Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
Table 1: Details of primers used for semi quantitative RT-PCR analysis[7]
Figure 1: Morphological changes in tolerant and susceptible rice genotypes under high temperature; 1: Nagina-22 (Check) 2: RRF-127 (Tolerant) 3: MTU-1010 (Susceptible)
Figure 2: Effect of high temperature on phenological traits in diverse rice genotypes
Table 2: Mean and Range for biochemical traits of all rice genotypes under control conditions
Table 3: Mean and Range for biochemical traits of all rice genotypes under stress conditions
Figure 3: Semi quantitative RT-PCR analysis of heat stress responsive genes in different rice genotypes under high temperature. (A) OsHSP26.7, (B) OsHSPDnaJ, (C) OsHSP18, (D) OsHSP16.9, (E) 60kDa Chaperon
Table 4: Correlation of Phenological and biochemical traits
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