叶绿体类囊体膜多肽与细胞质雄性不育性

本实验利用单向SDS-PAGE及双向电泳技术,比较了玉米、甜菜和高粱三种作物的细胞质雄性不育系与其保持系之间叶绿体类囊体膜多肽的差异。结果表明,三种供试材料的不育系与其相应的保持系之间类囊体膜多肽的单向SDS-PAGE中,除个别条带染色深度有一些差异外,没有观察到明显的差异。但是,在双向电泳图式中,两系之间在33kd附近肽斑的大小、数量与分布方面显示出明显的差异,从而暗示,叶绿体类囊体膜多肽的组成与细胞质雄性不育性之间可能存在某种联系。此外,试验还表明,单向SDS-PAGE条带,几乎都是分子量相同而等电点不尽相同的一组多肽混合物;在双向电泳图谱上,它们可按等电点的差异分成若干个不同的多肽斑点。     

成年牦牛与双性牦牛睾丸蛋白质双向电泳的比较研究

为了比较牦牛和双性牦牛睾丸组织中蛋白质的差异表达,以探索双性牦牛生殖障碍的机理。提取牦牛睾丸(n=4)和1头双性牦牛睾丸总蛋白质,采用双向电泳分离后,对差异表达蛋白质点进行质谱鉴定。实验获得了分辨率高、重复性好的牦牛与双性牦牛睾丸组织蛋白质的双向电泳图谱,2倍及以上差异表达的蛋白质24个,其中22个蛋白质经质谱分析和数据库搜索后得到鉴定。有6种蛋白质属于分子伴侣,在双性牦牛睾丸组织中表达量显著下降,推测与双性牦牛精子发生障碍有关。     

猪卵母细胞蛋白质组双向电泳体系的建立及初步分析

建立了猪(Sus scrofa)卵母细胞蛋白质双向电泳平台,并对裂解液的组成、样品处理、双向电泳程序等相关技术进行优化,得到清晰的微量卵母细胞蛋白质的电泳图谱.利用上述优化后的体系分别对未成熟和成熟的猪卵母细胞进行双向电泳分析,并用ImageMaser软件对图谱进行比对分析.结果表明,电泳图谱上大约有800个左右的蛋白点,其中差异蛋白35个,包括上调蛋白22个及下调蛋白13个.说明基于双向电泳的蛋白质组学可以用于卵母细胞成熟的蛋白表达差异的研究.     

肝癌亚细胞结构的蛋白质组分比较分析

运用亚细胞蛋白质组学的研究策略,分离纯化亚细胞结构,可以提高低丰度蛋白质在双向电泳中检出的数量。通过对比分析肝癌细胞与正常肝细胞线粒体、细胞核蛋白质组的差异表达情况,为肝癌发病机理的研究提供更多、更有价值的信息。以体外培养的人体肝癌细胞QGY-7703与正常肝细胞LO2为研究模型,通过超离心的方法分离细胞的线粒体和细胞核。双向电泳分离线粒体和细胞核的蛋白质,图像分析筛选差异表达蛋白斑点,MALDI-TOF-MS鉴定蛋白质。从线粒体、细胞核的蛋白质电泳图谱中筛选出54个候选差异表达的蛋白质斑点,质谱鉴定出22种差异表达蛋白质,其中17种在肝癌细胞中表达上调,5种在肝癌细胞中表达下调。筛选出的差异表达蛋白质涉及到细胞的能量代谢、蛋白质合成、细胞骨架与核骨架的改变、mRNA的加工成熟及凋亡调控等许多方面,表明癌变细胞的组织结构和代谢状态都发生了很大的变化。     

结肠癌蛋白质双向电泳技术的建立

目的:建立结肠癌13cm和24cm非线性分离系统的2-D图谱,分析比较两者的分辨率.方法:提取结肠癌总蛋白,用pH3-10非线性干胶条对样品进行等电聚焦分离,并分别使用13cm和24cm电泳系统进行双向电泳,考马斯亮蓝G250染色,图像分析,比较对比两组2-D图谱,量化分析两种系统的分辨率差异.结果:在等点电3-10,分子量20-170 kD范围内分别分离得到蛋白质斑点873个(13 cm电泳系统)和1349个(24cm电泳系统).对于24cm电泳系统,1 mg蛋白质上样量的电泳图谱清晰,分辨率较好.结论:成功建立了高分辨率、简便易控的结肠癌蛋白质组双向电泳技术平台.     

妊娠过程中血清蛋白的动态变化

利用聚丙烯酰胺凝胶(PAG)电泳分离技术对266份不同孕期的正常孕妇和妊娠高血压综合征病人的血清蛋白电泳图谱进行了分析。在266份图谱中发现41个染色深度有变化的组分,代表血清蛋白含量的变化。在正常中期妊娠电泳图谱中少数呈1个或2个“V”形异常成分位于P区或O段、M段,其意义尚难肯定。在妊娠高血压综合征病例中没有发现特异性异常蛋白,但血清前白蛋白、白蛋白减少与T-77组分增多和同期正常孕妇相比有显著差异(p<0.05)。     

牦牛生态类型的分类

为进一步弄清中国牦牛的遗传资源及其类型划分,利用微卫星DNA、随机扩增多态性（RAPD）、扩增片断长度多态性（AFLP）等3种分子遗传标记技术研究了麦洼牦牛、九龙牦牛、大通牦牛和天祝白牦牛的分类;并结合作者对牦牛染色体和血液蛋白多态性的研究结果探讨了中国牦牛类群的分类.结果：①根据微卫星位点的等位基因频率进行聚类分析,表明麦洼牦牛和九龙牦牛的遗传距离最大（1.506）,麦洼牦牛2个群体之间的遗传距离最小（1.062）.5个牦牛群体被聚为两大类,四川九龙牦牛单独成一大类,其他牦牛群体聚为一类.②根据RAPD和AFLP两种分子遗传标记的分析,表明天祝牦牛和大通牦牛的遗传距离最小（0.0336）,九龙牦牛和天祝牦牛的遗传距离最大（0.0414）,4个牦牛品种被聚为两大类,九龙牦牛品种聚为一类,其它3个牦牛品种聚为一类.大通牦牛和天祝白牦牛在较近的水平上首先聚为一类,然后在较远处与麦洼牦牛聚为一大类.③根据染色体特征和血液蛋白位点的基因频率进行聚类的结果与微卫星DNA、RAPD、AFLP的聚类结果相似.中国牦牛可分为以九龙牦牛和麦洼牦牛为代表的两个类群（型）.这与蔡立等将中国牦牛分为“青藏高原型”和“横断高山型”的结果是一致的.而与其他学者的分类结果有较大的差异.结合中国牦牛品种（群体）的地理分布、生态条件、育成史及其分化的实际情况,作者认为中国牦牛分为两个大的生态类型是合理的.     

双向电泳联合MALDI-TOF-MS技术在筛选食管癌铂类耐药患者中的应用研究

目的:采用基质辅助激光解吸电离飞行时间质谱(MALDI-TOF-MS)技术检测食管癌(EC)患者化疗敏感性血清蛋白质谱,指导临床EC患者化疗方案的选择。方法:收集2013年1月至2014年6月我院收治的EC术后复发并行含铂化疗的患者40例,按照化疗疗效分为敏感组和耐药组。将两组蛋白质双向凝胶电泳图谱用Image Master 2D platinum 5.0软件分析并匹配,筛选出两组差异斑点,并采用MALDI-TOF-MS技术检测EC患者化疗敏感性血清蛋白质谱。结果:两组差异斑点共有68个,以耐药组为参照,敏感组患者血清蛋白下调的斑点有42个,上调的斑点有26个。从这68个差异斑点中筛选出8个斑点进行质谱鉴定,通过数据库检索分析和鉴定最终确定上述斑点所对应的蛋白质名称分别为Kininogen-1,Alpha-2-HS-glycoprotein,Fibrinogen beta chain,Clusterin,Retinol-binding protein 4,Beta-2-glycoprotein 1,Ig kappa chain C region,Complement C4-A。结论:基于铂类化疗的EC敏感患者和耐药患者间存在差异表达蛋白。     

猪卵泡液样品制备方法对双向电泳图谱的影响

比较不同的蛋白制备方法,寻找适合猪卵泡液的双向电泳样品制备方法,提高2-DE图谱的分辨率和重复性。利用ProteoExtract Albumin/IgG Remove Kit去除卵泡液中的高峰度蛋白;然后分别用丙酮沉淀法、TCA/丙酮沉淀法和超滤法进行样品浓缩,比较分析对2-DE图谱的影响。结果表明,TCA/丙酮沉淀法制备的蛋白样品获得的电泳图谱质量较好,蛋白斑点数目较多,斑点较清晰、圆滑,分辨率较高,重复性较好。TCA-丙酮沉淀法更适合于制备猪卵泡液的双向电泳蛋白样品,为进一步对猪卵泡液2-DE图谱进行分析、鉴定及寻找生物标记物提供了保证。     

普通小麦线粒体蛋白质的双向电泳分析

采用改良的IEF-SDS双向电泳技术对普通小麦(T.aestivum L.)线粒体蛋白质进行了分析。电泳结果表明:改良后的电泳系统稳定性和重复性较好,并且分辨率较高;考马斯亮蓝染色图谱中线粒体多肽呈现150—180个斑点;本文还就一些技术理论等问题进行了讨论。     

西藏牦牛mtDNA D-loop区的遗传多样性及其遗传分化

通过测定和分析西藏11个牦牛类群114个个体的mtDNA D-loop区全序列,对西藏牦牛的遗传多样性、类群间的亲缘关系及其遗传分化进行了研究。结果表明:①西藏牦牛mtDNA D-loop区全序列长度为890—896 bp,4种核苷酸T、C、A、G的平均比例分别为28.5%、25.3%、32.4%、13.8%,西藏牦牛mtDNA D-loop区富含碱基A+T,表现出一定的碱基偏好性。②共检测到130个变异位点,占分析总位点数的14.33%;其中单一多态位点85个,占多态位点总数的65.38%,简约信息位点45个,占多态位点总数的34.62%。序列变异中碱基缺失、插入和碱基替换等均有,其中碱基替换变异类型中转换114次,颠换12次,在转换变异类型中以A/G、T/C为主,占95.61%,在颠换变异类型中以A/T为主,占75%。③在114个个体中鉴定出90种单倍型,单倍型多样性为0.981±0.008,核苷酸多样性为0.01056±0.00701,均说明西藏牦牛具有丰富的单倍型类型。④90种单倍型分为2个聚类簇(Ⅰ、Ⅱ),聚类簇Ⅰ包含80种单倍型,占全部单倍型的88.89%,涵盖本研究中所有的西藏牦牛类群;聚类簇Ⅱ中有10种单倍型,占单倍型总数的11.11%,涉及的类群有工布江达、帕里、丁青、巴青、江达、类乌齐、桑桑、桑日、斯布,说明西藏牦牛可能有2个母系起源。⑤西藏牦牛类群间核苷酸分歧度(Dxy)在0.503%—1.416%之间,聚类分析和AMOVA分析显示西藏牦牛可分为两大类,康布牦牛、嘉黎牦牛为一类,其余的牦牛类群为另一类。     

Assessment of cattle genetic introgression into domestic yak populations using mitochondrial and microsatellite DNA markers

Hybridization between yak Poephagus grunniens and taurine Bos taurus or indicine B. indicus cattle has been widely practiced throughout the yak geographical range, and gene flow is expected to have occurred between these species. To assess the impact of cattle admixture on domestic yak, we examined 1076 domestic yak from 29 populations collected in China, Bhutan, Nepal, India, Pakistan, Kyrgyzstan, Mongolia and Russia using mitochondrial DNA and 17 autosomal microsatellite loci. A cattle diagnostic marker‐based analysis reveals cattle‐specific mtDNA and/or autosomal microsatellite allele introgression in 127 yak individuals from 22 populations. The mean level of cattle admixture across the populations, calculated using allelic information at 17 autosomal microsatellite loci, remains relatively low (mY_cattle = 2.66 ± 0.53% and Q_cattle = 0.69 ± 2.58%), although it varies a lot across populations as well as among individuals within population. Although the level of cattle admixture shows a clear geographical structure, with higher levels of admixture in the Qinghai‐Tibetan Plateau and Mongolian and Russian regions, and lower levels in the Himalayan and Pamir Plateau region, our results indicate that the level of cattle admixture is not significantly correlated with the altitude across geographical regions as well as within geographical region. Although yak‐cattle hybridization is primarily driven to produce F₁ hybrids, our results show that the subsequent gene flow between yak and cattle took place and has affected contemporary genetic make‐up of domestic yak. To protect yak genetic integrity, hybridization between yak and cattle should be tightly controlled.     

Comparative analysis of ISSR marker polymorphism in populations of yak (Bos mutus) and in F1 hybrids between yak and cattle in the Sayan-Altai region

The genetic variability in seven yak populations from the Sayan-Altai region and in F₁ hybrids between yak and cattle (khainags) was investigated with the help of a technique that involves the use of inter simple sequence repeat (ISSR) markers generated with PCR primers (AG)⁹C and (GA)⁹C. Samples for the analysis were collected in Mongolia, Tuva, and Altai from 2008 through 2012. The examined yak populations differed in in the presence/absence of ISSR fragments, as well as in their frequency. In total, 46 ISSR fragments were identified using two marker systems; the proportion of polymorphic loci constituted 76% and 90% for the AG-ISSR and GA-ISSR markers, respectively. For the total sample of yaks, total genetic diversity (H _t), within-population diversity (H _s), and interpopulation diversity (G _st) constituted 0.081, 0.044, and 0.459 for the AG-ISSR and 0.137, 0.057, and 0.582 for the GA-ISSR markers, respectively. Based on ISSR finger-printing, species- and breed-specific DNA patterns were described for the three groups of animals (yaks, cattle, khainags). For the domestic yak, the species-specific profile was represented by eight ISSR fragments. Genetic relationships between the yak populations, cattle breeds, and khainags were examined with the help of four different approaches used in the analysis of population structure: estimation of phylogenetic similarity, multidimensional scaling, principal component analysis, and cluster analysis. Clear evidence on the differentiation of the populations examined at the interspecific, as well as at intraspecific, level were obtained. Similar (relative), as well as remote (isolated), yak populations were identified. Khainags occupy an intermediate position between yak and cattle. However, the data on the ISSR-PCR marker polymorphism (genome polymorphism, population structure) indicate that part of the analyzed khainag genome was more similar to the yak genome than to the cattle genome.     

西藏牦牛SRAP遗传多样性及分类进化研究

用4对SRAP分子标记引物对西藏11个牦牛类群和四川麦洼牦牛的DNA进行扩增,研究其遗传多样性和分类关系。结果表明,在335头牦牛中,共得到29个基因位点,其中有19个多态位点,多态率占65.52%。12个牦牛群体间的Nei’s遗传多样性和Shannon多样性指数分别为0.048 2和0.073 4,遗传相似系数在0.781 1-0.989 1。巴青牦牛和康布牦牛的遗传多样性指数较其他类群高,分别为0.095 5和0.090 0;桑日牦牛类群的遗传多样性指数最低,仅为0.008 5。这些结果表明,12个牦牛类群的SRAP遗传多样性较低。根据Nei’s遗传距离,利用UPGMAM构建聚类关系图结果显示,嘉黎牦牛、帕里牦牛、类乌齐牦牛、桑桑牦牛、康布牦牛、巴青牦牛、丁青牦牛、斯布牦牛和麦洼牦牛聚为一大类,然后依次才与桑日牦牛、工布江达牦牛和江达牦牛相聚在一起,显示在SRAP分子遗传标记所反映的牦牛基因组的遗传结构中,江达牦牛、工布江达牦牛和桑日牦牛与其他牦牛群体间的亲缘关系较远,牦牛的这种亲缘关系与其地理分布也不一致,说明这12个牦牛的起源、演化关系较复杂,有待于进一步研究分析。     

Genetic Diversity and Divergence in Chinese Yak (Bos grunniens) Populations Inferred from Blood Protein Electrophoresis

In 6 Chinese yak (Bos. Grunniens) populations including 177 yaks, 34 blood protein loci were studied by horizontal starch gel electrophoresis, four of these loci (AKP, ALB, LDH-1, TF) were found to be polymorphic. The percentage of polymorphic loci(P) is 0.118, the mean individual heterozygosity(H) is 0.015, which means a low level of genetic diversity in the whole Chinese yak population. The coefficient of gene differentiation (G _ST ) is 0.0625, which indicated an almost-indistinguishable divergence among different populations at the level of blood protein electrophoresis.     

Genetic Structure and Differentiation of Three Chinese Indigenous Cattle Populations

Levels of genetic differentiation, gene flow, and genetic structure of three indigenous cattle populations (Luxi, Bohai, and Minnan) and two reference cattle populations (Chinese Holstein and Qinhai yak) in China were estimated using the information from 12 microsatellites, and 141 microsatellite alleles were identified. The mean number of alleles per locus ranged from 2.9005 in yak to 4.9722 in Holstein. The observed heterozygosity ranged from 0.5325 (yak) to 0.7719 (Holstein); 29 private alleles were detected. The global heterozygote deficit across all populations amounted to 58.5% (p < 0.001). The overall significant (p < 0.001) deficit of heterozygotes because of inbreeding within breeds amounted to 43.2%. The five cattle populations were highly differentiated (F _st = 26.9%, p < 0.001) at all loci. The heterozygote deficit within the population was highest in Luxi cattle and lowest in yak. The average number of effective migrants exchanged per generation was highest (1.149) between Luxi and Holstein, and lowest (0.509) between Luxi and yak. With the application of prior population information, cluster analysis achieved posterior probabilities from 91% to 98% of correctly assigning individuals to populations. Combining the information of cluster analysis, gene flow, and Structure analysis, the five cattle populations belong to three genetic clusters, a taurine (Luxi and Chinese Holstein), a zebu (Bohai and Minnan), and a yak cluster. This indicates that Bohai black is closer to Bos indicus than Luxi cattle. The evolution and development of three indigenous cattle populations are discussed.     

2000-2015年祁连山南坡生态系统服务价值时空变化

祁连山是我国西部重要的生态安全屏障和生物多样性保护优先区域,其中南坡地区是水源涵养服务核心区,但目前对该区域生态系统服务时空分布及动态变化仍缺乏深入认识。利用遥感技术和生态系统服务理论,综合多源数据产品,借鉴生态系统服务计算方法,对包括土壤保持等7个生态系统服务类型展开功能及价值核算,对祁连山南坡土壤保持等7个生态系统服务类型2000-2015年间的时空分异及动态展开监测和评估,研究表明：（1）近16年来祁连山南坡生态系统服务平均单位面积价值为76.27万元/km²,总价值为658.74亿元,且调节气候、水源涵养和调节空气质量服务构成了研究区生态系统服务的主体。（2）高寒草甸和高寒草原的生态系统服务总价值最高,而森林和灌丛的单位面积服务价值最高;天峻县和祁连县的生态系统服务总价值最高,而海晏县和刚察县的单位面积服务价值最高。（3）近16年来祁连山南坡生态系统服务价值呈增长趋势,其中调节气候和调节空气质量服务价值的增速最快,且增长区域主要集中在研究区北部祁连县和天峻县境内。（4）研究区东部山区、南部环湖区以及中部湿地区能够提供多项复合生态服务功能,应作为生态保护和管理的重点。研究结果能为祁连山生态红线制定及国家公园建设提供理论依据和技术支撑。     

高寒草甸生态系统牲畜种群的线性规划模型和最优化利用策略

本文研究了高寒草甸生态系统牲畜种群的线性规划模型和最优利用策略。以门源马场牧场的实际数据作为模型的一个例子,分别提出了藏羊、改良羊和牦牛的最优种群结构和最优出栏方案。在改良羊、藏羊、牦牛和马为主的牧场上,改良羊是牧场上的主要牲畜,牦牛和马保持其数量下限,藏羊全部淘汰。在藏羊、牦牛和马为主的牧场上,藏羊是牧场上的主要牲畜,牦牛和马保持其数量下限。按照线性规划模型方案经营,可提高经济收益,并减轻冬舂草场上牲畜的过多采食。价格分析说明青海省现行的畜产品价格体系需要调整。