Jeffrey F. Harper

Transcriptome Changes for Arabidopsis in Response to Salt, Osmotic, and Cold Stress

To identify genes of potential importance to cold, salt, and drought tolerance, global expression profiling was performed on Arabidopsis plants subjected to stress treatments of 4°C, 100 mm NaCl, or 200 mm mannitol, respectively. RNA samples were collected separately from leaves and roots after 3- and 27-h stress treatments. Profiling was conducted with a GeneChip microarray with probe sets for approximately 8,100 genes. Combined results from all three stresses identified 2,409 genes with a greater than 2-fold change over control. This suggests that about 30% of the transcriptome is sensitive to regulation by common stress conditions. The majority of changes were stimulus specific. At the 3-h time point, less than 5% (118 genes) of the changes were observed as shared by all three stress responses. By 27 h, the number of shared responses was reduced more than 10-fold (< 0.5%), consistent with a progression toward more stimulus-specific responses. Roots and leaves displayed very different changes. For example, less than 14% of the cold-specific changes were shared between root and leaves at both 3 and 27 h. The gene with the largest induction under all three stress treatments was At5g52310 (LTI/COR78), with induction levels in roots greater than 250-fold for cold, 40-fold for mannitol, and 57-fold for NaCl. A stress response was observed for 306 (68%) of the known circadian controlled genes, supporting the hypothesis that an important function of the circadian clock is to “anticipate” predictable stresses such as cold nights. Although these results identify hundreds of potentially important transcriptome changes, the biochemical functions of many stress-regulated genes remain unknown.

Calcium at the crossroads of signaling

### Calcium Signals: A Central Paradigm in Stimulus–Response Coupling Cells must respond to an array of environmental and developmental cues. The signaling networks that have evolved to generate appropriate cellular responses are varied and are normally composed of elements that include a

Communicating with Calcium

### Calcium as a Ubiquitous Signal in Plants All living cells use a network of signal transduction pathways to conduct developmental programs, obtain nutrients, control their metabolism, and cope with their environment. A major challenge for cell biologists is to understand the “language” of

P-Type ATPase Heavy Metal Transporters with Roles in Essential Zinc Homeostasis in Arabidopsis

Arabidopsis thaliana has eight genes encoding members of the type 1B heavy metal–transporting subfamily of the P-type ATPases. Three of these transporters, HMA2, HMA3, and HMA4, are closely related to each other and are most similar in sequence to the divalent heavy metal cation transporters of prokaryotes. To determine the function of these transporters in metal homeostasis, we have identified and characterized mutants affected in each. Whereas the individual mutants exhibited no apparent phenotype, hma2 hma4 double mutants had a nutritional deficiency phenotype that could be compensated for by increasing the level of Zn, but not Cu or Co, in the growth medium. Levels of Zn, but not other essential elements, in the shoot tissues of a hma2 hma4 double mutant and, to a lesser extent, of a hma4 single mutant were decreased compared with the wild type. Together, these observations indicate a primary role for HMA2 and HMA4 in essential Zn homeostasis. HMA2promoter- and HMA4promoter-reporter gene constructs provide evidence that HMA2 and HMA4 expression is predominantly in the vascular tissues of roots, stems, and leaves. In addition, expression of the genes in developing anthers was confirmed by RT-PCR and was consistent with a male-sterile phenotype in the double mutant. HMA2 appears to be localized to the plasma membrane, as indicated by protein gel blot analysis of membrane fractions using isoform-specific antibodies and by the visualization of an HMA2-green fluorescent protein fusion by confocal microscopy. These observations are consistent with a role for HMA2 and HMA4 in Zn translocation. hma2 and hma4 mutations both conferred increased sensitivity to Cd in a phytochelatin-deficient mutant background, suggesting that they may also influence Cd detoxification.

CDPKs – a kinase for every Ca2+ signal?

Numerous stimuli can alter the Ca2+concentration in the cytoplasm, a factor common to many physiological responses in plant and animal cells. Calcium-binding proteins decode information contained in the temporal and spatial patterns of these Ca2+ signals and bring about changes in metabolism and gene expression. In addition to calmodulin, a calcium-binding protein found in all eukaryotes, plants contain a large family of calcium-binding regulatory protein kinases. Evidence is accumulating that these protein kinases participate in numerous aspects of plant growth and development.

Genomic scale profiling of nutrient and trace elements in Arabidopsis thaliana

Understanding the functional connections between genes, proteins, metabolites and mineral ions is one of biologys greatest challenges in the postgenomic era. We describe here the use of mineral nutrient and trace element profiling as a tool to determine the biological significance of connections between a plants genome and its elemental profile. Using inductively coupled plasma spectroscopy, we quantified 18 elements, including essential macro- and micronutrients and various nonessential elements, in shoots of 6,000 mutagenized M2 Arabidopsis thaliana plants. We isolated 51 mutants with altered elemental profiles. One mutant contains a deletion in FRD3, a gene known to control iron-deficiency responses in A. thaliana. Based on the frequency of elemental profile mutations, we estimate 2–4% of the A. thaliana genome is involved in regulating the plants nutrient and trace element content. These results demonstrate the utility of elemental profiling as a useful functional genomics tool.

A novel chloride channel in Vicia faba guard cell vacuoles activated by the serine/threonine kinase, CDPK.

Calcium‐Dependent Protein Kinases (CDPKs) in higher plants contain a C‐terminal calmodulin‐like regulatory domain. Little is known regarding physiological CDPK targets. Both kinase activity and multiple Ca2+‐dependent signaling pathways have been implicated in the control of stomatal guard cell movements. To determine whether CDPK or other protein kinases could have a role in guard cell signaling, purified and recombinant kinases were applied to Vicia faba guard cell vacuoles during patch‐clamp experiments. CDPK activated novel vacuolar chloride (VCL) and malate conductances in guard cells. Activation was dependent on both Ca2+ and ATP. Furthermore, VCL activation occurred in the absence of Ca2+ using a Ca2+‐independent, constitutively active, CDPK* mutant. Protein kinase A showed weaker activation (22% as compared with CDPK). Current reversals in whole vacuole recordings shifted with the Nernst potential for Cl‐and vanished in glutamate. Single channel recordings showed a CDPK‐activated 34 +/− 5 pS Cl‐ channel. VCL channels were activated at physiological potentials enabling Cl‐ uptake into vacuoles. VCL channels may provide a previously unidentified, but necessary, pathway for anion uptake into vacuoles required for stomatal opening. CDPK‐activated VCL currents were also observed in red beet vacuoles suggesting that these channels may provide a more general mechanism for kinase‐dependent anion uptake.

A novel calmodulin-regulated Ca2+-ATPase (ACA2) from Arabidopsis with an N-terminal autoinhibitory domain

To study transporters involved in regulating intracellular Ca2+, we isolated a full-length cDNA encoding a Ca2+-ATPase from a model plant,Arabidopsis, and named it ACA2( A rabidopsis Ca2+-ATPase, isoform2). ACA2p is most similar to a “plasma membrane-type” Ca2+-ATPase, but is smaller (110 kDa), contains a unique N-terminal domain, and is missing a long C-terminal calmodulin-binding regulatory domain. In addition, ACA2p is localized to an endomembrane system and not the plasma membrane, as shown by aqueous-two phase fractionation of microsomal membranes. ACA2p was expressed in yeast as both a full-length protein (ACA2-1p) and an N-terminal truncation mutant (ACA2-2p; Δ residues 2–80). Only the truncation mutant restored the growth on Ca2+-depleted medium of a yeast mutant defective in both endogenous Ca2+ pumps, PMR1 and PMC1. Although basal Ca2+-ATPase activity of the full-length protein was low, it was stimulated 5-fold by calmodulin (50% activation around 30 nm). In contrast, the truncated pump was fully active and insensitive to calmodulin. A calmodulin-binding sequence was identified within the first 36 residues of the N-terminal domain, as shown by calmodulin gel overlays on fusion proteins. Thus, ACA2 encodes a novel calmodulin-regulated Ca2+-ATPase distinguished by a unique N-terminal regulatory domain and a non-plasma membrane localization.

14‐3‐3 proteins activate a plant calcium‐dependent protein kinase (CDPK)

Plants and protozoa contain a unique family of calcium‐dependent protein kinases (CDPKs) which are defined by the presence of a carboxyl‐terminal calmodulin‐like regulatory domain. We present biochemical evidence indicating that at least one member of this kinase family can be stimulated by 14‐3‐3 proteins. Isoform CPK‐1 from the model plant Arabidopsis thaliana was expressed as a fusion protein in E. coli and purified. The calcium‐dependent activity of this recombinant CPK‐1 was shown to be stimulated almost twofold by three different 14‐3‐3 isoforms with 50% activation around 200 nM. 14‐3‐3 proteins bound to the purified CPK‐1, as shown by binding assays in which either the 14‐3‐3 or CPK‐1 were immobilized on a matrix. Both the 14‐3‐3 binding and activation of CPK‐1 were specifically disrupted by a known 14‐3‐3 binding peptide LSQRQRSTpSTPNVHMV (IC50=30 μM). These results raise the question of whether 14‐3‐3 can modulate the activity of CDPK signal transduction pathways in plants.

The plasma membrane H+-ATPase gene family in Arabidopsis: genomic sequence of AHA10 which is expressed primarily in developing seeds

The plasma membrane H+-ATPases in Arabidopsis thaliana represent the largest family of cation translocating P-type ATPases identified in plants or animals. We report here seven new isoforms, which were identified by polymerase chain reaction (PCR) amplification of genomic DNA. Amplifications were performed with degenerate primers corresponding to two short conserved sequence motifs (“CSDK” and “GDGV”) found in most P-type ATPases. A comparison was made of three CSDK-side primers, which were used either as totally degenerate mixtures or rendered less degenerate by substitution with deoxyinosine or fluorodeoxyuridine. Amplified genomic fragments were cloned, partially sequenced and shown to correspond to Arabidopsis genes by Southern blot analysis with gene-specific probes. One newly identified isoform, AHA10, was isolated as a cosmid clone and sequenced. The 5′ and 3′ ends of the gene were determined by comparison with the AHA10 cDNA sequence. AHA10 is the most divergent isoform characterized in the Arabidopsis family. AHA10 appears to be expressed primarily in developing seeds, as indicated by Northern blot analysis of AHA10 mRNA and by the analysis of transgenic plants expressing a β-glucuronidase (GUS) reporter gene fused to an AHA10 promoter. Our results indicate that one function of this unusually large H+-ATPase gene family is to allow for expression of different isoforms in different cell types.