RADS1和BRCA1在结直肠癌中的表达及临床意义

目的观察结直肠癌中RAD51和BRCA1基因的表达,探讨二者与结直肠癌发生发展及治疗的关系。方法收集结直肠癌癌灶及癌旁正常组织各42例,采用免疫组织化学法及逆转录一聚合酶链反应（reverse transeription-PCR,RTPCR）检测标本组织中RAD51、BRCA1蛋白和mRNA的表达水平。分析RAD51、BRCA1在结直肠癌中的表达水平与临床病理特征的关系以及二者之间的相互关系。结果在结直肠癌组织中RAD51（33例,78．6％）、BRCA1（30例,71．4％）的表达较癌旁正常组织RAD51（7例,16．7％）、BRCA1（18例,42．9％）高（P〈0．05）;结直肠癌中RAD51mRNA（0．51±0．26）和BRCA1 mRNA（O．70±0．96）的值较两者在正常组织中mRNA（0．10±0．22）高（P〈0．01）;两者蛋白及mRNA的表达水平与性别、年龄、分化程度、TNM分期等均无统计学差异（P〉0．05）;BRCA1与RAD51在结直肠癌中的表达水平成明显正相关（蛋白：r=0．731,P〈0．01mRNA：r=0．572,P〈0．01）。结论BRCA1与RAD51在结直肠癌组织中高表达,且二者的表达水平呈明显正相关;BRCAl与RAD51的表达异常可能与结直肠癌的发生发展有关。     

细菌染色体第1类整合子捕获耐药性基因盒反应模型的构建

【背景】整合子在细菌耐药性的获得及传播中占据重要地位,对于整合反应检测方法的改良及反应机制的研究,可以加深我们对细菌耐药性产生和播散的理解,为遏制耐药菌株的产生和播散提供新的途径。【目的】在细菌染色体上构建第1类整合子反应模型,用于评价整合酶介导的基因盒位点特异性重组。【方法】 PCR分别扩增含氯霉素耐药基因cat的CM片段、含基因盒aadA5的LacA5片段、含整合子重组位点attI1及强可变区启动子的PcS片段和插入位点两侧的同源臂,重叠延伸聚合酶链反应连接上述5个片段制备整合子模型插入片段,通过同源重组将构建好的整合子模型片段插入大肠埃希菌JM109染色体中。转入高表达第1类整合酶的质粒pHSint,在链霉素平板上筛选发生整合的菌株,并经聚合酶链反应和测序验证。【结果】构建的整合子模型片段经测序与预期一致,整合子模型片段成功插入大肠埃希菌JM109染色体中。转入高表达整合酶的质粒pHSint后,在链霉素平板上成功筛选出基因盒aadA5发生整合的菌株,经聚合酶链反应扩增并测序与预期一致。【结论】在大肠埃希菌染色体上成功构建第1类整合酶介导基因盒位点特异性重组反应模型,为进一步揭示整合子捕获耐药性基因盒的反应机制奠定基础。     

基于URA3基因快速构建表达载体及其在里氏木霉的应用

【背景】表达载体是基因工程必不可少的工具,对于真菌如里氏木霉(Trichoderma reesei)等,由于缺乏商品化的表达载体,使其基因工程蛋白表达既复杂又费时而难以开展。【目的】建立一种利用URA3序列快速构建表达载体的方法,解决真菌研究中难以简单、高效和快速构建表达载体的难题。【方法】基于URA3基因的序列,利用其启动子上游5′端序列和终止子下游3′端序列构建同源重组臂,通过同源重组臂定向同源重组到宿主基因组上,利用强启动子和终止子替换URA3基因,从而实现外源基因的表达。根据此方法构建pTRUC表达载体,将红色荧光蛋白基因mCherry克隆到该表达载体上,转化里氏木霉中并验证m Cherry的表达。【结果】阳性转化子在荧光显微镜下观察到强的红色荧光信号,在基因组PCR中检测到mCherry,Westernblotting结果表明红色荧光蛋白m Cherry能在里氏木霉中表达,以上结果说明该载体构建成功,使外源基因mCherry在里氏木霉中正确表达。【结论】基于URA3基因的快速构建表达载体及其构建方法切实可行,将成为推动真核表达系统表达异源蛋白的有力工具。     

The protein–protein interactions required for assembly of the Tn3 resolution synapse

The site-specific recombinase Tn3 resolvase initiates DNA strand exchange when two res recombination sites and six resolvase dimers interact to form a synapse. The detailed architecture of this intricate recombination machine remains unclear. We have clarified which of the potential dimer–dimer interactions are required for synapsis and recombination, using a novel complementation strategy that exploits a previously uncharacterized resolvase from Bartonella bacilliformis (“Bart”). Tn3 and Bart resolvases recognize different DNA motifs, via diverged C-terminal domains (CTDs). They also differ substantially at N-terminal domain (NTD) surfaces involved in dimerization and synapse assembly. We designed NTD-CTD hybrid proteins, and hybrid res sites containing both Tn3 and Bart dimer binding sites. Using these components in in vivo assays, we demonstrate that productive synapsis requires a specific “R” interface involving resolvase NTDs at all three dimer-binding sites in res. Synapses containing mixtures of wild-type Tn3 and Bart resolvase NTD dimers are recombination-defective, but activity can be restored by replacing patches of Tn3 resolvase R interface residues with Bart residues, or vice versa. We conclude that the Tn3/Bart family synapse is assembled exclusively by R interactions between resolvase dimers, except for the one special dimer–dimer interaction required for catalysis.     

The Theory and Applications of Measuring Broad-Range and Chromosome-Wide Recombination Rate from Allele Frequency Decay around a Selected Locus

Recombination is the exchange of genetic material between homologous chromosomes via physical crossovers. High-throughput sequencing approaches detect crossovers genome wide to produce recombination rate maps but are difficult to scale as they require large numbers of recombinants individually sequenced. We present a simple and scalable pooled-sequencing approach to experimentally infer near chromosome-wide recombination rates by taking advantage of non-Mendelian allele frequency generated from a fitness differential at a locus under selection. As more crossovers decouple the selected locus from distal loci, the distorted allele frequency attenuates distally toward Mendelian and can be used to estimate the genetic distance. Here, we use marker selection to generate distorted allele frequency and theoretically derive the mathematical relationships between allele frequency attenuation, genetic distance, and recombination rate in marker-selected pools. We implemented nonlinear curve-fitting methods that robustly estimate the allele frequency decay from batch sequencing of pooled individuals and derive chromosome-wide genetic distance and recombination rates. Empirically, we show that marker-selected pools closely recapitulate genetic distances inferred from scoring recombinants. Using this method, we generated novel recombination rate maps of three wild-derived strains of Drosophila melanogaster, which strongly correlate with previous measurements. Moreover, we show that this approach can be extended to estimate chromosome-wide crossover interference with reciprocal marker selection and discuss how it can be applied in the absence of visible markers. Altogether, we find that our method is a simple and cost-effective approach to generate chromosome-wide recombination rate maps requiring only one or two libraries.     

Evidence for widespread selection in shaping the genomic landscape during speciation of Populus

Increasing our understanding of how evolutionary processes drive the genomic landscape of variation is fundamental to a better understanding of the genomic consequences of speciation. However, genome‐wide patterns of within‐ and between‐ species variation have not been fully investigated in most forest tree species despite their global ecological and economic importance. Here, we use whole‐genome resequencing data from four Populus species spanning the speciation continuum to reconstruct their demographic histories and investigate patterns of diversity and divergence within and between species. Using Populus trichocarpa as an outgroup species, we further infer the genealogical relationships and estimate the extent of ancient introgression among the three aspen species (Populus tremula, Populus davidiana and Populus tremuloides) throughout the genome. Our results show substantial variation in these patterns along the genomes with this variation being strongly predicted by local recombination rates and the density of functional elements. This implies that the interaction between recurrent selection and intrinsic genomic features has dramatically sculpted the genomic landscape over long periods of time. In addition, our findings provide evidence that, apart from background selection, recent positive selection and long‐term balancing selection have also been crucial components in shaping patterns of genome‐wide variation during the speciation process.     

Recombination of T4-like Phages and Its Activity against Pathogenic Escherichia coli in Planktonic and Biofilm Forms

Virologica Sinica - The increasing emergence of multi-drug resistant Escherichia coli (E. coli) has become a global concern, primarily due to the limitation of antimicrobial treatment options....     

Genome of an iconic Australian bird: High‐quality assembly and linkage map of the superb fairy‐wren (Malurus cyaneus)

The superb fairy‐wren, Malurus cyaneus, is one of the most iconic Australian passerine species. This species belongs to an endemic Australasian clade, Meliphagides, which diversified early in the evolution of the oscine passerines. Today, the oscine passerines comprise almost half of all avian species diversity. Despite the rapid increase of available bird genome assemblies, this part of the avian tree has not yet been represented by a high‐quality reference. To rectify that, we present the first high‐quality genome assembly of a Meliphagides representative: the superb fairy‐wren. We combined Illumina shotgun and mate‐pair sequences, PacBio long‐reads, and a genetic linkage map from an intensively sampled pedigree of a wild population to generate this genome assembly. Of the final assembled 1.07‐Gb genome, 975 Mb (90.4%) was anchored onto 25 pseudochromosomes resulting in a final superscaffold N50 of 68.11 Mb. This high‐quality bird genome assembly is one of only a handful which is also accompanied by a genetic map and recombination landscape. In comparison to other pedigree‐based bird genetic maps, we find that the fairy‐wren genetic map more closely resembles those of Taeniopygia guttata and Parus major maps, unlike the Ficedula albicollis map which more closely resembles that of Gallus gallus. Lastly, we also provide a predictive gene and repeat annotation of the genome assembly. This new high‐quality, annotated genome assembly will be an invaluable resource not only regarding the superb fairy‐wren species and relatives but also broadly across the avian tree by providing a novel reference point for comparative genomic analyses.     

Adeno‐Associated Viral Vectors for Homology‐Directed Generation of CAR‐T Cells

Immunotherapy with T cells expressing chimeric antigen receptors (CAR) is an emerging and promising treatment against refractory cancers. However, the currently adopted methods of modification of T cells pose a risk of insertional oncogenesis because lentiviral and retroviral vectors integrate the CAR transgene in a semi‐random fashion. In addition, this therapy is only available using autologous cells, which create problems in production and limit the access for patients who have their T cells depleted. One modification method that shows the ability to overcome both drawbacks is the knock‐in of the CAR simultaneously knocking‐out genes that prevent allogeneic therapy, such as the endogenous T cell receptor. In this mini‐review, the authors present recent efforts to develop safer universal CAR‐T cells. More specifically, the combined application of target‐directed nucleases, which create a double‐strand break at a specific genome locus, and the delivery of CAR DNA via adeno‐associated viral vectors for subsequent integration via homologous recombination and silencing of the targeted gene is focused on.     

Evolution of major histocompatibility complex class I genes in the sable Martes zibellina (Carnivora,Mustelidae)

The molecules encoded by major histocompatibility complex (MHC) genes play an essential role in the adaptive immune response among vertebrates. We investigated the molecular evolution of MHC class I genes in the sable Martes zibellina. We isolated 26 MHC class I sequences, including 12 putatively functional sequences and 14 pseudogene sequences, from 24 individuals from two geographic areas of northeast China. The number of putatively functional sequences found in a single individual ranged from one to five, which might be at least 1–3 loci. We found that both balancing selection and recombination contribute to evolution of MHC class I genes in M. zibellina. In addition, we identified a candidate nonclassical MHC class I lineage in Carnivora, which may have preceded the divergence (about 52–57 Mya) of Caniformia and Feliformia. This may contribute to further understanding of the origin and evolution of nonclassical MHC class I genes. Our study provides important immune information of MHC for M. zibellina, as well as other carnivores.