CRISPR RNA binding and DNA target recognition by purified Cascade complexes from Escherichia coli

Clustered regularly interspaced short palindromic repeats (CRISPRs) and their associated Cas proteins comprise a prokaryotic RNA-guided adaptive immune system that interferes with mobile genetic elements, such as plasmids and phages. The type I-E CRISPR interference complex Cascade from Escherichia coli is composed of five different Cas proteins and a 61-nt-long guide RNA (crRNA). crRNAs contain a unique 32-nt spacer flanked by a repeat-derived 5′ handle (8 nt) and a 3′ handle (21 nt). The spacer part of crRNA directs Cascade to DNA targets. Here, we show that the E. coli Cascade can be expressed and purified from cells lacking crRNAs and loaded in vitro with synthetic crRNAs, which direct it to targets complementary to crRNA spacer. The deletion of even one nucleotide from the crRNA 5′ handle disrupted its binding to Cascade and target DNA recognition. In contrast, crRNA variants with just a single nucleotide downstream of the spacer part bound Cascade and the resulting ribonucleotide complex containing a 41-nt-long crRNA specifically recognized DNA targets. Thus, the E. coli Cascade-crRNA system exhibits significant flexibility suggesting that this complex can be engineered for applications in genome editing and opening the way for incorporation of site-specific labels in crRNA.     

Cas3 is a single-stranded DNA nuclease and ATP-dependent helicase in the CRISPR/Cas immune system

Clustered regularly interspaced short palindromic repeat (CRISPR) is a recently discovered adaptive prokaryotic immune system that provides acquired immunity against foreign nucleic acids by utilizing small guide crRNAs (CRISPR RNAs) to interfere with invading viruses and plasmids. In Escherichia coli, Cas3 is essential for crRNA-guided interference with virus proliferation. Cas3 contains N-terminal HD phosphohydrolase and C-terminal Superfamily 2 (SF2) helicase domains. Here, we provide the first report of the cloning, expression, purification and in vitro functional analysis of the Cas3 protein of the Streptococcus thermophilus CRISPR4 (Ecoli subtype) system. Cas3 possesses a single-stranded DNA (ssDNA)-stimulated ATPase activity, which is coupled to unwinding of DNA/DNA and RNA/DNA duplexes. Cas3 also shows ATP-independent nuclease activity located in the HD domain with a preference for ssDNA substrates. To dissect the contribution of individual domains, Cas3 separation-of-function mutants (ATPase(+)/nuclease(-) and ATPase(-)/nuclease(+)) were obtained by site-directed mutagenesis. We propose that the Cas3 ATPase/helicase domain acts as a motor protein, which assists delivery of the nuclease activity to Cascade-crRNA complex targeting foreign DNA.     

CRISPR/Cas9系统在基因组DNA片段编辑中的应用

源于细菌和古菌的Ⅱ型成簇规律间隔短回文重复系统[Clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated nuclease 9 (Cas9),CRISPR/Cas9]近年被改造成为基因组定点编辑的新技术。由于它具有设计简单、操作方便、费用低廉等巨大优势,给遗传操作领域带来了一场革命性的改变。本文重点介绍了CRISPR/Cas9系统在基因组DNA片段靶向编辑方面的研究和应用,主要包括DNA片段的删除、反转、重复、插入和易位,这一有效的DNA片段编辑方法为研究基因功能、调控元件、组织发育和疾病发生发展提供了有力手段。本文最后展望了Ⅱ型CRISPR/Cas9系统的应用前景和其他类型CRISPR系统的应用潜力,为开展利用基因组DNA片段靶向编辑进行基因调控和功能研究提供参考。     

Preferential binding of E.coli histone-like protein HU alpha to negatively supercoiled DNA.

Binding specificity of histone-like HU alpha protein to supercoiled DNA was examined by gel retardation assay and chemical probing with OsO4. The latter method was proved to be a unique means for detecting torsional tension restrained in supercoiled plasmid in the presence of HU alpha. It was shown that HU alpha protein has preferential affinity to negatively supercoiled DNA relative to relaxed, nicked and linearized DNAs. There were two modes for binding of HU alpha to the supercoiled DNA: one was the binding associated with topological changes in DNA and the other was relatively strong binding, probably specific to certain particular structures of DNA. It was suggested that HU in vivo interacts preferentially with the regions deformed under torsional stress or with the metabolically active regions along DNA.     

Preferential binding of tumor suppressor p53 to positively or negatively supercoiled DNA involves the C-terminal domain.

The C-terminal domain of the tumor suppressor protein p53 is the site of non-specific DNA binding. Purified p53 produced from baculovirus-infected insect cells binds preferentially to supercoiled DNA, forming bands with lower electrophoretic mobility. This non-covalent binding does not change the linking number of the DNA. An anti-p53 antibody targeting the C-terminal domain partially competes with supercoiled DNA in binding to p53, while antibodies targeted to the N terminus of p53 supershift the complex bands. A synthetic peptide corresponding to amino acid residues 319-393 of human p53 also displays preferential binding to supercoiled DNA, while a mutant peptide, which is unable to form tetramers, is inactive. The center of the equilibrium distribution of topoisomers formed by relaxation with topoisomerase I is not shifted in the presence of p53 although the distribution is broadened. The preferential binding of p53 is exhibited toward both positively and negatively supercoiled DNA. These observations are consistent with a model in which p53 binds to right-handed or left-handed strand crossings.     

Allosteric regulation in CRISPR/Cas1-Cas2 protospacer acquisition mediated by DNA and Cas2

Cas1 and Cas2 are highly conserved proteins across clustered-regularly-interspaced-short-palindromic-repeat-Cas systems and play a significant role in protospacer acquisition. Based on crystal structure of twofold symmetric Cas1-Cas2 in complex with dual-forked protospacer DNA (psDNA), we conducted all-atom molecular dynamics simulations to study the psDNA binding, recognition, and response to cleavage on the protospacer-adjacent-motif complementary sequence, or PAMc, of Cas1-Cas2. In the simulation, we noticed that two active sites of Cas1 and Cas1’ bind asymmetrically to two identical PAMc on the psDNA captured from the crystal structure. For the modified psDNA containing only one PAMc, as that to be recognized by Cas1-Cas2 in general, our simulations show that the non-PAMc association site of Cas1-Cas2 remains destabilized until after the stably bound PAMc being cleaved at the corresponding association site. Thus, long-range correlation appears to exist upon the PAMc cleavage between the two active sites (∼10 nm apart) on Cas1-Cas2, which can be allosterically mediated by psDNA and Cas2 and Cas2’ in bridging. To substantiate such findings, we conducted repeated runs and further simulated Cas1-Cas2 in complex with synthesized psDNA sequences psL and psH, which have been measured with low and high frequency in acquisition, respectively. Notably, such intersite correlation becomes even more pronounced for the Cas1-Cas2 in complex with psH but remains low for the Cas1-Cas2 in complex with psL. Hence, our studies demonstrate that PAMc recognition and cleavage at one active site of Cas1-Cas2 may allosterically regulate non-PAMc association or even cleavage at the other site, and such regulation can be mediated by noncatalytic Cas2 and DNA protospacer to possibly support the ensued psDNA acquisition.     

利用CRISPR/Cas9技术构建CTCF蛋白降解细胞系

CTCF是脊椎动物关键的绝缘子蛋白,在细胞生命过程中发挥重要作用,敲除CTCF基因会导致小鼠胚胎死亡。为进一步探讨CTCF的功能,本文利用CRISPR/Cas9介导的同源重组,在内源性CTCF表达框上游敲入一个有丝分裂期降解结构域(Mitosis-special degradation domain, MD),该结构域可以带动CTCF融合蛋白在M期降解。作为对照,将MD结构域的第42位的精氨酸突变为丙氨酸,形成无降解活性的MD^*,可使MD^*-CTCF融合蛋白始终稳定存在。将嘌呤霉素与融合蛋白同时表达,即可利用抗生素筛选,高效地筛选到纯合克隆。利用蛋白印迹技术和免疫荧光检测3种细胞在不同细胞周期的CTCF蛋白变化情况,发现MD-CTCF细胞系CTCF蛋白含量约为野生型细胞的10%,MD^*-CTCF细胞系的CTCF含量与野生型没有显著差别;通过流式细胞术观测降解CTCF对细胞的影响,发现MD-CTCF细胞系G1期明显延长。总之,利用CRISPR/Cas9技术在CTCF表达框上游高效地插入MD,首个CTCF特异性降解的人类细胞系获得成功构建。     

Structure- and sequence-specificity of ozone degradation of supercoiled plasmid DNA.

Ozone-reactive sites on the nucleobase moieties in supercoiled pBR322 DNA were investigated by using sequencing procedures. Ozonolysis in the absence of salt resulted in degradation of thymine residues in the A + T rich region located at 3100-3400bp. In the presence of salt, such as NaCl or MgCl2, a conformational change of plasmid DNA was induced. Subsequently the thymine and guanine residues in the loop of the cruciform located at 3120bp and 3220bp were degraded. In addition, central thymine residues present in sequences GTA, GTT and ATA were also degraded.     

Recognition of the structural distortions at the junctions between B and Z segments in negatively supercoiled DNA by osmium tetroxide

It has been shown for the first time that conformational junction between contiguous right-handed B and left-handed Z segments can be recognized by a chemical probe. Plasmid pRW751 containing (dC-dG)13 and (dC-dG)16 blocks was treated with osmium tetroxide, pyridine (a reagent known to be single-strand selective) at physiological ionic conditions (0.1 and 0.2 M NaCl) and neutral pH. Mapping of the osmium binding sites by restriction enzyme digestion followed by nuclease S1 cleavage has revealed selective binding of osmium at, or near to, the end of the (dC-dG)n segments proximal to the 95 bp lac sequence. The junction of the shorter (dC-dG)13 segment was modified to a substantially greater extent than that of the longer segment. Partial inhibition of DNA cleavage by BamHI was observed at the restriction sites neighbouring to the both (dC-dG)n segments as a result of DNA modification by osmium tetroxide. The site-selective modification occurred only in supercoiled and not in relaxed molecules. Differences in the sensitivity of the B/Z junctions in pRW751 to the osmium tetroxide were explained by different structural features of these junctions.     

Targeting DNA polymerase to DNA double-strand breaks reduces DNA deletion size and increases templated insertions generated by CRISPR/Cas9

Most insertions or deletions generated by CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9) endonucleases are short (<25 bp), but unpredictable on-target long DNA deletions (>500 bp) can be observed. The possibility of generating long on-target DNA deletions poses safety risks to somatic genome editing and makes the outcomes of genome editing less predictable. Methods for generating refined mutations are desirable but currently unavailable. Here, we show that fusing Escherichia coli DNA polymerase I or the Klenow fragment to Cas9 greatly increases the frequencies of 1-bp deletions and decreases >1-bp deletions or insertions. Importantly, doing so also greatly decreases the generation of long deletions, including those >2 kb. In addition, templated insertions (the insertion of the nucleotide 4 nt upstream of the protospacer adjacent motif) were increased relative to other insertions. Counteracting DNA resection was one of the mechanisms perturbing deletion sizes. Targeting DNA polymerase to double-strand breaks did not increase off-targets or base substitution rates around the cleavage sites, yet increased editing efficiency in primary cells. Our strategy makes it possible to generate refined DNA mutations for improved safety without sacrificing efficiency of genome editing.     

DNA binding and degradation by the HNH protein ColE7

The bacterial toxin ColE7 bears an HNH motif which has been identified in hundreds of prokaryotic and eukaryotic endonucleases, involved in DNA homing, restriction, repair, or chromosome degradation. The crystal structure of the nuclease domain of ColE7 in complex with a duplex DNA has been determined at 2.5 A resolution. The HNH motif is bound at the minor groove primarily to DNA phosphate groups at and beyond the 3' side of the scissile phosphate, with little interaction with ribose groups and bases. This result provides a structural basis for sugar- and sequence-independent DNA recognition and the inhibition mechanism by inhibitor Im7, which blocks the substrate binding site but not the active site. Structural comparison shows that two families of endonucleases bind and bend DNA in a similar way to that of the HNH ColE7, indicating that endonucleases containing a "betabetaalpha-metal" fold of active site possess a universal mode for protein-DNA interactions.     

The binding of actinomycin D and adriamycin to supercoiled DNA, single-stranded DNA and polynucleotides

The effect of actinomycin D and adriamycin on synthetic polynucleotides, single-stranded viral DNA and supercoiled DNA has been studied employing the fluorescent probe, terbium. Marked displacement of the probe was observed when any deoxyribose-containing polynucleotide was pretreated with either drug. With supercoiled DNA, an unwinding of the supercoil was observed at very low drug concentrations (at approx. 1:500 molar ratio of drug:DNA) prior to the displacement of the terbium. This unwinding was visualized by agarose gel electrophoresis at molar ratios of approx. 1:200. The effect was more apparent and occurred at lower drug:DNA ratios with actinomycin D than with adriamycin. Unlike cis-dichlorodiammine platinum(II), actinomycin D did not protect pBR322 DNA from cleavage at its BamHI site. The hydrolysis of Φχ174 DNA by a series of G-C-specific restriction nucleases (including HhaI, HpaII and HaeIII) was also not affected by prior treatment of the DNA with actinomycin D.     

以CRISPR/Cas9专利为例的知识产权教育

随着世界经济全球化步伐的加快, 知识产权的重要性凸显。高校是知识产权意识和能力教育的主战场。我国现有知识产权教育与专业的密切程度急需提高。文章结合全球首个CRISPR/Cas9专利权的授权公布和作者授课经历, 提出了一种新的知识产权普及教育模式, 将知识产权教育分为启蒙教育和深入研修两个阶段。第一阶段将知识产权教育与专业课课程无缝整合, 后一阶段主要针对有志于发展成为知识产权专业人才的学生。我们认为这种教学模式的推广将解决现有知识产权教育中教材的欠缺以及教师的不足, 有利于知识产权意识在生物医学等理工科学生的普及。遗传学在生物医学中具有特别重要的地位, 因此, 文章以遗传学最近的热点技术之一——基于CRISPR/Cas的基因组编辑新工具为例进行阐述。CRISPR/Cas从最初的微生物遗传学发现到成为基因组编辑的重要工具, 贯穿了基础研究转化为关键技术的全过程, 可以很好体现生物医学相关的知识产权教育的精髓。     

The effect of Escherichia coli Uvr protein binding on the topology of supercoiled DNA.

The effects of the binding of the E. coli UvrA and UvrB proteins on the linking number (delta L) of superhelical DNA has been measured. The effects of cofactor ATP structure on UvrAB-nucleoprotein complex formation revealed that nucleotide binding, not hydrolysis, is sufficient to locally unwind the DNA helix of both ultraviolet light-damaged as well as undamaged DNAs. The extent of this unwinding is of the same order of magnitude as the nucleotide distances of the double incision sites generated by the UvrABC endonucleolytic reaction.     

利用CRISPR/Cas9对基因组中高度同源DNA片段编辑多样性的遗传学研究

在基因组中,编码区存在许多高度相似的基因簇或基因群(多拷贝基因),非编码区也存在大量的重复序列。这些重复序列能通过改变染色体的三维结构调控基因的转录,对于生物体的遗传与进化起到了重要的作用。其高度同源的特征使得利用CRISPR/Cas9技术进行基因组编辑时面临更加复杂的状况。如果编辑的片段是二倍体或多倍体,还会产生各条染色单体上的编辑情况不相同的现象。为此本文选择了2个位于同一染色体相距11 kb的高度同源300 bp片段(L1和L2)进行CRISPR介导的DNA片段编辑。采用一对sgRNA(分别共同靶向两片段的上、下游位点)引导Cas9对HepG2细胞两个高度相似的DNA片段进行切割。片段编辑的细胞进一步单克隆化后,对获得的22个L1/L2编辑的CRISPR单克隆细胞株进行详细的基因型鉴定。结果发现除了这两个DNA片段本身被删除外,它们之间的大片段也存在被删除的现象,三个片段的各种反转组合也很频繁。该研究结果对于采用CRISPR/Cas9系统编辑多拷贝基因或重复序列,尤其是对二倍体或多倍体生物进行基因组编辑时具有重要的借鉴和参考价值。     

A possible aid in targeted insertion of large DNA elements by CRISPR/Cas in mouse zygotes

The CRISPR/Cas system has rapidly emerged recently as a new tool for genome engineering, and is expected to allow for controlled manipulation of specific genomic elements in a variety of species. A number of recent studies have reported the use of CRISPR/Cas for gene disruption (knockout) or targeted insertion of foreign DNA elements (knock‐in). Despite the ease of simple gene knockout and small insertions or nucleotide substitutions in mouse zygotes by the CRISPR/Cas system, targeted insertion of large DNA elements remains an apparent challenge. Here the generation of knock‐in mice with successful targeted insertion of large donor DNA elements ranged from 3.0 to 7.1 kb at the ROSA26 locus using the CRISPR/Cas system was achieved. Multiple independent knock‐in founder mice were obtained by injection of hCas9 mRNA/sgRNA/donor vector mixtures into the cytoplasm of C57BL/6N zygotes when the injected zygotes were treated with an inhibitor of actin polymerization, cytochalasin. Successful germ line transmission of three of these knock‐in alleles was also confirmed. The results suggested that treatment of zygotes with actin polymerization inhibitors following microinjection could be a viable method to facilitate targeted insertion of large DNA elements by the CRISPR/Cas system, enabling targeted knock‐in readily attainable in zygotes. genesis 54:65–77, 2016. © 2016 Wiley Periodicals, Inc.