Deepwater rice are varieties of rice (Oryza sativa) grown in flooded conditions with water more than 50 cm (20 in) deep for at least a month.[1] More than 100 million people in Southeast Asia including Northeastern India rely on deepwater rice for their sustenance.[2] Two adaptations permit the rice to thrive in deeper water, floating rice and traditional talls. Traditional talls are varieties that are grown at water depths between 50 and 100 cm (20 and 39 in) and have developed to be taller and have longer leaves than standard rice. Floating rice grows in water deeper than 100 cm through advanced elongation ability. This means when a field where rice is growing floods, accelerated growth in the internodal of the stem allows the plant to keep some of its foliage on top of the water. The O. s. indica cultivar is the main type of deepwater rice, although varieties of O. s. japonica have been found in Burma and Assam Plains.[3][4]

A farmer inspecting a crop of deepwater rice

Production edit

Deepwater rice is a staple food grown on roughly 90,000 km2 (35,000 sq mi) of land. The main areas where it is grown are in Southeast Asia including Northeastern India, where more than 100 million people rely on its production for their livelihood.[2] In South-East Asia, the main area deepwater rice is grown in the Brahmaputra valley in Assam, a state in Northeast India and other Northeast Indian states. In other regions of Mainland Southeast Asia, the main areas of cultivation are in Burma in the Irrawaddy Delta, in Thailand in the Chao Phraya[5] and Mekong in Vietnam and Cambodia.[6] In these countries, deepwater rice accounts for more than 25% of the land used to grow rice.[2]

Deepwater rice is cultivated less in West Africa than in Asia, with about 4,700 km2 (1,800 sq mi).[7] Areas it is grown include the Niger River basin.[6] Some areas in Ecuador grow deepwater rice.[8]

Cultivation methods edit

Deepwater rice is grown in tropical monsoon climates normally around river deltas and their floodplains mainly in backswamps and natural levees. The nature of the flood is important for success of deepwater rice, with timing and the rate of rise of water affecting survival and crop density. Generally, the flood water comes from rainfall or rises in the water table. In places with low rainfall, water overspilling from rivers can flood rice-producing areas.

Issues edit

When seeds are sown directly into the soil, the seeds and young plants can be damaged by drought conditions before floods arrive. During this stage, the plants can also suffer due to competition from weeds. Sudden flooding, where a large volume of water enters the field in a short time, can lead to a high level of seedling death.[8]

Floating rice faces additional problems due to the depth and time of the water in which it grows. Water conditions such as turbulence and temperature can adversely affect the crop.[9]

Natural disasters can also damage or destroy deepwater rice crops. Tropical cyclones are particularly a problem in Asia. For example, in 2008, Cyclone Nargis damaged 122,782 hectares of deepwater rice in Burma.[10] If predicted sea level rises due to climate change happen, this would affect the pattern of flooding, causing deeper floods over a wider area and eroding the coast.

Deepwater rice emits the least methane, a greenhouse gas, of the wetland rice ecologies, producing approximately one third of emissions compared to paddy field rice.

Floating rice adaptation edit

 
Researchers checking on floating rice

Floating rice is planted in dry ground and allowed to establish as young plants. The area becomes flooded which triggers the rice's elongation ability. This means when a field where rice is growing floods, accelerated growth in the internodes of the stem allows the plant to keep some of its foliage on top of the water. The stems are hollow and this allows gas to be exchanged between the plant and the atmosphere. Once the flooding ends, the plant is left lying on the ground. The nodes at the top of the plant then start growing upwards towards due to gravitropic sensitivity.[3]

The elongation is triggered when the plant is submerged through a mechanism involving ethylene gas. Ethylene is normally produced by plants and diffused into the air, but when floating rice is submerged in water, this process is disrupted as the gas moves more slowly into water. This leads to a buildup of ethylene in the plant. This triggers the production of a hormone called gibberellin which causes the rapid growth in the plant. When the plant reaches the surface, the ethylene gas can escape as normal and the rapid growth stops.[11] Research continues to enhance the ability to cope with increasing water depth.[12] Rice will drown if submerged for too long.[13]

New cultivars edit

A recent cultivar named Swarna Sub1 was developed via marker-assisted selection, with the ability to withstand prolonged periods of around 14 days beneath a flooded plain.[14][15] The submergence tolerance ability of this variety is conferred by the presence of the Sub1A gene, introgressed from the Indian cultivar FR13A into the flood-vulnerable (but high yielding) cultivar Swarna.[14][15]

Swarna Sub1 effectively enters a dormant, energy-conserving state upon being submerged in a flooded rice paddy, a process that involves the finely controlled metabolism of enzymes such amylases, starch phosphorylase and alcohol dehydrogenase, allowing the plant to survive with limited oxygen and sunlight unlike its standard variety relatives.[14][15] Given that the presence of the Sub1A gene does not impact upon the quality or quantity of the rice obtained,[14] this variety has been very popular, with 1.7 million hectares of land in India having Swarna Sub1 and other flood-resistant varieties used instead of conventional rice crops.[16]

See also edit

References edit

  1. ^ Catling, p. 2.
  2. ^ a b c Bhuiyan, Sadiq I. (2004). Rice research and development in the flood-prone ecosystem. International Rice Research Institute. p. v. ISBN 978-971-22-0197-4.
  3. ^ a b Hans, Kende; Esther van der Knaap; Hyung-Taeg Cho (1998). "Deepwater Rice: A Model Plant to Study Stem Elongation". Michigan State University-Department of Energy Plant Research Laboratory. Archived from the original on 27 July 2003. Retrieved 3 March 2011.
  4. ^ Catling, p. 110.
  5. ^ "Production of rice and associated crops in deeply flooded areas of the Chao Phraya delta" (PDF). Retrieved 4 January 2013.[permanent dead link]
  6. ^ a b Catling, p. 7.
  7. ^ Prein, Mark; Madan M. Dey (2006). "Community-based fish Culture in Seasonal Floodplains". Penang, Malaysia: WorldFish Center. Retrieved 7 March 2011.
  8. ^ a b De Datta, p. 244.
  9. ^ De Datta, p. 249.
  10. ^ "Water Buffaloes Needed in Cyclone-hit Burma, Says FAO". The Irrawaddy. June 19, 2008. Archived from the original on 2 March 2011. Retrieved 3 March 2011.
  11. ^ Fountain, Henry (August 21, 2009). "In Some Rice Varieties, Genes Fuel Fast Growth When the Water Pours In". The New York Times. Retrieved 3 March 2011.
  12. ^ Yoko Hattori, Yoko; Keisuke Nagai1, Keisuke; Shizuka Furukawa1, Shizuka; Xian-Jun Song, Xian-Jun; Ritsuko Kawano, Ritsuko; Hitoshi Sakakibara, Hitoshi; Jianzhong Wu, Jianzhong; Takashi Matsumoto, Takashi; Atsushi Yoshimura, Hidemi Kitano, Makoto Matsuoka, Hitoshi Mori & Motoyuki Ashikar, Atsushi; Kitano, Hidemi; Matsuoka, Makoto; Mori, Hitoshi; Ashikari, Motoyuki (20 August 2009). "The ethylene response factors SNORKEL1 and SNORKEL2 allow rice to adapt to deep water". Nature. 460 (7258): 1026–1030. Bibcode:2009Natur.460.1026H. doi:10.1038/nature08258. PMID 19693083. S2CID 4428878. Received 23 April 2009; Accepted 30 June 2009{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  13. ^ Abaño, Imelda V. (December 5, 2008). "Waterproof rice passes international field tests". SciDev.Net. Archived from the original on February 21, 2021. Retrieved March 17, 2013. A new type of rice that can survive total submersion for more than two weeks has passed its field tests with "flying colours," say researchers, and is now close to official release.
  14. ^ a b c d Debrata, P.; Sarkar, R.K. (2012). "Role of Non-Structural Carbohydrate and its Catabolism Associated with Sub 1 QTL in Rice Subjected to Complete Submergence". Experimental Agriculture. 48 (4): 502–512. doi:10.1017/S0014479712000397. S2CID 86192842.
  15. ^ a b c "Climate change-ready rice" Archived 2013-11-01 at the Wayback Machine, International Rice Research Institute (IRRI). Retrieved October 31, 2013.
  16. ^ "Best minds meet to help crops survive flooding Archived 2016-01-01 at the Wayback Machine" International Rice Research Institute (IRRI) (2013). Retrieved October 31, 2013.

Bibliography edit