Study on Tissue Cultures of Legume Plants

Plant regenerations were achieved from tissue cultures of 31 species of 15 genus of legume plants on A and B media. Various factors including medium composition (major elements, minor element:s, organic components and phytohormones), seed germination rate, illumination and temperature conditions were tested for their effects on callus differentiation in tissue cultures. Combinations of major elements of A or B medium, minor elements and organic components of B5 medium, illumination of 1500–2500 lx, and temperature of 18–27℃ were found suitable for callus differentiation of most legume plants. The calli induced from freshly collected seeds had higher differentiation capacity than from seeds sored for three years. Four types(a,b,c and d) of callus were morphologically distinguished during the differentiation in legume plant tissue cultures. Generally, calli from plants of the same genus belonged to the same type.     

Forms and Fates of Rhizobial Bacteria Present in the Infected Host Cells of Nodules

There were two forms of rhizobial bacteria present in infected host cells of nodules. One was bacteroids which were enclosed in peribacteroid membrane originated from the infected host cells. The other was rhizobia as vegetative cells. The infected host cells were occupied by most of the bacteroids and a certain number of the vegetative cells respectively. With the nodule senescence, there were two kinds of fate of the bacteria: The bacteroids degenerated togather with the infected host cells at the same time and further disintegrated completely, so it is not possible that the disintegrated bacteroids could be returned into soil to revive: the vegetative cells did not disintegrate and die when the infected host cells senesced, eventually could be turned back into soil. The vegetative cells may play an important role, on the one hand, in cycle between legume and soil, on the other hand, maintain rhizobia in natural balance of population ecosystem.     

Protein expression by Streptococcus uberis in co-culture with bovine mammary epithelial cells

Three strains of Streptococcus uberis isolated from dairy cows with mastitis were co-cultured with a bovine mammary epithelial cell line (MAC-T) in Dulbecco's modified Eagle's medium without fetal bovine serum. Protein profiles from culture supernatants and bacterial pellets among different treatments were compared by electrophoresis. There were proteins induced or having increased expression in both supernatant and surface-associated samples from S. uberis co-cultured with MAC-T cells. Some of these proteins were recognized by antibodies in serum obtained from a cow infected by S. uberis . In supernatant samples, there were two distinct protein bands at 35 and 36.8 kDa for all three strains of S. uberis co-cultured with MAC-T cells. These two bands were absent when bacterial protein synthesis was inhibited by chloramphenicol. This study clearly indicates that bacterial protein expression was regulated in response to co-culture with mammary epithelial cells.     

高CO2浓度下4种豆科乔木种子萌发和幼苗生长

 本文研究了高CO2浓度(550×10-6±50×10-6)对4种豆科乔木的种子萌发和幼苗生长的影响,结果如下：(1)高CO2浓度能使光叶红豆种子萌发率提高12％,对其它种的萌发没有明显影响。(2)高CO2环境能增加4种幼苗根瘤数量,提高根瘤的固氮活性和根瘤中可溶性糖的含量。(3)在高CO2环境下生长的幼苗叶片净光合速率比对照CO2环境(约350×10-6)下生长的幼苗提高66.7％～105.9％。在高CO2浓度和对照CO2浓度下生长的幼苗,移至相同C02浓度下测定时,光合速率无明显的差异。高CO2环境下生长并测定的幼苗叶片暗呼吸速率和对照CO2浓度下生长并测定的幼苗的测值差异不大,前者较后者低5.58％～l0.55％。(4)在高CO2环境下生长的4种幼苗干物质比对照的增加29.79％～50.30％,根系增加量较大,根冠比略上升。幼苗的相对生长速率和单位叶率上升,而叶面积比率下降。(5)幼苗对高CO2环境的反应和种的生态特性有关。喜光的大叶合欢幼苗对高CO2环境的反应较大,喜光而具一定耐荫性的猴耳环幼苗次之,而耐荫的光叶红豆和茸荚红豆幼苗则较小。     

根瘤菌结瘤基因研究的新进展

简要综述了目前根瘤菌结癌基因研究的3个热点方向,即结瘤因子、nodlD基因的调控和结瘤基因系统发育分析的新进展。结瘤因子的骨架核心是结瘤基因中的共同性基因nodABC表达的产物,宿主专一性基因则进行骨架结构的修饰,所形成的特异性结瘤因子是根瘤苗宿主范围的主要决定因素。结瘤调控基因nodD的作用方式与其存在的拷贝数目和产物NodD蛋白活性有关,同时NodD的敏感性还影响到根瘤菌的宿主范围。结瘤基因的系统发育揭示出根瘤菌宿主范围与共同性结瘤基因间比其它基荫的相关性更高。结瘤基因与豆科宿主之间存在一定的共进化关系。     

Understandings and future challenges in soybean functional genomics and molecular breeding

Soybean(Glycine max) is a major source of plant protein and oil.Soybean breeding has benefited from advances in functional genomics.In particular,the release of soybean reference genomes has advanced our understanding of soybean adaptation to soil nutrient deficiencies,the molecular mechanism of symbiotic nitrogen(N) fixation,biotic and abiotic stress tolerance,and the roles of flowering time in regional adaptation,plant architecture,and seed yield and quality.Nevertheless,many challenges remain...     

豆科固氮植物对CO2加富的生理响应

 全球CO2浓度升高对植物的影响成为近代植物生理生态学研究的热点,豆科植物因其独特的固氮能力使其研究具有重要价值。从光合生理、固氮特性及碳、氮代谢等几个方面综述了CO2浓度升高对豆科植物生理生态特性的影响,总结出如下结论：在高CO2浓度条件下,豆科植物的光合速率、根