植物硼营养研究的重要进展与展望

硼是高等植物必需的矿质营养元素, 但是人们对硼行使生理功能及其分子机理的认识远落后于其它必需营养元素。近几年国际上植物硼营养的研究取得了一些重要的突破。首先是进一步明确了B-RG-II复合物的形成及其影响细胞壁结构和功能的分子机制, 并且发现B-RG-II的形成及其含量与陆生植物的进化密切相关。其次是在拟南芥中克隆了第一个植物硼转运子基因 BOR1, 并揭示了它的作用机理; 通过转基因实验证明了植物硼的高效吸收与水通道基因NIP5;1密切相关。进而通过大量的种质筛选, 从油菜、小麦、大麦及棉花等农作物中获得一批硼高效吸收利用的优异种质材料, 并开展了硼高效QTL定位和克隆。本文详细综述了以上几个方面的研究进展, 并对进一步的研究做了展望。     

植物硼营养研究的重要进展与展望

硼是高等植物必需的矿质营养元素,但是人们对硼行使生理功能及其分子机理的认识远落后于其它必需营养元素。近几年国际上植物硼营养的研究取得了一些重要的突破。首先是进一步明确了B-RG-II复合物的形成及其影响细胞壁结构和功能的分子机制,并且发现B-RG-II的形成及其含量与陆生植物的进化密切相关。其次是在拟南芥中克隆了第一个植物硼转运子基因BOR1,并揭示了它的作用机理;通过转基因实验证明了植物硼的高效吸收与水通道基因NIP5;1密切相关。进而通过大量的种质筛选,从油菜、小麦、大麦及棉花等农作物中获得一批硼高效吸收利用的优异种质材料,并开展了硼高效QTL定位和克隆。本文详细综述了以上几个方面的研究进展,并对进一步的研究做了展望。     

硼抑制植物病害作用及机制的研究进展

硼不仅是植物生长必需的营养元素,也可减少和降低植物病害的发生。本文总结了硼抑制植物病害发生的作用机制：参与植物细胞壁和膜形成,增强植物细胞稳定性;诱导植物产生系统获得性抗性;诱导植物细胞产生适量的酚类和过氧化物;抑制病原菌菌丝生长,扭曲病原菌菌丝结构形态;破坏病原茵活性氧代谢系统,加快膜脂过氧化作用;与生防菌协同控制植物病害发生等。另外,还探讨了矿质元素防治植物病害可能存在的问题以及应用前景,以期为进一步的研究提供参考。     

菌根真菌与兰科植物互作的组学研究进展

兰科植物因其具有丰富的物种多样性和重要的社会经济价值,多年来一直是植物学及生态学界的重点研究对象。菌根真菌对兰科植物的种子萌发、营养吸收和种群动态等多个方面都具有十分重要的作用,因而近年来受到越来越多的关注。探究菌根真菌与兰科植物互作的内在机制是目前兰科菌根研究的一大热点领域,同时也为兰科植物野生资源保护和种群恢复提供了许多新方法与新思路。随着新一代测序技术以及多种组学数据库的发展与建立,菌根真菌与兰科植物互作机制研究已然进入了一个全新的时代。纵观近年来的研究,通过基因组学、转录组学、蛋白质组学和代谢组学等相关技术,人们对兰科菌根共生过程中的种子萌发、营养物质转运、信号转导、宿主免疫和逆境抗性等方面的内在机制有了一定的了解。本文对近十年来国内外采用组学技术研究菌根真菌与兰科植物互作机制方面的研究成果进行了总结和梳理,并对未来该领域的研究进行了展望。     

玉米与叶际微生物组的互作遗传机制

为了解玉米(Zeamays)和其定植微生物组之间的相互作用,探究玉米与叶际微生物组之间的互作遗传机制,该研究采用数学模型量化微生物之间相互作用的4种方式:互利共生、拮抗、侵略、利他,分析230份玉米叶际微生物组数据,利用网络作图研究玉米与叶际微生物组之间的互作遗传机制。结果表明:在微生物互作网络中确定了67个中心节点微生物,通过网络作图筛选到玉米405个显著单核苷酸多态性(SNPs)位点,最终定位到23个枢纽基因,发现其在促进植物生长、抵御病原菌侵染、耐受非生物胁迫方面起到重要作用。研究结果有助于在作物遗传育种以及构建新型菌剂促进植物生长方面提供思路。     

内蒙古草原植物的营养元素特征

对内蒙古草甸草原、典型草原和荒漠草原79种主要植物的氮、钾、钙、磷、硫、铁、锌、硼、锰、铜、钼等12种营养元素的研究结果表明:1.植物体内不同营养元素含量有不同的水平。氮、钾、钙最高,其含量变化在1—10%之间;钼最低,其含量变化在0.1—3ppm 之     

植物应答非生物胁迫的代谢组学研究进展

代谢组学技术是研究植物代谢的理想平台, 通过现代检测分析技术对胁迫环境下植物中代谢产物进行定性和定量分析, 可以监测其随时间变化的规律。而各种组学平台包括基因组学、转录组学及代谢组学的整合, 更是一个强有力的工具箱, 将所获得的不同组学的信息联系起来, 有利于从整体研究生物系统对基因或环境变化的响应, 如可判断代谢物的变化是从哪一个层面开始发生的, 帮助人们揭开复杂的植物胁迫应答机制。该文对近期代谢组学技术及其与蛋白质组学、基因组学技术相结合探索植物应答非生物胁迫的研究进行了综述。代谢组学的应用, 拓展了对植物耐受非生物胁迫分子机制的认识, 开展更多这方面的研究, 再通过植物代谢组学、转录组学、蛋白质组学和基因组学整合, 有助于从整体水平上把握植物胁迫应答机制。     

植物对硼的吸收、转运及其遗传调控(综述)

硼是植物生长发育必需的一种微量营养元素,缺硼和硼毒害是国内外农业生产中普遍存在的问题,不仅影响产量,而且还会降低品质。近年来,植物的硼吸收和转运机制研究取得较大进展,从而为基因工程改良植物的缺硼和硼毒害奠定了重要基础。本文就植物对硼的吸收和转运机制以及植物对缺硼和硼毒害耐性的遗传调控研究概况进行综述。     

植物硅营养的研究进展

阐述了植物吸收硅的机理、硅与其它营养元素的关系及其对非胁迫和胁迫条件下植物生长发育的有益作用 .植物吸收硅的机制目前尚不是很清楚 ,不同植物吸收硅的方式不同 .硅可影响植物中其它营养元素的含量 .在非胁迫条件下 ,硅可促进植物的生长 ;硅也参与了植物抗病、抗虫等生物胁迫 ,以及抗金属毒害、盐害、温度胁迫、干旱、抗倒伏等非生物胁迫的反应 .目前 ,应从多种植物上深入研究硅的吸收方式与机理 ;同时 ,应该改变硅在细胞壁的沉积仅仅起增强组织机械强度作用的观点 ,而应从生理代谢调控的角度进行硅作用机制的研究 ,为生产实践中硅肥的应用奠定理论基础     

植物硅营养的研究进展

阐述了植物吸收硅的机理、硅与其它营养元素的关系及其对非胁迫和胁迫条件下植物生长发育的有益作用。植物吸收硅的机制目前尚不是很清楚,不同植物吸收硅的方式不同。硅可影响植物中其它营养元素的含量。在非胁迫条件下,硅可促进植物的生长;硅也参与了植物抗病、抗虫等生物胁迫,以及抗金属毒害、盐害、温度胁迫、干旱、抗倒伏等非生物胁迫的反应。目前,应从多种植物上深入研究硅的吸收方式与机理;同时,应该改变硅在细胞壁的沉积仅仅起增强组织机械强度作用的观点．而应从生理代谢调控的角度进行硅作用机制的研究,为生产实践中硅肥的应用奠定理论基础。     

Effects of boron deficiency and calcium supply on the calcium metabolism in tomato plant

Summary Tomato plants were grown in water-culture with a different supply of Ca (10, 100 ppm) and B (0, 0.2 ppm), and the effects of B deficiency on the translocation and subcellular distribution of Ca in tomato plants were studied by using⁴⁵CaCl₂ as a carrier of Ca. Boron deficiency slight increased the total Ca uptake by the plant and inhibited the Ca translocation to the upper leaves. The incorporation of⁴⁵Ca into the cell wall in the upper leaves was increased by B deficiency at both Ca levels. As Ca supply decreased, the distribution of⁴⁵Ca in the 1N NaCl fraction of the cell wall increased only at 0.2 ppm B. As B supply decreased, the distribution of⁴⁵Ca in the 0.6N HCl fraction increased at both Ca levels. These results suggest that B deficiency inhibit the translocation of Ca, and induce the abnormal changes of the Ca metabolism in the cell wall.     

枸杞体细胞胚发生中Ca^2＋和ATPase的超微结构定位研究

研究2,4-D诱导枸杞体细胞胚发生中的作用及其与Ca^2 含量和ATPase活性时空分布动态之间的关系,以探讨2,4-D诱导植物体细胞胚发生的作用机理。采用超微细胞化学定位的方法,跟踪分析了体细胞胚发生与发育的不同时期,Ca^2 和ATPase活性的时空分布动态。结果表明：2,4-D是诱导离体培养的枸杞体细胞进入胚胎状态的关键激素。在含有2,4-D和不含2,4-D的培养条件下,分别诱导枸杞体细胞脱分化后,再转入除去2,4-D的MS培养基上,进行分化培养,结果前者可分化形成体细胞胚,因而称为胚性愈伤组织。后者在相同条件却不能分化形成胚,故称为非胚性愈伤组织。在2,4-D诱导枸杞的胚性愈伤组织中,胚性细胞分化早期的细胞间隙和细胞壁上均有Ca^2 沉淀。随着胚性细胞的分化、分裂和多细胞原胚形成,这时Ca^2 在细胞内的分布主要集中在细胞膜和液泡膜上;球形胚期在细胞核中Ca^2 呈弥散性分布。在此过程中,ATPase活性时空分布与Ca^2 的定位变化具有高度一致性,仅仅稍滞后于Ca^2 出现的时间。而在胚性细胞分化早期,ATPase活性同样位于质膜上,随后在液泡和细胞核都可见ATPase活性分布。而在非胚性愈伤组织中,则未见Ca^2 和ATPase活性呈时空动态分布,而且随着非胚性细胞的液泡化,无论是Ca^2 含量,还是ATPase活性都呈逐渐降低的趋势。表明Ca^2 和ATPase活性变化与2,4-D诱导的胚性细胞分化和发育密切相关。并由此推测,Ca^2 和ATPase的时空分布对胚性细胞分化中的信息传递和调控相关基因表达起着关键性作用。     

Cell wall proteomics contributes to explore the functional proteins of Brachypodium distachyon grains

The plant cell wall is the first barrier in response to external stimuli and cell wall proteins (CWPs) can play an important role in the modulation of plant growth and development. In the past 10 years, the plant cell wall proteomics has increasingly become a very active research filed, which provides a broader understanding of CWPs for people. The cell wall proteome of Arabidopsis, rice, and other model plants has begun to take shape, and proteomic technology has become an effective way to identify the candidate functional CWPs in large scale. The challenging work of Francin‐Allami et al. (Proteomics 2015, 15, 2296–2306) is a vital step toward building the most extensive cell wall proteome of a monocot species. They identified 299 cell wall proteins in Brachypodium distachyon grains, and also compared the grain cell wall proteome with those of B. distachyon culms and leaves, which provides a new perspective for further explaining the plant cell wall structures and remodeling mechanism.     

枸杞体细胞胚发生中Ca2+和ATPase的超微结构定位研究

研究2,4-D诱导枸杞体细胞胚发生中的作用及其与Ca~(2+)含量和ATPase活性时空分布动态之间的关系,以探讨2,4-D诱导植物体细胞胚发生的作用机理。采用超微细胞化学定位的方法,跟踪分析了体细胞胚发生与发育的不同时期,Ca~(2+)和ATPase活性的时空分布动态。结果表明:2,4-D是诱导离体培养的枸杞体细胞进入胚胎状态的关键激素。在含有2,4-D和不含2,4-D的培养条件下,分别诱导枸杞体细胞脱分化后,再转入除去2,4-D的MS培养基上,进行分化培养,结果前者可分化形成体细胞胚,因而称为胚性愈伤组织。后者在相同条件却不能分化形成胚,故称为非胚性愈伤组织。在2,4-D诱导枸杞的胚性愈伤组织中,胚性细胞分化早期的细胞间隙和细胞壁上均有Ca~(2+)沉淀。随着胚性细胞的分化、分裂和多细胞原胚形成,这时Ca~(2+)在细胞内的分布主要集中在细胞膜和液泡膜上;球形胚期在细胞核中Ca~(2+)呈弥散性分布。在此过程中,ATPase活性时空分布与Ca~(2+)的定位变化具有高度一致性,仅仅稍滞后于Ca~(2+)出现的时间。而在胚性细胞分化早期,ATPase活性同样位于质膜上,随后在液泡和细胞核都可见ATPase活性分布。而在非胚性愈伤组织中,则未见Ca~(2+)和ATPase活性呈时空动态分布,而且随着非胚性细胞的液泡化,无论是Ca~(2+)含量,还是ATPase活性都呈逐渐降低的趋势。表明Ca~(2+)和ATPase活性变化与2,4-D诱导的胚性细胞分化和发育密切相关。并由此推测,Ca~(2+)和ATPase的时空分布对胚性细胞分化中的信息传递和调控相关基因表达起着关键性作用。     

Boron deficiency in cultured pine cells : quantitative studies of the interaction with ca and mg

A pronounced interaction between calcium, magnesium, and boron was found in growth studies with Pinus radiata cell cultures. Quantitative isoactivity data for the interaction was analyzed in terms of selected simple and plausible theoretical models. The data was found to be consistent with a model in which a critical acceptor molecule is activated only by binding both Ca and B at separate sites; Mg competitively displaces Ca to inactivate the acceptor. It was found that B is, surprisingly, not bound strongly (K_diss = 450 ± 80 micromolar) and that the affinity for Ca is two orders of magnitude stronger than for Mg. Therefore only a small proportion of the acceptor will be boronated under natural conditions. Moderate levels of mannitol were found to aggravate B deficiency due to its effective removal by direct chemical complexation. At higher concentrations of mannitol (or other sugars), where osmotic contribution is significant, little B was needed to overcome growth inhibition—a result consistent with B having a primary role in cell wall biosynthesis.     

Formation of plant cell wall supramolecular structure

Plant cell wall is an example of a widespread natural supramolecular structure: its components are considered to be the most abundant organic compounds renewable by living organisms. Plant cell wall includes numerous components, mainly polysaccharidic; its formation is largely based on carbohydrate-carbohydrate interactions. In contrast to the extracellular matrix of most other organisms, the plant cell compartment located outside the plasma membrane is so structured that has been named “wall”. The present review summarizes data on the mechanisms of formation of this supramolecular structure and considers major difficulties and results of research. Existing approaches to the study of interactions between polysaccharides during plant cell wall formation have been analyzed, including: (i) characterization of the structure of natural polysaccharide complexes obtained during cell wall fractionation; (ii) analysis of the interactions between polysaccharides “at mixing in a tube”; (iii) study of the interactions between isolated individual plant cell wall matrix polysaccharides and microfibrils formed by cellulose-synthesizing microorganisms; and (iv) investigation of cell wall formation and modification directly in plant objects. The key stages in formation of plant cell wall supramolecular structure are defined and characterized as follows: (i) formation of cellulose microfibrils; (ii) interactions between matrix polysaccharides within Golgi apparatus substructures; (iii) interaction between matrix polysaccharides, newly secreted outside the plasma membrane, and cellulose microfibrils during formation of the latter; (iv) packaging of the formed complexes and individual polysaccharides in cell wall layers; and (v) modification of deposited cell wall layers.     

Ionic signaling in plant responses to gravity and touch

Touch and gravity are two of the many stimuli that plants must integrate to generate an appropriate growth response. Due to the mechanical nature of both of these signals, shared signal transduction elements could well form the basis of the cross-talk between these two sensory systems. However, touch stimulation must elicit signaling events across the plasma membrane whereas gravity sensing is thought to represent transformation of an internal force, amyloplast sedimentation, to signal transduction events. In addition, factors such as turgor pressure and presence of the cell wall may also place unique constraints on these plant mechanosensory systems. Even so, the candidate signal transduction elements in both plant touch and gravity sensing, changes in Ca2+, pH and membrane potential, do mirror the known ionic basis of signaling in animal mechanosensory cells. Distinct spatial and temporal signatures of Ca2+ ions may encode information about the different mechanosignaling stimuli. Signals such as Ca2+ waves or action potentials may also rapidly transfer information perceived in one cell throughout a tissue or organ leading to the systemic reactions characteristic of plant touch and gravity responses. Longer-term growth responses are likely sustained via changes in gene expression and asymmetries in compounds such as inositol-1,4,5-triphosphate (IP3) and calmodulin. Thus, it seems likely that plant mechanoperception involves both spatial and temporal encoding of information at all levels, from the cell to the whole plant. Defining this patterning will be a critical step towards understanding how plants integrate information from multiple mechanical stimuli to an appropriate growth response.     

植物与病原真菌互作机制研究进展

植物与病原真菌之间的互作是当今植物病理学研究的热点问题之一,相关的研究有望为植物抗病机制的解析和抗病品种的选育奠定理论基础。我们从形态、细胞、生理生化和分子等水平综述了植物与病原真菌互作机制的研究进展。     

The effect of calmodulin on histamine release in the rat peritoneal mast cell

To investigate the role of the Ca2+-binding protein calmodulin on histamine release in the rat peritoneal mast cell, we exposed cells to exogenous calmodulin in the presence of a variety of histamine secretagogues. Histamine release stimulated by compound 48/80, polymyxin B and ionophore A23187 was inhibited while concanavalin A-stimulated release was not affected. Calmodulin in the presence of the secretagogues did not affect cell viability and calmodulin alone had no effect on histamine release. No direct interaction between calmodulin and the secretagogues was observed. Exogenous calmodulin does not appear to be incorporated into the cell. The inhibition of histamine release by calmodulin can be explained as a labile interaction between the protein and the cell that requires externally-bound Ca2+. These experiments demonstrate the use of exogenous calmodulin as a probe in the study of the mechanism of histamine release.     

Influence of boron and calcium on the tolerance to salinity of nitrogen-fixing pea plants

The effects of different levels of B (from 9.3 to 93 M B) and Ca (from 0.68 to 5.44 mM Ca) on plant development, nitrogen fixation, and mineral composition of pea (Pisum sativum L. cv. Argona) grown in symbiosis with Rhizobium leguminosarum bv. viciae 3841 and under salt stress, were analysed. The addition of extra B and extra Ca to the nutrient solution prevented the reduction caused by 75 mM NaCl of plant growth and the inhibition of nodulation and nitrogen fixation. The number of nodules recovered by the increase of Ca concentration at any B level, but only nodules developed at high B and high Ca concentrations could fix nitrogen. Addition of extra B and Ca during plant growth restored nodule organogenesis and structure, which was absolutely damaged by high salt. The increase in salt tolerance of symbiotic plants mediated by B and Ca can be co-related with the recovery of the contents of some nutrients. Salinity produced a decrease of B and Ca contents both in shoots and in nodulated roots, being increased by the supplement of both elements in the nutrient solution. Salinity also reduced the content in plants of other nutrients important for plant development and particularly for symbiotic nitrogen fixation, as K and Fe. A balanced nutrition of B and Ca (55.8 M B, 2.72 mM Ca) was able to counter-act the deficiency of these nutrients in salt-stressed plants, leading to a huge increase in salinity tolerance of symbiotic pea plants. The necessity of nutritional studies to successfully cultivate legumes in saline soils is discussed and proposed.