Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.6.1.25 (
triphosphatase
)
1,529
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The replication and packaging of the rotavirus genome, comprising 11 segments of double-stranded RNA, take place in specialized compartments called viroplasms, which are formed during infection and involve a coordinated interplay of multiple components. Two rotavirus nonstructural proteins, NSP2 (with nucleoside
triphosphatase
, single-stranded RNA [ssRNA] binding and helix-destabilizing activities) and
NSP5
, are essential in these events. Previous structural analysis of NSP2 showed that it is an octamer in crystals, obeying 4-2-2 crystal symmetry, with a large 35-A central hole along the fourfold axis and deep grooves at one of the twofold axes. To ascertain that the solution structure of NSP2 is the same as that in the crystals and investigate how NSP2 interacts with
NSP5
and RNA, we carried out single-particle cryoelectron microscopy (cryo-EM) analysis of NSP2 alone and in complexes with
NSP5
and ssRNA at subnanometer resolution. Because full-length
NSP5
caused severe aggregation upon mixing with NSP2, the deletion construct NSP566-188 was used in these studies. Our studies show that the solution structure of NSP2 is same as the crystallographic octamer and that both NSP566-188 and ssRNA bind to the grooves in the octamer, which are lined by positively charged residues. The fitting of the NSP2 crystal structure to cryo-EM reconstructions of the complexes indicates that, in contrast to the binding of NSP566-188, the binding of RNA induces noticeable conformational changes in the NSP2 octamer. Consistent with the observation that both
NSP5
and RNA share the same binding site on the NSP2 octamer, filter binding assays showed that
NSP5
competes with ssRNA binding, indicating that one of the functions of
NSP5
is to regulate NSP2-RNA interactions during genome replication.
...
PMID:Cryoelectron microscopy structures of rotavirus NSP2-NSP5 and NSP2-RNA complexes: implications for genome replication. 1692 40
Interactions between
NSP5
and NSP2 drive the formation of viroplasms, sites of genome replication and packaging in rotavirus-infected cells. The serine-threonine-rich
NSP5
transitions between hypo- and hyper-phosphorylated isomers during the replication cycle. In this study, we determined that purified recombinant
NSP5
has a Mg2+-dependent ATP-specific
triphosphatase
activity that generates free ADP and Pi (Vmax of 19.33 fmol of product/min/pmol of enzyme). The ATPase activity was correlated with low levels of
NSP5
phosphorylation, suggestive of a possible link between ATP hydrolysis and an
NSP5
autokinase activity. Mutagenesis showed that the critical residue (Ser67) needed for
NSP5
hyperphosphorylation by cellular casein kinase-like enzymes has no role in the ATPase or autokinase activities of
NSP5
. Through its NDP kinase activity, the NSP2 octamer may support
NSP5
phosphorylation by creating a constant source of ATP molecules for the autokinase activity of
NSP5
and for cellular kinases associated with
NSP5
.
...
PMID:An ATPase activity associated with the rotavirus phosphoprotein NSP5. 1782 41
