Efficient isolation of specific genomic regions and identification of associated proteins by engineered DNA-binding molecule-mediated chromatin immunoprecipitation (enChIP) using CRISPR

Isolation of specific genomic regions retaining molecular interactions is necessary for their biochemical analysis. Here, we established a novel method, engineered DNA-binding molecule-mediated chromatin immunoprecipitation (enChIP), for purification of specific genomic regions retaining molecular interactions. We showed that enChIP using the CRISPR system efficiently isolates specific genomic regions. In this form of enChIP, specific genomic regions are immunoprecipitated with antibody against a tag(s), which is fused to a catalytically inactive form of Cas9 (dCas9), which is co-expressed with a guide RNA (gRNA) and recognizes endogenous DNA sequence in the genomic regions of interest. enChIP–mass spectrometry (enChIP–MS) targeting endogenous loci identified associated proteins. enChIP using the CRISPR system would be a convenient and useful tool for dissecting chromatin structure of genomic regions of interest.     

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。     

A barley stripe mosaic virus-based guide RNA delivery system for targeted mutagenesis in wheat and maize

Plant RNA virus-based guide RNA (gRNA) delivery has substantial advantages compared to that of the conventional constitutive promoter-driven expression due to the rapid and robust amplification of gRNAs during virus replication and movement. To date, virus-induced genome editing tools have not been developed for wheat and maize. In this study, we engineered a barley stripe mosaic virus (BSMV)-based gRNA delivery system for clustered regularly interspaced short palindromic repeat (CRISPR)/Cas9-mediated targeted mutagenesis in wheat and maize. BSMV-based delivery of single gRNAs for targeted mutagenesis was first validated in Nicotiana benthamiana. To extend this work, we transformed wheat and maize with the Cas9 nuclease gene and selected the wheat TaGASR7 and maize ZmTMS5 genes as targets to assess the feasibility and efficiency of BSMV-mediated mutagenesis. Positive targeted mutagenesis of the TaGASR7 and ZmTMS5 genes was achieved for wheat and maize with efficiencies of up to 78% and 48%. Our results provide a useful tool for fast and efficient delivery of gRNAs into economically important crops.     

Front Cover Image,Volume 116, Number 11, November 2019

CRISPR/Cas9-guided cytidine deaminase enables C:G to T:A base editing in bacterial genome without introduction of lethal double-stranded DNA break, supplement of foreign DNA template, or dependence on inefficient homologous recombination. However, limited by genome-targeting scope, editing window, and base transition capability, the application of base editing in metabolic engineering has not been explored. Herein, four Cas9 variants accepting different protospacer adjacent motif (PAM) sequences were used to increase the genome-targeting scope of bacterial base editing. After a comprehensive evaluation, we demonstrated that PAM requirement of bacterial base editing can be relaxed from NGG to NG using the Cas9 variants, providing 3.9-fold more target loci for gene inactivation in Corynebacterium glutamicum. Truncated or extended guide RNAs were employed to expand the canonical 5-bp editing window to 7-bp. Bacterial adenine base editing was also achieved with Cas9 fused to adenosine deaminase. With these updates, base editing can serve as an enabling tool for fast metabolic engineering. To demonstrate its potential, base editing was used to deregulate feedback inhibition of aspartokinase via amino acid substitution for lysine overproduction. Finally, a user-friendly online tool named gBIG was provided for designing guide RNAs for base editing-mediated inactivation of given genes in any given sequenced genome ( www.ibiodesign.net/gBIG ).     

Recent advances in plasmid-based tools for establishing novel microbial chassis

A key challenge for domesticating alternative cultivable microorganisms with biotechnological potential lies in the development of innovative technologies. Within this framework, a myriad of genetic tools has flourished, allowing the design and manipulation of complex synthetic circuits and genomes to become the general rule in many laboratories rather than the exception. More recently, with the development of novel technologies such as DNA automated synthesis/sequencing and powerful computational tools, molecular biology has entered the synthetic biology era. In the beginning, most of these technologies were established in traditional microbial models (known as chassis in the synthetic biology framework) such as Escherichia coli and Saccharomyces cerevisiae, enabling fast advances in the field and the validation of fundamental proofs of concept. However, it soon became clear that these organisms, although extremely useful for prototyping many genetic tools, were not ideal for a wide range of biotechnological tasks due to intrinsic limitations in their molecular/physiological properties. Over the last decade, researchers have been facing the great challenge of shifting from these model systems to non-conventional chassis with endogenous capacities for dealing with specific tasks. The key to address these issues includes the generation of narrow and broad host plasmid-based molecular tools and the development of novel methods for engineering genomes through homologous recombination systems, CRISPR/Cas9 and other alternative methods. Here, we address the most recent advances in plasmid-based tools for the construction of novel cell factories, including a guide for helping with “build-your-own” microbial host.     

HIV-1 viral RNA is selected in the form of monomers that dimerize in a three-step protease-dependent process; the DIS of stem-loop 1 initiates viral RNA dimerization

We have characterized the viral RNA conformation in wild-type, protease-inactive (PR-) and SL1-defective (DeltaDIS) human immunodeficiency virus type 1 (HIV-1), as a function of the age of the viruses, from newly released to grown-up (>or=24 h old). We report evidence for packaging HIV-1 genomic RNA (gRNA) in the form of monomers in PR- virions, viral RNA rearrangement (not maturation) within PR- HIV-1, protease-dependent formation of thermolabile dimeric viral RNAs, a new form of immature gRNA dimer at about 5 h post virion release, and slow-acting dimerization signals in SL1-defective viruses. The rates of gRNA dimer formation were >or=3-fold and >or=10-fold slower in DeltaDIS and PR- viruses than in wild-type, respectively. Thus, the DIS, i.e. the palindrome in the apical loop of SL1, is a dimerization initiation signal, but its role can be masked by one or several slow-acting dimerization site(s) when grown-up SL1-inactive virions are investigated. Grown-up PR- virions are not flawless models for immature virions because gRNA dimerization increases with the age of PR- virions, indicating that the PR- mutation does not "freeze" gRNA conformation in a nascent primordial state. Our study is the first on gRNA conformation in newly released mutant or primate retroviruses. It shows for the first time that the packaged retroviral gRNA matures in more than one step, and that formation of immature dimeric viral RNA requires viral protein maturation. The monomeric viral RNAs isolated from budding HIV-1, as modeled by newly released PR- virions, may be seen as dimers that are much more fragile than thermolabile dimers.     

Beyond Plasma Membrane Targeting: Role of the MA domain of Gag in Retroviral Genome Encapsidation

The MA (matrix) domain of the retroviral Gag polyprotein plays several critical roles during virus assembly. Although best known for targeting the Gag polyprotein to the inner leaflet of the plasma membrane for virus budding, recent studies have revealed that MA also contributes to selective packaging of the genomic RNA (gRNA) into virions. In this Review, we summarize recent progress in understanding how MA participates in genome incorporation. We compare the mechanisms by which the MA domains of different retroviral Gag proteins influence gRNA packaging, highlighting variations and similarities in how MA directs the subcellular trafficking of Gag, interacts with host factors and binds to nucleic acids. A deeper understanding of how MA participates in these diverse functions at different stages in the virus assembly pathway will require more detailed information about the structure of the MA domain within the full-length Gag polyprotein. In particular, it will be necessary to understand the structural basis of the interaction of MA with gRNA, host transport factors and membrane phospholipids. A better appreciation of the multiple roles MA plays in genome packaging and Gag localization might guide the development of novel antiviral strategies in the future.     

An RNA Structural Switch Regulates Diploid Genome Packaging by Moloney Murine Leukemia Virus

Retroviruses selectively package two copies of their RNA genomes via mechanisms that have yet to be fully deciphered. Recent studies with small fragments of the Moloney murine leukemia virus (MoMuLV) genome suggested that selection may be mediated by an RNA switch mechanism, in which conserved UCUG elements that are sequestered by base-pairing in the monomeric RNA become exposed upon dimerization to allow binding to the cognate nucleocapsid (NC) domains of the viral Gag proteins. Here we show that a large fragment of the MoMuLV 5′ untranslated region that contains all residues necessary for efficient RNA packaging (Ψ^WT; residues 147-623) also exhibits a dimerization-dependent affinity for NC, with the native dimer ([Ψ^WT]₂) binding 12 ± 2 NC molecules with high affinity (K_d = 17 ± 7 nM) and with the monomer, stabilized by substitution of dimer-promoting loop residues with hairpin-stabilizing sequences (Ψ^M), binding 1-2 NC molecules. Identical dimer-inhibiting mutations in MoMuLV-based vectors significantly inhibit genome packaging in vivo (∼ 100-fold decrease), whereas a large deletion of nearly 200 nucleotides just upstream of the gag start codon has minimal effects. Our findings support the proposed RNA switch mechanism and further suggest that virus assembly may be initiated by a complex comprising as few as 12 Gag molecules bound to a dimeric packaging signal.