The product of the UL31 gene of herpes simplex virus 1 is a nuclear phosphoprotein which partitions with the nuclear matrix.

The nucleotide sequence of the UL31 open reading frame is predicted to encode a basic protein with a hydrophilic amino terminus and a nuclear localization signal. To identify its gene product, we constructed a viral genome in which the thymidine kinase gene was inserted between the UL31 and UL32 open reading frames. The thymidine kinase gene was then deleted, and in the process, the 5' terminus of the UL31 open reading frame was replaced with a 64-bp sequence in frame with the complete, authentic sequence of the UL31 open reading frame. The inserted sequence encoded a hydrophilic epitope derived from glycoprotein B of human cytomegalovirus and for which a monoclonal antibody is available. We report that in infected cells, the tagged protein localized in and was dispersed throughout the nucleus. Nuclear fractionation studies revealed that the UL31 protein partitions with the nuclear matrix. The protein is phosphorylated in infected cells maintained in medium containing 32Pi.     

Bovine herpesvirus 1 UL49.5 homolog gene encodes a novel viral envelope protein that forms a disulfide-linked complex with a second virion structural protein.

We previously reported that the genome of bovine herpesvirus 1 (BHV-1) contains an open reading frame (ORF) homologous to the herpes simplex virus UL49.5 ORF, and as with the herpes simplex virus UL49.5 ORF, the deduced amino acid sequence of the BHV-1 UL49.5 homolog (UL49.5h) contains features characteristic of an integral membrane protein, implying that it may constitute a functional gene encoding a novel viral envelope protein. This communication reports on the identification of the BHV-1 UL49.5h gene product. By employing an antibody against a synthetic BHV-1 UL49.5h peptide and an UL49.5h gene deletion mutant, the primary product of BHV-UL49.5h gene was identified as a polypeptide with a size of approximately 9 kDa; in both infected cells and isolated virions, the UL49.5h products were found to exist in three forms; monomer, disulfide-linked homodimer, and disulfide-linked heterodimer containing a second viral protein with a size of about 39 kDa. O-Glycosidase digestion and [3H]glucosamine labelling experiments showed that the UL49.5h protein is not glycosylated. Although the deduced amino acid sequence contains putative sites for myristylation and phosphorylation, we were unable to detect either modification. Surface labelling and trypsin digestion protection experiments showed that the BHV-1 UL49.5h protein was present on the surface of infected cells and on the surface of mature virions. Nonionic detergent partition of isolated virions revealed that the UL49.5h protein is more tightly associated with the virion tegument-nucleocapsid structure than envelope protein gD. The results from this study demonstrate that the BHV-1 UL49.5h gene encodes a nonglycosylated virion envelope protein which may associate with virion internal structures by forming a complex with the 39-kDa virion structural protein.     

The UL49.5 gene of pseudorabies virus codes for an O-glycosylated structural protein of the viral envelope.

Sequence analysis of BamHI fragment 1 of the pseudorabies virus (PrV) genome identified a novel PrV gene located upstream of the UL50 gene encoding PrV dUTPase. The deduced protein product displayed homology to the product of the herpes simplex virus type 1 UL49.5 protein. The predicted PrV UL49.5 protein consists of 98 amino acids with a calculated molecular mass of 10,155 Da. It contains putative signal peptide and transmembrane domains but lacks a consensus sequence for N glycosylation. PrV UL49.5 was expressed as a fusion protein with glutathione S-transferase in Escherichia coli, and a rabbit antiserum was generated. In Western blots (immunoblots) of purified virions, the antiserum detected a protein with an apparent molecular mass of 14 kDa. After fractionation of the virions, the 14-kDa protein was detected in the envelope fraction. Localization of the UL49.5 protein in the viral envelope was confirmed by immunoelectron microscopy. The treatment of purified virions with glycosidases led to a reduction of the apparent molecular mass in Western blots by approximately 2 kDa following digestion with neuraminidase and O-glycosidase. Our results demonstrate that the PrV UL49.5 protein is an O-glycosylated structural component of the viral envelope. It represents the 10th PrV glycoprotein described. According to the unified nomenclature for alphaherpesvirus glycoproteins, we propose to designate it glycoprotein N (gN).     

Mutational analysis of the ICP4 binding sites in the 5'' transcribed noncoding domains of the herpes simplex virus 1 UL 49.5 gamma 2 gene.

A previous report (P. Mavromara-Nazos and B. Roizman, Proc. Natl. Acad. Sci. USA 86:4071-4075, 1989) demonstrated that substitution of sequences of the thymidine kinase (tk) gene, a beta gene, extending from -16 to +51 with sequences extending from -12 to +104 of the gamma 2 UL 49.5 gene in viral recombinant R3820 conferred upon the chimeric gene gamma 2 attributes in the context of the viral genome in a productive infection. The UL49.5 gene sequences extending from -179 to +104 contain four DNA binding sites for the major regulatory protein ICP4. Of these sites, two map between nucleotides +20 and +80 within the sequence which confers gamma 2 regulation upon the chimeric gene. To determine the role of these ICP4 binding sites in conferring the gamma 2 gene attributes, sequences comprising the two ICP4 binding sites were mutagenized and used to reconstruct the R3820 recombinant virus. In addition, a new recombinant virus (R8023) was constructed in which tk sequences extending from -240 to +51 were replaced with wild-type or mutated sequences contained between nucleotides -179 to +104 of the UL 49.5 gene. Vero cells infected with the recombinant viruses in the presence or absence of phosphonoacetate, a specific inhibitor of viral DNA synthesis, were then tested for accumulation of tk RNA by using an RNase protection assay. The results indicate that in the recombinant R3820, a mutation which destroyed one of the two UL49.5 ICP4 DNA binding sites significantly reduced the accumulation of tk RNA at both early and late times after infection. The effect of this mutation was less pronounced in cells infected with the R8023 virus, whose chimeric tk gene contains the two upstream UL49.5 ICP4 binding sites. None of the mutations affected the sensitivity of the chimeric genes to phosphonoacetate. The mutated site appears to be involved in the accumulation of RNA.     

Gene Arrangement within the Unique Long Genome Region of Infectious Laryngotracheitis Virus Is Distinct from That of Other Alphaherpesviruses

The genome of the avian alphaherpesvirus infectious laryngotracheitis virus (ILTV) comprises ca. 155 kbp of which ca. one-third have been sequenced so far. To gain additional sequence information we analyzed two stretches of 15.5 and 1.9 kbp of the ILTV unique long (U_L) genome region. The larger fragment contains homologs of the herpes simplex virus (HSV) UL23 (thymidine kinase) and UL22 (glycoprotein H) genes followed by five open reading frames (ORF) encoding putative proteins of 334 to 410 amino acids which exhibit no homology to any known herpesvirus protein. RNA analyses showed that these unique ILTV genes are indeed expressed. An origin of replication separates this cluster of unique genes from a conserved gene cluster consisting of the UL45, UL46, UL48, UL49, UL49.5, and UL50 homologs. The absence of UL47 from this position coincides with the localization of a UL47-homologous ORF within the unique short (U_S) region of the ILTV genome (M. Wild, S. Cook, and M. Cochran, Virus Genes 12:107–116, 1996). Within the second analyzed region the ILTV UL21 homolog was found adjacent to the UL44 gene. We thus identified five novel herpesvirus genes in ILTV and present evidence for a large internal inversion in the ILTV U_L region, in contrast to the collinear genomes of other alphaherpesviruses. Interestingly, a similar inversion is also present in the porcine alphaherpesvirus pseudorabies virus.     

Localization of a type-specific antigenic site on herpes simplex virus type 2 glycoprotein D.

A herpes simplex virus type 1 strain isolated from a recurrent lesion of the nose reacted with monoclonal antibodies recognizing a type 2-specific site on glycoprotein D but not with monoclonal antibodies recognizing other type 2-specific sites. DNA sequence analysis of the glycoprotein D gene of the isolate revealed a single nucleotide alteration which changed the codon for asparagine to one encoding histidine at amino acid 97 in the protein. Histidine is located at this position in glycoprotein of herpes simplex virus type 2; thus, the monoclonal antibody 17 beta A3 recognizes an epitope located at this region of the protein.     

A组轮状病毒SA11VP6基因的克隆和表达

从ＳＡ１１ＶＰ６基因全序列克隆开始,设计一对两端带有酶切位点的引物,逆转录ＰＣＲ扩增出ＶＰ６全基因ＣＤＮＡ。经酶切后插入ＰＵＣ１９,构建了ＶＰ６全基因克隆ＰＲＡ６。再经酶切后插入痘苗病毒载休质凿ＰＪＳＡ１１７５中。利用Ｌｉｐｏｆｅｃｔｉｎ导入ＴＫ１４３细胞,利用ＴＫ基因和Ｌａｃ基因作为重组病毒的筛选标记。表达产物用单克隆抗体ＥＬＩＳＡ法检测,发现细胞培养上清和细胞裂解液都是阳性。Ｗｅｓｔｅｒｎ ｂ     

The herpes simplex virus 1 gene encoding a protease also contains within its coding domain the gene encoding the more abundant substrate.

The herpes simplex virus 1 open reading frames UL26 and UL26.5 are 3' coterminal. The larger, UL26 open reading frame encodes a protein approximately 80,000 in apparent molecular weight and contains the promoter and coding sequence of the UL26.5 gene, which specifies a capsid protein designated infected cell protein 35. The larger product contains in its entirety the amino acid sequence of the smaller protein. We report that the UL26 gene encodes a protease which catalyzes its own cleavage and that of the more abundant product of UL26.5. By inserting the coding sequence of an epitope to a cytomegalovirus monoclonal antibody and homologs of the immunoglobulin G binding domain of staphylococcal protein A into the 3' termini of the coding domains of the two open reading frames, we identified both products of the cleavage and determined that the cleavage site is approximately 20 amino acids from the carboxyl termini of both proteins.     

Bruton酪氨酸激酶在昆虫细胞中表达的初步研究

用杆状病毒表达载体系统表达小鼠Ｂｒｕｔｏｎ酪氨酸激酶（Ｂｒｕｔｏｎｔｙｒｏｓｉｎｅｋｉｎａｓｅ,Ｂｔｋ）．构建重组转染载体时,于Ｂｔｋ起始码的上游插入了一段Ｈ９０２序列．用重组转染载体、苜蓿夜蛾核型多角体病毒线性ＤＮＡ和质脂体共转染Ｓｆ９昆虫细胞,经过对重组杆状病毒三轮扩增后,用Ｈ９０２抗体检测表明,昆虫细胞中Ｂｔｋ的表达已达最高水平．对表达后Ｂｔｋ自身磷酸化检测表明,该激酶具有自身磷酸化活性．从而证实Ｂｔｋ在昆虫细胞中的表达获得了成功     

The alpha subunit of type II Ca2+/calmodulin-dependent protein kinase is highly conserved in Drosophila

A monoclonal antibody against rat brain type II Ca2+/calmodulin-dependent protein kinase (CaM kinase) precipitates three proteins from Drosophila heads with apparent molecular weights similar to those of the subunits of the rat brain kinase. Fly heads also contain a CaM kinase activity that becomes partially independent of Ca2+ after autophosphorylation, as does the rat brain kinase. We have isolated a Drosophila cDNA encoding an amino acid sequence that is 77% identical to the sequence of the rat alpha subunit. All known autophosphorylation sites are conserved, including the site that controls Ca(2+)-independent activity. The gene encoding the cDNA is located between 102E and F on the fourth chromosome. The protein product of this gene is expressed at much higher levels in the fly head than in the body. Thus, both the amino acid sequence and the tissue specificity of the mammalian kinase are highly conserved in Drosophila.     

Labeling and Localization of the Herpes Simplex Virus Capsid Protein UL25 and Its Interaction with the Two Triplexes Closest to the Penton

The herpes simplex virus type 1 UL25 protein is one of seven viral proteins that are required for DNA cleavage and packaging. Together with UL17, UL25 forms part of an elongated molecule referred to as the C-capsid-specific component (CCSC). Five copies of the CCSC are located at each of the capsid vertices on DNA-containing capsids. To study the conformation of UL25 as it is folded on the capsid surface, we identified the sequence recognized by a UL25-specific monoclonal antibody and localized the epitope on the capsid surface by immunogold electron microscopy. The epitope mapped to amino acids 99-111 adjacent to the region of the protein (amino acids 1-50) that is required for capsid binding. In addition, cryo-EM reconstructions of C-capsids in which the green fluorescent protein (GFP) was fused within the N-terminus of UL25 localized the point of contact between UL25 and GFP. The result confirmed the modeled location of the UL25 protein in the CCSC density as the region that is distal to the penton with the N-terminus of UL25 making contact with the triplex one removed from the penton. Immunofluorescence experiments at early times during infection demonstrated that UL25-GFP was present on capsids located within the cytoplasm and adjacent to the nucleus. These results support the view that UL25 is present on incoming capsids with the capsid-binding domain of UL25 located on the surface of the mature DNA-containing capsid.     

Comparison between human cytomegalovirus pUL97 and murine cytomegalovirus (MCMV) pM97 expressed by MCMV and vaccinia virus: pM97 does not confer ganciclovir sensitivity

The UL97 protein (pUL97) of human cytomegalovirus (HCMV) is a protein kinase that also phosphorylates ganciclovir (GCV), but its biological function is not yet clear. The M97 protein (pM97) of mouse cytomegalovirus (MCMV) is the homolog of pUL97. First, we studied the consequences of genetic replacement of M97 by UL97. Using the infectious bacterial plasmid clone of the full-length MCMV genome (M. Wagner, S. Jonjic, U. H. Koszinowski, and M. Messerle, J. Virol. 73:7056-7060, 1999), we replaced the M97 gene with the UL97 gene and constructed an MCMV M97 deletion mutant and a revertant virus. In addition, pUL97 and pM97 were expressed by recombinant vaccinia virus to compare both for known functions. Remarkably, pM97 proved not to be the reason for the GCV sensitivity of MCMV. When expressed by the recombinant MCMV, however, pUL97 was phosphorylated and endowed MCMV with the capacity to phosphorylate GCV, thereby rendering MCMV more susceptible to GCV. We found that deletion of pM97, although it is not essential for MCMV replication, severely affected virus growth. This growth deficit was only partially amended by pUL97 expression. When expressed by recombinant vaccinia viruses, both proteins were phosphorylated and supported phosphorylation of GCV, but pUL97 was about 10 times more effective than pM97. One hint of the functional differences between the proteins was provided by the finding that pUL97 accumulates in the nucleus, whereas pM97 is predominantly located in the cytoplasm of infected cells. In vivo testing revealed that the UL97-MCMV recombinant should allow evaluation of novel antiviral drugs targeted to the UL97 protein of HCMV in mice.     

Identification and characterization of pseudorabies virus dUTPase.

Sequence analysis within the long segment of the pseudorabies virus (PrV) genome identified an open reading frame of 804 bp whose deduced protein product of 268 amino acids exhibited homology to dUTPases of other herpesviruses. The gene was designated UL50 because of its colinearity with the homologous gene of herpes simplex virus type 1. An antiserum raised against a bacterially expressed fragment of PrV UL50 specifically detected a 33-kDa protein in lysates of infected cells, which is in agreement with the predicted molecular mass of the PrV UL50 protein. A UL50-negative PrV mutant (PrV UL50-) was constructed by the insertion of a beta-galactosidase expression cassette into the UL50 coding sequence. A corresponding rescuant (PrV UL50resc) was also isolated. The interruption of the UL50 gene led to the disappearance of the 33-kDa protein, whereas restoration of UL50 gene expression restored detection of the 33-kDa protein. Enzyme activity assays confirmed that UL50 of PrV codes for a dUTPase which copurifies with nuclei of infected cells. PrV UL50- replicated with an only slightly reduced efficiency in epithelial cells in culture compared with that of its parental wild-type virus strain. Our results thus demonstrate that UL50 of PrV encodes a protein of 33 kDa with dUTPase activity which copurifies with nuclei of infected cells and is dispensable for replication in cultured epithelial cells.     

Identification and characterization of the pseudorabies virus UL3.5 protein, which is involved in virus egress.

Alphaherpesvirus genomes exhibit a generally collinear gene arrangement, and most of their genes are conserved among the different members of the subfamily. Among the exceptions is the UL3.5 gene of pseudorabies virus (PrV) for which positional homologs have been detected in the genomes of varicella-zoster virus, equine herpesvirus 1, and bovine herpesvirus 1 but not in the genomes of herpes simplex virus types 1 and 2. To identify and characterize the predicted 224 amino acid UL3.5 protein of PrV, a rabbit antiserum was prepared against a UL3.5 fusion protein expressed in Escherichia coli. In Western blot (immunoblot) analyses the antiserum detected a 30-kDa protein in the cytoplasm of PrV infected cells which was absent from purified virions. For functional analysis, UL3.5-expressing cell lines were established and virus mutants were isolated after the rescue of defective, glycoprotein B-negative PrV by insertion of the complementing glycoprotein B-encoding gene of bovine herpesvirus 1 at two sites within the UL3.5 locus. A PrV mutant carrying the insertion at codon 159 and expressing a truncated UL3.5 protein was still capable of efficient productive replication in noncomplementing cells. In contrast, a PrV mutant carrying the insertion at codon 10 of the UL3.5 gene did not express detectable UL3.5 protein and exhibited a dramatic growth deficiency on non-complementing cells with regard to plaque formation and one-step replication. Electron microscopical studies showed an accumulation of unenveloped capsids in the vicinity of the Golgi apparatus. This defect could be compensated by propagation on complementing UL3.5-expressing cell lines. Our results thus demonstrate that the PrV UL3.5 gene encodes a nonstructural protein which plays an important role in virus replication, presumably during virus egress. The functionally relevant domains appear to be located within the N-terminal part of the UL3.5 protein which also comprises the region exhibiting the highest level of homology between the predicted UL3.5 homologous proteins of other alphaherpesviruses.     

Activities of herpes simplex virus type 1 (HSV-1) ICP4 genes specifying nonsense peptides.

Synthetic oligonucleotide linkers containing translational termination codons in all possible reading frames were inserted at various positions in the cloned gene encoding the herpes simplex virus type 1 (HSV-1) immediate-early regulatory protein, ICP4. It was determined that the amino-terminal 60 percent of the ICP4 gene was sufficient for trans-induction of a thymidine kinase promoter-CAT chimera (pTKCAT) and negative regulation of an ICP4 promoter-CAT chimera (pIE3CAT); however, it was relatively inefficient in complementing an ICP4 deletion mutant. The amino-terminal ninety amino acids do not appear to be required for infectivity as reflected by the replication competence of a mutant virus containing a linker insertion at amino acid 12. The size of the ICP4 molecule expressed from the mutant virus was consistent with translational restart at the next methionine codon corresponding to amino acid 90 of the deduced ICP4 amino acid sequence.     

Human cytomegalovirus (HCMV) smallest capsid protein identified as product of short open reading frame located between HCMV UL48 and UL49.

The capsid of cytomegalovirus contains an abundant, low-molecular-weight protein whose coding sequence within the viral genome had not been identified. We have used a combination of biochemical and immunological techniques to demonstrate that this protein, called the smallest capsid protein in human cytomegalovirus, is encoded by a previously unidentified 225-bp open reading frame (ORF) located between ORFs UL48 and UL49. This short ORF, called UL48/49, is the positional homolog of herpes simplex virus ORF UL35 (encoding capsid protein VP26) and shows partial amino acid sequence identity to positional homologs in human herpes viruses 6 and 7.     

Identification and expression of a human cytomegalovirus glycoprotein with homology to the Epstein-Barr virus BXLF2 product, varicella-zoster virus gpIII, and herpes simplex virus type 1 glycoprotein H.

An open reading frame with the characteristics of a glycoprotein-coding sequence was identified by nucleotide sequencing of human cytomegalovirus (HCMV) genomic DNA. The predicted amino acid sequence was homologous with glycoprotein H of herpes simplex virus type 1 and the homologous protein of Epstein-Barr virus (BXLF2 gene product) and varicella-zoster virus (gpIII). Recombinant vaccinia viruses that expressed this gene were constructed. A glycoprotein of approximately 86 kilodaltons was immunoprecipitated from cells infected with the recombinant viruses and from HCMV-infected cells with a monoclonal antibody that efficiently neutralized HCMV infectivity. In HCMV-infected MRC5 cells, this glycoprotein was present on nuclear and cytoplasmic membranes, but in recombinant vaccinia virus-infected cells it accumulated predominantly on the nuclear membrane.     

Novel rearrangements of herpes simplex virus DNA sequences resulting from duplication of a sequence within the unique region of the L component.

We constructed insertion mutants of herpes simplex virus type 1 that contained a duplication of DNA sequences from the BamHI-L fragment (map units 0.706 to 0.744), which is located in the unique region of the L component (UL) of the herpes simplex virus type 1 genome. The second copy of the BamHI-L sequence was inserted in inverted orientation into the viral thymidine kinase gene (map units 0.30 to 0.32), also located within UL. A significant fraction of the progeny produced by these insertion mutants had genomes with rearranged DNA sequences, presumably resulting from intramolecular or intermolecular recombination between the BamHI-L sequences at the two different genomic locations. The rearranged genomes either had an inversion of the DNA sequence flanked by the duplication or were recombinant molecules in which different regions of the genome had been duplicated and deleted. Genomic rearrangements similar to those described here have been reported previously but only for herpes simplex virus insertion mutants containing an extra copy of the repetitive a sequence. Such rearrangements have not been reported for insertion mutants that contain duplications of herpes simplex virus DNA sequences from largely unique regions of the genome. The implications of these results are discussed.