P123
P123'
mRNA-capping enzyme nsP1
     (EC 2.1.1.-)
     (EC 2.7.7.-)
     (Non-structural protein 1)
Protease/triphosphatase/NTPase/helicase nsP2
     (EC 3.4.22.-)
     (EC 3.1.3.33)
     (EC 3.6.1.15)
     (EC 3.6.1.-)
     (Non-structural protein 2)
     (nsP2)
Non-structural protein 3
     (nsP3)
Non-structural protein 3'
     (nsP3')
RNA-directed RNA polymerase nsP4
     (EC 2.7.7.48)
     (Non-structural protein 4)
     (nsP4)

Gene name

None

From

Getah virus (GETV)

[TaxID: 59300]

Taxonomy

Viruses; ssRNA positive-strand viruses, no DNA stage; Togaviridae; Alphavirus; SFV complex.

Virus hosts

Aedes vexans [TaxID: 7163]
Culex tritaeniorhynchus [TaxID: 7178]
Equus caballus (Horse) [TaxID: 9796]

Protein existence

2: Evidence at transcript level;

References

[1]	NUCLEOTIDE SEQUENCE [GENOMIC RNA]. Kim C.-J., Lee J.-Y., Cruz D.J.M.; "Complete genome sequence of Getahvirus."; Submitted (JUL-2004) to the EMBL/GenBank/DDBJ databases.

Comments

FUNCTION: P123 and P123' are short-lived polyproteins, accumulating during early stage of infection. P123 is directly translated from the genome, whereas P123' is a product of the cleavage of P1234. They localize the viral replication complex to the cytoplasmic surface of modified endosomes and lysosomes. By interacting with nsP4, they start viral genome replication into antigenome. After these early events, P123 and P123' are cleaved sequentially into nsP1, nsP2 and nsP3/nsP3'. This sequence of delayed processing would allow correct assembly and membrane association of the RNA polymerase complex (By similarity).
FUNCTION: nsP1 is a cytoplasmic capping enzyme. This function is necessary since all viral RNAs are synthesized in the cytoplasm, and host capping enzymes are restricted to the nucleus. The enzymatic reaction involves a covalent link between 7-methyl-GMP and nsP1, whereas eukaryotic capping enzymes form a covalent complex only with GMP. nsP1 capping would consist in the following reactions: GTP is first methylated and then forms the m7GMp-nsP1 complex, from which 7-methyl-GMP complex is transferred to the mRNA to create the cap structure. Palmitoylated nsP1 is remodeling host cell cytoskeleton, and induces filopodium-like structure formation at the surface of the host cell (By similarity).
FUNCTION: nsP2 has two separate domain with different biological activities. The N-terminal section is part of the RNA polymerase complex and has RNA trisphosphatase and RNA helicase activity. The C-terminal section harbors a protease that specifically cleaves and releases the four mature proteins (By similarity).
FUNCTION: nsP3 and nsP3' are essential for minus strand and subgenomic 26S mRNA synthesis (By similarity).
FUNCTION: nsP4 is a RNA dependent RNA polymerase. It replicates genomic and antigenomic RNA by recognizing replications specific signals. Transcribes also a 26S subgenomic mRNA by initiating RNA synthesis internally on antigenomic RNA. This 26S mRNA encodes for structural proteins. nsP4 is a short-lived protein regulated by several ways: the opal codon readthrough and degradation by ubiquitin pathway (By similarity).
CATALYTIC ACTIVITY: S-adenosyl-L-methionine + GTP = m₇GTP.
CATALYTIC ACTIVITY: m₇GTP + (5')pp-Pur-mRNA = diphosphate + m₇G(5')ppp-Pur-mRNA.
CATALYTIC ACTIVITY: (5')ppp-mRNA + H₂O = (5')pp-mRNA + phosphate.
CATALYTIC ACTIVITY: A 5'-phosphopolynucleotide + H₂O = a polynucleotide + phosphate.
CATALYTIC ACTIVITY: NTP + H₂O = NDP + phosphate.
CATALYTIC ACTIVITY: Nucleoside triphosphate + RNA(n) = diphosphate + RNA(n+1).
SUBUNIT: P123 interacts with nsP4; nsP1, nsP2, nsP3 and nsP4 interact with each other, and with uncharacterized host factors.
SUBCELLULAR LOCATION: Non-structural polyprotein: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Note=Located on the cytoplasmic surface of modified endosomes and lysosomes, also called cytopathic vacuoles type I (CPVI). These vacuoles contain numerous small circular invaginations (spherules) which may be the sites of RNA synthesis.
SUBCELLULAR LOCATION: P123: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity).
SUBCELLULAR LOCATION: P123': Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity).
SUBCELLULAR LOCATION: mRNA-capping enzyme nsP1: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Cell membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Cell projection, filopodium (By similarity). Note=In the late phase of infection, the polyprotein is quickly cleaved before localization to cellular membranes. Then a fraction of nsP1 localizes to the inner surface of the plasma membrane and its filopodial extensions (By similarity).
SUBCELLULAR LOCATION: Protease/triphosphatase/NTPase/helicase nsP2: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Nucleus (By similarity). Note=In the late phase of infection, the polyprotein is quickly cleaved before localization to cellular membranes. Then approximately half of nsP2 is found in the nucleus (By similarity).
SUBCELLULAR LOCATION: Non-structural protein 3: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Cytoplasm (By similarity). Note=In the late phase of infection, the polyprotein is quickly cleaved before localization to cellular membranes. Then nsP3 and nsP3' seems to aggregate in cytoplasm (By similarity).
SUBCELLULAR LOCATION: Non-structural protein 3': Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Cytoplasm (By similarity). Note=In the late phase of infection, the polyprotein is quickly cleaved before localization to cellular membranes. Then nsP3 and nsP3' seems to aggregate in cytoplasm (By similarity).
SUBCELLULAR LOCATION: RNA-directed RNA polymerase nsP4: Endosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity). Lysosome membrane; Peripheral membrane protein; Cytoplasmic side (By similarity).
INDUCTION: Viral replication produces dsRNA in the late phase of infection, resulting in a strong activation of host EIF2AK2/PKR, leading to almost complete phosphorylation of EIF2A. This inactivates completely cellular translation initiation, resulting in a dramatic shutoff of proteins synthesis. Translation of viral non-structural polyprotein and all cellular proteins are stopped in infected cell between 2 and 4 hours post infection. Only the 26S mRNA is still translated into viral structural proteins, presumably through a unique mechanism of enhancer element which counteract the translation inhibition mediated by EIF2A. By doing this, the virus uses the cellular defense for its own advantage: shutoff of cellular translation allows to produce big amounts of structural proteins needed for the virus to bud out of the doomed cell.
PTM: Specific enzymatic cleavages in vivo yield mature proteins. The polyprotein is synthesized as P123, or P1234 by stop codon readthrough. These polyproteins are processed differently depending on the stage of infection. In early stages, P1234 is first cleaved in trans, through its nsP2 protease activity, releasing P123' and nsP4. P123/P123' and nsP4 start to replicate the viral genome into its antigenome. After these early events, nsP1 is cleaved in cis by nsP2 protease, releasing the P23/P23' polyprotein. Cleavage of nsP1 exposes an 'activator' at the N-terminus of P23/P23' which induces its cleavage into nsP2 and nsP3 by the viral protease. This sequence of delayed processing would allow correct assembly and membrane association of the RNA-polymerase complex. In the late stage of infection, the presence of free nsP2 in the cytoplasm cleaves P1234 quickly into P12 and P34, then into the four nsP (By similarity).
PTM: nsP1 is palmitoylated by host (By similarity).
PTM: nsP4 is ubiquitinated; targets the protein for rapid degradation via the ubiquitin system (By similarity).
MISCELLANEOUS: The genome encodes for P123, but readthrough of a terminator codon UGA occurs between the codons for Ser-1849 and Leu-1850. This readthrough produces P1234, cleaved quickly by nsP2 into P123' and nsP4. Further processing of p123' gives nsP1, nsP2 and nsP3' which is 6 amino-acids longer than nsP3 since the cleavage site is after the readthrough. This unusual molecular mechanism ensures that few nsP4 are produced compared to other non-structural proteins. Mutant viruses with no alternative termination site grow significantly slower than wild-type virus.
SIMILARITY: Contains 1 Macro domain.
SIMILARITY: Contains 1 peptidase C9 domain [view classification].
SIMILARITY: Contains 1 RdRp catalytic domain.

Copyright

Copyrighted by the UniProt Consortium, see http://www.uniprot.org/terms. Distributed under the Creative Commons Attribution-NoDerivs License.

Cross-references

Sequence databases

EMBL

AY702913; AAU85259.1; -; Genomic_RNA.

[EMBL / GenBank / DDBJ] [CoDingSequence]

RefSeq

YP_164438.1; -.

3D structure databases

ModBase

Q5Y389.

Ontologies

GO:0005765;	Cellular component: lysosomal membrane (inferred from electronic annotation from UniProtKB-SubCell).
QuickGo view.

Family and domain databases

InterPro

IPR002589; A1pp.
IPR002588; MeTrfase_vir.
IPR002620; Peptidase_C9.
IPR001788; RNA-dep_RNA_pol_vir-typ.
IPR000606; RNA_helicase1_vir.
IPR007094; RNA_pol_PSvir.
Graphical view of domain structure.

Pfam

PF01661; A1pp; 1.
PF01707; Peptidase_C9; 1.
PF00978; RdRP_2; 1.
PF01443; Viral_helicase1; 1.
PF01660; Vmethyltransf; 1.
Pfam graphical view of domain structure.

SMART

SM00506; A1pp; 1.
SMART graphical view of domain structure.

PROSITE

PS51154; MACRO; 1.
PS50507; RDRP_SSRNA_POS; 1.
PROSITE graphical view of domain structure (profiles).

BLOCKS

Q5Y389.

Genome annotation databases

GeneID

5075854; -.

Other

ProtoNet

Q5Y389.

UniRef

View cluster of proteins with at least 50% / 90% / 100% identity.

Keywords

ATP-binding; Cell membrane; Cell projection; Cytoplasm; Endosome; Helicase; Hydrolase; Lipoprotein; Lysosome; Membrane; Methyltransferase; mRNA capping; mRNA processing; Multifunctional enzyme; Nucleotide-binding; Nucleotidyltransferase; Nucleus; Palmitate; Protease; RNA replication; RNA-binding; RNA-directed RNA polymerase; Thiol protease; Transferase; Ubl conjugation.

Features

Feature table viewer

Feature aligner

`Key`	`From To`	`Length`	`Description`	`FTId`
`CHAIN`	`1 2466`	`2466`	`Non-structural polyprotein.`	`PRO_0000308392`
`CHAIN`	`1 1855`	`1855`	`P123'.`	`PRO_0000228773`
`CHAIN`	`1 1849`	`1849`	`P123.`	`PRO_0000228774`
`CHAIN`	`1 534`	`534`	`mRNA-capping enzyme nsP1.`	`PRO_0000228775`
`CHAIN`	`535 1332`	`798`	`Protease/triphosphatase/NTPase/helicase nsP2.`	`PRO_0000228776`
`CHAIN`	`1333 1855`	`523`	`Non-structural protein 3'.`	`PRO_0000228777`
`CHAIN`	`1333 1849`	`517`	`Non-structural protein 3.`	`PRO_0000228778`
`CHAIN`	`1856 2466`	`611`	`RNA-directed RNA polymerase nsP4.`	`PRO_0000228779`
`DOMAIN`	`963 1163`	`201`	`Peptidase C9.`
`DOMAIN`	`1333 1492`	`160`	`Macro.`
`DOMAIN`	`2220 2335`	`116`	`RdRp catalytic.`
`NP_BIND`	`720 727`	`8`	`ATP (Potential).`
`REGION`	`243 262`	`20`	`nsP1 membrane-binding (By similarity).`
`REGION`	`1004 1023`	`20`	`Nucleolus localization signal (By similarity).`
`MOTIF`	`1180 1184`	`5`	`Nuclear localization signal (By similarity).`
`ACT_SITE`	`1012 1012`		`For cysteine protease nsP2 activity (By similarity).`
`ACT_SITE`	`1081 1081`		`For cysteine protease nsP2 activity (By similarity).`
`SITE`	`534 535`	`2`	`Cleavage; by nsP2 (By similarity).`
`SITE`	`1332 1333`	`2`	`Cleavage; by nsP2 (By similarity).`
`SITE`	`1855 1856`	`2`	`Cleavage; by nsP2 (By similarity).`
`LIPID`	`416 416`		`S-palmitoyl cysteine; by host (By similarity).`
`LIPID`	`418 418`		`S-palmitoyl cysteine; by host (By similarity).`

Sequence information

Length: 2466 AA [This is the length of the unprocessed precursor]

Molecular weight: 275210 Da [This is the MW of the unprocessed precursor]

CRC64: 5870CF4316BEFB79 [This is a checksum on the sequence]

        10         20         30         40         50         60 
MKVTVDVEAD SPFLKALQKA FPAFEVESQQ VTPNDHANAR AFSHLATKLI EQEVPTGVTI 

        70         80         90        100        110        120 
LDVGSAPARR LMSDHTYHCI CPMKSAEDPE RLANYARKLA KASGTVLDKN VSGKITDLQD 

       130        140        150        160        170        180 
VMATPDLESP TFCLHTDETC RTRAEVAVYQ DVYAVHAPTS LYHQAIKGVR TAYWIGFDTT 

       190        200        210        220        230        240 
PFMFEALAGA YPAYSTNWAD EQVLQARNIG LCATGLSEGR RGKLSIMRKK CLRPSDRVMF 

       250        260        270        280        290        300 
SVGSTLYTES RKLLRSWHLP SVFHLKGKNS FTCRCDTVVS CEGYVVKKIT ISPGIYGKTV 

       310        320        330        340        350        360 
DYAVTHHAEG FLMCKITDTV RGERVSFPVC TYVPATICDQ MTGILATDVT PEDAQKLLVG 

       370        380        390        400        410        420 
LNQRIVVNGR TQRNTNTMKN YLLPVVAQAF SKWAREARAD MEDEKPLGTR ERTLTCCCLW 

       430        440        450        460        470        480 
AFKSHKIHTM YKRPETQTIV KVPSTFDSFV IPSLWSSSLS MGIRQRIKLL LSARMAQGLP 

       490        500        510        520        530        540 
YSGDRTEARA AEEEEKEVQE AELTRAALPP LVSGSCADDI AQVDVEELTF RAGAGVVETP 

       550        560        570        580        590        600 
RNALKVTPQA HDHLIGSYLI LSPQTVLKSE KLAPIHPLAE QVTVMTHSGR SGRYPVDKYD 

       610        620        630        640        650        660 
GRVLIPTGAA IPVSEFQALS ESATMVYNER EFINRKLHHI ALYGPALNTD EESYEKVRAE 

       670        680        690        700        710        720 
RAETEYVFDV DKKACIKKEE ASGLVLTGDL INPPFHEFAY EGLKIRPAAP YHTTIIGVFG 

       730        740        750        760        770        780 
VPGSGKSAII KNMVTTRDLV ASGKKENCQE IMNDVKRQRG LDVTARTVDS ILLNGCKKGV 

       790        800        810        820        830        840 
ENLYVDEAFA CHSGTLLALI ALVRPSGKVV LCGDPKQCGF FNLMQLKVHY NHNICTRVLH 

       850        860        870        880        890        900 
KSISRRCTLP VTAIVSTLHY QGKMRTTNRC NTPIQIDTTG SSKPASGDIV LTCFRGWVKQ 

       910        920        930        940        950        960 
LQIDYRGHEV MTAAASQGLT RKGVYAVRQK VNENPLYSPL SEHVNVLLTR TENRLVWKTL 

       970        980        990       1000       1010       1020 
SGDPWIKVLT NVPRGDFSAT LEEWHEEHDG IMRVLNERPA EVDPFQNKAK VCWAKCLVQV 

      1030       1040       1050       1060       1070       1080 
LETAGIRMTA DEWNTILAFR EDRAYSPEVA LNEICTRYYG VDLDSGLFSA QSVSLFYENN 

      1090       1100       1110       1120       1130       1140 
HWDNRPGGRM YGFNHEVARK YAARFPFLRG NMNSGLQLNV PERKLQPFSA ECNIVPSNRR 

      1150       1160       1170       1180       1190       1200 
LPHALVTSYQ QCRGERVEWL LKKIPGHQML LVSEYNLVIP HKRVFWIAPP RVSGADRTYD 

      1210       1220       1230       1240       1250       1260 
LDLGLPMDAG RYDLVFVNIH TEYRQHHYQQ CVDHSMRLQM LGGDSLHLLR PGGSLLMRAY 

      1270       1280       1290       1300       1310       1320 
GYADRVSEMV VTALARKFSA FRVLRPACVT SNTEVFLLFS NFDNGRRAVT LHQANQKLSS 

      1330       1340       1350       1360       1370       1380 
MYACNGLHTA GCAPSYRVRR ADISGHSEEA VVNAANAKGT VSDGVCRAVA KKWPSSFKGA 

      1390       1400       1410       1420       1430       1440 
ATPVGTAKMI RADGMTVIHA VGPNFSTVTE AEGDRELAAA YRAVASIIST NNIKSVAVPL 

      1450       1460       1470       1480       1490       1500 
LSTGTFSGGK DRVMQSLNHL FTALDATDAD VVIYCRDKNW EKKIQEAIDR RTAIELVSED 

      1510       1520       1530       1540       1550       1560 
VTLETDLVRV HPDSCLVGRN GYSATDGKLY SYLEGTRFHQ TAVDMAEIST LWPRLQDANE 

      1570       1580       1590       1600       1610       1620 
QICLYALGET MDSIRTKCPV EDADSSTPPK TVPCLCRYAM TAERVARLRM NNTKNIIVCS 

      1630       1640       1650       1660       1670       1680 
SFPLPKYRIE GVQKVKCDRV LIFDQTVPSL VSPRKYIQQP PEQLDNVSLT STTSTGSAWS 

      1690       1700       1710       1720       1730       1740 
FPSETTYETM EVVAEVHTEP PIPPPRRRRA AVAQLRQDLE VTEEIEPYVT QQAEIMVMER 

      1750       1760       1770       1780       1790       1800 
VATTDIRAIP VPARRAITMP VPAPRVRKVA TEPPLEPEAP IPAPRKRRTT STSPPHNPED 

      1810       1820       1830       1840       1850       1860 
FVPRVPVELP WEPEDLDIQF GDLEPRRRNT RDRDVSTGIQ FGDIDFNQSL GRAGAYIFSS 

      1870       1880       1890       1900       1910       1920 
DTGPGHLQQK SVRQHELPCE TLYAHEDERI YPPAFDGEKE KVLQAKMQMA PTEANKSRYQ 

      1930       1940       1950       1960       1970       1980 
SRKVENMKAL IVERLREGAK LYLHEQTDKV PTYTSKYPRP VYSPSVDDSL SDPEVAVAAC 

      1990       2000       2010       2020       2030       2040 
NSFLEENYPT VANYQITDEY DAYLDLVDGS ESCLDRATFC PAKLRCYPKH HAYHQPQIRS 

      2050       2060       2070       2080       2090       2100 
AVPSPFQNTL QNVLAAATKR NCNVTQMREL PTMDSAVFNV ESFKKYACTG EYWQEFKDNP 

      2110       2120       2130       2140       2150       2160 
IRITTENITT YVAKLKGPKA AALFAKTHNL VPLQEVPMDR FVMDMKRDVK VTPGTKHTEE 

      2170       2180       2190       2200       2210       2220 
RPKVQVIQAA EPLATAYLCG IHRELVRRLK AVLTPNIHTL FDMSAEDFDA IIAAHFQPGD 

      2230       2240       2250       2260       2270       2280 
AVLETDIASF DKSQDDSLAL TALMLLEDLG VDQELLDLIE AAFGEITSVH LPTGTRFKFG 

      2290       2300       2310       2320       2330       2340 
AMMKSGMFLT LFINTLLNIV IACRVLRDKL SSSACAAFIG DDNIVHGVRS DPLMAERCAS 

      2350       2360       2370       2380       2390       2400 
WVNMEVKIID ATMCEKPPYF CGGFILYDSV AGTACRVADP LKRLFKLGKP LPADDNQDED 

      2410       2420       2430       2440       2450       2460 
RRRALKDETV KWSRIGLREE LDVALSSRYQ VSGVGNITRA MSTLSKSLKS FRKIRGPIIH 


LYGGPK

Q5Y389 in FASTA format

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View entry in raw text format (no links)
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	BLAST submission on ExPASy/SIB or at NCBI (USA)		Sequence analysis tools: ProtParam, ProtScale, Compute pI/Mw, PeptideMass, PeptideCutter, Dotlet (Java)
	ScanProsite, MotifScan		Submit a homology modeling request to SWISS-MODEL
	NPSA Sequence analysis tools