NUCLEOTIDE SEQUENCES OF SEGMENT FIVE OF THE EGYPTIAN BANANA BUNCHY TOP BABUVIRUS
Abstract
Banana and plantains (Musa sp.) are the most important staple food and source of carbohydrates in different geographical regions mainly in Africa. The productivity of banana crop is attacked by many pests and diseases. Banana bunchy top babuvirus (BBTV) is the most destructive viral disease because it has an enormous negative impact on the productivity of banana in all of bananacultivated- countries in the world. Accordingly, in this study we are focusing on the molecular characterization of the full length of the Egyptian isolate of BBTV DNA-5. The full length of BBTV DNA-5 was synthesized via polymerase chain reaction (PCR) then manipulated and cloned into pGEM-T easy vector and sequenced. The size of the full length of DNA-5 was 1017 nucleotides (nts) which includes one open reading frame (ORF) of 489 nts. The nucleotide sequences of the full length of DNA-5 of the Egyptian isolate was aligned with those of seven overseas isolates (three isolates from India, two from Taiwan and one from Hainan). Results showed that the major outcome of this alignment was restricted in two groups, the first group called Asian group that comprised Taiwan 1, Taiwan 2 and the second group contained the Egyptian, Indian 1, Indian 2, Australian and Hainan isolates that formed the South Pacific group. As a conclusion, one can recommend that a strategy of PCR detection of BBTV could be introduced as an early step for controlling such virus based on the nucleotide sequence of the Egyptian BBTV Q-DNA-5 beside the other published sequences.References
Amati, B. and Vlach, J. (1999). Kip1 meets SKP2: new links in cell cycle control. Natural of Cell Biology 1: 91-93.
Anonymous, (2001). Rwanda development indicators 2001. Ministry of Economy and Finance, 4:28-33.
Aronson, M. N., A. D. Meyer, J. Gyorgyey, L. Katul, H. J. Vetten, B. Gronenborn, and T. Timchenko (2000). Clink, a nanovirusencoded protein, binds both pRB and SKP1. Journal of Virology, 74: 2967-2972.
Beetham, P. R., G. J. Hafner, R. M. Harding and J. L. Dale (1997). Two mRNAs are transcribed from banana bunchy top virus DNA-1. Journal of General Virology, 78: 229-236.
Beetham, P. R., R. M. Hading, and J. L. Dale (1999). Banana bunchy top virus DNA-2 to 6 are monocistronic. Archives of Virology, 144: 89- 105.
Bisheng, W., L. Qihao, B. S. Wang and Q. H. Luo (1997). The important diseases of banana. Guangdong Province and Methods of Control. South China Fruits, 26: 33-36.
Burns, T. M., R. M. Harding and J. L. Dale (1995). The genome organization of banana bunchy top virus: analysis of six ssDNA components. Journal of General Virology, 76: 1471-1482.
Dale, J. L. (1987). Banana bunchy top, an economically important tropical plant virus disease. Advances in Virus Research, 33: 301-325.
Dugdale, B., P. R. Beetham, K. Becker, R. M Harding and J. L. Dale (1998). Promoter activity associated with the intergenic regions of banana bunchy top virus DNA-1 to -6 in transgenic tobacco and banana cells. Journal of General Virology, 79: 2301-2311.
Gronenborn, B. (2004). Nanoviruses: genome organisation and protein function. Veterinary Microbiology, 98: 103-109.
Hafner, G. J., M. R. Stafford, L. C. Wolter, R.M. Harding and J.L. Dale (1997). Nicking and joining activity of banana bunchy top virus replication protein in vitro. Journal of General Virology, 78: 1795- 1799.
Hammond, J. and R. W. Hammond, (1989). Molecular cloning, sequencing and expression in Escherichia coli of the bean yellow mosaic virus coat protein gene. Journal of General Virology, 70: 1961-1974.
Harding, R. M., T. M. Burns and J. L. Dale (1991). Virus-like particles associated with banana bunchy top disease contain small singlestranded DNA. Journal of General Virology, 72: 225-230.
Harding, R. M., A. Bahieldin, A. S. Sadik, and J. L. Dale (2000). A sensitive detection of banana bunchy top nanovirus using molecular genetic approaches. Arab Journal of Biotechnology, 3: 103-114.
Karan, M., R. M. Harding and J. L. Dale (1997). Association of banana bunchy top virus DNA components 1 to 6 with all infections. Molecular Plant Pathology On- Line, http://www.bspp.org.uk/mppol/1997/0624karan
Karan, M., R. M. Harding and J. L. Dale (1994). Evidence for two groups of banana bunchy top virus isolates. Journal of General Virology, 75: 3541-3546.
Katul, L., T. Timchenko, B. Gronenborn, and H. J. Vetten (1998). Ten distinct circular ssDNA components, four of which encode putative replication-associated proteins, are associated with the faba bean necrotic yellows virus genome. Journal of General Virology, 79: 3101–3109.
Nour El-Din Hanan A., M. I. Saloama, A. B. Barakat, A. M Saleim and A. S. Sadik (2005). Nucleotide sequence of BBTV-cp gene and using its fusion protein for producing specific polyclonal antibodies. Arab Journal of Biotechnology, 8: 355-368.
Piertersen, G. and J. E. Thomas (2001). Overview of Musa virus diseases. Plant virology in Sub-Saharan Africa Conference, p 50-60.
Sadik, A. S., M. I. Salama and M. A. Madkour (1999). Purification and partial characterization of an Egyptian isolate of banana bunchy top virus. Arab Journal of Biotechnology 2: 181-192.
Sambrook, J., E. F. Fritsch and T. Maniatis (1989). Molecular Cloning: A Laboratory Manual Cold Spring Harbor Laboratory, Cold Spring Harbor, New York.
Wanitchakorn, R., R. M. Harding and J. L. Dale (2000a). Sequence variability in the coat protein gene of two groups of banana bunchy top virus isolates. Archives of Virology 145: 593-602.
Wanitchakorn, R., G. J. Hafner, R. M. Harding and J. L. Dale (2000b). Functional analysis of proteins encoded by banana bunchy top virus DNA-4 to -6. Journal of General Virology, 81: 299-306.
Wanitchakorn, R., R. M. Harding and J. L. Dale (1997). Banana bunchy top virus DNA-3 encodes the viral coat protein. Archives of Virology, 142: 1673-1680.
Wu, R. Y. and H. J. Su (1990). An ELISA kit for banana bunchy top virus. J. of Phytopathology, 128:153.
