Mimicking the plant cell interior under water stress by macromolecular crowding: disordered dehydrin proteins are highly resistant to structural collapse

The dehydrins are a class of drought-induced proteins in plants that lack a fixed three-dimensional structure. Their specific molecular action, as well as the reason for their disordered character, is as yet poorly understood. It has been speculated, however, that the dehydrins are tuned to acquire a biologically active structure only under the conditions in which they normally function (i.e. upon dehydration). To test this hypothesis, we here investigate the effect of reduced water content and macromolecular crowding on three dehydrins from Arabidopsis (Arabidopsis thaliana). As a simplistic model for mimicking cellular dehydration, we used polyethylene glycol, glycerol, and sugars that plants naturally employ as compatible solutes (i.e. sucrose and glucose). Macromolecular crowding was induced by the large polysaccharides Ficoll and dextran. The results show that the dehydrins are remarkably stable in their disordered state and are only modestly affected by the solvent alterations. A notable exception is the dehydrin Cor47, which shows a small, intrinsic increase in helical structure at high concentrations of osmolytes. We also examined the effect of phosphorylation but found no evidence that such posttranslational modifications of the dehydrin sequences modulate their structural response to osmolytes and crowding agents. These results suggest that the dehydrins are highly specialized proteins that have evolved to maintain their disordered character under conditions in which unfolded states of several globular proteins would tend to collapse.     

Isolation and characterization of a novel dehydrin gene from Capsella bursa-pastoris

A novel dehydrin gene designated as Cbcor29 was cloned from Capsella bursa-pastoris by rapid amplification of cDNA ends (RACE) and genome walker technique. The full-length cDNA of Cbcor29 was 1101 bp long with a 783 bp open reading frame (ORF), encoding a putative protein of 261 amino acids. Like other dehydrin proteins, CbCOR29 contained a high percentage of charged and polar amino acids, in which Cys and Trp amino acids were absent. Besides, predicted CbCOR29 protein possesses three conserved repeats of the characterized Lys-rich domains (K-segments), and a Ser-rich domain (S-segment) prior to the first Lys-rich domain, which presented a typical SK3 structure of dehydrins. Analysis of Cbcor29 genomic DNA revealed that it contained 2 exons and 1 intron, which was a typical character of dehydrin genes. Subsequent bioinformatic analysis also showed that the sequence of CbCOR29 had high homology with other dehydrin proteins, especially with cor47 from Arabidopsis thaliana. Moreover, semi-quantitative RT-PCR revealed that the expression of Cbcor29 could be induced by exposure to drought, low-temperature, NaCl and exogenous ABA treatment respectively. Our study implied that the Cbcor29 gene was a new member of the dehydrin gene family and might exert functions in drought-, cold- and salt- responsiveness in Capsella bursa-pastoris.     

Sequence composition versus sequence order in the cryoprotective function of an intrinsically disordered stress‐response protein

Intrinsically disordered stress proteins have been shown to act as chaperones, protecting proteins from damage caused by stresses such as freezing and thawing. Dehydration proteins (dehydrins) are intrinsically disordered stress proteins that are found in almost all land plants. They consist of a variable number of the short, semi‐conserved, Y‐, S‐, and K‐segments, with longer stretches of poorly conserved sequences in between. Previous studies have provided conflicting views on the details of the dehydrin cryoprotective mechanism of enzymes. Experiments with polyethylene glycol (PEG) have shown that PEG cryoprotective efficiency is the same as dehydrins of the same hydrodynamic radius, suggesting that the protein's disordered and polar nature is important, rather than the specific order of the residues. To further elucidate the mechanism, we created scrambled variants of the wild grape dehydrins K₂ and YSK₂ and tested their ability to protect lactate dehydrogenase and yeast frataxin homolog‐1 from freeze/thaw damage. The results show that for preventing aggregation, it is the sequence composition and the size of the dehydrin that is the most important factor in protection, while for freeze/thaw damage causing loss of secondary structure, it is the sequence composition that is most significant.     

Tunable membrane binding of the intrinsically disordered dehydrin Lti30, a cold-induced plant stress protein

Dehydrins are intrinsically disordered plant proteins whose expression is upregulated under conditions of desiccation and cold stress. Their molecular function in ensuring plant survival is not yet known, but several studies suggest their involvement in membrane stabilization. The dehydrins are characterized by a broad repertoire of conserved and repetitive sequences, out of which the archetypical K-segment has been implicated in membrane binding. To elucidate the molecular mechanism of these K-segments, we examined the interaction between lipid membranes and a dehydrin with a basic functional sequence composition: Lti30, comprising only K-segments. Our results show that Lti30 interacts electrostatically with vesicles of both zwitterionic (phosphatidyl choline) and negatively charged phospholipids (phosphatidyl glycerol, phosphatidyl serine, and phosphatidic acid) with a stronger binding to membranes with high negative surface potential. The membrane interaction lowers the temperature of the main lipid phase transition, consistent with Lti30's proposed role in cold tolerance. Moreover, the membrane binding promotes the assembly of lipid vesicles into large and easily distinguishable aggregates. Using these aggregates as binding markers, we identify three factors that regulate the lipid interaction of Lti30 in vitro: (1) a pH dependent His on/off switch, (2) phosphorylation by protein kinase C, and (3) reversal of membrane binding by proteolytic digest.     

The Plant Dehydrins: Structure and Putative Functions

This review deals with recent data on the structure and biochemical properties of dehydrins, proteins that are normally synthesized in maturating seeds during their desiccation, and also in vegetative tissues of plants treated with abscisic acid or exposed to environmental stress factors that result in cellular dehydration. The dehydrins are considered as stress proteins involved in formation of plant protective reactions against dehydration. The generally accepted classification of dehydrins is based on their structural features, such as the presence of conserved sequences, designated as Y-, S-, and K-segments. The K-segment representing a highly conserved 15 amino acid motif (EKKGIMDKIKEKLPG) forming amphiphilic -helix has been found in all dehydrins. The pathways of regulation of dehydrin gene expression, putative functions of dehydrins, and molecular mechanisms of their actions are discussed.     

Isolation and characterization of a novel dehydrin gene from Capsella bursa-pastoris

A novel dehydrin gene designated as Cbcor29 was cloned from Capsella bursa-pastoris by rapid amplification of cDNA ends (RACE) and genome walker technique. The full-length cDNA of Cbcor29 was 1101 bp long with a 783 bp open reading frame (ORF), encoding a putative protein of 261 amino acids. Like other dehydrin proteins, CbCOR29 contained a high percentage of charged and polar amino acids, in which Cys and Trp amino acids were absent. In addition, the predicted CbCOR29 protein possesses three conserved repeats of the characterized Lys-rich domains (K-segments), and a Ser-rich domain (S-segment) prior to the first Lys-rich domain, which presented a typical SK3 structure of dehydrins. Analysis of Cbcor29 genomic DNA revealed that it contains 2 exons and 1 intron, which is a typical character of dehydrin genes. Subsequent bioinformatic analysis also showed that the sequence of CbCOR29 has high homology with other dehydrin proteins, especially with cor47 from Arabidopsis thaliana. Moreover, semi-quantitative RT-PCR revealed that the expression of Cbcor29 can be induced by exposure to drought, low temperature, NaCl, and exogenous ABA treatment. Our study led to the conclusion that the Cbcor29 gene is a new member of the dehydrin gene family and might exert functions in responsiveness to drought, cold, and salt in Capsella bursa-pastoris. Published in Russian in Molekulyarnaya Biologiya, 2006, Vol. 40, No. 1, pp. 52–60. The article was submitted by the authors in English.     

Cryoprotective mechanism of a small intrinsically disordered dehydrin protein

Dehydration proteins (Dehydrins) are expressed during dehydration stress in plants and are thought to protect plant proteins and membranes from the loss of water during drought and at cold temperatures. Several different dehydrins have been shown to protect lactate dehydrogenase (LDH) from damage from being frozen and thawed. We show here that a 48 residue K₂ dehydrin from Vitis riparia protects LDH more effectively than bovine serum albumin, a protein with known cryoprotective function. Light scattering and 8‐anilino‐1‐naphthalene sulfonate fluorescence experiments show that dehydrins prevent aggregation and unfolding of the enzyme. The cryoprotective effects of LDH are reduced by the addition of salt, suggesting that the positively charged K‐segments are attracted to a negatively charged surface but this does not result in binding. Overall K₂ is an intrinsically disordered protein; nuclear magnetic resonance relaxation experiments indicate that the two‐terminal, Lys‐rich K‐segments show a weak propensity for α‐helicity and are flexible, and that the central, polar rich phi‐segment has no secondary structure preference and is highly flexible. We propose that the phi‐segments in dehydrins are important for maintaining the disordered structure so that the protein can act as a molecular shield to prevent partially denatured proteins from interacting with one another, whereas the K‐segments may help to localize the dehydrin near the enzyme surface.     

Phosphorylation of Thellungiella salsuginea dehydrins TsDHN-1 and TsDHN-2 facilitates cation-induced conformational changes and actin assembly

Group 2 late embryogenesis abundant (LEA) proteins, also known as dehydrins, are intrinsically disordered proteins that are expressed in plants experiencing extreme environmental conditions such as drought or low temperatures. These proteins are characterized by the presence of at least one conserved, lysine-rich K-segment and sometimes by one or more serine-rich S-segments that are phosphorylated. Dehydrins may stabilize proteins and membrane structures during environmental stress and can sequester and scavenge metal ions. Here, we investigate how the conformations of two dehydrins from Thellungiella salsuginea, denoted as TsDHN-1 (acidic) and TsDHN-2 (basic), are affected by pH, interactions with cations and membranes, and phosphorylation. Both TsDHN-1 and TsDHN-2 were expressed as SUMO fusion proteins for in vitro phosphorylation by casein kinase II (CKII), and structural analysis by circular dichroism and attenuated total reflection-Fourier transform infrared spectroscopy. We show that the polyproline II conformation can be induced in the dehydrins by their environmental conditions, including changes in the concentration of divalent cations such as Ca(2+). The assembly of actin by these dehydrins was assessed by sedimentation assays and viewed by transmission electron and atomic force microscopy. Phosphorylation allowed both dehydrins to polymerize actin filaments. These results support the hypothesis that dehydrins stabilize the cytoskeleton under stress conditions and further that phosphorylation may be an important feature of this stabilization.     

Zinc induces disorder-to-order transitions in free and membrane-associated Thellungiella salsuginea dehydrins TsDHN-1 and TsDHN-2: a solution CD and solid-state ATR-FTIR study

Dehydrins are intrinsically unstructured proteins that are expressed in plants experiencing extreme environmental conditions such as drought or low temperature. Although their role is not completely understood, it has been suggested that they stabilize proteins and membrane structures during environmental stress and also sequester metals such as zinc. Here, we investigate two dehydrins (denoted as TsDHN-1 and TsDHN-2) from Thellungiella salsuginea. This plant is a crucifer that thrives in the Canadian sub-Arctic (Yukon Territory) where it grows on saline-rich soils and experiences periods of both extreme cold and drought. We show using circular dichroism and attenuated total reflection-Fourier transform infrared spectroscopy that ordered secondary structure is induced and stabilized in these proteins, both in free and vesicle-bound form, by association with zinc. In membrane-associated form, both proteins have an increased proportion of β-strand conformation induced by the cation, in addition to the amphipathic α-helices formed by their constituent K-segments. These results support the hypothesis that dehydrins stabilize plant plasma and organellar membranes in conditions of stress, and further that zinc may be an important co-factor in stabilization. Whereas dehydrins in the cytosol of a plant cell undergoing dehydration or temperature stress form bulk hydrogels and remain primarily disordered, dehydrins with specific membrane- or protein-associations will have induced ordered secondary structures.     

Phosphorylation regulated ion-binding is a property shared by the acidic subclass dehydrins

Dehydrins are a family of proteins that accumulate in response to abiotic stresses. Little is known about the biochemical functions of these proteins. It is known that the Arabidopsis dehydrin, ERD14, is activated by phosphorylation to bind calcium and other ions. To begin to categorize the Arabidopsis dehydrins into functional families, we determined whether representative members of the dehydrin sub families share the properties of ERD14. When phosphorylated in vitro with casein kinase II; recombinant COR47, and ERD10 (and ERD14) become activated to bind calcium. ERD14 exhibited the highest calcium-binding activity followed by ERD10 and COR47. These dehydrins, when isolated from cold-treated Arabidopsis plants were also shown to have phosphorylation-dependent, calcium-binding activity. RAB18 showed very little calcium binding activity, even though it was phosphorylated by casein kinase II. XERO2 was not phosphorylated with CKII and did not bind calcium. Competition studies suggest that other divalent cations may bind to the dehydrins COR47, ERD10, and ERD14. Utilizing matrix-assisted laser desorption ionization – time of flight mass spectroscopy (MALDI-TOF), we determined that the poly serine region located in all three calcium-binding family members (COR47, ERD10, and ERD14) is the most likely phosphorylation site responsible for the activation of calcium binding. These results are consistent with a distinct biochemical function for the acidic subclass of dehydrins (COR47, ERD10, and ERD14) as ion (calcium)-interacting proteins.     

Interactions of intrinsically disordered Thellungiella salsuginea dehydrins TsDHN-1 and TsDHN-2 with membranes - synergistic effects of lipid composition and temperature on secondary structure

Dehydrins are intrinsically disordered (unstructured) proteins that are expressed in plants experiencing stressful conditions such as drought or low temperature. Dehydrins are typically found in the cytosol and nucleus, but also associate with chloroplasts, mitochondria, and the plasma membrane. Although their role is not completely understood, it has been suggested that they stabilize proteins or membrane structures during environmental stress, the latter association mediated by formation of amphipathic α-helices by conserved regions called the K-segments. Thellungiella salsuginea is a crucifer that thrives in the Canadian sub-Arctic (Yukon Territory) where it grows on saline-rich soils and experiences periods of both extreme cold and drought. We have cloned and expressed in Escherichia coli two dehydrins from this plant, denoted TsDHN-1 (acidic) and TsDHN-2 (basic). Here, we show using transmission-Fourier transform infrared (FTIR) spectroscopy that ordered secondary structure is induced and stabilized in these proteins by association with large unilamellar vesicles emulating the lipid compositions of plant plasma and organellar membranes. Moreover, this induced folding is enhanced at low temperatures, lending credence to the hypothesis that dehydrins stabilize plant outer and organellar membranes in conditions of cold.     

Overexpression of Multiple Dehydrin Genes Enhances Tolerance to Freezing Stress in Arabidopsis

To elucidate the contribution of dehydrins (DHNs) to freezing stress tolerance in Arabidopsis, transgenic plants overexpressing multiple DHN genes were generated. Chimeric double constructs for expression of RAB18 and COR47 (pTP9) or LTI29 and LTI30 (pTP10) were made by fusing the coding sequences of the respective DHN genes to the cauliflower mosaic virus 35S promoter. Overexpression of the chimeric genes in Arabidopsis resulted in accumulation of the corresponding dehydrins to levels similar or higher than in cold-acclimated wild-type plants. Transgenic plants exhibited lower LT50 values and improved survival when exposed to freezing stress compared to the control plants. Post-embedding immuno electron microscopy of high-pressure frozen, freeze-substituted samples revealed partial intracellular translocation from cytosol to the vicinity of the membranes of the acidic dehydrin LTI29 during cold acclimation in transgenic plants. This study provides evidence that dehydrins contribute to freezing stress tolerance in plants and suggests that this could be partly due to their protective effect on membranes.     

In vitro selection of SV40 T antigen epitope loss variants by site-specific cytotoxic T lymphocyte clones

SV40-transformed cells of C57BL/6 (B6) mouse origin (H-2b) express four distinct predominant antigenic sites, I, II, III, and IV, on SV40 large tumor (T) Ag that are recognized by SV40 T Ag-specific CTL clones. In this study, we selected SV40 T Ag-positive cell lines which had lost one or more of the antigenic sites, by in vitro cocultivation of a SV40-transformed B6 mouse kidney cell line (K-0) with SV40 T Ag site-specific CTL clones, Y-1 (site I specific), Y-2 (site II specific), Y-3 (site III specific), and Y-4 (site IV specific). All of the CTL-resistant cell lines expressed large quantities of cell surface H-2 class I Ag. K-1 cells selected by CTL clone Y-1 lost the expression of antigenic sites I, II, and III, but not site IV. K-2 and K-3 cells selected by CTL clones Y-2 and Y-3, respectively, were found to be negative for sites II and III but expressed sites I and IV. K-4 cells selected by CTL clone Y-4 lost the expression of only site IV. K-1,4 cells (sites I-, II-, III-, IV-) were selected from K-1 cells by cocultivation with CTL clone Y-4, K-2,4 cells (sites I+, II-, III-, IV-) were selected from K-2 cells by CTL clone Y-4. K-3,1 cells (sites I-, II-, III-, IV+) were selected from K-3 cells by CTL clone Y-1, and K-3,1,4 cells (sites I-, II-, III-, IV-) were selected from K-3,1 cells by CTL clone Y-4. From K-4 cells, K-4,1 cells (sites I-, II-, III-, IV-) and K-4,3 cells (sites I+, II-, III-, IV-) were selected by CTL clone Y-1 and Y-3, respectively. The antigenic site loss variant cell lines K-1, K-1,4, K-3,1 K-3,1,4, K-4,1, and K-4,3 synthesized SV40 T Ag molecules of 75, 75, 78, 78, 81, and 88 kDa, respectively. Expression of wild-type SV40 T Ag in the antigenic site loss variants by infection with SV40 or transfection with cloned SV40 DNA restored the CTL recognition sites on the variant cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

脱水素研究进展

脱水素(dehydrin)是植物体内的一种LEA蛋白,能够在植物胚胎发育后期以及逆境下大量表达,广泛存在于植物界。它是具有高度热稳定性的亲水性蛋白,有三类非常保守的区域,即K,Y和S片段。依据这三类片段的组成情况,可将脱水素分为5个基本类别。脱水素可通过多种转运方式定位于植物细胞的不同部位,以行使其功能。其基因的表达存在依赖ABA和不依赖ABA两种途径,并且受到多种环境因素的影响,能稳定细胞膜和许多大分子的结构以避免脱水对细胞造成的伤害。近年来,脱水素的结构和组成、在细胞中的定位及转运、基因的表达与调控、功能与作用机理等方面的研究已取得了很大的进展。     

Temporal accumulation and ultrastructural localization of dehydrins in Zea mays

Immunolocalization using polyclonal antibodies raised against a conserved dehydrin amino acid sequence was used to establish the temporal and spatial patterns of dehydrin accumulation in embryo tissue of Zea mays L. (var. Ohio 43) kernels imbibed in the presence of abscisic acid. The temporal pattern of accumulation indicated an increase in dehydrins over time (particularly between 15 and 30 h) and with maximum levels detected 48 h after the onset of imbibition. Dehydrins were first evident, and also the most concentrated, in the cytosol throughout the accumulation period suggesting that the primary function of dehydrins involves the cytosol and the structures contained therein. Only after an accumulation of dehydrins in the cytosol was there an increase in the abundance of nuclear dehydrins. In addition, dehydrins were also observed in association with the proteinaceous matrix of protein bodies and membranes of protein and lipid bodies; these findings have not been reported previously. The observed localization at a number of sites indicates that the specific biochemical roles of dehydrins are likely to be diverse.     

Intrinsically unstructured proteins and their functions

Many gene sequences in eukaryotic genomes encode entire proteins or large segments of proteins that lack a well-structured three-dimensional fold. Disordered regions can be highly conserved between species in both composition and sequence and, contrary to the traditional view that protein function equates with a stable three-dimensional structure, disordered regions are often functional, in ways that we are only beginning to discover. Many disordered segments fold on binding to their biological targets (coupled folding and binding), whereas others constitute flexible linkers that have a role in the assembly of macromolecular arrays.     

Expression of KS-type dehydrins is primarily regulated by factors related to organ type and leaf developmental stage during vegetative growth

The expression of a gene, designated as DHN10, was analyzed at the protein level in two Solanum species. The DHN10 protein displays some consensus amino acid sequences of dehydrins, termed K- and S-segments. Unlike most dehydrins, both segments occur only in single copies in the DHN10 sequence and the S-segment is at a C-terminal position. Database searches revealed that KS-type dehydrins constitute a specific subclass distributed in dicotyledons and monocotyledons. In Solanum tuberosum L. plants, a high DHN10 abundance was observed under control conditions, particularly in flowers, stems, tubers and young developing leaves. In other Solanaceae and in barley (Hordeum vulgare L.), the amount of DHN10 was much more elevated in young leaves than in old leaves. DHN10 abundance was investigated in two Solanum species subjected to low temperature or to drought. Under stress conditions, we observed substantially higher protein levels only in mature expanded leaves. These findings clearly indicate that KS-type dehydrins are present at a high level in the absence of stress during vegetative growth and that their expression is primarily regulated by factors related to organ type and to leaf development stage. A potential role for the DHN10 dehydrin during plant development and in tolerance to environmental stress is discussed.Abbreviations DHN10 Dehydrin protein of 10 kDa - His Histidine - KS-type dehydrin Dehydrin containing a single K-segment followed by a single S-segment - LEA Late embryogenesis abundant - NTS Nuclear targeting signal     

A large disordered region confers a wide spanning volume to vertebrate Suppressor of Fused as shown in a trans-species solution study

Hedgehog (Hh) pathway inhibition by the conserved protein Suppressor of Fused (SuFu) is crucial to vertebrate development. By constrast, SuFu loss-of-function mutant has little effect in drosophila.Previous publications showed that the crystal structures of human and drosophila SuFu consist of two ordered domains that are capable of breathing motions upon ligand binding. However, the crystal structure of human SuFu does not give information about twenty N-terminal residues (IDR1) and an eighty-residue-long region predicted as disordered (IDR2) in the C-terminus, whose function is important for the pathway repression. These two intrinsically disordered regions (IDRs) are species-dependent.To obtain information about the IDR regions, we studied full-length SuFu’s structure in solution, both with circular dichroism and small angle X-ray scattering, comparing drosophila, zebrafish and human species, to better understand this considerable difference. Our studies show that, in spite of similar crystal structures restricted to ordered domains, drosophila and vertebrate SuFu have very different structures in solution. The IDR2 of vertebrates spans a large area, thus enabling it to reach for partners and be accessible for post-translational modifications. Furthermore, we show that the IDR2 region is highly conserved within phyla but varies in length and sequence, with insects having a shorter disordered region while that of vertebrates is broad and mobile. This major variation may explain the different phenotypes observed upon SuFu removal.     

Canonical structures for the hypervariable regions of T cell alphabeta receptors

T cell alphabeta receptors have binding sites for peptide-MHC complexes formed by six hypervariable regions. Analysis of the six atomic structures known for Valpha and for Vbeta domains shows that their first and second hypervariable regions have one of three or four different main-chain conformations (canonical structures). Six of these canonical structures have the same conformation in complexes with peptide-MHC complexes, the free receptor and/or in an isolated V domain. Thus, for at least the first and second hypervariable regions in the currently known structures, the conformation of the canonical structures is well defined in the free state and is conserved on formation of complexes with peptide-MHC.We identified the key residues that are mainly responsible for the conformation of each canonical structure. The first and second hypervariable regions of Valpha and Vbeta domains are encoded by the germline V segments. Humans have 37 functional Valpha segments and 47 Vbeta segments, and mice have 20 Vbeta segments. Inspection of the size of their hypervariable regions, and of sites that contain key residues, indicates that close to 70 % of Valpha segments and 90 % of Vbeta segments have hypervariable regions with a conformation of one of the known canonical structures. The alpha and beta V gene segments in both humans and mice have only a few combinations of different canonical structure in their first and second hypervariable regions. In human Vbeta domains, the number of different sequences with these canonical structure combinations is larger than in mice, whilst for Valpha domains it is probably smaller.     

Plant dehydrins and stress tolerance: Versatile proteins for complex mechanisms

Dehydrins (DHNs), or group 2 LEA (Late Embryogenesis Abundant) proteins, play a fundamental role in plant response and adaptation to abiotic stresses. They accumulate typically in maturing seeds or are induced in vegetative tissues following salinity, dehydration, cold and freezing stress. The generally accepted classification of dehydrins is based on their structural features, such as the presence of conserved sequences, designated as Y, S and K segments. The K segment representing a highly conserved 15 amino acid motif forming amphiphilic a-helix is especially important since it has been found in all dehydrins. Since more than 20 y, they are thought to play an important protective role during cellular dehydration but their precise function remains unclear. This review outlines the current status of the progress made toward the structural, physico-chemical and functional characterization of plant dehydrins and how these features could be exploited in improving stress tolerance in plants.Key words: abiotic stress, dehydration stress, drought, cold acclimation, freezing tolerance, LEA proteins, dehydrins