金线侧褶蛙和泽陆蛙的两性异形与生育力

比较金线侧褶蛙和泽陆蛙的两性异形和生育力,首次通过种间比较来验证生育力选择理论是否能解释两栖动物两性异形的进化。金线侧褶蛙和泽陆蛙均为雌体大于雄体的两性异形类型,其两性异形程度存在显著差异,金线侧褶蛙两性异形程度指数为0 .30 ,而泽陆蛙仅为0 .0 8。然而,两者的怀卵量无显著差异。因此,结果与生育力选择理论预测不一致。此种不一致性可能由下述原因导致:选择压力作用于雄体而非雌体、能量分配策略和死亡率的种间差异、以及系统发育历史的种间差异。金线侧褶蛙和泽陆蛙雄体的身体状态指数显著高于雌体。金线侧褶蛙的头,眼和四肢都显著大于泽陆蛙;两者雌体的前后肢长度显著大于雄体。两性金线侧褶蛙的前后肢随体长呈同速生长,而泽陆蛙的前后肢随体长呈异速生长     

北京猛禽寄生合饰带属旋尾线虫的报道及一新种记述(线虫纲,针形总科,针形科)

记述了寄生于北京猛禽体内的2种合饰带属线虫,其中一种为新种,一种为中国新纪录种.标本保存于北京师范大学生命科学学院.红角鸮合饰带线虫Synhimantus(Dispharynx)oti sp.nov.(图1～7)新种与Synhimantus(Dispharynx)capitata(Molin,1860)和S.(D.)buccalis(Gogoi and Sarmah,1988)较相似,但新种在第5对肛后乳突内侧有1对无柄乳突,左交合刺末端分叉,饰带长而与S.(D.)capitata有明显区别.新种与S.(D.)buccalis的主要区别为肛后乳突5对,左交合刺短,颈乳突三叉状位于饰带之后,阴门位于体中之前.正模♂,副模♀,采自红角鸮Otus scops(Linnaeus,1758)的食道.词源:新种的种名来自宿主名.纵纹腹小鸮合饰带线虫乌兹别克斯坦亚种Synhimantus(Dispharynx)noctuae uzbehistanica(Sultanov,1950)中国新纪录(图8～10)从纵纹腹小鸮Athene noctua(Scopoli,1769)的食道和口腔中采到3条雄虫.作者所采标本与Sultanov(1950)的原始描述基本相同,但前者饰带稍有波浪状的弯曲而原始描述为直的.     

人胎海马内nNOS神经元的形态学观察

目的研究胎儿海马内nNOS神经元的分布、形态的变化以及意义.方法采用ABC免疫细胞化学法结合DAB显色技术研究人胎儿海马内nNOS神经元的定位和分布.结果人胎脑13周开始有少量的nNOS的表达,20周后随着胎龄的增加含nNOS阳性神经元数量逐渐增加,于28周海马内nNOS神经元数量最多,随后数量逐渐减少;阳性神经元胞体体积随着胎龄的增加逐渐增大;根据细胞形态nNOS阳性神经元可分两种类型,其比例随着胎龄的变化而变化.结论人胎海马存在有nNOS阳性神经元的表达,且呈两种不同的形态.     

p38MAPK介导的胶质细胞iNOS的转录激活机制

丝裂原激活蛋白激酶(MAPK)酶级联反应系统参与胶质细胞中iNOS的合成.通过瞬时转染p38MAPK途径中上游激酶,MAPK激酶3(MKK3)和MAPK激酶6 (MKK6 )表达质粒,进一步了解p38MAPK级联传导信号系统调节iNOS基因在胶质细胞中的转录激活机制.MKK3或MKK6表达质粒与接有荧光素酶(luciferase ,Luc)的大鼠iNOS启动基因质粒(iNOS Luc)联合转染C6星形胶质细胞株引起iNOS Luc的激活,并且使细胞因子诱导的iNOSmRNA的表达增强.这两种效应都能够被p38MAPK抑制剂SB2 0 35 80所抑制.MKK3 6也可以诱导核因子κB(NFκB Luc)依赖的转录活性.这些分子水平的研究结果为p38MAPK信号级联传导途径在调节大鼠胶质细胞中iNOS基因转录激活中的重要作用,包括转录因子NFκB的作用提供了证据.通过阻断iNOS表达或NO的生成,抑制细胞炎症发生,为防治神经细胞炎症反应性疾病提供实验依据.     

大头蛙Sox基因的克隆与序列分析

参考人SRY基因HMC—box的保守区序列,设计一对特异引物,采用PCR技术扩增了大头蛙的Sox基因,并对扩增产物进行了克隆与测序。结果在雌雄个体中均扩增出217bp的基因片段,与人对照相同。序列分析表明,大头蛙雌雄个体之间Sox序列没有差异,与人SOX基因的同源性达到88％,与其它各类动物的Sox基因也都有非常高的相似性。结果支持Sox基因在进化上十分保守的结论。     

重组Rhodobacter sphaeroides hemA表达的调控

RhodobactersphaeroideshemA编码5氨基乙酰丙酸合酶(ALAS),催化磷酸吡哆醛依赖性琥珀酰CoA和甘氨酸缩合成ALA.将R.spaeroideshemA导入E.coli进行表达,当hemA具有与lac启动子相同的转录方向时,ALAS有活性.lac启动子与hemA之间的距离会影响ALAS在不同培养基上的表达.E.coli宿主菌对ALAS表达、ALA产量有显著影响,在实验所用6种菌株中,E.coliDH1是最佳宿主菌(P<0.05).ALAS表达还与碳源有关,琥珀酸为碳源时,重组ALAS活性最高(P<0.05),以乳酸为碳源时,ALAS活性很低.重组ALAS活性也受培养基pH值影响,pH6.5时,活性最高(P<0.05).     

倭蛙属(无尾目:蛙科)肩带研究

对倭蛙属（Nanorana）已知3种：高山倭蛙（Nanorana parkeri）、倭蛙（N. pleskei）和腹斑倭蛙（N. ventripunctata）的肩带作了连续切片后进行Masson染色,发现其上喙骨（epicoracoid）的融合与重叠的状况与虎纹蛙（Rana rugulosa）较相似,而与无尾目中其它物种已知的肩带形态存在较大的差异.倭蛙属和虎纹蛙等与已知肩带类型的蛙亚科其它的物种在系统进化中可能来源于不同的最近共同祖先.     

肝破裂的治疗体会(附61例报告)

肝破裂在各种腹部损伤中占15％～20％,肝破裂后胆汁可流入腹腔,出现腹痛及腹膜刺激征,肝被膜下破裂有转为真性破裂的可能,故在腹部损伤中应注意有无肝破裂征象,及时作相应处理。我院2000-2003年共收治肝破裂61例。现将治疗体会报告如下。     

Genetic Transformation of Tobacco with the Trehalose Synthase Gene from Grifola frondosa Fr. Enhances the Resistance to Drought and Salt in Tobacco

Trehalose is a non-reducing disaccharide of glucose that functions as a protectant in the stabilization of biological structures and enhances the tolerance of organisms to abiotic stress. In the present study, we report on the expression of the Grifolafrondosa Fr. trehalose synthase (TSase) gene for manipulating abiotic stress tolerance in tobacco (Nicotiana tabaccum L.). The expression of the transgene was under the control of two tandem copies of the CaMV35S promoter and was transferred into tobacco by Agrobacterium tumefaciens EHA105. Compared with non-transgenic plants, transgenic plants were able to accumulate high levels of products of trehalose, which were increased up to 2.126-2.556 mg/g FW, although levels were undetectable in non-transgenic plants. This level of trehalose in transgenic plants was 400-fold higher than that of transgenic tobacco plants cotransformed with Escherichia coli TPS and TPP on independent expression cassettes, twofold higher than that of transgenic rice plants transformed with a bifunctional fusion gene (TPSP) of the trehalose-6-phosphate (T-6-P) synthase (TPS) and T-6-P phosphatase(TPP) of E. coil, and 12-fold higher than that of transgenic tobacco plants transformed the yeast TPS1 gene.It has been reported that transgenic plants with E. coil TPS and/or TPP were severely stunted and had morphological alterations of their roots. Interestingly, our transgenic plants have obvious morphological changes, including thick and deep-coloured leaves, but show no growth inhibition; moreover, these morphological changes can restore to normal type in T2 progenies. Trehalose accumulation in 35S-35S:TSase plants resulted in increased tolerance to drought and salt, as shown by the results of tests on drought, salt tolerance, and drought physiological indices, such as water content in excised leaves, malondialdehyde content, chlorophyll a and b contents, and the activity of superoxide dismutase and peroxidase in excised leaves. These results suggest that transgenic plants transformed with the TSase gene can accumulate high levels of trehalose and have enhanced tolerance to drought and salt.