野生大豆

野生大豆种皮形态结构和萌发特性的研究

Testa Morphology Structure and Germination Characteristic of Glycine soja

保护植物野生大豆群落不同物种间的生态关系分析

Ecological Relationships Among Species in Communities of A Protected Plant Glycine soja in Beijing , China

Natural（天然等同）相近。野生大豆在自然界中光温反应的规律

Response Regularity of Wild Soybean to Photoperiod and Temperature in Natural Environment

将杨树和野生大豆DNA直接导入栽培大豆的研究

Directly Leading DNA of Poplar and Wild Soybean into Domestic Soybean

外源野生大豆DNA导入栽培大豆引起的变异

Variation occuring by introduction of Wild Soybean DNA into cultivar soybean

野生大豆与栽培大豆种子贮藏蛋白含量的PAGE分析

PAGE Analysis of Storage Protein Content in Glycine soja and Glycine max

导入野生大豆DNA小麦后代的农艺性状研究

Study on the agronomic traits of variation lines obtained by introducing G.soja DNA into wheat

利用RAPD技术进行野生大豆种群内分化的研究

Research of RAPD in local population differentiation of wild soybean

栽培大豆的叶绿素总量较野生大豆低9.65%，但叶绿素b的含量有较大幅度的提高。

The chlorophyll amount of culture soybean is lower 9.65 % than that of wild soybean , but the content of chlorophyll b raises greatly .

野生大豆与栽培大豆（GlycineMax）球蛋白的cDNA序列存在99%相似性。

99 % globulin cDNA sequence was similar between Glycine soja and Glycine max.

野生大豆种子cDNA文库构建及其球蛋白基因克隆

Construction of cDNA Library and Cloning of Globulin Gene from Wild Soybean ( Glycine soja ) Seeds

短期NaCl胁迫对野生大豆和栽培大豆叶片光合作用的影响

Effects of Short-term NaCl Stress on Photosynthesis in Leaves of Glycine soja and Glycine max

半野生大豆种质资源SSR位点遗传多样性分析

Genetic diversity of semi-wild soybean using SSR markers

25～50°N自然光温动态是形成一年生野生大豆的主要条件。

The natural trend of light and temperature between 25 ° N and 50 ° N is the essential condition to form annual wild so bean .

我国野生大豆与栽培大豆AFLP指纹图谱研究

AFLP Fingerprint Analysis of G.soja and G.max in China

本文利用花粉管通道在大豆自花受粉后，将野生大豆DNA导入栽培大豆，从而引起了后代性状的广泛变异。

This study reports that wild soybean DNA was introduced into cultivar soybean through pollen tube after soybean self-fertilizing , it led to wide variation in offspring characteristics .

中国不同纬度野生大豆和栽培大豆SSR分析

SSR Analysis of wild soybean ( g.soja ) and cultivated soybean from different latitude in China

Q分析及图论分析揭示野大豆、半野生大豆与栽培大豆之间存在较大差异。

Q cluster analysis and graph theory analysis shows these is great diversity among wild soybeans , semi wild soybeans and cultivated soybeans .

地市材料间SSR数据的Nei's标准遗传距离的平均值为0.2584，变化范围为0.0735～0.5079。基于SSR数据对野生大豆材料分布的17个地市进行聚类，聚类结

The Nei 's standard genetic distance of 17 cities ranged from 0.0735 to 0.5079 , with a

栽培大豆（GlycineMax）与野生大豆（G.soja）解剖学的比较研究&Ⅰ.雄配子体的发育

Comparative-study on male gametophyte development between Glycine max and Glycine soja

用花粉管通道法将野生大豆总DNA导入小麦，获得了转基因小麦，其后代的农艺性状有较大的变化。

The DNA of Glycine soja was introduced into wheat through the pollen tube pathway after self pollination . The T 2 generation population 's agronomic traits have greatly changed .

栽培大豆（GlycineMax）与野生大豆（GlyCineSoja）杂交后代耐盐生理机制与籽粒品质的研究

Salt-Tolerant Mechanism and Seed Quality of Offspring Gained by Crossing Glycine max with Glycine soja

野生大豆抗蚜性的利用研究Ⅰ栽培大豆和野生大豆杂交F2代的抗蚜性

Study on the utilization of aphid resistant character in wild soybean ⅰ . aphid resistant performance of f_2 generation from crosses between cultivated and wild soybeans

除根瘤外其他器官GS活性野生大豆明显低于其他栽培品种。

The GS activities in the organs except nodules of G.soja were obviously lower than other varieties .

耐盐野生大豆（GlyCineSoja）的光周期效应

Effects of Photoperiod on Salt - tolerant Glycine soja

利用12对SSR引物对67份半野生大豆种质进行了遗传多样性的检测分析。

SSR ( Simple Sequence Repeats ) primers were used to detect genetic diversity among 67 germplasm semi wild soybean .

半野生大豆7S贮藏蛋白的提取及某些特性的研究

Isolation and characterization of 7S storage protein in semi-wild species of soybean

根据野生大豆与这7种植物的SOD基因序列相似性所建立的进化树，显示与传统的分类地位基本一致。

We establish phylogenetic tree according to wild soybean and seven kinds of plant SOD gene sequence similarity , finally , it is consistent with traditional taxonomic status .

野生大豆（GlyCineSoja）耐高盐碱土壤种质的鉴定与评价

Identification and Assessment of Salt-Tolerant Germplasm of Wild Soybean ( Glycine soja ) in High Saline Soil

野生大豆（GlyCineSoja）C2H2型锌指蛋白基因的克隆与序列分析

Cloning and Sequence Analysis of a C2H2 type Zinc Finger Protein Gene from Glycine soja