K K Vinod
[Following is the text of my short presentation made to my class at UNIVERSITY OF NEBRAKSA-LINCLON]
Rice is a semiaquatic annual grass belonging to the genus Oryza.
The genus oryza includes 24 species, of which 22 are wild and two namely Oryza
sativa and Oryza glaberrima are cultivated. O. sativa is
grown all over the world while Oryza glaberrima has been cultivated in West Africa for about 3500 years. There are more than
120,000 varieties of cultivated rice (IRRI, 2001). It is believed that rice
domestication occurred independently in China ,
India and Indonesia , thereby giving rise to three races of
rice: sinica (also known as japonica), indica and javanica (also known as bulu
in Indonesia ).
Cultivated rice is diploid (2n=24) and belongs to AA genome. The
sativa rice varieties of the world are commonly grouped into three
subspecies namely indica, japonica and javanica. Rice grown in India belongs
to the indica subspecies. They are characterised by having leaves
slightly pubescent and pale green in colour. Indicas are awnless or possess
short and smooth awns. The rice grown in Japan belongs to japonica
subspecies. Japonicas are adapted for cultivation in the subtropical and warm
temperate regions. Japonica varieties mostly have oval and round grains. They
may be awned or awnless. Leaves are narrow and dark green in colour. Subspecies
javanica is
characterised by a stiff straw, long panicle with awned grains, sparse
tillering habit, long duration and low sensitivity to difference in day length.
These are found mainly in Indonesia .
Rice was domesticated
more than 10,000 years ago is possibly one of the oldest domesticated species. Huke and Huke (1990) observes that the domestication of rice ranks
as one of the most important developments in history, for this grain has fed
more people over a longer period of time than has any other crop. Rice
is the staple cereal for more than 50% people (~3.25 billion) around the world,
cultivated in about 9% of the earth's arable land, which is the largest single
use of land for producing food. Rice provides 25 to
85 percent of the calories in the daily diet and 15% of per capita
protein (IRRI, 2002). In Asia , where rice is
the major energy providing food, it accounts for 50-80% of daily caloric intake,
especially among the poor (IRRI, 2001). Unlike other
major cultivated grains like wheat and corn which are also used for feeding
livestock, rice is exclusively used for human consumption.
With China , India
and Indonesia producing the
most of the world’s rice, Asia accounts for
over 90% of the world's production of rice. Only 6-7% of the world's rice crop
is traded in the world market. Production of rice in The United States accounts
to 1.5% of the world's production, with Arkansas ,
California and Louisiana
producing 80% of the U.S.
rice. Thailand , Vietnam , China
and the United States
are the world's largest exporters (IRRI, 2002).
Rice is the only
cereal that can be grown for long period in standing water. Even though
predominantly semi-aquatic, rice is grown under many different conditions and
production systems, including upland and dry conditions. (FAO, 2004a). 57% of the
world’s rice is grown on irrigated land, 25% on rainfed lowland, 10% on the
uplands, 6% in deepwater, and 2% in tidal wetlands (Chopra and Prakash, 2002).
The flooded rice paddy sustains rich aquatic biodiversity, providing a home for
fish, plants, amphibians, reptiles, mollusks, and crustaceans (FAO, 2004b).
Rice has many
characteristics, making it useful in various ways to be included in cereals,
snack foods, brewed beverages, flour, oil, syrup, flakes and religious
ceremonies. Rice grains can be short, medium and long or waxy (sticky) or
non-waxy. Some are aromatic (Alford and Duguid, 1998; Chaudhary et al.,
2001), some are colored including brown, red, purple and black (FAO, 2004c) and
some are of medicinal value. The variation in characteristics makes one variety
more popular in one region of the world than another.
Rice breeding
The primary
breeding objective in rice growing countries has been high yield potential. Plant
breeders have greatly contributed to the development of high-yielding crop
varieties and have changed the morphology and physiology of crop plants, and
incorporated desirable traits and resistant gene(s) into traditional varieties
while stabilizing or increasing crop production. Dramatic advancement in
productivity has achieved by incorporation of the semi-dwarf gene from Dee-Gee-Woo-Gen
into traditional tall, leafy rice. The semi-dwarf rice varieties are now planted
in 60% of the world's rice land.
High-yielding
varieties have made a great contribution to the world's food supply, but they
also have several major problems. The high yields of these varieties can only
be attained with a high level of inputs, in particular heavy applications of
fertilizer. This has led to problems associated with pest outbreaks in certain
areas, while increased rice production has resulted in lower rice prices.
In rice
breeding, the ideal plant type sought by breeders have been high yield
potential; resistance to major diseases and insects; and improved grain and
eating quality. However, there are few conflicting objectives like, high grain
quality tends to result in unstable yields and also, too much emphasis on
disease and insect resistance and stable yields leads to poor grain quality.
Hence, breeding efforts should be fashioned in a way to sustain the yield under
unfavorable conditions, and to maximize yields when conditions are favorable.
The following breeding approaches should be emphasized in producing varieties
for sustainable rice production.
· - High-yield potential under low inputs.
· - Heterotic F1 hybrid
· - New plant type
· - Premium grain and eating quality to meet consumer demand,
and to provide grain suitable for processing.
· - More genetic diversity.
· - Durable host resistance to major diseases and insects.
· - Wider range of growth duration for various purposes.
· - Proper levels of tolerance to environmental and climatic
stresses in specific areas.
Common
breeding method used in rice is pedigree breeding method. Other than the introduction of semi-dwarf
gene (sd1), popularization of male sterile systems in early 1980’s,
hybrid rice production has met dramatic increase in rice yields in China . Three line
breeding of hybrid rice carrying wild-abortive cytoplasmic male sterility has
been utilized in commercial scale (Kim and Rutger, 1988). The advent of
environmentally sensitive male sterility systems (TGMS and PGMS) paved way for
the development of two-line hybrid breeding in rice. Transfer of cytoplasm from wild species to
cultivated backgrounds used backcross procedures widely.
Host resistance
to various biotic stresses is a very important aspect of high yields, and can
be expected to play a significant role in sustainable rice production. There are
now numerous varieties resistant to rice blast, bacterial blight, various virus
diseases, and plant hoppers and some possess multiple resistance to diseases
and insects. Varieties with the Xa4 gene resistant to bacterial wilt
have been grown in the Philippines
for the last 15 years, and continue to be resistant. It is extremely difficult
to identify polygenic resistance and incorporate it into improved germplasm
(Khush and Virmani, 1985). Current studies on host resistance to crops
emphasize the durability of resistance (Ikehashi and Kiyosawa, 1981; Ahn, 1982;
Lee et al., 1989). Polygenic traits rather than absolute resistance
would be preferable in sustainable agricultural production (Hauptli et al.,
1990).
Improvements
in rice quality are very important in meeting the demands of consumers for
healthy, high-quality food. Many traditional varieties in both the tropics and
the temperate zone have excellent cooking and eating quality, but a low grain
yield (Khush and Juliano, 1985). For many years, breeders have focused their
attention on quality improvement, but there seems to be some unknown genetic
barrier to incorporating this trait into high-yielding varieties.
Biotechnological Advances
Modern
day crop breeding in rice is supplemented with biotechnological tools. Success stories are fast emerging with the
development of golden rice (Ye et al., 2000), and many efforts are on to
develop transgenic rice with various incorporated traits, including resistance
to pests, herbicides etc. Successfully
the Xa21 gene conferring resistance to Bacterial leaf blight has been
cloned. The deciphering the entire rice genome has been completed. Marker
assisted frameworks of quantitative trait loci are being developed intensively
which will help in developing strong target trait directed marker assisted
selection programs.
References:
Ahn, S.W. 1982. The slow blasting resistance. Proceedings, Symposium on Resistance to Rice Blast. IRAT/GERDAT, Montpellier, France, pp. 343-70.
Alford, J. and N. Duguid, 1998. Seductions of Rice. Artisan Publishers, NY, NY
Chaudhary, R., et al., eds., 2001. Speciality rices of the world. Science Publishers, Inc, NH, USA.
Chopra, V.L. and S. Prakash, 2002. Evolution and Adaptation of Cereal Crops. Science Publishers Inc, NH, USA.
Food and Agriculture Organization, 2004a. Rice and water: a long and diversified story, International Year of Rice, 2pp.
Food and Agriculture Organization, 2004b. Aquatic biodiversity in rice fields, International Year of Rice, 2pp.
Food and Agriculture Organization, 2004c. Rice and human nutrition, International year of rice, 2pp.
Hauptli, H., K. David, B.R. Thomas, and R.M. Goodman. 1990. Biotechnology and crop breeding for sustainable agriculture. In: Sustainable Agricultural Systems, A. Edwards, R. Lal, P. Madden, R.H. Miller,and G. House. (eds.). Soil and Water Conservation Society, U.S.A., pp. 142-156.
Huke, R.E. & Huke, E.H. 1990. Rice. then and now. Manila, International Rice Research Institute. 44 pp.
Ikehashi, H., and S. Kiyosawa. 1981. Strain-specific reaction of field resistance of Japanese rice varieties revealed with Philippine strains of rice blast fungus, Pyricularia oryzae Cav.. Jap. J. Breed. 31, 3: 293-301.
International Rice Research Institute, 2001. Rice Research and Production in the 21st Century.
International Rice Research Institute, 2002. Rice Almanac, 3rd Edition.
Khush, G.S., and B.O. Juliano. 1985. Breeding for high-yielding rices of excellent cooking and eating qualities. In: Rice Grain Quality and Marketing, International Rice Research Institute, College, Laguna, Philippines, pp. 61-69.
Khush, G.S., and Virmani. 1985. Breeding rice for disease resistance. In: Progress in Plant Breeding. Vol. 1. Butterworths, United Kingdom, pp. 240-279.
Kim, C.H., and J.N. Rutger. 1988. Heterosis in rice. In: Hybrid Rice. International Rice Research Institute, College, Laguna, Philippines, pp. 39-54.
Lee, E.J., Qi Zhang and T.W. Mew. 1989. Durable resistance to rice disease in irrigated environments. In: Progress in Irrigation Rice Research. International Rice Research Institute, College, Laguna, Philippines, pp. 93-100.
Ye, X, Al-Babili, S., Kloti, A., Zhang, J., Lucca, P., Beyer, P and Potrykus, I. 2000. Engineering the Provitamin A (b-Carotene) Biosynthetic Pathway into (Carotenoid-Free) Rice Endosperm, Science, 287: 303-305.
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