be considerably divergent.

Interaction(s) of rotavirus non-structural protein 4 (NSP4) C-terminal peptides with model membranes

Rotavirus is the major cause of dehydrating gastroenteritis in children and young animals. NSP4 (non-structural protein 4), a rotaviral non-structural glycoprotein and a peptide NSP4(114-135) (DKLTTREIEQVELLKRIYDKLT), corresponding to NSP4 amino acids 114-135, induce diarrhoeal disease in a neonatal mouse model and interact with model membranes that mimic caveolae. Correlation of the mechanisms of diarrhoea induction and membrane interactions by NSP4 protein and peptide remain unclear. Several additional NSP4 peptides were synthesized and their interactions with membranes studied by (i) CD, (ii) a filtration-binding assay and (iii) a fluorescent molecule leakage assay. Model membranes that varied in lipid compositions and radius of curvature were utilized to determine the compositional and structural requirements for optimal interaction with the peptides of NSP4. Similar to the intact protein and NSP4(114-135), peptides overlapping residues 114-135 had significantly higher affinities to membranes rich in negatively charged lipids, rich in cholesterol and with a high radius of curvature. In the leakage assay, small and large unilamellar vesicles loaded with the fluorophore/quencher pair 8-aminonaphthalene-1,3,6-trisulphonic acid disodium salt/p -xylene-bis-pyridinium bromide were incubated with the NSP4 peptides and monitored for membrane disruption by lipid reorganization or by pore formation. At a peptide concentration of 15 microM, none of the NSP4 peptides caused leakage. These results confirm that NSP4 interacts with caveolae-like membranes and the alpha-helical region of NSP4(114-135) comprises a membrane interaction domain that does not induce membrane disruption at physiological concentrations.

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.

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Detailed computational analysis of a comprehensive set of group A rotavirus NSP4 proteins

Rotavirus infection causes diarrhea to humans, animals and birds. The NSP4 protein of Group A rotavirus has been recognized as a viral enterotoxin. This single protein plays important roles in viral pathogenesis and morphogenesis. Domains involved in structure and biologic functions have been proposed mainly based on the SA11 strain, a prototype of group A rotavirus. NSP4 has been classified into different genotypes based on sequence homology. These analyses are based on representative strains selected but not comprehensive. In this paper, we collected all NSP4 sequences in the GenBank and performed a detailed computational analysis. Our analysis of 176 NSP4 proteins in Groups A, B and C rotaviruses confirms that the recently published avian NSP4 sequences belong to a new genotype (Mori Y., Borgan M.A., Ito N., Sugiyama M. and Minamoto N., Virus Res 89, 145-151, 2002), besides the four known NSP4 genotypes of Group A mammalian rotaviruses. Significant differences were discovered in the physicochemical properties between the avian and mammalian NSP4 proteins. In particular, lack of a highly probable coiled-coil region in the avian sequences implies a diversion of the NSP4 quaternary structure from the latter, although the secondary and tertiary structures may be similar. Fourteen amino acids are found absolutely conserved in the Group A NSP4 sequences, regardless of genotype. Of the conserved residues, two are glycosylation sites, one is in the middle of the transmembrane segment, seven span the VP4 binding domain, and five are clustered in the middle of the toxic peptide region, indicating the functional importance of the conservation.

Sequential analysis of nonstructural protein NSP4s derived from Group A avian rotaviruses

We determined the NSP4 sequences of turkey rotavirus strains Ty-1 and Ty-3 and a chicken rotavirus, strain Ch-1, and compared these sequences with those of a pigeon rotavirus, strain PO-13, and mammalian rotaviruses. The turkey strains and PO-13 were found to be closely related (90-97% homologies). Ch-1 NSP4 was distinctly different from other avian rotavirus NSP4s, with 78-79% homologies. The NSP4 sequences of avian rotaviruses were found to be 6-7 amino acids shorter than those of all mammalian strains and to have considerably low identities (31-37%) with them. Therefore, it seems highly likely that the NSP4 genes of avian rotaviruses are classified into two NSP4 genotypes distinct from those of mammalian rotaviruses. The enterotoxin domain in NSP4 is conserved in terms of its sequential and structural properties despite extremely low homologies in the full lengths of NSP4s in avian and mammalian rotaviruses.

Relaxation, equilibrium oligomerization, and molecular symmetry of the VASP (336-380) EVH2 tetramer

An investigation of the structural and dynamic properties of the C-terminal fragment of the human protein VASP (VASP 336-380) has been performed. Full length VASP has been shown to be tetrameric in solution, and the C-terminal 45 residues of the protein have been suggested to be responsible for the oligomerization. We have expressed and purified a C-terminal fragment of the human VASP protein from residue 336-380. It was found to form a stable domain in its own right. The fragment was shown by CD spectroscopy to form a helical structure, stable under a wide range of temperature and pH conditions. A (15)N-HSQC-experiment exhibits only one set of peaks, suggesting a high degree of symmetry for a putative oligomer. Measurements of the rotational correlation time tau(C) of the molecule and analytical ultracentrifugation data show VASP (336-380) to be entirely tetrameric in solution. The secondary structure was confirmed from a (15)N-NOESY-HSQC experiment and is completely alpha-helical. We conclude that VASP (336-380) forms a tetramer in solution via a coiled coil arrangement and is solely responsible for tetramerization of full-length VASP.

Systemic and intestinal antibody responses to NSP4 enterotoxin of Wa human rotavirus in a gnotobiotic pig model of human rotavirus disease

Antibody responses to the Wa human rotavirus (HRV) nonstructural protein NSP4, a viral enterotoxin, were evaluated in neonatal gnotobiotic (Gn) pigs. Gn pigs were inoculated orally with one dose of 10(5) fluorescent focus units (FFU) of virulent Wa HRV (HRV-V), to mimic natural infection, or with three doses of 5 x 10(7) FFU attenuated Wa HRV (HRV-A) at 10-day intervals, to mimic oral attenuated rotavirus vaccines, or they were mock inoculated (mock). Subsets of pigs were challenged with 10(6) FFU of virulent Wa HRV at post-inoculation day 28 (PID 28). Post-challenge, the HRV-V pigs were completely protected against diarrhea and virus shedding, whereas the HRV-A pigs had a 50% protection rate against diarrhea and a 67% protection rate against virus shedding. All mock-inoculated pigs shed virus and had diarrhea post-challenge. Isotype antibody titers to NSP4 were compared in serum and intestinal contents, at post-inoculation day (PID) 28 and at post-challenge day 7 (PCD 7/PID 35) by indirect ELISA, using purified recombinant NH2-6xHis-tagged NSP4 of virulent Wa HRV. Pre-challenge, both the HRV-V and HRV-A-inoculated pigs had similar moderate titers of serum IgG antibodies to NSP4. However, only the HRV-V-inoculated pigs developed detectable serum and intestinal IgA antibody titers to NSP4 pre-challenge, compared with the HRV-A-inoculated pigs. The mock-inoculated pigs had no IgM, IgA, or IgG antibodies to NSP4 pre-challenge. All Wa HRV-inoculated pigs developed low to moderate titers of serum IgM, IgG, and IgA antibodies to NSP4 post-challenge, but the mock-inoculated pigs had only IgM antibodies post-challenge. Both Wa HRV-inoculated groups developed low titers of IgA antibody to NSP4 in the small intestinal contents post-challenge, but titers were 5.8-fold higher in the HRV-V pigs. Our results concur with findings that both rotavirus vaccinated and naturally infected children seroconvert with modest IgG antibodies to NSP4 [Johansen et al. (1999) J Med Virol 59:369-367]. These data suggest that Gn pigs could be a useful model to evaluate serum and intestinal IgA antibodies to NSP4 and their role in protection against HRV infection. Further experiments may clarify whether (1) the NSP4 antibodies detected pre-challenge in the HRV-V pigs contribute to the higher protection rates observed, or (2) the reduced or delayed NSP4 antibody responses of the HRV-A pigs are associated with the lower protection rates in these pigs.

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.

Microbes and microbial toxins: paradigms for microbial-mucosal interactions. VIII. Pathological consequences of rotavirus infection and its enterotoxin

Rotaviral infection in neonatal animals and young children leads to acute self-limiting diarrhea, but infected adults are mainly asymptomatic. Recently, significant in-roads have been made into our understanding of this disease: both viral infection and virally manufactured nonstructural protein (NSP)4 evoke intracellular Ca(2+) ([Ca(2+)]i) mobilization in native and transformed gastrointestinal epithelial cells. In neonatal mouse pup mucosa models, [Ca(2+)]i elevation leads to age-dependent halide ion movement across the plasma membrane, transepithelial Cl(-) secretion, and, unlike many microbial enterotoxins, initial cyclic nucleotide independence to secretory diarrhea. Similarities between rotavirus infection and NSP4 function suggest that NSP4 is responsible for these enterotoxigenic effects. NSP4-mediated [Ca(2+)]i mobilization may further facilitate diarrhea by signaling through other Ca(2+)-sensitive cellular processes (cation channels, ion and solute transporters) to potentiate fluid secretion while curtailing fluid absorption. Apart from these direct actions in the mucosa at the onset of diarrhea, innate host-mediated defense mechanisms, triggered by either or both viral replication and NSP4-induced [Ca (2+)]i mobilization, sustain the diarrheal response. This secondary component appears to involve the enteric nervous system and may be cyclic nucleotide dependent. Both phases of diarrhea occur in the absence of significant inflammation. Thus age-dependent rotaviral disease represents an excellent experimental paradigm for understanding a noninflammatory diarrhea.