Genetic Analysis of a Small Grain Mutant Induced by T-DNA Insertion in Rice

[Objective] The aim of this study is to understand the genetic characteristics of a grain shape mutant and its possible role in genetic improvement of grain yield in rice. [Method] On the basis of the collection of T-DNA tag lines, the progeny of homozygous plants carrying T-DNA insertion were screened for mutants with mutated phenotypes. The genetic analysis of the mutant and test for the linkage between the mutated phenotype and the T-DNA insertion were carried out to determine its genetic characteristics. [Result] In the present study, a grain shape mutant induced by T-DNA insertion in rice was identified, which showed small grain. Genetic analysis of the mutant showed that the two types of phenotype, normal and small grain in the segregating populations derived from the T-DNA heterozygotes, fit the ratio of 3∶1. Test for Basta resistance showed that all the mutants were resistant while the normal plants segregated for resistant and susceptible by the ratio of 2∶1. The results indicated that the mutant phenotype cosegregated with Bar gene. The small grain mutant caused by T-DNA insertion was confirmed by PCR amplification aiming at T-DNA. [Conclusion] The grain shape mutant is useful for isolation of the tagged gene and genetic improvement in rice.

Distribution of Grain Hardness in Chinese Wheats and Genetic Analysis

A hundred winter wheat and 41 spring wheat cultivars and advanced lines were used to investigate the distribution of grain hardness in Chinese wheats and correlations between grain hardness and other kernel traits. P1, P2, F1 , F2 and F3 from three crosses, i. e. , Liken2/Yumai2, 85Zhong33/Wenmai6 and 85Zhong33/95Zhong459 were sown to study the genetics of grain hardness. Significant correlation was observed between hardness measured by Single Kernel Characteristic System 4100 (SKCS 4100) and Near Infrared (NIR) Spectroscopy, r ranging from 0.85 to 0.94. Chinese wheat is a mixed population in terms of hardness, ranging from very soft to very hard. For autumn-sown wheat, on average, grain hardness decreases from north to south and spring-sown wheat is dominant with hard type. Hardness is negatively associated with flour color, and its associations with flour yield and ash content differ in winter and spring wheats. Grain hardness is controlled by a major gene and several minor genes with additive effect mostly, but dominant effect is also observed, with heritability of 0.78.

Characterization of Iron Grains near the P/T Boundary in the Meishan Section of China

The Meishan section of China has been confirmed as the ＂Global Stratotype Section and Point＂ of the P/T boundary. In the section, the authors found several types of iron grains, including pyrite, pure iron grains and goethite. From the research of macro minerals, it is easy to find that the grains rich in iron appear from the bottom of the event layer of the section. In other words, it is probably residue of the geochemical catastrophe of that time. Therefore, it is important to trace the source of these iron grains and their relationships, which probably provides evidence for volcanic eruption or impact-volcanoes and has directive significance to the crisis during the P/T transitional period. Through the study of the characterization and relationships of these iron grains, the authors make a preliminary discussion on the P/T mass extinction.

Genetic Analysis of Grain Yield in a 7×7 Diallel Cross F_2 Population of Wheat(T.Aestivum L.)

In order to obtain genetic information for grain yield, seven genetically diverse wheat cultivars were crossed in an incomplete diallel to study the inheritance of grain yield using F_2 progenies for two years. Significant differences were observed among genotype, year and genotype × year interaction for grain yield, and both general combining ability(GCA) and specific combining ability(SCA) were also highly significant for grain yield, suggesting that the trait was controlled by both additive and non-additive effect. The GCA estimates revealed that the best combiners for grain yield were Yangmai 5 and Ningmai 9. Adequacy tests revealed that data of grain yield was fully adequate for genetic interpretation. Over-dominance genetic effects were important for the expression of grain yield. Grain yield exhibited moderately high value of narrow sense heritability(h_N^2=66.98% and h_N^2=72.37%).

中国春小麦品种籽粒硬度等位变异的STS检测

籽粒硬度是重要的小麦品质性状。采用单籽粒硬度仪(SKCS)和STS标记对春麦区主要推广品种和品系55份进行了籽粒硬度和Puroindoline等位变异类型检测,结果表明,全国春麦品种61.8%为硬质类型,混合和软质品种频率较低,分别为25.5%和12.7%,SKCS硬度指数分布范围为11～84。共检测到6种Puroindoline基因类型,其中Pinb-D1b 分布范围最广,出现在29个品种(系)中;Pina-D1b有2份,Pinb-D1a为7份,Pinb-D1c、Pinb-D1d和Pinb-D1e分别为1、13和3份。Pinb-D1a(野生型)硬度低于突变型,差异达1%显著水平,Pinb-D1b和Pina-D1d无显著性差异。

明胶中蛋氨酸含量对氯化银{100}面T-颗粒乳剂晶形的影响

氯化银{100}面T 颗粒乳剂是一种新型感光乳剂,近年来受到感光界广泛关注.本文着重讨论了明胶中蛋氨酸含量对该种乳剂生成过程的影响.实验发现,明胶中蛋氨酸含量对乳剂微晶的晶体形态和形成一定晶形的乳化时间的长短有直接影响,并推断这一作用与蛋氨酸对颗粒表面Ag+的吸附密切相关.

氯化银T-颗粒乳剂制备专用的氧化明胶的研究

以往的研究表明:低蛋氨酸含量的明胶能制得晶体形态比较高的高氯T 颗粒乳剂.本文用氧化方法进一步降低明胶中的蛋氨酸含量.明胶经氧化剂(H2O2)氧化能得到不同的氧化明胶.用电位法测定氧化明胶的还原性;用氨基酸分析仪测定它们的蛋氨酸含量;用SDS PAGE电泳法测定它们不同结构的组份含量.结果表明,还原性及蛋氨酸含量随氧化剂加入量的多少而变化;但氧化明胶的分子量分布与原胶相比变化甚小.

CIMMYT小麦在中国春麦区的适应性分析

目的研究CIMMYT小麦在中国的适应性有助于提高春麦区的育种水平。方法10份CIMMYT代表性品种和15份中国春麦主栽品种于2001和2002年种植在中国春麦区的9个试点和CIMMYT的4种不同处理环境,分析产量、产量构成因子和农艺性状的变化趋势。结果CIMMYT品种穗数和穗粒数多,千粒重中等,具有广泛适应性,比中国品种具有更高的产量优势;黑龙江光敏感品种植株高、抽穗和成熟晚、穗数中等、穗粒数少、千粒重和产量低;中国其它品种株高中等、抽穗和成熟早、穗数少、穗粒数中等、千粒重高、产量中等。CIMMYT品种引种到中国后,株高降低,抽穗和成熟提早,并略减产;黑龙江光敏感品种在CIMMYT种植时株高增加,抽穗和成熟推迟,千粒重降低,并显著减产;中国其它品种在CIMMYT种植时株高增加、抽穗和成熟略推迟、千粒重变化较小,并略减产。结论CIMMYT品种可在云南、青海和新疆直接推广种植;内蒙古、甘肃和宁夏为其次适宜地区,可以直接推广应用,但主要用作杂交亲本;在黑龙江以作杂交亲本为宜。为提高引种效率,并考虑到性状的重复力大小,在CIMMYT为中国选种时应重点选择籽粒较大的材料。为云南所选材料可略矮、适当晚熟,内蒙古、甘肃、宁夏和新疆所选材料可略高、较早熟,青海所选材料可较高、熟期相当,黑龙江应主要选择高纬度材料、植株偏高且晚熟。

一个控制水稻籽粒长度主效基因——Lk-4(t)的BC_2F_2群体定位及其遗传效应分析(英文)

水稻籽粒大小和形状是影响稻米外观品质和产量的重要影响因素,对控制这些性状基因的定位和克隆有助于弄清 籽粒大小基因的表达模式和相应的代谢系统,最终实现该性状的自由调控。运用SSR和CAPs标记对来源于蜀恢527//蜀 恢527／小粒回交组合BC2F2群体800隐性长粒单株进行分析,定位了一个控制水稻籽粒长短的基因,Lk-4(t)。对F2和BC2F2 群体籽粒大小形状和千粒重的遗传分析表明,回交能将大部分对目的基因效应具有干扰修饰作用的微效基因多态性除去, 从而有利于对目的基因型的准确鉴定;在F2和BC2F2群体中只发现两类籽粒长短表现型,即短粒和长粒,并且二者分离比 例符合3:1的典型一对等位基因分离比例。这说明群体中籽粒长短变异是受一对基因控制。通过对BC2F2群体中隐性(长 粒)单株进行分子标记分析,将这个控制籽粒长短的主效基因定位在3个CAPs标记,P1-EcoRV,P2-Sac I和P3-Mbo I 附近。连锁分析表明,Lk-4(t)位于水稻第3染色体着丝粒附近,离标记P1-EcoRV和P2-Sac I分别有0．90 cM和0．50 cM 的距离。

[Fe(CN)_6]^(4-)在溴碘化银T-颗粒乳剂中的掺杂

本文研究了K4[Fe(CN) 6 ]掺杂对溴碘化银T 颗粒乳剂感光性能的影响 .结果表明 ,掺杂剂的掺杂量以及掺杂位置对乳剂的感光性能都有影响 .K4[Fe(CN) 6 ]的掺杂量在每克乳剂 3 1× 1 0 - 9-3 1× 1 0 - 11mol之间时 ,乳剂感光度都有提高 .最佳掺杂量为每克乳剂 3 1× 1 0 - 10 mol.掺杂位置接近表面时效果相对较好 ,表明K4[Fe(CN) 6 ]是浅电子陷阱掺杂剂 .当掺杂剂的掺杂量大于每克乳剂 3 1× 1 0 8mol,且掺杂位置在乳剂颗粒较深内部时 。

原子力显微镜观察T-颗粒乳剂晶体形貌

应用原子力显微镜对T 颗粒照相乳剂晶体表面形貌进行观察,直接测得样品的大小和厚度.得到的精细结构显示样品表面不是平坦的,而是呈现凸凹不平的结构,高低起伏最大可达5nm左右.样品经充分曝光后起伏增大到9nm左右,说明银原子簇优先在较活泼的凸起部位生成.

溴碘化银T-颗粒乳剂晶体的表面形貌研究

用原子力显微镜研究了 T-颗粒卤化银晶体、掺杂有浅电子陷阱掺杂剂 K4 [Ru(CN) 6 ]的掺杂乳剂晶体、经硫加金化学增感后的掺杂乳剂晶体的表面形貌以及曝光后表面形貌的变化 .观察结果表明 ,T-颗粒晶体表面存在很多突起 ,经曝光后这些突起高度增加 ,更集中 .掺入浅电子陷阱掺杂剂 K4 [Ru(CN) 6 ]后 ,T-颗粒晶体对光更敏感 ,曝光后表面突起高度的增加幅度大于未掺杂乳剂光照后表面高度的变化 .同时硫增感剂对表面突起的分布也有很大的影响 .

气相色谱仪宽口径毛细管柱检测谷物中T-2毒素方法

目的 测定谷物中 T- 2毒素含量。方法 用 GC- 9A宽口径毛细管柱测定面粉中 T- 2毒素的含量。结果 该方法的回收率 2 0 0 ng为 86 .31%± 1.40 % ,5 0 0 ng为 89.2 2 %± 2 .0 4%。结论 方法操作简单 ,回收率高 ,最低检出量为 30 ng,线性范围 5 0～ 2 0 0 0

黑龙江省大骨节病病区非病区主食中T-2毒素检测报告

用ＥＬＩＳＡ法检查黑龙江省大骨节病病区富裕县３４号村住户当地产面粉１０份，Ｔ－２毒素均为阳性，全距为２１２．５～３５０．５ｎｇ／ｇ，均数２７８．４ｎｇ／ｇ；当地产玉米粉５份，均为阳性，全距３５．８～２３７．３ｎｇ／ｇ，均数１２２．０ｎｇ／ｇ。非病区双城幸福村住户当地产玉米粉５份，４份阳性，全距为５２．４～２２４．８ｎｇ／ｇ，均数１５．２ｎｇ／ｇ；采该村购自外地的面粉、大米各５份，均＜５０ｎｇ／ｇ。尚志县河东乡，当地产大米１０份，７份阳性，全距为３．９～８．５ｎｇ／ｇ，均数６．

哈尔滨市市售粮食T-2毒素污染水平的气相色谱法检测报告

用气相色谱法检测哈尔滨市市售玉米粉２４份，面粉２３份，大米１２份，小米１１份，发现Ｔ－２毒素阳性例数分别为玉米粉８份，面粉９份，大米和小米各３份。污染水平以玉米粉和面粉为高，最高者玉米为７４８ｎｇ／ｇ。大米、小米的污染水平多数小于５０ｎｇ／ｇ，仅有１份小米达到８０ｎｇ／ｇ。

小麦籽粒硬度及其Pinb-D1基因等位变异的STS标记检测

为了明确内蒙古春小麦和部分引进冬小麦的籽粒硬度及其等住变异类型，用SKCS 4100单籽粒谷物硬度仪和STS分子标记对17份冬小麦、87份春小麦品种和38份春小麦高代品系的籽粒硬度及其Pinb-D1a、Pinb-D1b和Pinb-D1c等位基因进行了分析。结果表明，在104份冬、春小麦品种中，籽粒硬度指数变幅为1±16-74±21，其中软质、混合和硬质麦频率分别为23．1％、49．0%和27．9％；Pina—D1a／Pinb-D1a、Pina—D1a／Pinb-D1b和Pina—D1a／Pinb-D1c基因型分别为68份、27份和4份。在38份高代品系中，籽粒硬度指数变幅为0±18～49±17，软质和混合麦频率分剐为68．4％和31．6％，Pina—D1a／Pinb-D1a和Pina—D1a／Pinb-D1b基因型分别为20份和18份。

单克隆抗体酶联免疫法测定谷物中T-2毒素的研究

运用抗T-2毒素的单克隆抗体,建立了检测谷物(小麦、大米)中T-2毒素的直接竞争性酶联免疫吸附测定法。样品经三氯甲烷—无水乙醇(4∶1)提取,用中性氧化铝/活性炭柱净化,制备成样液,供ELISA检测之用。本方法最低检出量为0.1ng/检测孔(1ng/ml),敏感范围为4～1000ng/ml,平均回收率为97.2％～113.2％,精密度为5.1％～14.2％。运用该方法,首次从引起食物中毒的大米中检出T-2毒素,其含量为178.2～418.8ppb。

[Ru(CN)_6]^(3-)在溴碘化银T-颗粒乳剂中的掺杂

研究了K4犤Ru(CN)6犦掺杂剂对溴碘化银T-颗粒乳剂感光性能的影响,结果表明掺杂剂的掺杂量以及掺杂位置对乳剂的感光性能都有影响。当K4犤Ru(CN)6犦的掺杂量为3.1×10-8～3.1×10-9mol/g乳剂之间时,掺杂剂掺杂在乳剂的任意位置,乳剂感光度都有提高,表明K4犤Ru(CN)6犦是浅电子陷阱掺杂剂。掺杂位置接近表面或接近内核时效果相对较好,最佳的掺杂量为3.1×10-8mol/g乳剂。当掺杂剂的掺杂量小于3.1×10-10mol/g乳剂,且掺杂位置接近富碘区时,乳剂的感光度反而下降。

免疫亲和柱净化/柱前衍生化-高效液相色谱荧光检测法测定粮谷中的T-2毒素

建立了免疫亲和柱净化／柱前衍生化-高效液相色谱荧光检测器测定粮谷中T-2毒素含量的方法。样品经甲醇-水（体积比为80：20）混合溶剂提取，通过免疫亲和柱（IAC）净化，以氰酸蒽（1-AN）为衍生化试剂、4-二甲基氨基吡啶（DMAP）为催化剂进行衍生，以ZORBAX Eclipse XDB-C18柱为分离柱，乙腈-水（体积比为80：20）为流动相进行高效液相色谱分离及荧光检测，荧光检测的激发波长为381nm，发射波长为470nm。T-2毒素的质量浓度为0．01～1．5mg／L时与峰高呈良好的线性，相关系数为0．9985。在0．01～1．5μg／g添加水平下，回收率为79．7％～94．5％，相对标准偏差小于7％；检出限（S/N=3）为0．01μg／g。该方法净化效果好，灵敏度高，操作简便快速。

T型通道挤压变形Mg-1.5Mn-0.3Ce合金的超塑性和组织演变

采用T型通道挤压(TCP)对Mg-1.5Mn-0.3Ce合金(质量分数,%)进行了4道次热挤压变形,其平均晶粒尺寸由原始轧制态的35μm细化至2μm;TEM观察表明,经TCP变形后细小的第二相粒子Mg_(12)Ce弥散分布于晶内及晶界处.变形合金在573—673 K及1×10^(-1)—4×10^(-4)S^(-1)应变速率范围内显示良好的超塑性变形;在温度为673 K及3×10^(-3)s^(-1)条件下,得到最大的断裂延伸率为604%,应变速率敏感系数m为0.36.超塑性变形后断裂区域显微组织观察表明,Mg 1.5Mn-0.3Ce合金超塑性变形的主要机制为晶界滑移,在较高温度、较低应变速率条件下超塑性变形时出现晶内滑移现象,作为超塑性变形的协调机制促进晶界滑移,随应变速率的降低或温度的升高晶内滑移越明显.