Field validation of heat tolerance and early morning flowering QTLs (qHTSF4.1 and qEMF3) and combination of the two QTLs introduced into IR64 (Oryza sativa L.) background at CSU Piat, Philippines
Paper Details
Field validation of heat tolerance and early morning flowering QTLs (qHTSF4.1 and qEMF3) and combination of the two QTLs introduced into IR64 (Oryza sativa L.) background at CSU Piat, Philippines
Abstract
Heat stress reduces rice yield by 10% for every degree Celsius increase beyond optimum temperature. Field testing of IR64-derived near-isogenic lines with heat tolerance and early morning flowering QTLs was conducted at CSU Piat during hottest months of 2016-2017. To evaluate how well IR64 NILs tolerated heat, morpho-agronomic data were collected and analyzed when they were subjected to high temperature at field conditions. Flower opening time (FOT), the peak flowering time (PFT), and the time when all of the flowers are closed (FCT) were also determined for early morning flowering traits (EMF). Results showed that morpho-agronomic features of IR64-derived NILs such panicle length, number of tillers per hill, spikelet fertility, spikelet/panicle, plant height, days to 50% flowering and maturity were similar when compared to its recurrent parent. Moreover, EMF traits results revealed that IR64HT+EMF and IR64EMF NILs exhibited the earliest FOT, PFT, and CFT. This research under high temperature field condition clearly validated the heat tolerance performance of IR64-derived NILs had similar morpho-agronomic traits compared to its recurrent parent indicating recovery of recurrent parent genome. Furthermore, IR64HT+EMF and IR64EMF NILs exhibited the earliest FOT, PFT, and CFT indicating that the presence of qEMF3 and its combination with qHTSF4.1 strongly confers EMF traits as an escape mechanism from heat stress. The researchers recommend the use of genetic materials with combined genes of heat tolerance (qHTSF4.1) and early morning flowering (qEMF3) for these are useful germplasm for future and expected global warming.
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