Research Progress of the Mechanisms of Semipersistent Viruses Transmission by Vectors

Abstract

Abstract: Most of plant viruses are transmitted by insect vectors. Hemipteran is the most common vector which spread viruses in nonpersistent, semipersistent and persistent manner. The complex interactions between vector and virus can be classified into two general mechanisms. One is capsid mechanism and other one is helper mechanism. Semipersistent transmitted viruses mainly belong to Closteroviridae, Caulimoviridae, Flexiviridae and Sequiviridae. In recent years, the mechanism of the virus transmission, especially of semipersistent viruses transmission, has attracted an extensive attention. This paper summarizes the research progress of the mechanisms of semipersistent viruses transmission by vectors.

Key words: Semipersistent viruses, Vector transmission, The capsid mechanism, The helper mechanism

Tian Xiao,Li Lingdi,Liu Jinxiang,. Research Progress of the Mechanisms of Semipersistent Viruses Transmission by Vectors[J]. Biotechnology Bulletin, 2013, 0(7): 48-53.

References

[1] 胡淑霞. 论植物病毒的传播介体及传播方式[J]. 生物学杂志, 1997, 14（79）：33-34.
[2] Gray SM, Banerjee N. Mechanisms of arthropod transmission of plant and animal viruses[J]. Microbiol Mol Biol Rev, 1999, 63（1）：128-148.
[3] 梁小波, 鲁瑞芳, 吴云锋, 彭学贤. 植物病毒昆虫介体传播的研究进展[J]. 生物工程进展, 2001, 21（4）：11-17.
[4] 范在丰, 李怀方, 韩成贵, 等译校, 赫尔R,著. 马修斯植物病毒学[M]. 第4版.北京：北京科学出版社, 2007：533-586.
[5] Tian T, Rubio L, Yeh HH, et al. Lettuce infectious yellows virus in vitro：acquisition analysis using partially purified virions and the whitefly Bemisia tabaci[J]. J Gen Virol, 1999（80）：1111-1117.
[6] Satyanarayana T, Goeda S, Ayllón MA, et al. Closterovirus bipolar virion：Evidence for initiation of assembly by minor coat protein and its restriction to the genomic RNA 5'region[J]. PNAS, 2004, 101（3）：799-804.
[7] Drucker M, Froissart R, Hébrard E, et al. Intracellular distribution of viral gene products regulates a complex mechanism of cauliflower mosaic virus acquisition by its aphid vector[J]. PNAS, 2002, 99（4）：2422-2427.
[8] Peremyslov VV, Andreev IA, Prokhnevsky AI, et al. Complex molecular architecture of beet yellows virus particles[J]. PNAS, 2004, 101（14）：5030 -5035.
[9] Druka A, Burns T, Zhang SL, Hull R. Immunological characterization of rice tungro spherical virus coat proteins and differentiation of isolates from the Philippines and India[J]. J Gen Virol, 1996（77）：1975-1983.
[10] Hibino H, Cabauatan PQ. Infectivity neutralization of rice tungro-associated viruses acquired by vector leafhoppers[J]. Phytopathology, 1987, 77（3）：473-476.
[11] Khelifa M, Journou S, Krishnan K, et al. Electron-lucent inclusion bodies are structures specialized for aphid transmission of Caulifl-ower mosaic virus[J]. J Gen Virol, 2007（88）：2872-2880.
[12] Chen AYS, Walker GP, Carter D, Ng JCK. A virus capsid component mediates virion retention and transmission by its insect vector[J]. PNAS, 2011（08）：16777-16782.
[13] Martinière A, Gargani D, Uzest M, et al. A role for plant microtubules in the formation of transmission-specific inclusion bodies of Cauli-flower mosaic virus[J]. Plant J, 2009（58）：135-146.
[14] Hoh F, Uzest M, Drucker M, et al. Structural insights into the mole-cular mechanisms of cauliflower mosaic virus transmission by its insect vector[J]. J Virol, 2010（84）：4706-4713.
[15] Ng JCK, Falk BW. Virus-vector interactions mediating nonpersistent and semipersistent transmission of plant viruses[J]. Annu Rev Phytopathol, 2006（44）：183-212.
[16] Stewart LR, Medina V, Tian TY, et al. A mutation in the lettuce infectious yellows virus minor coat protein disrupts whitely transmission but not in planta systemic movement[J]. J Virol, 2010（84）：12165-12173.
[17] 史晓斌, 谢文, 张友军. 植物病毒病媒介昆虫的传毒特性和机制研究进展[J]. 昆虫学报, 2012, 55（7）：841-848.
[18] Uzest M, Gargani D, Drucker M, et al. A protein key to plant virus transmission at the tip of the insect vector stylet[J]. PNAS, 2007, 104（46）：17959-17964.
[19] Leh V, Jacquot E, Geldreich A, et al. Interaction between the open reading frame III product and the coat protein is required for transmission of cauliflower mosaic virus by aphids[J]. J Virol, 2001, 75（1）：100-106.
[20] Plisson C, Uzest M, Drucker M, et al. Structure of the mature p3-virus particle complex of cauliflower mosaic virus revealed by cryo-electron microscopy[J]. J Mol Biol, 2005（346）：267-277.
[21] Moreno A, Hébrard E, Uzest M, et al. A single amino acid position in the helper component of cauliflower mosaic virus can change the sp-ectrum of transmitting vector species[J]. J Virol, 2005, 79（21）：13587-13593.
[22] Blanc S, Uzest M, Drucker M. New research horizons in vector-transmission of plant viruses[J]. Microbiology, 2011（14）：483-491.
[23] Hunt RE, Nault LR, Gingery RE. Evidence for infectivity of maize chlorotic dwarf virus and for a helper component in its leafhopper transmission[J]. Phytopathology, 1998, 78（4）：499-504.
[24] Chaouch-Hamada R, Redinbaugh MG, Gingery RE, et al. Accumulation of maize chlorotic dwarf virus proteins in its plant host and leafhopper vector[J]. Virology, 2004（325）：379-388.
[25] Jones MC, Gough K, Dasgupta I, et al. Rice tungro disease is caused by an RNA and a DNA virus[J]. J Gene Virol, 1991（72）：757-761.
[26] Hibino H. Bioloy and epidemiology of rice viruses[J]. Annu Rev Phytopathol, 1996（34）：249-274.
[27] Hibino H, Roechan M, Sudarisman S. Association of two types of virus particles with prnyakit habang（tungro disease）of rice in Indonesia[J]. Phytopathology, 1978（68）：1412-1416.
[28] Murant AF, Roberts IM, Elnagar S. Association of virus-like particles with the foregut of the aphid Cavariella aegopodii transmitting the semipersistent viruses anthriscus yellows and parsnip yellow fleck[J]. J Gen Virol, 1976（31）：47-57.
[29] Perry KL, Zhang L, Palukaitis P. Amino acid changes in the coat protein of cucumber mosaic virus differentially affect transmission by the aphids Myzus persicae and Aphis gossypii[J]. Virology, 1998（242）：204-210.
[30] Liu SJ, He XH, Park G, et al. A conserved capsid protein surface domain of cucumber mosaic virus is essential for efficient aphid vector transmission[J]. J Virol, 2002, 76（19）：9756-9762.
[31] Soto MJ, Chen LF, Seo Y, Gilbertson RL. Identification of regions of the beet mild curly top virus（family Geminiviridae）capsid protein involved in systemic infection, virion formation and leafhopper transmission[J]. Virology, 2005（341）：257-270.
[32] Blanc S, López-moya J, Wang RY, et al. A specific interaction between coat protein and helper component correlates with aphid transmission of a Potyvirus[J]. Virol, 1997, 231（1）：141-147.
[33] Savenkov EI, Valkonen JPT. Potyviral helper-component proteinase expressed in transgenic plants enhances titers of potato leaf roll virus but does not alleviate its phloem limitation[J]. Virology, 2001（283）：285-293.
[34] Maia IG, Haenni A, Bernardi F. Potyviral HC-Pro：a multifunctio-nal protein[J]. J Gen Virol, 1996（77）：1335-1341.
[35] 李玲娣, 田晓, 刘金香. 蚜虫体内柑桔衰退病毒分子生物学检测研究进展[J]. 中国南方果树, 2012, 41（4）：42-46.
[36] 刘金香, 周常勇, 周彦, 等. 柑橘衰退病毒研究进展[C]//中国植物病理学会2006年学术年会论文集. 北京：中国农业科学技术出版社, 2006：164-172.
[37] 周彦, 周常勇, 王雪峰, 等. 柑橘衰退病毒分离株分子特征初步研究[J]. 植物病理学报, 2005, 35（6）：147-150.
[38] Albiach-martí MR, Guerri J, de Mendoza AH, et al. Aphid transmi-ssion alters the genomic and defective RNA populations of Citrus tristeza virus isolates[J]. Virol, 2000, 90（2）：134-138.
[39] Herron CM, Mirkov TE, da Graca JV, Lee RF. Citrus tristeza virus transmission by the Toxoptera citricida vector：In vitro acquisition and transmission and infectivity immunoneutralization experiments[J]. J Virolo Methods, 2006（134）：205-211.
[40] Barzegar A, Rahimian H, Sohi HH. Comparison of the minor coat protein gene sequences of aphidtransmissible and -nontransmissible isolates of Citrus tristeza virus[J]. J Gen Plant Pathol, 2010（76）：143-151.
[41] He X, Harper K, Grantham G, et al. Serological characterization of the 3 -proximal encoded proteins of beet yellows closterovirus[J]. Arch Virol, 1998（143）：1349-1363.