Interactions of Escherichia coli RNA with bacteriophage MS2 coat protein: genomic SELEX

Genomic SELEX is a method for studying the network of nucleic acid–protein interactions within any organism. Here we report the discovery of several interesting and potentially biologically important interactions using genomic SELEX. We have found that bacteriophage MS2 coat protein binds several Escherichia coli mRNA fragments more tightly than it binds the natural, well-studied, phage mRNA site. MS2 coat protein binds mRNA fragments from rffG (involved in formation of lipopolysaccharide in the bacterial outer membrane), ebgR (lactose utilization repressor), as well as from several other genes. Genomic SELEX may yield experimentally induced artifacts, such as molecules in which the fixed sequences participate in binding. We describe several methods (annealing of oligonucleotides complementary to fixed sequences or switching fixed sequences) to eliminate some, or almost all, of these artifacts. Such methods may be useful tools for both randomized sequence SELEX and genomic SELEX.     

Parasite-specific aptamers as biosynthetic reagents and potential pharmaceuticals

Aptamers are short, synthetic nucleic acid molecules. They are generated by a Darwinian-type in vitro evolution method known as 'systematic evolution of ligands by exponential enrichment' (SELEX). SELEX represents an experimental platform to identify rare ligands with predetermined functionality from combinatorial nucleic acid libraries. Since its discovery about 20 years ago the method has been instrumental in identifying a large number of aptamers that recognize targets of very different chemistry and molecular complexity. Although aptamers have been converted into sophisticated biomolecular tools for a diverse set of technologies, only a limited number of aptamers have been selected as binding reagents for parasites or parasite-derived molecules. Here the published examples of aptamers that target Leishmania-, Trypanosoma- and Plasmodia-specific molecules are reviewed.     

Selection of genomic sequences that bind tightly to Ff gene 5 protein: primer-free genomic SELEX

Single-stranded DNA or RNA libraries used in SELEX experiments usually include primer-annealing sequences for PCR amplification. In genomic SELEX, these fixed sequences may form base pairs with the central genomic fragments and interfere with the binding of target molecules to the genomic sequences. In this study, a method has been developed to circumvent these artificial effects. Primer-annealing sequences are removed from the genomic library before selection with the target protein and are then regenerated to allow amplification of the selected genomic fragments. A key step in the regeneration of primer-annealing sequences is to employ thermal cycles of hybridization-extension, using the sequences from unselected pools as templates. The genomic library was derived from the bacteriophage fd, and the gene 5 protein (g5p) from the phage was used as a target protein. After four rounds of primer-free genomic SELEX, most cloned sequences overlapped at a segment within gene 6 of the viral genome. This sequence segment was pyrimidine-rich and contained no stable secondary structures. Compared with a neighboring genomic fragment, a representative sequence from the family of selected sequences had about 23-fold higher g5p-binding affinity. Results from primer-free genomic SELEX were compared with the results from two other genomic SELEX protocols.     

Combining SELEX and the yeast three-hybrid system for in vivo selection and classification of RNA aptamers

Aptamers are small nucleic acid ligands that bind to their targets with specificity and high affinity. They are generated by a combinatorial technology, known as SELEX. This in vitro approach uses iterative cycles of enrichment and amplification to select binders from nucleic acid libraries of high complexity. Here we combine SELEX with the yeast three-hybrid system in order to select for RNA aptamers with in vivo binding activity. As a target molecule, we chose the RNA recognition motif-containing RNA-binding protein Rrm4 from the corn pathogen Ustilago maydis. Rrm4 is an ELAV-like protein containing three N-terminal RNA recognition motifs (RRMs). It has been implicated in microtubule-dependent RNA transport during pathogenic development. After 11 SELEX cycles, four aptamer classes were identified. These sequences were further screened for their in vivo binding activity applying the yeast three-hybrid system. Of the initial aptamer classes only members of two classes were capable of binding in vivo. Testing representatives of both classes against Rrm4 variants mutated in one of the three RRM domains revealed that these aptamers interacted with the third RRM. Thus, the yeast three-hybrid system is a useful extension to the SELEX protocol for the identification and characterization of aptamers with in vivo binding activity.     

In vitro selection of high-affinity nucleic acid ligands to parasite target molecules

The logic of using nucleic acids as pharmaceutical reagents is in part based on their capacity to interact with high affinity and specificity with other biological components. Considerable progress has been made over the past 10 years in the development of nucleic acid-based drug molecules using a variety of different technologies. One approach is a combinatorial technology that involves an iterative Darwinian-type in vitro evolution process, which has been termed SELEX for 'systematic evolution of ligands by exponential enrichment'. The procedure is a highly efficient method of identifying rare ligands from combinatorial nucleic acid libraries of very high complexity. It allows the selection of nucleic acid molecules with desired functions and it has been instrumental in the identification of a number of synthetic DNA and RNA molecules, so-called aptamers that recognise ligands of different chemical origin. The method is fast, it does not require special equipment and the selected aptamers typically bind their target with high affinity and high specificity. Here we summarise the recent examples of the SELEX technique within the context of identifying high-affinity ligands against parasite target molecules.     

Monitoring Genomic Sequences during SELEX Using High-Throughput Sequencing: Neutral SELEX

Background

SELEX is a well established in vitro selection tool to analyze the structure of ligand-binding nucleic acid sequences called aptamers. Genomic SELEX transforms SELEX into a tool to discover novel, genomically encoded RNA or DNA sequences binding a ligand of interest, called genomic aptamers. Concerns have been raised regarding requirements imposed on RNA sequences undergoing SELEX selection.

Methodology/Principal Findings

To evaluate SELEX and assess the extent of these effects, we designed and performed a Neutral SELEX experiment omitting the selection step, such that the sequences are under the sole selective pressure of SELEX''s amplification steps. Using high-throughput sequencing, we obtained thousands of full-length sequences from the initial genomic library and the pools after each of the 10 rounds of Neutral SELEX. We compared these to sequences obtained from a Genomic SELEX experiment deriving from the same initial library, but screening for RNAs binding with high affinity to the E. coli regulator protein Hfq. With each round of Neutral SELEX, sequences became less stable and changed in nucleotide content, but no sequences were enriched. In contrast, we detected substantial enrichment in the Hfq-selected set with enriched sequences having structural stability similar to the neutral sequences but with significantly different nucleotide selection.

Conclusions/Significance

Our data indicate that positive selection in SELEX acts independently of the neutral selective requirements imposed on the sequences. We conclude that Genomic SELEX, when combined with high-throughput sequencing of positively and neutrally selected pools, as well as the gnomic library, is a powerful method to identify genomic aptamers.     

SELEX experiments: new prospects, applications and data analysis in inferring regulatory pathways

Systematic Evolution of Ligands by EXponential enrichment (SELEX) is an experimental procedure that allows extraction, from an initially random pool of oligonucleotides, of the oligomers with a desired binding affinity for a given molecular target. The procedure can be used to infer the strongest binders for a given DNA or RNA binding protein, and the highest affinity binding sequences isolated through SELEX can have numerous research, diagnostic and therapeutic applications. Recently, important new modifications of the SELEX protocol have been proposed. In particular, a modification of the standard SELEX procedure allows generating a dataset from which protein-DNA interaction parameters can be determined with unprecedented accuracy. Another variant of SELEX allows investigating interactions of a protein with nucleic-acid fragments derived from the entire genome of an organism. We review here different SELEX-based methods, with particular emphasis on the experimental design and on the applications aimed at inferring protein-DNA interactions. In addition to the experimental issues, we also review relevant methods of data analysis, as well as theoretical modeling of SELEX.     

Short bioactive Spiegelmers to migraine-associated calcitonin gene-related peptide rapidly identified by a novel approach: tailored-SELEX

We developed an integrated method to identify aptamers with only 10 fixed nucleotides through ligation and removal of primer binding sites within the systematic evolution of ligands by exponential enrichment (SELEX) process. This Tailored-SELEX approach was validated by identifying a Spiegelmer (‘mirror-image aptamer’) that inhibits the action of the migraine-associated target calcitonin gene-related peptide 1 (α-CGRP) with an IC₅₀ of 3 nM at 37°C in cell culture. Aptamers are oligonucleotide ligands that can be generated to bind to targets with high affinity and specificity. Stabilized aptamers and Spiegelmers have shown activity in vivo and may be used as therapeutics. Aptamers are isolated by in vitro selection from combinatorial nucleic acid libraries that are composed of a central randomized region and additional fixed primer binding sites with ~30–40 nt. The identified sequences are usually not short enough for efficient chemical Spiegelmer synthesis, post-SELEX stabilization of aptamers and economical production. If the terminal primer binding sites are part of the target recognizing domain, truncation of aptamers has proven difficult and laborious. Tailored-SELEX results in short sequences that can be tested more rapidly in biological systems. Currently, our identified CGRP binding Spiegelmer serves as a lead compound for in vivo studies.     

Generation of amplifiable genome-specific oligonucleotide probes and libraries

Here we describe a process for the generation of oligonucleotide libraries representative of a given nucleic acid. Starting from at random pool of DNA oligonucleotides, the technique selects only those that hybridize to the nucleic acid template. This selection yields a highly specific library that represents an oligonucleotide image of the chosen template. The novel quality of this approach is the generation of amplifiable oligonucleotide probes that are of unique length and are easily subjected to differential selection. Here we apply this technique to produce different genomic oligonucleotide libraries and show that these genomic oligonucleotide libraries do not cross-hybridize. Differential selection of these genomic oligonucleotide libraries produces oligonucleotides that can be used in the identification, characterzation, and isolation of nucleic acids.     

甲基营养菌MP681基因组测序文库的构建

目的:建立甲基营养菌MP681基因组文库,用于鸟枪法测序。方法:提取MP681基因组DNA,经超声随机片段化及T4 DNA聚合酶末端修平处理后,与经SmaⅠ酶切、小牛肠碱性磷酸酶(CIP)去磷酸化处理的pUC19载体连接,电击转化大肠杆菌DH5α感受态,并通过末端双向测序对文库质量进行评价。结果:分别构建了2～4 kb和4～6 kb基因组文库,电泳结果显示插入片段长度与预期符合,文库库容均在10万以上。结论:构建了插入片段大小和库容符合要求的甲基营养菌MP681全基因组鸟枪法2～4 kb、4～6 kb测序文库。     

Locked Nucleic Acid Pentamers as Universal PCR Primers for Genomic DNA Amplification

Background

Multiplexing technologies, which allow for simultaneous detection of multiple nucleic acid sequences in a single reaction, can save a lot of time, cost and labor compared to traditional single reaction detection methods. However, the multiplexing method currently used requires precise handiwork and many complicated steps, making a new, simpler technique desirable. Oligonucleotides containing locked nucleic acid residues are an attractive tool because they have strong affinities for their complementary targets, they have been used to avoid dimer formation and mismatch hybridization and to enhance efficient priming. In this study, we aimed to investigate the use of locked nucleic acid pentamers for genomic DNA amplification and multiplex genotyping.

Results

We designed locked nucleic acid pentamers as universal PCR primers for genomic DNA amplification. The locked nucleic acid pentamers were able to prime amplification of the selected sequences within the investigated genomes, and the resulting products were similar in length to those obtained by restriction digest. In Real Time PCR of genomic DNA from three bacterial species, locked nucleic acid pentamers showed high priming efficiencies. Data from bias tests demonstrated that locked nucleic acid pentamers have equal affinities for each of the six genes tested from the Klebsiella pneumoniae genome. Combined with suspension array genotyping, locked nucleic acid pentamer-based PCR amplification was able to identify a total of 15 strains, including 3 species of bacteria, by gene- and species-specific probes. Among the 32 species used in the assay, 28 species and 50 different genes were clearly identified using this method.

Conclusion

As a novel genomic DNA amplification, the use of locked nucleic acid pentamers as universal primer pairs in conjunction with suspension array genotyping, allows for the identification of multiple distinct genes or species with a single amplification procedure. This demonstrates that locked nucleic acid pentamer-based PCR can be utilized extensively in pathogen identification.     

Libraries of large-insert genomic clones as a tool for molecular cytogenetic analysis of avian genome

Integration of molecular and cytegenetic levels of investigation results in complex understanding of structural and functional genome organization. Gridded libraries of large-insert genomic clones represent a powerful tool of the genome analysis. Their utilization provides coordination of data on molecular organization of nucleic acids with cytogenetic data on the chromosome structure. These libraries played an important role in sequencing of genomes of human, mouse, and other organisms as an instrument linking molecular biological and cytogenetic data via construction of contigs and their localization on the chromosomes. They also enabled analysis of orthology between the mammalian genomes. The existing avian libraries fit molecular cytogenetic analysis of the class Aves genome, and can be successfully used for the isolation and characterization of large genomic fragments. This provides utilization of these libraries not only for the chromosome mapping, but also for positional cloning and search for candidate genes for quantitative traits.     

SELEX技术及Aptamer研究的新进展

综述了近几年指数富集的配体系统进化(SELEX)技术的改良与寡核苷酸配基(aptamer)研究应用方面的新进展.Aptamer是指利用SELEX(systematicevolutionofligandsbyexponentialenrichment)技术,从随机寡核苷酸文库中筛选获得的能够与靶分子特异结合的短单链寡核苷酸配基,通常具有纳摩尔到皮摩尔的亲和力.高通量筛选的技术特点与aptamer精确识别、易体外合成与修饰等特性,使得aptamer在分析化学与生物医药研究方面具有广阔的应用前景.     

Association of Arabidopsis topoisomerase IIA cleavage sites with functional genomic elements and T-DNA loci

Topoisomerase IIA (Topo IIA) is an essential ubiquitous enzyme involved in controlling DNA topology during multiple processes of genome function, and has been implicated in the generation of double-stranded breaks (DSB) in genomic DNA prior to DNA integration in plant genomes. Despite extensive characterization of type II topoisomerases from bacteria, viruses and animals, no studies on the specificity of plant Topo IIA-mediated DNA cleavage have been reported. We mapped and characterized Arabidopsis thaliana Topo IIA (AtTopoIIA) cleavage sites and demonstrated that they were cleaved in vivo. The consensus for the AtTopoIIA cleavage sites (ANNNRN downward arrowGTACNTNNNY) was significantly different from recognition sequences reported for Topo IIA from other organisms. The mapped cleavage sites were abundant in the Arabidopsis genome, exhibited a weak consensus, and were cleaved with relatively low efficiency. Use of the systematic evolution of ligands by exponential enrichment (SELEX) protocol identified a single, efficiently cleaved sequence TATATATATGTATATATATA that was over-represented in the genome. The mapped AtTopoIIA cleavage sites and the SELEX sites differed in their genomic distribution and associations with gene regulatory elements, matrix attachment regions, stress-induced DNA duplex destabilization sequences and T-DNA loci, suggesting different genome functions. Mapped AtTopoIIA sites but not SELEX sites were strongly associated with T-DNA integration sites, providing evidence for the involvement of AtTopoIIA-mediated DSB formation in T-DNA integration.     

应用SELEX技术筛选人类血型IgG适体的实验研究

目的:建立Rh(D)血型的IgG类抗体适体的筛选方法,为后续合成适体并进行新生儿溶血病的防治研究奠定基础。方法:利用SELEX技术,构建含有52个随机序列的单链DNA文库,利用硝酸纤维素膜法筛选与IgG类抗体分子高亲和力结合的核酸分子,同时探索并优化将其扩增为双链DNA核酸库的PCR反应条件;通过膜结合实验检测核酸分子的富集效果并用凝胶阻滞实验初步测定所得核酸适体与Rh(D)血型IgG类抗体的亲和力。结果:随着筛选的进行,核酸分子的富集库向着与靶分子亲和性增强的方向进化,经过了11个循环,筛选出与Rh(D)血型IgG抗体结合力较强的核酸分子,与核酸结合的IgG分子在凝胶阻滞实验中显示出阻滞带。结论:初步建立了利用SELEX技术筛选人类Rh(D)血型IgG抗体适体的方法。     

Detection of new transposable element families in Drosophila melanogaster and Anopheles gambiae genomes

The techniques that are usually used to detect transposable elements (TEs) in nucleic acid sequences rely on sequence similarity with previously characterized elements. However, these methods are likely to miss many elements in various organisms. We tested two strategies for the detection of unknown elements. The first, which we call "TBLASTX strategy," searches for TE sequences by comparing the six-frame translations of the nucleic acid sequences of known TEs with the genomic sequence of interest. The second, "repeat-based strategy," searches genomic sequences for long repeats and clusters them in groups of similar sequences. TE copies from a given family are expected to cluster together. We tested the Drosophila melanogaster genomic sequence and the recently sequenced Anopheles gambiae genome in which most TEs remain unknown. We showed that the "TBLASTX strategy" is very efficient as it detected at least 332 new TE families in D. melanogaster and 400 in A. gambiae. This was unexpected in Drosophila as TEs of this organism have been extensively studied. The "repeat-based strategy" appeared to be very inefficient because of two problems: (i) TE copies are heavily deleted and few copies share homologous regions, and (ii) segmental duplications are frequent and it is not easy to distinguish them from TE copies.     

Selective recognition of a DNA G-quadruplex by an engineered antibody

Particular guanine rich nucleic acid sequences can fold into stable secondary structures called G-quadruplexes. These structures have been identified in various regions of the genome that include the telomeres, gene promoters and UTR regions, raising the possibility that they may be associated with biological function(s). Computational analysis has predicted that intramolecular G-quadruplex forming sequences are prevalent in the human genome, thus raising the desire to differentially recognize genomic G-quadruplexes. We have employed antibody phage display and competitive selection techniques to generate a single-chain antibody that shows >1000-fold discrimination between G-quadruplex and duplex DNA, and furthermore >100-fold discrimination between two related intramolecular parallel DNA G-quadruplexes. The amino acid sequence composition at the antigen binding site shows conservation within the light and heavy chains of the selected scFvs, suggesting sequence requirements for G-quadruplex recognition. Circular dichroism (CD) spectroscopic data showed that the scFv binds to the prefolded G-quadruplex and does not induce G-quadruplex structure formation. This study demonstrates the strongest discrimination that we are aware of between two intramolecular genomic G-quadruplexes.