{PDOC51992}
{PS51992; COV_NSP3_Y}
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* Coronavirus (CoV) Nsp3 Y domain profile *
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Coronaviruses (CoVs)  are  enveloped  positive-strand  RNA viruses that infect
many species, including humans, other mammals, and birds. After infection, the
host may   develop  respiratory,  bowel,  liver,  and  neurological  diseases.
Coronaviruses are divided into four genera: Alphacoronavirus, Betacoronavirus,
Gammacoronavirus, and  Deltacoronavirus.  SARS,  SARS-CoV-2, BatCoV RaTG13 and
Bat-SARS-like coronavirus  (BATSL-CoVZXC21  and  BAT-SL-CoVZC45) belong to the
Sarbecovirus subgenus of Betacoronavirus [E1].

The CoV  replicase  gene encodes two overlapping polyproteins, termed pp1a and
pp1ab, which  mediate  viral  replication  and transcription. The polypeptides
pp1a and  pp1ab  are  processed  by  the action of a main protease (Nsp5) (see
<PDOC51442>) and of one or two papain-like proteases (PLpro) (see <PDOC51124>)
found in  Nsp3  into  non-structural  proteins (Nsps) to form the replication/
transcription complex  (RTC).  Among  these,  Nsp3 is the largest multi-domain
protein produced  by  coronaviruses. This glycosylated, multi-domain, integral
membrane protein  plays  many  roles  in the viral life cycle. It can act as a
scaffold protein  to interact with itself and to bind other viral Nsps or host
proteins. In  particular,  Nsp3 is essential for RTC formation. Nsp3 comprises
various domains of functional and structural importance for virus replication,
the organization  of  which  differs between CoV genera, due to duplication or
absence of  some  domains.  However,  eight domains of Nsp3 exist in all known
CoVs: the  ubiquitin-like  domain  1  (Ubl1)  (see  <PDOC51943>), the Glu-rich
acidic domain  (also called “hypervariable region”), a macrodomain (also named
“X domain”)  (see  <PDOC51154>),  the  ubiquitin-like  domain  2  (Ubl2)  (see
<PDOC51943>), the  papain-like protease 2 (PL2pro) (see <PDOC51124>), the Nsp3
ectodomain (3Ecto),  as well as the Y domain which includes a widely-conserved
initial domain  (Y1), and an apparently coronavirus-specific carboxyl-terminal
domain (CoV-Y) consisting of three distinct subdomains named Y2, Y3 and Y4. In
addition, two transmembrane regions, TM1 and TM2, exist in all CoVs [1,2,3,4].

The Y  domains  including  Y1  and  CoV-Y  may  form  higher-order  oligomeric
complexes and play a role in pore formation in double-membrane vesicles (DMVs)
that serve  as  the  central hubs for viral RNA replication. Specific membrane
binding might be a conserved activity of the Y domain [4].

The Y1  domain  is  predicted  to  contain  two adjacent zinc finger (ZF)-like
motifs. The  first  IF  motif  (ZF1) adopts a HCCC-type TAZ2 domain-like zinc-
binding site. The second ZF motif (ZF2) harbors a CHCC-type zinc-binding site.
The CoV-Y domain has a twisted structure resembling a letter V. The protein is
organized into  three distinct subdomains (Y2, Y3 and Y4) with a deep cleft in
the middle  (see  <PDB:8F2E>). The N-terminal Y2 subdomain is dominated by six
beta strands  arranged  into  two nearly orthogonal beta sheets to form a beta
sandwich like  structure  packed  across  a  hydrophobic  core. An alpha helix
stacks on  the  exposed  side of the parallel sheet, whereas three short 3(10)
helices surround  the  open side of the beta sandwich. The middle Y3 subdomain
adopts a  compact  alpha helical fold composed of a three-helix bundle packing
against the  4th  helix.  All  four  helices  of  the Y3 subdomain are largely
amphipathic, with  polar and charged residues on the outside and nonpolar side
chains buried  inside.  The  C-terminal  Y4 subdomain consists of a alpha/beta
fold with  two three-stranded beta sheets in the center flanked by three alpha
helices and a 3(10) helix (see <PDB:7RQG>) [4].

The profile we developed covers the entire CoV Nsp3 Y domain.

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.
-Last update: April 2023 / Text and profile revised.

[ 1] Lei J., Kusov Y., Hilgenfeld R.
     "Nsp3 of coronaviruses: Structures and functions of a large
     multi-domain protein."
     Antiviral. Res. 149:58-74(2018).
     PubMed=29128390; DOI=10.1016/j.antiviral.2017.11.001
[ 2] Neuman B.W., Joseph J.S., Saikatendu K.S., Serrano P., Chatterjee A.,
     Johnson M.A., Liao L., Klaus J.P., Yates J.R. III, Wuethrich K.,
     Stevens R.C., Buchmeier M.J., Kuhn P.
     "Proteomics analysis unravels the functional repertoire of coronavirus
     nonstructural protein 3."
     J. Virol. 82:5279-5294(2008).
     PubMed=18367524; DOI=10.1128/JVI.02631-07
[ 3] Neuman B.W.
     "Bioinformatics and functional analyses of coronavirus nonstructural
     proteins involved in the formation of replicative organelles."
     Antiviral. Res. 135:97-107(2016).
     PubMed=27743916; DOI=10.1016/j.antiviral.2016.10.005
[ 4] Mascaro G., Cadario G., Bordin G., Tarditi M., Ferraris G.,
     Monteverde A., Castano L., Monteverde A.
     "Plasma exchange in the treatment of nonadvanced stages of progressive
     systemic  sclerosis."
     J. Clin. Apher. 3:219-225(1987).
     PubMed=3680193; DOI=10.1002/jca.2920030406
[E1] https://viralzone.expasy.org/30?outline=all_by_species

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