玉米耐盐分子机制研究进展

玉米是我国总产量最大的农作物,它对盐胁迫耐受性较差.玉米主产区日益加剧的土壤盐渍化已成为导致玉米产量和品质下降的主要环境胁迫之一.因此,研究玉米的耐盐机制,改良玉米的耐盐性对保障我国乃至世界玉米生产的可持续发展有重要意义.土壤中盐浓度过高会导致玉米根系外围土壤溶液的水势降低,引起渗透胁迫,而盐离子(Na+、Cl-等)的...     

Identification of QTLs for Salt Tolerance Traits and Prebreeding Lines with Enhanced Salt Tolerance in an Introgression Line Population of Rice

Plant Molecular Biology Reporter - Salinity is a major abiotic stress that limits rice productivity worldwide. Due to involvement of multiple genes and multiple mechanisms in salinity tolerance,...     

玉米花期耐旱导入系群体的构建与评价

以黄早四X齐319回交群体（BC2F1）为试验材料,在花期进行高强度干旱胁迫和耐旱导入系筛选,获得花期耐旱性显著高于亲本材料的玉米耐旱导入系。利用分子标记对其导入片段进行分析结果表明,在全基因组范围内,耐旱群体在36．59％的位点上含有供体亲本的特异标记,尤其在第4、5染色体上分别达到63．94％、56％,显著高于群体平均值;同时发现,导入频率的提高主要集中于染色体的部分区段,其中部分基因组区域与已定位的耐旱性相关QTL相邻或重叠。     

大豆耐盐机理及相关基因分子标记

大豆耐盐涉及多种生理代谢途径.耐盐大豆能够通过Cl-排除、控制Na 的吸收和转运、合成渗透调节物质、改变细胞膜膜脂组分及相关酶类的活性等多种形式来适应盐胁迫;野生大豆群体具有盐腺,从形态结构上适应盐逆境;大豆-根瘤菌共生体在盐胁迫下通过互作来提高整体的耐盐性.分子生物学技术应用于大豆耐盐研究,已获得了一些与耐盐相关基因连锁的分子标记.广泛搜集筛选大豆栽培种和野生种资源,利用分子生物学技术和基因工程提高大豆耐盐性,将成为未来大豆耐盐研究的主要内容.     

大豆耐盐机理及相关基因分子标记

大豆耐盐涉及多种生理代谢途径。耐盐大豆能够通过Cl-排除、控制Na+的吸收和转运、合成渗透调节物质、改变细胞膜膜脂组分及相关酶类的活性等多种形式来适应盐胁迫;野生大豆群体具有盐腺,从形态结构上适应盐逆境;大豆-根瘤菌共生体在盐胁迫下通过互作来提高整体的耐盐性。分子生物学技术应用于大豆耐盐研究,已获得了一些与耐盐相关基因连锁的分子标记。广泛搜集筛选大豆栽培种和野生种资源,利用分子生物学技术和基因工程提高大豆耐盐性,将成为未来大豆耐盐研究的主要内容。     

基于染色体置换系的普通野生稻耐盐性QTL定位

本研究分别利用SSR标记、InDel标记以及简化基因组测序技术对一套以普通野生稻为供体亲本,9311为受体亲本的染色体置换系进行基因型鉴定,并通过对其不同生育期的耐盐性鉴定,共发掘2个与发芽期耐盐相关的QTL,13个与苗期耐盐性相关的QTL。其中与苗期存活率相关的QTL qSSR5.1、苗期耐盐等级相关的QTL qSSG5.1均被定位于同一位点,该位点对苗期存活率、苗期耐盐等级均具有增效作用,贡献率分别为6.36%、8.13%。在此QTL内包含与非生物胁迫相关基因OsDi19-1。经序列比对发现,OsDi19-1启动子区域在两亲本间存在较大差异,且受到盐胁迫时该基因表达量上升。同时,鉴定出水稻芽期耐盐的优异种质资源CSSL72、苗期耐盐的优异种质资源CSSL23、CSSL153,为水稻育种中耐盐性的改良提供了新的种质资源。     

ABA与植物的耐盐性

文章介绍近年来ABA与植物耐盐性的研究进展。     

Salt Tolerance in Soybean

Soybean is an Important cash crop and its productivity is significantly hampered by salt stress. High salt Imposes negative impacts on growth, nodulation, agronomy traits, seed quality and quantity, and thus reduces the yield of soybean. To cope with salt stress, soybean has developed several tolerance mechanisms, including: (I) maintenance of ion homeostasis; (ii) adjustment in response to osmotic stress; (iii) restoration of osmotic balance; and (iv) other metabolic and structural adaptations. The regulatory network for abiotic stress responses in higher plants has been studied extensively in model plants such as Arabidopsis thaliana. Some homologous components involved in salt stress responses have been identified in soybean. In this review, we tried to integrate the relevant works on soybean and proposes a working model to descdbe Its salt stress responses at the molecular level.     

Salt Tolerance in Soybean

Soybean is an Important cash crop and its productivity is significantly hampered by salt stress. High salt Imposes negative impacts on growth, nodulation, agronomy traits, seed quality and quantity, and thus reduces the yield of soybean. To cope with salt stress, soybean has developed several tolerance mechanisms, including: (I) maintenance of ion homeostasis; (ii) adjustment in response to osmotic stress; (iii) restoration of osmotic balance; and (iv) other metabolic and structural adaptations. The regulatory network for abiotic stress responses in higher plants has been studied extensively in model plants such as Arabidopsis thaliana. Some homologous components involved in salt stress responses have been identified in soybean. In this review, we tried to integrate the relevant works on soybean and proposes a working model to descdbe Its salt stress responses at the molecular level.     

Salt Tolerance ofEchinochloa crusgalli

Salt tolerance ofEchinochloa crusgalli was studied using gravel culture with root medium electrical conductivity between 3 to 25 dS m^-1. Salinity depressed germination and shoot yield. A 50 % reduction in shoot yield occurred at 15.9 dS m^-1. The plant was able to maintain its tissue water content and K concentration in the tissue water while Na, Ca and Cl increased and Mg decreased with increasing root zone salinity.     

转AtNHX1基因玉米的产生及其耐盐性分析

以玉米(ZeamaysL.)骨干自交系DH4866、齐319和鲁原16106的胚性愈伤组织为材料,采用农杆菌介导法将AtNHX1和hpt基因转入玉米培养细胞,经筛选获得了抗潮霉素的愈伤组织并再生植株。经PCR检测和Southernblot验证,确定了22.8%的再生植株为转基因植株。农杆菌液浓度、愈伤组织基因型及共培养时间对转化率均有明显影响。外源基因在转基因植株后代中的分离呈多样性,在部分株系中表现出孟德尔遗传规律。耐盐筛选表明,一些转基因植株及其后代具有很好的耐盐性,部分株系可在0.8%-1.0%NaCl溶液浇灌下萌发和生长。Northern杂交表明,植株耐盐性提高与AtNHX1基因的转录水平相一致。     

转AtNHX1基因玉米的产生及其耐盐性分析

以玉米(Zea mays L.)骨干自交系DH4866、齐319和鲁原16106的胚性愈伤组织为材料,采用农杆菌介导法将AtNHX1和hpt因转入玉米培养细胞,经筛选获得了抗潮霉素的愈伤组织并再生植株.经PCR检测和Southernblot验证,确定了22.8%的再生植株为转基因植株.农杆菌液浓度、愈伤组织基因型及共培养时间对转化率均有明显影响.外源基因在转基因植株后代中的分离呈多样性,在部分株系中表现出孟德尔遗传规律.耐盐筛选表明,一些转基因植株及其后代具有很好的耐盐性,部分株系可在0.8%-1.0%NaCl溶液浇灌下萌发和生长.Northern杂交表明,植株耐盐性提高与AtNHX1基因的转录水平相一致.     

一氧化氮与植物耐盐性

盐胁迫是制约植物生长发育的主要环境因子之一,信号分子一氧化氮（NO）参与调节植物的耐盐性,本文介绍近年来NO合成及其与植物耐盐性关系的研究进展,并讨论了NO可能的作用机制。     

Drought and Salt Tolerance in Plants

Agricultural productivity worldwide is subject to increasing environmental constraints, particularly to drought and salinity due to their high magnitude of impact and wide distribution. Traditional breeding programs trying to improve abiotic stress tolerance have had some success, but are limited by the multigenic nature of the trait. Tolerant plants such as Craterostigma plantagenium, Mesembryanthemum crystallinum, Thellungiella halophila and other hardy plants could be valuable tools to dissect the extreme tolerance nature. In the last decade, Arabidopsis thaliana, a genetic model plant, has been extensively used for unravelling the molecular basis of stress tolerance. Arabidopsis also proved to be extremely important for assessing functions for individual stress-associated genes due to the availability of knock-out mutants and its amenability for genetic transformation. In this review, the responses of plants to salt and water stress are described, the regulatory circuits which allow plants to cope with stress are presented, and how the present knowledge can be applied to obtain tolerant plants is discussed.     

Salt Tolerance and Crop Potential of Halophytes

Although they represent only 2% of terrestrial plant species, halophytes are present in about half the higher plant families and represent a wide diversity of plant forms. Despite their polyphyletic origins, halophytes appear to have evolved the same basic method of osmotic adjustment: accumulation of inorganic salts, mainly NaCl, in the vacuole and accumulation of organic solutes in the cytoplasm. Differences between halophyte and gly-cophyte ion transport systems are becoming apparent. The pathways by which Na⁺ and Cl^? enters halophyte cells are not well understood but may involve ion channels and pinocytosis, in addition to Na⁺ and Cl^? transporters. Na⁺ uptake into vacuoles requires Na⁺/H⁺ antiporters in the tonoplast and H⁺ ATPases and perhaps PP_i ases to provide the proton motive force. Tonoplast antiporters are constitutive in halophytes, whereas they must be activated by NaCl in salt-tolerant glycophytes, and they may be absent from salt-sensitive glycophytes. Halophyte vacuoles may have a modified lipid composition to prevent leakage of Na⁺ back to the cytoplasm. Becuase of their diversity, halophytes have been regarded as a rich source of potential new crops. Halophytes have been tested as vegetable, forage, and oilseed crops in agronomic field trials. The most productive species yield 10 to 20 ton/ha of biomass on seawater irrigation, equivalent to conventional crops. The oilseed halophyte, Sali-cornia bigelovii, yields 2?t/ha of seed containing 28% oil and 31% protein, similar to soybean yield and seed quality. Halophytes grown on seawater require a leaching fraction to control soil salts, but at lower salinities they outperform conventional crops in yield and water use efficiency. Halophyte forage and seed products can replace conventional ingredients in animal feeding systems, with some restrictions on their use due to high salt content and antinutritional compounds present in some species. Halophytes have applications in recycling saline agricultural wastewater and reclaiming salt-affected soil in arid-zone irrigation districts.     

新疆自然高温环境下玉米自交系开花期耐热性鉴定与评价

在新疆夏季自然高温环境下,以田间玉米空秆率、果穗结实率、相对结实率为主要评价指标,综合籽粒产量与穗部性状,对26份国内外玉米骨干自交系连续2年进行耐热性鉴定与评价,结合新疆当地高温干燥的气候特点,建立一套适宜玉米种质资源大田耐热性的鉴定、评价体系,为中国玉米耐热种质资源的遗传改良和新品种选育提供参考。结果表明:(1)不同基因型玉米自交系空秆率、果穗结穗率、相对结实率和耐热性差异较大,其中GW5F、GW4F、GW7F和PH6WC耐热性最强,在高温胁迫下空秆率最低,果穗结实率与相对结实率最高;其次为PHBA6、新自351等8份自交系,在高温胁迫下籽粒产量及综合表现较好;其余自交系对高温均表现敏感。(2)高温胁迫导致玉米穗部性状严重衰退,其中的穗重、穗行数和行粒数所受影响最大。(3)在年份或材料之间,玉米自交系籽粒产量与其主要农艺性状相关性差异较大,并以果穗重与籽粒产量相关性最高。(4)以相对结实率为主要指标通过层次聚类可将参试材料分为两大群,耐热性最强的GW5F、PH6WC、GW4M聚为第Ⅰ群,其余自交系聚为第Ⅱ群;第Ⅱ群中‘吉63’、Mo17等6份自交系可聚为第1亚群,PHBA6、LH82等6份自交系聚为第2亚群,郑58、新农育6390M等11份自交系聚为第3亚群。综合分析来看,该研究中表现极耐高温的4份自交系均为国外优异种质,可用于玉米耐高温基础研究和遗传改良;表现较强耐热性的8份品系多来自于新疆本地选育的材料,其遗传基础较为广泛,适应当地的高温环境,也是优异的耐热育种资源。     

基于水稻染色体片段代换系的耐盐发芽QTL分析

为了检测水稻种子的耐盐相关数量性状位点,也为耐盐遗传机理的研究提供理论基础,本实验以Koshihikari(受体)和Nona Bokra(供体)为亲本构建的全基因组单片段代换系(154个)作为研究群体,采用培养皿培养,在水稻种子的萌发期进行浓度为1％的盐胁迫,以种子的发芽情况为指标,统计发芽率数据,利用分子标记技术,定...     

SOS基因家族与植物耐盐性

介绍了模式植物--以南芥SOS(Salt overly sensitve)基因家族(SOS1、SOS2、SOS3、SOS4和SOS5)的发现及其遗传学和分子生物学的研究新进展.     

Na+转运体与植物的耐盐性

简要介绍Na 转运体与植物耐盐性的研究进展。