There is a need to set up a germplasm resource centre or gene bank in Sabah to keep the collections of varieties of locally cultivated crops, especially rice. This is necessary to prevent genetic loss caused by the infrastructure development in the state of Sabah especially when Sabah is known for her rich genetic resources for food and agriculture. This gene bank will play an important role in the conservation of genetic resources especially for future rice crop improvement and development. These collections are known to carry useful gene(s) for crop improvement such as aroma, taste, resistance to insect pests and diseases, and tolerance to abiotic stress. Decades ago, a set of local landrace rice collection were made and conserved at International Rice Research Institute (IRRI) and Malaysia Agriculture Research and Development Institute (MARDI). Besides IRRI and MARDI, local farmers also play an important role as conservationist. Therefore, this study has been carried out to re ne the status of the current genetic diversity in local rice farming. From January 2009 to February 2010, 108 samples were collected from Tuaran and Kota Belud districts. Preliminary observation of 19 samples found that
there is a high genetic diversity based on seed morphology alone. Variations in the characteristics were detected in awn, apiculus, lemma and palea, sterile lemma and seed coat. Length and width of seeds were measured and calculated for ratio to estimate the shapes of the seeds. The weight of 100 grains ranged from 1.42 to 3.19 g. However, further studies on morphology evaluation, disease screening, and molecular evaluation are needed to be compared with the existing data. In addition, genetic erosion, migration, and drift also need to be studied due to high seed exchanges among the local farmers.
Crosses were made between four varieties ('Mahsuri', 'Setanjung", 'MR84" and 'MR103") of Oryza sativa L. (2n=24, AA) and one accession of O. minuta (2n= 8, BBCC). The seed set obtained ranged between 9.5% and 25.1% depending on the rice variety used. By rescuing 14-day-old embryos and culturing them on 25%-strength MS medium we obtained a total of 414 F1 hybrids. The F1s were vigorous, tillered profusely, were perennial and male-sterile. The hybrids were triploid (ABC) with 36 chromosomes and showed irregular meiosis. The average frequency and range of chromosome associations at metaphase I or early anaphase I pollen mother cells of F1 plants were 29.31(16-36) Is +3.32(0-10) IIs+0.016(0-1) IIIs+0.002(0-1) IVs. Upon backcrossing the original triploid hybrids and colchicine-treated hybrids to their respective recurrent parents, and further embryo rescue, 17 backcross-1 (BC1) plants were obtained. Of all the crosses using MR84, no BC1 plant was obtained even after pollinating 13 894 spikelets of the triploid hybrid. The BC1s were similar in appearence to the F1s and were male-sterile, their chromosome number ranged from 44 to 48. By backcrossing these BC1s and nurturing them through embryo rescue, we obtained 32 BC2 plants. Of these, however, only 18 plants grew vigorously. One of these plants has 24 chromosomes and the other 17 have chromosome numbers ranging between 30 and 37. The 24-chromosome plant was morphologically similar to the O. sativa parent and was partially fertile with a pollen and spikelet fertility of 58.8% and 12.5% respectively. All of the F1 and BC1 plants were found to be resistant to five Malaysian isolates (XO66, XO99, XO100, XO257 and XO319) of Xanthomonas campestris pv oryzae. Amongst the BC2s, the reaction varied from resistant to moderately susceptible. The 24-chromosome BC2 plant was resistant to the four isolates and moderately resistant to isolate XO100 to which the O. sativa parent was susceptible.