Interaction between the J3R subunit of vaccinia virus poly(A) polymerase and the H4L subunit of the viral RNA polymerase

Investigations of Single-Subunit tRNA Methyltransferases from Yeast

tRNA methylations, including base modification and 2'-O-methylation of ribose moiety, play critical roles in the structural stabilization of tRNAs and the fidelity and efficiency of protein translation. These modifications are catalyzed by tRNA methyltransferases (TRMs). Some of the TRMs from yeast can fully function only by a single subunit. In this study, after performing the primary bioinformatic analyses, the progress of the studies of yeast single-subunit TRMs, as well as the studies of their homologues from yeast and other types of eukaryotes and the corresponding TRMs from other types of organisms was systematically reviewed, which will facilitate the understanding of the evolutionary origin of functional diversity of eukaryotic single-subunit TRM.

Orthopoxvirus targets for the development of new antiviral agents

Investments in the development of new drugs for orthopoxvirus infections have fostered new avenues of research, provided an improved understanding of orthopoxvirus biology and yielded new therapies that are currently progressing through clinical trials. These broad-based efforts have also resulted in the identification of new inhibitors of orthopoxvirus replication that target many different stages of viral replication cycle. This review will discuss progress in the development of new anti-poxvirus drugs and the identification of new molecular targets that can be exploited for the development of new inhibitors. The prototype of the orthopoxvirus group is vaccinia virus and its replication cycle will be discussed in detail noting specific viral functions and their associated gene products that have the potential to serve as new targets for drug development. Progress that has been achieved in recent years should yield new drugs for the treatment of these infections and might also reveal new approaches for antiviral drug development with other viruses.

Poxvirus transcription

Most DNA viruses selfishly exploit the cellular transcription machinery of infected cells. Poxviruses are unique among DNA viruses in that they encode the majority of the enzymes required for RNA synthesis. Poxviruses are large DNA viruses that replicate entirely within the cytoplasmic compartment of the cell, and they encode their own multisubunit RNA polymerase and gene-specific transcription and termination factors. The virus-encoded RNA polymerase has sequence and structural homology to eukaryotic RNA polymerases. Virus-encoded and cellular proteins regulate promoter specificity by recruiting the viral RNA polymerase to one of three different classes of genes. Functional interplay between viral and cellular transcription factors in viral gene regulation represents a new frontier in poxvirus biology. Targeting these transcription systems may serve as an undeveloped and potent antiviral strategy to combat poxvirus infections.

Poxvirus proteomics and virus-host protein interactions

Studies of the functional proteins encoded by the poxvirus genome provide information about the composition of the virus as well as individual virus-virus protein and virus-host protein interactions, which provides insight into viral pathogenesis and drug discovery. Widely used proteomic techniques to identify and characterize specific protein-protein interactions include yeast two-hybrid studies and coimmunoprecipitations. Recently, various mass spectrometry techniques have been employed to identify viral protein components of larger complexes. These methods, combined with structural studies, can provide new information about the putative functions of viral proteins as well as insights into virus-host interaction dynamics. For viral proteins of unknown function, identification of either viral or host binding partners provides clues about their putative function. In this review, we discuss poxvirus proteomics, including the use of proteomic methodologies to identify viral components and virus-host protein interactions. High-throughput global protein expression studies using protein chip technology as well as new methods for validating putative protein-protein interactions are also discussed.

Interaction of the vaccinia virus RNA polymerase-associated 94-kilodalton protein with the early transcription factor

A multisubunit RNA polymerase (RPO) encoded by vaccinia virus (VACV), in conjunction with specific factors, transcribes early, intermediate, and late viral genes. However, an additional virus-encoded polypeptide referred to as the RPO-associated protein of 94 kDa (RAP94) is tightly bound to the RPO for the transcription of early genes. Unlike the eight RPO core subunits, RAP94 is synthesized exclusively at late times after infection. Furthermore, RAP94 is necessary for the packaging of RPO and other components needed for early transcription in assembling virus particles. The direct association of RAP94 with NPH I, a DNA-dependent ATPase required for transcription termination, and the multifunctional poly(A) polymerase small subunit/2'-O-methyltransferase/elongation factor was previously demonstrated. That RAP94 provides a structural and functional link between the core RPO and the VACV early transcription factor (VETF) has been suspected but not previously demonstrated. Using VACV recombinants that constitutively or inducibly express VETF subunits and RAP94 with affinity tags, we showed that (i) VETF associates only with RPO containing RAP94 in vivo and in vitro, (ii) the association of RAP94 with VETF requires both subunits of the latter, (iii) neither viral DNA nor other virus-encoded late proteins are required for the interaction of RAP94 with VETF and core RPO subunits, (iv) different domains of RAP94 bind VETF and core subunits of RPO, and (v) NPH I and VETF bind independently and possibly simultaneously to the N-terminal region of RAP94. Thus, RAP94 provides the bridge between the RPO and proteins needed for transcription initiation, elongation, and termination.

Genomic sequence of a clonal isolate of the vaccinia virus Lister strain employed for smallpox vaccination in France and its comparison to other orthopoxviruses

Since 1980 there has been global eradication of smallpox due to the success of the vaccination programme using vaccinia virus (VACV). During the eradication period, distinct VACV strains circulated, the Lister strain being the most commonly employed in Europe. Analysis of the safety of smallpox vaccines has suggested that they display significant heterogeneity. To gain a more detailed understanding of the diversity of VACV strains it is important to determine their genomic sequences. Although the sequences of three isolates of the Japanese Lister original strain (VACV-LO) are available, no analysis of the relationship of any Lister sequence compared to other VACV genomes has been reported. Here, we describe the sequence of a representative clonal isolate of the Lister vaccine (VACV-List) used to inoculate the French population. The coding capacity of VACV-List was compared to other VACV strains. The 201 open reading frames (ORFs) were annotated in the VACV-List genome based on protein size, genomic localization and prior characterization of many ORFs. Eleven ORFs were recognized as pseudogenes as they were truncated or fragmented counterparts of larger ORFs in other orthopoxviruses (OPVs). The VACV-List genome also contains several ORFs that have not been annotated in other VACVs but were found in other OPVs. VACV-List and VACV-LO displayed a high level of nucleotide sequence similarity. Compared to the Copenhagen strain of VACV, the VACV-List sequence diverged in three main regions, one of them corresponding to a substitution in VACV-List with coxpox virus GRI-90 strain ORFs, suggestive of prior genetic exchanges. These studies highlight the heterogeneity between VACV strains and provide a basis to better understand differences in safety and efficacy of smallpox vaccines.

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.