SRY盒基因在斑马鱼和胡子鲇中的保守性分析

本文采用人类SRY基因探针,与EcoRI消化的中国的胡子鲇(Clarias fusc us)和美国的斑马鱼(Brachydanio rerio)基因组DNA进行了Southern印迹杂交分析。首次在这两种鱼中发现了SRY盒基因及其存在特征;在斑马鱼中发现了明显的限制性片段长度多态性; 并深入分析了SRY盒基因的进化保守性。 Abstract:Using,Southern bloting analysis,EcoRI-digested genomic DNA from Clarias fuscus and Brachydanio rerio were hybridizae to human SRY probe.Hybridization occurred in both male and female of the two species.RFLP associated with SRY-box genes was observed in Brachydanio rerio.The conservation of SRY-box genes was analysed.     

AAV-ITR单链DNA微载体在小鼠骨骼肌中的表达

AAV-ITR单链DNA微载体是一种基于腺相关病毒(AAV)倒置末端重复序列(ITR)的基因表达载体(AAV-ITR ss DNA mini vector)。前期研究已证明AAV-ITR单链DNA微载体在HEK 293T细胞中具有较高的转染、表达效率。本文中将相同拷贝数的AAV-ITR单链DNA微载体、3?-ITR末端错配的AAV-ITR单链DNA微载体(AAV-ITRmm ss DNA mutant vector)、AAV-ITR双链DNA和质粒分别用Turbo Fect转入小鼠骨骼肌中,比较检测AAV-ITR单链DNA微载体与其他基因表达载体在小鼠体内1周、1个月及3个月的表达效率。组织切片经荧光显微镜观察及荧光灰度值分析表明,相同分子摩尔数的AAV-ITR单链DNA微载体比AAV-ITR双链DNA和质粒在不同时期表达效率都要高且更稳定。提取注射3个月后的肌肉组织的DNA,用荧光定量PCR分析比较各载体的存留分子数。RT-PCR的结果显示AAV-ITR单链DNA微载体在注射3个月后的存留分子数较其他载体高。综合结果显示AAV-ITR单链DNA微载体在动物体内具有表达效率高和长久稳定的优势,有可能开发为基因治疗的一种高效、稳定的新型载体。     

微卫星DNA标记技术及其在植物研究中的应用

微卫星DNA(或简单重复序列,simplesequencerepeats,SSR)是继RFLP、RAPD等分子标记后出现的第二代分子标记技术。随着分子生物学的发展,微卫星标记技术在植物基因组中的应用越来越广泛。由于SSR具有多态性高,呈共显性遗传,遵守孟德尔式分离,在数量上没有生物学的限制,实验操作简单,对样品质量要求不高等特点,因此被广泛用于植物遗传图谱的构建、基因定位、构建指纹图谱、遗传多样性及物种进化与亲缘关系的研究等方面。     

难培养菌的多条带PCR产物产生原因分析

【目的】分析严重威胁柑橘产业发展的毁灭性病害——柑橘黄龙病的强致病性病原亚洲种“Candidatus Liberibacter asiaticus”的种群多样性研究中出现多条带PCR产物的原因,为难培养菌的分子生物学研究提供参考。【方法】通过使用PCR、聚丙烯酰胺凝胶电泳(PAGE)和测序相结合分析“Ca. L. asiaticus”基因组上2个短串联重复(Short tandem repeats,STR)基因的PCR产物。【结果】单个菌株可扩增获得多个PCR条带且其扩增产物多态性受寄主品种影响;这2个STR基因的PCR产物在菌株间呈明显的多态性;扩增所获得的序列可来自“Ca. L. asiaticus”本身,也可来自其寄主或内生菌。【结论】难培养菌的STR基因PCR产物多态性产生的主要原因是该基因内部的串联重复序列数目存在差异,但目的菌及外源物种(寄主或内生菌等)基因组的非特异性扩增也是影响其多态性的因素。     

The Structural Organization of Oligonucleosomes

Abstract

We have used electric birefringence to study the structure of oligonucleosomes and to show the influence of histone H1 depletion on their conformation in solution. Measurements are made at low ionic strength on monodisperse samples containing up to 8 nucleosomes. For each oligomer, having H1 or not, the analysis of both relaxation and orientation times gives information about the particle's orientation mechanism through the ratio r of permanent over induced dipole terms. For native oligomers, the data confirm the previous finding of a discontinuity in hydrodynamic behavior between pentamer and heptamer: the rotational times are multiplied by 10 and r increases from 0.2 to 0.7 showing the appearance of a non-negligible contribution of a permanent dipole to the orientation mechanism. We suggest a model for the hexanucleosome at low ionic strength and discuss its implications for the higher-order structure of chromatin.

The treatment for H1 depletion abolishes the transitions in electro-optical properties: the value of r remains constant, r=0.15, and both rotational times increase progressively with the number of nucleosomes in the chain. That reflects an important unfolding of oligonucleosomal structure which we attributed to the unwinding of DNA tails and internucleosomal segments. The disc planes of nucleosomes become closely parallel to the nucleosomal chain axis.     

Peters plus syndrome mutations affect the function and stability of human β1,3-glucosyltransferase

Peters Plus Syndrome (PTRPLS OMIM #261540) is a severe congenital disorder of glycosylation where patients have multiple structural anomalies, including Peters anomaly of the eye (anterior segment dysgenesis), disproportionate short stature, brachydactyly, dysmorphic facial features, developmental delay, and variable additional abnormalities. PTRPLS patients and some Peters Plus-like (PTRPLS-like) patients (who only have a subset of PTRPLS phenotypes, have mutations in the gene encoding β1,3-glucosyltransferase [B3GLCT]). B3GLCT catalyzes the transfer of glucose to O-linked fucose on thrombospondin type-1 repeats. Most B3GLCT substrate proteins belong to the ADAMTS superfamily and play critical roles in extracellular matrix. We sought to determine whether the PTRPLS or PTRPLS-like mutations abrogated B3GLCT activity. B3GLCT has two putative active sites, one in the N-terminal region and the other in the C-terminal glycosyltransferase domain. Using sequence analysis and in vitro activity assays, we demonstrated that the C-terminal domain catalyzes transfer of glucose to O-linked fucose. We also generated a homology model of B3GLCT and identified D421 as the catalytic base. PTRPLS and PTRPLS-like mutations were individually introduced into B3GLCT, and the mutated enzymes were evaluated using in vitro enzyme assays and cell-based functional assays. Our results demonstrated that PTRPLS mutations caused loss of B3GLCT enzymatic activity and/or significantly reduced protein stability. In contrast, B3GLCT with PTRPLS-like mutations retained enzymatic activity, although some showed a minor destabilizing effect. Overall, our data supports the hypothesis that loss of glucose from B3GLCT substrate proteins is responsible for the defects observed in PTRPLS patients, but not for those observed in PTRPLS-like patients.     

Characterization of EST derived SSRs from the bay scallop,Argopecten irradians

Interest in bay scallop conservation has resulted in organized stock enhancement efforts and increased attention to fisheries management issues. Genetic markers can facilitate the monitoring of enhancement efforts, characterization of wild populations, and optimize hatchery practices. We have identified eight polymorphic simple sequence repeat markers including one dinucleotide, six trinucleotide and one compound dinucleotide repeats, in expressed sequence tags generated from multiple bay scallop cDNA libraries. The numbers of alleles range from two to five. The expected and observed heterozygosities range from 0.093 to 0.720 and 0.095 to 0.600, respectively.     

Double-strand break repair can lead to high frequencies of deletions within short CAG/CTG trinucleotide repeats

Trinucleotide repeats undergo contractions and expansions in humans, leading in some cases to fatal neurological disorders. The mechanism responsible for these large size variations is unknown, but replication-slippage events are often suggested as a possible source of instability. We constructed a genetic screen that allowed us to detect spontaneous expansions/contractions of a short trinucleotide repeat in yeast. We show that deletion of RAD27, a gene involved in the processing of Okazaki fragments, increases the frequency of contractions tenfold. Repair of a chromosomal double-strand break (DSB) using a trinucleotide repeat-containing template induces rearrangements of the repeat with a frequency 60 times higher than the natural rate of instability of the same repeat. Our data suggest that both gene conversion and single-strand annealing are major sources of trinucleotide repeat rearrangements. Received: 8 January 1999 / Accepted: 17 March 1999