Differences in the heat-shock response between thermotolerant and thermosusceptible cultivars of hexaploid wheat

Varying patterns of protein synthesis in bread wheat during heat shock

High temperatures during seedling growth are considered as one of the factors that can modify surviving properties in wheat (Triticum aestivum L.) plant. This work attempts to evaluate the heat shock responses of seedling of winter wheat (Bezostaya-1) using growth parameters (seedling length, embryonal root length and embryonal root number), membrane stability index (MSI) and two dimensional (2D) gel electrophoresis analysis of heat shock proteins (HSPs) during heat shock. Seedlings grown until first leaf opening at controlled conditions (23 degrees C, 200 micromol m(-2) s(-1), 16h day/8h night, 50-60% humidity) were exposed to 37 degrees C or 45 degrees C high temperatures for 2, 4 and 8 hours. While 37 degrees C did not cause any significant change, 45 degrees C heat treatments caused significant decrease in terms of seedling and root length, and leaf MSI for all exposure times. However, all the plants from 45 degrees C heat treatments continued to grow during recovery period. 2D protein analysis indicated that 37 degrees C, 8 hours exposure caused stronger and more diverse heat shock response than the other treatments, followed by 37 degrees C, 4 hours, 45 degrees C, 8 hours, 45 degrees C, 4 hours, 45 degrees C, 2 hours treatments. 5 protein spots, ranging from 6-7.8 pl (isoelectric point) and 27-31.7 kDA molecular weight, were expressed at 37 degrees C, 2 hours and continued at 37 and 45 degrees C for all exposure times. This suggests that these early proteins and other newly synthesized proteins may have protective effects at 37 and 45 degrees C and provide plants for healthy growth during the recovery period.

Photoinhibition, bleaching susceptibility and mortality in two scleractinian corals, Platygyra ryukyuensis and Stylophora pistillata, in response to thermal and light stresses

In the present study, we examined the effect of thermal stress on the photoinhibitory light threshold in a bleaching susceptible (Stylophora pistillata) and a bleaching resistant (Platygyra ryukyuensis) coral. Four light (0, 110, 520, 1015 micromol quantam(-2)s(-1)) and three temperature (26, 32 and 34 degrees C) conditions were used over a 3-h period, followed by 24- and 48-h recovery periods at approximately 21 degrees C under dim light. Dynamic photoinhibition could be detected in both P. ryukyuensis and S. pistillata under 520 and 1015 micromol quantam(-2)s(-1) at 26 degrees C and under 110 micromol quantam(-2)s(-1) at 32 degrees C only in S. pistillata. Chronic photoinhibition was recorded under 520 and 1015 micromol quantam(-2)s(-1) at 34 degrees C in P. ryukyuensis, and under 1015 micromol quantam(-2)s(-1) at 32 degrees C and under all light levels at 34 degrees C in S. pistillata. These results show that high temperature reduced the threshold light intensity for photoinhibition differently in two corals with different bleaching susceptibilities under thermal stress. No visual paling and mortality in P. ryukyuensis was observed at any treatment, even in chronically photoinhibited specimens, while paling and high mortality of S. pistillata was noted in all treatments, apart from samples at 26 degrees C. These observations suggest a potential role of the host in differential bleaching and mortality determination.

Small heat shock proteins genes are differentially expressed in distinct varieties of common bean

Plants respond to temperature stress by synthesizing a set of heat shock proteins (HSPs), which may be responsible for the acquisition of thermotolerance. In this study, the induction of small HSPs (sHSPs) in eight common bean varieties was evaluated by Northern blot analysis using the W HSP 16.9 cDNA as heterologous probe. Cowpea was used, as a positive control since this plant, as opposed to common bean, is known to grow well under high temperature regimes such as that found in the Brazilian semi-arid region. After the growth period, the plants were submitted to two h of heat shock at 40 ºC. All varieties tested were able to induce sHSP mRNAs that hybridized with W HSP 16.9 probe. However, significant kinetic differences were found when comparing different varieties. SHSP mRNA levels induced after heat shock in cowpea was higher than the levels observed on the bean varieties displaying the highest expression of these proteins. Besides, the sHSP expression was also assessed at the protein accumulation level by Western-blot analysis for cowpea and both IPA 7 and Negro Argel varieties of bean plants. The revealed protein pattern confirmed that sHSPs are differentially expressed in distinct varieties of common bean according their heat stress tolerance.

Correlated evolution of chloroplast heat shock protein expression in closely related plant species

Interspecific variation in chloroplast low molecular weight (cLMW) HSP (heat shock protein) expression was examined with respect to phylogeny, species specific leaf area, chlorophyll fluorescence, and mean environmental conditions within species ranges. Eight species of Ceanothus (Rhamnaceae) were heat shocked for 4 h at several different temperatures. Leaf samples were collected immediately after the heat shock, and cLMW HSP expression was quantified using Western blots. At 45°C species from the subgenus Cerastes had significantly greater cLMW HSP expression than species from the subgenus Ceanothus. Specific leaf area was negatively correlated with cLMW HSP expression after the 45°C heat treatment. In addition, chlorophyll fluorescence (F(v)/F(m)) 1 h after the heat shocks was positively correlated with cLMW HSP expression. Contrary to our prediction, there was no correlation between July maximum temperature within species ranges and cLMW HSP expression. These results suggest that evolutionary differentiation in cLMW HSP expression is associated with leaf physiological parameters and related aspects of life history, yet associations between climatic conditions within species ranges and cLMW HSP expression require further study.

Cloning of new members of heat shock protein HSP101 gene family in wheat (Triticum aestivum (L.) Moench) inducible by heat, dehydration, and ABA(1)

We have cloned two cDNAs, TaHSP101B and TaHSP101C, encoding two heat stress-inducible members of HSP101/ClpB family in bread wheat (Triticum aestivum (L.) Moench.). Proteins encoded by these cDNAs are highly similar at the primary sequence level and diverged from the previously reported TaHSP101 (designated TaHSP101A) both in the consensus ATP/GTP-binding region II and in the carboxy terminal region. The HSP101 gene was determined to be a single copy gene or a member of a small gene family in hexaploid wheat. Messages encoding HSP101 proteins were inducible by heat stress treatments in both wheat leaves and roots. Accumulation of the TaHSP101C mRNA was less abundant than that of TaHSP101B mRNA. We are showing for the first time that in addition to heat stress, expression of HSP101 mRNAs in wheat leaves was induced by a 2-h dehydration and a treatment with 5x10(-5)M ABA, but not affected by chilling or wounding, indicating that HSP101 proteins may be involved in both heat and drought responses in wheat.

Heat-shock proteins, molecular chaperones, and the stress response: evolutionary and ecological physiology

Molecular chaperones, including the heat-shock proteins (Hsps), are a ubiquitous feature of cells in which these proteins cope with stress-induced denaturation of other proteins. Hsps have received the most attention in model organisms undergoing experimental stress in the laboratory, and the function of Hsps at the molecular and cellular level is becoming well understood in this context. A complementary focus is now emerging on the Hsps of both model and nonmodel organisms undergoing stress in nature, on the roles of Hsps in the stress physiology of whole multicellular eukaryotes and the tissues and organs they comprise, and on the ecological and evolutionary correlates of variation in Hsps and the genes that encode them. This focus discloses that (a) expression of Hsps can occur in nature, (b) all species have hsp genes but they vary in the patterns of their expression, (c) Hsp expression can be correlated with resistance to stress, and (d) species' thresholds for Hsp expression are correlated with levels of stress that they naturally undergo. These conclusions are now well established and may require little additional confirmation; many significant questions remain unanswered concerning both the mechanisms of Hsp-mediated stress tolerance at the organismal level and the evolutionary mechanisms that have diversified the hsp genes.

Differential display-mediated rapid identification of different members of a multigene family, HSP 16.9 in wheat

Isolation of cDNAs encoding individual members of a gene family is essential for assessing their role in a biological phenomenon. However, this process is often laborious and slow due to highly conserved protein-coding region that interferes with the isolation of the individual members. Identification of gene-specific probes from 3' non-coding regions of different members can assist in the fast retrieval and characterization of individual members of a multigene family. We used the recent technique of differential display for the same purpose. As an example of a multigene family in plants, we selected a heat shock protein gene family, HSP16.9 from wheat, with estimated 12 members. We modified the original differential display technique for selective amplification of the 3' non-coding regions of different wheat HSP16.9 genes by replacing the random 10-mer in the original method with a conserved HSP16.9 gene family-specific primer. Sixteen cDNA fragments from these experiments were sequenced and they represent 8 different members of a 12 member gene family. Our success can be attributed to shorter 3' non-coding regions that are typical of higher-plant genes and use of highly conserved gene family-specific primer in these experiments. This modified differential display technique can be of general application to other plant systems where cloning of the different members of a gene family is desired.