Structure and in vitro molecular chaperone activity of cytosolic small heat shock proteins from pea

Small heat shock proteins and stress tolerance in plants

Small heat shock proteins (sHsps) are produced ubiquitously in prokaryotic and eukaryotic cells upon heat. The special importance of sHsps in plants is suggested by unusual abundance and diversity. Six classes of sHsps have been identified in plants based on their intracellular localization and sequence relatedness. In addition to heat stress, plant sHsps are also produced under other stress conditions and at certain developmental stages. Induction of sHsp gene expression and protein accumulation upon environmental stresses point to the hypothesis that these proteins play an important role in stress tolerance. The function of sHsps as molecular chaperones is supported by in vitro and in vivo assays. This review summarizes recent knowledge about plant sHsp gene expression, protein structure and functions.

Distinct roles of the N-terminal-binding domain and the C-terminal-solubilizing domain of alpha-synuclein, a molecular chaperone

alpha-Synuclein, an acidic neuronal protein of 140 amino acids, is extremely heat-resistant and is natively unfolded. Recent studies have demonstrated that alpha-synuclein has chaperone activity both in vitro and in vivo, and that this activity is lost upon removing its C-terminal acidic tail. However, the detailed mechanism of the chaperone action of alpha-synuclein remains unknown. In this study, we investigated the molecular mechanism of the chaperone action of alpha-synuclein by analyzing the roles of its N-terminal and C-terminal domains. The N-terminal domain (residues 1-95) was found to bind to substrate proteins to form high molecular weight complexes, whereas the C-terminal acidic tail (residues 96-140) appears to be primarily involved in solubilizing the high molecular weight complexes. Because the substrate-binding domain and the solubilizing domain for chaperone function are well separated in alpha-synuclein, the N-terminal-binding domain can be substituted by other proteins or peptides. Interestingly, the resultant engineered chaperone proteins appeared to display differential efficiency and specificity in terms of the chaperone function, which depended upon the nature of the binding domain. This finding implies that the C-terminal acidic tail of alpha-synuclein can be fused with other proteins or peptides to engineer synthetic chaperones for specific purposes.

A critical motif for oligomerization and chaperone activity of bacterial alpha-heat shock proteins

Oligomerization into multimeric complexes is a prerequisite for the chaperone function of almost all alpha-crystallin type heat shock proteins (alpha-Hsp), but the molecular details of complex assembly are poorly understood. The alpha-Hsp proteins from Bradyrhizobium japonicum are suitable bacterial models for structure-function studies of these ubiquitous stress proteins. They fall into two distinct classes, A and B, display chaperone activity in vitro and form oligomers of approximately 24 subunits. We constructed 19 derivatives containing truncations or point mutations within the N- and C-terminal regions and analyzed them by gel filtration, citrate synthase assay and coaffinity purification. Truncation of more than the initial few amino acids of the N-terminal region led to the formation of distinct dimeric to octameric structures devoid of chaperone activity. In the C-terminal extension, integrity of an isoleucine-X-isoleucine (I-X-I) motif was imperative for alpha-Hsp functionality. This I-X-I motif is one of the characteristic consensus motifs of the alpha-Hsp family, and here we provide experimental evidence of its structural and functional importance. alpha-Hsp proteins lacking the C-terminal extension were inactive, but still able to form dimers. Here, we demonstrate that the central alpha-crystallin domain alone is not sufficient for dimerization. Additional residues at the end of the N-terminal region were required for the assembly of two subunits.

Escherichia coli small heat shock proteins, IbpA and IbpB, protect enzymes from inactivation by heat and oxidants

To examine functions of two small heat shock proteins of Escherichia coli, IbpA and IbpB, we constructed His-IbpA and His-IbpB, in which a polyhistidine tag was fused to the N-terminals. Both purified His-IbpA and His-IbpB formed multimers, which have molecular masses of about 2.0-3.0 MDa and consist of about 100-150 subunits. They suppressed the inactivation of several enzymes including citrate synthase and 6-phosphogluconate dehydrogenase by heat, potassium superoxide, hydrogen peroxide and freeze-thawing, but not the inactivation of glyceraldehyde-3-phosphate dehydrogenase by hydrogen peroxide. Both His-IbpA and His-IbpB suppressed enzyme inactivation by various treatments and were also found to be associated with their non-native forms. However, both His-IbpA and His-IbpB were not able to reactivate enzymes inactivated by heat, oxidants or guanidine hydrochloride. When heated to 50 degrees C, each multimeric form of His-IbpA or His-IbpB was dissociated to form a monomer for His-IbpA, and an oligomer of about one-quarter size for His-IbpB. These structural changes were reversible, as both heated proteins regained the multimeric structures after incubation at 25 degrees C. However, when exposed to hydrogen peroxide or potassium superoxide, the large multimeric forms of His-IbpA and His-IbpB were maintained. The results suggest that His-IbpA and His-IbpB suppress the inactivation of enzymes and bind non-native proteins to protect their structures from heat and oxidants.

Monodisperse Hsp16.3 nonamer exhibits dynamic dissociation and reassociation, with the nonamer dissociation prerequisite for chaperone-like activity

Small heat-shock proteins (sHsps) of various origins exist commonly as oligomers and exhibit chaperone-like activities in vitro. Hsp16.3, the sHsp from Mycobacterium tuberculosis, was previously shown to exist as a monodisperse nonamer in solution when analyzed by size-exclusion chromatography and electron cryomicroscropy. This study represents part of our effort to understand the chaperone mechanism of Hsp16.3, focusing on the role of the oligomeric status of the protein. Here, we present evidence to show that the Hsp16.3 nonamer dissociates at elevated temperatures, accompanied by a greatly enhanced chaperone-like activity. Moreover, the chaperone-like activity was increased dramatically when the nonameric structure of Hsp16.3 was disturbed by chemical cross-linking, which impeded the correct reassociation of Hsp16.3 nonamer. These suggest that the dissociation of the nonameric structure is a prerequisite for Hsp16.3 to bind to denaturing substrate proteins. On the other hand, our data obtained by using radiolabeled and non-radiolabeled proteins clearly demonstrated that subunit exchange occurs readily between the Hsp16.3 oligomers, even at a temperature as low as 4 degrees C. In light of all these observations, we propose that Hsp16.3, although it appears to be homogeneous when examined at room temperature, actually undertakes rapid dynamic dissociation/reassociation, with the equilibrium, and thus the chaperone-like activities, regulated mainly by the environmental temperature.

Alpha-crystallin-type heat shock proteins: socializing minichaperones in the context of a multichaperone network

Alpha-crystallins were originally recognized as proteins contributing to the transparency of the mammalian eye lens. Subsequently, they have been found in many, but not all, members of the Archaea, Bacteria, and Eucarya. Most members of the diverse alpha-crystallin family have four common structural and functional features: (i) a small monomeric molecular mass between 12 and 43 kDa; (ii) the formation of large oligomeric complexes; (iii) the presence of a moderately conserved central region, the so-called alpha-crystallin domain; and (iv) molecular chaperone activity. Since alpha-crystallins are induced by a temperature upshift in many organisms, they are often referred to as small heat shock proteins (sHsps) or, more accurately, alpha-Hsps. Alpha-crystallins are integrated into a highly flexible and synergistic multichaperone network evolved to secure protein quality control in the cell. Their chaperone activity is limited to the binding of unfolding intermediates in order to protect them from irreversible aggregation. Productive release and refolding of captured proteins into the native state requires close cooperation with other cellular chaperones. In addition, alpha-Hsps seem to play an important role in membrane stabilization. The review compiles information on the abundance, sequence conservation, regulation, structure, and function of alpha-Hsps with an emphasis on the microbial members of this chaperone family.

Functional regions of rice heat shock protein, Oshsp16.9, required for conferring thermotolerance in Escherichia coli

Rice (Oryza sativa) class I low-molecular mass (LMM) heat shock protein (HSP), Oshsp16.9, has been shown to be able to confer thermotolerance in Escherichia coli. To define the regions for this intriguing property, deletion mutants of this hsp have been constructed and overexpressed in E. coli XL1-blue cells after isopropyl beta-D-thioglactopyranoside induction. The deletion of amino acid residues 30 through 36 (PATSDND) in the N-terminal domain or 73 through 78 (EEGNVL) in the consensus II domain of Oshsp16.9 led to the loss of chaperone activities and also rendered the E. coli incapable of surviving at 47.5 degrees C. To further investigate the function of these two domains, we determined the light scattering changes of Oshsp16.9 mutant proteins at 320 nm under heat treatment either by themselves or in the presence of a thermosensitive enzyme, citrate synthase. It was observed that regions of amino acid residues 30 through 36 and 73 through 78 were responsible for stability of Oshsp16.9 and its interactions with other unfolded protein substrates, such as citrate synthase. Studies of two-point mutants of Oshsp16.9, GST-N74E73K and GST-N74E74K, indicate that amino acid residues 73 and 74 are an important part of the substrate-binding site of Oshsp16.9. Non-denaturing gel analysis of purified Oshsp16.9 revealed that oligomerization of Oshsp16.9 was necessary but not sufficient for its chaperone activity.

Xenopus small heat shock proteins, Hsp30C and Hsp30D, maintain heat- and chemically denatured luciferase in a folding-competent state

In this study we characterized the chaperone functions of Xenopus recombinant Hsp30C and Hsp30D by using an in vitro rabbit reticulocyte lysate (RRL) refolding assay system as well as a novel in vivo Xenopus oocyte microinjection assay. Whereas heat- or chemically denaturated luciferase (LUC) did not regain significant enzyme activity when added to RRL or microinjected into Xenopus oocytes, compared with native LUC, denaturation of LUC in the presence of Hsp30C resulted in a reactivation of enzyme activity up to 80-100%. Recombinant Hsp30D, which differs from Hsp30C by 19 amino acids, was not as effective as its isoform in preventing LUC aggregation or maintaining it in a folding-competent state. Removal of the first 17 amino acids from the N-terminal region of Hsp30C had little effect on its ability to maintain LUC in a folding-competent state. However, deletion of the last 25 residues from the C-terminal end dramatically reduced Hsp30C chaperone activity. Coimmunoprecipitation and immunoblot analyses revealed that Hsp30C remained associated with heat-denatured LUC during incubation in reticulocyte lysate and that the C-terminal mutant exhibited reduced affinity for unfolded LUC. Finally, we found that Hsc70 present in RRL interacted only with heat-denatured LUC bound to Hsp30C. These findings demonstrate that Xenopus Hsp30 can maintain denatured target protein in a folding-competent state and that the C-terminal end is involved in this function.

ATP causes small heat shock proteins to release denatured protein

Small heat-shock proteins (sHSPs) are a ubiquitous family of low molecular mass (15-30 kDa) stress proteins that have been found in all organisms. Under stress, sHSPs such as alpha-crystallin can act as chaperones binding partially denatured proteins and preventing further denaturation and aggregation. Recently, it has been proposed that the function of sHSPs is to stabilize stress-denatured protein and then act cooperatively with other HSPs to renature the partially denatured protein in an ATP-dependent manner. However, the process by which this occurs is obscure. As no significant phosphorylation of alpha-crystallin was observed during the renaturation, the role of ATP is not clear. It is now shown that ATP at normal physiological concentrations causes sHSPs to change their confirmation and release denatured protein, allowing other molecular chaperones such as HSP70 to renature the protein and renew its biological activity. In the absence of ATP, sHSPs such as alpha-crystallin are more efficient than HSP70 in preventing stress-induced protein aggregation. This work also indicates that in mammalian systems at normal cellular ATP concentrations, sHSPs are not effective chaperones.

Molecular characterization of thermoinduced immunogenic proteins Q1p42 and Hsp15 of Leptospira interrogans

Leptospira interrogans is a mammalian pathogen which must adapt to a range of new environmental conditions including temperature change when it infects new hosts. In vitro studies of organisms cultured at 30 degrees C and shifted to 37 degrees C for 5 to 7 days have confirmed that synthesis of several proteins involved in equine infection is regulated in response to temperature change (J. E. Nally, J. F. Timoney, and B. Stevenson, Infect. Immun. 69:400-404, 2001). In order to specifically identify antigenic proteins upregulated at 37 degrees C, groups of three ponies were immunized with organisms shifted to 37 degrees C for 5 to 7 days or with organisms maintained at 30 degrees C. A lambda ZAP II genomic DNA library was screened with the pool of antisera to organisms shifted to 37 degrees C. Clones reactive with this pool but unreactive with the pool of pony antisera to organisms cultured at 30 degrees C were selected for further analysis. Sequence analysis of the first two clones identified open reading frames for proteins designated Qlp42 and Hsp15. Qlp42 is predicted to be an outer membrane lipoprotein. Its synthesis was upregulated when cultures were shifted from 30 to 37 degrees C and downregulated when cultures were shifted from 37 to 30 degrees C. Although the predicted molecular mass of Qlp42 is 39.8 kDa for the mature protein, Qlp42-specific equine antiserum was reactive with two bands of 30 and 29.5 kDa. Hsp15 is a stress response protein and a member of the Hsp20/alpha-crystallin family. PCR detected homologues of qlp42 and hsp15 in pathogenic serovars of L. interrogans but not in the nonpathogenic Leptospira biflexa. Enzyme-linked immunosorbent assays of antibody in convalescent sera from mares naturally infected with L. interrogans suggest that Qlp42 is expressed during leptospiral infection.

Activation of the redox-regulated molecular chaperone Hsp33--a two-step mechanism

BACKGROUND

Hsp33 is a novel redox-regulated molecular chaperone. Hsp33 is present in the reducing environment of the cytosol and is, under normal conditions, inactive. The four highly conserved cysteines found in Hsp33 constitute a novel zinc binding motif. Upon exposure to oxidative stress, Hsp33's chaperone activity is turned on. This activation process is initiated by the formation of two intramolecular disulfide bonds. Recently, the 2.2 A crystal structure of Hsp33 has been solved, revealing that Hsp33 is present as a dimer in the structure (Vijayalakshmi et al., this issue, 367-375 [1]).

RESULTS

We show here that oxidized, highly active Hsp33 is a dimer in solution. In contrast, reduced and inactive Hsp33 is monomeric. The incubation of reduced Hsp33 in H(2)O(2) leads to the simultaneous formation of two intramolecular disulfide bonds and the concomitant release of zinc. This concentration-independent step is followed by a concentration-dependent association reaction. The dimerization of Hsp33 requires highly temperature-sensitive structural rearrangements. This allows Hsp33's activation process to be greatly accelerated at heat shock temperatures.

CONCLUSIONS

The regulation of Hsp33's chaperone function is highly sophisticated. On a transcriptional level, Hsp33 is under heat shock control. This increases the concentration of Hsp33 under heat and oxidative stress, a process that favors dimerization, a critical step in Hsp33's activation reaction. On a posttranslational level, Hsp33 is redox regulated. Dimerization of disulfide-bonded Hsp33 monomers leads to the formation of two extended, putative substrate binding sites. These sites might explain Hsp33's high and promiscuous affinity for unstructured protein folding intermediates.

alpha-B- and alpha-A-crystallin prevent irreversible acidification-induced protein denaturation

alpha-Crystallin (alpha), a major structural protein of the mammalian lens, is a large, physically heterogeneous macromolecule with an average molecular weight of approximately 800 kDa and is composed of two 20-kDa polypeptides designated as alphaA and alphaB. A line of evidence strongly suggests that alphaB may have an essential nonlenticular function. Here it is demonstrated that alphaB can bind partially denatured enzymes effectively at acidic pH and prevent their irreversible aggregation, but cannot prevent loss of enzyme activity. However, when the inactive luciferase bound to alphaB was treated with reticulocyte lysate (a rich source of molecular chaperones) and an ATP-generating system, more than 50% of the original luciferase activity could be recovered. Somewhat less activation was observed when alphaA-bound enzyme or the alpha-bound enzyme was renatured similarly. The overall results suggest that alpha acts as a chaperone to stabilize denaturing proteins at acidic pH so that at a later time they can be reactivated by other chaperones.

In vivo modifications of the maize mitochondrial small heat stress protein, HSP22

A maize (Zea mays L.) small heat shock protein (HSP), HSP22, was previously shown to accumulate to high levels in mitochondria during heat stress. Here we have purified native HSP22 and resolved the protein into three peaks using reverse phase high performance liquid chromatography. Mass spectrometry (MS) of the first two peaks revealed the presence of two HSP22 forms in each peak which differed in mass by 80 daltons (Da), indicative of a monophosphorylation. Phosphorylation of HSP22 by [gamma-(32)P]ATP was also observed in mitochondria labeled in vitro, but not when purified native HSP22 was similarly used, demonstrating that HSP22 does not autophosphorylate, implicating a kinase involvement in vivo. Collisionally induced dissociation tandem MS (CID MS/MS) identified Ser(59) as the phosphorylated residue. We have also observed forms of HSP22 that result from alternative intron splicing. The two HSP22 proteins in the first peak were approximately 57 Da larger than the two HSP22 proteins in the second peak. MS analysis revealed that the +57-Da forms have an additional Gly residue directly N-terminal of the expected Asp(84), which had been converted to an Asn residue. These results are the first demonstrations of phosphorylation and alternative intron splicing of a plant small HSP.

Temperature interactions of the molecular chaperone Hsc70 from the eurythermal marine goby Gillichthys mirabilis

Molecular chaperones participate in many aspects of protein biogenesis. Mechanistically, they recognize and bind to non-native proteins, prevent the aggregation of unfolded proteins and also, in some cases, facilitate refolding. Although a great deal is known about the cellular function of molecular chaperones in general, very little is known about the effect of temperature on molecular chaperones in non-model organisms, particularly in ectotherms that fold proteins under variable-temperature conditions in nature. To address this issue, we studied the temperature interactions of a major cytosolic molecular chaperone, Hsc70, from the eurythermal marine goby Gillichthys mirabilis. Using in vitro assays, we measured the intrinsic activity, unfolded-protein-stimulated activity, temperature sensitivity and heat stability of the ATPase activity of native Hsc70 purified from G. mirabilis white muscle. Similar to other chaperones in the 70kDa heat-shock protein family, G. mirabilis Hsc70 exhibited a low intrinsic ATPase activity that was stimulated in vitro by the addition of unfolded protein. Across the environmentally relevant temperature range (10–35°C), the ATPase activity of G. mirabilis Hsc70 displayed differential thermal sensitivity, with the greatest sensitivity occurring between 10 and 15°C and the least sensitivity between 15 and 25°C. In addition, the activity of Hsc70 was not significantly different between the unstimulated and unfolded-protein-stimulated treatments, suggesting that the ATPase activity and the peptide-binding domain of Hsc70 have similar thermal sensitivities in vitro. Finally, the thermal stability of Hsc70 ATPase activity greatly exceeded environmental temperatures for G. mirabilis, with activity up to 62.5°C. Overall, the biochemical characterization of the ATPase activity suggests that, although Hsc70 is not an extraordinarily thermally stable protein, it is capable of protein chaperoning cycles even at the extremes of environmental temperatures encountered by G. mirabilis in nature.

The expanding family of Arabidopsis thaliana small heat stress proteins and a new family of proteins containing alpha-crystallin domains (Acd proteins)

Comprehensive analysis of the Arabidopsis genome revealed a total of 13 sHsps belonging to 6 classes defined on the basis of their intracellular localization and sequence relatedness plus 6 ORFs encoding proteins distantly related to the cytosolic class Cl or the plastidial class of sHsps. The complexity of the Arabidopsis sHsp family far exceeds that in any other organism investigated to date. Furthermore, we have identified a new family of ORFs encoding multidomain proteins that contain one or more regions with homology to the ACD (Acd proteins). The functions of the Acd proteins and the role of their ACDs remain to be investigated.

Proteomic analysis of arabidopsis seed germination and priming

To better understand seed germination, a complex developmental process, we developed a proteome analysis of the model plant Arabidopsis for which complete genome sequence is now available. Among about 1,300 total seed proteins resolved in two-dimensional gels, changes in the abundance (up- and down-regulation) of 74 proteins were observed during germination sensu stricto (i.e. prior to radicle emergence) and the radicle protrusion step. This approach was also used to analyze protein changes occurring during industrial seed pretreatments such as priming that accelerate seed germination and improve seedling uniformity. Several proteins were identified by matrix-assisted laser-desorption ionization time of flight mass spectrometry. Some of them had previously been shown to play a role during germination and/or priming in several plant species, a finding that underlines the usefulness of using Arabidopsis as a model system for molecular analysis of seed quality. Furthermore, the present study, carried out at the protein level, validates previous results obtained at the level of gene expression (e.g. from quantitation of differentially expressed mRNAs or analyses of promoter/reporter constructs). Finally, this approach revealed new proteins associated with the different phases of seed germination and priming. Some of them are involved either in the imbibition process of the seeds (such as an actin isoform or a WD-40 repeat protein) or in the seed dehydration process (e.g. cytosolic glyceraldehyde-3-phosphate dehydrogenase). These facts highlight the power of proteomics to unravel specific features of complex developmental processes such as germination and to detect protein markers that can be used to characterize seed vigor of commercial seed lots and to develop and monitor priming treatments.

Comprehensive expression profile analysis of the Arabidopsis Hsp70 gene family

We isolated cDNA clones for two nuclear-encoded, organellar members of the Arabidopsis hsp70 gene family, mtHsc70-2 (AF217458) and cpHsc70-2 (AF217459). Together with the completion of the genome sequence, the hsp70 family in Arabidopsis consists of 14 members unequally distributed among the five chromosomes. To establish detailed expression data of this gene family, a comprehensive reverse transcriptase-polymerase chain reaction analysis for 11 hsp70s was conducted including analysis of organ-specific and developmental expression and expression in response to temperature extremes. All hsp70s showed 2- to 20-fold induction by heat shock treatment except cpHsc70-1 and mtHsc70-1, which were unchanged or repressed. The expression profiles in response to low temperature treatment were more diverse than those evoked by heat shock treatment. Both mitochondrial and all cytosolic members of the family except Hsp70b were strongly induced by low temperature, whereas endoplasmic reticulum and chloroplast members were not induced or were slightly repressed. Developmentally regulated expression of the heat-inducible Hsp70 in mature dry seed and roots in the absence of temperature stress suggests prominent roles in seed maturation and root growth for this member of the hsp70 family. This reverse transcriptase-polymerase chain reaction analysis establishes the complex differential expression pattern for the hsp70s in Arabidopsis that portends specialized functions even among members localized to the same subcellular compartment.

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.

Functional characterization of Xenopus small heat shock protein, Hsp30C: the carboxyl end is required for stability and chaperone activity

Small heat shock proteins protect cells from stress presumably by acting as molecular chaperones. Here we report on the functional characterization of a developmentally regulated, heat-inducible member of the Xenopus small heat shock protein family, Hsp30C. An expression vector containing the open reading frame of the Hsp30C gene was expressed in Escherichia coli. These bacterial cells displayed greater thermoresistance than wild type or plasmid-containing cells. Purified recombinant protein, 30C, was recovered as multimeric complexes which inhibited heat-induced aggregation of either citrate synthase or luciferase as determined by light scattering assays. Additionally, 30C attenuated but did not reverse heat-induced inactivation of enzyme activity. In contrast to an N-terminal deletion mutant, removal of the last 25 amino acids from the C-terminal end of 30C severely impaired its chaperone activity. Furthermore, heat-treated concentrated solutions of the C-terminal mutant formed nonfunctional complexes and precipitated from solution. Immunoblot and gel filtration analysis indicated that 30C binds with and maintains the solubility of luciferase preventing it from forming heat-induced aggregates. Coimmunoprecipitation experiments suggested that the carboxyl region is necessary for 30C to interact with target proteins. These results clearly indicate a molecular chaperone role for Xenopus Hsp30C and provide evidence that its activity requires the carboxyl terminal region.

The molecular chaperone alpha-crystallin is in kinetic competition with aggregation to stabilize a monomeric molten-globule form of alpha-lactalbumin

In vivo, alpha-crystallin and other small heat-shock proteins (sHsps) act as molecular chaperones to prevent the precipitation of 'substrate' proteins under stress conditions through the formation of a soluble sHsp-substrate complex. Using a range of different salt conditions, the rate and extent of precipitation of reduced alpha-lactalbumin have been altered. The interaction of alpha-crystallin with reduced alpha-lactalbumin under these various salt conditions was then studied using a range of spectroscopic techniques. Under conditions of low salt, alpha-lactalbumin aggregates but does not precipitate. alpha-Crystallin is able to prevent this aggregation, initially by stabilization of a monomeric molten-globule species of alpha-lactalbumin. It is proposed that this stabilization occurs through weak transient interactions between alpha-crystallin and alpha-lactalbumin. Eventually a stable, soluble high-molecular-mass complex is formed between the two proteins. Thus it appears that a tendency for alpha-lactalbumin to aggregate (but not necessarily precipitate) is the essential requirement for alpha-crystallin-alpha-lactalbumin interaction. In other words, alpha-crystallin interacts with a non-aggregated form of the substrate to prevent aggregation. The rate of precipitation of alpha-lactalbumin is increased significantly in the presence of Na2SO4 compared with NaCl. However, in the former case, alpha-crystallin is unable to prevent this aggregation and precipitation except in the presence of a large excess of alpha-crystallin, i.e. at mass ratios more than 10 times greater than in the presence of NaCl. It is concluded that a kinetic competition exists between aggregation and interaction of unfolding proteins with alpha-crystallin.

The chaperone-like activity of a small heat shock protein is lost after sulfoxidation of conserved methionines in a surface-exposed amphipathic alpha-helix

The small heat shock proteins (sHsps) possess a chaperone-like activity which prevents aggregation of other proteins during transient heat or oxidative stress. The sHsps bind, onto their surface, molten globule forms of other proteins, thereby keeping them in a refolding competent state. In Hsp21, a chloroplast-located sHsp in all higher plants, there is a highly conserved region forming an amphipathic alpha-helix with several methionines on the hydrophobic side according to secondary structure prediction. This paper describes how sulfoxidation of the methionines in this amphipathic alpha-helix caused conformational changes and a reduction in the Hsp21 oligomer size, and a complete loss of the chaperone-like activity. Concomitantly, there was a loss of an outer-surface located alpha-helix as determined by limited proteolysis and circular dichroism spectroscopy. The present data indicate that the methionine-rich amphipathic alpha-helix, a motif of unknown physiological significance which evolved during the land plant evolution, is crucial for binding of substrate proteins and has rendered the chaperone-like activity of Hsp21 very dependent on the chloroplast redox state.

Developmental regulation of a gene coding for a low-molecular-weight heat shock protein during haustorium formation in the seedlings of a holoparasitic plant, Cuscuta japonica

Dodder (Cuscuta japonica), a holoparasitic angiosperm, develops haustoria that are essential for parasitism. We have previously demonstrated that in Cuscuta seedlings, haustorial formation could be induced efficiently by cooperative effects of far-red light and tactile stimuli in the absence of any host plant [Tada et al. (1996) Plant Cell Physiol. 37: 1049]. In this study, we performed differential display and isolated several cDNAs that were expressed differentially during haustorium development in the seedlings. Sequence similarities identified one of them as a gene encoding a 17-kDa low-molecular-weight heat shock protein (CJHSP17). Northern blot analysis revealed that CJHSP17 mRNAs constitutively accumulated in the seedlings in the absence of environmental stress, and that the transcripts dramatically decreased to undetectable levels prior to emergence of haustoria upon irradiation with far-red light in the presence of tactile stimuli. When treated with either of the two stimuli, the CJHSP17 transcript levels did not decrease and there was no differentiation of haustoria. Moreover, irradiation of red light immediately after far-red light completely repressed both the decrease of mRNAs and the subsequent formation of haustoria. These observations suggest the involvement of down-regulation of CJHSP17 in haustorium development in Cuscuta seedlings.

Transient expression and heat-stress-induced co-aggregation of endogenous and heterologous small heat-stress proteins in tobacco protoplasts

Heat-stress granules (HSG) are highly ordered, cytoplasmic chaperone complexes found in all heat-stressed plant cells. We have developed an experimental system involving expression of cytosolic class I and class II small heat-stress proteins (Hsps) of pea, Arabidopsis and tomato in tobacco protoplasts to study the structural prerequisites for the assembly of HSG or HSG-like complexes. Class I and class II small Hsps formed class-specific dodecamers of 210-280 kDa, which, upon heat stress, were incorporated into HSG complexes. Interestingly, class II dodecamers alone could form HSG-like complexes (auto-aggregation), whereas class I dodecamers could do so only in the presence of class II proteins (recruitment). By analysing C-terminal deletion forms of Hsp17 class II, we obtained evidence that the intact C-terminus is critical for the oligomerization state, for the heat-stress-induced auto-aggregation and for recruitment of class I proteins. The class-specific formation of dimers as a prerequisite for oligomerization was analysed by the yeast two-hybrid system. In the presence of the endogenous (tobacco) set of heat-stress-induced proteins, all heterologous class I and class II proteins were incorporated into HSG complexes, whose ultrastructure was different from that of complexes formed by class I and class II proteins alone. Although other, more distantly related, members of the Hsp20 family, i.e. the plastidic pea Hsp21, the Drosophila Hsp23 and the mouse Hsp25, were well expressed in tobacco protoplasts and formed homo-oligomers of 200-700 kDa, none of them could be recruited to HSG complexes.

The structural differences between bovine lens alphaA- and alphaB-crystallin

Lens alphaA- and alphaB-crystallin have been reported to act differently in their protection against nonthermal destabilization of proteins. The nature of this difference, however, is not completely understood. Therefore we used a combination of thermally and solvent-induced structural changes to investigate the difference in the secondary, tertiary and quaternary structures of alphaA- and alphaB-crystallin. We demonstrate the relationship between the changes in the tertiary and quaternary structures for both polypeptides. Far-ultraviolet circular dichroism revealed that the secondary structure of alphaB-crystallin is more stable than that of alphaA-crystallin, and the temperature-induced secondary structure changes of both polypeptides are partially reversible. Tryptophan fluorescence revealed two distinct transitions for both alphaA- and alphaB-crystallin. Compared to alphaB-crystallin, both transitions of alphaA-crystallin occurred at higher temperature. The changes in the hydrophobicity are accompanied by changes in the quaternary structure and are biphasic, as shown by bis-1-anilino-8-naphthalenesulfonate fluorescence and sedimentation velocity. These phenomena explain the difference in the chaperone capacity of alphaA- and alphaB-crystallin carried out at different temperatures. The quaternary structure of alpha-crystallin is more stable than that of alphaA- and alphaB-crystallin. The latter has a strong tendency to dissociate under thermal or solvent destabilization. This phenomenon is related to the difference in subunit organization of alphaA- and alphaB-crystallin where both hydrophobic and ionic interactions are involved. We find that an important subunit rearrangement of alphaA-crystallin takes place once the molecule is destabilized. This subunit rearrangement is a requisite phenomenon for maintaining alpha-crystallin in its globular form and as a stable complex. On the base of our results, we suggest a four-state model describing the folding and dissociation of alphaA- and alphaB-crystallin better than a three-state model [Sun et al. (1999) J. Biol. Chem. 274, 34067-34071].

Chaperone activity of tobacco HSP18, a small heat-shock protein, is inhibited by ATP

NtHSP18P (HSP18), a cytosolic class I small heat-shock protein from tobacco pollen grains, was expressed in Escherichia coli. The viability of these cells was improved by 50% at 50 degrees C, demonstrating its functionality in vivo. Purified recombinant protein formed 240 kDa HSP18 oligomers, irrespective of temperature. These oligomers interacted with the model substrate citrate synthase (CS) to form large complexes in a temperature-dependent manner. Furthermore, HSP18 prevented thermally induced aggregation of CS at 45 degrees C. The fluorescence probe bis-ANS revealed the exposure of HSP18 hydrophobic surfaces at this temperature. Reactivation of chemically denatured CS was also significantly enhanced by HSP18. Surprisingly, HSP18 function was inhibited (in contrast to the related chaperone alphabeta-crystallin and plant sHSPs studied so far) by the presence of ATP in a concentration-dependent manner. The conformational changes of HSP18 imposed by ATP binding were indicated by the difference in the quenching of intrinsic tryptophan fluorescence, and implied more compact structure with ATP. Fluorescence measurements with bis-ANS showed that the conformational shift of HSP18 is suppressed in the presence of ATP. Decreased chaperone activity of HSP18 in the presence of ATP is caused by the lower affinity of conformationally blocked HSP18 for the substrate, as demonstrated by a higher susceptibility of model substrate, malate dehydrogenase, to proteolytic cleavage. Our results suggest that the chaperone activity of some plant sHSPs could be regulated by the availability of ATP in the cytoplasm, which would provide a mechanism to monitor the cell environment, control biological activity of sHSPs, and coordinate it with other ATP-dependent chaperones such as HSP70.

High-molecular-mass complexes formed in vivo contain smHSPs and HSP70 and display chaperone-like activity

Stress can have profound effects on the cell. The elicitation of the stress response in the cell is often accompanied by the synthesis of high-molecular-mass complexes, sometimes termed heat shock granules (HSGs). The presence of the complexes has been shown to be important for the survival of cells subjected to stress. We purified these complexes from heat-stressed BY-2 tobacco cells. HSG complexes formed in vivo contain predominantly smHSPs, HSP40 and HSP70 and display chaperone-like activity. Tubulins as well as other proteins may be part of the complex or its substrate. The proteins, except smHSPs and to some extent HSP70, were hypersensitive to proteolysis, suggesting that they were partially denatured and not an integral part of the HSG complexes. When citrate synthase was used as the substrate, in vivo generated HSG complexes exhibited strong nucleotide-dependent in vitro chaperone activity. Measurable ATP-mediated hydrolytic activity was detected. Isolated HSG complexes are stable until ATP is added, which leads to rapid dissociation of the complex into subunits. It is proposed that smHSPs form the core of the complex in association with ATP-dependent HSP70 and HSP40 cochaperones. Implications of these findings are discussed.

The expression of small heat shock proteins in seeds responds to discrete developmental signals and suggests a general protective role in desiccation tolerance

To learn more about the function and regulation of small heat shock proteins (sHSPs) during seed development, we studied sHSP expression in wild-type and seed maturation mutants of Arabidopsis by western analysis and using an HSP17.4 promoter-driven beta-glucuronidase (GUS) reporter gene in transgenic plants. In the absence of stress, GUS activity increases during development until the entire embryo is stained before desiccation. Heat-stressed embryos stained for GUS at all stages, including early stages that showed no detectable HSP17. 4::GUS activity without heat. Examination of HSP17.4 expression in seeds of the transcriptional activator mutants abi3-6, fus3-3 (AIMS no. CS8014/N8014), and lec1-2 (AIMS no. CS2922/N2922) showed that protein and HSP17.4::GUS activity were highly reduced in fus3-3 and lec1-2 and undetectable in abi3-6 seeds. In contrast, heat-stressed abi3-6, fus3-3, and lec1-2 seeds stained for GUS activity throughout the embryo. These data indicate that there is distinct developmental and stress regulation of HSP17.4, and imply that ABI3 activates HSP17.4 transcription during development. Quantitation of sHSP protein in desiccation-intolerant seeds of abi3-6, fus3-3, lec1-2, and line24 showed that all had <2% of wild-type HSP17.4 levels. In contrast, the desiccation-tolerant but embryo-defective mutants emb266 (AIMS no. CS3049/N3049) and lec2-1 (AIMS no. CS2728/N2728) had wild-type levels of HSP17.4. These data correlate a reduction in sHSPs with desiccation intolerance and suggest that sHSPs have a general protective role throughout the seed.

Functional characterization of Xenopus small heat shock protein, Hsp30C: the carboxyl end is required for stability and chaperone activity

Small heat shock proteins protect cells from stress presumably by acting as molecular chaperones. Here we report on the functional characterization of a developmentally regulated, heat-inducible member of the Xenopus small heat shock protein family, Hsp30C. An expression vector containing the open reading frame of the Hsp30C gene was expressed in Escherichia coli. These bacterial cells displayed greater thermoresistance than wild type or plasmid-containing cells. Purified recombinant protein, 30C, was recovered as multimeric complexes which inhibited heat-induced aggregation of either citrate synthase or luciferase as determined by light scattering assays. Additionally, 30C attenuated but did not reverse heat-induced inactivation of enzyme activity. In contrast to an N-terminal deletion mutant, removal of the last 25 amino acids from the C-terminal end of 30C severely impaired its chaperone activity. Furthermore, heat-treated concentrated solutions of the C-terminal mutant formed nonfunctional complexes and precipitated from solution. Immunoblot and gel filtration analysis indicated that 30C binds with and maintains the solubility of luciferase preventing it from forming heat-induced aggregates. Coimmunoprecipitation experiments suggested that the carboxyl region is necessary for 30C to interact with target proteins. These results clearly indicate a molecular chaperone role for Xenopus Hsp30C and provide evidence that its activity requires the carboxyl terminal region.

Hsp25 and the p38 MAPK pathway are involved in differentiation of cardiomyocytes

The small heat-shock protein HSP25 is expressed in the heart early during development, and although multiple roles for HSP25 have been proposed, its specific role during development and differentiation is not known. P19 is an embryonal carcinoma cell line which can be induced to differentiate in vitro into either cardiomyocytes or neurons. We have used P19 to examine the role of HSP25 in differentiation. We found that HSP25 expression is strongly increased in P19 cardiomyocytes. Antisense HSP25 expression reduced the extent of cardiomyocyte differentiation and resulted in reduced expression of cardiac actin and the intermediate filament desmin and reduced level of cardiac mRNAs. Thus, HSP25 is necessary for differentiation of P19 into cardiomyocytes. In contrast, P19 neurons did not express HSP25 and antisense HSP25 expression had no effect on neuronal differentiation. The phosphorylation of HSP25 by the p38/SAPK2 pathway is known to be important for certain of its functions. Inhibition of this pathway by the specific inhibitor SB203580 prevented cardiomyocyte differentiation of P19 cells. In contrast, PD90589, which inhibits the ERK1/2 pathway, had no effect. Surprisingly, cardiogenesis was only sensitive to SB203580 during the first 2 days of differentiation, before HSP25 expression increases. In contrast to the effect of antisense HSP25, SB203580 reduced the level of expression of the mesodermal marker Brachyury-T during differentiation. Therefore, we propose that the p38 pathway acts on an essential target during early cardiogenesis. Once this initial step is complete, HSP25 is necessary for the functional differentiation of P19 cardiomyocytes, but its phosphorylation by p38/SAPK2 is not required.

The LEA-like protein HSP 12 in Saccharomyces cerevisiae has a plasma membrane location and protects membranes against desiccation and ethanol-induced stress

The LEA-like protein HSP 12 was identified as having a plasma membrane location in yeast. Gold particles, indicative of the presence of HSP 12, were observed on the external side of the plasma membrane when yeast grown to stationary phase were subjected to immunocytochemical analysis. Growth of yeast in the osmolyte mannitol resulted in an increased number of gold particles that were now observed to be present on both sides of the plasma membrane. No gold particles were observed using a mutant strain of the same yeast that did not express HSP 12. A model liposome system encapsulating the fluorescent dye calcein was used to investigate the protection by HSP 12 of membranes during desiccation. HSP 12 was found to act in an analogous manner to trehalose and protect liposomal membrane integrity against desiccation. The interaction between HSP 12 and the liposomal membrane was judged to be electrostatic as membrane protection was only observed with positively charged liposomes and not with either neutral or negatively charged liposomes. The ability of the wild-type and mutant yeast to grow in media containing ethanol was compared. It was found that yeast not expressing the HSP 12 protein were less able to grow in media containing ethanol. HSP 12 was shown to confer increased integrity on the liposomal membrane in the presence of ethanol. Ethanol, like mannitol, was found to induce HSP 12 protein synthesis. However, yeast grown in both ethanol and mannitol showed a decreased HSP 12 response compared with yeast grown in the presence of either osmolyte alone.

A small heat shock protein cooperates with heat shock protein 70 systems to reactivate a heat-denatured protein

Small heat shock proteins (sHsps) are a diverse group of heat-induced proteins that are conserved in prokaryotes and eukaryotes and are especially abundant in plants. Recent in vitro data indicate that sHsps act as molecular chaperones to prevent thermal aggregation of proteins by binding non-native intermediates, which can then be refolded in an ATP-dependent fashion by other chaperones. We used heat-denatured firefly luciferase (Luc) bound to pea (Pisum sativum) Hsp18.1 as a model to define the minimum chaperone system required for refolding of a sHsp-bound substrate. Heat-denatured Luc bound to Hsp18.1 was effectively refolded either with Hsc/Hsp70 from diverse eukaryotes plus the DnaJ homologs Hdj1 and Ydj1 (maximum = 97% Luc reactivation with k(ob) = 1.0 x 10(-2)/min), or with prokaryotic Escherichia coli DnaK plus DnaJ and GrpE (100% Luc reactivation, k(ob) = 11.3 x 10(-2)/min). Furthermore, we show that Hsp18.1 is more effective in preventing Luc thermal aggregation than the Hsc70 or DnaK systems, and that Hsp18.1 enhances the yields of refolded Luc even when other chaperones are present during heat inactivation. These findings integrate the aggregation-preventive activity of sHsps with the protein-folding activity of the Hsp70 system and define an in vitro system for further investigation of the mechanism of sHsp action.

Chloroplast small heat shock proteins: evidence for atypical evolution of an organelle-localized protein

Knowledge of the origin and evolution of gene families is critical to our understanding of the evolution of protein function. To gain a detailed understanding of the evolution of the small heat shock proteins (sHSPs) in plants, we have examined the evolutionary history of the chloroplast (CP)-localized sHSPs. Previously, these nuclear-encoded CP proteins had been identified only from angiosperms. This study reveals the presence of the CP sHSPs in a moss, Funaria hygrometrica. Two clones for CP sHSPs were isolated from a F. hygrometrica heat shock cDNA library that represent two distinct CP sHSP genes. Our analysis of the CP sHSPs reveals unexpected evolutionary relationships and patterns of sequence conservation. Phylogenetic analysis of the CP sHSPs with other plant CP sHSPs and eukaryotic, archaeal, and bacterial sHSPs shows that the CP sHSPs are not closely related to the cyanobacterial sHSPs. Thus, they most likely evolved via gene duplication from a nuclear-encoded cytosolic sHSP and not via gene transfer from the CP endosymbiont. Previous sequence analysis had shown that all angiosperm CP sHSPs possess a methionine-rich region in the N-terminal domain. The primary sequence of this region is not highly conserved in the F. hygrometrica CP sHSPs. This lack of sequence conservation indicates that sometime in land plant evolution, after the divergence of mosses from the common ancestor of angiosperms but before the monocot-dicot divergence, there was a change in the selective constraints acting on the CP sHSPs.

Folding pattern of the alpha-crystallin domain in alphaA-crystallin determined by site-directed spin labeling

The folding pattern of the alpha-crystallin domain, a conserved protein module encoding the molecular determinants of structure and function in the small heat-shock protein superfamily, was determined in the context of the lens protein alphaA-crystallin by systematic application of site-directed spin labeling. The sequence-specific secondary structure was assigned primarily from nitroxide scanning experiments in which the solvent accessibility and mobility of a nitroxide probe were measured as a function of residue number. Seven beta-strands were identified and their orientation relative to the aqueous solvent determined, thus defining the residues lining the hydrophobic core. The pairwise packing of adjacent strands in the primary structure was deduced from patterns of proximities in nitroxide pairs with one member on the exposed surface of each strand. In addition to identifying supersecondary structures, these proximities revealed that the seven strands are arranged in two beta-sheets. The overall packing of the two sheets was determined by application of the general rules of protein structure and from proximities in nitroxide pairs designed to distinguish between known all beta-sheet folds. Our data are consistent with an immunoglobulin-like fold consisting of two aligned beta-sheets. Comparison of this folding pattern to that of the evolutionary distant alpha-crystallin domain in Methanococcus jannaschii heat-shock protein 16.5 reveals a conserved core structure with the differences sequestered at one edge of the beta-sandwich. A beta-strand deletion in alphaA-crystallin disrupts a subunit interface and allows for a different dimerization motif. Putative substrate binding regions appear to include a buried loop and a buried turn, suggesting that the chaperone function involves a disassembly of the oligomer.

Molecular characterization of Oryza sativa 16.9 kDa heat shock protein

A rice class I low-molecular-mass heat shock protein (LMM HSP) Oshsp 16.9 was overexpressed in Escherichia coli. Oligomerized complexes of Oshsp16.9 were harvested and electron microscopic observations of purified complexes revealed globular structures of 10-20 nm in diameter (with majority of 15-18 nm) and calculated to comprise approx. 12 monomers per complex. In comparison, complexes from native rice class I LMM HSPs were observed as larger ellipsoid- or globular-like random aggregated hetero-oligomers. To characterize the biochemical functions of the hydrophobic N-terminal region of Oshsp16.9, a truncation in the N-terminal region was constructed and introduced into E. coli. Results showed that the N-terminal truncated Oshsp16.9 mutant was capable of forming complexes similar to the full-length Oshsp16.9; however, the deletion protein failed to confer in vitro protein thermostability under elevated temperatures. Protein assays from in vivo treatments at higher temperatures exhibited that non-specific interactions of E. coli cellular proteins only occurred with full-length Oshsp16.9 complexes but not with the mutant complex. In vitro immunoprecipitation of cellular proteins from E. coli overexpressing full-length Oshsp16.9 showed that interactions between plant LMM HSP and E. coli cellular proteins are temperature-dependent. Taken together, the hydrophobic N-terminal region of rice class I LMM HSP is critical in the ability of the protein to interact/bind with its potential substrates.

Methionine sulfoxidation of the chloroplast small heat shock protein and conformational changes in the oligomer

The small heat shock proteins (sHsps), which counteract heat and oxidative stress in an unknown way, belong to a protein family of sHsps and alpha-crystallins whose members form large oligomeric complexes. The chloroplast-localized sHsp, Hsp21, contains a conserved methionine-rich sequence, predicted to form an amphipatic helix with the methionines situated along one of its sides. Here, we report how methionine sulfoxidation was detected by mass spectrometry in proteolytically cleaved peptides that were produced from recombinant Arabidopsis thaliana Hsp21, which had been treated with varying concentrations of hydrogen peroxide. Sulfoxidation of the methionine residues in the conserved amphipatic helix coincided with a significant conformational change in the Hsp21 protein oligomer.

ATP and the core "alpha-Crystallin" domain of the small heat-shock protein alphaB-crystallin

Electrospray ionization mass spectrometry (ESI-LC/MS) of tryptic digests of human alphaB-crystallin in the presence and absence of ATP identified four residues located within the core "alpha-crystallin" domain, Lys(82), Lys(103), Arg(116), and Arg(123), that were shielded from the action of trypsin in the presence of ATP. In control experiments, chymotrypsin was used in place of trypsin. The chymotryptic fragments of human alphaB-crystallin produced in the presence and absence of ATP were analyzed using liquid chromatography-tandem mass spectrometry (LC-MS/MS). Seven chymotryptic cleavage sites, Trp(60), Phe(61), Phe(75), Phe(84), Phe(113), Phe(118), and Tyr(122), located near or within the core alpha-crystallin domain, were shielded from the action of chymotrypsin in the presence of ATP. Chemically similar analogs of ATP were less protective than ATP against proteolysis by trypsin or chymotrypsin. ATP had no effect on the enzymatic activity of trypsin and the K(m) for trypsin was 0.031 mM in the presence of ATP and 0.029 mM in the absence of ATP. The results demonstrated an ATP-dependent structural modification in the core alpha-crystallin domain conserved in nearly all identified small heat-shock proteins that act as molecular chaperones.

Disruption of the gene for Hsp30, an alpha-crystallin-related heat shock protein of Neurospora crassa, causes defects in import of proteins into mitochondria

The gene for Hsp30, the only known alpha-crystallin-related heat shock protein of Neurospora crassa, was disrupted by repeat-induced point mutagenesis, leading to loss of cell survival at high temperature. Hsp30, which is not synthesized at 30 degrees C, associates reversibly with the mitochondria at high temperature (45 degrees C). In this study, we found that import of selected proteins into internal compartments of mitochondria, following their synthesis in the cytosol, was severely impaired at high temperature in a strain mutant in Hsp30. After 70 min of cell incubation at 45 degrees C, most matrix, inner membrane, and intermembrane-space proteins tested were reduced in import by about 50-70% in the mutant, as compared to wild-type cells. In contrast, assembly of selected proteins into the outer mitochondrial membrane was not reduced, except for one component of the preprotein translocase complex of the mitochondrial outer membrane. Three proteins of this complex co-immunoprecipitated with Hsp30 of wild-type cells incubated at 45 degrees C. We propose that Hsp30 interacts with the preprotein translocase of the mitochondrial outer membrane and that it chaperones the activity of one or more components of this translocase complex at high temperature.

Proteome analysis of heat shock protein expression in Bradyrhizobium japonicum

A set of 19 heat shock proteins (Hsp) was observed - by subtractive two-dimensional gel electrophoresis - to be induced when Bradyrhizobium japonicum, the nitrogen-fixing root-nodule symbiont of soybean, was temperature up-shifted from 28 degrees C to 43 degrees C. Up-regulated protein spots were excised from multiple two-dimensional gels. The proteins were concentrated using a funnel-gel device before being blotted onto poly(vinylidene difluoride) membranes for digestion with trypsin before MS and tandem MS analysis or for Edman sequence determination. Five proteins in the range 8-20 kDa were identified as the small Hsp (sHsp; HspB, C, D, E and H) and three others showed strong sequence similarity to the sHsp family. Two other low molecular mass proteins corresponded to GroES1 and GroES2, and five novel proteins were found. Four proteins of approximately 60 kDa were identified as GroEL2, GroEL4, and GroEL5 and DnaK. An analysis of the heat shock induction of DnaK, of four of the most strongly induced GroESL proteins and six of the sHsp revealed that the proteins could be placed into four distinct regulatory groups based on the kinetics of protein appearance.

A human nuclear-localized chaperone that regulates dimerization, DNA binding, and transcriptional activity of bZIP proteins

We have identified and cloned a human nuclear protein that dramatically increases DNA binding of transcription factors that contain a basic region-leucine zipper (bZIP) DNA binding domain. We show that this bZIP enhancing factor (BEF) functions as a molecular chaperone. BEF stimulates DNA binding by recognizing the unfolded leucine zipper and promoting the folding of bZIP monomers to dimers; the elevated concentration of the bZIP dimer then drives the DNA binding reaction. Antisense experiments indicate that BEF is required for efficient transcriptional activation by bZIP proteins in vivo. Our results reveal protein folding in the nucleus as a step at which sequence-specific DNA binding proteins can be regulated.

Regulation of Hsp27 oligomerization, chaperone function, and protective activity against oxidative stress/tumor necrosis factor alpha by phosphorylation

The small heat shock proteins (sHsps) from human (Hsp27) and mouse (Hsp25) form large oligomers which can act as molecular chaperones in vitro and protect cells from heat shock and oxidative stress when overexpressed. In addition, mammalian sHsps are rapidly phosphorylated by MAPKAP kinase 2/3 at two or three serine residues in response to various extracellular stresses. Here we analyze the effect of sHsp phosphorylation on its quaternary structure, chaperone function, and protection against oxidative stress. We show that in vitro phosphorylation of recombinant sHsp as well as molecular mimicry of Hsp27 phosphorylation lead to a significant decrease of the oligomeric size. We demonstrate that both phosphorylated sHsps and the triple mutant Hsp27-S15D,S78D,S82D show significantly decreased abilities to act as molecular chaperones suppressing thermal denaturation and facilitating refolding of citrate synthase in vitro. In parallel, Hsp27 and its mutants were analyzed for their ability to confer resistance against oxidative stress when overexpressed in L929 and 13.S.1.24 cells. While wild type Hsp27 confers resistance, the triple mutant S15D,S78D,S82D cannot protect against oxidative stress effectively. These data indicate that large oligomers of sHsps are necessary for chaperone action and resistance against oxidative stress whereas phosphorylation down-regulates these activities by dissociation of sHsp complexes to tetramers.

Accumulation of small heat-shock protein homologs in the endoplasmic reticulum of cortical parenchyma cells in mulberry in association with seasonal cold acclimation

Cortical parenchyma cells of mulberry (Morus bombycis Koidz.) trees acquire extremely high freezing tolerance in winter as a result of seasonal cold acclimation. The amount of total proteins in endoplasmic reticulum (ER)-enriched fractions isolated from these cells increased in parallel with the process of cold acclimation. Protein compositions in the ER-enriched fraction also changed seasonally, with a prominent accumulation of 20-kD (WAP20) and 27-kD (WAP27) proteins in winter. The N-terminal amino acid sequence of WAP20 exhibited homology to ER-localized small heat-shock proteins (smHSPs), whereas that of WAP27 did not exhibit homology to any known proteins. Like other smHSPs, WAP20 formed a complex of high molecular mass in native-polyacrylamide gel electrophoresis. Furthermore, not only WAP20 but also 21-kD proteins reacted with antibodies against WAP20. Fractionation of the crude microsomes by isopycnic sucrose-gradient centrifugation revealed that both WAP27 and WAP20 were distributed on a density corresponding to the fractions with higher activity of ER marker enzyme, suggesting localization of these proteins in the ER. When ER-enriched fractions were treated with trypsin in the absence of detergent, WAP20 and WAP27 were undigested, suggesting localization of these proteins inside the ER vesicle. The accumulation of a large quantity of smHSPs in the ER in winter as a result of seasonal cold acclimation indicates that these proteins may play a significant role in the acquisition of freezing tolerance in cortical parenchyma cells of mulberry trees.

Heterologous expression of a plant small heat-shock protein enhances Escherichia coli viability under heat and cold stress

A small heat-shock protein (sHSP) that shows molecular chaperone activity in vitro was recently purified from mature chestnut (Castanea sativa) cotyledons. This protein, renamed here as CsHSP17. 5, belongs to cytosolic class I, as revealed by cDNA sequencing and immunoelectron microscopy. Recombinant CsHSP17.5 was overexpressed in Escherichia coli to study its possible function under stress conditions. Upon transfer from 37 degrees C to 50 degrees C, a temperature known to cause cell autolysis, those cells that accumulated CsHSP17.5 showed improved viability compared with control cultures. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of cell lysates suggested that such a protective effect in vivo is due to the ability of recombinant sHSP to maintain soluble cytosolic proteins in their native conformation, with little substrate specificity. To test the recent hypothesis that sHSPs may be involved in protection against cold stress, we also studied the viability of recombinant cells at 4 degrees C. Unlike the major heat-induced chaperone, GroEL/ES, the chestnut sHSP significantly enhanced cell survivability at this temperature. CsHSP17.5 thus represents an example of a HSP capable of protecting cells against both thermal extremes. Consistent with these findings, high-level induction of homologous transcripts was observed in vegetative tissues of chestnut plantlets exposed to either type of thermal stress but not salt stress.

Purification and characterization of the 16-kDa heat-shock-responsive protein from the thermophilic cyanobacterium Synechococcus vulcanus, which is an alpha-crystallin-related, small heat shock protein

A 16-kDa protein, one of the major proteins that accumulates upon heat-shock treatment in the thermophilic cyanobacterium Synechococcus vulcanus, was purified to apparent homogeneity. The N-terminal and internal amino acid sequences of the protein exhibited a homology to the alpha-crystallin-related, small heat shock proteins from other organisms. The protein was designated HspA. Size-exclusion chromatography and nondenaturing gel electrophoresis demonstrated that HspA formed a large homo-oligomer consisting of 24 subunits. It prevented the aggregation of porcine malic dehydrogenase at 45 degrees C and 50 degrees C and citrate synthase at 50 degrees C. The activity of the malic dehydrogenase, however, was not protected under these heat-shock conditions or reactivated after a shift in temperature from 45 or 50 degrees C to 21 degrees C. HspA was able to enhance the refolding of chemically denatured rabbit muscle lactate dehydrogenase in an ATP-independent manner. A homologue to the 16-kDa protein was also found to be induced upon heat-shock treatment in the mesophilic cyanobacterium Synechocystis sp. PCC 6803.

Messenger RNA-binding properties of nonpolysomal ribonucleoproteins from heat-stressed tomato cells

Most cells experiencing heat stress reprogram their translational machinery to favor the synthesis of heat-stress proteins. Translation of other transcripts is almost completely repressed, but most untranslated messengers are not degraded. In contrast to yeast, Drosophila melanogaster, and HeLa cells, plant cells store repressed messengers in cytoplasmic nonpolysomal ribonucleoproteins (RNPs). To follow the fate of untranslated transcripts, we studied protein composition, mRNA content, and RNA-binding properties of nonpolysomal RNPs from heat-stressed tomato (Lycopersicon peruvianum) cells. Contrary to the selective interaction in vivo, RNPs isolated from tomato cells bound both stress-induced and repressed messengers, suggesting that the selection mechanism resides elsewhere. This binding was independent of a cap or a poly(A) tail. The possible role of proteasomes and heat-stress granules (HSGs) in mRNA storage is a topic of debate. We found in vitro messenger-RNA-binding activity in messenger RNP fractions free of C2-subunit-containing proteasomes and HSGs. In addition, mRNAs introduced into tobacco (Nicotiana plumbaginifolia) protoplasts were found in the cytoplasm but were not associated with HSGs.

Biochemical characterization of the small heat shock protein IbpB from Escherichia coli

Escherichia coli IbpB was overexpressed in a strain carrying a deletion in the chromosomal ibp operon and purified by refolding. Under our experimental conditions, IbpB exhibited pronounced size heterogeneity. Basic oligomers, roughly spherical and approximately 15 nm in diameter, interacted to form larger particles in the 100-200-nm range, which themselves associated to yield loose aggregates of micrometer size. IbpB suppressed the thermal aggregation of model proteins in a concentration-dependent manner, and its CD spectrum was consistent with a mostly beta-pleated secondary structure. Incubation at high temperatures led to a partial loss of secondary structure, the progressive exposure of tryptophan residues to the solvent, the dissociation of high molecular mass aggregates into approximately 600-kDa oligomers, and an increase in surface hydrophobicity. Structural changes were reversible between 37 and 55 degrees C, and, up to 55 degrees C, hydrophobic sites were reburied upon cooling. IbpB exhibited a biphasic unfolding trend upon guanidine hydrochloride (GdnHCl) treatment and underwent comparable conformational changes upon melting and during the first GdnHCl-induced transition. However, hydrophobicity decreased with increasing GdnHCl concentrations, suggesting that efficient exposure of structured hydrophobic sites involves denaturant-sensitive structural features. By contrast, IbpB hydrophobicity rose at high NaCl concentrations and increased further at high temperatures. Our results support a model in which temperature-driven conformational changes lead to the reversible exposure of normally shielded binding sites for nonnative proteins and suggest that both hydrophobicity and charge context may determine substrate binding to IbpB.

The synthesis of a small heat shock/alpha-crystallin protein in Artemia and its relationship to stress tolerance during development

Fertilized oocytes of the brine shrimp Artemia franciscana undergo either ovoviviparous or oviparous development, yielding free-swimming larvae (nauplii) or encysted gastrulae (cysts), respectively. Encystment is followed by diapause, wherein metabolism is greatly reduced; the resulting cysts are very resistant to extreme stress, including desiccation and long-term anoxia. The synthesis of p26, a small heat shock/alpha-crystallin protein produced only in oviparously developing Artemia, is shown in this paper to be transcriptionally regulated. A p26 mRNA of about 0.7 kb was detected on Northern blots in the second day after oocyte fertilization. It peaked as embryos encysted and declined rapidly when activated cysts resumed development. The appearance of p26 protein, as indicated by immunoprobing of Western blots, followed mRNA by 1 day; it also increased as encystment occurred but remained constant during postgastrula development of cysts. However, p26 underwent a marked reduction during emergence of nauplii and could not be detected in cell-free extracts of second-instar larvae. p26 entered nuclei of encysting embryos soon after synthesis and was localized therein as late as instar II, when it was restricted to a small set of salt gland nuclei. First-instar larvae derived from cysts were more thermotolerant than larvae that had developed ovoviviparously, but synthesis of p26 was not induced by heat under the experimental conditions employed. Additionally, transformed bacteria synthesizing p26 were more thermotolerant than bacteria that lacked the protein. The results support the proposal that p26, a developmentally regulated protein synthesized during embryo encystment, has chaperone activity in vivo and protects the proteins of encysted Artemia from stress-induced denaturation.

Site-directed spin labeling study of subunit interactions in the alpha-crystallin domain of small heat-shock proteins. Comparison of the oligomer symmetry in alphaA-crystallin, HSP 27, and HSP 16.3

Site-directed spin labeling was used to investigate quaternary interactions along a conserved sequence in the alpha-crystallin domain of alphaA-crystallin, heat-shock protein 27 (HSP 27), and Mycobacterium tuberculosis heat-shock protein (HSP 16.3). In previous work, it was demonstrated that this sequence in alphaA-crystallin and HSP 27 forms a beta-strand involved in subunit contacts. In this study, the symmetry and geometry of the resulting interface were investigated. For this purpose, the pattern of spin-spin interactions was analyzed, and the number of interacting spins was determined in alphaA-crystallin and HSP 27. The results reveal a 2-fold symmetric interface consisting of two beta-strands interacting near their N termini in an antiparallel fashion. Remarkably, subunit interactions along this interface persist when the alpha-crystallin domains are expressed in isolation. Because this domain in alphaA-crystallin forms dimers and tetramers, it is inferred that interactions along this interface mediate the formation of a basic dimeric unit. In contrast, in HSP 16.3, spin-spin interactions are observed at only one site near the C terminus of the sequence. Furthermore, cysteine substitutions at residues flanking the N terminus resulted in the dissociation of the oligomeric structure. Analysis of the spin-spin interactions and size exclusion chromatography indicates a 3-fold symmetric interface. Taken together, our results demonstrate that subunit interactions in the alpha-crystallin domain of mammalian small heat-shock proteins assemble a basic building block of the oligomeric structure. Sequence divergence in this domain results in variations in the size and symmetry of the quaternary structure between distant members of the small heat-shock protein family.

Glucose metabolism in Neurospora is altered by heat shock and by disruption of HSP30

We compared the metabolism of [1-13C]glucose by wild type cells of Neurospora crassa at normal growth temperature and at heat shock temperatures, using nuclear magnetic resonance analysis of cell extracts. High temperature led to increased incorporation of 13C into trehalose, relative to all other metabolites, and there was undetectable synthesis of glycerol, which was a prominent metabolite of glucose at normal temperature (30 degrees C). Heat shock strongly reduced formation of tricarboxylic acid cycle intermediates, approximately 10-fold, and mannitol synthesis was severely depressed at 46 degrees C, but only moderately reduced at 45 degrees C. A mutant strain of N. crassa that lacks the small alpha-crystallin-related heat shock protein, Hsp30, shows poor survival during heat shock on a nutrient medium with restricted glucose. An analysis of glucose metabolism of this strain showed that, unlike the wild type strain, Hsp30-deficient cells may accumulate unphosphorylated glucose at high temperature. This suggestion that glucose-phosphorylating hexokinase activity might be depressed in mutant cells led us to compare hexokinase activity in the two strains at high temperature. Hexokinase was reduced more than 35% in the mutant cell extracts, relative to wild type extracts. alpha-Crystallin and an Hsp30-enriched preparation protected purified hexokinase from thermal inactivation in vitro, supporting the proposal that Hsp30 may directly stabilize hexokinase in vivo during heat shock.