Involvement of HLS1 in sugar and auxin signaling in Arabidopsis leaves

Sugar regulates a variety of genes and controls plant growth and development similarly to phytohormones. As part of a screen for Arabidopsis mutants with defects in sugar-responsive gene expression, we identified a loss-of-function mutation in the HOOKLESS1 (HLS1) gene. HLS1 was originally identified to regulate apical hook formation of dark-grown seedlings (Lehman et al., 1996, Cell 85: 183-194). In hls1, sugar-induced gene expression in excised leaf petioles was more sensitive to exogenous sucrose than that in the wild type. Exogenous IAA partially repressed sugar-induced gene expression and concomitantly activated some auxin response genes such as AUR3 encoding GH3-like protein. The repression and the induction of gene expression by auxin were attenuated and enhanced, respectively, by the hls1 mutation. These results suggest that HLS1 plays a negative role in sugar and auxin signaling. Because AUR3 GH3-like protein conjugates free IAA to amino acids (Staswick et al., 2002, Plant Cell 14: 1405-1415; Staswick et al., 2005, Plant Cell 17: 616-627), enhanced expression of GH3-like genes would result in a decrease in the free IAA level. Indeed, hls1 leaves accumulated a reduced level of free IAA, suggesting that HLS1 may be involved in negative feedback regulation of IAA homeostasis through the control of GH3-like genes. We discuss the possible mechanisms by which HLS1 is involved in auxin signaling for sugar- and auxin-responsive gene expression and in IAA homeostasis.     

Potential role of annexin AnnAt1 from Arabidopsis thaliana in pH-mediated cellular response to environmental stimuli

Plant annexins, Ca(2+)- and membrane-binding proteins, are probably implicated in the cellular response to stress resulting from acidification of cytosol. To understand how annexins can contribute to cellular ion homeostasis, we investigated the pH-induced changes in the structure and function of recombinant annexin AnnAt1 from Arabidopsis thaliana. The decrease of pH from 7.0 to 5.8 reduced the time of the formation of ion channels by AnnAt1 in artificial lipid membranes from 3.5 h to 15-20 min and increased their unitary conductance from 32 to 63 pS. These changes were accompanied by an increase in AnnAt1 hydrophobicity as revealed by hydrophobicity predictions, by an increase in fluorescence of 2-(p-toluidino)naphthalene-6-sulfonic acid (TNS) bound to AnnAt1 and fluorescence resonance energy transfer from AnnAt1 tryptophan residues to TNS. Concomitant lipid partition of AnnAt1 at acidic pH resulted in its partial protection from proteolytic digestion. Secondary structures of AnnAt1 determined by circular dichroism and infrared spectroscopy were also affected by lowering the pH from 7.2 to 5.2. These changes were characterized by an increase in beta-sheet content at the expense of alpha-helical structures, and were accompanied by reversible formation of AnnAt1 oligomers as probed by ultracentrifugation in a sucrose gradient. A further decrease of pH from 5.2 to 4.5 or lower led to the formation of irreversible aggregates and loss of AnnAt1 ionic conductance. Our findings suggest that AnnAt1 can sense changes of the pH milieu over the pH range from 7 to 5 and respond by changes in ion channel conductance, hydrophobicity, secondary structure of the protein and formation of oligomers. Further acidification irreversibly inactivated AnnAt1. We suggest that the pH-sensitive ion channel activity of AnnAt1 may play a role in intracellular ion homeostasis.     

Phosphorylation of the amino terminus of maize sucrose synthase in relation to membrane association and enzyme activity

Sucrose synthase (SUS) is phosphorylated on a major, amino-terminal site located at Ser-15 (S15) in the maize (Zea mays) SUS1 protein. Site- and phospho-specific antibodies against a phosphorylated S15 (pS15) peptide allowed direct analysis of S15 phosphorylation in relation to membrane association. Immunoblots of the maize leaf elongation zone, divided into 4-cm segments, demonstrated that the abundance of soluble (s-SUS) and membrane (m-SUS) SUS protein showed distinct positional profiles. The content of m-SUS was maximal in the 4- to 8-cm segment where it represented 9% of total SUS and occurred as a peripheral membrane protein. In contrast, s-SUS was highest in the 12- to 16-cm segment. Relative to s-SUS, m-SUS was hypophosphorylated at S15 in the basal 4 cm but hyperphosphorylated in apical segments. Differing capabilities of the anti-pS15 and anti-S15 peptide antibodies to immunoprecipitate SUS suggested that phosphorylation of S15, or exposure of unphosphorylated SUS to slightly acidic pH, altered the structure of the amino terminus. These structural changes were generally coincident with the increased sucrose cleavage activity that occurs at pH values below 7.5. In vitro S15 phosphorylation of the S170A SUS protein by a maize calcium-dependent protein kinase (CDPK) significantly increased sucrose cleavage activity at low pH. Collectively, the results suggest that (1) SUS membrane binding is controlled in vivo; (2) relative pS15 content of m-SUS depends on the developmental state of the organ; and (3) phosphorylation of S15 affects amino-terminal conformation in a way that may stimulate the catalytic activity of SUS and influence membrane association.     

Glycosyl hydrolases of cell wall are induced by sugar starvation in Arabidopsis

Three Arabidopsis genes encoding a putative beta-galactosidase (At5g56870), beta-xylosidase (At5g49360) and beta-glucosidase (At3g60140) are induced by sugar starvation. The deduced proteins belong to the glycosyl hydrolase families 35, 3 and 1, respectively. They are predicted to be secretory proteins that play roles in modification of cell wall polysaccharides based on amino acid similarity. The beta-galactosidase encoded by At5g56870 was identified as a secretory protein in culture medium of suspension cells by mass spectrometry analysis. This protein was specifically detected under sugar-starved conditions with a specific antibody. Induction of these genes was repressed in suspension cells grown with galactose, xylose and glucose, as well as with sucrose. In planta, expression of the genes and protein accumulation were detected when photosynthesis was inhibited. Glycosyl hydrolase activity against galactan also increased during sugar starvation. The amount of monosaccharide in pectin and hemicellulose in detached leaves decreased in response to sugar starvation. These findings suggest that the cell wall may function as a storage reserve of carbon in addition to providing physical support for the plant body.     

Mitochondrial localization and putative signaling function of sucrose synthase in maize

In many organisms, an increasing number of proteins seem to play two or more unrelated roles. Here we report that maize sucrose synthase (SUS) is distributed in organelles not involved in sucrose metabolism and may have novel roles beyond sucrose degradation. Bioinformatics analysis predicts that among the three maize SUS isoforms, SH1 protein has a putative mitochondrial targeting peptide (mTP). We validated this prediction by the immunodetection of SUS in mitochondria. Analysis with isoform-specific antisera revealed that both SH1 and SUS1 are represented in mitochondria, although the latter lacks a canonical mTP. The SUS2 isoform is not detectable in mitochondria, despite its presence in the cytosol. In maize primary roots, the mitochondrion-associated SUS (mtSUS; which includes SH1 and SUS1) is present mostly in the root tip, indicating tissue-specific regulation of SUS compartmentation. Unlike the glycolytic enzymes that occur attached to the outside of mitochondria, SH1 and SUS1 are intramitochondrial. The low abundance of SUS in mitochondria, its high Km value for sucrose, and the lack of sucrose in mitochondria suggest that mtSUS plays a non-sucrolytic role. Co-immunoprecipitation studies indicate that SUS interacts with the voltage-dependent anion channel in an isoform-specific and anoxia-enhanced manner and may be involved in the regulation of solute fluxes into and out of mitochondria. In several plant species, at least one of the SUS proteins possesses a putative mTP, indicating the conservation of the noncatalytic function across plant species. Taken together, these observations suggest that SUS has a novel noncatalytic function in plant cells.     

Determination of structural requirements and probable regulatory effectors for membrane association of maize sucrose synthase 1

Sucrose (Suc) synthase (SUS) cleaves Suc to form UDP glucose and fructose, and exists in soluble and membrane-associated forms, with the latter proposed to channel UDP glucose to the cellulose-synthase complex on the plasma membrane of plant cells during synthesis of cellulose. However, the structural features responsible for membrane localization and the mechanisms regulating its dual intracellular localization are unknown. The maize (Zea mays) SUS1 isoform is likely to have the intrinsic ability to interact directly with membranes because we show: (1) partial membrane localization when expressed in Escherichia coli, and (2) binding to carbonate-stripped plant microsomes in vitro. We have undertaken mutational analyses (truncations and alanine substitutions) and in vitro microsome-binding assays with the SUS1 protein to define intrinsic membrane-binding regions and potential regulatory factors that could be provided by cellular microenvironment. The results suggest that two regions of SUS1 contribute to membrane affinity: (1) the amino-terminal noncatalytic domain, and (2) a region with sequence similarity to the C-terminal pleckstrin homology domain of human pleckstrin. Alanine substitutions within the pleckstrin homology-like domain of SUS1 reduced membrane association in E. coli and with plant microsomes in vitro without reducing enzymatic activity. Microsomal association of wild-type SUS1 displayed cooperativity with SUS1 protein concentration and was stimulated by both lowering the pH and adding Suc. These studies offer insight into the molecular level regulation of SUS1 localization and its participation in carbon partitioning in plants. Moreover, transgenics with active SUS mutants altered in membrane affinity may be of technological utility.     

Transcriptional Induction of Two Genes for CCaPs, Novel Cytosolic Proteins, in Arabidopsis thaliana in the Dark

Ca2+-signaling in downstream effectors is supported by many kinds of Ca2+-binding proteins, which function as a signal mediator and a Ca2+-buffering protein. We found in Arabidopsis thaliana a new type of Ca2+-binding protein, CCaP1, which consists of 152 amino acid residues, and binds (45)Ca2+ even in the presence of a high concentration of Mg2+. We found two other proteins with similar motifs, CCaP2 and CCaP3. These three proteins had no organelle localization signal and their green fluorescent protein (GFP) fusions were detected in the cytosol. Real-time PCR and histochemical analysis of promoter-beta-glucuronidase fusions revealed that CCaP1 was predominantly expressed in petioles while CCaP2 was expressed in roots. CCaP3 was hardly expressed. Expression of CCaP1 and CCaP2 was enhanced in darkness and became maximal after 24 h. Immunoblotting revealed petiole-specific accumulation of CCaP1. Expression of CCaP1 and CCaP2 was suppressed by a high concentration of Ca2+ and other metal ions. Deletion of sucrose from the medium markedly increased the mRNA levels of CCaP1 and CCaP2 within 2 h. Gibberellic acid enhanced the expression of CCaP1 and CCaP2 by 5- and 2.5-fold, respectively, after 6 h. CCaP1 and CCaP2 were suppressed in the petiole and the root, respectively, by light and the product of photosynthesis (sucrose) or both. These results suggest that CCaP1 functions as a mediator in response to continuous dark or gibberellic acid.     

MAP kinases function downstream of HSP90 and upstream of mitochondria in TMV resistance gene N-mediated hypersensitive cell death

Although the involvement of heat shock protein 90 (HSP90), mitogen-activated protein kinase (MAPK) cascades and organelle dysfunction in plant hypersensitive cell death has been suggested, the mutual relationship among them has not been elucidated. Here, we show the molecular network of HSP90, the wound-induced protein kinase (WIPK)/salicylic acid-induced protein kinase (SIPK)-mediated MAPK cascade and mitochondrial dysfunction in tobacco mosaic virus (TMV) resistance gene N-dependent cell death. p50, the Avr component for N, NtMEK2(DD), a constitutively active form of a MAPK kinase of WIPK/SIPK, and a mammalian pro-apoptotic factor Bax were used for cell death induction. Suppression of HSP90 and treatment with geldanamycin, a specific inhibitor of HSP90, compromised p50- but not NtMEK2(DD)- or Bax-mediated cell death accompanying the reduction of NtMEK2, WIPK and SIPK activation. In WIPK/SIPK-double knockdown plants, p50- and NtMEK2(DD)- but not Bax-mediated cell death was suppressed. All three types of cell death induced mitochondrial dysfunction, but they were similarly suppressed by Bcl-xL, which is a mammalian anti-apoptotic factor, and prevents mitochondrial dysfunction in plants as it does in animals in the cell death signal pathway. Taken together with the expression profile of hypersensitive reaction marker genes, it was indicated that the MAPK cascade functions downstream of HSP90 and transduces the cell death signal to mitochondria for N gene-dependent cell death. Furthermore, we found that WIPK and SIPK are functionally redundant in cell death signaling using WIPK/SIPK single or double knockdown plants.     

Cytoskeleton-associated, carbohydrate-metabolizing enzymes in maize identified by yeast two-hybrid screening

We have used yeast two-hybrid screens and biochemical methods to identify glycolytic enzymes that interact with subcellular structures in hypoxic maize seedlings. As binding domain-bait fusion constructs, we have cloned actin, cytosolic aldolase, the three sucrose synthase (SUS) isoforms SUS1, SUS3, and SH1 as well as the SNF1-related protein kinase into yeast and identified cytosolic isoforms of glyceraldehyde 3-phosphate dehydrogenase (GAPDH), enolase, tubulin, and mitochondrial porin voltage-dependent anion channel protein (VDAC) as well as protein kinases and proteins involved in ubiquitinylation and proteasome-linked degradation as interacting activation domain-prey clones. The results were further confirmed using overlay blots (VDAC) as well as co-polymerization and co-precipitation assays (tubulin and actin). Some results were obtained that support the idea of metabolite and modification effects on the association, namely guanosine triphosphate (GTP)/MgCl₂ was necessary for the binding of enolase to actin. GAPDH is inactivated upon association with tubulin but then serves to stabilize the microtubules. The findings support the idea of the dynamic formation of locally associated complexes of enzymes involved in sucrose breakdown and glycolysis in plant cells depending on their metabolic state.     

Changes in the sugarcane metabolome with stem development. Are they related to sucrose accumulation?

Sucrose content increases with internode development down the stem of sugarcane. In an attempt to determine which other changes in metabolites may be linked to sucrose accumulation gas chromatography-mass spectrometry was used to obtain metabolic profiles from methanol/water extracts of four samples of different age down the stem of cultivar Q117. Extracts were derivatized with either N-methyl-N-(trimethylsilyl) trifluoracetamide (TMS) or N-methyl N-(tert-butyldimethylsilyl) trifluoroacetamide (TBS) separately in order to increase the number of metabolites that could be detected. This resulted in the measurement of 121 and 71 metabolites from the TMS and TBS derivatization, respectively. Fifty-five metabolites were identified using commercial and publicly available libraries. Statistical analysis of the metabolite profiles resulted in clustering of tissue types. Particular metabolites were correlated with the level of sucrose accumulation, which as expected increased down the stem. Metabolites, such as tricarboxylic acid cycle intermediates and amino acids, were more abundant in the M2 sample (meristem to internode 2) that was actively growing and decreased in an apparently coordinated developmentally programmed manner in more mature internodes down the stem. However, other metabolites such as trehalose and raffinose showed positive correlations with sucrose concentration. Here we discuss the technique used to measure metabolites in sugarcane and the changes in metabolite abundance down the sugarcane stem.     

Molecular Characterization of Caveolin-induced Membrane Curvature

The generation of caveolae involves insertion of the cholesterol-binding integral membrane protein caveolin-1 (Cav1) into the membrane, however, the precise molecular mechanisms are as yet unknown. We have speculated that insertion of the caveolin scaffolding domain (CSD), a conserved amphipathic region implicated in interactions with signaling proteins, is crucial for caveola formation. We now define the core membrane-juxtaposed region of Cav1 and show that the oligomerization domain and CSD are protected by tight association with the membrane in both mature mammalian caveolae and a model prokaryotic system for caveola biogenesis. Cryoelectron tomography reveals the core membrane-juxtaposed domain to be sufficient to maintain oligomerization as defined by polyhedral distortion of the caveolar membrane. Through mutagenesis we demonstrate the importance of the membrane association of the oligomerization domain/CSD for defined caveola biogenesis and furthermore, highlight the functional significance of the intramembrane domain and the CSD for defined caveolin-induced membrane deformation. Finally, we define the core structural domain of Cav1, constituting only 66 amino acids and of great potential to nanoengineering applications, which is required for caveolin-induced vesicle formation in a bacterial system. These results have significant implications for understanding the role of Cav1 in caveola formation and in regulating cellular signaling events.     

Sucrose Synthase: Expanding Protein Function

Sucrose synthase (SUS: EC 2.4.1.13), a key enzyme in plant sucrose catabolism, is uniquely able to mobilize sucrose into multiple pathways involved in metabolic, structural, and storage functions. Our research indicates that the biological function of SUS may extend beyond its catalytic activity. This inference is based on the following observations: (a) tissue-specific, isoform-dependent and metabolically-regulated association of SUS with mitochondria and (b) isoform-specific and anoxia-responsive interaction of SUS with the voltage-dependent anion channel (VDAC), the major outer mitochondrial membrane protein. More recent work shows that both VDAC and SUS are also localized to the nucleus in maize seedling tissues. Their intricate regulation under anoxia indicates that these two proteins may have a role in inter-compartmental signaling.Key Words: sucrose synthase, mitochondria, nucleus, localization, voltage-dependent anion channel (VDAC), non-catalytic rolesThe biochemical function of a protein is encoded within its primary sequence and can often be deciphered by simple in vitro assays. The cellular or organismal function of a protein is frequently the same as its biochemical activity. However, for many proteins, the biological function cannot be easily derived based on its biochemical function. This appears to be particularly true when the gene encoding the protein has a history of duplication and is represented by a family of paralogs. In maize and other species, sucrose synthase (SUS) isoforms are almost identical in their catalytic properties.^1,2 However, the characteristic phenotypes of mutants in specific isoforms suggest that the isoforms contribute to vastly different organismal functions.^2–4 Our interest is to identify the range of functions that maize SUS isoforms may have and elucidate the molecular basis of this functional diversity. Although expression divergence and consequent variation in their cellular abundance significantly contributes to this diversity,⁵ other factors such as intracellular distribution, post-translational modifications and interacting partners,^3,4,6,7 seem to be equally critical for the functional diversification of different SUS isoforms.Our study, spurred by a bioinformatics prediction, opened up a new facet of SUS biology, in that the protein may have organelle-based functions.⁸ Our analysis indicated that two of the three maize SUS isoforms (SH1 and SUS1) partly localize to mitochondria and nuclei, compartments not related to sucrose metabolism. In addition to this isoform-specificity, the compartmentation of SUS isoforms is influenced by developmental as well as environmental cues. Furthermore, its isoform-specific interaction with the voltage-dependent anion channel (VDAC) and an apparent conservation of SUS mitochondrial targeting across plant species suggest that SUS may have novel, noncatalytic biological functions. Our recent work shows that along with SUS, VDAC is also localized to the nucleus and these two proteins are inversely regulated in these two compartments under anoxic stress, indicating SUS-VDAC interaction may play a role in inter-compartmental signaling (Fig. 1).Open in a separate windowFigure 1Current working model of SUS-VDAC interactions in maize root tip cells. Prolonged anoxia leads to de-oligomerization of VDAC and the release of SUS from mitochondria, resulting in the migration of SUS to the nucleus. We hypothesize that the nuclear accumulation of SUS signals the induction of cell death pathway leading to the death of the root tip in anoxic maize seedlings. The insets show the primary root tip and a part of the axis from aerobic and anoxic seedlings. The root tip death is indicated by Evans Blue staining pattern of the anoxic root. ≠ = SUS. □ = VDAC.SUS mitochondrial localization also provided us an opportunity to reinterpret the phylogeny of sucrose metabolism. The proposed origin of sucrose metabolism is equivocal between the proteobacterial and cyanobacterial lineages.^9,10 Our discovery of SUS inside mitochondria, absence of plastid-bound SUS or plastid-targeting information in any of the plant SUS proteins and occurrence of mitochondrial targeting information in proteobacterial SUS orthologs strongly support a proteobacterial origin of plant sucrose synthases.⁸ Based on a genome-wide analysis of E. coli proteins, Lucattini et al.¹¹ proposed that mitochondrial targeting information may have been derived from the preexisting sequences of the endosymbiont proteins. We hypothesize that, in addition to the structural features needed for mitochondrial association, the functional basis of SUS-VDAC interaction may have been recruited by plants from the prokaryotic SUS genes. Based on striking similarities between bacterial and mitochondrial porins in their structure as well as regulation by purine nucleotides and their role in the host-cell death as modulated by cellular ATP levels, Frade and Michaelidis¹² speculated that the eukaryotic programmed cell death may have been a consequence of acquiring aerobic metabolism via the endosymbiotic process. Is organellar SUS a part of this acquisition?     

Arabidopsis VPS35, a retromer component, is required for vacuolar protein sorting and involved in plant growth and leaf senescence

The retromer complex is responsible for retrograde transport,which is coordinated with anterograde transport in the secretorypathway including vacuolar protein sorting. Yeast VPS35 is acomponent of the retromer complex that is essential for recognitionof specific cargo molecules. The physiological function of VPS35has not been determined in vacuolar protein sorting in higherorganisms. Arabidopsis thaliana has three VPS35 homologs designatedVPS35a, VPS35b and VPS35c. We isolated four vps35 mutants (vps35a-1,vps35b-1, vps35b-2 and vps35c-1) and then generated four doublemutants and one triple mutant. vps35a-1 vps35c-1 exhibited nounusual phenotypes. On the other hand, vps35b-1 vps35c-1 andthe triple mutant (vps35a-1 vps35b-2 vps35c-1) exhibited severephenotypes: dwarfism, early leaf senescence and fragmentationof protein storage vacuoles (PSVs). In addition, these mutantsmis-sorted storage proteins by secreting them out of the cellsand accumulated a higher level of vacuolar sorting receptor(VSR) than the wild type. VPS35 was localized in pre-vacuolarcompartments (PVCs), some of which contained VSR. VPS35 wasimmunoprecipitated with VPS29/MAG1, another component of theretromer complex. Our findings suggest that VPS35, mainly VPS35b,is involved in sorting proteins to PSVs in seeds, possibly byrecycling VSR from PVCs to the Golgi complex, and is also involvedin plant growth and senescence in vegetative organs.     

Identification of the gravitropism-related rice gene LAZY1 and elucidation of LAZY1-dependent and -independent gravity signaling pathways

We identified the gene responsible for three allelic lazy1 mutations of Japonica rice (Oryza sativa L.) by map-based cloning, complementation and RNA interference. Sequence analysis and database searches indicated that the wild-type gene (LAZY1) encodes a novel and unique protein (LAZY1) and that rice has no homologous gene. Two lazy1 mutants were LAZY1 null. Confirming and advancing the previously reported results on lazy1 mutants, we found the following. (i) Gravitropism is impaired, but only partially, in lazy1 coleoptiles. (ii) Circumnutation, observed in dark-grown coleoptiles, is totally absent from lazy1 coleoptiles. (iii) Primary roots of lazy1 mutants show normal gravitropism and circumnutation. (iv) LAZY1 is expressed in a tissue-specific manner in gravity-sensitive shoot tissues (i.e. coleoptiles, leaf sheath pulvini and lamina joints) and is little expressed in roots. (v) The gravitropic response of lazy1 coleoptiles is kinetically separable from that absent from lazy1 coleoptiles. (vi) Gravity-induced lateral translocation of auxin, found in wild-type coleoptiles, does not occur in lazy1 coleoptiles. Based on the genetic and physiological evidence obtained, it is concluded that LAZY1 is specifically involved in shoot gravitropism and that LAZY1-dependent and -independent signaling pathways occur in coleoptiles. It is further concluded that, in coleoptiles, only the LAZY1-dependent gravity signaling involves asymmetric distribution of auxin between the two lateral halves and is required for circumnutation.     

Protein phosphorylation and binding of a 14-3-3 protein in Vicia guard cells in response to ABA

Under drought stress, ABA promotes stomatal closure to prevent water loss. Although protein phosphorylation plays an important role in ABA signaling, little is known about these processes at the biochemical level. In this study, we searched for substrates of protein kinases in ABA signaling through the binding of a 14-3-3 protein to phosphorylated proteins using Vicia guard cell protoplasts. ABA induced binding of a 14-3-3 protein to proteins with molecular masses of 61, 43 and 39 kDa, with the most remarkable signal for the 61 kDa protein. The ABA-induced binding to the 61 kDa protein occurred only in guard cells, and reached a maximum within 3 min at 1 microM ABA. The 61 kDa protein localized in the cytosol. ABA induced the binding of endogenous vf14-3-3a to the 61 kDa protein in guard cells. Autophosphorylation of ABA-activated protein kinase (AAPK), which mediates anion channel activation, and ABA-induced phosphorylation of the 61 kDa protein showed similar time courses and similar sensitivities to the protein kinase inhibitor K-252a. AAPK elicits the binding of the 14-3-3 protein to the 61 kDa protein in vitro when AAPK in guard cells was activated by ABA. The phosphorylation of the 61 kDa protein by ABA was not affected by the NADPH oxidase inhibitor, H(2)O(2), W-7 or EGTA. From these results, we conclude that the 61 kDa protein may be a substrate for AAPK and that the 61 kDa protein is located upstream of H(2)O(2) and Ca(2+), or on Ca(2+)-independent signaling pathways in guard cells.     

A cell-free translation and proteoliposome reconstitution system for functional analysis of plant solute transporters

We describe here a novel proteoliposome reconstitution system for functional analysis of plant membrane transporters that is based on a modified wheat germ cell-free translation system. We established optimized conditions for the reconstitution system with Arabidopsis thaliana phosphoenolpyruvate/phosphate translocator 1 (AtPPT1) as a model transporter. A high activity of AtPPT1 was achieved by synthesis of the protein in the presence of both a detergent such as Brij35 and liposomes. We also determined the substrate specificities of three putative rice PPT homologs with this system. The cell-free proteoliposome reconstitution system provides a valuable tool for functional analysis of transporter proteins.