Impact of Humidity on Temperature-Induced Grain Sterility in Rice (Oryza sativa L)

• Published in: Journal of agronomy and crop science (1986) Vol. 194; no. 2; pp. 135 - 140
• Main Authors: Weerakoon, W.M.W, Maruyama, A, Ohba, K
• Format: Journal Article
• Language: English
• Published: Oxford, UK Oxford, UK : Blackwell Publishing Ltd 01.04.2008; Blackwell Publishing Ltd; Blackwell
• Subjects: Agronomy. Soil science and plant productions; air temperature; Biological and medical sciences; cultivars; Economic plant physiology; Flowering, floral biology, reproduction patterns; Fundamental and applied biological sciences. Psychology; Growth and development; heat; heat stress; heat tolerance; high temperature; inflorescence temperature; inflorescences; night temperature; Oryza sativa; plant development; plant fertility; pollen; pollination; relative humidity; rice; seeds; sterility; stigma; viability; Relative humidity; Monocotyledones; Grains; Reproductive pattern; Temperature effect; Environmental factor; High temperature; Sexual reproduction; Sterility; Cereal crop; Stress; Pollination; Floral biology; Oryza sativa; heat stress; Gramineae; Agronomy; Thermal shock; Angiospermae; Spermatophyta; C3-Type
• ISSN: 0931-2250; 1439-037X
• DOI: 10.1111/j.1439-037X.2008.00293.x

High temperature-induced grain sterility in rice is becoming a serious problem in tropical rice-growing ecosystems. We studied the mechanism of high temperature-induced grain sterility of different rice (Oryza sativa L) cultivars at two relative humidity (RH) levels. Four varieties of Indica and Japonica rice were exposed to over 85 % RH and 60 % RH at 36/30 °C, 34/30 °C, 32/24 °C and 30/24 °C day/night air temperatures from late booting to maturity inside sunlit phytotrons. Increasing both air temperature and RH significantly increased spikelet sterility while high temperature-induced sterility decreased significantly with decreasing RH. Neither Indica nor Japonica rice types were superior to the other in the response of their spikelets to increased air temperature and RH. Increased spikelet sterility was due to increased pollen grain sterility which reduced deposition of viable pollen grains on stigma. Reduction in sterility with decreased RH was more due to decreased spikelet temperature than to air temperature. Thus the impact of RH should be considered when interpreting the effect of high temperature on grain sterility. Spikelet fertility was curvilinearly related to spikelet temperature. Grain sterility increased when spikelet temperature increased over 30 °C while it became completely sterile at 36 °C. The ability of a variety to decrease its spikelet temperature with decreasing RH could be considered as avoidance while the variability in spikelet sterility among varieties at a given spikelet temperature could be considered as true tolerance.