Overexpression of miR172 suppresses the brassinosteroid signaling defects of bak1 in Arabidopsis

BRI1-Associated Receptor Kinase 1 (BAK1) is a leucine-rich repeat serine/threonine receptor-like kinase (LRR-RLK) that is involved in multiple developmental pathways, such as brassinosteroid (BR) signaling, plant immunity and cell death control in plants. Because the roundish and compact rosette leaves of bak1 mutant plants are characteristic phenotypes for deficient BR signaling, we screened genetic suppressors of bak1 according to changes in leaf shape to identify new components that may be involved in BAK1-mediated BR signaling using the activation-tagging method. Here, we report bak1-SUP1, which exhibited longer and narrower rosette leaves and an increased BR sensitivity compared with those of bak1. Analyses of the T-DNA insertional site and the gene expression that was affected by the T-DNA insertion revealed that a microRNA, namely, miR172, over-accumulates in bak1-SUP1. Detailed phenotypic analyses of bak1-SUP1 and a single mutant in which the bak1 mutation was segregated out (miR172-D) revealed that the overexpression of miR172 promotes leaf length elongation in adult plants and increases the root and hypocotyl growth during the seedling stage compared with that of wild type plants. Taken together with its increased BR sensitivity, these results suggest that miR172 regulates vegetative growth patterns by modulating BR sensitivity as well as by the previously identified developmental phase transition.     

The Arabidopsis homeobox gene, ATHB16, regulates leaf development and the sensitivity to photoperiod in Arabidopsis

This report describes the characterisation of ATHB16, a novel Arabidopsis thaliana homeobox gene, which encodes a homeodomain-leucine zipper class I (HDZip I) protein. We demonstrate that ATHB16 functions as a growth regulator, potentially as a component in the light-sensing mechanism of the plant. Endogenous ATHB16 mRNA was detected in all organs of Arabidopsis, at highest abundance in rosette leaves. Reduced levels of ATHB16 expression in transgenic Arabidopsis plants caused an increase in leaf cell expansion and consequently an increased size of the leaves, whereas leaf shape was unaffected. Transgenic plants with increased ATHB16 mRNA levels developed leaves that were smaller than wild-type leaves. Therefore, we suggest ATHB16 to act as a negative regulator of leaf cell expansion. Furthermore, the flowering time response to photoperiod was increased in plants with reduced ATHB16 levels but reduced in plants with elevated ATHB16 levels, indicating that ATHB16 has an additional role as a suppressor of the flowering time sensitivity to photoperiod in wild-type Arabidopsis. As deduced from the response of transgenic plants with altered levels of ATHB16 expression in hypocotyl elongation assays, the gene may act to regulate plant development as a mediator of a blue light response.     

Leafy head formation of the progenies of transgenic plants of Chinese cabbage with exogenous auxin genes

The experiment was performed to evaluate the progenies of plant lines transgenic for auxin synthesis genes derived from Ri T-DNA.Four lines of the transgenic plants were self-crossed and the foreign auxin genes in plants of T5 generation were confirmed by Southern hybridization.Two lines,D1232 and D1653,showed earlier folding of expanding leaves than untransformed line and therefore had early initiation of leafy head.Leaf cuttings derived from plant of transgenic line D1653 produced more adventitious roots than the control whereas the cuttings from folding leaves had much more roots than rosette leaves at folding stage,and the cuttings from head leaves had more roots than rosette leaves at heading stage.It is demonstrated that early folding of transgenic leaf may be caused by the relatively higher concentration of auxin.These plant lines with auxin transgenes can be used for the study of hormonal regulation in differentiation and development of plant orgens and for the breeding of new variety with rapid growth trait.     

Transgenic rice plants ectopically expressing AtBAK1 are semi-dwarfed and hypersensitive to 24-epibrassinolide

Brassinosteroids (BRs) are endogenous plant hormones essential for plant growth and development. Brassinosteroid insensitive1 (BRI1)-assocaiated receptor kinase (BAK1) is one of the key components in the BR signal transduction pathway due to its direct association with the BR receptor, BRI1. Although BRI1 and its orthologs have been identified from both dicotyledonous and monocotyledonous plants, less is known about BAK1 and its orthologs in higher plants other than Arabidopsis. This article provides the first piece of evidence that AtBAK1 can greatly affect growth and development of rice plants when ectopically expressed, suggesting that rice may share similar BR perception mechanism via BRI1/BAK1 complex. Interestingly, transgenic rice plants displayed semi-dwarfism and shortened primary roots. Physiological analysis and cell morphology assay demonstrated that the observed phenotypes in transgenic plants were presumably caused by hypersensitivity to endogenous levels of BRs, different from BR insensitive and deficient rice mutants. Consistently, several known BR inducible genes were also upregulated in transgenic rice plants, further suggesting that BAK1 was able to affect BR signaling in rice. On the other hand, the transgenic plants generated by overproducing AtBAK1 may potentially have agricultural applications because the dwarfed phenotype is generally resistant to lodging, while the fertility remains unaffected.     

An indole-3-acetic acid carboxyl methyltransferase regulates Arabidopsis leaf development

Auxin is central to many aspects of plant development; accordingly, plants have evolved several mechanisms to regulate auxin levels, including de novo auxin biosynthesis, degradation, and conjugation to sugars and amino acids. Here, we report the characterization of an Arabidopsis thaliana mutant, IAA carboxyl methyltransferase1-dominant (iamt1-D), which displayed dramatic hyponastic leaf phenotypes caused by increased expression levels of the IAMT1 gene. IAMT1 encodes an indole-3-acetic acid (IAA) carboxyl methyltransferase that converts IAA to methyl-IAA ester (MeIAA) in vitro, suggesting that methylation of IAA plays an important role in regulating plant development and auxin homeostasis. Whereas both exogenous IAA and MeIAA inhibited primary root and hypocotyl elongation, MeIAA was much more potent than IAA in a hypocotyl elongation assay, indicating that IAA activities could be effectively regulated by methylation. IAMT1 was spatially and temporally regulated during the development of both rosette and cauline leaves. Changing expression patterns and/or levels of IAMT1 often led to dramatic leaf curvature phenotypes. In iamt1-D, the decreased expression levels of TCP genes, which are known to regulate leaf curvature, may partially account for the curly leaf phenotype. The identification of IAMT1 and the elucidation of its role in Arabidopsis leaf development have broad implications for auxin-regulated developmental process.     

拟南芥突变体uro的表型分析表明URO基因参与生长素调节的植物发育过程

在筛选拟南芥(ArabidopsisthalianaL.)叶突变体的过程中获得拟南芥uprightrosette(uro)突变体。uro为半显性突变体,因突变体在幼苗生长期莲座叶竖直生长而得名。对uro突变体的表型进行了详细的分析,结果表明uro突变不仅造成叶生长模式的改变,还出现多种其他异常表型。uro杂合和纯合突变体都表现出植物顶端优势的丧失,纯合突变体表现得更为严重。uro纯合突变体的一些二级分枝会被叶取代,这种叶的叶柄与叶片远轴面连接。突变体的花发育也有多种异常表型,主要表现为花瓣及雄蕊数目的改变、花器官的同源异型转化和不同花器官的融合。uro突变体茎软,细胞学水平分析表明突变体的内皮层组织发生增生,束间纤维发育及维管束分化受阻。顶端优势的丧失及维管组织的异常发育表明,URO基因可能参与生长素对植物发育的调节。pin1uro双突变体表型的分析表明,虽然双突变茎表型出现了两亲本表型的叠加,但双突变体的花却出现了新的表型,说明URO与PIN1基因在调节植物发育过程中具有部分遗传上的相互作用,这一结果进一步证明URO基因参与了生长素调节的植物发育过程。     

Ethylene regulates the timing of leaf senescence in Arabidopsis

The plant hormone ethylene influences many aspects of plant growth and development, including some specialized forms of programmed senescence such as fruit ripening and flower petal senescence. To study the relationship between ethylene and leaf senescence, etr1-1, an ethylene-insensitive mutant in Arabidopsis, was used. Comparative analysis of rosette leaf senescence between etr1-1 and wild-type plants revealed that etr1-1 leaves live approximately 30% longer than the wild-type leaves. Delayed leaf senescence in etr1-1 coincided with delayed induction of senescence-associated genes (SAGs) and higher expression levels of photosynthesis-associated genes (PAGs). In wild-type plants, exogenous ethylene was able to further accelerate induction of SAGs and decrease expression of PAGs. The extended period of leaf longevity in etr1-1 was associated with low levels of photosynthetic activity. Therefore, the leaves in etr1-1 functionally senesced even though the apparent life span of the leaf was prolonged.     

拟南芥突变体uro的表型分析表明URO基因参与生长素调节的植物发育过程

在筛选拟南芥(Arabidopsisthaliana L.)叶突变体的过程中获得拟南芥upright rosette(uro)突变体.uro为半显性突变体,因突变体在幼苗生长期莲座叶竖直生长而得名.对uro突变体的表型进行了详细的分析,结果表明:uro突变不仅造成叶生长模式的改变,还出现多种其他异常表型.uro杂合和纯合突变体都表现出植物顶端优势的丧失,纯合突变体表现得更为严重.uro纯合突变体的一些二级分枝会被叶取代,这种叶的叶柄与叶片远轴面连接.突变体的花发育也有多种异常表型,主要表现为花瓣及雄蕊数目的改变、花器官的同源异型转化和不同花器官的融合.uro突变体茎软,细胞学水平分析表明突变体的内皮层组织发生增生,束间纤维发育及维管束分化受阻.顶端优势的丧失及维管组织的异常发育表明,URO基因可能参与生长素对植物发育的调节.pin1 uro双突变体表型的分析表明,虽然双突变茎表型出现了两亲本表型的叠加,但双突变体的花却出现了新的表型,说明URO-与PIN1基因在调节植物发育过程中具有部分遗传上的相互作用,这一结果进一步证明URO基因参与了生长素调节的植物发育过程.     

The Analysis of Arabidopsis Nicotianamine Synthase Mutants Reveals Functions for Nicotianamine in Seed Iron Loading and Iron Deficiency Responses

Nicotianamine chelates and transports micronutrient metal ions in plants. It has been speculated that nicotianamine is involved in seed loading with micronutrients. A tomato (Solanum lycopersicum) mutant (chloronerva) and a tobacco (Nicotiana tabacum) transgenic line have been utilized to analyze the effects of nicotianamine loss. These mutants showed early leaf chlorosis and had sterile flowers. Arabidopsis (Arabidopsis thaliana) has four NICOTIANAMINE SYNTHASE (NAS) genes. We constructed two quadruple nas mutants: one had full loss of NAS function, was sterile, and showed a chloronerva-like phenotype (nas4x-2); another mutant, with intermediate phenotype (nas4x-1), developed chlorotic leaves, which became severe upon transition from the vegetative to the reproductive phase and upon iron (Fe) deficiency. Residual nicotianamine levels were sufficient to sustain the life cycle. Therefore, the nas4x-1 mutant enabled us to study late nicotianamine functions. This mutant had no detectable nicotianamine in rosette leaves of the reproductive stage but low nicotianamine levels in vegetative rosette leaves and seeds. Fe accumulated in the rosette leaves, while less Fe was present in flowers and seeds. Leaves, roots, and flowers showed symptoms of Fe deficiency, whereas leaves also showed signs of sufficient Fe supply, as revealed by molecular-physiological analysis. The mutant was not able to fully mobilize Fe to sustain Fe supply of flowers and seeds in the normal way. Thus, nicotianamine is needed for correct supply of seeds with Fe. These results are fundamental for plant manipulation approaches to modify Fe homeostasis regulation through alterations of NAS genes.     

拟南芥叶片数目变化突变体对营养生长时相转变的影响

拟南芥(Arabidopsis thaliana)的营养生长可以分为2个阶段: 幼龄期与成熟期。由幼龄期向成熟期的转变(VPC)与叶片的形态学特征、茎顶端分生组织(SAM)形状、远轴面表皮毛的出现以及SPL家族转录因子表达水平的变化相关。研究表明, 造成这种转变的信号来源于叶原基。该研究利用2种莲座叶数目改变了的突变体和对野生型切除叶片的方法, 分析了叶片数目对VPC的影响。结果表明, 莲座叶数目的减少推迟了VPC的发生; 而莲座叶数目增多突变体amp1-1并未使VPC的发生提前, 推测叶源信号的产生受到了光合作用的影响。