A polyadenylylation-specific RNA-contact site on the surface of the bifunctional vaccinia virus RNA modifying protein VP39 that is distinct from the mRNA 5' end-binding "cleft"

Domain-level rocking motion within a polymerase that translocates on single-stranded nucleic acid

Vaccinia virus poly(A) polymerase (VP55) is the only known polymerase that can translocate independently with respect to single-stranded nucleic acid (ssNA). Previously, its structure has only been solved in the context of the VP39 processivity factor. Here, a crystal structure of unliganded monomeric VP55 has been solved to 2.86 Å resolution, showing the first backbone structural isoforms among either VP55 or its processivity factor (VP39). Backbone differences between the two molecules of VP55 in the asymmetric unit indicated that unliganded monomeric VP55 can undergo a `rocking' motion of the N-terminal domain with respect to the other two domains, which may be `rigidified' upon VP39 docking. This observation is consistent with previously demonstrated experimental molecular dynamics of the monomer during translocation with respect to nucleic acid and with different mechanisms of translocation in the presence and absence of processivity factor VP39. Side-chain conformational changes in the absence of ligand were observed at a key primer contact site and at the catalytic center of VP55. The current structure completes the trio of possible structural forms for VP55 and VP39, namely the VP39 monomer, the VP39-VP55 heterodimer and the VP55 monomer.

Comparative whole genome sequence analysis of wild-type and cidofovir-resistant monkeypoxvirus

We performed whole genome sequencing of a cidofovir {[(S)-1-(3-hydroxy-2-phosphonylmethoxy-propyl) cytosine] [HPMPC]}-resistant (CDV-R) strain of Monkeypoxvirus (MPV). Whole-genome comparison with the wild-type (WT) strain revealed 55 single-nucleotide polymorphisms (SNPs) and one tandem-repeat contraction. Over one-third of all identified SNPs were located within genes comprising the poxvirus replication complex, including the DNA polymerase, RNA polymerase, mRNA capping methyltransferase, DNA processivity factor, and poly-A polymerase. Four polymorphic sites were found within the DNA polymerase gene. DNA polymerase mutations observed at positions 314 and 684 in MPV were consistent with CDV-R loci previously identified in Vaccinia virus (VACV). These data suggest the mechanism of CDV resistance may be highly conserved across Orthopoxvirus (OPV) species. SNPs were also identified within virulence genes such as the A-type inclusion protein, serine protease inhibitor-like protein SPI-3, Schlafen ATPase and thymidylate kinase, among others. Aberrant chain extension induced by CDV may lead to diverse alterations in gene expression and viral replication that may result in both adaptive and attenuating mutations. Defining the potential contribution of substitutions in the replication complex and RNA processing machinery reported here may yield further insight into CDV resistance and may augment current therapeutic development strategies.

Polymerase translocation with respect to single-stranded nucleic acid: looping or wrapping of primer around a poly(A) polymerase

Vaccinia virus protein VP55 translocates continuously with respect to single-stranded nucleic acid while extending its 3'end. Here, all key sites of polymerase-primer interaction were identified, demonstrating the wrapping or looping of polyadenylation primer around the polymerase during translocation. Side-chain substitutions at one of the sites indicated its requirement for tail extension beyond approximately 12 nucleotides in length, and conformational changes observed upon oligonucleotide binding suggested allosteric connectivity during translocation. Conformational changes in VP39 upon VP55 binding suggested that, within the VP55-VP39 complex, VP39's mRNA 5' cap binding site closes. The crystallographic structure showed a PAPase catalytic center without side-chain substitutions, possessing two metal ions and with all known reactive and catalytic groups represented, fitting a classical two-metal ion mechanism for phosphoryl transfer.

Saltatory Forward Movement of a Poly(A) Polymerase during Poly(A) Tail Addition

Vaccinia poly(A) polymerase (VP55) interacts with > or = 33-nucleotide (nt) primers via uridylates at two sites (-27/-26 and -10). It adds approximately 30-nt poly(A) tails with a rapid, processive burst in which the first few nt are added without substantial primer movement, and addition of the remaining adenylates is dependent upon a six-uridylate tract at the extreme 3' end of the primer and accompanied by polymerase translocation. Interaction of VP55 with 2-aminopurine (2-AP)-containing primers was associated with a 3-fold enhancement in 2-AP fluorescence. In stopped-flow experiments, fluorescence intensity changed with time during the polyadenylation burst in a manner dependent upon the position of 2-AP, indicating a non-uniform isomerization of the polymerase-primer complex with time consistent with a discontinuous (saltatory) translocation mechanism. Three distinct translocatory phases could be discerned: a -10(U)-binding site forward movement, a -27/-26(UU)-binding site jump to -10, then a -27/-26(UU)-binding site movement further downstream. Poly(A) tail elongation showed no apparent pauses during these isomerizations. Fluorescence changes during polyadenylation of 2-AP-containing primers with short preformed oligo(A) tails reinforced the above observations. Primers composed entirely of oligo(U) (apart from the 2-AP sensor), in which the polymerase modules might be most able to "slide" uniformly, also showed the characteristic saltatory pattern of translocation. These data indicate, for the first time, a discontinuous mode of translocation for a non-templated polymerase.

Crystal structures of the vaccinia virus polyadenylate polymerase heterodimer: insights into ATP selectivity and processivity

Polyadenylation of mRNAs in poxviruses, crucial for virion maturation, is carried out by a poly(A) polymerase heterodimer composed of a catalytic component, VP55, and a processivity factor, VP39. The ATP-gamma-S bound and unbound crystal structures of the vaccinia polymerase reveal an unusual architecture for VP55 that comprises of N-terminal, central or catalytic, and C-terminal domains with different topologies and that differs from many polymerases, including the eukaryotic poly(A) polymerases. Residues in the active site of VP55, located between the catalytic and C-terminal domains, make specific interactions with the adenine of the ATP analog, establishing the molecular basis of ATP recognition. VP55's concave surface docks the globular VP39. A model for RNA primer binding that involves all three VP55 domains and VP39 is proposed. The model supports biochemical evidence that VP39 functions as a processivity factor by partially enclosing the RNA primer at the heterodimer interface.

Regulation of viral transcription elongation and termination during vaccinia virus infection

Vaccinia virus provides a useful genetic and biochemical tool for studies of the basic mechanisms of eukaryotic transcription. Vaccinia genes are transcribed in three successive gene classes during infection, early, intermediate, and late. Vaccinia transcription is regulated primarily by virus gene products not only during initiation, but also during elongation and termination. The factors and mechanisms regulating early elongation and termination differ from those regulating intermediate and late gene expression. Control of transcription elongation and termination in vaccinia virus bears some similarity to the same process in other prokaryotic and eukaryotic systems, yet features some novel mechanisms as well.

The "cap-binding slot" of an mRNA cap-binding protein: quantitative effects of aromatic side chain choice in the double-stacking sandwich with cap

The N7-methylguanine portion of the mRNA cap structure interacts with cap-binding proteins via an unusual double-stacking arrangement in which the positively charged cap is sandwiched between two parallel-oriented aromatic protein side chains. Three-dimensional costructures of cap with two mRNA cap-binding proteins, namely, translational initiation factor eIF4E and VP39 (the vaccinia virus-encoded mRNA cap-specific 2'-O-methyltransferase), have heretofore been reported. Despite striking similarities between the two proteins in the double stack with the cap, the stack differs most notably in the species of stacked side chain donated by the protein. Whereas eIF4E employs two tryptophans, VP39 uses a tyrosine and a phenylalanine. Here, we have generated tryptophan substitutions in VP39. Tryptophan substitution was shown, crystallographically, not to disrupt the maintenance of a bona fide parallel stack. However, the single-tryptophan and double-tryptophan substitutions were associated with increased affinity for cap nucleoside by factors of 10 and 50, respectively. VP39 interacted more strongly with a true substrate (containing portions of RNA downstream of the cap in addition to the cap itself) than with isolated cap nucleoside, by several orders of magnitude. VP39 mutants with tryptophan substitution at position 180 exhibited apparent defects in substrate catalytic rate during the first turnover cycle, indicating the possibility of an exquisite sensitivity of the catalytic center to subtle changes in substrate position brought about by alterations in the cap-binding slot. The X-ray structure of VP39 with a genuine nucleobase analogue of N7-methylguanosine, namely, N7,9-dimethylguanine, indicated that the N7-methylguanosine rotational orientation within the stack is a property of the cap nucleobase itself.

Path of an RNA ligand around the surface of the vaccinia VP39 subunit of its cognate VP39-VP55 protein heterodimer

VP39 is a vaccinia virus-encoded RNA modifying protein with roles in the modification of both mRNA ends. At the 3' end it acts as a processivity factor for the vaccinia poly(A) polymerase (VP55), promoting poly(A) tail elongation. Despite VP39's three-dimensional structure having been elucidated along with details of its mode of mRNA 5' end binding, the VP39-VP55 heterodimer's molecular mechanism of processivity is largely unknown. Here, the area immediately above almost the entire surface of the VP39 subunit was probed using chemical reporters, and the path of a previously unidentified RNA binding site was revealed. The path was indicated to fall within a cleft formed by the intersubunit interface and was consistent with both a previously reported model of the heterodimer-nucleic acid ternary complex and the known function of the heterodimer in processive poly(A) tail elongation.

RNA binding characteristics and overall topology of the vaccinia poly(A) polymerase-processivity factor-primer complex

The vaccinia virus-encoded heterodimer responsible for poly(A) tail elongation comprises a polyadenylylation catalytic subunit (VP55) and associated processivity factor (VP39). We show that monomeric VP39's affinity for RNA homopolymers follows the hierarchy poly(I) >poly(U) >>poly(G) >poly(A) >poly(C), that the heterodimer interacts stably with 40-45 nucleotide nucleic acid segments, and that its homopolymer preference for polyadenylylation priming is comparable to the VP39 affinity hierarchy (above). For oligonucleotide ligands possessing the previously-identified (rU)2-(N)25-rU heterodimer-binding motif, the heterodimer's affinity and base-type preference are mediated via both the (rU)2and rU portions, with the greater contribution coming from (rU)2. VP39's R107 sidechain contributes to specificity at the downstream rU. Substitution of each ribouridylate of the motif with either ribothymidine or 4-thiodeoxythymidine indicated that the downstream rU interacts with both heterodimer subunits, whereas the upstream (rU)2interacts only with VP55. A 'crosslinking SELEX' approach indicated VP39-base proximity around position -10 of a 4-thioribouridine/deoxycytidine ligand pool. Upon incubating the heterodimer with a panel of identical-sequence oligonucleotides derivatized with azidophenacyl bromide at various phosphate positions, those derivatized at positions -11 to -21 photocrosslinked to both subunits in a coordinated manner. This region may therefore pass through a 'cleft' or enclosed 'channel' at the subunit interface.