冬小麦麦苗不同叶龄的耐寒力

我们在生产中观察到不同叶龄的麦苗死亡情况不同。但是这方面的报道不多,1979—1985年连续六年对不同品种不同叶龄的麦苗越冬耐寒力进行了观察,其结果基本一致。材料与方法我们先后观察了26个品种,并用春季播种和春化处理种子的方法,确定了几个主要品种的生态类型,从中选了分蘖节深度(2.5—3厘米)适中的五个品种:强冬性的班克麦,冬性     

干旱条件下冬小麦不同叶龄叶绿素荧光及叶黄素循环组分的变化

干旱条件下冬小麦叶片光化学效率的降低伴随着叶黄素循环组分玉米黄质含量的增加。干旱初期,Ｆｖ／Ｆｍ的降低约在暗置这夜后完全恢复。当干旱诱导的玉米黄质含量的增加达最大值时,Ｆｖ／Ｆｍ不可逆下降,Ｆｏ上升,表明发生了光破坏。与老叶相比,干旱条件下功能叶具有较高的玉米黄质含量,对光破坏的抗性较强。推测干旱条件下老叶不可逆衰老与其依赖于叶黄素循环的耗散过剩光能能力的下降有关。     

水分对番茄不同叶龄叶片光合作用的影响

以番茄品种"金棚1号"为材料,采用盆栽方式,按照蒸腾蒸发量(ET)的50%、75%、100%和125%作为补充灌溉量研究了不同水分下番茄结果期叶片气体交换特性和光响应特征参数随叶龄的变化。结果表明:番茄叶片随着叶龄的增加,净光合速率(Pn)、气孔导度(Gs)、蒸腾速率(Tr)逐渐降低,水分利用效率(WUE)呈先上升后下降趋势;叶龄为18 d和29 d的叶片最大净光合速率(Pmax)随灌溉量的增加均先增加后降低,分别在75%ET和100%ET处理达到最大值。叶龄为38 d和47 d的叶片Pmax均以125%ET处理最大。表观量子效率(α)随叶龄的增大也先升高后下降,在叶龄为38 d时最大;番茄叶片的光饱和点(LSP)随叶龄的加大而减小。不同水分处理下不同叶龄叶片的光响应特征参数为:叶片在叶龄为18 d时,Pmax为20.64—26.73μmol.m-.2s-1,α为0.0518—0.0556;叶龄为29 d时,Pmax为11.00—24.24μmol.m-.2s-1,α为0.0522—0.0594;叶龄为38 d时,Pmax为11.77—18.18μmol.m-.2s-1,α为0.0619—0.0693;叶龄为47 d时,Pmax为9.09—18.17μmol.m-.2s-1,α为0.0538—0.0606。随叶龄加大,增加补充灌溉量有利于延缓叶片光合能力的降低。气孔限制是水分影响番茄叶片光合作用的主要因素,气孔限制与非气孔限制因素是番茄叶片Pn随叶龄变化的原因。     

干旱条件下冬小麦不同叶龄叶绿素荧光及叶黄素循环组分的变化(英文)

干旱条件下冬小麦叶片光化学效率（Ｆｖ／Ｆｍ）的降低伴随着叶黄素循环组分玉米黄质含量的增加。干旱初期,Ｆｖ／Ｆｍ 的降低约在暗置过夜后完全恢复。当干旱诱导的玉米黄质含量的增加达最大值时,Ｆｖ／Ｆｍ 不可逆下降,Ｆｏ 上升,表明发生了光破坏。与老叶相比,干旱条件下功能叶具有较高的玉米黄质含量,对光破坏的抗性较强。推测干旱条件下老叶不可逆衰老与其依赖于叶黄素循环的耗散过剩光能能力的下降有关。     

不同叶龄黄瓜叶片叶绿素蛋白质复合物组分的比较研究

用SDS-聚丙烯酰胺凝胶电泳的方法,对比分析了老、嫩黄瓜叶片叶绿素蛋白质复合物之间的差异,发现嫩黄瓜叶片中缺少1条属光系统Ⅰ的CPI_b带。从低温荧光发射光谱观察到,嫩黄瓜的光系统Ⅰ相对高于光系统Ⅱ,而老黄瓜则相反。指出在叶绿体发育过程中首先形式光系统Ⅰ,以后是光系统Ⅱ。我们还注意到,叶片中的F685/F735比值与叶绿素蛋白质复合物中的单体/寡聚体比值之间是正相关关系。     

不同叶龄黄瓜叶片叶绿素蛋白质复合物组分的比较研究

用SDS — 聚丙烯酰胺凝胶电泳的方法,对比分析了老、嫩黄瓜叶片叶绿素蛋白质复合物之间的差异,发现嫩黄瓜叶片中缺少1条属光系统I的CPIb带。从低温荧光发射光谱观察到,嫩黄瓜的光系统I相对高于光系统Ⅱ,而老黄瓜则相反。指出在叶绿体发育过程中首先形成光系统I,以后是光系统Ⅱ。我们还注意到,叶片中的F685/F735比值与叶绿素蛋白质复合物中的单体／寡聚体比值之间呈正相关关系。     

羊草不同叶龄叶片光－光合特性的初步研究

在6月至7月,羊草叶片在充分展开后的数天之内,即最上展开叶,其净光合速率及其光强系数,以及光饱和点,近饱和点和半饱和点最高;幼龄叶和老龄叶的上述各项指标均较低,但随着光强的下降,不同叶龄叶片的净光合速率或光合的光强系数的差别均逐渐减小,光补偿点以半展开幼叶较低,而后随叶龄增长逐渐升高,羊草的壮龄叶对光的利用能力较强,在其光合生产中起主要作用,幼龄叶仅对弱光的利用能力高,老龄叶相对地较为耐阴。     

羊草不同叶龄叶片光－光合特性的初步研究

在6月至7月,羊草叶片在充分展开后的数天之内,即最上展开叶,其净光合速率及其光强系数,以及光饱和点,近饱和点和半饱和点最高;幼龄叶和老龄叶的上述各项指标均较低,但随着光强的下降,不同叶龄叶片的净光合速率或光合的光强系数的差别均逐渐减小,光补偿点以半展开幼叶较低,而后随叶龄增长逐渐升高,羊草的壮龄叶对光的利用能力较强,在其光合生产中起主要作用,幼龄叶仅对弱光的利用能力高,老龄叶相对地较为耐阴。     

不同叶龄鸭跖草耐咪唑乙烟酸能力差异的生理生化基础

比较不同叶龄鸭跖草耐咪唑乙烟酸能力的结果表明,鸭跖草受咪唑乙烟酸伤害的程度有随着鸭跖草叶龄的增加而减轻的趋势,株高和鲜重的抑制率也有减小的趋势。另外,随着叶龄的增大,鸭跖草叶中超氧化物歧化酶（SOD）、过氧化物酶（POD）、谷胱甘肽-S-转移酶（GST）、乙酰乳酸合成酶（ALS）的活性和谷胱甘肽（GSH）的含量增大。三叶龄以上鸭跖草的各项指标与二叶龄之间差异显著。     

低温胁迫对水稻幼苗不同叶龄叶片叶绿素荧光特性的影响

以‘蜀恢162’(‘Shuhui 162’)、‘糯89-1’(‘Nuo 89-1’)、‘蜀恢162/糯89-1’(‘Shuhui 162/Nuo 89-1’)、‘奇妙香’(‘Qimiaoxiang’)和早黄矮(‘Zaohuang’ai’)5个水稻(Oryza sativa L.)品种(系)为研究对象,采用叶绿素荧光成像系统研究了低温(4℃)胁迫对水稻3叶期幼苗不同叶龄叶片叶绿素荧光特性的影响。结果表明:经低温胁迫处理后,5个水稻品种(系)幼苗3个叶龄叶片的各叶绿素荧光参数变化有明显差异,其中第一叶的各项参数均降至0。经低温处理后5个水稻品种(系)幼苗3片叶片的PSⅡ最大光化学量子产量(Fv/Fm)均明显小于对照(25℃),其中第一叶的降低幅度最大、第三叶最小。经低温胁迫处理后,5个水稻品种(系)幼苗第三叶的非光化学淬灭系数(qN)均显著大于对照,耐冷性品种‘糯89-1’幼苗第二叶的qN较对照显著增大,而其他水稻品种(系)幼苗第二叶的qN均显著小于对照;‘糯89-1’幼苗第二叶的光化学淬灭系数(qP)较对照略有增大,第三叶的qP显著大于对照;‘早黄矮’幼苗第三叶的qP也大于对照但差异不显著,而其余水稻品种(系)幼苗第二叶和第三叶的qP均显著小于对照。经低温胁迫后5个水稻品种(系)幼苗3片叶片的PSⅡ最大相对电子传递速率(rETRmax)和半饱和光强(Ik)均显著小于对照;除‘糯89-1’幼苗第三叶外,5个水稻品种(系)幼苗3片叶片的快速光响应曲线初始斜率(α)也均显著小于对照,总体上第一叶的rETRmax、Ik和α下降幅度最大、第三叶最小。研究结果揭示:受低温胁迫后,叶片自身生理差异是导致水稻幼苗不同叶龄叶片受伤害程度不同的主要因素。     

Determination of Frost Tolerance in Winter Wheat and Barley at the Seedling Stage

Detailed studies were made on changes in the quantity of 1.4 MDa rRNA precursor in barley and wheat cultivars with different degrees of frost tolerance. When analysing genotypes with different LT₅₀ values a close negative correlation was found between the quantity of 1.4 MDa molecular mass rRNA precursor and the forst tolerance of the given barley or wheat cultivar. The results suggest that a technique based on low temperature phosphorus incubation at the seedling stage could be suitable for the selection of genotypes on the basis of this character in applied research.     

Correlation between Cold- and Drought-Induced Frost Hardiness in Winter Wheat and Rye Varieties

Exposure of six wheat (Triticum aestivum L.) and one rye (Secale cereale L.) cultivar to 40% relative humidity for 24 hours induced the same degree of freezing tolerance in seedling epicotyls as did cold conditioning for 4 weeks at 2°C.     

Revealing Hereditary Variation of Winter Hardiness in Cereals

A set of cereal crops and differentiating cultivars was shown to be of utility for identifying the major abiotic factors that limit the survival of winter crops in the cold season of a particular year. With this approach, the season was identified (1997–1998, Belgorod) when the survival of cereals depended on the tolerance to anaerobiosis rather than on the frost resistance. Differentiation of common wheat cultivars with respect to this property was attributed to a locus designated Win1 (Winter hardiness 1) and localized 3.2–5.8% recombination away from the B1 (awnlessness 1) gene. Winter barley (cultivar Odesskii 165) displayed the highest tolerance to anaerobiosis in the cold season; low and intermediate tolerance was established for winter durum wheat (cultivar Alyi Parus) and winter common wheat, respectively. Frost resistance and winter hardiness type 1 proved to be determined by different genetic systems, which showed no statistical association. Correlation analysis revealed significant positive associations of frost resistance in the field (1996–1997, Belgorod) with productivity, sedimentation index (Zeleny test), plant height, and vegetation period in wheat. Statistical analysis associated frost resistance with gliadin-coding alleles of homeologous chromosomes 1 and 6 of the A, B, and D wheat genomes.     

Mapping QTLs for Phosphorus-Deficiency Tolerance at Wheat Seedling Stage

Soil phosphorus (P) deficiency is one of the major limiting factors to crop production throughout the world. It is an important strategy to breed varieties with improved P-deficiency tolerance for sustainable agriculture. The objective of this study was to map QTLs for P-deficiency tolerance in wheat, and develop molecular marker assisted selection in breeding wheat with improved P-deficiency tolerance. A doubled haploid (DH) population, consisting of 92 DH lines (DHLs) derived from P-deficiency tolerant wheat variety Lovrin 10 and P-deficiency sensitive variety Chinese Spring, was developed for mapping QTLs for P-deficiency tolerance. A genetic linkage map consisting of 34 linkage groups was constructed using 253 SSR markers. Shoot dry weight (SDW), tiller number (TN), shoot P uptake (SPU), and shoot P utilization efficiency (PUE) were investigated at seedling stage under P deficiency (−P) and sufficiency (+P) condition in two pot trials in 2002 and 2003, respectively. All traits segregated continuously in the population under either −P or +P condition. Significant positive correlations were found in between TN, SDW and SPU, whereas significant negative correlations were observed between PUE and SPU and between PUE and TN. Twenty and 19 QTLs were detected under −P and +P condition, respectively. The 39 QTLs were distributed on 21 chromosomal regions. There were three clusters of QTLs, which were associated with Xgwm25l (on chromosomes 4B), Xgwm271.2 (on chromosome 5A), and Xgwm121 (on chromosome 5D), respectively. Compared to the DHLs with all Chinese Spring alleles at the three loci, those with all Lovrin 10 alleles had, on average, much higher SPU, SDW and TN under −P condition in both trials, suggesting the importance of the three loci in controlling P-deficiency tolerance. It was interesting to find that two of the above three loci were closely linked with vernalization requirement genes VRN-A1 (on chromosome 5A) and VRN-D1 (on chromosome 5D). Potential implication of the linkage between P-deficiency tolerance and VRN genes was discussed.     

Effect of the 5R(5A) Alien Chromosome Substitution on the Growth Habit and Winter Hardiness of Wheat

The growth habit, ear emergence time, and frost tolerance of wheat/rye substitution lines have been studied in cultivars Rang and Mironovskaya Krupnozernaya whose chromosome 5A is substituted with chromosome 5R of Onkhoyskaya rye. Hybrid analysis has demonstrated that the spring habit of the recipient cultivars Rang and Mironovskaya Krupnozernaya is controlled by dominant gene Vrn-A1 located in chromosome 5A. Onokhoyskaya rye has a dominant gene for the spring habit (Sp1) located in chromosome 5R. It has been found that the resultant 5R(5A) alien-substitution lines have a winter type of development and ears do not emerge during summer in plants sown in spring. The change in growth habit has been shown to be related to the absence of the rye Sp1 gene expression in the substitution lines. The winter hardiness of winter 5R(5A) alien-substitution lines has been studied under the environmental conditions of Novosibirsk. Testing the lines in the first winter demonstrated that their winter survival is 20–27%. The possible presence of the frost resistance gene homeoallelic to the known genes Fr1 and Fr2 of the common wheat located on chromosomes 5A and 5D, respectively, is discussed.     

氮素水平对小麦幼苗叶绿体色素蛋白复合体含量的影响

在水培条件下,研究了不同氮素水平对小麦幼苗叶绿体色素、色素蛋白复合体含量及其光谱特征的影响。结果显示:(1)氮素水平较低时PSⅡ捕光色素蛋白复合体LHCⅡ在24~30 kD范围内的蛋白含量降低,不供氮时,色素蛋白复合体含量最低,而高分子量区域的蛋白组分相对较为稳定,说明氮素水平影响PSⅡ的多肽组分,而对PSⅠ多肽组分的影响相对较小。(2)室温吸收光谱分析表明,氮素水平较低时结合态色素的含量及比例发生改变,影响植物对光的吸收能力;荧光激发及发射光谱的峰值均随氮素浓度的升高而升高,说明增加施氮量时,叶绿体类囊体中受激发的色素分子数目增加,荧光强度也随之增大;叶绿体蛋白含量在16.86 mg.L-1氮素浓度时最大。     

Grain Size and Seedling Growth of Wheat at Different Ploidy Levels

A study was made of the influence of grain size variation withinand between diploid, tetraploid and hexaploid wheat, on a numberof seedling growth characters. Differences in grain size within the three ploidy levels appearedto be related to total photosynthetic area and dry weight accretionin the seedling. In the diploids there was a positive correlationbetween seed size and total photosynthetic area (r = +0·99,P < 0·01) and total dry weight (r = +0·84,P < 0·05) of the seedling at 10 weeks after emergence.In the tetraploid and hexaploids, seed size was negatively correlatedwith both total photosynthetic area (r = –0·69,P < 0·05 and r = –0·33, P < 0·05for the tetraploids and hexaploids respectively) and total dryweight (r = –0·69, P < 0·05 and r = –0·59,P < 0·05 for the tetraploids and hexaploids respectively),of the seedlings 10 weeks after emergence. The main physiological distinction between the tetraploids andhexaploids appeared to be the superiority of the hexaploidsin rate of leaf appearance and the lower ratio of expanded tounexpanded leaves in the seedling 10 weeks after emergence.The tetraploids, in turn, appeared to be superior to the diploidsin these two characters. Triticum spp., wheat, polyploidy, grain size, photosynthetic area, net assimilation rate, tiller number