A toolbox and procedural notes for characterizing novel zinc finger nucleases for genome editing in plant cells

The induction of double-strand breaks (DSBs) in plant genomes can lead to increased homologous recombination or site-specific mutagenesis at the repair site. This phenomenon has the potential for use in gene targeting applications in plant cells upon the induction of site-specific genomic DSBs using zinc finger nucleases (ZFNs). Zinc finger nucleases are artificial restriction enzymes, custom-designed to cleave a specific DNA sequence. The tools and methods for ZFN assembly and validation could potentially boost their application for plant gene targeting. Here we report on the design of biochemical and in planta methods for the analysis of newly designed ZFNs. Cloning begins with de novo assembly of the DNA-binding regions of new ZFNs from overlapping oligonucleotides containing modified helices responsible for DNA-triplet recognition, and the fusion of the DNA-binding domain with a Fok I endonuclease domain in a dedicated plant expression cassette. Following the transfer of fully assembled ZFNs into Escherichia coli expression vectors, bacterial lysates were found to be most suitable for in vitro digestion analysis of palindromic target sequences. A set of three in planta activity assays was also developed to confirm the nucleic acid digestion activity of ZFNs in plant cells. The assays are based on the reconstruction of GUS expression following transient or stable delivery of a mutated uidA and ZFN-expressing cassettes into target plants cells. Our tools and assays offer cloning flexibility and simple assembly of tested ZFNs and their corresponding target sites into Agrobacterium tumefaciens binary plasmids, allowing efficient implementation of ZFN-validation assays in planta .     

Targeting DNA with triplex-forming oligonucleotides to modify gene sequence

Molecules that interact with DNA in a sequence-specific manner are attractive tools for manipulating gene sequence and expression. For example, triplex-forming oligonucleotides (TFOs), which bind to oligopyrimidine.oligopurine sequences via Hoogsteen hydrogen bonds, have been used to inhibit gene expression at the DNA level as well as to induce targeted mutagenesis in model systems. Recent advances in using oligonucleotides and analogs to target DNA in a sequence-specific manner will be discussed. In particular, chemical modification of TFOs has been used to improve binding to chromosomal target sequences in living cells. Various oligonucleotide analogs have also been found to expand the range of sequences amenable to manipulation, including so-called "Zorro" locked nucleic acids (LNAs) and pseudo-complementary peptide nucleic acids (pcPNAs). Finally, we will examine the potential of TFOs for directing targeted gene sequence modification and propose that synthetic nucleases, based on conjugation of sequence-specific DNA ligands to DNA damaging molecules, are a promising alternative to protein-based endonucleases for targeted gene sequence modification.     

Rapid routes of synthesis of chemically reactive and highly radioactively labeled alpha- and beta-oligonucleotide derivatives for in vivo studies

Development of the antisense oligonucleotide strategy for the regulation of gene expression in vivo poses several problems: the stability of oligonucleotides toward intracellular nucleases, labeling of oligonucleotides with high specific radioactivity, improvements of penetration of oligonucleotides into living cells, and enhancement of antisense action by coupling of chemically active groups. In the present paper synthesis of highly radioactively labeled [32P]- and [35S]oligonucleotide derivatives is described starting from both natural (beta) and nuclease-resistant (alpha) anomers of oligonucleotides. Conditions for preparative phosphorylation and thiophosphorylation suitable for oligonucleotides of various lengths, base composition, and anomeric forms were established. The stability of the phosphoramide bond under in vivo experimental conditions was checked. The methods of terminal phosphate chemical activation and terminal thiophosphate alkylation were applied to synthesize oligonucleotides equipped with hydrophobic, intercalating, alkylating, and photoactivatable groups. In the case of porphyrin-oligonucleotide conjugates, a series of new monofunctional porphyrin derivatives bearing a free aliphatic amino group was developed.     

Single-stranded DNA versus tailed duplex in sequence conversion of lacZα DNA

Abstract

Targeted DNA editing has great potential to cure some genetic diseases; however, the use of artificial nucleases such as CRISPR-Cas9 and TALEN in gene therapy can potentially cause severe side effects due to off-target DNA cleavages. Single-stranded (ss) DNAs and 5'-tailed duplexes (TDs) can achieve target base substitutions when introduced without artificial nucleases into cultured cells and mouse liver. In this study, ss DNA and TD were separately co-introduced into human U2OS cells, together with a target plasmid DNA bearing an inactivated lacZα gene, and the gene correction efficiencies were compared. Unlike the genes examined in previous studies, ss DNA and TD showed similar efficiencies. Therefore, ss DNAs might be as useful as TD for gene correction, depending on the target sequence.     

In vitro selection of oligonucleotides that bind double-stranded DNA in the presence of triplex-stabilizing agents

A SELEX approach has been developed in order to select oligonucleotides that bind double-stranded DNA in the presence of a triplex-stabilizing agent, and was applied to a target sequence containing an oligopurine–oligopyrimidine stretch. After only seven rounds of selection, the process led to the identification of oligonucleotides that were able to form triple helices within the antiparallel motif. Inspection of the selected sequences revealed that, contrary to GC base pair which were always recognized by guanines, recognition of AT base pair could be achieved by either adenine or thymine, depending on the sequence context. While thymines are strongly preferred for several positions, some others can accommodate the presence of adenines. These results contribute to set the rules for designing oligonucleotides that form stable triple helices in the presence of triplex-stabilizing agents at physiological pH. They set the basis for further experiments regarding extension of potential target sequences for triple-helix formation or recognition of ligand–DNA complexes.     

快速构建CRISPR/Cas9基因组靶向编辑系统

CRISPR/Cas9核酸酶作为一种新的基因组靶向编辑技术,已成功应用于多种动植物基因组修饰研究. CRISPR/Cas9作用后的阳性细胞筛选和富集是该技术的关键之一. 本研究以鸡EAV-HP（endogenous avian retrovirus-HP）基因和MSTN（myostatin）基因为例,从靶位点的选择、表达载体构建、双基因报告载体构建和核酸酶活性验证4个方面,系统研究了CRISPR/Cas9核酸酶技术平台. 结果表明,利用寡聚核苷酸直接退火方法,构建表达载体和报告载体的阳性率分别高达100%和89.5%. 报告载体的PuroR（puromycin resistant gene）和eGFP（enhanced green fluorescent protein）基因的成功表达表明,构建的CRISPR/Cas9系统能有效切割靶序列,并用于后续阳性克隆的筛选和富集. 本方法摒弃了传统分子克隆的PCR扩增和酶切处理目标基因的方法,而是利用寡聚核苷酸直接退火获得含有黏性末端的目标DNA,简化了载体构建过程,低成本且快速获得CRISPR/Cas9基因组靶向编辑系统.     

Site-directed gene mutation at mixed sequence targets by psoralen-conjugated pseudo-complementary peptide nucleic acids

Sequence-specific DNA-binding molecules such as triple helix-forming oligonucleotides (TFOs) provide a means for inducing site-specific mutagenesis and recombination at chromosomal sites in mammalian cells. However, the utility of TFOs is limited by the requirement for homopurine stretches in the target duplex DNA. Here, we report the use of pseudo-complementary peptide nucleic acids (pcPNAs) for intracellular gene targeting at mixed sequence sites. Due to steric hindrance, pcPNAs are unable to form pcPNA–pcPNA duplexes but can bind to complementary DNA sequences by Watson–Crick pairing via double duplex-invasion complex formation. We show that psoralen-conjugated pcPNAs can deliver site-specific photoadducts and mediate targeted gene modification within both episomal and chromosomal DNA in mammalian cells without detectable off-target effects. Most of the induced psoralen-pcPNA mutations were single-base substitutions and deletions at the predicted pcPNA-binding sites. The pcPNA-directed mutagenesis was found to be dependent on PNA concentration and UVA dose and required matched pairs of pcPNAs. Neither of the individual pcPNAs alone had any effect nor did complementary PNA pairs of the same sequence. These results identify pcPNAs as new tools for site-specific gene modification in mammalian cells without purine sequence restriction, thereby providing a general strategy for designing gene targeting molecules.     

Structural constraints regulating triple helix formation by A-tracts

The study concerns the propensity of triple helix formation by different DNA oligonucleotides containing long A-tracts with and without flanking GxC base pairs in order to probe the role of length of the A-tract and the flanking sequences. From nuclear magnetic resonance (NMR) studies of imino proton spectra and circular dichroism (CD) spectroscopy of samples composed of potential triplex forming strand sequences in correct stoichiometries, we have concluded that 8-mer A-tracts flanked by GxC base pairs exert significant steric hindrance to triple helix formation. When as much as 50 mM Mg2+ was added, no triple helix formation was observed in these samples. In contrast, open-ended 8-mer A-tracts formed triplex with the corresponding two T8 strands under relatively mild ionic conditions (100 mM Na+). Moreover, the shorter the length of the A-tract, the less is the hindrance to form a triple helix.     

Microfluidic PicoArray synthesis of oligodeoxynucleotides and simultaneous assembling of multiple DNA sequences

Large DNA constructs of arbitrary sequences can currently be assembled with relative ease by joining short synthetic oligodeoxynucleotides (oligonucleotides). The ability to mass produce these synthetic genes readily will have a significant impact on research in biology and medicine. Presently, high-throughput gene synthesis is unlikely, due to the limits of oligonucleotide synthesis. We describe a microfluidic PicoArray method for the simultaneous synthesis and purification of oligonucleotides that are designed for multiplex gene synthesis. Given the demand for highly pure oligonucleotides in gene synthesis processes, we used a model to improve key reaction steps in DNA synthesis. The oligonucleotides obtained were successfully used in ligation under thermal cycling conditions to generate DNA constructs of several hundreds of base pairs. Protein expression using the gene thus synthesized was demonstrated. We used a DNA assembly strategy, i.e. ligation followed by fusion PCR, and achieved effective assembling of up to 10 kb DNA constructs. These results illustrate the potential of microfluidics-based ultra-fast oligonucleotide parallel synthesis as an enabling tool for modern synthetic biology applications, such as the construction of genome-scale molecular clones and cell-free large scale protein expression.     

Recognition of hairpin-containing single-stranded DNA by oligonucleotides containing internal acridine derivatives.

Oligodeoxynucleotides with an internal intercalating agent have been targeted to single-stranded sequences containing hairpin structures. The oligonucleotide binds to nonadjacent single-stranded sequences on both sides of the hairpin structure in such a way as to form a three-way junction. The acridine derivative is inserted at a position that allows it to interact with the three-way junction. The melting temperature (Tm) of complexes formed between the hairpin-containing target and oligonucleotides containing one internal acridine derivative was higher than that obtained with the same target and an unmodified oligonucleotide (DeltaTm = +13 degrees C). The internal acridine provided the oligonucleotide with a higher affinity than covalent attachment to the 5' end. Oligonucleotides could also be designed to recognize a hairpin-containing single-stranded nucleic acid by formation of Watson-Crick hydrogen bonds with a single-stranded part and Hoogsteen hydrogen bonds with the stem of the hairpin. An internal acridine derivative was introduced at the junction between the two domains, the double helix domain with Watson-Crick base pairs and the triple helix domain involving Hoogsteen base triplets in the major groove of the hairpin stem. Oligonucleotides with an internal acridine or an acridine at their 5' end have similar binding affinities for the stem-loop-containing target. The bis-modified oligonucleotide containing two acridines, one at the 5' end and one at an internal site, did not exhibit a higher affinity than the oligonucleotides with only one intercalating agent. The design of oligonucleotides with an internal intercalating agent might be of interest to control gene expression through recognition of secondary structures in single-stranded targets.     

人工转录因子研究进展

转录因子是真核表达调控中非常重要的一类反式作用因子,通常由DNA结合结构域与效应结构域两部分组成,研究发现这两个结构域可以各自独立发生作用。基于转录因子的这种结构特点,可以人为地选择针对特定序列的DNA结合结构域与具有特定作用的效应结构域构建人工转录因子。目前人工转录因子的DNA结合结构域多为C₂H₂ 型锌指结构,每一个锌指单元由大约30个氨基酸组成,识别DNA双螺旋大沟中相连的3bp序列,并可通过氢键作用与相应的碱基结合;多个锌指可以串联成簇,从而识别并结合较长的DNA序列区域。常见的人工转录因子的效应结构域有激活结构域以及抑制结构域,不同的效应结构域赋予人工转录因子不同的功能。目前人工转录因子已经在基础研究、药物设计以及基因治疗等领域得到了广泛的应用。     

Azole substituted oligonucleotides promote antiparallel triplex formation at non-homopurine duplex targets.

The ability of certain azole substituted oligodeoxy-ribonucleotides to promote antiparallel triple helix formation with duplex targets having CG or TA interruptions in the otherwise homopurine sequence was examined. 2'-Deoxyribonucleosides of the azoles, which include pyrazole, imidazole, 1,2,4-triazole and 1,2,3,4-tetrazole were synthesized using the stereo-specific sodium salt glycosylation procedure. These nucleosides were successfully incorporated using solid-support, phosphoramidite chemistry, into oligonucleotides designed to interact with the non-homopurine duplex targets. The interaction of these modified oligonucleotides with all four possible base pairs was evaluated and compared to similar data for a series of natural oligonucleotides. The oligonucleotides containing simple azoles enhanced the triplex forming ability considerably at non-homopurine targets. Binding of these modified oligonucleotides to duplex targets containing TA inversion sites was particularly noteworthy, and compare favorably to unmodified oligonucleotides for binding to duplex targets containing CG as well as TA base pairs. The selectivity exhibited by certain azoles is suggestive of base pair specific interactions. Thus, the azoles evaluated during this study show considerable promise for efforts to develop generalized triplex formation at non-homopurine duplex sequences.     

Cationic oligonucleotides can mediate specific inhibition of gene expression in Xenopus oocytes.

Base-specific hydrogen bonding between an oligonucleotide and the purines in the major groove of a DNA duplex provide an approach to selective inhibition of gene expression. Oligonucleotide-mediated triplex formation in vivo may be enhanced by a number of different chemical modifications. We have previously described an in vitro analysis of triplex formation using oligonucleotides containing internucleoside phosphate linkages modified with the cation N , N -diethyl-ethylenediamine (DEED). When compared with unmodified oligonucleotides of identical base composition, DEED-modified oligonucleotides were better able to form DNA triplexes under conditions that approximate the pH, magnesium and potassium levels found in vivo . Here we report the ability of DEED-modified oligonucleotides to inhibit the expression of plasmid DNA injected into Xenopus oocytes. Inhibition is specific to plasmids containing a triplex formation target and sensitive to sequence alteration in the triplex forming target site. Inhibition of gene expression was nearly complete when oligonucleotide and plasmid were mixed together prior to injection. Inhibition was partial when oligonucleotide was injected first and not evident when plasmid was injected and allowed to form chromatin prior to oligonucleotide injection. Thus, access to DNA is a determining factor in effective triplex inhibition of gene expression.