水分胁迫下冬小麦芽鞘长度与抗旱性的关系及其遗传特性的研究

研究结果表明：抗旱性不同的小麦品种低水势下芽鞘长差异显著,抗旱性强的品种芽鞘长度高于抗旱性弱的品种。分析了低水势下芽鞘长度与大田干旱条件下产量的相关性,发现低水势下芽鞘长度与旱田产量,抗旱系数的相产 达显著或极显著水平。对低水势下芽鞘长度的遗传率进行了测定,证明该指标的广义遗传率及狭义遗传率都很高,可以用这一指标在进育种早代材料中进行抗旱个体选择。认为,低水势下芽鞘长是抗旱鉴定与抗育种个体选择的良     

低水势下冬小麦胚芽鞘长度与叶片的渗透调节能力及大田产量关系的研究

本文以７个抗旱性不同的冬小麦品种（系）为材料,研究了低水势下芽鞘长度与大田干旱条件下叶片的渗透调节能力及大田产量的关系。结果表明：低水势下芽鞘长度与叶片的渗透调节能力及产量有极为密切的关系。为冬小麦抗旱鉴定及抗旱个体筛选提供了一个良好的指标。     

渗透胁迫对不同抗旱性小麦品种胚芽鞘生长的影响

20％PEG－6000作渗透介质,室内模拟干旱条件下,不同抗旱性小麦品种萌发期的胚芽鞘长度与品种的抗旱性基本一致。据此认为,低水势下穿鞘长度是冬小麦抗旱鉴定及抗旱个体选择的良好指标。     

水分胁迫条件下抗旱性不同小麦品种芽鞘生长的动态分析

提要　在３０％ＰＥＧ－６０００室内模拟干旱条件下,对抗旱性不同的４个小麦品种萌发期的胚芽鞘长度进行了测定,用Ｌｏｇｉｓｔｉｃ方程对芽鞘生长进行了模拟。对曲线参数的分析表明,水分胁迫下芽鞘生长的最快速度下降,生长最快的时间提前,最终导致芽鞘长度缩短。抗旱性强的品种生长速度下降小于抗旱性弱的品种,因而前者芽鞘最终长度长于后者。渗透调节能力强是抗旱性强的品种芽鞘较长的重要原因。     

白菜型油菜品种萌发期的抗旱性鉴定与筛选

秋旱影响我国长江流域油菜的播种和生长。从遗传基础广泛的白菜型油菜资源中筛选抗旱材料,对于培育抗旱油菜品种具有重要意义。以不同浓度的PEG-6000溶液于萌发期对5份不同遗传背景的白菜型油菜进行模拟干旱胁迫处理,并测定种子萌发抗旱指数、相对发芽率、相对发芽势、相对根长、相对芽长。与对照相比,干旱胁迫下各指标均有显著差异,对各指标进行主成分分析,确定了抗旱性鉴定参数,并确立了白菜型油菜资源抗旱性筛选的工作液为200 g/L的PEG-6000。选用该工作液于萌芽期对203份白菜型油菜资源进行了抗旱筛选,结果表明,模拟干旱胁迫下,大部分材料的抗旱性与对照有显著差异,用隶属函数法和聚类分析对抗旱性鉴定指标进行分析,并对所有供试材料的抗旱性进行了排序,鉴定出了抗旱性最强的PI226505白菜型油菜,其来源为Iran,为油菜下一步抗旱性遗传改良奠定了基础。     

谷子品种抗旱性的苗期快速鉴定

报道了在苗期快速鉴定谷子品种抗旱性的实验结果.通过比较种子在甘露醇渗透胁迫条件下的相对萌发率和芽生长抑制率、幼苗在适度控水条件下的相对含水量和水势、幼苗严重失水恢复供水后的存活率等几个指标,对5个谷子品种(鲁7060、羊角黄、豫谷5号、Jun 24和Mar 51)的苗期抗旱性进行鉴定.结果表明,Mar 51在所鉴定的品种中具有相对的抗旱优势,可以作为谷子苗期抗旱性研究的代表性材料.谷子种子在甘露醇渗透胁迫条件下的相对萌发率与幼苗在适度控水条件下相对含水量的变化趋势一致,初步认为这两个指标可以作为苗期快速鉴定谷子抗旱性的筛选指标.     

棉花花铃期抗旱性综合评价及指标筛选

以90份国内棉花为材料,在大田采用花铃期胁迫,考察6个农艺性状和单株产量(Y值)指标,采用综合抗旱系数、因子分析、隶属性函数值、聚类分析、灰色关联度和广义遗传力分析相结合的方法,对其抗旱性进行综合评价、抗旱性划分和评价指标筛选。结果表明,基于D值相关性状指标对干旱胁迫关联度位次依次为:单株产量、有效铃数、有效果枝数、株高、单铃重、衣分、第一果枝节位。因子分析表明,3个公因子可代表棉花抗旱性72.45%的原始数据信息量。基于D值和加权抗旱系数(WDC值)的各品种抗旱性排序相近,位居前10位的抗旱品种基本相同。各品种D值与综合抗旱系数(CDC值)、WDC值之间均呈极显著正相关,广义遗传率分析表明D值的遗传率为55.4%,为最高,其次为CDC值、WDC值。各品种Y值与CDC、WDC值间极显著正相关;根据D值将试验材料划分为5个抗旱级别,可较好地反映品种的选育条件及适应地区。试验结果说明基于遗传力大小的综合抗旱指标中用D值为主要参数,WDC为辅助评价参数,评价以单株产量为主要考量目标的棉花抗旱性是适宜且必须的;以抗旱性综合评价方法进行棉花抗旱性综合评价、抗旱性划分和评价指标筛选是可行且有效的。     

不同陆地棉基因型抗旱性评价与抗旱丰产种质筛选

为了鉴定陆地棉的抗旱性与丰产性,在年降雨量不足40 mm的敦煌市,设干旱胁迫和正常灌溉两个处理,通过测定102份棉花品种的15个形态与产量指标,应用相关分析的方法确定抗旱指标,采用直接抗旱鉴定评价法与综合抗旱鉴定法对其进行抗旱性评价,结果显示,棉花抗旱性综合评价应选择年际间变异较小的单铃重、株高、主茎节间长度、果枝数、单株铃数、单株产量和茎干重7个指标,基于这7个单项指标计算的综合抗旱性评价指标之间相关性较高,都能评价棉花品种的抗旱性,抗旱丰产棉花种质的筛选需要综合考虑多种因素的影响,在综合评价品种抗旱性的基础上,结合单株籽棉产量计算的改进抗旱指数和抗旱系数,可筛选出抗旱丰产品种金垦1号和金垦108,不抗旱丰产品种中21371、巴西012、石远321、冀丰1056和新陆早33号,两年鉴定结果一致,品种抗旱丰产性表现稳定,适合西北内陆棉区种植,可作为抗旱鉴定标准品种。     

用GGE双标图及隶属函数综合分析山西小麦地方品种抗旱性

以7个山西小麦地方品种和2个对照品种为试材,测定了其在大田正常供水及水分胁迫条件下的形态和生理指标,并计算各指标性状抗旱系数;再利用GGE双标图在主成分分析的基础上,分析各指标性状间的相关性及其与品种抗旱性的关系;最后利用隶属函数与抗旱指数相结合的方法对小麦品种的抗旱性进行综合评价.结果表明:影响小麦品种抗旱性的主要形态及生理指标包括穗下节长、株高、节间长、叶面积、过氧化物酶(POD)、超氧化物歧化酶(SOD)、叶片相对含水量(RWC)和相对电导率;各单项抗旱指标间存在不同程度的相关性,各指标对不同品种抗旱性的影响不同,这是造成小麦品种抗旱性差异的主要原因.依据抗旱性可将参试品种划分为3类,即抗旱型、中间型和敏感型,从中选出两个高抗旱小麦地方品种白和尚头和竹杆青,其抗旱性与对照抗旱型品种晋麦47相似,可作为小麦抗旱育种的亲本材料.     

持续水分胁迫对大豆鼓粒期抗旱性及籽粒品质的影响

用抗旱性不同的品种及新选育品系进行了离体叶片失水率与抗旱性有关的水分生理指标研究及籽粒品质分析。结果表明：(1)抗旱品种的叶片失水率低,保水力强,束缚水含量高,束缚水／自由水比值也高;(2)在失水率与抗旱性的研究中,发现第6h是失水率转折的关键时间,6h以前抗旱类型的失水率低于敏感类型,以后抗旱类型高于敏感类型,而且在不同抗旱类型或同一类型的不同生育时期所测结果均符合这个规律;(3)严重水分胁迫下,蛋白质含量下降,脂肪含量增加,但抗旱类型蛋白质含量高且下降得少,蛋白质含量与抗旱性有一定相关性。因此,在选育抗旱品种时,应选择在干旱条件下失水率低、抗旱性强、蛋白质含量高、蛋白质含量下降少的材料。     

转GhDREB小麦株系‘G鲁麦23’抗旱性分析

以T6代转抗旱相关基因GhDREB小麦株系‘G鲁麦23’及其受体对照‘鲁麦23’为材料,通过PEG-6000人工模拟干旱胁迫处理观察小麦萌发期胚芽鞘长度、胚根数、胚根长度,采用大田不同水分处理试验研究其不同生育时期的生理生化、形态指标与抗旱指数,以明确转基因材料的抗旱性.结果表明:(1)在种子萌发期20%(W/V)PEG-6000干旱胁迫条件下,‘G鲁麦23’及其受体对照‘鲁麦23’的胚芽鞘长度、胚根长度和胚根数均比非胁迫时降低,且‘G鲁麦23’的降幅较小但均显著高于受体对照;(2)与对照鲁麦23相比,‘G鲁麦23’具有较高的叶片相对含水量和可溶性蛋白含量;(3)随干旱胁迫程度的增强‘G鲁麦23’与‘鲁麦23’株高均有不同程度的降低,但G鲁麦23株高始终高于‘鲁麦23’;在不浇水条件下,‘G鲁麦23’穗叶距显著长于‘鲁麦23’;而3种水分处理下‘G鲁麦23’与‘鲁麦23’穗长几乎没有变化;(4)‘G鲁麦23’在不浇水和浇1次水条件下分别比对照增产11.68%和9.05%,其抗旱指数为1.22,属较强抗旱等级,表现出比‘鲁麦23’更强的抗旱、节水性能.     

不同生育时期干旱对冬小麦氮素吸收与利用的影响

以抗旱性强的‘石家庄8号’和抗旱性弱的‘偃麦20’冬小麦(Triticum aestivum)为材料, 在田间遮雨棚条件下, 研究返青-拔节期、拔节-开花期和灌浆后期3个生育期不同干旱程度对冬小麦产量、氮素吸收、分配和利用的影响。结果表明, 在干旱条件下, 抗旱性强的‘石家庄8号’产量高于抗旱性弱的‘偃麦20’, 并且其3个生育时期轻度干旱均可提高产量。拔节-开花期干旱对两个冬小麦品种氮素的吸收和运转影响均最大, 其次为返青-拔节期, 而灌浆后期影响较小。不同生育期中度和重度干旱均降低了花前贮藏氮素向籽粒中的转移, 并且氮肥利用效率和生产率也较低, 而在返青-拔节和灌浆后期轻度干旱有利于营养器官的氮素向籽粒中转移, 提高了氮肥利用效率和生产率。在干旱条件下, 抗旱性强的‘石家庄8号’籽粒氮素积累对花前贮藏氮素再运转的依赖程度高, 而‘偃麦20’对花后氮素的积累和转移依赖较高。综合产量和氮素的转移特点, 在生产实践中, 返青-拔节期和灌浆后期要注意对小麦进行适度的干旱处理, 在拔节-开花期要保证冬小麦的充分灌溉, 从而有利于氮素的积累和分配。     

河北省冬小麦丰产抗旱性表型鉴定指标分析

以河北省审定的85个冬小麦品种为材料,采用防雨棚春季干旱和露地灌溉2个处理,分别于开花期、成熟期调查株高等27个表型性状,分析了各表型性状与单株子粒产量的相关性。结果表明,单株成穗数等12个性状与单株子粒产量抗旱系数或抗旱指数呈显著或极显著相关;结合表型性状变异系数,明确了提高单株成穗数、穗粒数、灌溉条件下较长的旗叶长度和干旱条件下较短的旗叶长度是培育丰产抗旱小麦新品种的主攻方向;子粒比重、子粒长度及干旱条件下的结实率和每穗小穗数可作为河北省小麦种质资源丰产抗旱性的鉴定依据;河北省小麦品种丰产性高,而抗旱性尚需进一步改善。     

Paclobutrazol-induced alleviation of water-deficit damage in relation to photosynthetic characteristics and expression of stress markers in contrasting wheat genotypes

Our experiment was conducted in order to find out effects of paclobutrazol (PBZ; 30 μl l^–1) on morphology, photosynthetic process, and stress markers under water surplus and deficit conditions in several wheat genotypes. Study revealed that relative water content (RWC), photosynthetic rate, and maximal quantum yield of PSII (F_V/F_M) was improved after a PBZ application both under irrigation and water deficit across the genotypes, while the stomatal conductance was reduced. Further, the application of PBZ led to reduced leaf area in wheat genotypes. Moreover, a proline content was higher in the wheat genotypes under water stress as compared to the irrigated plants. The application of PBZ led to downregulation of the proline content under water deficit, while there was no significant change in the content and activity under irrigation with or without the PBZ treatment. These findings indicated that due to the application of PBZ the wheat genotypes might sense a lower stress level (indicated by the proline content) and better drought tolerance (according to RWC and photosynthetic characteristics).     

不同水氮水平下小麦品种对光、水和氮利用效率的权衡

通过再裂区设计田间试验,以3个春小麦品种(和尚头、西旱2号和宁春4号)为材料,设置两个灌溉水平(充分灌水4500 m³·hm^-2和有限灌水3000 m³·hm^-2)和5个施氮水平(0、75、150、225、300 kg N·hm^-2),研究小麦光能利用效率(LUE)、水分利用效率(WUE)、氮素利用效率(NUE)对水氮的响应特性及其相互关系.结果表明: 3个小麦品种间LUE、WUE和NUE差异显著.在一定范围内增加灌水和施氮量则LUE升高,过量施氮则LUE下降.强抗旱和中等抗旱品种(和尚头和西旱2号)WUE受灌水量的影响比不抗旱品种(宁春4号)小.施氮可以调节小麦WUE,中等施氮水平(和尚头和西旱2号在150 kg N·hm^-2时,宁春4号在225 kg N·hm^-2时)有最高的WUE.随施氮量增加,植株氮素累积量先增后减,氮素干物质生产效率(NUE_b)、氮素收获指数(NHI)、氮肥农学利用效率(NAE)和氮肥偏生产力(PFP)均显著降低.灌溉水平对NHI无显著影响;随灌水量增加,小麦氮素积累量显著增加,强抗旱和中等抗旱品种NUE_b和NAE显著降低,不抗旱品种 NUE_b和PFP显著升高,对其他指标无显著影响.3个小麦品种氮素获取能力与氮素利用效率呈极显著负相关,NUE_b与LUE、WUE呈显著负相关,LUE与WUE呈显著正相关,春小麦氮素利用效率与光能利用效率、水分利用效率间存在明显的权衡关系.当灌水量为3000 m³·hm^-2,强抗旱和中等抗旱品种在150 kg N·hm^-2,不抗旱品种在225 kg N·hm^-2时,有较高的资源利用效率.     

Exploration of Genetic Pattern of Phenological Traits in Wheat (<i>Triticum aestivum</i> L.) under Drought Stress

Drought is the major detrimental environmental factor for wheat (Triticum aestivum L.) production. The exploration of genetic patterns underlying drought tolerance is of great significance. Here we report the gene actions controlling the phenological traits using the line × tester model studying 27 crosses and 12 parents under normal irrigation and drought conditions. The results interpreted via multiple analysis (mean performance, correlations, principal component, genetic analysis, heterotic and heterobeltiotic potential) disclosed highly significant differences among germplasm. The phenological waxiness traits (glume, boom, and sheath) were strongly interlinked. Flag leaf area exhibits a positive association with peduncle and spike length under drought. The growing degree days (heat-units) greatly influence spikelets and grains per spike, however, the grain yield/plant was significantly reduced (17.44 g to 13.25 g) under drought. The principal components based on eigenvalue indicated significant PCs (first-seven) accounted for 79.9% and 73.9% of total variability under normal irrigation and drought, respectively. The investigated yield traits showed complex genetic behaviour. The genetic advance confronted a moderate to high heritability for spikelets/spike and grain yield/plant. The traits conditioned by dominant genetic effects in normal irrigation were inversely controlled by additive genetic effects under drought and vice versa. The magnitude of dominance effects for phenological and yield traits, i.e., leaf twist, auricle hairiness, grain yield/plant, spikelets, and grains/spike suggests that selection by the pedigree method is appropriate for improving these traits under normal irrigation conditions and could serve as an indirect selection index for improving yield-oriented traits in wheat populations for drought tolerance. However, the phenotypic selection could be more than effective for traits conditioned by additive genetic effects under drought. We suggest five significant cross combinations based on heterotic and heterobeltiotic potential of wheat genotypes for improved yield and enhanced biological production of wheat in advanced generations under drought.     

Photosynthetic characteristics and enzymatic antioxidant capacity of leaves from wheat cultivars exposed to drought

Two durum (Triticum durum L.), Barakatli-95 and Garagylchyg-2; and two bread (Triticum aestivum L.) wheat cultivars, Azamatli-95 and Giymatli-2/17 with different sensitivities to drought were grown in the field on a wide area under normal irrigation and severe water deficit. Drought caused a more pronounced inhibition in photosynthetic parameters in the more sensitive cvs Garagylchyg-2 and Giymatli-2/17 compared with the tolerant cvs Barakatli-95 and Azamatli-95. Upon dehydration, a decline in total chlorophyll and relative water content was evident in all cultivars, especially in later periods of ontogenesis. Potential quantum yield of PS II (F(v)/F(m) ratio) in cv Azamatli-95 was maximal during stalk emergency stage at the beginning of drought. This parameter increased in cv Garagylchyg-2, while in tolerant cultivar Barakatli-95 significant changes were not observed. Contrary to other wheat genotypes in Giymatli-2/17 drought caused a decrease in PS II quantum yield. Drought-tolerant cultivars showed a significant increase in CAT activity as compared to control plants. In durum wheat cultivars maximal activity of CAT was observed at the milk ripeness and in bread wheat cultivars at the end of flowering. APX activity also increased in drought-treated leaves: in tolerant wheat genotypes maximal activity occurred at the end of flowering, in sensitive ones at the end of ear formation. GR activity increased in the tolerant cultivars under drought stress at all stages of ontogenesis. SOD activity significantly decreased in sensitive cultivars and remained at the control level or increased in resistant ones. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

主要抗蚜小麦品种(系)的抗性类型及其生化抗性机制

通过对10个抗麦蚜品种(系)室内苗期生命参数、抗性类型和抗蚜次生物质的研究,明确了不同抗性级别的品种对麦蚜种群控制力及部分生化抗蚜机制。实验结果表明,参试的抗蚜品种(系)中30%左右为不选择性：表现为爬行频繁,定殖率低,但是定殖个体生长发育良好;70%为抗生性;表现为使麦长管蚜Sitobion avenae(F.)和禾谷缢管蚜只Rhopalosiphum padi(L.)的发育历期分别延长2.1%～28.2%和3.7%～13.9%,若蚜死亡率增加1.0～3.6倍和1.0～2.25倍,平均寿命缩短10.2%～96.5%和37.5～97,1%,繁殖力下降3.4%～72.8%和25%～97.2%。苗期生化测定结果表明：不同抗源的单宁和总酚含量明显高于感蚜品种,其总酚含量与抗麦长管蚜级别呈显著负相关,以抗生性为主的品种其总酚含量亦与麦长管蚜的内禀增长力(r_m)呈显著负相关(P<0.05),表明总酚是小麦抗长管蚜的关键因子之一,而与禾谷缢管蚜抗性水平无关;单宁含量与麦蚜抗性关系不密切。