One out of Four: HspL but No Other Small Heat Shock Protein of Agrobacterium tumefaciens Acts as Efficient Virulence-Promoting VirB8 Chaperone

Alpha-crystallin-type small heat shock proteins (sHsps) are ubiquitously distributed in most eukaryotes and prokaryotes. Four sHsp genes named hspL, hspC, hspAT1, and hspAT2 were identified in Agrobacterium tumefaciens, a plant pathogenic bacterium capable of unique interkingdom DNA transfer via type IV secretion system (T4SS). HspL is highly expressed in virulence-induced growth condition and functions as a VirB8 chaperone to promote T4SS-mediated DNA transfer. Here, we used genetic and biochemical approaches to investigate the involvement of the other three sHsps in T4SS and discovered the molecular basis underlying the dominant function of HspL in promoting T4SS function. While single deletion of hspL but no other sHsp gene reduced T4SS-mediated DNA transfer and tumorigenesis efficiency, additional deletion of other sHsp genes in the hspL deletion background caused synergistic effects in the virulence phenotypes. This is correlated with the high induction of hspL and only modest increase of hspC, hspAT1, and hspAT2 at their mRNA and protein abundance in virulence-induced growth condition. Interestingly, overexpression of any single sHsp gene alone in the quadruple mutant caused increased T4SS-mediated DNA transfer and tumorigenesis. Thermal aggregation protecting assays in vitro indicated that all four sHsps exhibit chaperone activity for the model substrate citrate synthase but only HspL functions as efficient chaperone for VirB8. The higher VirB8 chaperone activity of HspL was also demonstrated in vivo, in which lower amounts of HspL than other sHsps were sufficient in maintaining VirB8 homeostasis in A. tumefaciens. Domain swapping between HspL and HspAT2 indicated that N-terminal, central alpha-crystallin, and C-terminal domains of HspL all contribute to HspL function as an efficient VirB8 chaperone. Taken together, we suggest that the dominant role of HspL in promoting T4SS function is based on its higher expression in virulence-induced condition and its more efficient VirB8 chaperone activity as compared to other sHsps.     

The plant sHSP superfamily: five new members in Arabidopsis thaliana with unexpected properties

The small heat shock proteins (sHsps), which are ubiquitous stress proteins proposed to act as chaperones, are encoded by an unusually complex gene family in plants. Plant sHsps are classified into different subfamilies according to amino acid sequence similarity and localization to distinct subcellular compartments. In the whole Arabidopsis thaliana genome, 19 genes were annotated to encode sHsps, of which 14 belong to previously defined plant sHsp families. In this paper, we report studies of the five additional sHsp genes in A. thaliana, which can now be shown to represent evolutionarily distinct sHsp subfamilies also found in other plant species. While two of these five sHsps show expression patterns typical of the other 14 genes, three have unusual tissue specific and developmental profiles and do not respond to heat induction. Analysis of intracellular targeting indicates that one sHsp represents a new class of mitochondrion-targeted sHsps, while the others are cytosolic/nuclear, some of which may cooperate with other sHsps in formation of heat stress granules. Three of the five new proteins were purified and tested for chaperone activity in vitro. Altogether, these studies complete our basic understanding of the sHsp chaperone family in plants. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Selective translation of heat shock mRNA in Drosophila melanogaster depends on sequence information in the leader.

One of the effects of a temperature increase above 35 degrees C on Drosophila melanogaster is a rapid switch in selectivity of the translational apparatus. Protein synthesis from normal, but not from heat shock, mRNA is much reduced. Efficient translation at high temperature might be a result of the primary sequence of heat shock genes. Alternatively a mRNA modification mechanism, altered as a consequence of heat shock, might allow for efficient high temperature translation of any mRNA synthesized during a heat shock. The gene for alcohol dehydrogenase (Adh) was fused to the controlling elements of a heat shock protein 70 (hsp70) gene. Authentic Adh mRNA, synthesized from this fusion gene at elevated temperatures was not translated during heat shock. A second Adh fusion gene in which the mRNA synthesized contained the first 95 nucleotides of the Hsp70 non-translated leader sequence gave rise, at high temperature, to mRNA which was translated during the heat shock. Thus, the signal(s) in the mRNAs controlling translation efficiency at heat shock temperatures is encoded within the heat shock genes.     

Effects of thermal acclimation on transcriptional responses to acute heat stress in the eurythermal fish Gillichthys mirabilis (Cooper)

The capacities of eurythermal ectotherms to withstand wide ranges of temperature are based, in part, on abilities to modulate gene expression as body temperature changes, notably genes encoding proteins of the cellular stress response. Here, using a complementary DNA microarray, we investigated the sequence in which cellular stress response-linked genes are expressed during acute heat stress, to elucidate how severity of stress affects the categories of genes changing expression. We also studied how prior acclimation history affected gene expression in response to acute heat stress. Eurythermal goby fish (Gillichthys mirabilis) were acclimated to 9 ± 0.5, 19 ± 0.5, and 28 ± 0.5°C for 1 mo. Then fish were given an acute heat ramp (4°C/h), and gill tissues were sampled every +4°C to monitor gene expression. The average onset temperature for a significant change in expression during acute stress increased by ～2°C for each ～10°C increase in acclimation temperature. For some genes, warm acclimation appeared to obviate the need for expression change until the most extreme temperatures were reached. Sequential expression of different categories of genes reflected severity of stress. Regardless of acclimation temperature, the gene encoding heat shock protein 70 (HSP70) was upregulated strongly during mild stress; the gene encoding the proteolytic protein ubiquitin (UBIQ) was upregulated at slightly higher temperatures; and a gene encoding a protein involved in cell cycle arrest and apoptosis, cyclin-dependent kinase inhibitor 1B (CDKN1B), was upregulated only under extreme stress. The tiered, stress level-related expression patterns and the effects of acclimation on induction temperature yield new insights into the fundamental mechanisms of eurythermy.     

温度胁迫下棉花粉蚧热激蛋白基因的表达分析

【目的】为了研究热激蛋白 Hsp70, Hsp70-4和Hsp90在棉花粉蚧Phenacoccus solenopsis抵抗逆温中的作用。【方法】在测序棉花粉蚧转录组的基础上,分析了该虫热激蛋白Hsp70基因家族的2个序列［Pshsp70（GenBank登录号为KJ909505）和Pshsp70-4（GenBank登录号为KJ909506）］和Hsp90基因家族的1个序列,［Pshsp90(GenBank登录号为KJ909507)］,采用实时荧光定量 PCR（RT-qPCR）检测了在不同温度（18和32℃恒温, 37, 39, 41, 43和45℃热激1 h 后26℃恢复1 h)下棉花粉蚧不同发育阶段（2龄若虫、3龄若虫、雌成虫）3种热激蛋白基因的表达量。【结果】Pshsp70 cDNA序列包含1 923 bp的开放阅读框,编码641个氨基酸,理论分子量和等电点分别为70.9 kDa和5.65; Pshsp70-4 cDNA序列包含1 962 bp的开放阅读框,编码654个氨基酸,理论分子量和等电点分别为71.8 kDa和5.38;Pshsp90 cDNA序列包含2 172 bp的开放阅读框,编码724个氨基酸,理论分子量和等电点分别为83.5 kDa和4.93。Pshsp70 和Pshsp70-4均含有Hsp70基因家族高度保守的基序,Pshsp70编码的氨基酸序列与烟粉虱Bemisia tabaci和家蚕Bombyx mori等昆虫的Hsp70 的氨基酸序列一致性为 85%;Pshsp70-4编码的氨基酸序列与白蜡蚧Ericerus pela和点蜂缘蝽Riptortus pedestris等昆虫的Hsp70的氨基酸序列一致性高达95%;Pshsp90也含有Hsp90基因家族高度保守的基序,Pshsp90编码的氨基酸序列与赤拟谷盗Tribolium castaneum和东亚小花蝽Orius sauteri等昆虫的Hsp90 的氨基酸序列一致性为 87%。热激蛋白基因表达量分析结果表明,在18℃恒温条件下,粉蚧2龄若虫的3个PsHsps基因的mRNA相对表达量均比对照(26℃)低,在32℃恒温条件下,各龄期的Hsp70基因的相对表达量均显著高于对照。在37~45℃下热激1 h并在26℃下恢复1 h,棉花粉蚧3个龄期的3个热激蛋白PsHsps基因的相对表达量随温度的升高总体呈增加趋势,相关性分析表明,除Pshsp70-4在雌成虫中的表达量与热胁迫温度的相关系数为0.225外,各龄期中3个基因的表达量与温度的相关系数均大于0.6,显著相关;43℃和45℃胁迫下,各龄期的3个热激蛋白基因相对表达量均显著高于对照组（P<0.05）。【结论】棉花粉蚧热激蛋白基因的表达与温度呈正相关,在该虫应对高温中起着重要作用。     

棉花粉蚧热休克蛋白基因的鉴定

热休克蛋白(heat shock proteins,Hsps)是生物体或细胞受到热胁迫后新合成的一类遗传上高度保守的蛋白,在昆虫应对外界环境因子胁迫时起着重要作用。为了系统研究棉花粉蚧Phenacoccus solenopsis Hsp基因家族,对棉花粉蚧转录组基因注释信息进行分析、获得目标序列,并应用NCBI上Blast X等软件进行比对、共鉴定出24条热激蛋白(Hsp)基因,包括3个Hsp90、8个Hsp70、2个Hsp60和11个s Hsp(small heat shock protein,s Hsp)基因。对棉花粉蚧与模式昆虫家蚕Bombyx mori、黑腹果蝇Drosophila melanogaster、赤拟谷盗Tribolium castaneum系统进化关系分析显示,昆虫的小分子量热休克蛋白s Hsp具有很强的种属特异性,Hsp70家族的保守性比s Hsp强。棉花粉蚧热激蛋白基因的鉴定为深入研究该虫Hsp与生长发育、抗逆境的相互关系奠定了基础。     

The translation start signal region of TEM beta-lactamase mRNA is responsible for heat shock-induced repression of amp gene expression in Escherichia coli.

pBR322 contains the amp gene encoding beta-lactamase. When Escherichia coli carrying this plasmid is exposed to heat shock, beta-lactamase synthesis is repressed transiently at the translational level. To identify the DNA element responsible for this translational repression, DNA segments containing the translation start region of the amp gene were excised from pAT153 and fused in frame with the lacZ reading frame in the open reading frame vector pORF1. These constructs were introduced into E. coli, and the effect of heat shock of the cells on the synthesis of beta-galactosidase starting from the amp start codon was examined. As is the case for pBR322-encoded synthesis of beta-lactamase, the synthesis of beta-galactosidase encoded by the fused genes also ceased transiently upon heat shock. It is concluded that the heat shock-induced repression of the amp gene occurs at the initiation step of translation. As far as the present study is concerned, the minimum DNA segment responsible for the repression is AT TGA AAA AGG AAG AGT ATG AG, which includes the Shine-Dalgarno sequence (AAGGA) and the initiation codon (ATG).     

Ty Element-Induced Temperature-Sensitive Mutations of Saccharomyces Cerevisiae

Temperature-sensitive mutants of Saccharomyces cerevisiae were isolated by insertional mutagenesis using the HIS3 marked retrotransposon TyH3HIS3. In such mutants, the TyHIS3 insertions are expected to identify loci which encode genes essential for cell growth at high temperatures but dispensable at low temperatures. Five mutations were isolated and named hit for high temperature growth. The hit1-1 mutation was located on chromosome X and conferred the pet phenotype. Two hit2 mutations, hit2-1 and hit2-2, were located on chromosome III and caused the deletion of the PET18 locus which has been shown to encode a gene required for growth at high temperatures. The hit3-1 mutation was located on chromosome VI and affected the CDC26 gene. The hit4-1 mutation was located on chromosome XIII. These hit mutations were analyzed in an attempt to identify novel genes involved in the heat shock response. The hit1-1 mutation caused a defect in synthesis of a 74-kD heat shock protein. Western blot analysis revealed that the heat shock protein corresponded to the SSC1 protein, a member of the yeast hsp70 family. In the hit1-1 mutant, the TyHIS3 insertion caused a deletion of a 3-kb DNA segment between the delta 1 and delta 4 sequences near the SUP4 locus. The 1031-bp wild-type HIT1 DNA which contained an open reading frame encoding a protein of 164 amino acids and the AGG arginine tRNA gene complemented all hit1-1 mutant phenotypes, indicating that the mutant phenotypes were caused by the deletion of these genes. The pleiotropy of the HIT1 locus was analyzed by constructing a disruption mutation of each gene in vitro and transplacing it to the chromosome. This analysis revealed that the HIT1 gene essential for growth at high temperatures encodes the 164-amino acid protein. The arginine tRNA gene, named HSX1, is essential for growth on a nonfermentable carbon source at high temperatures and for synthesis of the SSC1 heat shock protein.     

Hsp26: a temperature-regulated chaperone

Small heat shock proteins (sHsps) are a conserved protein family, with members found in all organisms analysed so far. Several sHsps have been shown to exhibit chaperone activity and protect proteins from irreversible aggregation in vitro. Here we show that Hsp26, an sHsp from Saccharomyces cerevisiae, is a temperature-regulated molecular chaperone. Like other sHsps, Hsp26 forms large oligomeric complexes. At heat shock temperatures, however, the 24mer chaperone complex dissociates. Interestingly, chaperone assays performed at different temperatures show that the dissociation of the Hsp26 complex at heat shock temperatures is a prerequisite for efficient chaperone activity. Binding of non-native proteins to dissociated Hsp26 produces large globular assemblies with a structure that appears to be completely reorganized relative to the original Hsp26 oligomers. In this complex one monomer of substrate is bound per Hsp26 dimer. The temperature-dependent dissociation of the large storage form of Hsp26 into a smaller, active species and the subsequent re-association to a defined large chaperone-substrate complex represents a novel mechanism for the functional activation of a molecular chaperone.     

Mutations altering heat shock specific subunit of RNA polymerase suppress major cellular defects of E. coli mutants lacking the DnaK chaperone.

An Escherichia coli mutant lacking HSP70 function, delta dnaK52, is unable to grow at both high and low temperatures and, at intermediate temperature (30 degrees C), displays defects in major cellular processes such as cell division, chromosome segregation and regulation of heat shock gene expression that lead to poor growth and genetic instability of the cells. In an effort to understand the roles of molecular chaperones such as DnaK in cellular metabolism, we analyzed secondary mutations (sid) that suppress the growth defects of delta dnaK52 mutants at 30 degrees C and also permit growth at low temperature. Of the five suppressors we analyzed, four were of the sidB class and mapped within rpoH, which encodes the heat shock specific sigma subunit (sigma 32) of RNA polymerase. The sidB mutations affected four different regions of the sigma 32 protein and, in one case, resulted in a several fold reduction in the cellular concentration of sigma 32. Presence of any of the sidB mutations in delta dnaK52 mutants as well as in dnaK+ cells caused down-regulation of heat shock gene expression at 30 degrees C and decreased induction of the heat shock response after shift to 43.5 degrees C. These findings suggest that the physiologically most significant function of DnaK in the metabolism of unstressed cells is its function in heat shock gene regulation.     

Heat causes oligomeric disassembly and increases the chaperone activity of small heat shock proteins from sugarcane

Small heat shock proteins (sHsp) constitute an important chaperone family linked to conformational diseases. In plants, sHsps prevent protein aggregation by acting as thermosensors and to enhance cell stress tolerance. SsHsp17.2 and SsHsp17.9 are the most highly expressed class I sHsps in sugarcane. They exist as dodecamers at 20 °C and have distinct substrate specificities. Therefore, they are useful models to study how class I SHsps work. Here we present data on the effects of heat on the oligomerization and chaperone activity of SsHsp17.2 and SsHsp17.9. Using several biophysical and biochemical probes, we show that the effects of heat are completely reversible, an important property for proteins that act at heat shock temperatures. SsHsp17.2 and SsHsp17.9 dodecamers dissociated to dimers at temperatures ranging from 40 to 45 °C and this dissociation was followed by enhanced chaperone activity. We conclude that high temperature affects the oligomeric state of these chaperones, resulting in enhanced chaperone activity.     

Microbial small heat shock proteins and their use in biotechnology

Small heat shock proteins (sHsps) exist in almost all organisms. Most organisms have more than one sHsp, but their number can be as high as 65, as found in the eukaryote, Vitis vinifera. The function of sHsps is well-known; they confer thermotolerance to cellular cultures and proteins in cellular extracts during prolonged incubations at elevated temperatures. This demonstrates the ability of sHsps to protect cellular proteins, and to maintain cellular viability under conditions of intensive stress, such as heat shock or chemical treatments. sHsps have several properties that distinguish them from heat shock proteins (Hsps): they function as ATP-independent chaperones, require the flexible assembly and reassembly of oligomeric complex structures for their activation, and exhibit a wide range of substrate-binding capacities. Recent studies indicate that sHsps have important biological functions in thermostability, disaggregation, and proteolysis inhibition. These functions can be harnessed for various applications, including nanobiotechnology, proteomics, bioproduction, and bioseparation. In this review, we discuss the properties and diversity of microbial sHsps, as well as their potential uses in the biotechnology industry.     

Analysis of the role of mitochondrial and endoplasmic reticulum localized small heat shock proteins in tomato

This communication examines the role of small heat shock proteins (sHsps) targeted to mitochondria (Mt) and endoplasmic reticulum (ER) in tomato plants (Lycopersicon esculentum Mill.) under heat stress. Genetic response of transgenic and wild type plants varied under optimum, moderately elevated and elevated temperature. In optimum temperature higher biomass was recorded in wild type than the transgenic lines, whereas in moderately elevated temperature biomass increased in Mt-sHsp line. Also, net photosynthetic rate (P_N) increased in Mt-sHsp line in both the elevated temperatures, though higher in moderately elevated. Cell membrane stability (CMS) improved in all the lines after exposure to elevated temperatures, but always remained higher in transgenic lines. Transgenic lines expressed sHsps in different temperature regimes in both vegetative and reproductive parts, while wild type expressed such proteins only after 1 h of heat shock.     

Extracellular small heat shock proteins: exosomal biogenesis and function

Small heat shock proteins (sHsps) belong to the family of heat shock proteins (Hsps): some are induced in response to multiple stressful events to protect the cells while others are constitutively expressed. Until now, it was believed that Hsps, including sHsps, are present inside the cells and perform intracellular functions. Interestingly, several groups recently reported the extracellular presence of Hsps, and sHsps have also been detected in sera/cerebrospinal fluids in various pathological conditions. Secretion into the extracellular milieu during many pathological conditions suggests additional or novel functions of sHsps in addition to their intracellular properties. Extracellular sHsps are implicated in cell-cell communication, activation of immune cells, and promoting anti-inflammatory and anti-platelet responses. Interestingly, exogenous administration of sHsps showed therapeutic effects in multiple disease models implying that extracellular sHsps are beneficial in pathological conditions. sHsps do not possess signal sequence and, hence, are not exported through the classical Endoplasmic reticulum-Golgi complex (ER-Golgi) secretory pathway. Further, export of sHsps is not inhibited by ER-Golgi secretory pathway inhibitors implying the involvement of a nonclassical secretory pathway in sHsp export. In lieu, lysoendosomal and exosomal pathways have been proposed for the export of sHsps. Heat shock protein 27 (Hsp27), αB-crystallin (αBC), and Hsp20 are shown to be exported by exosomes. Exosomes packaged with sHsps have beneficial effects in in vivo disease models. However, secretion mechanisms and therapeutic use of sHsps have not been elucidated in detail. Therefore, this review aimed at highlighting the current understanding of sHsps (Hsp27, αBC, and Hsp20) in the extracellular medium.     

Temperature-controlled structural alterations of an RNA thermometer

Thermoresponsive structures in the 5'-untranslated region of mRNA are known to control translation of heat shock and virulence genes. Expression of many rhizobial heat shock genes is regulated by a conserved sequence element called ROSE for repression of heat shock gene expression. This cis-acting, untranslated mRNA is thought to prevent ribosome access at low temperature through an extended secondary structure, which partially melts when the temperature rises. We show here by a series of in vivo and in vitro approaches that ROSE is a sensitive thermometer responding in the physiologically relevant temperature range between 30 and 40 degrees C. Point mutations predicted to disrupt base pairing enhanced expression at 30 degrees C. Compensatory mutations restored repression, emphasizing the importance of secondary structures in the sensory RNA. Only moderate inducibility of a 5'-truncated ROSE variant suggests that interactions between individual stem loops coordinate temperature sensing. In the presence of a complementary oligonucleotide, the functionally important stem loop of ROSE was rendered susceptible to RNase H treatment at heat shock temperatures. Since major structural rearrangements were not observed during UV and CD spectroscopy, subtle structural changes involving the Shine-Dalgarno sequence are proposed to mediate translational control. Temperature perception by the sensory RNA is an ordered process that most likely occurs without the aid of accessory factors.