Interaction of the vaccinia virus nucleoside triphosphate phosphohydrolase I with linear oligonucleotides

Structural Basis of Poxvirus Transcription: Transcribing and Capping Vaccinia Complexes

Poxviruses use virus-encoded multisubunit RNA polymerases (vRNAPs) and RNA-processing factors to generate m⁷G-capped mRNAs in the host cytoplasm. In the accompanying paper, we report structures of core and complete vRNAP complexes of the prototypic Vaccinia poxvirus (Grimm et al., 2019; in this issue of Cell). Here, we present the cryo-electron microscopy (cryo-EM) structures of Vaccinia vRNAP in the form of a transcribing elongation complex and in the form of a co-transcriptional capping complex that contains the viral capping enzyme (CE). The trifunctional CE forms two mobile modules that bind the polymerase surface around the RNA exit tunnel. RNA extends from the vRNAP active site through this tunnel and into the active site of the CE triphosphatase. Structural comparisons suggest that growing RNA triggers large-scale rearrangements on the surface of the transcription machinery during the transition from transcription initiation to RNA capping and elongation. Our structures unravel the basis for synthesis and co-transcriptional modification of poxvirus RNA.

Nucleoside Triphosphate Phosphohydrolase I (NPH I) Functions as a 5' to 3' Translocase in Transcription Termination of Vaccinia Early Genes

Vaccinia virus early genes are transcribed immediately upon infection. Nucleoside triphosphate phosphohydrolase I (NPH I) is an essential component of the early gene transcription complex. NPH I hydrolyzes ATP to release transcripts during transcription termination. The ATPase activity of NPH I requires single-stranded (ss) DNA as a cofactor; however, the source of this cofactor within the transcription complex is not known. Based on available structures of transcription complexes it has been hypothesized that the ssDNA cofactor is obtained from the unpaired non-template strand within the transcription bubble. In vitro transcription on templates that lack portions of the non-template strand within the transcription bubble showed that the upstream portion of the transcription bubble is required for efficient NPH I-mediated transcript release. Complementarity between the template and non-template strands in this region is also required for NPH I-mediated transcript release. This observation complicates locating the source of the ssDNA cofactor within the transcription complex because removal of the non-template strand also disrupts transcription bubble reannealing. Prior studies have shown that ssRNA binds to NPH I, but it does not activate ATPase activity. Chimeric transcription templates with RNA in the non-template strand confirm that the source of the ssDNA cofactor for NPH I is the upstream portion of the non-template strand in the transcription bubble. Consistent with this conclusion we also show that isolated NPH I acts as a 5' to 3' translocase on single-stranded DNA.

Vaccinia virus early gene transcription termination factors VTF and Rap94 interact with the U9 termination motif in the nascent RNA in a transcription ternary complex

The vaccinia virus core contains a 195 kb double stranded DNA genome, a multi-subunit RNA polymerase, transcription initiation and termination factors and mRNA processing enzymes. Upon infection, vaccinia virus early gene transcription takes place in the virus core. Transcription initiates at early promoters and terminates in response to a termination motif, UUUUUNU, in the nascent mRNA. Early gene transcription termination requires the vaccinia virus termination factor, VTF, a single stranded DNA-dependent ATPase, and NPH I, the Rap94 subunit of the virion RNA polymerase, as well as the presence of the UUUUUNU motif in the nascent RNA. The position of UUUUUNU in the ternary complex suggests that it serves as a site of interaction with one or more components of the transcription termination complex. In order to identify the factor(s) that interact with UUUUUNU a series of direct UV photo crosslinking and ribonuclease A protection studies were undertaken. Through these analyses both VTF and Rap94 were shown to interact with UUUUUNU in the isolated ternary complex. Evidence indicates that the interaction is not mutually exclusive. VTF was shown to bind to UUUUUNU through the N-terminal domain of the large D1 subunit. Furthermore, VTF protects from RNAse A digestion both the 5' region of the nascent transcript as well as a large central component containing UUUUUNU. The addition of an oligonucleotide containing the (5Br)U9 sequence both directly inhibits transcription termination, in vitro and inhibits UV photo crosslinking of VTF to the nascent RNA in the ternary complex. These results support a model in which the availability of the UUUUUNU motif outside of the transcribing RNA polymerase permits binding of both transcription termination factors, VTF and Rap94, to UUUUUNU. The assembly of this termination complex initiates the transcription termination sequence.

Determinants of vaccinia virus early gene transcription termination

Vaccinia virus early gene transcription requires the vaccinia termination factor, VTF, nucleoside triphosphate phosphohydrolase I, NPH I, ATP, the virion RNA polymerase, and the motif, UUUUUNU, in the nascent RNA, found within 30 to 50 bases from the poly A addition site, in vivo. In this study, the relationships among the vaccinia early gene transcription termination efficiency, termination motif specificity, and the elongation rate were investigated. A low transcription elongation rate maximizes termination efficiency and minimizes specificity for the UUUUUNU motif. Positioning the termination motif over a 63 base area upstream from the RNA polymerase allowed efficient transcript release, demonstrating a remarkable plasticity in the transcription termination complex. Efficient transcript release was observed during ongoing transcription, independent of VTF or UUUUUNU, but requiring both NPH I and either ATP or dATP. This argues for a two step model: the specifying step, requiring both VTF and UUUUUNU, and the energy-dependent step employing NPH I and ATP. Evaluation of NPH I mutants for the ability to stimulate transcription elongation demonstrated that ATPase activity and a stable interaction between NPH I and the Rap94 subunit of the viral RNA polymerase are required. These observations demonstrate that NPH I is a component of the elongating RNA polymerase, which is catalytically active during transcription elongation.

Effect of UTP sugar and base modifications on vaccinia virus early gene transcription

Prior efforts demonstrated that RNA oligonucleotides containing the transcription termination signal UUUUUNU stimulate premature termination of vaccinia virus early gene transcription, in vitro. This observation suggests that viral transcription termination may be an attractive target for the development of anti-poxvirus agents. Since short RNA molecules are readily susceptible to nuclease digestion, their use would require stabilizing modifications. In order to evaluate the effect of both ribose and uracil modifications of the U5NU signal on early gene transcription termination, UTP derivatives harboring modifications to the uracil base, the 2' position of the ribose sugar and the phosphodiester bond were examined in an in vitro vaccinia virus early gene transcription termination system. Incorporation of 4-S-U, 5-methyl-U, 2-S-U, pseudo U and 2'-F-dU into the nascent transcript inhibited transcription termination. 6-aza-U, 2'-amino-U, 2'-azido-U and 2'-O methyl-U inhibited transcription elongation resulting in the accumulation of short transcripts. The majority of the short transcripts remained in the ternary complex and could be chased into full-length transcripts. Initially, derivatives of all uridines in the termination signal were tested. Partial modification of the termination signal reduced termination activity, as well. Introduction of 2'-O methyl ribose to the first three uridines of the U9 termination signal reduced the ability of U9 containing oligonucleotides to stimulate in vitro transcription termination, in trans. Further modifications eliminated this activity. Thus, viral early gene transcription termination demonstrates a rigorous requirement for a U5NU signal that is unable to tolerate modification to the base or sugar. Additionally, VTF was shown to enhance transcription elongation through the T9 sequence in the template. These results suggest that VTF may play a subtle role in early gene transcription elongation in addition to its known function in mRNA cap formation, early gene transcription termination and intermediate gene transcription initiation.

UUUUUNU stimulation of vaccinia virus early gene transcription termination. Oligonucleotide sequence and structural requirements for stimulation of premature termination in vitro

Vaccinia virus early genes are unique in that transcription terminates in a signal- and factor-dependent manner. Recent results from this laboratory demonstrated that a 22-mer RNA oligonucleotide containing a central U9 sequence exhibited sequence- and concentration-dependent stimulation of premature transcription termination and transcript release in trans. In an effort to better understand the different aspects of the U5NU stimulation of premature termination, we evaluated the activity of various oligonucleotides in vitro. Neither RNA containing a mutant U5NU signal nor single-stranded DNA containing T5NT was able to stimulate premature termination, demonstrating both sequence specificity and a requirement for ribose. Furthermore, neither oligonucleotide was able to compete with U5NU, demonstrating that each failed to bind to the U5NU recognition factor. Substitution of the U9 signal with either BrU9 or BrdU9 inhibited normal termination but did not stimulate premature termination. The addition of BrdU5NdU inhibited U5NU stimulation of premature termination, demonstrating that both oligonucleotides bind to the same site on the U5NU recognition factor. Finally, U5NU containing RNA as short as nine bases served as an effective stimulator of premature termination. These observations impact directly on the development of oligonucleotide based anti-poxvirus therapeutic agents.

Effect of selected mutations in the C-terminal region of the vaccinia virus nucleoside triphosphate phosphohydrolase I on binding to the H4L subunit of the viral RNA polymerase and early gene transcription termination in vitro

Vaccinia virus nucleoside triphosphate phosphohydrolase I (NPH I) is an essential early gene transcription termination factor. The C-terminal end of NPH I binds to the N-terminal end of the H4L subunit (RAP94) of the virion RNA polymerase. This interaction is required for transcription termination and transcript release. To refine our understanding of the specific amino acids in the C-terminal end of NPH I involved in binding to H4L, and to develop a collection of mutations exhibiting various degrees of activity to be employed in in vivo studies, we prepared a set of short deletions, and clustered substitutions of charged amino acids to alanine, or bulky hydrophobic amino acids to alanine mutations. These NPH I mutant proteins were expressed, purified, and tested for ATPase activity, binding to H4L, and transcription termination activity. Most mutations in amino acids 609 to 631 exhibited reduced activity. Deletion of the terminal five amino acids (627-631), or substitution of Y(629) with alanine or glutamic acid, dramatically reduced NPH I mediated transcription termination. Deletion of the terminal F(631), or substitution of F(631) with alanine, reduced binding to H4L and eliminated termination activity. These observations demonstrate that the terminal five amino acids directly participate in binding to RNA polymerase and in early gene transcription termination.

UUUUUNU oligonucleotide stimulation of vaccinia virus early gene transcription termination, in trans

Vaccinia virus early gene transcription termination requires the vaccinia termination factor (VTF), NPH I, a single stranded DNA-dependent ATPase, the virion form of RNA polymerase containing the Rap 94 subunit, and the signal UUUUUNU, which resides in the nascent mRNA, located 30 to 50 bases upstream from the poly(A) addition site. Evidence indicates that a required termination factor acts through binding to the UUUUUNU signal. To further investigate the function of UUUUUNU, the ability of UUUUUNU containing oligonucleotides to inhibit transcription termination was tested. A 22-mer RNA oligonucleotide containing a central U9 sequence exhibited sequence and concentration-dependent stimulation of premature transcription termination and transcript release, in trans. Activation of premature termination required VTF, NPH I, Rap 94, and ATP, demonstrating that the normal termination machinery was employed. Premature termination was not stimulated by RNA harboring a mutant UUUUUNU, demonstrating specificity. These data are consistent with a model in which a required termination factor is converted from an inactive to an active form by binding to a UUUUUNU containing oligonucleotide. The active termination factor then interacts with the ternary complex stimulating transcription termination through the normal mechanism, independent of the nascent mRNA sequence.

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.

Interaction between nucleoside triphosphate phosphohydrolase I and the H4L subunit of the viral RNA polymerase is required for vaccinia virus early gene transcript release

Signal-dependent termination is restricted to early poxvirus genes whose transcription is catalyzed by the virion form of RNA polymerase. Two termination factors have been identified. Vaccinia termination factor/capping enzyme is a multifunctional heterodimer that also catalyzes the first three steps of mRNA cap formation and is an essential intermediate gene transcription initiation factor. Nucleoside triphosphate phosphohydrolase I (NPH I) is a single-stranded DNA-dependent ATPase. COOH-terminal deletion mutations of NPH I retain both ATPase and DNA binding activities but are unable either to terminate transcription or to act as dominant negative mutants in vitro. One appealing model posits that the COOH-terminal region of NPH I binds to one or more components in the termination complex. In an attempt to identify NPH I-related protein/protein interactions involved in transcription termination, a series of pull-down experiments were done. Among several vaccinia virus proteins tested, the H4L subunit, unique to the virion form of RNA polymerase, was shown to bind glutathione S-transferase (GST)-NPH I. To further confirm this interaction in virus-infected cells, we constructed recombinant vaccinia virus, vNPHINGST, that expresses GST-tagged NPH I. The H4L subunit of virion RNA polymerase specifically co-purified with GST-NPH I, consistent with a physical interaction. Through the analysis of a series of NH(2)- and COOH-terminal truncation mutations of H4L, the NPH I interaction site was localized to the NH(2)-terminal 195 amino acids of the H4L protein. The H4L binding site on NPH I was mapped to the COOH-terminal region between 457 and 631. Furthermore, COOH-terminal deletion mutations of NPH I failed to bind the NH(2)-terminal region of H4L, explaining their inability to support transcription termination. The COOH-terminal end of NPH I was also shown to be required for transcript release activity and for dominant negative inhibition of release. The requirement for an essential interaction between NPH I and H4L provides an explanation for the observed restriction of transcription termination to early viral genes.