Expression of heat shock proteins in adult honey bee (Apis mellifera L.) workers under hot-arid subtropical ecosystems

Heat stress elicits the expression of heat shock proteins (HSPs) in honey bee subspecies. These highly conserved proteins have significant role in protecting cells from thermal-induced stresses. Honey bees in subtropical regions face extremely dry and hot environment. The expression of HSPs in the nurses and foragers of indigenous (Apis mellifera jemenitica) and imported European (Apis mellifera ligustica and Apis mellifera carnica) honey bee subspecies after heat shock treatment were compared using SDS-PAGE. Hsp70 and Hsp82 were equally expressed in the nurses of all tested bee subspecies when exposed to 40 °C and 45 °C for 4 h. The forager bees exhibited differential expression of HSPs after heat stress. No HSPs was expressed in the foragers of A. m. jemenitica, and Hsp70 was expressed only in the foragers of A. m. ligustica and A. m. carnica at 40 °C. A prominent diversity in HSPs expression was also exhibited in the foragers at 45 °C with one HSP (Hsp70) in A. m. jemenitica, two HSPs (Hsp40 and Hsp70) in A. m. carnica, and three HSPs (Hsp40, Hsp60 and Hsp70) in A. m. ligustica. No HSPs was expressed in the control nurse and forager bees at any of the tested temperatures. These findings illustrated the differences in HSP expression among nurse and forager bees. It is obvious that the native foragers are more heat tolerant with least HSPs expression than exotic bee races. Further investigations will help to understand the potential role of HSPs in the adaptability, survival, and performance of bee subspecies in harsh climate of the subtropical regions.     

Transcript analysis and expression profiling of three heat shock protein 70 genes in the ectoparasitoid Habrobracon hebetor （Hymenoptera： Braconidae）

Heat shock proteins （HSPs） are known as chaperones that help with folding of other proteins when cells are under environmental stresses. The upregulation of HSPs is essential for cold survival during insect diapause. The ectoparasitoidHabrobracon hebetor, a potential biological control agent, can enter reproductive diapause when reared at low temperature and short photoperiod. However, the expression of HSPs during diapause of H. hebetor has not been studied. In this study, we sequenced and characterized the full-length complementary DNAs of three Hsp70 genes （HhHsp70I, HhHsp70II and HhHsp70IIl） from 11. hebetor. Their deduced amino acid sequences showed more than 80% identities to their counterparts from other insect species. However, the multiple se- quence alignment among the three deduced amino acid sequences of HhHsp70s showed only 46% identities. A phylogenetic analysis of the three HhHsp70s and all other known Hsp70 sequences from Hymenoptera clustered all the Hsp70s into four groups, and the three HhHsp70s were distributed into three different groups. Real-time quantitative poly- merase chain reaction analysis showed that the expression of the three HhHspTO genes in H. hebetor reared at different conditions was quite different. HhHspTOI showed higher relative expression when H. hebetor were reared at 27.5℃ than at two lower temperatures （17.5℃ and 20℃） regardless of the photoperiod, whereas HhHspTOII showed higher ex- pression when H. hebetor were reared at 20℃ and 10 ： 14 L ： D than when reared at 17.5℃ and either 16 ： 8 L ： D or 10 ： 14 L ： D. In contrast, HhHSP7OIIIwas expressed at similar levels regardless of the rearing conditions. These results may suggest functional differences among the three HhHspTO genes in H. hebetor.     

The relationship between the differences in frost resistance of Arabidopsis and Thellungiella and heat shock proteins and dehydrins

Plants of extremophile Thellungiella (Thellungiella salsuginea (Pall.) OE Schulz) withstood freezing at ?15°C for 2 h without hardening, whereas plants of Arabidopsis (Arabidopsis thaliana (L.) Heinh.) were damaged at ?10°C and died at ?15°C under these conditions. The content of heat shock proteins (HSPs) HSP101, HSP60 and constitutive HSC70 was significantly higher in unhardened Thellungiella plants than in unhardened Arabidopsis plants. The spectrum of dehydrins (DHNs) in unhardened Thellungiella plants was more diverse and their total content was higher than in unhardened Arabidopsis plants. Frost resistance of Arabidopsis increased after hardening (4°C, 7 days), and there was an increase in the content of HSP101 and HSP60, as well as in the content of the DHN with a mol wt of 70 kD. Thellungiella plants survived after hardening at ?18°C, and the increase in the content of HSP101, HSP70, and HSP60 was significantly less pronounced than in Arabidopsis. At the same time, the content of DHNs in Thellungiella increased significantly during the hardening primarily because of the appearance of two DHNs (mol wts of 42 and 45 kD). It is assumed that an increased content of HSPs and DHNs and their greater diversity can be one of the factors of Thellungiella resistance to low temperatures as compared to Arabidopsis.     

Cloning of heat shock protein genes from the brown planthopper,Nilaparvata lugens,and the small brown planthopper,Laodelphax striatellus,and their expression in relation to thermal stress

Three heat shock protein (HSP) genes (hsp70, hsc70, hsp90) were partially cloned from the brown planthopper Nilaparvata lugens and the small brown planthopper Laodelphax striatellus (Homoptera: Delphacidae), which are serious pests of the rice plant. Sequence comparisons at the deduced amino acid level showed that the three HSPs of planthoppers were most homologous to corresponding HSPs of dipteran and lepi‐dopteran species. Identities of both heat shock cognate 70 and HSP90 were higher than HSP70 in both species. Identity of the HSP70 between the two planthopper species was only 81%, a value much lower than seen among fly and moth groups. Effects of heat and cold shocks were demonstrated on expression of the three hsp genes in the two planthopper species. Heat shock (40 °C) upregulated the hsp90 level but did not change the hsc70 level in either the nymph and adult stages of either species. On the other hand, the hsp70 level was only upregulated in L. striatellus. This heat shock response was prompt and lasted only for 1 h after treatment. In contrast, cold shock at 4°C did not change the expression levels of any hsp in either species.     

Antarctic marine molluscs do have an HSP70 heat shock response

The success of any organism depends not only on niche adaptation but also the ability to survive environmental perturbation from homeostasis, a situation generically described as stress. Although species-specific mechanisms to combat “stress” have been described, the production of heat shock proteins (HSPs), such as HSP70, is universally described across all taxa. Members of the HSP70 gene family comprising the constitutive (HSC70) and inducible (HSP70) members, plus GRP78 (glucose-regulated protein, 78 kDa), a related HSP70 family member, were cloned using degenerate polymerase chain reaction (PCR) from two evolutionary divergent Antarctic marine molluscs (Laternula elliptica and Nacella concinna), a bivalve and a gastropod, respectively. The expression of the HSP70 family members was surveyed via quantitative PCR after an acute 2-h heat shock experiment. Both species demonstrated significant up-regulation of HSP70 gene expression in response to increased temperatures. However, the temperature level at which these responses were induced varied with the species (+6–8°C for L. elliptica and +8–10°C for N. concinna) compared to their natural environmental temperature). L. elliptica also showed tissue-specific expression of the genes under study. Previous work on Antarctic fish has shown that they lack the classical heat shock response, with the inducible form of HSP70 being permanently expressed with an expression not further induced under higher temperature regimes. This study shows that this is not the case for other Antarctic animals, with the two molluscs showing an inducible heat shock response, at a level probably set during their temperate evolutionary past.     

Expression analysis of nine small heat shock protein genes from Tamarix hispida in response to different abiotic stresses and abscisic acid treatment

Heat shock proteins (HSPs) play important roles in protecting plants against environmental stresses. Furthermore, small heat shock proteins (sHSPs) are the most ubiquitous HSP subgroup with molecular weights ranging from 15 to 42 kDa. In this study, nine sHSP genes (designated as ThsHSP1–9) were cloned from Tamarix hispida. Their expression patterns in response to cold, heat shock, NaCl, PEG and abscisic acid (ABA) treatments were investigated in the roots and leaves of T. hispida by real-time RT-PCR analysis. The results showed that most of the nine ThsHSP genes were expressed at higher levels in roots than in leaves under normal growth condition. All of ThsHSP genes were highly induced under conditions of cold (4 °C) and different heat shocks (36, 40, 44, 48 and 52 °C). Under NaCl stress, all nine ThsHSPs genes were up-regulated at least one stress time-point in both roots and leaves. Under PEG and ABA treatments, the nine ThsHSPs showed various expression patterns, indicating a complex regulation pathway among these genes. This study represents an important basis for the elucidation of ThsHSP gene function and provides essential information that can be used for stress tolerance genetic engineering in future studies.     

Seasonal variation in expression pattern of genes under HSP70

Heat shock protein 70 (HSP70) is one of the most abundant and best characterized heat shock protein family that consists of highly conserved stress proteins, expressed in response to stress, and plays crucial roles in environmental stress tolerance and adaptation. The present study was conducted to identify major types of genes under the HSP70 family and to quantify their expression pattern in heat- and cold-adapted Indian goats (Capra hircus) with respect to different seasons. Five HSP70 gene homologues to HSPA8, HSPA6, HSPA1A, HSPA1L, and HSPA2 were identified by gene-specific primers. The cDNA sequences showed high similarity to other mammals, and proteins have an estimated molecular weight of around 70 kDa. The expression of HSP70 genes was observed during summer and winter. During summer, the higher expression of HSPA8, HSPA6, and HSPA1A was observed, whereas the expression levels of HSPA1L and HSPA2 were found to be lower. It was also observed that the expression of HSPA1A and HSPA8 was higher during winter in both heat- and cold-adapted goats but downregulates in case of other HSPs. Therefore, both heat and cold stress induced the overexpression of HSP70 genes. An interesting finding that emerged from the study is the higher expression of HSP70 genes in cold-adapted goats during summer and in heat-adapted goats during winter. Altogether, the results indicate that the expression pattern of HSP70 genes is species- and breed-specific, most likely due to variations in thermal tolerance and adaptation to different climatic conditions.     

induction of heat shock response and acquisition of thermotolerance in callus cultures of Gerbera jamesonii

Summary The heat shock (HS) response in callus cultures of the ornamental plant Gerbera jamesonii H. Bolus var. hybrida was analyzed. A HS at 35° C or 40° C for 4 h induced (a) the synthesis of several heat shock proteins (HSPs), especially in the small molecular weight range and some spots corresponding to HSP70 components, and (b) an increase in the steady state levels of some specific mRNAs. At the nonstressing temperature (26° C), a sustainable level of translation for HSP70 was indeed carried out, as confirmed by immunological analysis with a monoclonal antibody against cotton HSP70. The steady state levels of mRNAs measured before and after a HS by Northern hybridization showed an increase with the heterologous probes HSP17.4, HSP17.6, and HSP21, whereas the probes HSC70 and HSP70 did not show any difference between the levels of control and HS-mRNAs. A pretreatment at 35° C, which induced a set of HSPs in the callus cultures, decreased the cell damage upon exposure to a temperature of 45° C as determined either with a regrowth test or by the tetrazolium reduction assay. Typically, as with the whole plants, callus of Gerbera jamesonii possessed the ability to respond to HS both by inducing HSPs and by developing an acquired thermotolerance.     

Expression pattern of bta-mir-2898 miRNA and their correlation with heat shock proteins during summer heat stress among native vs crossbred cattle

Earlier studies identified the role of bta-mir-2898 in bovine. Our earlier study identified that, bta-mir-2898 can be over expressed in crossbred cattle during heat stress. Nevertheless the differential expression of bta-mir-2898 among native vs crossbred cattle during summer stress along with it's correlation with different heat shock proteins (HSPs) is not yet studied. In the present context, we studied the differential expression of bta-mir-2898 among Frieswal (Bos indicus x Bos taurus) and Sahiwal (Bos indicus) breeds of cattle during a range of environmental air temperatures and further investigated the correlation of bta-mir-2898 with different HSPs (HSP70, HSP90, HSP60. HSF, HSPB8 and HSP27). It was observed that, at peak air temperature the relative miRNA expression level (p < 0.05) of bta-mir-2898 was 3.4 ± 0.41 and 0.79 ± 0.22 among Frieswal and Sahiwal, respectively. We also observed significant levels (p < 0.05) of mRNA abundance of HSP70, HSP90, HSPB8 and HSP27 among the breeds. In all the cases Sahiwal found to exhibited higher level of HSPs in comparison to Frieswal. Studies revealed that the expression profile of bta-mir-2898 was negatively correlated with the expression of all the HSPs during thermal stress in post anti-mir2898 treated PBMC invitro cultured model originated from both Frieswal and Sahiwal cattle breeds. However, significantly (p < 0.05) higher negative correlations were observed between bta-mir-2898 and HSP70, HSP60 and HSPB8. Present findings highlighted the preliminary role of overexpressed bta-mir-2898 in cattle during thermal stress and its impact on different heat shock proteins.     

Response of Heat-Shock Protein (HSP) Genes to Temperature and Salinity Stress in the Antarctic Psychrotrophic Bacterium Psychrobacter sp. G

Temperature and salinity fluctuations are two of the most important factors affecting the growth of polar bacteria. In an attempt to better understand the function of heat-shock proteins (HSPs) in the adaptive mechanisms of the Antarctic psychrotrophic bacterium Psychrobacter sp. G to such conditions, genes Hsp845, Hsp2538, Hsp2666, and Hsp2667 were cloned on the basis of the draft genome. The expression characteristics of these HSP genes under different stress conditions were analyzed by the qRT-PCR method. Expression of Hsp845 and Hsp2667 was inhibited significantly by low temperature (0 and 10 °C, respectively). There was no difference of expression when Hsp2538 and Hsp2666 were exposed to 0 °C but the expression of Hsp2666 was inhibited when exposed to 10 °C. Expression of Hsp2538 and Hsp2667 was not sensitive but expression of Hsp845 and Hsp2666 was increased at low salinity (0 and 15, respectively). Expression of the four HSP genes was enhanced at high salinity (90 and 120) and at high temperature independent of salinity. By contrast, low temperature had no significant effect independent of salinity.