The role of miR156/SPLs modules in Arabidopsis lateral root development

miR156 is an evolutionarily highly conserved miRNA in plants that defines an age‐dependent flowering pathway. The investigations thus far have largely, if not exclusively, confined to plant aerial organs. Root branching architecture is a major determinant of water and nutrients uptake for plants. We show here that MIR156 genes are differentially expressed in specific cells/tissues of lateral roots. Plants overexpressing miR156 produce more lateral roots whereas reducing miR156 levels leads to fewer lateral roots. We demonstrate that at least one representative from the three groups of miR156 targets SQUAMOSA PROMOTER BINDING PROTEIN‐LIKE (SPL) genes: SPL3, SPL9 and SPL10 are involved in the repression of lateral root growth, with SPL10 playing a dominant role. In addition, both MIR156 and SPLs are responsive to auxin signaling suggesting that miR156/SPL modules might be involved in the proper timing of the lateral root developmental progression. Collectively, these results unravel a role for miR156/SPLs modules in lateral root development in Arabidopsis.     

The role of miR156 in developmental transitions in Nicotiana tabacum

Plants undergo a series of developmental transitions during their life cycle. After seed germination, plants pass through two distinct phases: the vegetative phase in which leaves are produced and the reproductive phase in which flowering occurs. Based on the reproductive competence and morphological changes, the vegetative phase can be further divided into juvenile and adult phases. Here, we demonstrate that the difference between juvenile and adult phase of Nicotiana tabacum is characterized by the changes in leaf size, leaf shape as well as the number of leaf epidermal hairs(trichomes). We further show that miR156, an age-regulated microR NA, regulates juvenile-to-adult phase transition in N. tabacum. Overexpression of miR156 results in delayed juvenile-to-adult transition and flowering. Together, our results support an evolutionarily conserved role of miR156 in plant developmental transitions.     

Analysis of gradient-like expression of miR167 in Arabidopsis thaliana embryonic tissue

MicroRNAs (miRNAs) constitute a class of small non-coding endogenous RNAs that regulate gene expression by targeting mRNAs for degradation or translational repression. MiRNAs are intensively investigated and they have been found to be a pivotal component of developmental regulation processes. Recent studies showed the non-cell autonomous function of several miRNAs. We analyzed the accumulation pattern of selected miRNAs in Arabidopsis thaliana embryonic tissues. The majority of the investigated miRNAs showed uniform accumulation across the embryo suggesting their possible role at this developmental stage. In the case of miR167 however, we detected a gradient-like expression profile which in earlier studies has been considered to be the hallmark of the non-cell autonomous activity of miRNAs. Using reporter assay we analyzed the expression patterns of the four MIR167 precursor genes. We found that two of the precursor genes, MIR167A and MIR167B, also showed an overlapping gradient-like expression patterns in the embryo. These data indicate that in addition to non-cell autonomous activity of some miRNAs, the gradient-like expression patterns can be generated also by the specific expression characteristic of miRNA precursor genes.     

高表达miR396小分子导致拟南芥花柱头弯曲

MicroRNAs（miRNAs）是大小约21个碱基、内源、非编码的小分子RNA。以拟南芥（Arabidopsis thaliana）miR396小分子为研究对象,分别克隆到了miR396小分子的两个前体（MIR396a,MIR396b）,得到了转基因植株。通过转基因植株的遗传学研究发现,高表达miR396小分子导致转基因拟南芥的花柱头弯曲。花柱头的弯曲影响了角果的正常发育。另外,Northern杂交结果表明转基因拟南芥花部位的miR396及其前体的表达量与对照相比显著增加。这些结果表明高表达miR396小分子可以导致拟南芥花柱头弯曲。     

UV‐B radiation delays flowering time through changes in the PRC2 complex activity and miR156 levels in Arabidopsis thaliana

UV‐B is a high‐energy component of the solar radiation perceived by the plant and induces a number of modifications in plant growth and development, including changes in flowering time. However, the molecular mechanisms underlying these changes are largely unknown. In the present work, we demonstrate that Arabidopsis plants grown under white light supplemented with UV‐B show a delay in flowering time, and this developmental reprogramming is mediated by the UVR8 photoreceptor. Using a combination of gene expression analyses and UV‐B irradiation of different flowering mutants, we gained insight into the pathways involved in the observed flowering time delay in UV‐B‐exposed Arabidopsis plants. We provide evidence that UV‐B light downregulates the expression of MSI1 and CLF, two of the components of the polycomb repressive complex 2, which in consequence drives a decrease in H3K27me3 histone methylation of MIR156 and FLC genes. Modification in the expression of several flowering time genes as a consequence of the decrease in the polycomb repressive complex 2 activity was also determined. UV‐B exposure of flowering mutants supports the involvement of this complex in the observed delay in flowering time, mostly through the age pathway.     

Dual effects of miR156-targeted SPL genes and CYP78A5/KLUH on plastochron length and organ size in Arabidopsis thaliana

Leaves of flowering plants are produced from the shoot apical meristem at regular intervals, with the time that elapses between the formation of two successive leaf primordia defining the plastochron. We have identified two genetic axes affecting plastochron length in Arabidopsis thaliana. One involves microRNA156 (miR156), which targets a series of SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) genes. In situ hybridization studies and misexpression experiments demonstrate that miR156 is a quantitative, rather than spatial, modulator of SPL expression in leaf primordia and that SPL activity nonautonomously inhibits initiation of new leaves at the shoot apical meristem. The second axis is exemplified by a redundantly acting pair of cytochrome P450 genes, CYP78A5/KLUH and CYP78A7, which are likely orthologs of PLASTOCHRON1 of rice (Oryza sativa). Inactivation of CYP78A5, which is expressed at the periphery of the shoot apical meristem, accelerates the leaf initiation rate, whereas cyp78a5 cyp78a7 double mutants often die as embryos with supernumerary cotyledon primordia. The effects of both miR156-targeted SPL genes and CYP78A5 on organ size are correlated with changes in plastochron length, suggesting a potential compensatory mechanism that links the rate at which leaves are produced to final leaf size.     

Control of sulfate concentration by miR395-targeted APS genes in Arabidopsis thaliana

Sulfur nutrition is crucial for plant growth and development,as well as crop yield and quality.Inorganic sulfate in the soil is the major sulfur source for plants.After uptake,sulfate is activated by ATP sulfurylase,and then gets assimilated into sulfur-containing metabolites.However,the mechanism of regulation of sulfate levels by ATP sulfurylase is unclear.Here,we investigated the control of sulfate levels by miR395-mediated regulation of APS1/3/4.Sulfate was over-accumulated in the shoots of miR395 over-expression plants in which the expression of the APS1,APS3,and APS4 genes was suppressed.Accordingly,reduced expression of miR395 caused a decline of sulfate concentration.In agreement with these results,over-expression of the APS1,APS3,and APS4 genes led to the reduction of sulfate levels.Differential expression of these three APS genes in response to sulfate starvation implied that they have different functions.Further investigation revealed that the regulation of sulfate levels mediated by miR395 depends on the repression of its APS targets.Unlike the APS1,APS3,and APS4 genes,which encode plastid-localized ATP sulfurylases,the APS2 gene encodes a cytosolic version of ATP sulfurylase.Genetic analysis indicated that APS2 has no significant effect on sulfate levels.Our data suggest that miR395-targeted APS genes are key regulators of sulfate concentration in leaves.     

The role of ABC transporters in kin recognition in Arabidopsis thaliana

The ability to sense and respond to the surrounding rhizosphere including communications with neighboring plants and microbes is essential for plant survival. Recently, it has been established that several plant species including Arabidopsis thaliana have the ability to recognize rhizospheric neighbors based or their genetic identity. This study investigated the role of ABC transporters in kin recognition in A. thaliana based on previous evidence that root secretions are involved in the kin recognition response and that ABC transporters are responsible for secretion of a number of compounds. Three genes, AtPGP1, AtATH1 and AtATH10, are all implicated to be partially involved in the complex kin recognition response in A. thaliana based on this report. These findings highlight the importance of ABC transporters in understanding root secretions and plant-plant community interactions.Key words: root biology, rhizosphere, kin recognition, root secretions, Arabidopsis     

The role of AtMSH2 in homologous recombination in Arabidopsis thaliana

During homologous recombination (HR), a heteroduplex DNA is formed as a consequence of strand invasion. When the two homologous strands differ in sequence, a mismatch is generated. Earlier studies showed that mismatched heteroduplex often triggers abortion of recombination and that a pivotal component of this pathway is the mismatch repair Msh2 protein. In this study, we analysed the roles of AtMSH2 in suppression of recombination in Arabidopsis. We report that AtMSH2 has a broad range of anti-recombination effects: it suppresses recombination between divergent direct repeats in somatic cells or between homologues from different ecotypes during meiosis. This is the first example of a plant gene that affects HR as a function of sequence divergence and that has an anti-recombination meiotic effect. We discuss the implications of these results for plant improvement by gene transfer across species.