Identification of genes expressed in vascular tissues using NPA-induced vascular overgrowth in Arabidopsis

The genetic basis of vascular differentiation and function isrelatively poorly understood, partly due to the difficulty ofscreening for mutants defective in internal vascular tissues.Here we present an approach based on a predicted increase invascular-related gene expression in response to an auxin transportinhibitor-induced vascular overgrowth. We used microarray analysesto identify 336 genes that were up-regulated 2-fold in shoottissues of Arabidopsis thaliana showing vascular overgrowth.Promoter–marker gene fusions revealed that 38 out of 40genes with 4-fold up-regulation in vascular overgrowth tissueshad vascular-related expression in transgenic Arabidopsis plants.Obtained expression patterns included cambial tissues and differentiatingxylem, phloem and fibers. A total of 15 genes were found tohave vascular-specific expression patterns in the leaves and/orinflorescence stems. This study provides empirical evidenceof the efficiency of the approach and describes for the firsttime the in situ expression patterns of the majority of theassessed genes.     

Morphogenetic Effect of the Herbicide Cinch on Arabidopsis thaliana Root Development

Cinch is a morphogenetically active herbicide that inhibits primary root growth and induces abnormal ``nodule-like' lateral roots on Arabidopsis thaliana seedlings. Using 200 nm Cinch, the early stages of lateral root formation occurred along the apical half of the root axis; but once emerged, they were inhibited from further growth. Second-order lateral roots formed at the base of stunted first-order lateral roots after 5 days of Cinch treatment. Results from Cinch experiments suggested that pericycle cells are determined in the meristem to be potential sites of lateral root formation, and the developmental transition point between emerged lateral roots and subsequent growth is inhibited. Results using 2,4-dichlorophenoxyacetic acid and 2,3,5-triiodobenzoic acid suggest that Cinch is not a chemical analog of auxin. Received August 8, 1997; accepted February 23, 1998     

Genetic Analysis of the Effects of Polar Auxin Transport Inhibitors on Root Growth in Arabidopsis thaliana

Polar auxin transport inhibitors, including N-1-naphthylphthalamicacid (NPA) and 2,3,5-triiodobenzoic acid (TIBA), have variouseffects on physiological and developmental events, such as theelongation and tropism of roots and stems, in higher plants.We isolated NPA-resistant mutants of Arabidopsis thaliana, withmutations designated pir1 and pir2, that were also resistantto TIBA. The mutations specifically affected the root-elongationprocess, and they were shown ultimately to be allelic to aux1and ein2, respectively, which are known as mutations that affectresponses to phytohormones. The mechanism of action of auxintransport inhibitors was investigated with these mutants, inrelation to the effects of ethylene, auxin, and the polar transportof auxin. With respect to the inhibition of root elongationin A. thaliana, we demonstrated that (1) the background levelof ethylene intensifies the effects of auxin transport inhibitors,(2) auxin transport inhibitors might act also via an inhibitorypathway that does not involve ethylene, auxin, or the polartransport of auxin, (3) the hypothesis that the inhibitory effectof NPA on root elongation is due to high-level accumulationof auxin as a result of blockage of auxin transport is not applicableto A. thaliana, and (4) in contrast to NPA, TIBA itself hasa weak auxin-like inhibitory effect. (Received April 12, 1996; Accepted September 2, 1996)     

Identification of maize silicon influx transporters

Maize (Zea mays L.) shows a high accumulation of silicon (Si),but transporters involved in the uptake and distribution havenot been identified. In the present study, we isolated two genes(ZmLsi1 and ZmLsi6), which are homologous to rice influx Sitransporter OsLsi1. Heterologous expression in Xenopus laevisoocytes showed that both ZmLsi1 and ZmLsi6 are permeable tosilicic acid. ZmLsi1 was mainly expressed in the roots. By contrast,ZmLsi6 was expressed more in the leaf sheaths and blades. Differentfrom OsLsi1, the expression level of both ZmLsi1 and ZmLsi6was unaffected by Si supply. Immunostaining showed that ZmLsi1was localized on the plasma membrane of the distal side of rootepidermal and hypodermal cells in the seminal and crown roots,and also in cortex cells in lateral roots. In the shoots, ZmLsi6was found in the xylem parenchyma cells that are adjacent tothe vessels in both leaf sheaths and leaf blades. ZmLsi6 inthe leaf sheaths and blades also exhibited polar localizationon the side facing towards the vessel. Taken together, it canbe concluded that ZmLsi1 is an influx transporter of Si, whichis responsible for the transport of Si from the external solutionto the root cells and that ZmLsi6 mainly functions as a Si transporterfor xylem unloading.     

Involvement of Polypyrimidine Tract-Binding Protein (PTB)-Related Proteins in Pollen Germination in Arabidopsis

The pollen grains of most angiosperms contain stores of RNAsand their translation products required for pollen germinationand subsequent early elongation of pollen tubes. Polypyrimidinetract-binding protein (PTB), which is involved in the regulationof pre-mRNA alternative splicing, internal ribosomal entry site(IRES)-mediated translation and mRNA localization/sorting, isknown to act as a bridging molecule between RNAs and a varietyof cellular factors to fulfill cellular functions in both thenucleus and cytoplasm. Moreover, it has been reported that PTBplays roles in the differentiation and development of animalcells and tissues. In the Arabidopsis genome, there are twoPTB-related genes, tentatively termed AtPTB1 and AtPTB2. Inthe present study, the physiological functions of AtPTBs wereinvestigated using genetic and cytological approaches. The AtPTBpromoter was highly active in vegetative cells of mature pollengrains, and AtPTB was localized in the nucleus and cytoplasmof these vegetative cells. Mutations in the AtPTB genes resultedin decreased germination efficiency, and this effect was rescuedby introduction of the AtPTB2 promoter::AtPTB2–GFP. Takentogether, these findings suggest that AtPTB is involved in pollengermination through possible RNA metabolism processes in late-maturingand mature pollen grains.     

Electrophysiological characterization of the node in Chara corallina: functional differentiation for wounding response

Electrical characteristics of the node were analyzed in comparisonwith those of the flank of the internodal cell in Chara corallina.The dependence of the membrane potential of the node on pH andK⁺ concentration was almost the same as that of the flank. Inthe flank, the increase in the Ca²⁺ concentration stopped thedepolarization in the presence of 100 mM KCl. In the node, however,Ca²⁺ could not stop the depolarization induced by 100 mM KCl.It has been reported that the node has a function to tranducethe signal of osmotic shock into a transient depolarization.In combination with osmotic shock, 10 mM K⁺ could induce a long-lastingdepolarization of the node. These electrical characteristicsof the node were suggested to be responsible for the electricalresponse to wounding in Characeae.     

Aeromonas punctata PNS-1: a promising candidate to change the root morphogenesis of Arabidopsis thaliana in MS and sand system

A model system of sand, comprising Arabidopsis plants inoculated with Aeromonas punctata PNS-1 strain, was used to evaluate the bacterial effect in modulation of plant root structure at second-order lateral root level. In MS media, the root morphogenesis was changed only at first-order lateral root level when inoculated with PNS-1 strain. Inoculation with PNS-1 strain was subjected to significant (P < 0.01) increase in primary root length and lateral root density in both MS and sand system. However, this strain modulated the root structure in the sand environment in a complex manner that may be helpful for incitation of the plant–microbe interaction close to natural environment. In order to determine whether this change in root morphology was due to bacterial auxin, Arabidopsis transgenic line (DR5:GUS) was used to reveal the change in homeostasis of endogenous auxin. In PNS-1 inoculated transgenic seedlings of Arabidopsis plant (DR5:GUS), endogenous auxin in primary root apices and lateral roots was enhanced. For confirmation, PNS-1 was evaluated for auxin production in vitro, showed an increase in auxin production after supplementation of l-tryptophan. The presence of ACC deaminase activity in PNS-1 showed its possible involvement in primary root elongation. In the present study Aeromonas punctata PNS-1 is the potential candidate for triggering the change in root morphogenesis of Arabidopsis thaliana with the involvement of auxin and ACC deaminase production.     

The signaling role of extracellular ATP and its dependence on Ca2+ flux in elicitation of Salvia miltiorrhiza hairy root cultures

The application of a polysaccharide elicitor from yeast extract,YE, to Salvia miltiorrhiza hairy root cultures induced transientrelease of ATP from the roots to the medium, leading to a dose-dependentincrease in the extracellular ATP (eATP) level. The eATP levelrose to a peak (about 6.5 nM with 100 mg l^–1 YE) at about10 h after YE treatment, but dropped to the control level 6h later. The elicitor-induced ATP release was dependent on membraneCa²⁺ influx, and abolished by the Ca²⁺ chelator EGTA or thechannel blocker La³⁺. The YE-induced H₂O₂ production was stronglyinhibited by reactive blue (RB), a specific inhibitor of membranepurinoceptors. On the other hand, the application of exogenousATP at 10–100 µM to the cultures also induced rapidand dose-dependent increases in H₂O₂ production and medium pH,both of which were effectively blocked by RB and EGTA. The non-hydrolyzableATP analog ATPS was as effective as ATP, but the hydrolyzedderivatives ADP or AMP were not so effective in inducing thepH and H₂O₂ increases. Our results suggest that ATP releaseis an early event and that eATP plays a signaling role in theelicitation of plant cell responses; Ca²⁺ is required for activationof the elicitor-induced ATP release and the eATP signal transduction.This is the first report on ATP release induced by a fungalelicitor and its involvement in the elicitor-induced responsesin plant cells.     

Nod Factor/Nitrate-Induced CLE Genes that Drive HAR1-Mediated Systemic Regulation of Nodulation

Host legumes control root nodule numbers by sensing externaland internal cues. A major external cue is soil nitrate, whereasa feedback regulatory system in which earlier formed nodulessuppress further nodulation through shoot–root communicationis an important internal cue. The latter is known as autoregulationof nodulation (AUT), and is believed to consist of two long-distancesignals: a root-derived signal that is generated in infectedroots and transmitted to the shoot; and a shoot-derived signalthat systemically inhibits nodulation. In Lotus japonicus, theleucine-rich repeat receptor-like kinase, HYPERNODULATION ABERRANTROOT FORMATION 1 (HAR1), mediates AUT and nitrate inhibitionof nodulation, and is hypothesized to recognize the root-derivedsignal. Here we identify L. japonicus CLE-Root Signal 1 (LjCLE-RS1)and LjCLE-RS2 as strong candidates for the root-derived signal.A hairy root transformation study shows that overexpressingLjCLE-RS1 and -RS2 inhibits nodulation systemically and, furthermore,that the systemic suppression depends on HAR1. Moreover, LjCLE-RS2expression is strongly up-regulated in roots by nitrate addition.Based on these findings, we propose a simple model for AUT andnitrate inhibition of nodulation mediated by LjCLE-RS1, -RS2peptides and the HAR1 receptor-like kinase.     

Constitutive components and induced gene expression are involved in the desiccation tolerance of Selaginella tamariscina

Selaginella tamariscina, one of the most primitive vascularplants, can remain alive in a desiccated state and resurrectwhen water becomes available. To evaluate the nature of desiccationtolerance in this plant, we compared the composition of solublesugars and saturation ratios of phospholipids (PLs) betweenhydrated and desiccated tissues of S. tamariscina using gaschromatography. In this study, differences in gene expressionand ABA contents were also analyzed during dehydration. Theresults revealed that trehalose (at >130 mg g^–1 DW)was the major soluble sugar, and low saturated fatty acid contentin PLs (0.31) was maintained in both hydrated and desiccatedtissues. In addition, the ABA content of S. tamariscina increased3-fold, and genes involved in ABA signaling and cellular protectionwere up-regulated while photosystem-related genes were down-regulatedduring dehydration. The biochemical and molecular findings suggestthat both constitutive and inducible protective molecules contributeto desiccation tolerance of S. tamariscina.     

Novel Cysteine-Rich Peptides from Digitaria ciliaris and Oryza sativa Enhance Tolerance to Cadmium by Limiting its Cellular Accumulation

By means of functional screening using the cadmium (Cd)-sensitiveycf1 yeast mutant, we have isolated a novel cDNA clone, DcCDT1,from Digitaria ciliaris growing in a former mining area in northernJapan, and have shown that it confers Cd tolerance to the yeastcells, which accumulated almost 2-fold lower Cd levels thancontrol cells. The 521 bp DcCDT1 cDNA contains an open readingframe of 168 bp and encodes a deduced peptide, DcCDT1, thatis 55 amino acid residues in length, of which 15 (27.3%) arecysteine residues. Five DcCDT1 homologs (here termed OsCDT1–OsCDT5)have been identified in rice, and all of them were up-regulatedto varying degrees in the above-ground tissues by CdCl₂ treatment.Localization of green fluorescent protein fusions suggests thatDcCDT1 and OsCDT1 are targeted to both cytoplasmic membranesand cell walls of plant cells. Transgenic Arabidopsis thalianaplants overexpressing DcCDT1 or OsCDT1 displayed a Cd-tolerantphenotype and, consistent with our yeast data, accumulated loweramounts of Cd when grown on CdCl₂. Collectively, our data suggestthat DcCDT1 and OsCDT1 function to prevent entry of Cd intoyeast and plant cells and thereby enhance their Cd tolerance.     

The mechanism selecting the guide strand from small RNA duplexes is different among argonaute proteins

Double-stranded RNA induces RNA silencing and is cleaved into21–24 nt small RNA duplexes by Dicer enzyme. A strandof Dicer-generated small RNA duplex (called the guide strand)is then selected by a thermodynamic mechanism to associate withArgonaute (AGO) protein. This AGO–small RNA complex functionsto cleave mRNA, repress translation or modify chromatin structurein a sequence-specific manner. Although a model plant, Arabidopsisthaliana, contains 10 AGO genes, their roles and molecular mechanismsremain obscure. In this study, we analyzed the roles of ArabidopsisAGO2 and AGO5. Interestingly, the 5' nucleotide of small RNAsthat associated with AGO2 was mainly adenine (85.7%) and thatwith AGO5 was mainly cytosine (83.5%). Small RNAs that wereabundantly cloned from the AGO2 immunoprecipitation fraction(miR163-LL, which is derived from the Lower Left of mature miR163in pre-miR163, and miR390) and from the AGO5 immunoprecipitationfraction (miR163-UL, which is derived from the Upper Left ofmature miR163 in pre-miR163, and miR390^*) are derived from thesingle small RNA duplexes, miR163-LL/miR163-UL and miR390/miR390^*.Each strand of the miR163-LL/miR163-UL duplex is selectivelysorted to associate with AGO2 or AGO5 in a 5' nucleotide-dependentmanner rather than in a thermodynamic stability-dependent manner.Furthermore, we showed that both AGO2 and AGO5 have the abilityto bind cucumber mosaic virus-derived small RNAs. These resultsclearly indicate that the mechanism selecting the guide strandis different among AGO proteins and that multiple AGO genesare involved in anti-virus defense in plants.     

PP2A mediates lateral root development under NaCl-induced osmotic stress throughout auxin redistribution in Arabidopsis thaliana

Aim

Auxin plays an important role in modulating root system architecture. The effect of salinity on root development has been extensively studied; however, evidence on how salinity affects lateral root development and its underlying molecular mechanism is scarce. Here, we analyzed the role of protein phosphatase PP2A activity in auxin redistribution during Arabidopsis root system adaptation under NaCl-induced osmotic stress.

Method

Arabidopsis Col-0 and DR5::UidA seedlings were grown in MS media containing NaCl alone or in combination with the auxin transport inhibitor naphthylphthalamic acid, the synthetic auxin α-Naphthaleneacetic acid or the phosphatase inhibitor Okadaic acid. After 8 days, primary root length and lateral root number in seedlings were quantified and the auxin distribution was analyzed.

Results

Promotion of primary root shortening and lateral root development induced by osmotic stress correlated with an increase in active auxin content and a >50 % reduction in protein phosphatase type 2A (PP2A) activity. Moreover, the observed effects on seedlings under osmotic stress are more pronounced with the PP2A inhibitor Okadaic acid.

Conclusion

Our data suggest PP2A is a positive regulator of osmotic stress-induced root system architecture modulation, involving auxin redistribution in Arabidopsis thaliana.     

The AtXTH28 Gene, a Xyloglucan Endotransglucosylase/Hydrolase, is Involved in Automatic Self-Pollination in Arabidopsis thaliana

Successful automatic self-pollination in flowering plants isdependent on the correct development of reproductive organs.In the stamen, the appropriate growth of the filament, whichlargely depends on the mechanical properties of the cell wall,is required to position the anther correctly close to the stigmaat the pollination stage. Xyloglucan endotransglucosylase/hydrolases(XTHs) are a family of enzymes that mediate the constructionand restructuring of xyloglucan cross-links, thereby controllingthe extensibility or mechanical properties of the cell wallin a wide variety of plant tissues. Our reverse genetic analysishas revealed that a loss-of-function mutation of an ArabidopsisXTH family gene, AtXTH28, led to a decrease in capability forself-pollination, probably due to inhibition of stamen filamentgrowth. Our results also suggest that the role of AtXTH28 inthe development of the stamen is not functionally redundantwith its closest paralog, AtXTH27. Thus, our finding indicatesthat AtXTH28 is specifically involved in the growth of stamenfilaments, and is required for successful automatic self-pollinationin certain flowers in Arabidopsis thaliana.     

Roles for the N- and C-terminal domains of phytochrome B in interactions between phytochrome B and cryptochrome signaling cascades

Plants fine-tune light responses through interactions betweenphotoreceptors. We have previously reported that the greeningof Arabidopsis thaliana roots is regulated synergistically byphytochromes and cryptochromes. In the present study, we investigatedthe functions of the N- and C-terminal domains of phytochromeB (phyB) in the interactions between phyB and cryptochrome signalingcascades. Transgenic Arabidopsis expressing the phyB N-terminaldomain fused to green fluorescent protein (GFP), ß-glucuronidase(GUS) and the nuclear localization signal (NLS) showed intenseroot greening under blue light, indicating that the C-terminaldomain was dispensable for the synergistic interaction in theinduction of root greening. However, root greening under redlight was substantially reduced in the absence of the C-terminaldomain. This effect was opposite to the previous observationthat removal of the C-terminal domain enhanced the signalingactivity of phyB in the inhibition of hypocotyl elongation.In addition, we found that overexpression of the isolated C-terminaldomain of phyB enhanced the blue light response not only forroot greening but also for the inhibition of hypocotyl elongation.Analysis of this activity on various photoreceptor mutant backgroundsdemonstrated that the isolated C-terminal domain enhanced cryptochromesignaling. In summary, these results demonstrate that differentdomains of phyB can play various roles which are dependent onlight conditions as well as on the specific physiological response.