P1 (~33 kilo
daltons (kDa) in molecular weight) is a
serine protease which facilitates its own cleavage from the polyprotein at the P1-HC-Pro junction. P1 consists of a conserved C-terminal protease domain and an N-terminal region which has a high level of variation in sequence and length between potyvirus species but exhibits conserved patterns of
intrinsic disorder. P1 is also promotes viral RNA replication, though it is not required for it.
HC-Pro (~52 KDa) is a
cysteine protease which cleaves a
glycine-glycine dipeptide at its own
C-terminus. HC-Pro's activity is regulated by the adjacent P1 protein: before P1 cleaves itself off the P1-HC-Pro intermediate, the P1 terminus reduces HC-Pro's RNA silencing suppression activity. Though the exact mechanism is unknown, HC-Pro has been proposed to attach to host aphid mouth parts through its N-terminal
zinc finger-like domain and anchor virions through its interactions with the capsid protein.
P3 (~41 kDa) is a membrane protein which is required for viral replication and accumulates in viral replication vesicles. It mediates the interactions between replication vesicles and movement complex proteins which may allow replication vesicles to be recruited to the movement complex for efficient intercellular movement. P3 also interacts with large subunit of the
ribulose-1,5-bisphosphate carboxylase/oxygenase.
CI (~71 kDa) is an RNA
helicase with
ATPase activity. Its most unusual property is its ability to form large and highly symmetrical conical and cylindrical inclusions with a central hollow cylinder from which laminate sheets radiate outward and fold in on themselves in a pattern often described as "
pinwheels". These inclusions are easily seen in
transmission electron micrographs of infected tissues and were historically used as a diagnostic criterion for potyvirus infections. CI inclusions are a major component of the potyviral movement complex which is assembled at
plasmodesmata. CI is also required for viral replication and is present on replication membranes. Its exact contributions to replication are not clear but, as an RNA helicase, CI is likely facilitating replication by dismantling the secondary structures of viral RNA.
NIa (~50 kDa) forms crystalline inclusions in the host nucleus. It is cleaved into NIa-Pro and VPg.
NIa-Pro (~27 kDa) is a
cysteine protease which processes most of the cleavage sites of the polyprotein. The only exceptions are the self-cleavages of P1 and HC-Pro. The high degree of cleavage sequence specificity and conservation has made NIa-Pro (often that of
Tobacco etch virus) a valuable tool in biotechnology, especially in applications which require removing
affinity tags from
recombinant proteins after
affinity purification. NIa-Pro has also shown to exhibit sequence-independent
DNase activity and to interfere with host
DNA methylation suggesting that NIa and/or NIa-Pro are altering in host
gene expression. Potyviral NIa-Pro shares a high level of homology with the
picornaviral 3C protease.
VPg (~22 kDa) is covalently attached to the 5' end of the viral genomic RNA through uridylation and is thought to act as a primer for viral genome replication similarly to the VPg proteins of
picornaviridae. It is a highly disordered protein and its flexibility has been suggested to allow it to interact with many other viral proteins. VPg also interacts with various host proteins including
eukaryotic initiation factor 4E (eIF4E), eukaryotic elongation factor 1A (eEF1A), and poly(A)-binding protein (PABP).
NIb (~59 kDa) is a superfamily II
RNA-dependent RNA polymerase (RdRp) which polymerises viral RNA during replication. Like NIa, NIb forms inclusions in the host nucleus where it is transported due to its two
nuclear localisation sequences. NIb has the three-domain "palm, thumb, and fingers" structure typical of RdRps.
6K1 (~6 kDa) the function is not known, but because it accumulates in replication vesicles and has a
transmembrane domain, 6K1 is thought to contribute to virus-induced vesicle formation.
6K2 (~6 kDa) is a
transmembrane protein which rearranges host membranes into virus-induced membrane structures. It interacts with various
ER exit site proteins to produce vesicular and tubular extensions which eventually mature into replication vesicles. 6K2 has three main domains: the N-terminal domain which is required for cell-to-cell movement, the central hydrophobic transmembrane
alpha helix, and the C terminal domain which is required for viral replication.
P3N-PIPO (~25 kDa) is a dedicated movement protein which anchors the movement complex to the
plasmodesma. It may also modulate the plasmodesmatal size exclusion limit by interacting with host proteins which sever plasmodesmatal
actin filaments and reduce
callose deposition. It interacts with both the large and small subunits of the ribulose-1,5-bisphosphate carboxylase/oxygenase.
CP (~30 - 35 kDa) is the capsid protein. It has two terminal domains which are disordered and exposed at the surface of the virion. The central core domain contains an RNA-binding pocket which binds to viral RNA. The structure of the capsid protein is highly conserved in potyviruses, though there is a relatively high degree of sequence variability. In addition to encapsidating the virion, CP core domain is required for intercellular movement and contributes to seed transmission. Certain atypical potyviruses code for additional proteins or protein domains, such as P1-PISPO,
Alkylation B (AlkB), and
inosine triphosphate pyrophosphatase (known as ITPase or HAM1). Such anomalies are often situated in the hypervariable P1-HC-Pro region. == Life cycle ==