A late embryogenesis abundant (LEA) protein gene, HVA7, from barley (Hordeum vulgare L.) was introduced into rice suspension cells using the Biolistic-mediated transformation method, and a large number of independent transgenic rice (Oryza sativa L.) plants were generated. Expression of the barley HVA 7 gene regulated by the rice actin 1 gene promoter led to high-level, constitutive accumulation of the HVAl protein in both leaves and roots of transgenic rice plants. Second-generation transgenic rice plants showed significantly increased tolerance to water deficit and salinity. Transgenic rice plants maintained higher growth rates than nontransformed control plants under stress conditions. The increased tolerance was also reflected by delayed development of damage symptoms caused by stress and by improved recovery upon the removal of stress conditions. We also found that the extent of increased stress tolerante correlated with the leve1 of the HVAl protein accumulated in the transgenic rice plants. Using a transgenic approach, this study provides direct evidence supporting the hypothesis that LEA proteins play an important role in the protection of plants under wateror salt-stress conditions. Thus, LEA genes hold considerable potentia1 for use as molecular tools for genetic crop improvement toward stress tolerance.
Calcium-dependent protein kinases (CDPKs) are specific to plants and some protists. Their activation by calcium makes them important switches for the transduction of intracellular calcium signals. Here, we identify the subcellular targeting potentials for nine CDPK isoforms from Arabidopsis, as determined by expression of green fluorescent protein (GFP) fusions in transgenic plants. Subcellular locations were determined by fluorescence microscopy in cells near the root tip. Isoforms AtCPK3-GFP and AtCPK4-GFP showed a nuclear and cytosolic distribution similar to that of free GFP. Membrane fractionation experiments confirmed that these isoforms were primarily soluble. A membrane association was observed for AtCPKs 1, 7, 8, 9, 16, 21, and 28, based on imaging and membrane fractionation experiments. This correlates with the presence of potential N-terminal acylation sites, consistent with acylation as an important factor in membrane association. All but one of the membrane-associated isoforms targeted exclusively to the plasma membrane. The exception was AtCPK1-GFP, which targeted to peroxisomes, as determined by covisualization with a peroxisome marker. Peroxisome targeting of AtCPK1-GFP was disrupted by a deletion of two potential N-terminal acylation sites. The observation of a peroxisome-located CDPK suggests a mechanism for calcium regulation of peroxisomal functions involved in oxidative stress and lipid metabolism.
To study transporters involved in regulating intracellular Ca 2؉ , we isolated a full-length cDNA encoding a Ca 2؉ -ATPase from a model plant, Arabidopsis, and named it ACA2 (Arabidopsis Ca 2؉ -ATPase, isoform 2). ACA2p is most similar to a "plasma membrane-type"
Plants can grow in soils containing highly variable amounts of mineral nutrients, like Ca2+ and Mn2+, though the mechanisms of adaptation are poorly understood. Here, we report the first genetic study to determine in vivo functions of a Ca2+ pump in plants. Homozygous mutants of Arabidopsis harboring a T-DNA disruption in ECA1 showed a 4-fold reduction in endoplasmic reticulum-type calcium pump activity. Surprisingly, the phenotype of mutant plants was indistinguishable from wild type when grown on standard nutrient medium containing 1.5 mmCa2+ and 50 μm Mn2+. However, mutants grew poorly on medium with low Ca2+ (0.2 mm) or high Mn2+ (0.5 mm). On high Mn2+, the mutants failed to elongate their root hairs, suggesting impairment in tip growth processes. Expression of the wild-type gene (CAMV35S::ECA1) reversed these conditional phenotypes. The activity of ECA1 was examined by expression in a yeast (Saccharomyces cerevisiae) mutant, K616, which harbors a deletion of its endogenous calcium pumps. In vitro assays demonstrated that Ca2+, Mn2+, and Zn2+stimulated formation of a phosphoenzyme intermediate, consistent with the translocation of these ions by the pump. ECA1 provided increased tolerance of yeast mutant to toxic levels of Mn2+ (1 mm) and Zn2+(3 mm), consistent with removal of these ions from the cytoplasm. These results show that despite the potential redundancy of multiple Ca2+ pumps and Ca2+/H+ antiporters in Arabidopsis, pumping of Ca2+ and Mn2+ by ECA1 into the endoplasmic reticulum is required to support plant growth under conditions of Ca2+ deficiency or Mn2+ toxicity.
A unique subfamily of calmodulin-dependent Ca 2؉ -ATPases was recently identified in plants. In contrast to the most closely related pumps in animals, plasma membrane-type Ca 2؉ -ATPases, members of this new subfamily are distinguished by a calmodulin-regulated autoinhibitor located at the N-terminal instead of a C-terminal end. In addition, at least some isoforms appear to reside in non-plasma membrane locations. To begin delineating their functions, we investigated the subcellular localization of isoform ACA2p (Arabidopsis Ca 2؉ -ATPase, isoform 2 protein) in Arabidopsis. Here we provide evidence that ACA2p resides in the endoplasmic reticulum (ER). In buoyant density sucrose gradients performed with and without Mg 2؉ , ACA2p cofractionated with an ER membrane marker and a typical "ER-type" Ca 2؉ -ATPase, ACA3p/ECA1p. To visualize its subcellular localization, ACA2p was tagged with a green fluorescence protein at its C terminus (ACA2-GFPp) and expressed in transgenic Arabidopsis. We collected fluorescence images from live root cells using confocal and computational optical-sectioning microscopy. ACA2-GFPp appeared as a fluorescent reticulum, consistent with an ER location. In addition, we observed strong fluorescence around the nuclei of mature epidermal cells, which is consistent with the hypothesis that ACA2p may also function in the nuclear envelope. An ER location makes ACA2p distinct from all other calmodulin-regulated pumps identified in plants or animals. Ca2ϩ is thought to function as an important second messenger in all eukaryotes (Bootman and Berridge, 1995;Clapham, 1995). In addition, Ca 2ϩ is required for the stability and activity of many proteins and appears to play a critical role in protein processing in the secretory pathway (Rudolph et al., 1989; Gill et al., 1996) Type IIA and IIB pumps include the "ER-type" and the "PM-type" Ca 2ϩ pumps, respectively, first characterized in animal cells. Previously, homologs of ER-or PM-type pumps were distinguished by three criteria: (a) localization to either the ER or PM, respectively, (b) differential sensitivity to inhibitors (e.g. ER-type inhibition by cyclopiazonic acid and thapsigargin), and (c) direct activation of PM-type pumps by calmodulin. However, not all plant homologs conform to these criteria (Bush, 1995;Evans and Williams, 1998).In plants several genes encoding type IIA pumps (ERtype homologs) have been cloned, including LCA1 from tomato (Wimmers et al., 1992), OsCA from rice (Chen et al., 1997), and ACA3/ECA1 (Arabidopsis Ca 2ϩ -ATPase, isoform 3/ER-Ca 2ϩ -ATPase isoform 1) from Arabidopsis (Liang et al., 1997). Consistent with the criteria for a typical ER-type pump, ACA3p (ACA isoform 3 protein) appears to reside in the ER (Liang et al., 1997). However, non-ER locations have been suggested for other isoforms. For example, Ferrol and Bennett (1996) obtained evidence for tonoplast and PM isoforms from membrane fractionation and immunodetection of pumps cross-reacting with an anti-LCA1 antibody.Three plant genes encoding type IIB pumps (PM...
Abscisic acid (ABA) inhibits the gibberellic acid induced synthesis of α-amylase in barley aleurone layers, yet ABA itself induces more than a dozen polypeptides (Lin & Ho, Plant Physiol 82: 289-297, 1986). As part of our effort to elucidate the molecular action of ABA in barley aleurone layers, we have isolated and characterized an ABA-induced cDNA clone, pHV A1. This cDNA clone hybridizes to an RNA species of approximately 1.1 kb from ABA-treated barley aleurone layers. The level of this mRNA is tripled within 40 minutes after ABA treatment, reaches a peak at 8-12 h, and is present up to 48 h. The induction of this mRNA responds to concentrations of ABA as low as 10(-9) M, but higher ABA concentrations induce higher expression of this mRNA. The products of hybrid-select translation and in vitro transcription/translation with pHV A1 comigrate on SDS gel as a 27 kDa polypeptide. However, the sequence of pHV A1 indicates that it has an open reading frame encoding a 22 kDa protein. This size discrepancy is probably due to the high content of the basic amino acid, lysine. This notion has been confirmed by two-dimensional gel electrophoresis showing that this polypeptide is one of the most basic proteins in ABA-treated barley aleurone layers. The deduced amino acid sequence of pHV A1 contains nine imperfect repeats 11 amino acids long which share homology with cotton Lea 7 protein (Baker, Steele & Dure, Plant Mol Biol, in press). The identity and function of the encoded product of pHV A1 is under investigation.
An mRNA species, HVA1, has been shown to be rapidly induced by abscisic acid (ABA) in barley aleurone layers (Hong, Uknes and Ho, Plant Mol Biol 11: 495-506, 1988). In the current work we have investigated the expression of HVA1 in other organs of barley plants. In developing seeds, HVA1 mRNA is not detected in starchy endosperm cells, yet it accumulates in aleurone layers and embryo starting 25 days after anthesis, and its level remains high in these organs in dry seeds. Although the levels of HVA1 mRNA are equivalent in the dry embryos of dormant and nondormant barley seeds, upon imbibition HVA1 mRNA declines much slower in the dormant than in the nondormant embryos. The HVA1 mRNA and protein levels are highly induced by ABA treatment in all organs of 3-day-old seedlings. However, the induction in the leaf of 7-day-old seedlings is less than one tenth the level observed in the leaf of 3-day-old seedlings. In the leaf, HVA1 mRNA and protein are induced mainly at the base. These observations indicate that the expression of HVA1 is under developmental regulation. Besides the HVA1 protein, a smaller protein (p20) of approximately 20 kDa cross-reacting with anti-HVA1 polyclonal antibodies, is induced by ABA in barley seedlings but not in seeds. HVA1 mRNA is induced by drought, NaCl, cold or heat treatment. Similar to ABA treatment, the drought induction of HVA1 occurs in all the tissues of 3-day-old seedlings, but the induction decreases dramatically in the leaf of 7-day-old plants. The significance of organ-specific, developmentally regulated, and stress-induced expression of HVA1 is discussed.
More than 11 different P-type H+-ATPases have been identified in Arabidopsis by DNA cloning. The subcellular localization for individual members of this proton pump family has not been previously determined. We show by membrane fractionation and immunocytology that a subfamily of immunologically related P-type H+-ATPases, including isoforms AHAZ and AHA3, are primarily localized to the plasma membrane. To verify that AHAZ and AHA3 are both targeted to the plasma membrane, we added epitope tags to their C-terminal ends and expressed them in transgenic plants. Both tagged isoforms localized to the plasma membrane, as indicated by aqueous two-phase partitioning and sucrose density gradients. In contrast, a truncated AHAZ (residues 1-193) did not, indicating that the first two transmembrane domains alone are not sufficient for plasma membrane localization. Two epitope tags were evaluated: c-myc, a short, 11 -amino acid sequence, and /3-glucuronidase (CUS), a 68-kD protein. The c-myc tag is recommended for its sensitivity and specific immunodetection. CUS worked well as an epitope tag when transgenes were expressed at relatively high levels (e.g. with AHA2-CUS944); however, evidence suggests that GUS activity may be inhibited when a CUS domain is tethered to an H+-ATPase complex. Nevertheless, the apparent ability to localize a CUS protein to the plasma membrane indicates that a P-type H+-ATPase can be used as a delivery vehicle to target large, soluble proteins to the plasma membrane.In fungi and higher plants, protons pumped out of the cell generate a pH gradient and electrical potential across the plasma membrane (Sussman et al., 1994;Michelet and Boutry, 1995). The proton gradient provides the driving force for nutrient uptake through proton-coupled co-transport systems. In addition, the electrical potential plays a role in regulating voltage-gated ion channels. This plasma membrane proton gradient is generated primarily by Ptype H+-ATPases, as demonstrated by biochemical and physiological studies (Briskin, 1990). Thus, P-type H+-
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