Project description:This is a mathematical model of Hsp70 induction. To model heat shock effects, the model incorporates temperature dependencies in transcirption to Hsp70 mRNA and in dissociation of transcriptional complexes, in addition to a formal expression relating temperature to protein denaturation.

Project description:we utilized transcriptome sequencing to identify differentially expressed genes in rice heat-tolerant line and heat-sensitive line under high night temperature stress .

Project description:we utilized microRNA sequencing to identify differentially expressed miRNAs in rice heat-tolerant line and heat-sensitive line under high night temperature stress .

Project description:we utilized microRNA sequencing to identify differentially expressed miRNAs in rice heat-tolerant line and heat-sensitive line under high night temperature stress .

Project description:The expression of heat shock proteins is considered a central adaptive mechanism to heat stress. This study investigated the expression of heat shock proteins (HSPs) and other stress-protective proteins against heat stress in cowpea genotypes under field (IT-96D-610 and IT-16) and controlled (IT-96D-610) conditions. Plants in the control environment were under 25/20°C (day/night) in a warm chamber and 40/25 °C in a hot chamber. In the field, plants grew at Eensaamheid with 26 to 28°C and at Marapyane with 30 to 32°C monthly average maximum temperatures. Heat stress response analysis of proteins at 72 h in the controlled environment showed 270 differentially regulated proteins identified using label-free quantitative proteomics in IT-96D-610 plants. These plants expressed HSPs and chaperones (BAG family molecular chaperone 6 (BAG6), Multiprotein bridging factor1c (MBF1C) and cold shock domain protein 1 (CSDP1)) in the controlled environment. However, IT-96D-610 plants expressed a wider variety of small HSPs and more HSPs in the field. IT-96D-610 plants also responded to heat stress by exclusively expressing chaperones (DnaJ chaperones, universal stress protein and heat shock binding protein (HSBP)) and non-HSP proteins (Deg1, EGY3, ROS protective proteins, temperature-induced lipocalin and succinic dehydrogenase). Photosynthesis recovery and induction of proteins related to photosynthesis, were better in IT-96D-610 because of the concurrent induction of heat stress response proteins for chaperone functions, protein degradation for repair and ROS scavenging proteins and PSII operating efficiency (Fq’/Fm’) than IT-16. This study contributes to identification of thermotolerance mechanisms in cowpea that can be useful in knowledge-based crop improvement.

Project description:In order to study the importance of HSFA1 in thermotolerance in Arabidopsis, we generated the HSFA1a, b, d and e quadruple mutant (QK). QK is very sensitive to heat. Therefore, we used microarray to study how many genes regulated by HSFA1 after heat shock.

Project description:The analysis of the mapped QTLs and their genetic dissection in the US grown japonica rice genotypes, Cypress and Lagrue at genomic and transcriptomic levels The gene expression profiling using Deseq was performed using data collected under control and heat stress For heat stress:a day/night temperature of 30°C (86°F)/28°C (82.4°F) for 10 h (20:00–6:00) was maintained while the control treatment was set at a day/night temperature of 30°C (86°F)/22.2°C (72°F) until harvest maturity (approximately 18–20% grain moisture content)

Project description:Plants coordinate their growth and developmental programs with various endogenous signals and environmental challenges such as seasonal and diurnal temperature fluctuations. The bHLH transcription factor PIF4 plays critical roles in thermoresponsive hypocotyl growth in Arabidopsis, and the evening complex component ELF3 negatively regulates PIF4's activity for downstream gene expression and hypocotyl elongation at elevated temperature. However, how warm temperature signal is transmitted to ELF3 is not known. Here, we report the identification of two B-Box protein BBX18/BBX23 as new regulators of thermomorphogenesis in Arabidopsis. Mutations of BBX18/BBX23 confer reduced thermoresponsive hypocotyl elongation. Overexpression of BBX18 enhances the sensitivity of hypocotyl growth to elevated temperature, which is dependent on the function of PIF4 and RING E3 ligase COP1, respectively. Both BBX18 and BBX23 interact with ELF3 or COP1, relegating the protein abundance of ELF3 at warm temperature. Further, the expression of multiple thermoresponsive genes is impaired in both the PIF4 single mutant and BBX18/BBX23 double mutant. In addition, both the transcription and protein levels of BBX18/BBX23 are up-regulated by elevated ambient temperature. Thus, our findings reveal the important roles of B-Box proteins in plant thermomorphogenesis, and build a new connection from warm temperature information to ELF3 and its downstream signaling components.

Project description:Poplar (Populus trichocarpa, clone Nisqually-1) plants were grown in a Conviron PGR 15 growth chamber using precise control of temperature, light, and humidity. Diurnal (driven) conditions included 12L:12D light cycles and 25C/12C thermocycles in three different combinations. These were: photocycles (LDHH), 12 hrs. light (L)/12 hrs. dark (D) at a constant temperature (25C; HH); photo/thermocycles (LDHC): 12 hrs. light (L) /12 hrs. dark (D) with a high day temperature (25C) and a low night temperature (12C); and thermocycles (LLHC): continuous light (LL) with 12 hrs. high/12 hrs. low temperature (25C, day; 12C, night). Light intensity and relative humidity were 700 micromol m-2s-2 and 50%, respectively. Three-month-old poplar plants were entrained for at least one week under the respective condition prior to initiation of each experiment. Leaves and stems from individual poplar plants were collected every four hours for 48 hrs in driven (diurnal) conditions followed by a two day freerun spacer under continuous light/temperature followed by two additional days of sampling under the same continuous free run condition.

Project description:Rice (Oryza sativa, spp. Indica, cv. 93-11) plants were grown in a Conviron PGR 15 growth chamber using precise control of temperature, light, and humidity.<br>Diurnal (driven) conditions included 12L:12D light cycles and 31C/20C thermocycles in three different combinations. These were: photocycles (LDHH), 12 hrs. light (L)/12 hrs. dark (D) at a constant temperature (31C; HH); photo/thermocycles (LDHC): 12 hrs. light (L) /12 hrs. dark (D) with a high day temperature (31C) and a low night temperature (20C); and thermocycles (LLHC): continuous light (LL) with 12 hrs. high/12 hrs. low temperature (31C, day; 20C, night). Light intensity and relative humidity were 1000 micromol m-2s-2 and 60%, respectively.<br>Three-month-old rice plants were entrained for at least one week under the respective condition prior to initiation of each experiment. Leaves and stems from individual rice plants were collected every four hours for 48 hrs in driven (diurnal) conditions followed by a two day freerun spacer under continuous light/temperature followed by two additional days of sampling under the same continuous free run condition.