microRNA在玉米生长发育及非生物胁迫响应中的调控功能

microRNA（miRNA）是一类广泛存在于真核生物中长度为20~24 nt的内源非编码小RNA，它们通过对靶基因mRNA进行切割或翻译抑制，在转录后水平调控靶基因的表达。近期研究表明，miRNA参与植物生长发育与逆境胁迫响应的多个重要生物学过程，对作物的农艺性状也起到重要的调控作用。玉米作为重要的粮食、饲料和工业原料，提高其产量和品质对于保障世界粮食安全至关重要，然而与模式植物拟南芥和水稻相比，玉米中miRNA的研究仍然相对较少，理解miRNA在玉米中的功能和调控机理有助于通过分子育种对关键农艺性状进行遗传改良。本文综述了玉米中miRNA的发现与鉴定，系统总结了参与玉米miRNA代谢途径的关键蛋白DCL、AGO和HEN1的研究进展，重点阐述了在玉米生长发育和非生物胁迫响应过程中已开展功能研究miRNA的调控作用，并对玉米miRNA研究当前存在的问题和未来的发展趋势进行了讨论。     

植物小肽信号生物学功能及其在作物改良中研究进展

作为植物体内一类重要的信号分子,小肽在飞摩尔(fmol)级的浓度下被相应的细胞质膜类受体激酶识别并结合,开启小肽-受体介导的细胞间信号转导过程,从而调控植物干细胞的生长与增殖,调节根、茎、叶、花和果实等多种植物器官的发育,协调植物响应生物和非生物胁迫等多种生理过程。随着研究的不断深入,越来越多的报道揭示了小肽在水稻(Oryza sativa)、玉米(Zea mays)、马铃薯(Solanum tuberosum)及番茄(Solanum lycopersicum)等多种作物农艺性状中的重要调控功能,暗示着小肽信号在作物遗传改良中的巨大应用潜力。本文系统总结了小肽-受体介导的信号转导模式在植物中的生物学功能及分子机制,重点综述了小肽在调控作物产量、品质和抗性等重要农艺性状中的研究进展,并讨论了小肽信号应用于作物育种改良的策略,最后提出了小肽研究的未来方向。     

RNA调控与作物农艺性状改良

具有重要育种价值的基因资源挖掘与功能研究对于现代农业育种应用至关重要.已有大量研究显示,核糖核酸(ribonucleic acid, RNA)在多种植物的生长发育和环境信号应答中发挥重要作用,是调控多种农作物与经济作物复杂农艺性状的重要基因资源.本文综述了小RNA和长链非编码RNA的生成代谢和功能机制,着重介绍了小RNA、长链非编码RNA及其RNA修饰在调控作物产量与品质、抗病与抗逆等方面的研究进展.同时介绍了利用RNA技术改良遗传性状的研究,并展望了RNA技术的开发与利用对于未来农业生物技术应用的重要意义.     

分离植物基因

通过遗传转化,按人们的意愿、有目的改良作物的农艺性状,现已成为可能。目前,该技术在实际应用中因缺少控制重要农艺性状的克隆基因受到了限制。近期,图谱克隆、插入突变、大片段cDNA测序等植物基因鉴定和分离技术的发展,大大提高了分离基因的效率,这为遗传工程在作物改良中的利用提供了更多的机会。 自然界没有作物完全适合人类的需要。所以,在作物改良过程中,育种学家很自然将育种目标集中在培育抗病、抗逆、高产、优质及合理株型等更适合于人类需要的性状改良方面。另外,有些能生产对人类有用产品的植物却不大适合大面积种植。因此将生产这些有用产品的能力转移进适于现代农业耕种的植物     

主编导读

<正>本期主编导读主题：重要农艺性状功能基因及植物-微生物互作机制、病毒检测及疫苗研究、微生物与环境、多方位及混合式教学模式。重要农艺性状功能基因及植物-微生物互作机制阐明作物重要农艺性状分子控制的机理,以及植物-微生物(包括有益微生物和病原微生物)互作机制,能够为分子改良和设计重要农艺性状奠定理论基础,进而推动我国育种科学的可持续发展。     

赤霉素生物合成与信号传递对植物株高的调控

植物株高是影响作物产量和品质的重要农艺性状。赤霉素(Gibberellins,GAs)是调控植物株高的重要激素,GA相关株高基因的克隆与分子机制研究对于合理调控作物生长发育和农业生产具有极其重要的利用价值,在水稻、小麦等粮食作物育种中得到了广泛应用。为了促进GA在果树、花卉等园艺作物育种中的有效利用,文中在分子生物学水平上介绍GA生物合成和GA信号传递途径对植物株高的调控。     

突破复杂性状多基因转化技术壁垒,首创胚乳花青素高积累的水稻新种质

随着转基因技术的日趋成熟,利用生物工程手段加快改良作物农艺性状,已经越来越显示出其巨大的应用潜力。在改良多基因调控的复杂农艺性状方面,单基因转化收效甚微,而长期以来多基因转化不仅受限于技术因素,而且在协调表达调控、代谢及修饰等一系列相关基因方面更是难于突破。近期,我国科学家首次利用自创的多基因垛叠表达系统,成功在水稻(Oryza sativa)胚乳中合成了具有抗氧化活性的花青素,在复杂性状多基因转化领域取得了突破性进展。     

泛素-蛋白酶体系统影响植物农艺性状的研究进展

当前人口激增、环境污染、生态破坏等问题层出不穷。改良农艺性状,如提高产量、增强逆境耐受能力,是作物遗传改良的重要目标,是推动农业高质量发展的基础。泛素-蛋白酶体系统（UPS）是一种快速的选择性水解植物体产生的冗余蛋白和被损坏蛋白的体系。目前,研究发现泛素-蛋白酶系统影响植物的发育、生殖和重要的农艺性状：如应对环境胁迫、开花诱导和种子大小等。综述了近年来的研究成果,阐述了蛋白酶体UPS组分和各亚基的重要功能,并描述了泛素-蛋白酶系统是如何影响植物农艺性状的。最后,讨论了未来的研究热点和利用UPS改良作物的潜力。     

miRNA在植物病原调控方面的研究进展

miRNA是一类在真核生物体内普遍存在的,长度在22 nt左右的单链小RNA分子。大量研究发现,miRNA可广泛参与植物的生长发育、新陈代谢、物质运输、逆境响应及病原防御等多种生理生化过程。目前已经从植物中鉴定到大量的miRNA,但其中参与植物病原调控相关miRNA的研究较少。miRNA作为一种重要的转录调控因子,可参与调控病原相关分子模式触发的免疫反应和效应因子触发的免疫反应。拟南芥中,miRNA393通过靶向生长素受体基因对植物生长素进行负调控,从而在抵御细菌侵染方面发挥作用;水稻中,miRNA528可响应水稻条纹病毒(RSV)的侵染,人为提高miRNA528水平有助于维持水稻对RSV的抗性。阐述了miRNA的作用机制,与植物细菌、真菌和病毒侵染相关的miRNA研究进展,总结了葡萄,苹果,梨和桃等具有重要经济价值果树中病原调控相关miRNA研究情况,旨在为今后miRNA在植物,特别是在果树抗病研究方面提供全面的理论依据。     

MicroRNA调控造血干细胞发育

造血干细胞是目前研究最为深入的成体干细胞,是极富应用前景的研究领域,然而其维持自我更新以及多向分化潜能的分子机制尚不明.MicroRNA (miRNA)是一类崭新的调控性非编码小分子RNA,在监控生物体个体发育和细胞增殖、分化进程中起着重要作用.miRNA参与包括胚胎干细胞和多种成体干细胞的发育进程,人类造血干细胞及其发育过程中也存在特征性miRNA表达谱,参与调控造血干细胞发育进程,以miRNA为分子靶点的防治造血功能低下疾患的研究具有广阔的应用前景.     

Prediction and validation of conservative microRNAs of <Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.

Potato (Solanum tuberosum) is an important crop around the world, and accounts for a significant amount of the food consumed by humans. However, little information is available about potato miRNAs which play important regulatory roles in plant growth and development. In the present study, computational prediction of potential miRNAs from potato revealed 71 miRNAs belonging to 48 families. Amongst these 71 mRNAs, 65 were predicted for the first time. Most potato miRNA families have one to three members, and sequence analysis showed that the candidate pre-miRNA sequences varied from 48 to 224 bp in length. To verify the predicted miRNAs, specific stem-loop RT primers were designed and real-time PCR assays were used to profile the expression levels of seven miRNAs from different tissues of potato. The results showed that all the selected miRNAs were successfully amplified. Most of them had their highest expression levels in leaves, and the lowest levels in the stem, while miR159 and miR164 presented a different expression pattern. The specific expression levels of each miRNAs in the tested tissues may be related to their particular functions in regulating potato vegetative growth and organ development.     

Functional Role of miRNAs: Key Players in Soybean Improvement

Soybean (Glycine max (L.) Merr) is an agro-economic crop growing across the world to cater nutrition for both human and animal feed due to the high oil and protein content in its edible seeds. The genes and QTLs associated with important agronomic traits in this crop have already been identified and validated for soybean cyst nematode (SCN), Phytophthora root and stem rot, Pythium root rot and aphid resistance, seed quality, nutrient values, and also employed for genetic improvement in soybean. In the last decade, micro RNAs (miRNAs) have been considered the effector molecules, so the detection and characterization of novel miRNAs in soybean have been taken up by several workers. The advancement in the strategy of sequencing and tools of bioinformatics during last decade has contributed to the discovery of many soybean miRNAs, thus miRNA can be used as a tool in molecular breeding studies, and this has opened new vistas for miRNA mediated genetic improvement of soybean to augment crop productivity as well as nutritional quality. This review addresses the current state of understanding of miRNAmediated stress responses, nutrient acquisition, plant development and crop production processes in soybean.     

Plant protein phosphatases 2C: from genomic diversity to functional multiplicity and importance in stress management

Protein phosphatases (PPs) counteract kinases in reversible phosphorylation events during numerous signal transduction pathways in eukaryotes. Type 2C PPs (PP2Cs) represent the major group of PPs in plants, and recent discovery of novel abscisic acid (ABA) receptors (ABARs) has placed the PP2Cs at the center stage of the major signaling pathway regulating plant responses to stresses and plant development. Several studies have provided deep insight into vital roles of the PP2Cs in various plant processes. Global analyses of the PP2C gene family in model plants have contributed to our understanding of their genomic diversity and conservation, across plant species. In this review, we discuss the genomic and structural accounts of PP2Cs in plants. Recent advancements in their interaction paradigm with ABARs and sucrose nonfermenting related kinases 2 (SnRK2s) in ABA signaling are also highlighted. In addition, expression analyses and important roles of PP2Cs in the regulation of biotic and abiotic stress responses, potassium (K⁺) deficiency signaling, plant immunity and development are elaborated. Knowledge of functional roles of specific PP2Cs could be exploited for the genetic manipulation of crop plants. Genetic engineering using PP2C genes could provide great impetus in the agricultural biotechnology sector in terms of imparting desired traits, including a higher degree of stress tolerance and productivity without a yield penalty.     

A new mechanism in plant engineering: The potential roles of microRNAs in molecular breeding for crop improvement

MicroRNAs (miRNAs) are small, endogenous, noncoding RNAs that negatively modulate the expression of genes by inhibiting translation or by promoting the degradation of target mRNAs. miRNAs are now known to have greatly expanded roles in a variety of plant developmental processes, in signal transduction, and in the response to environmental stress and pathogen invasion. Because of their ability to inactivate either specific genes or entire gene families, artificial miRNAs function as dominant suppressors of gene activity when brought into a plant. Consequently, miRNA-based manipulations have emerged as promising new approaches for the improvement of crops. This includes the development of breeding strategies and the genetic modification of agronomic traits. Herein, we highlight new findings regarding the roles of miRNAs in plant traits, and describe the current miRNA-based plant engineering approaches. Finally, we consider the feasibility of modulating current approaches to address future challenges such as breeding programs to increase crop yield.