DEVELOPMENT OF RAPD AND ISSR MARKERS FOR DROUGHT TOLERANCE IN SUGARCANE (Saccharum officinarum L.)

Authors

  • EMAN M. FAHMY Genetic Dept., Fac. Agriculture, Ain Shams University, Cairo, Egypt
  • NERMIN M. ABD EL-GAWAD Genetic Dept., Fac. Agriculture, Ain Shams University, Cairo, Egypt
  • I. H. EL-GEDDAWY Sugar Crops Research Institute, Agricultural Research Centre (ARC), Giza, Egypt
  • O. M. SALEH National Centre for Radiation Research and Technology (NCRRT), Nasr City, Cairo, Egypt
  • NASRA M. EL-AZAB Sugar Crops Research Institute, Agricultural Research Centre (ARC), Giza, Egypt

Abstract

ugar amounts of cane represent 72% of the world production of crystallized sugar (FAO, 1999). In Egypt, sugarcane crop is one of the important industrial crops and it is the main source of sugar production. Moreover, it is widely used in Egypt for fresh juice consumption and molasses industry. Limitation of irrigation water led to minimizing the cultivated area of sugarcane, so, there is a very limited opportunity to increase it horizontally. Improving agricultural practices, in addition to developing new promising cultivars, became the possible ways of raising sugarcane production. Drought resistance is the ability of plant to resist all adverse conditions created by unfavorable phenomena related to water deficit (Clark et al., 1986). It is well known that sugarcane water requirements are very high compared to our limited share in River Nile, so studying the effect of drought is a major limiting factor in the production of field crops. One effective approach is to develop sugarcane varieties tolerant to drought stress (Abdel-Tawab et al., 1999). Biotechnology has been used as a tool to increase agricultural productivity in the context of sustainable agriculture (Tecson, 2002). Molecular markers have been used for studying genetic diversity, cultivar identification and for marker-assisted selection (MAS) of major crops such as rice, maize, wheat and sugarcane. Moreover, Molecular markers such as RFLP, RAPD, ISSR and SSR have recently shown excellent potentiality to assist selection of quantitive trait loci (QTLs) associated with these markers (Stuber, 1992). The developing of RAPD approach (Williams et al., 1990) has allowed simple, easy and less time-consuming genome analysis at DNA level compared with RFLP. The detection of molecular markers linked to many genes of interest has been widely achieved in this regard. RAPD-PCR as a simple and rapid procedure has gained a worldwide acceptance and application (Michelmore et al., 1991; Paran et al., 1991). Moreover, RAPD markers were detected for salt and drought stresses in sugarcane (Abdel-Tawab et al., 2003a&b; Piperidies et al., 2004), in wheat (Abdel- Tawab et al., 2003c), in maize (Abdel- Tawab et al., 2002) and in sorghum (Abdel-Tawab et al., 1998). ISSRs are semi-arbitrary markers amplified by PCR using a single primer composed of a microsatellite repeated sequences. Such amplification does not require genome sequence information and leads to multilocus and highly polymorphic patterns (Wolfe, 1998). Therefore, ISSRs have proven to be a powerful amplificationbased fingerprinting technique. The aim of this study was to obtain molecular markers for drought tolerance in sugarcane and to assess the genetic relationships among some of its varieties.

References

Abdel-Tawab, F. M., A. L. Allam, Eman M. Fahmy, A. Abo Doma, H. A. El Rashidy and A. H. Higgy (1999). Production of sugarcane strains tolerance to environmental stress by modern biotechnological me- thods. 1st International Conference on Sugar& Integrated Industries, Present and Future, Luxor, Egypt, 15-18 Feb., p. 499 -513.

Abdel-Tawab, F. M., Eman M. Fahmy, A.I. Allam, H. A. El-Rashidy and R. M. Shoaib (2003a). Development of RAPD and SSR marker asso- ciated with stress tolerance and some technological traits and tran- sient transformation of sugarcane (Saccharum spp.). Proc. Interna- tional Conf. The Arab Region and Africa in the World Sugar Context,10-12 March, Aswan, Egypt. p. 1-23.

Abdel-Tawab, F. M., Eman M. Fahmy, A.L. Allam, H.A. El Rashidy and R. M. Shoaib (2003b). Marker as- sisted selection for abiotic stress tolerance in sugarcane (Saccharum spp). Egypt. J. Agric. Res., 81:635- 646.

Abdel-Tawab, F. M., Eman M. Fahmy, A.Bahieldin, Asmahan A. Mahmoud, H. T. Mahfouz, Hala F. Eissa and O. Moseilhy (2003c). Marker- assisted selection for drought tolerance in Egyptian bread wheat (Triticum aestivum L.). Egyptian J. Genet. & Cytol., 31: 43-63.

Abdel-Tawab, F. M., Eman M. Fahmy, M. A. Rashed, Gh. A. Gad EL- Karim, S. H. Abdel-Aziz and S. E. Ibrahim (2002). Development of molecular markers for salt and drought tolerance in maize (Zea mays L.). Egyptian J. Genet. & Cytol., 32: 355-371.

Abdel-Tawab, F. M., M. A. Rashed, R. S.Dhindsa, A. Bahieldin, and A. Abo Doma (1998). Molecular markers for salt tolerance in Sorghum bicolor. International Congress on Molecular Genetics, 21-26 Feb., Cairo, Egypt.

Adawy, S. S., H. A. H. Ebtissam, M. M.Shaker and Hanaiya, A. El-Etriby (2004). Intra and inter varietals variation of Upper Egypt date palm varieties (Phoenix dactylifera L.) as revealed by RAPD and ISSR markers. Plant Molecular Breading, 1: 165-179.

Ceron, A. and F. Angel (2001). Genetic diversity in sugarcane hybrids in Colombia measured using mole- cular markers. Proc. Int. Soc. Su- garcane Technol. of North Amer- ica, 24: 626.

Clark, J. M., T. F. Towenley-Smith, T. N.McCaig and D. G. Green (1986). Growth analysis of spring wheat varieties of varying drought resistance. Crop Sci., 24, May- June.

Fahmy, Eman M., A. Abo Doma, A. M.A. Hameed, O. E. Elsayed and Magda A. M. El-Enany (2007). RAPD and ISSR markers related to drought tolerance in rice. Egypt. J. Genet. & Cytol., 36: 195-206.

FAO, Food and Agriculture Organization of the United Nations (1999). http://www.Fao.org.

Harvey, M. and F. C. Botha (1995). PCR- based methodologies for finger- printing sugarcane: use of random decamer, microsatellite and telo- mere sequences. Pric. Int. Soc. Sugarcane Technol. Assoc. 22nd Congr., 2: 299-302.

Maniatis, T., E. F. Fritch and J. Sambrook (1982). Molecular cloning; a laboratory manual. Cold Spring Harbor Laboratory Publisher, New York, USA.

Michelmore, R. W., I. Paran and R. V.Kesseli (1991). Identification of markers linked to disease-resis- tance genes by bulked segregate analyses. A rapid method to detect markers in specific region by using segregating population. Proc. Nat. Acad. Sci., 88: 9828-9832.

Oropeza, M., E. Garcia and E. De-Garcia (1997). Utilization of molecular markers for the identification of sugarcane varieties (Saccharum spp). Phyton. Buenos Aires, 61:

-85.

Paran, L., R. Kesseli and R. Michelmore (1991). Identification of restriction fragment length polymorphism and random amplified polymorphic DNA markers linked to downy mildew resistance genes in lettuce, using near-isogenic lines. Genome,

: 1021-1027.

Piperidies, G. A., R. Rattey, G. O. Taylor, M. C. Cox and D. M. Hogarth (2004). DNA markers: a tool for identifying sugarcane varieties. Conference of Australian Society of Sugarcane Technologists, Bris- bane, Queensland, Australia, 4-7 May.

Ratnaparkhe, M. B., M. Tekeoglu and F.J. Muehlbaure (1998). Inter-simple sequence repeats (ISSR) polymor- phisms are useful for finding markers associated with disease resistance gene clusters, Theor. Appl. Genet., 97: 515-519.

Reddy, M. P., N. Sarla and E. A. Siddiq (2002). Fourth International Rice Genetics Symposium, IRRI, Phil- ippines, Abstract, pp. 212.

Saghi-Maroof, M. A., K. Soliman and R.A. Jorgenson (1984). Ribosomal DNA spacer-length polymor- phisms in barley; Mendelian inhe- ritance, chromosomal location, and Population dynamic. Proc. Nat. Acad. Sci., 81:80/4-80/8.

Sambrok, J., E. F. Fritch and T. Maniatis (1989). Molecular cloning a labo- ratory manual. Cold Spring Har- bore Laboratory Press.

Snedecor, C. W. and W. G. Cochran (1969). Statistical methods. 6th Ed., Iowa State Univ. Ames Press, Iowa, USA.

Stuber, C. W. (1992). Biochemical and molecular markers in plant breed- ing. Plant Breeding Reviews, 9:

-61.

Tecson, E. M. (2002). Crop biotechnol-ogy in the Philippines. Ag Biotech

Net. 4 ABNO79, 1-7.

Ubayaseua, W. L. C. and A. L. T. Perera (1999). Assessment of genetic diversity within wild sugarcane germplasm using randomly amplified polymorphic DNA techniques (RAPD). Trop. Agric. Res., 11: 110-122.

Wagih, M. E., A. Ala and Y. Musa (2003). Biomass analysis and se- lection of sugarcane genotypes for drought tolerance. Sugarcane Technol., 5: 257-263.

Wagih, M. E., J. V. Kaiulo, A. Ala and Y. Musa (2001). Screening sugarcane varieties for drought tolerance. Science in New Guinea, 26: 38-45.

Williams, J. G. K, A. R. Kubelik, K. J.Livak, J. A. Rafalski and S. V. Tingey (1990). DNA polymor- phisms amplified by arbitrary primers are useful as genetic markers. Nucleic Acids Res., 18:

-6535.

Wolfe, A. D., Q. Y. Xiang and S. R. Kephart (1998). Assessing hybri- dization in natural populations of Penstemon (Scrophulariaceae) using hypervariable intersimple sequence repeat (ISSR) bands. Mol. Ecol., 7: 1107-1126.

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2016-01-13

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