拟南芥叶边缘锯齿状突变体的分离与鉴定

叶的极性建立直接决定叶的平展性发育,极性改变导致叶形态异常,影响植物体的各种正常生理活动。利用反向遗传学方法,从拟南芥基因激活标签突变体库中分离到一个叶片边缘锯齿状表型的突变体（命名为pCB1294）,该突变体同时表现出叶表皮腺毛形态发育异常。通过TailPCR方法成功定位突变基因为At5g41663,该基因编码miR319b基因。Real time PCR显示,pCB1294突变体植株中miR319b基因的表达量是野生型（col）植株的11倍多。所得结果为进一步研究miRNA调控叶极性的分子机制和进一步分析miR319b与叶形态发生的关系奠定了基础。     

HYL1 regulates the balance between adaxial and abaxial identity for leaf flattening via miRNA-mediated pathways

HYPONASTIC LEAVES1 (HYL1) is an important regulator of microRNA (miRNA) biogenesis. Incurvature of rosette leaves in loss-of-function mutants of HYL1 implicates the regulation of leaf flatness by HYL1 via miRNA pathways. Recent studies have identified jba-1D, jaw-1D, and oe-160c, the dominant mutants of MIR166g, MIR319a, and MIR160c genes, respectively, which display three types of leaf curvature. However, it remains unclear whether or how HYL1 controls leaf flatness through the pathways mediated by these miRNAs. To define which miRNAs and target genes are relevant to the hyl1 phenotype in terms of leaf incurvature, the effects of three mutated MIRNA genes and their targets on the direction and extent of leaf curvature in hyl1 mutants were examined. The genetic analysis shows that the hyl1 phenotype is strongly rescued by jba-1D, but not by jaw-1D or oe-160c, whereas the mutant phenotypes of jba-1D, jaw-1D, or oe-160c leaves are compromised by the hyl1 allele. Expression analysis indicates that reduced accumulation of miR166, rather than of miR319a or miR160, causes incurvature of hyl1 leaves, and that miR319a-targeted TCP3 positively regulates the adaxial identity gene PHABULOSA while miR160-targeted ARF16 negatively regulates the abaxial identity gene FILAMENTOUS FLOWER. In these cases, the direction and extent of leaf incurvature are associated with the expression ratio of adaxial to abaxial genes (adaxial to abaxial ratio). HYL1 regulates the balance between adaxial and abaxial identity and modulates leaf flatness by preventing leaf incurvature, wavy margins, and downward curvature. It is concluded that HYL1 monitors the roles of miR165/166, miR319a, and miR160 in leaf flattening through the relative activities of adaxial and abaxial identity genes, thus playing an essential role in leaf development.     

Regulation of leaf morphology by microRNA394 and its target LEAF CURLING RESPONSIVENESS

The present study identified Arabidopsis miR394 and its target, an F-box (SKP1-Cullin/CDC53-F-box) gene At1g27340 (here referred to as LEAF CURLING RESPONSIVENESS, LCR), for regulation of leaf curling-related morphology. The loss-of-function lcr mutants exhibit pleiotropic defects with semi-dwarfism, altered leaf shape and a shorter stem. Overexpression of an miR394-resistant version of LCR under the 35S promoter (35S:m5LCR) and target mimicry MIM394 resulted in a curled-down leaf defect. Conversely, transgenic plants overexpressing 35S:MIR394a/b display a curled-up leaf phenotype. Detailed analyses show that there is a certain level of LCR that is optimal for leaf morphology, but lower or higher levels lead to abnormal leaf development, indicating that expression of miR394 in the leaf lamina is necessary for proper leaf morphology. Because the phytohormone auxin plays a crucial role in leaf morphogenesis and patterning, the DR5-GUS reporter gene was used to monitor the auxin response. We show that DR5 expression patterns in lcr and 35S::m5LCR plants were significantly different from those in the wild type. Also, overexpression of LCR in 35S::m5LCR plants drastically decreased the expression of the auxin-responsive genes IAA3, AXR3 and IAMT1, whereas increased expression of the genes was found in 35S::MIR394a plants. These results indicate that miR394 and its target LCR are involved in the regulation of leaf development.     

Production of transgenic pea (Pisum sativum L.) plants resistant to the herbicide pursuit

Transgenic pea (Pisum sativum L.) plants containing mutant ahas/als gene were obtained using Agrobacterium-mediated genetic transformation. Transformation has been carried out using cocultivation of pea explants with Agrobacterium tumefaciens strain lBA4404 carrying genetic vectors pCB004, pCB006 and pCB007 containing ahas/als and nptII genes. The presence of transferred genes in the genomes of transgenic plants has been confirmed by PCR analysis.     

Overexpression of microRNA319 impacts leaf morphogenesis and leads to enhanced cold tolerance in rice (Oryza sativa L.)

MicroRNA319 (miR319) family is one of the conserved microRNA (miRNA) families among diverse plant species. It has been reported that miR319 regulates plant development in dicotyledons, but little is known at present about its functions in monocotyledons. In rice (Oryza sativa L.), the MIR319 gene family comprises two members, Osa‐MIR319a and Osa‐MIR319b. Here, we report an expression pattern analysis and a functional characterization of the two Osa‐MIR319 genes in rice. We found that overexpressing Osa‐MIR319a and Osa‐MIR319b in rice both resulted in wider leaf blades. Leaves of osa‐miR319 overexpression transgenic plants showed an increased number of longitudinal small veins, which probably accounted for the increased leaf blade width. In addition, we observed that overexpressing osa‐miR319 led to enhanced cold tolerance (4 °C) after chilling acclimation (12 °C) in transgenic rice seedlings. Notably, under both 4 and 12 °C low temperatures, Osa‐MIR319a and Osa‐MIR319b were down‐regulated while the expression of miR319‐targeted genes was induced. Furthermore, genetically down‐regulating the expression of either of the two miR319‐targeted genes, OsPCF5 and OsPCF8, in RNA interference (RNAi) plants also resulted in enhanced cold tolerance after chilling acclimation. Our findings in this study demonstrate that miR319 plays important roles in leaf morphogenesis and cold tolerance in rice.     

Regulation of miR319 during cold stress in sugarcane

MicroRNAs (miRNAs) are part of a novel mechanism of gene regulation that is active in plants under abiotic stress conditions. In the present study, 12 miRNAs were analysed to identify miRNAs differentially expressed in sugarcane subjected to cold stress (4 °C). The expression of miRNAs assayed by stem–loop RT‐PCR showed that miR319 is up‐regulated in sugarcane plantlets exposed to 4 °C for 24 h. The induction of miR319 expression during cold stress was observed in both roots and shoots. Sugarcane miR319 was also regulated by treatment with abscisic acid. Putative targets of this miRNA were identified and their expression levels were decreased in sugarcane plantlets exposed to cold. The cleavage sites of two targets were mapped using a 5′ RACE PCR assay confirming the regulation of these genes by miR319. When sugarcane cultivars contrasting in cold tolerance were subjected to 4 °C, we observed up‐regulation of miR319 and down‐regulation of the targets in both varieties; however, the changes in expression were delayed in the cold‐tolerant cultivar. These results suggest that differences in timing and levels of the expression of miR319 and its targets could be tested as markers for selection of cold‐tolerant sugarcane cultivars.     

Constructing and Phenotypic Analyzing an Activation Tagging Arabidopsis Mutant Pool

Activation tagging method is an effective tool of obtaining gain of function mutant and investigating the gene function, which plays an important role in plant functional genomics study. In this paper, we used Arabidopsis Columbia wild type as material to construct an activation tagging mutant pool by Agrobacterium tumefaciens mediated transformation, the binary vector pCB260 contained two Ds elements, one GFP report gene and one basta resistance selection genes, which show more convenient and efficient to screen the transgenic plant. Until now, over ten thousand transformed plants were generated. Among them, about 50 dominant mutants with obvious phenotypes were isolated, including early or late flowering time, unmoral leaf shape and flower, sterility and thin seed capsule color. T DNA flanking sequences of ten special mutants were validated by TAIL PCR and sequencing, whose T DNA insertion fragments distributed in all five chromosomes of Arabidopsis genome, respectively.     

毛竹miR164b前体的克隆及其在叶形态建成中的功能分析

microRNA（miRNA）参与植物多种生理代谢过程,在调控植物形态建成中发挥着重要作用。miR164作为植物特有的miRNA,其主要的靶基因是NAC转录因子,参与调控植物茎、叶顶端分生组织的建立、器官的分化和植株衰老等过程。本研究以毛竹（Phyllostachys edulis（Carr.） Lehaie）为材料,从中分离出miR164b的前体序列（82 bp）,二级结构分析结果发现该前体序列能够形成稳定的茎环结构,其成熟序列（21 bp）产生于茎环结构5'端的臂上,且碱基具有较高的保守性。本研究还构建了由CaMV 35S启动,包含毛竹miR164b前体序列的植物表达载体,并转化野生型拟南芥（Arabidopsis thaliana（L.） Heynh）,获得了转基因植株。结果表明,转基因植株生长瘦弱,莲座叶数量明显减少,叶片变小且叶片边缘锯齿减少,更加光滑。实时定量PCR分析结果显示,转基因拟南芥中毛竹miR164b的表达量极显著上升,而拟南芥内源靶基因CUC1与CUC2的表达量极显著下降。表明毛竹miR164b通过调节CUC1和CUC2的表达来参与植物叶形态建成过程。研究结果可为利用miRNA开展竹子分子育种提供参考。     

miR396-targeted AtGRF transcription factors are required for coordination of cell division and differentiation during leaf development in Arabidopsis

In plants, cell proliferation and polarized cell differentiation along the adaxial-abaxial axis in the primordium is critical for leaf morphogenesis, while the temporal-spatial relationships between these two processes remain largely unexplored. Here, it is reported that microRNA396 (miR396)-targeted Arabidopsis growth-regulating factors (AtGRFs) are required for leaf adaxial-abaxial polarity in Arabidopsis. Reduction of the expression of AtGRF genes by transgenic miR396 overexpression in leaf polarity mutants asymmetric leaves1 (as1) and as2 resulted in plants with enhanced leaf adaxial-abaxial defects, as a consequence of reduced cell proliferation. Moreover, transgenic miR396 overexpression markedly decreased the cell division activity and the expression of cell cycle-related genes, but resulted in an increased percentage of leaf cells with a higher ploidy level, indicating that miR396 negatively regulates cell proliferation by controlling entry into the mitotic cell cycle. miR396 is mainly expressed in the leaf cells arrested for cell division, coinciding with its roles in cell cycle regulation. These results together suggest that cell division activity mediated by miR396-targeted AtGRFs is important for polarized cell differentiation along the adaxial-abaxial axis during leaf morphogenesis in Arabidopsis.