4种小鼠的寒、热体质研究

[目的]研究4种品系小鼠的寒、热体质。[方法]8~9周龄昆明、BALB/c、C57BL/6J、ICR小鼠,以及4~5周龄昆明小鼠,同步系统检测其生物学特性,然后以统一的评价标准评价4种品系小鼠的寒、热体质。并对BALB/c小鼠给予参桂理中丸和利血平做药物反证。[结果]①4~5周龄昆明小鼠与8~9周龄昆明小鼠比较体质明显偏热;②BALB/c小鼠与C57BL/6J小鼠比较体质偏寒;③8~9周龄雄性BALB/c小鼠、雄性和雌性C57BL/6J小鼠与8~9周龄相应性别昆明小鼠比较体质无明显差异;8~9周龄雌性BALB/c小鼠与8~9周龄雌性昆明小鼠比较体质偏寒;④8~9周龄ICR小鼠与8~9周龄BALB/c小鼠、C57BL/6J小鼠比较体质偏热;8~9周龄雄性ICR小鼠与8~9周龄雄性昆明小鼠比较体质偏热。[结论]4种品系小鼠存在寒、热体质差异。     

BALB/c小鼠遗传质量检测的新方法

目的比较随即扩增多态性方法（RAPD）、微卫星方法（STR）与生化标记方法对近交系小鼠遗传质量检测的差异,为近交系动物遗传质量控制提供一种分子生物学方法。方法提取近交系小鼠BALB/c基因组DNA,用6条RAPD引物和20对STR引物对其进行PCR扩增,用生化标记法检测13个位点。结果在6条RAPD引物中,引物2（p2）、引物3（p3）、引物5（p5）和引物6（p6）这四条引物扩增的条带出现差异,表现为不同的RAPD图谱;在20对STR引物中,引物2、4、10和11,这四对引物扩增的条带出现差异,表现为不同的STR图谱;13个生化标记位点中,过氧化氢酶-2（Ce-2）等6个生化位点发现杂合基因。结论RAPD和STR可用于验证生化标记方法的实验结果,并用于保证近交系动物的遗传质量。     

辽宁省6种常用近交系小鼠10个微卫星位点的遗传质量检测报告

目的利用微卫星技术对辽宁省6种近交系小鼠进行遗传质量分析。方法根据Mouse Genome Database和相关文献选取10个多态信息丰富的位点和引物,进行PCR扩增和PAGE电泳,对小鼠的遗传多态性进行研究。结果不同品系小鼠同一位点的扩增结果表现出多态性,同一品系同一位点表现单态性,所有小鼠的10个位点都处于纯合状态;遗传距离分析表明,C57BL/10与C57BL/6J小鼠之间的遗传距离最近,为0.1021,遗传距离最远的是BALB/c与C57BL/10、C57BL/6J,分别为0.1635和0.1614。结论运用所筛选的10个微卫星位点可以对近交系小鼠进行遗传质量检测,说明该方法具备可行性。     

基于RAPD的群体标记法分析苜蓿种质遗传多样性

苜蓿种质资源的分子遗传多样性分析对于种质资源保存和育种利用具有重要指导意义。本研究选用群体标记法对来自甘肃省的16个苜蓿品种的DNA进行RAPD扩增,旨在研究其遗传多样性,并在此基础上筛选品种特异性引物用于进一步的品种鉴定。依据16个苜蓿品种间的Roger’s遗传距离进行UPGMA聚类分析结果显示,品种间亲缘关系与其选育背景紧密相关,供试的16个品种被划为4个类群,其中,匍匐型品种Jindera与其他直立型品种差异显著,自成1个类群,引进品种和甘肃省内具有国外种质来源的育成品种被划为同1类群,而甘肃地方品种聚为2个类群。10个RAPD引物中有4个引物OPE4、OPE5、OPE6和OPE7分别检测到5个品种甘农3号、甘杂27、Jindera、陇东和Algonuin的特异性条带,可进一步用于开发设计特异性引物进行品种鉴定工作。以上结果进一步证实,利用RAPD标记研究苜蓿系谱发育关系和选择杂交亲本应采用群体标记法。     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA(randomamplifiedpolymorphicDNA,RAPD)技术获得与大麻性别连锁的分子标记.将10株雄性大麻或10株雌性大麻的单个DNA样品等量混合分别组成雄性或雌性DNA池(DNApool),以提供具有相同遗传背景的雌、雄性DNA样品.每个随机引物分别用三个不同的循环程序进行PCR扩增.在30个随机引物中,用引物401扩增得到一条约2.5kb雄性多态性片段.对该片段进行了克隆和序列分析,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR(sequencecharacterizedamplifiedregions)分子标记.     

东方田鼠特异DNA片段的克隆及核苷酸序列分析

目的获得东方田鼠的特异DNA序列.方法Aβ基因使用PCR,基因克隆,斑点杂交,DNA序列分析,生物信息学技术.结果根据小鼠MHCⅡ外显子2及其两侧序列,合成引物并扩增东方田鼠基因组DNA,将PCR产物回收、测序后,分别设计内引物扩增东方田鼠基因组DNA,其中一对引物可得到特异性扩增带,将得到的DNA片段插入PGEM-Teasy载体,进行序列分析.用这对引物扩增人、昆明小鼠、BALB/c小鼠及C57BL/6J小鼠基因组DNA,均无扩增产物.以东方田鼠特异性扩增产物为探针进行斑点杂交,除东方田鼠基因组DNA外,其他几种动物基因组DNA均为阴性结果.进一步对该DNA片段进行了BLAST同源性搜索和外显子预测,在Genbank中没有发现高度同源序列,并且找到一个可能的外显子,该外显子由69个氨基酸组成.结论获得的DNA片段为东方田鼠的特异片段,这将为从分子水平深入研究东方田鼠的遗传背景、生物进化规律以及东方田鼠抗日本血吸虫的机理奠定基础.     

柚类种质资源RAPD标记研究的引物筛选

利用 10 0个 10碱基随机引物 ,对柚类 4个品种酸柚、沙田柚、文旦柚和泰国柚进行了RAPD标记的引物筛选研究 ,结果为无扩增产物的引物 18个 ,在 1、 2、 3个和所有 4个样品中有扩增产物的引物数分别为 2 0、 13、 2 5和 2 4个 ;读取了 12个在所有 4个样品中都有扩增产物的引物的 RAPD带 ,计算了样品间 RAPD多态性位点的百分率为 60 .6% ;计算了样品间的相似系数和遗传距离 ,并对遗传距离进行了 UPGMA聚类分析 ,论证了利用所筛选出的引物对柚类进行 RAPD标记研究的可行性和可靠性     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA（random amplified polymorphic DNA,RAPD)技术获得与大麻性别连锁的分子标记,将10株雄性大麻或10株雌性麻的单个DNA样品等量混合分别组成雄性或雌性DNA池（DNApool),以提供具有相同遗传背景的雄,雄性DNA样品。每个随机引物分别用三个不同的循环程序进行PCR扩增,在30个随机引物中,用引物S401扩增得到一条约2．5kb雄性多态性片段,对该片段进行了克隆和序列分析 ,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR（Sequence characterized amplified regions)分子标记。     

大血藤DNA提取及RAPD研究初探

以浙江天台山大血藤为材料,对其DNA提取和RAPD分子标记方法进行了研究。结果表明:所采用的经改进的SDS提取法可获得高质量的大血藤DNA,分子量大于23kb,可满足RPAD扩增;用15个不同的随机引物对所提取的12个个体的大血藤DNA进行了RAPD分子标记分析,其中14个引物扩增产物具有多态性。建立了大血藤DNA提取和RAPD标记的分析程序,为RAPD分析应用于大血藤遗传多样性研究打下了良好的基础。     

不同品系小鼠在三种常见抑郁检测方法中的行为学表现

目的探讨4种不同品系小鼠在3种实验（空场实验、悬尾实验及强迫游泳实验）中的行为学差异,为抗抑郁新药研究中的实验动物选择提供参考。方法利用空场实验检测C57BL/6、BALB/c、ICR、和昆明小鼠的自主活动能力和对新奇环境的探索能力;利用悬尾实验和强迫游泳实验检测它们在应激刺激下的行为绝望状态。结果在空场实验中,BALB/c、ICR和昆明小鼠的运动总路程、运动速度和运动时间明显高于C57BL/6小鼠（P〈0.05）,ICR和昆明小鼠的直立次数也明显高于C57BL/6小鼠（P〈0.05）;悬尾实验C57BL/6小鼠的不动时间显著长于其他3种品系小鼠（P〈0.05）,但是4种品系小鼠在强迫游泳实验中的不动时间差异无显著性。结论 C57BL/6小鼠自发活动量低,对新奇环境的探索能力差,并且在急性应激刺激下容易造成行为绝望,因此C57BL/6小鼠可能适合作为急性应激抑郁模型动物。     

CHARACTERIZATION OF GENETIC MARKERS LINKED TO SEX DETERMINATION IN THE HAPLOID‐DIPLOID RED ALGA GRACILARIA CHILENSIS1

Bulk segregant analysis, random amplified polymorphic DNA (RAPD), and sequence characterized amplified region (SCAR) methods were used to identify sex‐linked molecular markers in the haploid‐diploid rhodophyte Gracilaria chilensis C. J. Bird, McLachlan et E. C. Oliveira. One hundred and eighty 10 bp primers were tested on three bulks of DNA: haploid males, haploid females, and diploid tetrasporophytes. Three RAPD primers (OPD15, OPG16, and OPN20) produced male‐specific bands; and one RAPD primer (OPD12), a female‐specific band. The sequences of the cloned putative sex‐specific PCR fragments were used to design specific primers for the female marker SCAR‐D12‐386 and the male marker SCAR‐G16‐486. Both SCAR markers gave unequivocal band patterns that allowed sex and phase to be determined in G. chilensis. Thus, all the females presented only the female band, and all the males only the male band, while all the tetrasporophytes amplified both male and female bands. Despite this sex‐specific association, we were able to amplify SCAR‐D12‐386 and SCAR‐G16‐486 in both sexes at low melting temperature. The differences between male and female sequences were of 8%–9% nucleotide divergence for SCAR‐D12‐386 and SCAR‐G16‐486, respectively. SCAR‐D12‐386 and SCAR‐G16‐486 could represent degenerated or diverged sequences located in the nonrecombining region of incipient sex chromosomes or heteromorphic sex chromosomes with sequence differences at the DNA level such that PCR primers amplify only one allele and not the other in highly specific PCR conditions. Seven gametic progenies composed of 19 males, 19 females, and the seven parental tetrasporophytes were analyzed. In all of them, the two SCAR markers segregated perfectly with sexual phenotypes.     

Development of SCAR marker linked to anthracnose resistance from Indian French bean (Phaseolus vulgaris L.) germplasm

This study was performed to identify the French bean genotypes resistant to anthracnose disease. Thirty-five RAPD primers were used for screening four resistant and nine susceptible French bean accessions. Of these, three RAPD primers, viz. OPAH16₇₀₀, OPN6₇₀₀ and OPS₉₀₀ showed polymorphic bands differentiating between resistant and susceptible genotypes. The RAPD primer OPAH16 was then selected for conversion into a SCAR marker. The polymorphic band present in the resistant line (D line) was eluted, cloned in pTZ57R/T cloning vector and was then transferred into DH5α Escherichia coli cells. The positively transformed clones were selected based on ampicillin resistance blue-white colony selection method. The plasmid DNA was isolated from transformed white colonies, sequenced and developed into SCAR marker SPAH 16. This SCAR marker SPAH 16 was then verified via PCR using the original French bean accessions.     

与小麦白粉病抗性基因Pm2紧密连锁RAPD标记的筛选研究

以２５６个随机引物对含小麦抗白粉病基因Ｐｍ２近等基因系进行ＲＡＰＤ分析,发现１７个随机引物的扩增产物在抗、感ＮＩＬｓ材料间表现多态性,且其中５个引物经４次以上重复,均获相同结果,其多态性标记分别为ＯＰＭ０８(１６００)、ＯＰＩ０４(１７００)、ＯＰＨ１９(１１００、ＯＰＥ０９(９００)及ＯＰＭ１６(８５０)。当以这５个随机引物对１４个已知含Ｐｍ２基因的抗病材料及９个不含Ｐｍ２基因的感病材料进行检测时,只有标记ＯＰＩ０４(１７００)在１２个抗病材料中出现（另两个抗病材料中未检测到）,而在９个感病材料中均未出现。进一步用 ＯＰI(０４)对１０２株（Ｃｈａｎｃｅｌｌｏｒｘ Ｕｋａ／８＊Ｃｃ）Ｆ２分离群体进行分析,估算出标记ＯＰＩ０４(１７００)与Ｐｍ２基因间的遗传距离为１２．２±３．３ｃＭ。     

Characterization of native <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> strains by PCR-RAPD based fingerprinting

Seventy isolates of Bacillus thuringiensis were isolated from soil samples collected from cotton fields. These isolates were characterized by randomly amplified poylmorphic DNA (RAPD) markers to determine their genetic diversity pattern based on their source of origin. Different random decamer primers were used for RAPD amplification, which generated a total of 1935 fragments; of these 1865 were polymorphic and 68 monomorphic. The primers OPA03, OPA08, OPD14, OPD19, OPD20, OPE17 and OPD19 produced 100% polymorphic fragments, whereas primers OPC06, OPC20 and OPD17 produced 20, 31 and 17 monomorphic fragments, respectively. When the RAPD banding pattern data was subjected to dendrogram construction, the 70 isolates fell into two separate clusters, cluster I and cluster II, which includes 26 and 44 B. thuringiensis isolates, respectively. These two main clusters were further divided into four subclusters at Eucledian distance of 150 and 80% similarity index. All primers showed amplification and indicated the good diversity of B. thuringiensis isolates. The RAPD pattern showed 4–10 bands per isolate, with MWt in the range of 0.4–3.5 Kb and an average of 193.5 fragments were produced per primer. The primer OPE17 was found to be the most discriminatory as it produced 286 polymorphic bands.     

Qualitative and quantitative characterization of RAPD variation among snap bean (Phaseolus vulgaris) genotypes

Ten snap bean (Phaseolus vulgaris) genotypes were screened for polymorphism with 400 RAPD (random amplified polymorphic DNA) primers. Polymorphic RAPDs were scored and classified into three categories based on ethidium bromide staining intensity. An average of 5.19 RAPD bands were scored per primer for the 364 primers that gave scorable amplification products. An average of 2.15 polymorphic RAPDs were detected per primer. The results show that primer screening may reduce the number of RAPD reactions required for the analysis of genetic relationships among snap-bean genotypes by over 60%. Based on the analysis of the distribution of RAPD amplification, the same number of polymorphic RAPDs were amplified from different genotypes for all RAPD band intensity levels. A comparison of RAPD band amplification frequency among genotypes for the three categories of bands classified by amplification strength revealed a measurable difference in the frequencies of RAPDs classified as faint (weakly amplifying) compared to RAPD bands classified as bold (strongly amplifying) indicating a possible scoring error due to the underscoring of faint bands. Correlation analysis showed that RAPD bands amplified by the same primer are not more closely correlated then RAPD bands amplified by different primers but are more highly correlated then expected by chance. Pairwise comparisons of RAPD bands indicate that the distribution of RAPD amplification among genotypes will be a useful criterion for establishing RAPD band identity. For the average pairwise comparison of genotypes, 50% of primers tested and 15.8% of all scored RAPDs detected polymorphism. Based on RAPD data Nei's average gene diversity at a locus was 0.158 based on all scorable RAPD bands and 0.388 if only polymorphic RAPD loci were considered. RAPD-derived 1 relationships among genotypes are reported for the ten genotypes included in this study. The data presented here demonstrate that many informative, polymorphic RAPDs can be found among snap bean cultivars. These RAPDs may be useful for the unique identification of bean varieties, the organization of bean germplasm, and applications of molecular markers to bean breeding.     

RAPD标记在山葡萄种质鉴定中的应用

采用修改后的CTAB 法获得了高质量的基因组DNA 。利用RAPD 标记技术对山葡萄7 份种质进行鉴定, 用4 个引物(从30 个引物中筛选)对试材进行PCR 扩增, 共扩增出30 条谱带, 平均每条引物产生7.5 条谱带, 其中21 条谱带为多态性谱带, 占总谱带数的70%。不同引物扩增的谱带数不同, 范围在6~9 条之间。利用4 个引物扩增出的多态性谱带可以将7 份山葡萄种质区分。     

Detection of Intra-Clonal Genetic Variability in Vegetatively Propagated Tea Using RAPD Markers

The role of random amplified polymorphic DNA (RAPD) markers in detecting intra-clonal genetic variability in vegetatively propagated UPASI-9 clone of tea (Camellia sinensis) was studied. Twenty five decamer primers were used, of which three did not amplify, three gave single bands and the rest of nineteen primers generated upto twelve bands (an average of 6.3 bands per primer). Twenty one primers exhibiting amplified products gave monomorphic banding patterns. Only one primer (OPE-17) gave a unique extra band of similar size in four plants.     

Patterns of inheritance with RAPD molecular markers reveal novel types of polymorphism in the honey bee

Summary The polymerase chain reaction (PCR) was used to generate random amplified polymorphic DNA (RAPD) from honey bee DNA samples in order to follow the patterns of inheritance of RAPD markers in a haplodiploid insect. The genomic DNA samples from two parental bees, a haploid drone and a diploid queen, were screened for polymorphism with 68 different tennucleotide primers of random sequence. Parents were scored for the presence or absence of individual bands. An average of 6.3 bands and 1.3 polymorphisms for presence/absence were observed per primer between the parents. Thirteen of these primers were used to determine the inheritance of RAPD marker alleles in the resulting progeny and in haploid drones from a daughter queen. Four types of polymorphisms were observed. Polymorphisms for band presence/absence as well as for band brightness were inherited as dominant markers, meeting Mendelian expectations in haploid and diploid progeny. Polymorphisms for fragment-length were also observed. These segregated in a near 11 ratio in drone progeny. The last type of polymorphism was manifested as a diploid-specific band. Mixing of amplification products after PCR showed that the diploid-specific band was the result of heteroduplex formation from the DNA of alternate alleles in heterozygotes. In two of the four cases of heteroduplex formation, the alternative alleles were manifested as small fragment-length polymorphisms, resulting in co-dominant markers. This is the first demonstration that a proportion of RAPD markers are not inherited in a dominant fashion.     

应用RAPD方法对近交系小鼠进行遗传检测的研究

目的　为实验室日常检测近交系小鼠的遗传背景提供一种分子生物学方法。方法　用 6条随机引物对 6个品系近交系小鼠基因组DNA进行PCR扩增。结果　 6条随机引物中p2、p3、p5和p6四引物扩增的条带差异较为明显。结论　RAPD方法是一种有效的近交系小鼠遗传检测手段