Involvement of TAAAG elements suggests a role for Dof transcription factors in guard cell-specific gene expression.

Due to their unique structure and function, guard cells have attracted much attention at the physiological level. Very little, however, is known about the molecular events involved in the determination and maintenance of guard cell specificity. The KST1 gene encodes a K+ influx channel of guard cells in potato, and was therefore chosen as a model to study regulation of guard cell-specific gene expression. Transgenic potato plants carrying a fusion between the KST1 promoter and the E. coli uidA (beta-glucuronidase) reporter gene revealed promoter activity in guard cells and in flowers. A detailed dissection of the KST1 promoter led to the discovery of two independent small TATA box-proximal regulatory units, each of which was sufficient to direct guard cell-specific gene transcription. Both fragments contain the sequence motif, 5'-TAAAG-3', which is related to known target sites for a novel class of zinc finger transcription factors, called Dof proteins. Block mutagenesis of these Dof target sites in the context of different promoter constructs dramatically reduced guard cell promoter activity. A Dof gene, StDof1, was cloned and shown to be expressed in epidermal fragments highly enriched for guard cells. In gel retardation experiments, the StDof1 protein interacted in a sequence-specific manner with a KST1 promoter fragment containing the TAAAG motif. These results provide evidence that TAAAG elements are target sites for trans-acting Dof proteins controlling guard cell-specific gene expression. Our data will add to the design of tailor-made guard cell promoters as a further tool in molecular engineering of guard cell function and, hence, control of stomatal carbon dioxide (CO2) uptake and water loss in crop plants.

The K+ channel SKT1 is co-expressed with KST1 in potato guard cells--both channels can co-assemble via their conserved KT domains.

An appreciable number of potassium channels mediating K+ uptake have been identified in higher plants. Promoter-beta-glucuronidase reporter gene studies were used here to demonstrate that SKT1, encoding a potato K+ inwardly rectifying channel, is expressed in guard cells in addition to KST1 previously reported. However, whereas KST1 was found to be expressed in essentially all mature guard cells, SKT1 expression was almost exclusively restricted to guard cells of the abaxial leaf epidermis. This suggests that different types of K+ channel subunits contribute to channel formation in potato guard cells and therefore differential regulation of stomatal movements in the two leaf surfaces. The overlapping expression pattern of SKT1 and KST1 in abaxial guard cells indicates that K+in channels of different sub-families contribute to ionic currents in this cell type, thus explaining the different properties of channels expressed solely in heterologous systems and those endogenous to guard cells. Interaction studies had previously suggested that plant K+ inward rectifiers form clusters via their conserved C-terminal domain, KT/HA. K+ channels co-expressed in one cell type may therefore form heteromers, which increase functional variability of K+ currents, a phenomenon well described for animal voltage-gated K+ channels. Co-expression of KST1 and SKT1 in Xenopus oocytes resulted in currents with an intermediate sensitivity towards Cs+, suggesting the presence of heteromers, and a sensitivity towards external Ca2+, which reflected the property of the endogenous K+in current in guard cells. Modulation of KST1 currents in oocytes by co-expressing KST1 with a SKT1 pore-mutant, which by itself was not able to confer activating K+ currents, demonstrated the possibility that KST1 and SKT1 co-assemble to hetero-oligomers. Furthermore, various C-terminal deletions of the mutated SKT1 channel restored KST1 currents, showing that the C-terminal KT motif is essential for heteromeric channel formation.

Ion channels in plant signaling.

Plant ion channel activities are rapidly modulated in response to several environmental and endogenous stimuli such as light, pathogen attack and phytohormones. Electrophysiological as well as pharmacological studies provide strong evidence that ion channels are essential for the induction of specific cellular responses, implicating their tight linkage to signal transduction cascades. Ion channels propagate signals by modulating the membrane potential or by directly affecting cellular ion composition. In addition, they may also be effectors at the end of signaling cascades, as examplified by ion channels which determine the solute content of stomatal guard cells. Plant channels are themselves subject to regulation by a variety of cellular factors, including calcium, pH and cyclic nucleotides. In addition, they appear to be regulated by (de)-phosphorylation events as well as by direct interactions with cytoskeletal and other cellular proteins. This review summarizes current knowledge on the role of ion channels in plant signaling.

[Behavior therapy competence training--a specific intervention with beginning Alzheimer dementia]. / Das Verhaltenstherapeutische Kompetenztraining VKT--Eine spezifische Intervention für Patienten mit einer beginnenden Alzheimer-Demenz.

At the Psychiatric Department, Ludwig-Maximilians-Universität, Munich, a behavioral competency training (Verhaltenstherapeutisches Kompetenztraining) VKT is offered to patients with early stages of Alzheimer's disease (AD). The primary objects of VKT are, (a) patient support in coping with the diagnosis of AD, (b) mobilization of the present personal activity resources, and (c) minimization of depressive symptoms. The VKT consists of six therapy-modules: 1. behavior analysis, 2. psychoeducation, 3. stress management, 4. increase of pleasant activities, 5. enhancement of social competency, and 6. modification of depressive cognitive patterns. The VKT is derived from scientific findings that show the involvement of psycho-social factors in the genesis of AD. Inadequate coping-behavior, unescapable stress and resulting neurodegenerative effects, a low premorbid niveau of activity and the presence of premorbid depressive symptoms outline the necessity of psychotherapeutic treatment in AD patients.

Characterization of SKT1, an inwardly rectifying potassium channel from potato, by heterologous expression in insect cells.

A cDNA encoding a novel, inwardly rectifying K+ (K+in) channel protein, SKT1, was cloned from potato (Solanum tuberosum L.). SKT1 is related to members of the AKT family of K+in channels previously identified in Arabidopsis thaliana and potato. Skt1 mRNA is most strongly expressed in leaf epidermal fragments and in roots. In electrophysiological, whole-cell, patch-clamp measurements performed on baculovirus-infected insect (Spodoptera frugiperda) cells, SKT1 was identified as a K+in channel that activates with slow kinetics by hyperpolarizing voltage pulses to more negative potentials than -60 mV. The pharmacological inhibitor Cs+, when applied externally, inhibited SKT1-mediated K+in currents half-maximally with an inhibitor concentration (IC50) of 105 microM. An almost identical high Cs+ sensitivity (IC50 = 90 microM) was found for the potato guard-cell K+in channel KST1 after expression in insect cells. SKT1 currents were reversibly activated by a shift in external pH from 6.6 to 5.5, which indicates a physiological role for pH-dependent regulation of AKT-type K+in channels. Comparative studies revealed generally higher current amplitudes for KST1-expressing cells than for SKT1-expressing insect cells, which correlated with a higher targeting efficiency of the KST1 protein to the insect cell's plasma membrane, as demonstrated by fusions to green fluorescence protein.

Association of plant K+(in) channels is mediated by conserved C-termini and does not affect subunit assembly.

Inward rectifying potassium (K+(in)) channels play an important role in turgor regulation and ion uptake in higher plants. Here, we report a previously unrecognized feature of these proteins: K+(in) channel C-terminal polypeptides mediate channel protein interactions. Using a C-terminal fragment of potato guard cell K+(in) channel KST1 in a yeast two-hybrid screen two novel putative K+(in) channel proteins (SKT2 and SKT3) were identified by interaction of their C-termini which contained a conserved domain (K(HA)). Interactions were confirmed by Western blot-related assays utilizing K+(in) channel C-termini fused to green fluorescence protein. Although deletion of the K(HA)-domain abolished these interactions, K+(in) currents were still detectable by patch-clamp measurements of insect cells expressing these KST1 mutants, indicating that formation of a functional channel does not depend on this C-terminal domain.

New structure and function in plant K+ channels: KCO1, an outward rectifier with a steep Ca2+ dependency.

Potassium (K+) channels mediating important physiological functions are characterized by a common pore-forming (P) domain. We report the cloning and functional analysis of the first higher plant outward rectifying K+ channel (KCO1) from Arabidopsis thaliana. KCO1 belongs to a new class of 'two-pore' K+ channels recently described in human and yeast. KCO1 has four putative transmembrane segments and tandem calcium-binding EF-hand motifs. Heterologous expression of KCO1 in baculovirus-infected insect (Spodoptera frugiperda) cells resulted in outwardly rectifying, K+-selective currents elicited by depolarizing voltage pulses in whole-cell measurements. Activation of KCO1 was strongly dependent on the presence of nanomolar concentrations of cytosolic free Ca2+ [Ca2+]cyt. No K+ currents were detected when [Ca2+]cyt was adjusted to <150 nM. However, KCO1 strongly activated at increasing [Ca2+]cyt, with a saturating activity observed at approximately 300 nM [Ca2+]cyt. KCO1 single channel analysis on excised membrane patches, resulting in a single channel conductance of 64 pS, confirmed outward rectification as well as Ca2+-dependent activation. These data suggest a direct link between calcium-mediated signaling processes and K+ ion transport in higher plants. The identification of KCO1 as the first plant K+ outward channel opens a new field of structure-function studies in plant ion channels.

A peptide derived from a B cell epitope of Plasmodium falciparum rhoptry associated protein 2 specifically raises antibodies to rhoptry associated protein 1.

Mice immunised with a recombinant form of malarial antigen rhoptry-associated protein 2 (RAP2) produce antisera which recognise the native protein by indirect immunofluorescence and immunoblotting. Purified IgG components of the antisera partially inhibit erythrocyte invasion in vitro. This response was obtained only if the recombinant immunogen was presented to the mice in the presence of reducing and denaturing agents. An 8-mer epitope in RAP2 was recognised by antibodies in three of the antisera: E25TEFSKLY32. Immunisation with this octapeptide raised antibodies which strongly recognised reduced RAP2 in seven out of eight mice. However, this antisera either failed to recognise (five out of eight mice), or only weakly (three out of eight mice) recognised nonreduced RAP2. Examination of disulphide bonds in native RAP2 showed that the 4 cysteines of RAP2 form two disulphide bridges: Cys24-Cys88, and Cys277-Cys376. One of these (Cys24-Cys88) is adjacent to the octapeptide in the native protein. Surprisingly, seven out of eight mice immunised with the octapeptide also raised antibodies against native rhoptry-associated protein 1 (RAP1). The raising of antibodies which recognise RAP1 was induced specifically by the RAP2 octapeptide rather than the carrier protein used for immunisation. The epitope in RAP1 recognised by the antibodies was identified and shown not to be the result of any shared contiguous homologous sequence between the two proteins, but to shared homologous amino acids in critical positions within the epitope. Purified IgG components from the antisera of mice immunised with the octapeptide gave partial inhibition of erythrocyte invasion in vitro.

The gene for ribosomal protein S10 is present in mitochondria of pea and potato but absent from those of Arabidopsis and Oenothera.

A novel group II intron has been identified in the pea (Pisum sativum) mitochondrial genome. The gene harbouring this intron is identified as rps10 (encoding protein S10 of the small ribosomal subunit) by similarity to its known homologues in bacteria and in the mitochondrion of the liverwort Marchantia polymorpha. The rps10 gene is transcribed in pea, the intron is removed, and RNA editing in the rps10 reading frame increases similarity to its homologue in the M. polymorpha mitochondrion. Contrary to the situation in bacteria and Marchantia, rps10 is not part of a ribosomal-protein gene cluster in pea. It is flanked upstream by the genes trnF and trnP, encoding phenylalanine- and proline-accepting tRNAs, and downstream by cox1, encoding subunit 1 of the cytochrome-c-oxidase. Southern hybridization shows that sequences homologous to rps10 exist in potato mitochondria but not in mitochondria of Oenothera berteriana and Arabidopsis thaliana. The pea rps10 intron is homologous to introns in rrn26 and cox3 in the Marchantia mitochondrial genome, while the Marchantia rps10 gene lacks an intron.