Cytokinin inhibits a subset of diageotropica-dependent primary auxin responses in tomato

Many aspects of plant development are regulated by antagonistic interactions between the plant hormones auxin and cytokinin, but the molecular mechanisms of this interaction are not understood. To test whether cytokinin controls plant development through inhibiting an early step in the auxin response pathway, we compared the effects of cytokinin with those of the dgt (diageotropica) mutation, which is known to block rapid auxin reactions of tomato (Lycopersicon esculentum) hypocotyls. Long-term cytokinin treatment of wild-type seedlings phenocopied morphological traits of dgt plants such as stunting of root and shoot growth, reduced elongation of internodes, reduced apical dominance, and reduced leaf size and complexity. Cytokinin treatment also inhibited rapid auxin responses in hypocotyl segments: auxin-stimulated elongation, H(+) secretion, and ethylene synthesis were all inhibited by cytokinin in wild-type hypocotyl segments, and thus mimicked the impaired auxin responsiveness found in dgt hypocotyls. However, cytokinin failed to inhibit auxin-induced LeSAUR gene expression, an auxin response that is affected by the dgt mutation. In addition, cytokinin treatment inhibited the auxin induction of only one of two 1-aminocyclopropane-1-carboxylic acid synthase genes that exhibited impaired auxin inducibility in dgt hypocotyls. Thus, cytokinin inhibited a subset of the auxin responses impaired in dgt hypocotyls, suggesting that cytokinin blocks at least one branch of the DGT-dependent auxin response pathway.     

The growth of tomato (Lycopersicon esculentum Mill.) hypocotyls in the light and in darkness differentially involves auxin.

Light and auxin antagonistically regulate hypocotyl elongation. We have investigated the physiological interactions of light and auxin in the control of tomato (Lycopersicon esculentum Mill.) hypocotyl elongation by studying the auxin-insensitive mutant diageotropica (dgt). The length of the hypocotyls of the dgt mutant is significantly reduced when compared to the wild type line Ailsa Craig (AC) in the dark and under red light, but not under the other light conditions tested, indicating that auxin sensitivity is involved in the elongation of hypocotyls only in these conditions. Similarly, the auxin transport inhibitor naphthylphthalamic [correction of naphtylphtalamic] acid (NPA) differentially affects elongation of dark- or light-grown hypocotyls of the MoneyMaker (MM) tomato wild type. Using different photomorphogenic mutants, we demonstrate that at least phytochrome A, phytochrome B1 and, to a much lesser extent [correction of extend], cryptochrome 1, are necessary for a switch from an auxin transport-dependent elongation of hypocotyls in the dark to an auxin transport-independent elongation in the light. Interestingly, the dgt mutant and NPA-treated seedlings exhibit a looped phenotype only under red light, indicating that the negative gravitropism of hypocotyls also differentially involves auxin in the various light conditions.     

Arabidopsis SMALL AUXIN UP RNA63 promotes hypocotyl and stamen filament elongation

Auxin regulates plant growth and development in part by activating gene expression. Arabidopsis thaliana SMALL AUXIN UP RNAs (SAURs) are a family of early auxin-responsive genes with unknown functionality. Here, we show that transgenic plant lines expressing artificial microRNA constructs (aMIR-SAUR-A or -B) that target a SAUR subfamily (SAUR61-SAUR68 and SAUR75) had slightly reduced hypocotyl and stamen filament elongation. In contrast, transgenic plants expressing SAUR63:GFP or SAUR63:GUS fusions had long hypocotyls, petals and stamen filaments, suggesting that these protein fusions caused a gain of function. SAUR63:GFP and SAUR63:GUS seedlings also accumulated a higher level of basipetally transported auxin in the hypocotyl than did wild-type seedlings, and had wavy hypocotyls and twisted inflorescence stems. Mutations in auxin efflux carriers could partially suppress some SAUR63:GUS phenotypes. In contrast, SAUR63:HA plants had wild-type elongation and auxin transport. SAUR63:GFP protein had a longer half-life than SAUR63:HA. Fluorescence imaging and microsomal fractionation studies revealed that SAUR63:GFP was localized mainly in the plasma membrane, whereas SAUR63:HA was present in both soluble and membrane fractions. Low light conditions increased SAUR63:HA protein turnover rate. These results indicate that membrane-associated Arabidopsis SAUR63 promotes auxin-stimulated organ elongation.     

Effects of ethylene, kinetin, and calcium on growth and wall composition of pea epicotyls

Ethylene supplied with indoleacetic acid at 0.1 and 1 mum inhibited elongation and enhanced swelling in epicotyls of decapitated and derooted pea seedlings (Pisum sativum L., var. Alaska). These growth responses were correlated with the development of cell walls rich in weak acid-extractable materials and pectic uronic acids. Ethylene had no effect on the formation of hemicellulose, or hemicellulosic uronic acid. Ethylene stimulated the formation of residual materials at 0.1 mum indoleacetic acid but had little effect at 1 mum. With indoleacetic acid at 10 mum, ethylene modified neither the growth or wall composition appreciably. Growth and wall composition in intact seedlings were modified in similar fashion by ethylene. In intact seedlings ethylene promoted the development of walls high in weak acid-extractable materials and pectic uronic acid. These effects were less impressive in the first 24 hours than in the second 24 hours when the control plants suffered a net loss of these constituents. Ethylene considerably inhibited the formation of hemicellulose and residual wall materials in the apical sections but promoted it in the basal sections of the intact seedlings.Measurements of ethylene production by decapitated and derooted pea seedlings suggest that Ca(2+) and kinetin do not promote swelling through an effect on the formation of ethylene.We propose that cells of ethylene-treated pea epicotyls lack polarity because their walls are abnormally rich in pectic substances.     

Promotion of Xyloglucan Metabolism by Acid pH

Like indoleacetic acid, buffers of acidic pH, which stimulate elongation of pea (Pisum sativum var. Alaska) stem tissue, induce the appearance within the tissue of a watersoluble xyloglucan polymer that probably arises from previously deposited wall material. Neutral pH buffers, which inhibit the elongation response to indoleacetic acid in this tissue, inhibit indoleacetic acid-induced increase in soluble xyloglucan. The findings provide further evidence that release of soluble xyloglucan from the cell walls of pea results from the biochemical action on the cell wall that is responsible for wall extension. The data also indicate that treatment of tissue with either auxin or acidic pH has a similar biochemical effect on the cell wall. This is consistent with the H⁺ secretion theory of auxin action.     

Mutations in the Diageotropica (Dgt) gene uncouple patterned cell division during lateral root initiation from proliferative cell division in the pericycle

In angiosperms, root branching requires a continuous re-initiation of new root meristems. Through some unknown mechanism, in most eudicots pericycle cells positioned against the protoxylem change identity and initiate patterned division, leading to formation of lateral root primordia that further develop into lateral roots. This process is auxin-regulated. We have observed that three mutations in the Diageotropica (Dgt) gene in tomato prevent primordium formation. Detailed analysis of one of these mutants, dgt1-1, demonstrated that the mutation does not abolish the proliferative capacity of the xylem-adjacent pericycle in the differentiated root portion. Files of shortened pericycle cells found in dgt1-1 roots were unrelated to primordium formation. Auxin application stimulated this unusual proliferation, leading to formation of a multi-layered xylem-adjacent pericycle, but did not rescue the primordium formation. In contrast to wild type, auxin could not induce any cell divisions in the pericycle of the most distal dgt1-1 root-tip portion. In wild-type roots, the Dgt gene promoter was expressed strongly in lateral root primordia starting from their initiation, and on auxin treatment was induced in the primary root meristem. Auxin level and distribution were altered in dgt1-1 root tissues, as judged by direct auxin measurements, and the tissue-specific expression of an auxin-response reporter was altered in transgenic plants. Together, our data demonstrate that the Dgt gene product, a type-A cyclophilin, is essential for morphogenesis of lateral root primordia, and that the dgt mutations uncouple patterned cell division in lateral root initiation from proliferative cell division in the pericycle.     

葡萄SAUR基因家族鉴定与生物信息学分析

为了研究葡萄早期应答生长素基因SAUR(Small auxin-up RNA)家族,本研究利用全基因组信息鉴定了葡萄64个SAUR家族成员,并对SAUR家族成员的基因结构、氨基酸特性、染色体定位、基因进化、基因功能以及组织表达进行分析。结果表明,葡萄全基因组上64个SAUR家族成员在19条染色体中的8条染色体上呈现簇状分布,主要分布在3、4号染色体上,其中3号染色体上数量最多为37个;葡萄SAUR家族基因长度较短,有59个基因是无内含子基因;蛋白理化特征分析显示,多数SAUR蛋白呈碱性,结构稳定性较差,蛋白脂溶指数高,呈亲水性;基因功能预测结果表明,葡萄SAUR基因主要担当生长因子、结构蛋白、转录、转录调控以及响应胁迫应答和免疫应答6种功能,其中更多参与生长调节功能;根据系统进化分析将其分为10个分支,另外不同组织表达谱的分析结果表明SAUR基因家族成员具有不同的组织表达模式,对于非生物胁迫具有一定的调节作用。这些信息为葡萄SAUR基因家族功能分析奠定了一定的工作基础。     

Effects of calcium and kinetin on growth and cell wall composition of pea epicotyls

Kinetin and CaCl₂, in the presence of indoleacetic acid, promoted lateral expansion of epicotyls of decapitated and derooted Alaska pea seedlings (Pisum sativum L.) and inhibited their elongation. This growth response was correlated with the development of cell walls unusually rich in pectic uronic acids. Epicotyls in calcium-auxin solutions continued to enlarge and to add new wall material long after tissues in auxin only had stopped. Longitudinal enlargement, associated with the development of walls poor in pectic uronic acids, was favored by KCl, MgCl₂, and ethylenediaminetetraacetate. The last of these agents promoted the loss of ⁴⁵Ca from the epicotyls. Seedings grown in vermiculite moistened with CaCl₂, KCl, or MgCl₂ solutions did not differ in appearance or in the composition of their walls. They responded similarly to experimental treatment except that the decapitated epicotyls of the MgCl₂-grown plants suffered an absolute loss of pectic uronate when incubated in that salt.     

Effect of gibberellic Acid on elongation and longevity of coleus petioles

The effects of gibberellic acid on the longevity and elongation of variously aged, debladed petioles of Coleus blumei were studied, with particular reference to the hypotheses 1) that auxin increases longevity by increasing growth, and 2) that gibberellic acid acts by increasing the endogenous levels of auxin.

Gibberellic acid, substituted for the leaf blades, significantly decreased longevity of younger petioles, as measured by days or hours to abscission. Gibberellic acid also decreased the longevity resulting from 0.1% indoleacetic acid. This is the opposite of the effect expected if it is increasing auxin levels in the petiole.

In its effect on elongation of younger petioles, however, gibberellic acid did act in the direction expected if it were increasing effective levels of auxin in the petiole. The elongation rate from 0.1% gibberellic acid plus 0.1% indoleacetic acid in lanolin was as large or larger than that for 1.0% indoleacetic acid.

Petioles which were 10 or more weeks old (i.e., at positions 5+ below the apical bud were not affected by 0.1% gibberellic acid in either longevity or rate of elongation, with or without 0.1% indoleacetic acid. Since 1.0% indoleacetic acid increases both longevity and elongation rate of these petioles over 0.1% indoleacetic acid, gibberellic acid is clearly not acting on older petioles as if it were increasing effective auxin levels).

     

Genetic evidence for auxin involvement in arbuscular mycorrhiza initiation

? Formation of arbuscular mycorrhiza (AM) is controlled by a host of small, diffusible signaling molecules, including phytohormones. To test the hypothesis that the plant hormone auxin controls mycorrhiza development, we assessed mycorrhiza formation in two mutants of tomato (Solanum lycopersicum): diageotropica (dgt), an auxin-resistant mutant, and polycotyledon (pct), a mutant with hyperactive polar auxin transport. ? Mutant and wild-type (WT) roots were inoculated with spores of the AM fungus Glomus intraradices. Presymbiotic root-fungus interactions were observed in root organ culture (ROC) and internal fungal colonization was quantified both in ROC and in intact seedlings. ? In ROC, G. intraradices stimulated presymbiotic root branching in pct but not in dgt roots. pct roots stimulated production of hyphal fans indicative of appressorium formation and were colonized more rapidly than WT roots. By contrast, approaching hyphae reversed direction to grow away from cultured dgt roots and failed to colonize them. In intact seedlings, pct and dgt roots were colonized poorly, but development of hyphae, arbuscules, and vesicles was morphologically normal within roots of both mutants. ? We conclude that auxin signaling within host roots is required for the early stages of AM formation, including during presymbiotic signal exchange.     

Hydroxyproline-rich cell wall protein (extensin): role in the cessation of elongation in excised pea epicotyls

The synthesis and accumulation of cell wall hydroxyproline increases coincident with the cessation of elongation growth in pea epicotyls. We examined the relationship between these biochemical and physiological events by using epicotyl sections challenged with α, α′-dipyridyl. This chelator blocked hydroxyproline biosynthesis without affecting overall protein synthesis. Epicotyl sections mimicked elongation growth in situ when placed in indoleacetic acid. Elongation was blocked by the addition of benzimidazole or Ethrel. These latter compounds acted independently as judged by their kinetics of action and the inhibition of Ethrel's effect only by CO₂.During rapid elongation growth in indoleacetic acid, there was no increase in cell wall hydroxyproline. However, incubation in either growth-inhibitory agent increased hydroxyproline 3-fold. When this increase was blocked by dipyridyl incubation, growth was not inhibited in benzimidazole or Ethrel, but proceeded at the maximal rate. During long-term incubations in buffer, cell wall hydroxyproline increased and the sections eventually became unable to grow. However, if dipyridyl was added to block the hydroxyproline increase, growth potential remained. Elongation was inhibited by supraoptimal concentrations of indoleacetic acid. However, such inhibition did not occur in the presence of dipyridyl.These results indicate that an hydroxyproline-containing component is necessary in rendering the cell wall inextensible when elongation growth ceases.     

Ethylene plays multiple nonprimary roles in modulating the gravitropic response in tomato.

Ethylene is known to interact with auxin in regulating stem growth, and yet evidence for the role of ethylene in tropic responses is contradictory. Our analysis of four mutants of tomato (Lycopersicon esculentum) altered in their response to gravity, auxin, and/or ethylene revealed concentration-dependent modulation of shoot gravitropism by ethylene. Ethylene inhibitors reduce wild-type gravicurvature, and extremely low (0.0005-0.001 microliter L-1) ethylene concentrations can restore the reduced gravitropic response of the auxin-resistant dgt (diageotropica) mutant to wild-type levels. Slightly higher concentrations of ethylene inhibit the gravitropic response of all but the ethylene-insensitive nr (never-ripe) mutant. The gravitropic responses of nr and the constitutive-response mutant epi (epinastic) are slightly and significantly delayed, respectively, but otherwise normal. The reversal of shoot gravicurvature by red light in the lz-2 (lazy-2) mutant is not affected by ethylene. Taken together, these data indicate that, although ethylene does not play a primary role in the gravitropic response of tomato, low levels of ethylene are necessary for a full gravitropic response, and moderate levels of the hormone specifically inhibit gravicurvature in a manner different from ethylene inhibition of overall growth.     

Ethylene and auxin-induced cell growth in relation to auxin transport and metabolism and ethylene production in the semi-aquatic plant,Regnellidium diphyllum

Cell elongation in the rachis of the semiaquatic fern Regnellidium diphyllum is induced by the addition of ethylene or indoleacetic acid (IAA). Experiments with whole plants or rachis segments have shown that ethylene-induced growth requires the presence of auxin. Ethylene does not cause a modification in either endogenous auxin levels or in the extent of auxin metabolism but auxin transport is reduced. Rates of ethylene production in Regnellidium are not altered by either mechanical excitation or by the addition of auxin. A two-hormone control of cell expansion is proposed in which an initial, auxin-dependent growth event pre-conditions the cells to a further subsequent (or synchronous) ethylene-dependent growth event.Abbreviation IAA indole-3yl-acetic acid