Advance in Herpesvirus US10 gene and its encoded protein
ZHANG Dai-xi, CHENG An-chun, WANG Ming-shu
Avian Diseases Research Center, College of Veterinary Medicine, Sichuan Agricultural University/Key Laboratory of Animal Diseases and Human Health of Sichuan Province/Institute of Preventive Veterinary Medicine, Sichuan Agricultural University, Chengdu 611130, China
Abstract:US10 gene of Herpesvirus is located in the short unique region of its genome and not essential for virus replication. US10 gene encodes a phosphorylated tegument-capsid associated protein or type I transmembrane glycoprotein which selectively targets the cytoplasmic tail of HLA-G,a kind of nonclassical class I MHC molecular, to reduce and block the host NK cell cytotoxicity in immune evasion. US10 can also interact with host proteins to play a pathogenic role and regulate the expression of other viral proteins such as glycoprotein E (gE). Through further research, the role of US10 in virulence and its ability to combine with RNA and regulate transcription can be judged in the future.
张代熙, 程安春, 汪铭书. 疱疹病毒US10基因及其编码蛋白研究进展[J]. 中国人兽共患病学报, 2017, 33(1): 61-66.
ZHANG Dai-xi, CHENG An-chun, WANG Ming-shu. Advance in Herpesvirus US10 gene and its encoded protein. Chinese Journal of Zoonoses, 2017, 33(1): 61-66.
[1] King AMQ, Lefkowitz E, Adams MJ, et al. Virus taxonomy: ninth report of the International Committee on taxonomy of viruses[M]. San Diego: Elsevier Academic Press, 2011. [2] Yuan GP, Cheng AC, Wang MS, et al. Electron microscopic studies of the morphogenesis of duck enteritis virus[J]. Avian Dis, 2005, 49(1): 50-55. [3] Guo YF, Cheng AC, Wang MS, et al. Purification of anatid herpesvirus 1 particles by tangential-flow ultrafiltration and sucrose gradient ultracentrifugation[J]. J Virol Methods, 2009, 161(1): 1-6. [4] Arvin AM. Human herpesviruses: biology, therapy, and immunoprophylaxis[M]. Cambridge: Cambridge University Press, 2007, 1(Pt 2): 10-26. [5] Wu Y, Cheng AC, Wang MS, et al. Comparative genomic analysis of duck enteritis virus strains[J]. J Virol, 2012, 86(24): 13841-13842. [6] Hu Y, Zhou HoB, Yu ZJ, et al. Characterization of the genes encoding complete US10, SORF3, and US2 proteins from duck enteritis virus[J]. Virus Genes, 2009, 38(2): 295-301. [7] Wu Y, Cheng AC, Wang MS, et al. Complete genomic sequence of Chinese virulent duck enteritis virus[J]. J Virol, 2012, 86(10): 5965-5965. [8] Vittone V, Diefenbach E, Triffett D, et al. Determination of interactions between tegument proteins of herpes simplex virus type 1[J]. J Virol, 2005, 79(15): 9566-9571. [9] Furman MH, Dey N, Tortorella D, et al. The human cytomegalovirus US10 gene product delays trafficking of major histocompatibility complex class I molecules[J]. J Virol, 2002, 76(22): 11753-11756. [10] Park B, Spooner E, Houser BL, et al. The HCMV membrane glycoprotein US10 selectively targets HLA-G for degradation[J]. J Exper Med, 2010, 207(9): 2033-2041. [11] Thureen DR, Keeler CL. Psittacid herpesvirus 1 and infectious laryngotracheitis virus: comparative genome sequence analysis of two avian alphaherpesviruses[J]. J Virol, 2006, 80(16): 7863-7872. [12] Liu C, Guo W, Lu G, et al. Complete genomic sequence of an equine herpesvirus type 8 WH strain isolated from China[J]. J Virol, 2012, 86(9): 5407-5407. [13] Cohrs RJ, Hurley MP, Gilden DH. Array analysis of viral gene transcription during lytic infection of cells in tissue culture with varicella-zoster virus[J]. J Virol, 2003, 77(21): 11718-11732. [14] Tyler SD, Peters GA, Severini A. Complete genome sequence of cercopithecine herpesvirus 2 (SA8) and comparison with other simplexviruses[J]. Virology, 2005, 331(2): 429-440. [15] Severini A, Tyler SD, Peters GA, et al. Genome sequence of a chimpanzee herpesvirus and its relation to other primate alphaherpesviruses[J]. Archives Virol, 2013, 158(8): 1825-1828. [16] Macdonald SJ, Mostafa HH, Morrison LA, et al. Genome sequence of herpes simplex virus 1 strain McKrae[J]. J Virol, 2012, 86(17): 9540-9541. [17] Liu X, Han Z, Shao Y, et al. Different linkages in the long and short regions of the genomes of duck enteritis virus Clone-03 and VAC Strains[J]. Virol J, 2010, 8(1): 1-12. [18] Watson G, Xu W, Reed A, et al. Sequence and comparative analysis of the genome of HSV-1 strain McKrae[J]. Virology, 2012, 433(2): 528-537. [19] García M, Volkening J, Riblet S, et al. Genomic sequence analysis of the United States infectious laryngotracheitis vaccine strains chicken embryo origin (CEO) and tissue culture origin (TCO)[J]. Virology, 2013, 440(1): 64-74. [20] Yang C, Li Q, Li J, et al. Comparative genomic sequence analysis between a standard challenge strain and a vaccine strain of duck enteritis virus in China[J]. Virus Genes, 2014, 48(2): 296-303. [21] Gruffat H, Marchione R, Manet E. Herpesvirus late gene expression: a viral-specific Pre-Initiation Complex is key[J]. Front Microbiol, 2016, 7: 869. [22] Qin H, Cheng AC, Wang MS, et al. Replication kinetics of duck enteritis virus UL16 gene in vitro[J]. Virol J, 2012, 9(1): 1-4. [23] Gao J, Cheng AC, Wang MS, et al. Identification and characterization of the duck enteritis virus (DEV) US2 gene[J]. Genet Mol Res, 2015, 14(4): 13779-13790. [24] Holden VR, Yalamanchili RR, Harty RN, et al. Identification and characterization of an equine herpesvirus 1 late gene encoding a potential zinc finger[J]. Virology, 1992, 188(2): 704-713. [25] Yamada H, Daikoku T, Yamashita Y, et al. The product of the US10 gene of herpes simplex virus type 1 is a capsid/tegument-associated phosphoprotein which copurifies with the nuclear matrix[J]. J General Virol 1997, 78(11): 2923-2931. [26] Zhao Y, Wang JW, Liu F, et al. Molecular analysis of US10, S3, and US2 in duck enteritis virus[J]. Virus Genes, 2009, 38(2): 243-248. [27] Huber MT, Tomazin R, Wisner T, et al. Human cytomegalovirus US7, US8, US9, and US10 are cytoplasmic glycoproteins, not found at cell surfaces, and US9 does not mediate cell-to-cell spread[J]. J Virol, 2002, 76(11): 5748-5758. [28] Mao WF. Characterizing chicken stem cell antigen 2, a putative marek's disease resistant gene[D]. Michigan: Michigan State University, 2010. [29] Amiot L, Vu N, Samson M. Immunomodulatory properties of HLA-G in infectious diseases[J]. Res J Immunol, 2014, 2014(2014): 143-146. [30] Kaur G, Trowsdale J, Fugger L. Natural killer cells and their receptors in multiple sclerosis[J]. Brain, 2013, 136(Pt 9): 2657-2676. [31] Alegre E, Rizzo R, Bortolotti D, et al. Some basic aspects of HLA-G biology[J]. J Immunol Res, 2014, 2014(1): 657625-657625. [32] Gao H, Cui H, Cui X, et al. Expression of HA of HPAI H5N1 virus at US2 gene insertion site of turkey herpesvirus induced better protection than that at US10 gene insertion site[J]. PLoS One, 2010, 6(7): 3007-3024. [33] Zhang F, Chen W, Ma C, et al. Transcriptional activity comparison of different sites in recombinant Marek's disease virus for the expression of the H9N2 avian influenza virus hemagglutinin gene[J]. J Virologic Methods, 2014, 207: 138-145. [34] Hildebrandt E, Dunn JR, Perumbakkam S, et al. Characterizing the molecular basis of attenuation of Marek's disease virus via in vitro serial passage identifies de novo mutations in the helicase-primase subunit gene UL5 and other candidates associated with reduced virulence[J]. J Virol, 2014, 88(11): 6232-6242. [35] Mao W, Hunt HD, Cheng HH. Cloning and functional characterization of chicken stem cell antigen 2[J]. Developmental Comparat Immunol, 2010, 34(3): 360-368. [36] Liu HC, Niikura M, Fulton JE, et al. Identification of chicken lymphocyte antigen 6 complex, locus E (LY6E, alias SCA2) as a putative Marek?s disease resistance gene via a virus-host protein interaction screen[J]. Cytogenet Genome Res, 2004, 102(1-4): 304-308. [37] Sommer MH, Zagha E, Serrano OK, et al. Mutational analysis of the repeated open reading frames, ORFs 63 and 70 and ORFs 64 and 69, of varicella-zoster virus[J]. J Virol, 2001, 75(17): 8224-8239. [38] Grose C, Tyler S, Peters G, et al. Complete DNA sequence analyses of the first two Varicella-Zoster virus glycoprotein E (D150N) mutant viruses found in North America: Evolution of genotypes with an accelerated cell spread phenotype[J]. J Virol, 2004, 78(13): 6799-6807.