VP4_ROTS4
ID VP4_ROTS4 Reviewed; 776 AA.
AC P0C6Y9;
DT 14-APR-2009, integrated into UniProtKB/Swiss-Prot.
DT 14-APR-2009, sequence version 1.
DT 23-FEB-2022, entry version 54.
DE RecName: Full=Outer capsid protein VP4 {ECO:0000255|HAMAP-Rule:MF_04132};
DE AltName: Full=Hemagglutinin {ECO:0000255|HAMAP-Rule:MF_04132};
DE Contains:
DE RecName: Full=Outer capsid protein VP8* {ECO:0000255|HAMAP-Rule:MF_04132};
DE Contains:
DE RecName: Full=Outer capsid protein VP5* {ECO:0000255|HAMAP-Rule:MF_04132};
OS Rotavirus A (strain RVA/SA11-4F/G3P6[1]) (RV-A) (Simian Agent 11 (strain
OS 4F)).
OC Viruses; Riboviria; Orthornavirae; Duplornaviricota; Resentoviricetes;
OC Reovirales; Reoviridae; Sedoreovirinae; Rotavirus; Rotavirus A.
OX NCBI_TaxID=36436;
OH NCBI_TaxID=9544; Macaca mulatta (Rhesus macaque).
RN [1]
RP NUCLEOTIDE SEQUENCE [GENOMIC RNA].
RX PubMed=1656916; DOI=10.1007/bf01310953;
RA Mattion N.M., Estes M.K.;
RT "Sequence of a rotavirus gene 4 associated with unique biologic
RT properties.";
RL Arch. Virol. 120:109-113(1991).
RN [2]
RP SIALIC ACID DEPENDENCY.
RX PubMed=11907248; DOI=10.1128/jvi.76.8.4087-4095.2002;
RA Ciarlet M., Ludert J.E., Iturriza-Gomara M., Liprandi F., Gray J.J.,
RA Desselberger U., Estes M.K.;
RT "Initial interaction of rotavirus strains with N-acetylneuraminic (sialic)
RT acid residues on the cell surface correlates with VP4 genotype, not species
RT of origin.";
RL J. Virol. 76:4087-4095(2002).
RN [3]
RP STRUCTURE BY ELECTRON MICROSCOPY OF CAPSID SHELL, AND SUBUNIT (OUTER CAPSID
RP PROTEIN VP4).
RX PubMed=19036817; DOI=10.1128/jvi.01855-08;
RA Li Z., Baker M.L., Jiang W., Estes M.K., Prasad B.V.V.;
RT "Rotavirus architecture at subnanometer resolution.";
RL J. Virol. 83:1754-1766(2009).
CC -!- FUNCTION: [Outer capsid protein VP4]: Spike-forming protein that
CC mediates virion attachment to the host epithelial cell receptors and
CC plays a major role in cell penetration, determination of host range
CC restriction and virulence. Rotavirus attachment and entry into the host
CC cell probably involves multiple sequential contacts between the outer
CC capsid proteins VP4 and VP7, and the cell receptors. It is subsequently
CC lost, together with VP7, following virus entry into the host cell.
CC Following entry into the host cell, low intracellular or intravesicular
CC Ca(2+) concentration probably causes the calcium-stabilized VP7 trimers
CC to dissociate from the virion. This step is probably necessary for the
CC membrane-disrupting entry step and the release of VP4, which is locked
CC onto the virion by VP7. During the virus exit from the host cell, VP4
CC seems to be required to target the newly formed virions to the host
CC cell lipid rafts. {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- FUNCTION: [Outer capsid protein VP5*]: Forms the spike 'foot' and
CC 'body' and acts as a membrane permeabilization protein that mediates
CC release of viral particles from endosomal compartments into the
CC cytoplasm. During entry, the part of VP5* that protrudes from the virus
CC folds back on itself and reorganizes from a local dimer to a trimer.
CC This reorganization may be linked to membrane penetration by exposing
CC VP5* hydrophobic region. In integrin-dependent strains, VP5* targets
CC the integrin heterodimer ITGA2/ITGB1 for cell attachment.
CC {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- FUNCTION: [Outer capsid protein VP8*]: Forms the head of the spikes and
CC mediates the recognition of specific host cell surface glycans. It is
CC the viral hemagglutinin and an important target of neutralizing
CC antibodies. In sialic acid-dependent strains, VP8* binds to host cell
CC sialic acid, most probably a ganglioside, providing the initial
CC contact. In some other strains, VP8* mediates the attachment to histo-
CC blood group antigens (HBGAs) for viral entry. {ECO:0000255|HAMAP-
CC Rule:MF_04132}.
CC -!- SUBUNIT: [Outer capsid protein VP4]: Homotrimer (PubMed:19036817). VP4
CC adopts a dimeric appearance above the capsid surface, while forming a
CC trimeric base anchored inside the capsid layer (PubMed:19036817). Only
CC hints of the third molecule are observed above the capsid surface. It
CC probably performs a series of molecular rearrangements during viral
CC entry. Prior to trypsin cleavage, it is flexible. The priming trypsin
CC cleavage triggers its rearrangement into rigid spikes with approximate
CC two-fold symmetry of their protruding parts. After an unknown second
CC triggering event, cleaved VP4 may undergo another rearrangement, in
CC which two VP5* subunits fold back on themselves and join a third
CC subunit to form a tightly associated trimer, shaped like a folded
CC umbrella. Interacts with VP6. Interacts with VP7. {ECO:0000255|HAMAP-
CC Rule:MF_04132, ECO:0000269|PubMed:19036817}.
CC -!- SUBUNIT: [Outer capsid protein VP5*]: Homotrimer. The trimer is coiled-
CC coil stabilized by its C-terminus, however, its N-terminus, known as
CC antigen domain or 'body', seems to be flexible allowing it to self-
CC associate either as a dimer or a trimer. The two- to three-fold
CC reorganization and fold-back of VP5* may be linked to membrane
CC penetration, by exposing its hydrophobic region (By similarity).
CC {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- SUBCELLULAR LOCATION: [Outer capsid protein VP4]: Virion
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Host rough endoplasmic reticulum
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Host cell membrane
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Host cytoplasm, host cytoskeleton
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Host endoplasmic reticulum-Golgi
CC intermediate compartment {ECO:0000255|HAMAP-Rule:MF_04132}. Note=The
CC outer layer contains 180 copies of VP4, grouped as 60 dimers. Immature
CC double-layered particles assembled in the cytoplasm bud across the
CC membrane of the endoplasmic reticulum, acquiring during this process a
CC transient lipid membrane that is modified with the ER resident viral
CC glycoproteins NSP4 and VP7; these enveloped particles also contain VP4.
CC As the particles move towards the interior of the ER cisternae, the
CC transient lipid membrane and the non-structural protein NSP4 are lost,
CC while the virus surface proteins VP4 and VP7 rearrange to form the
CC outermost virus protein layer, yielding mature infectious triple-
CC layered particles. VP4 also seems to associate with lipid rafts of the
CC host cell membrane probably for the exit of the virus from the infected
CC cell by an alternate pathway. {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- SUBCELLULAR LOCATION: [Outer capsid protein VP8*]: Virion
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Note=Outer capsid protein.
CC {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- SUBCELLULAR LOCATION: [Outer capsid protein VP5*]: Virion
CC {ECO:0000255|HAMAP-Rule:MF_04132}. Note=Outer capsid protein.
CC {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- DOMAIN: [Outer capsid protein VP4]: The VP4 spike is divided into a
CC foot, a stalk and body, and a head. {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- PTM: [Outer capsid protein VP4]: Proteolytic cleavage by trypsin
CC results in activation of VP4 functions and greatly increases
CC infectivity. The penetration into the host cell is dependent on trypsin
CC treatment of VP4. It produces two peptides, VP5* and VP8* that remain
CC associated with the virion. Cleavage of VP4 by trypsin probably occurs
CC in vivo in the lumen of the intestine prior to infection of
CC enterocytes. Trypsin seems to be incorporated into the three-layered
CC viral particles but remains inactive as long as the viral outer capsid
CC is intact and would only be activated upon the solubilization of the
CC latter. {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- MISCELLANEOUS: In group A rotaviruses, VP4 defines the P serotype.
CC {ECO:0000255|HAMAP-Rule:MF_04132}.
CC -!- MISCELLANEOUS: Some rotavirus strains are neuraminidase-sensitive and
CC require sialic acid to attach to the cell surface. Some rotavirus
CC strains are integrin-dependent. Some rotavirus strains depend on
CC ganglioside for their entry into the host cell. Hsp70 also seems to be
CC involved in the entry of some strains. {ECO:0000255|HAMAP-
CC Rule:MF_04132}.
CC -!- MISCELLANEOUS: This strain probably uses sialic acid to attach to the
CC host cell. {ECO:0000255|HAMAP-Rule:MF_04132,
CC ECO:0000269|PubMed:11907248}.
CC -!- SIMILARITY: Belongs to the rotavirus VP4 family. {ECO:0000255|HAMAP-
CC Rule:MF_04132}.
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DR EMBL; X57319; -; NOT_ANNOTATED_CDS; Genomic_RNA.
DR SMR; P0C6Y9; -.
DR GO; GO:0044172; C:host cell endoplasmic reticulum-Golgi intermediate compartment; IEA:UniProtKB-SubCell.
DR GO; GO:0020002; C:host cell plasma membrane; IEA:UniProtKB-SubCell.
DR GO; GO:0044168; C:host cell rough endoplasmic reticulum; IEA:UniProtKB-SubCell.
DR GO; GO:0044163; C:host cytoskeleton; IEA:UniProtKB-SubCell.
DR GO; GO:0016020; C:membrane; IEA:UniProtKB-KW.
DR GO; GO:0039624; C:viral outer capsid; IEA:UniProtKB-UniRule.
DR GO; GO:0039665; P:permeabilization of host organelle membrane involved in viral entry into host cell; IEA:UniProtKB-UniRule.
DR GO; GO:0099008; P:viral entry via permeabilization of inner membrane; IEA:UniProtKB-KW.
DR GO; GO:0019062; P:virion attachment to host cell; IEA:UniProtKB-UniRule.
DR HAMAP; MF_04132; Rota_A_VP4; 1.
DR HAMAP; MF_04125; Rota_VP4; 1.
DR InterPro; IPR013320; ConA-like_dom_sf.
DR InterPro; IPR042546; Rota_A_VP4.
DR InterPro; IPR035330; Rota_VP4_MID.
DR InterPro; IPR038017; Rota_VP4_MID_sf.
DR InterPro; IPR000416; VP4_concanavalin-like.
DR InterPro; IPR035329; VP4_helical.
DR Pfam; PF17477; Rota_VP4_MID; 1.
DR Pfam; PF00426; VP4_haemagglut; 1.
DR Pfam; PF17478; VP4_helical; 1.
DR SUPFAM; SSF111379; SSF111379; 1.
DR SUPFAM; SSF49899; SSF49899; 1.
PE 1: Evidence at protein level;
KW Capsid protein; Coiled coil; Disulfide bond; Hemagglutinin;
KW Host cell membrane; Host cytoplasm; Host cytoskeleton;
KW Host endoplasmic reticulum; Host membrane; Host-virus interaction;
KW Membrane; Outer capsid protein; Viral attachment to host cell;
KW Viral penetration into host cytoplasm;
KW Viral penetration via permeabilization of host membrane; Virion;
KW Virus entry into host cell.
FT CHAIN 1..776
FT /note="Outer capsid protein VP4"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT /id="PRO_0000368156"
FT CHAIN 1..231
FT /note="Outer capsid protein VP8*"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT /id="PRO_0000368157"
FT CHAIN 248..776
FT /note="Outer capsid protein VP5*"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT /id="PRO_0000368158"
FT REGION 65..224
FT /note="Spike head"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT REGION 248..479
FT /note="Spike body and stalk (antigen domain)"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT REGION 389..409
FT /note="Hydrophobic; possible role in virus entry into host
FT cell"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT REGION 510..776
FT /note="Spike foot"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT COILED 484..518
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT MOTIF 308..310
FT /note="DGE motif; interaction with ITGA2/ITGB1 heterodimer"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT MOTIF 448..450
FT /note="YGL motif; interaction with ITGA4"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT MOTIF 644..646
FT /note="KID motif; interaction with HSPA8"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT SITE 101
FT /note="Binding to sialic acid"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT SITE 190
FT /note="Binding to sialic acid"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT SITE 231..232
FT /note="Cleavage"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT SITE 241..242
FT /note="Cleavage"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT SITE 247..248
FT /note="Cleavage; associated with enhancement of
FT infectivity"
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT DISULFID 203..216
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
FT DISULFID 318..380
FT /evidence="ECO:0000255|HAMAP-Rule:MF_04132"
SQ SEQUENCE 776 AA; 86697 MW; 867C02F9B819487E CRC64;
MASLIYRQLL TNSYTVELSD EIQEIGSTKT QNVTVNPGPF AQTNYAPVNW GPGETNDSTT
VEPVLDGPYQ PTTFNPPVSY WMLLAPTNAG VVVEGTNNTN RWLATILIEP NVQQVERTYT
LFGQQVQVTV SNDSQTKWKF VDLSKQTQDG NYSQHGSLLS TPKLYGVMKH GGKIYTYNGE
TPNANTGYYS TTNFDTVNMT AYCDFYIIPL AQEAKCTEYI NNGLPPIQNT RNIVPVSIVS
RNIVYTRAQP NQDIVVSKTS LWKEMQYNRD IVIRFKFANS IIKSGGLGYK WSEVSFKPAN
YQYTYTRDGE EVTAHTTCSV NGVNDFNYNG GSLPTDFVIS KYEVIKENSF VYIDYWDDSQ
AFRNMVYVRS LAADLNSVMC TGGDYSFALP VGNYPVMTGG AVSLHSAGVT LSTQFTDFVS
LNSLRFRFRL SVEEPPFSIL RTRVSGLYGL PAAKPNNSQE YYEIAGRFSL ISLVPLNDDY
QTPIMNSVTV RQDLERQLGE LRDEFNNLSQ QIAMSQLIDL ALLPLDMFSM FSGIKSTIDA
AKSMATNVMK RFKKSSLANS VSTLTDSLSD AASSISRSAS VRSVSSTASA WTEVSNIASD
INVTTSSIST QTSTISRRLR LKEMATQTDG MNFDDISAAV LKTKIDKSTQ LNTNTLPEIV
TEASEKFIPN RAYRVIKDDE VLEASTDGKY FAYKVETFEE IPFDVQKFAD LVTDSPVISA
IIDFKTLKNL NDNYGISRQQ ALNLLRSDPR VLREFINQDN PIIRNRIESL IMQCRL