The ERD14 protein (early response to dehydration) is a member of the dehydrin family of proteins which accumulate in response to dehydration-related environmental stresses. Here we show the Arabidopsis dehydrin, ERD14, possesses ion binding properties. ERD14 is an in vitro substrate of casein kinase II; the phosphorylation resulting both in a shift in apparent molecular mass on SDS-PAGE gels and increased calcium binding activity. The phosphorylated protein bound significantly more calcium than the nonphosphorylated protein, with a dissociation constant of 120 M and 2.86 mol of calcium bound per mol of protein. ERD14 is phosphorylated by extracts of cold-treated tissues, suggesting that the phosphorylation status of this protein might be modulated by cold-regulated kinases or phosphatases. Calcium binding properties of ERD14 purified from Arabidopsis extracts were comparable with phosphorylated Escherichia coli-expressed ERD14. Approximately 2 mol of phosphate were incorporated per mol of ERD14, indicating a minimum of two phosphorylation sites. Western blot analyses confirmed that threonine and serine are possible phosphorylation sites on ERD14. Utilizing matrix assisted laser desorption ionization-time of flight/ mass spectrometry we identified five phosphorylated peptides that were present in both in vivo and in vitro phosphorylated ERD14. Our results suggest that the polyserine (S) domain is most likely the site of phosphorylation in ERD14 responsible for the activation of calcium binding.
A vacuole membrane-associated calcium-binding protein with an apparent mass of 45 kD was purified from celery (Apium graveolens). This protein, VCaB45, is enriched in highly vacuolate tissues and is located within the lumen of vacuoles. Antigenically related proteins are present in many dicotyledonous plants. VCaB45 contains significant amino acid identity with the dehydrin family signature motif, is antigenically related to dehydrins, and has a variety of biochemical properties similar to dehydrins. VCaB45 migrates anomalously in sodium dodecyl sulfate-polyacrylamide gel electrophoresis having an apparent molecular mass of 45 kD. The true mass as determined by matrix-assisted laser-desorption ionization time of flight was 16.45 kD. VCaB45 has two characteristic dissociation constants for calcium of 0.22 Ϯ 0.142 mm and 0.64 Ϯ 0.08 mm, and has an estimated 24.7 Ϯ 11.7 calcium-binding sites per protein. The calcium-binding properties of VCaB45 are modulated by phosphorylation; the phosphorylated protein binds up to 100-fold more calcium than the dephosphorylated protein. VCaB45 is an "in vitro" substrate of casein kinase II (a ubiquitous eukaryotic kinase), the phosphorylation resulting in a partial activation of calcium-binding activity. The vacuole localization, calcium binding, and phosphorylation of VCaB45 suggest potential functions.The vacuole is a reservoir for calcium (Machlon, 1984) and consequently plays an important role in calcium homeostasis (Miller et al., 1990;Allen and Sanders, 1995;Sanders et al., 1999). Regulation of vacuole calcium levels is complex involving a variety of calcium channels and pumps (Sanders et al., 1999;Sze et al., 2000). Sustained elevated levels of cytosolic calcium can be toxic (Hepler and Wayne, 1985), so under normal conditions, cytosolic calcium levels increase only transiently. Proteinaceous calcium buffers may serve as homeostats to attenuate the signal transduction system. Well-characterized protein calcium buffers include calreticulin and calsequestrin (Ostwald and MacLennon, 1974;Campbell et al., 1983b). Homologs of calsequestrin (Krause et al., 1989;Xing et al., 1994), calreticulin (Chen et al., 1994;Napier et al., 1995;Nelson et al., 1997), and calnexin (Li et al., 1998) have been identified in plants. These calcium-binding proteins can bind on the order of 20 to 50 calcium ions with both high-(1-3 sites per protein) and low-(20-50 sites per protein) affinity sites. The levels of calcium binding proteins may have a significant impact on signaling processes and may regulate second messenger transmission (Camacho and Lechleiter, 1995;Mery et al., 1996;Coppolino et al., 1997). In an alternative role, calcium-dependent interactions of calnexin and calreticulin have been characterized with a variety of proteins (Nigam et al., 1994;Peterson et al., 1995) and both are implicated in the promotion of correct protein folding (Hebert et al., 1996). These latter activities clearly suggest a molecular chaperone role. Recently, a high-capacity, low-affinity calcium-binding protei...
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, calciumbinding 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.
To gain insight into the molecular basis contributing to overwintering hardiness, a comprehensive proteomic analysis comparing crowns of octoploid strawberry (Fragaria 3 ananassa) cultivars that differ in freezing tolerance was conducted. Four cultivars were examined for freeze tolerance and the most cold-tolerant cultivar ('Jonsok') and least-tolerant cultivar ('Frida') were compared with a goal to reveal how freezing tolerance is achieved in this distinctive overwintering structure and to identify potential cold-tolerance-associated biomarkers. Supported by univariate and multivariate analysis, a total of 63 spots from twodimensional electrophoresis analysis and 135 proteins from label-free quantitative proteomics were identified as significantly differentially expressed in crown tissue from the two strawberry cultivars exposed to 0-, 2-, and 42-d cold treatment. Proteins identified as cold-tolerance-associated included molecular chaperones, antioxidants/detoxifying enzymes, metabolic enzymes, pathogenesis-related proteins, and flavonoid pathway proteins. A number of proteins were newly identified as associated with cold tolerance. Distinctive mechanisms for cold tolerance were characterized for two cultivars. In particular, the 'Frida' cold response emphasized proteins specific to flavonoid biosynthesis, while the more freezing-tolerant 'Jonsok' had a more comprehensive suite of known stress-responsive proteins including those involved in antioxidation, detoxification, and disease resistance. The molecular basis for 'Jonsok'-enhanced cold tolerance can be explained by the constitutive level of a number of proteins that provide a physiological stress-tolerant poise. Strawberry (Fragaria 3 ananassa) cultivation predominates in regions with mild winters. In colder climates, overwintering hardiness is an essential trait for strawberry cultivation. Freezing injury of strawberry plants is one of the greatest factors in reducing crop yield and quality in temperate regions. Winter damage in Norway, for example, on average causes losses of 20%. Thus, production of cultivars with improved freezing hardiness is one of Norway's major objectives for their strawberry breeding programs. Improvement of cold hardiness is desirable for securing economic sustainability of the existing crops, and for expanding the growing regions of temperate fruit crops. Because strawberry is a representative species for the Rosaceae crops (e
The use of artificial freezing tests, identification of biomarkers linked to or directly involved in the low-temperature tolerance processes, could prove useful in applied strawberry breeding. This study was conducted to identify genotypes of diploid strawberry that differ in their tolerance to low-temperature stress and to investigate whether a set of candidate proteins and metabolites correlate with the level of tolerance. 17 Fragaria vesca, 2 F. nilgerrensis, 2 F. nubicola, and 1 F. pentaphylla genotypes were evaluated for low-temperature tolerance. Estimates of temperatures where 50 % of the plants survived (LT₅₀) ranged from -4.7 to -12.0 °C between the genotypes. Among the F. vesca genotypes, the LT₅₀ varied from -7.7 °C to -12.0 °C. Among the most tolerant were three F. vesca ssp. bracteata genotypes (FDP821, NCGR424, and NCGR502), while a F. vesca ssp. californica genotype (FDP817) was the least tolerant (LT₅₀) -7.7 °C). Alcohol dehydrogenase (ADH), total dehydrin expression, and content of central metabolism constituents were assayed in select plants acclimated at 2 °C. The LT₅₀ estimates and the expression of ADH and total dehydrins were highly correlated (r(adh) = -0.87, r (dehyd) = -0.82). Compounds related to the citric acid cycle were quantified in the leaves during acclimation. While several sugars and acids were significantly correlated to the LT₅₀ estimates early in the acclimation period, only galactinol proved to be a good LT₅₀ predictor after 28 days of acclimation (r(galact) = 0.79). It is concluded that ADH, dehydrins, and galactinol show great potential to serve as biomarkers for cold tolerance in diploid strawberry.
A Saccharomyces cerevisae microarray expression study indicated that an ORF, YER044C, now designated ERG28, was strongly coregulated with ergosterol biosynthesis. Disruption of the ERG28 gene results in slow growth and accumulation of sterol intermediates similar to those observed in erg26 and erg27 null strains, suggesting that the Erg28p may interact with Erg26p and/or Erg27p. In this study, a peptide from human hemagglutinin protein (HA) epitope tag was added to ERG26 and ERG27 genes, and a Myc tag was added to the ERG28 gene to detect interactions between Erg28p and Erg26p/Erg27p. Differential centrifugation showed that Erg26p, Erg27p, and Erg28p are all membrane-associated proteins. Green fluorescent protein-fusion protein localization studies showed that Erg26p, Erg27p, and Erg28p are all located in the endoplasmic reticulum. Solubilized membrane protein coimmunoprecipitation studies using rabbit anti-Erg25p indicated that Erg25p coimmunoprecipitates with both Erg27p and Erg28p. Erg28p was also shown to reciprocally coimmunoprecipitate with Erg27p. However, no coimmunoprecipitation was observed with Erg26p, most likely because of the poor solubilization of this protein. Sucrose gradient ultracentrifugation studies suggested that Erg25p/Erg26p/Erg27p/Erg28p, along with other proteins in sterol biosynthesis, might form a complex between 66 and 200 kDa. Using an anti-HA column with Erg27p-HA and Erg26p-HA as target proteins, a complex containing Erg25p/Erg26p/Erg27p/Erg28p was identified. Thus, we suggest that Erg28p works as a transmembrane scaffold to tether Erg27p and possibly other C-4 demethylation proteins (Erg25p, Erg26p), forming a demethylation complex in the endoplasmic reticulum.
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