Die Immunsysteme der Bakterien

The immune systems of bacteria and important applications in biotechnology and medicine At the end of the 70s of the last century, a new technique has been developed allowing the synthesis of genes and the inducible expression of their recombinant proteins using restriction enzymes and vectors, mainly plasmids. This era has been designated as genetic engineering and is being replenished by the CRISPR‐Cas9 technology know as genome editing. This technology is about to revolutionize alterations in the genomes of all types of organisms, including bacteria, fungi, plants, animals and even humans. It allows the introduction and elimination of point mutations and even whole genes in all organisms. Important goals are the genetic optimization of crop plants and animals, fighting against cancer in humans and elimination of human viruses and pathogenic multi‐resistant bacteria. Important drawbacks are OFF‐targets which can cause mutations in any gene or influence their expression.     

沙门氏菌分型研究进展

沙门氏菌是重要的致病菌之一,该菌属型别繁多。沙门氏菌的分型方法可分为以表型特征为依据的表型分型方法和以基因特征为依据的分子分型方法。沙门氏菌的表型分型主要有血清分型和噬菌体分型。分子分型主要有分子血清分型、脉冲场凝胶电泳(Pulsed field gel electrophoresis,PFGE)、多位点序列分析(Multi-locus sequence typing,MLST)、多位点可变重复序列分析(Multi-locus variable numbers tandem repeat analysis,MLVA)以及成簇的规律间隔的短回文重复序列分析(Clustered regularly interspaced short palindromic repeats,CRISPR)等。与表型分型相比,分子分型技术具有快速、准确、重复性好等特点,现已得到广泛应用。其中,分子血清分型是鉴定沙门氏菌血清型的新方法,PFGE被认为是病原微生物分子分型的"金标准",MLST和MLVA以其分辨率高、可重复性好和可比性强等优势满足了全球流行病学发展的要求,能实现序列数据交换和共享,成为新一代的分子分型新工具,而近年发现的CRISPR分型对同源性较高的同种血清型具有较高的分型能力。但每种分型方法也有各自的优缺点和使用条件及适用范围,因此可以根据菌株特性、分型目的和实验室拥有的条件选择最合适的分型方法。     

The Regulatory Status of Genome‐edited Crops

Genome editing with engineered nucleases (GEEN) represents a highly specific and efficient tool for crop improvement with the potential to rapidly generate useful novel phenotypes/traits. Genome editing techniques initiate specifically targeted double strand breaks facilitating DNA‐repair pathways that lead to base additions or deletions by non‐homologous end joining as well as targeted gene replacements or transgene insertions involving homology‐directed repair mechanisms. Many of these techniques and the ancillary processes they employ generate phenotypic variation that is indistinguishable from that obtained through natural means or conventional mutagenesis; and therefore, they do not readily fit current definitions of genetically engineered or genetically modified used within most regulatory regimes. Addressing ambiguities regarding the regulatory status of genome editing techniques is critical to their application for development of economically useful crop traits. Continued regulatory focus on the process used, rather than the nature of the novel phenotype developed, results in confusion on the part of regulators, product developers, and the public alike and creates uncertainty as of the use of genome engineering tools for crop improvement.     

Whither life? Conjectures on the future evolution of biochemistry

Life has existed on the Earth for approximately four billion years. The sheer depth of evolutionary time, and the diversity of extant species, makes it tempting to assume that all the key biochemical innovations underpinning life have already happened. But we are only a little over halfway through the trajectory of life on our planet. In this Opinion piece, we argue: (i) that sufficient time remains for the evolution of new processes at the heart of metabolic biochemistry and (ii) that synthetic biology is providing predictive insights into the nature of these innovations. By way of example, we focus on engineered solutions to existing inefficiencies in energy generation, and on the complex, synthetic regulatory circuits that are currently being implemented.     

基于CRISPR/Cas9系统构建精准调控Wnt信号通路的表达载体及其效果的验证

目的:构建基于CRISPR/cas9系统调控Wnt信号通路的载体,并在细胞水平验证其调控基因表达的效率。方法:选取Wnt信号中负性调控分子,设计并合成能够表达靶向上述分子gRNA的互补DNA克隆序列,BsmBI限制性内切酶酶切载体后,采用分子克隆的方法将上述序列克隆至目的载体lenti-sgRNA-Ms2-zeo,测序正确的克隆通过Lipofectamine2000与lenti-Ms2-P65-HSF1-Hygro和lenti-dcas9-VP64-blastine共同转染入293细胞;转染24h后收集细胞,qRt-PCR检测目的基因的表达。结果:筛选了Wnt信号通路中已知的19个负性调控基因;针对每个基因设计了两对gRNA序列,并构建了能够表达gRNA和MS2融合序列的载体,测序结果显示重组质粒的DNA序列与预期完全相符。随机挑选了4个表达载体与lenti-Ms2-P65-HSF1-Hygro和lenti-dcas9-VP64-blastine共转进入细胞,qPCR结果显示构建的目的载体联合lenti-Ms2-P65-HSF1-Hygro和lenti-dcas9-VP64-blastine载体可以协同促进靶分子表达。结论:本研究成功构建了基于CRISPR/cas9基因编辑系统调控Wnt信号的载体。     

1型CRISPR位点间区序列分析在嗜热链球菌菌株分型中的应用

为了建立适用于嗜热链球菌菌株资源多样性调查的菌株分型方法,尝试将1型CRISPR位点间区序列分析用于嗜热链球菌的菌株分型,并与常用ERIC-PCR指纹图谱方法进行了比较。结果表明,1型CRISPR位点间区序列分析可以把30株从三个不同样品中分离的嗜热链球菌分成三种差异明显的类型:不同类型菌株之间没有相同的间区序列;而同一类型菌株之间,间区序列的组成和排列则基本一致,并且上述分型的结果与用ERIC-PCR指纹图谱技术获得的结果完全一致。因此,1型CRISPR位点间区序列分析是嗜热链球菌分型鉴定的可靠方法,并适用于大量菌株的分型鉴定和多样性调查。