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
People also read
Full Research
Effect of Fungicides and Herbicides against Rhizoctonia solani f. sp. sasakii Exner Causing Banded Leaf and Sheath Blight in maize (Zea mays L.)
M. Madhavi, P. Narayan Reddy, K. Manohar and Ch. Aruna KumariMaize, Rhizoctonia solani, BLSB, sensitivity, fungicides, antibiotic, herbicides
Published Online : 07 Feb 2018
Innovative Technology
High Intensity Transplanting Increases Yield in Indigenous Aromatic Rice, Tulaipanji- a Case Study
Dhiman Sen and N. C. SarkarAromatic rice, tulaipanji, high intensity, transplanting, yield
Published Online : 07 Jun 2010
General
Steering Agriculture through the Concept of Triple S: Seed, Soil and Sustainability
C. S. PawarSustainable agriculture, chemical agriculture, seed-soil-sustainability
Published Online : 07 Sep 2010
Stress Management
Transgenic Approaches to Develop Abiotic Stress Tolerant Crop Plants: Rice as the Model Example
P. Satya, J. Mitra, C. S. Kar and H. K. SharmaRice, abiotic stress, genetic engineering
Published Online : 07 Sep 2010
Variation in Ralstonia solanacearum Isolated from Brinjal Plants in West Bengal
B. Mondal, I. Bhattacharya, A. sarkar and D. C. KhatuaBrinjal, bacterial wilt, Ralstonia solanacearum, aggressiveness
Published Online : 07 Jun 2011
Stress to Human Health Due to Electromagnetic Radiation Emitted from Mobile Phone
S. Ganguly, S. K. Mukhopadhayay and S. K. GuhaElectromagnetic radiations, harmful, health, mobile phone
Published Online : 07 Sep 2011