Major, minor and trace-elemental contents analysis in northeast soybeans by ICP-AES

Major, minor and trace elemental contents in northeast China soybeans were determined by using inductively, coupled plasma atomic emission spectrometry (ICP-AES). Three different sample digestion methods including two wet digestions, HNO3-HClO4 and HNO3-H2SO4 and a dry ash method were compared. Owing to the high oil content in soybeans, long time is needed and access acid should be added, with mixed acid digestion methods, which may result in higher sample blank. Therefore, the dry ask method would be more proper for the pre-treatment of soybean samples. Potassium and phosphorus are major elements in soybeans, so the effect of potassium and phosphorus on the other elements was investigated. Results showed that the potassium and phosphorus did not affect the determination. of other trace elements. There are not significant differences in trace elemental contents for the eleven northeast China soybeans.

Detection of transgenic DNA in tilapias (Oreochromis niloticus, GIFT strain) fed genetically modified soybeans (Roundup Ready)

We used nested-polymerase chain reaction (PCR) to detect Roundup Ready soybean in aquatic feeds and feeding tilapias. A template concentration of 10(-10) g mu L-1 DNA solution could be detected with a dilute degree of 0.01%. Most (90.6%) of the aquatic feeds containing soybean byproduct included exogenous DNA segments. We also compared genetically modified (GM) soybean with non-GM soybean diets in feeding tilapias (Oreochromis niloticus, GIFT strain) and examined the residual fragments (254 bp) of GM soybeans. Tilapias receiving GM soybean diets had DNA fragments in different tissues and organs, indicating that exogenous GM genes were absorbed systemically and not completely degraded by the tilapia's alimentary canal.

野大豆和栽培大豆抗盐分子标记的研究

野大豆群体3和群体4属盐渍群体，其个体有的是抗盐的，有的是敏感的，有的是中等抗盐的，本文通过随机扩增多态性DNA (RAPD)和DNA扩增指纹(DAF)分析野大豆群体抗盐性与分子标记之间的关系，从而更好地研究野大豆群体的盐适应机理。通过12个RAPD引物和3个DAF引物扩增发现：引物OPF05，OPF19和OPH02的扩增产物中有与抗盐性可能相关的特异标记，分别是OPF05_(213);OPF19_(4361);OPF19_(1727);OPF19_(1400);OPF19_(700);OPH02_(1350)。这些特异标记在所研究的抗盐植株中都存在;在敏感型植株中都不存在;在中等抗盐植株中有的存在，有的不存在。以上表明野大豆群体的抗盐性与RAPD分子标记有一定的相关性。为进一步研究抗盐性的特异标记，本文对栽培大豆抗盐品种Morgan和文丰七号的特异DAF标记片断8-27_(240) (Zhong et al., 1997)进行了克隆测序，测序结果通过BLASTn程序与基因库中的基因序列进行同源比较，发现上的DNA序列中的19组（每组大约二十到三十个碱基）序列与基因库中的其它基因相应序列有很高的同源性，几乎全部100%同源。尤其目的序列第15个碱基到第33个碱基（共19个碱基）之间的序列与基因库中的25个基因的相应序列的同源性全部是100%，并且与之相比的基因大多来自动物和人。因而推测其有可能是保守区，而不是编码区。进一步用DNASIS软件分析其碱基组成(A/T含量是64.9%，G/C含量是35.1%)并进行翻译，结果同样表明此序列可能是一调控序列并非编码区。至于这段序列是否与抗盐紧密相关，这有待于以后把此序列转到敏感型植株中然后检测其抗性来验证。 本文还通过RAPD分析野大豆群体3和群体4的多态性，发现群体3的多态性明显高于群体4。野大豆群体3的抗盐性大于群体4早已通过生理指标的鉴定，至于多态性与抗盐性之间是否有必然联系，还需进一步研究讨论。利用RAPD数据，通过MEGA软件中的NJ计算遗传距离的方法对群体3和4进行聚类分析，研究野大豆群体间及群体内个体间的亲缘及进化关系，探讨野大豆群体盐适应机理的分子起源。