Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
Disease
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Query: UMLS:C0017160 (
gastroenteritis
)
11,398
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Rotaviruses, members of family Reoviridae, are a major cause of acute
gastroenteritis
of infants and young children. The rotavirus genome consists of 11 segments of double-stranded (ds)RNA and the virion is an icosahedron composed of multiple layers of protein. The virion core is formed by a layer of VP2 and contains multiple copies of the RNA-dependent RNA polymerase VP1 and the mRNA-capping enzyme VP3. Double-layered particles (DLPs), representing cores surrounded by a layer of VP6, direct the synthesis of viral mRNAs. Rotavirus core- and DLP-like replication intermediates (RIs) catalyze the synthesis of dsRNA from viral template mRNAs coincidentally with the packaging of the mRNAs into the pre-capsid structures of RIs. In addition to structural proteins, the nonstructural proteins NSP2 and NSP5 are components of RIs with replicase activity. NSP2 self assembles into octameric structures that have affinity for ssRNA and
NTPase
and helix-destabilizing activites. Its interaction with nucleotides induces a conformational shift in the octamer to a more condensed form. Phosphate residues generated by the
NTPase
activity are believed to be transferred from NSP2 to NSP5, leading to the hyperphosphorylation of the latter protein. It is suspected that the transfer of the phosphate group to NSP5 allows NSP2 to return to its noncondensed state and, thus, to accept another NTP molecule. The NSP5-mediated cycling of NSP2 from condensed to noncondensed combined with its RNA binding and helix-destabilizing activities are consistent with NSP2 functioning as a molecular motor to facilitate the packaging of template mRNAs into the pre-capsid structures of RIs. Similarities with the bluetongue virus protein NS2 and the reovirus proteins sigmaNS and micro2 suggest that they may be functional homologs of rotavirus NSP2 and NSP5.
...
PMID:Nonstructural proteins involved in genome packaging and replication of rotaviruses and other members of the Reoviridae. 1501 Feb 17
The genome of Sapovirus (SaV), a causative agent of
gastroenteritis
in humans and swine, contains either two or three open reading frames (ORFs). Functional motifs characteristic to the 2C-like
NTPase
(
NTPase
), VPg, 3C-like protease (Pro), 3D-like RNA-dependent RNA polymerase (Pol), and capsid protein (VP1) are encoded in the ORF1 polyprotein, which is afterwards cleaved into the nonstructural and structural proteins. We recently determined the complete genome sequence of a novel human SaV strain, Mc10, which has two ORFs. To investigate the proteolytic cleavage of SaV ORF1 and the function of protease on the cleavage, both full-length and truncated forms of the ORF1 polyprotein either with or without mutation in (1171)Cys to Ala of the GDCG motif were expressed in an in vitro coupled transcription-translation system. The translation products were analyzed directly by sodium dodecyl sulfate-polyacrylamide gel electrophoresis or by immunoprecipitation with region-specific antibodies. The ORF1 polyprotein was processed into at least 10 major proteins: p11, p28, p35, p32, p14, p70, p60, p66, p46, and p120. Seven of these products were arranged in the following order: NH(2)-p11-p28-p35(
NTPase
)-p32-p14(VPg)-p70(Pro-Pol)-p60(VP1)-COOH. p66, p46 and p120 were precursors of p28-p35 (
NTPase
), p32-p14 (VPg), and p32-p14 (VPg)-p70 (Pro-Pol), respectively. Mutagenesis in the 3C-like protease motif fully abolished the proteolytic activity. The cleavage map of SaV ORF1 is similar to those of other heretofore known members of the family Caliciviridae, especially to rabbit hemorrhagic disease virus, a member of the genus Lagovirus.
...
PMID:Proteolytic processing of sapovirus ORF1 polyprotein. 1591 82
Sapovirus (SaV), a member of the family Caliciviridae, is a causative agent of acute
gastroenteritis
in humans and swine and is currently divided into five genogroups, GI-GV. The proteolytic processing of the SaV open reading frame 1 (ORF1) polyprotein with a human GII SaV Mc10 strain has recently been determined and the products are arranged in the following order: NH(2)-p11-p28-p35 (
NTPase
)-p32-p14 (VPg)-p70 (Pro-Pol)-p60 (VP1)-COOH. The cleavage site between p14 (VPg) and p70 (Pro-Pol) was identified as E(1055)/A(1056) by N-terminal amino acid sequencing. To identify other cleavage sites, a series of GII SaV Mc10 full-length clones containing disrupted potential cleavage sites in the ORF1 polyprotein were constructed and used to generate linear DNA templates for in vitro coupled transcription-translation. The translation products were analysed by SDS-PAGE or by immunoprecipitation with region-specific antibodies. N-terminal amino acid sequencing with Escherichia coli-expressed recombinant proteins was also used to identify the cleavage site between p32 and p14. These approaches enabled identification of the six cleavage sites of the Mc10 ORF1 polyprotein as E(69)/G(70), Q(325)/G(326), Q(666)/G(667), E(940)/A(941), E(1055)/A(1056) and E(1722)/G(1723). The alignment of the SaV full-length ORF1 amino acid sequences indicated that the dipeptides used for the cleavage sites were either E or Q at the P1 position and A, G or S at the P1' position, which were conserved in the GI, GII, GIII, GIV and GV SaV ORF1 polyprotein.
...
PMID:Identification of the cleavage sites of sapovirus open reading frame 1 polyprotein. 1703 Aug 67
The genotype II.4 (GII.4) variants of human noroviruses (HuNVs) are recognized as the major agent of global
gastroenteritis
outbreaks. Due to the lack of an efficient cell culture system for HuNV propagation, the exact roles of HuNV-encoded nonstructural proteins (including Nterm,
NTPase
, P22, VPg, Pro, and RdRp) in viral replication or pathogenesis have not yet been fully understood. Here, we report the molecular characterization of the GII.4 HuNV-encoded
NTPase
(designated GII-NTPase). Results from our studies showed that GII-
NTPase
forms vesicular or nonvesicular textures in the cell cytoplasm, and the nonvesicular fraction of GII-
NTPase
significantly localizes to the endoplasmic reticulum (ER) or mitochondria. Deletion analysis revealed that the N-terminal 179-amino-acid (aa) region of GII-
NTPase
is required for vesicle formation and for ER colocalization, whereas the C-terminal region is involved in mitochondrial colocalization. In particular, two mitochondrion-targeting domains were identified in the C-terminal region of GII-
NTPase
which perfectly colocalized with mitochondria when the N-terminal region of GII-
NTPase
was deleted. However, the corresponding C-terminal portions of
NTPase
derived from the GI HuNV did not show mitochondrial colocalization. We also found that GII-
NTPase
physically interacts with itself as well as with Nterm and P22, but not VPg, Pro, and RdRp, in cells. The Nterm- and P22-interacting region was mapped to the N-terminal 179-aa region of GII-
NTPase
, whereas the self-assembly of GII-
NTPase
could be achieved via a head-to-head, tail-to-tail, or head-to-tail configuration. More importantly, we demonstrate that GII-
NTPase
possesses a proapoptotic activity, which can be further enhanced by coexpression with Nterm or P22.
IMPORTANCE
Despite the importance of human norovirus GII.4 variants in global
gastroenteritis
outbreaks, the basic biological functions of the viral nonstructural proteins in cells remain rarely investigated. In this report, we focus our studies on characteristics of the GII.4 norovirus-encoded
NTPase
(GII-NTPase). We unexpectedly find that GII-
NTPase
can perfectly colocalize with mitochondria after its N-terminal region is deleted. However, such a phenomenon is not observed for
NTPase
encoded by a GI strain. We further reveal that the N-terminal 179-aa region of GII-
NTPase
is sufficient to mediate (i) vesicle formation, (ii) ER colocalization, (iii) the interaction with two other nonstructural proteins, including Nterm and P22, (iv) the formation of homodimers or homo-oligomers, and (v) the induction of cell apoptosis. Taken together, our findings emphasize that the virus-encoded
NTPase
must have multiple activities during viral replication or pathogenesis; however, these activities may vary somewhat among different genogroups.
...
PMID:Subcellular Localization and Functional Characterization of GII.4 Norovirus-Encoded NTPase. 2921 38
Human norovirus (HuNoV) is one of the main causes of acute
gastroenteritis
worldwide and is responsible for at least 20% of all cases. The detailed molecular mechanism of this norovirus remains unknown due to the lack of a suitable in vitro culturing system. An infectious clone of HuNoV would be a useful tool for elucidating the processes of viral infection and the mechanisms of replication. We developed an infectious cDNA clone of HuNoV using the rapid technique of Gibson Assembly. The complete genome of the HuNoV GII.4 Sydney subtype was cloned into a previously modified pcDNA3.1-based plasmid vector downstream from a cytomegaloviral promoter. We monitored the viral infection in vitro by inserting the reporter gene of the green fluorescent protein (GFP) between the
NTPase
and p22 genes, also by Gibson Assembly, to construct a HuNoV-GFP replicon. Human Caco-2 cells were transfected with the full-length genomic clone and the replicon containing GFP. The gene encoding the VP1/VP2 capsid protein was expressed, which was indirect evidence of the synthesis of subgenomic RNAs and thus the negative strand of the genome. We successfully constructed the infectious clone and its replicon containing GFP for the HuNoV GII.4 Sydney subtype, a valuable tool that will help the study of noroviral infection and replication.
...
PMID:Development of an infectious clone and replicon system of norovirus GII.4. 2980 May 92
Noroviruses are the primary cause of non-bacterial acute
gastroenteritis
worldwide, and GII.8 belongs to a non-epidemic genotype with a limited understanding currently. In this study, we assembled the first GII.8 norovirus genome from China and clarified the temporal evolutionary process of this non-epidemic variant. Using the "4+1+1" application strategy with newly designed primer sets, the genome of one GII.8 strain GZ2017-L601 from China was firstly sequenced that comprised 7476 nucleotides. The homology of the new genome and the previous only GII.8 genome reached 93.8% identity at the nucleotide level, but only 10, 6, 7 amino acid mutations occurred in three ORFs. When compared the new strain with other GII reference strains, p22 and P2 were calculated as the variable encoding regions, and
NTPase
, VPg, 3CL, RdRp and S were shown as the conserved ones. We then reconstructed the evolutionary process of the GII.8 genotype using other available sequences in GenBank. Based on the partial N/C region, all GII.8 strains could be subdivided chronologically into four clusters, which spans 1967-1994, 1997-2005, 2003-2009, and 2007-2017, respectively. Moreover, differences of capsid P proteins between GII.8 strains and the epidemic GII.4 strain VA387 were also compared. There existed 147/310 distinct amino acid sites in the alignment, including two insertion and three deletion mutations. Distribution of antigen epitopes of two GII.8 variants was comparable, but the numbers of antigenic sites of GII.8 strains were less than that of VA387. In summary, the first GII.8 genome from China was assembled and extensively characterized, and a time-order evolutionary process of this genotype was identified with a static pattern of antigenic variations.
...
PMID:Genome characterization and temporal evolution analysis of a non-epidemic norovirus variant GII.8. 3077 88
