Use of specific endonuclease cleavage in RNA sequencing.

Nonradioactive RNA fragments may be sequenced by incorporation of (3H)-label into 3'-terminal positions, controlled digestion with specific ribonucleases, and separation according to size of the digestion products on polyethyleneimine- (PEI-) cellulose thin layers. This combination of techniques allows one to measure accurately distances of specific cleavage sites from the labeled terminal positions. The cleavage specificities of RNases T1, U2, and A are utilized to identify the positions of G, A, and pyrimidine residues respectively. C and U may be distinguished by mobility differences on PEI-cellulose thin layers at ph 2.6. The procedure is simple, rapid, and highly sensitive; as little as 0.5 - 1 microgram of a RNA of the size of tRNA will be needed to sequence all fragments in a complete RNase digest.     

单分子实时测序技术的原理与应用

单分子DNA测序技术是近10年发展起来的新一代测序技术,也称为第三代测序技术,包括单分子实时测序、真正单分子测序、单分子纳米孔测序等技术。文章介绍了单分子实时(Single-molecule real-time,SMRT)测序技术的基本原理、性能以及应用。与Sanger测序法和下一代测序技术相比,SMRT测序具有超长读长、测序周期短、无需模板扩增和直接检测表观修饰位点等特点,为研究人员提供了新选择。同时,SMRT测序的低准确率备受争议(约85%),其中约93%的错误是插入缺失,因此,其数据应用于基因组组装前需先对数据进行纠错处理。目前,SMRT测序在小型基因组从头测序和完整组装中已有良好应用,并且已经或将在表观遗传学、转录组学、大型基因组组装等领域发挥其优势,促进基因组学的研究。     

Exploiting single-molecule transcript sequencing for eukaryotic gene prediction

We develop a method to predict and validate gene models using PacBio single-molecule, real-time (SMRT) cDNA reads. Ninety-eight percent of full-insert SMRT reads span complete open reading frames. Gene model validation using SMRT reads is developed as automated process. Optimized training and prediction settings and mRNA-seq noise reduction of assisting Illumina reads results in increased gene prediction sensitivity and precision. Additionally, we present an improved gene set for sugar beet (Beta vulgaris) and the first genome-wide gene set for spinach (Spinacia oleracea). The workflow and guidelines are a valuable resource to obtain comprehensive gene sets for newly sequenced genomes of non-model eukaryotes.

Electronic supplementary material

The online version of this article (doi:10.1186/s13059-015-0729-7) contains supplementary material, which is available to authorized users.     

Solid-phase methods for sequencing nucleic acids. III. Simultaneous sequencing of different long RNA fragments using DE 81 anion-exchange paper

A solid-phase method for simultaneous sequencing of different long RNA fragments has been developed using Whatman DE 81 anion-exchange paper as the support. The approach involves 8 operations including: immobilization of heat-denatured 3'-end labeled RNA fragment on DE 81 paper; washing; modification reactions; washing; aniline reaction; washing; RNA desorption by salt and ethanol precipitation. For modifying the RNA, the following reactions were selected for the routine: G with dimethylsulfate at 90 degrees C/sodium borohydride at 0 degrees C, A + G with diethylpyrocarbonate at 90 degrees C, U + C with hydrazine at 0 degrees C and C with hydrazine/5M NaCl at 0 degrees C. The losses of RNA material during the reactions with large excess of reactants were 50% during the reduction with NaBH4 and 30% during C-reaction. Almost no losses were observed during aniline reaction. The RNA could be recovered by desorption with 2M NaClO4 in 50-70% yield. The whole solid-phase procedure up to the sequencing gel takes about 2 hours and is much faster and more convenient than chemical RNA sequencing in solution according to Peattie, especially if many fragments are to be processed.     

An RNA toolbox for single-molecule force spectroscopy studies

Precise, controllable single-molecule force spectroscopy studies of RNA and RNA-dependent processes have recently shed new light on the dynamics and pathways of RNA folding and RNA-enzyme interactions. A crucial component of this research is the design and assembly of an appropriate RNA construct. Such a construct is typically subject to several criteria. First, single-molecule force spectroscopy techniques often require an RNA construct that is longer than the RNA molecules used for bulk biochemical studies. Next, the incorporation of modified nucleotides into the RNA construct is required for its surface immobilization. In addition, RNA constructs for single-molecule studies are commonly assembled from different single-stranded RNA molecules, demanding good control of hybridization or ligation. Finally, precautions to prevent RNase- and divalent cation-dependent RNA digestion must be taken. The rather limited selection of molecular biology tools adapted to the manipulation of RNA molecules, as well as the sensitivity of RNA to degradation, make RNA construct preparation a challenging task. We briefly illustrate the types of single-molecule force spectroscopy experiments that can be performed on RNA, and then present an overview of the toolkit of molecular biology techniques at one's disposal for the assembly of such RNA constructs. Within this context, we evaluate the molecular biology protocols in terms of their effectiveness in producing long and stable RNA constructs.     

Multicolor single-molecule FRET for DNA and RNA processes

Single-molecule fluorescence resonance energy transfer (smFRET) is a useful tool for observing the dynamics of protein–nucleic acid interactions. Although most smFRET measurements have used two fluorophores, multicolor smFRET measurements using more than two fluorophores offer more information about how protein–nucleic acid complexes dynamically move, assemble, and disassemble. Multicolor smFRET experiments include three or more fluorophores and at least one donor-acceptor pair. This review highlights how multicolor smFRET is being used to probe the dynamics of three different classes of biochemical processes—protein-DNA interactions, chromatin remodeling, and protein translation.     

Synthetic metallonucleases for RNA cleavage

Synthetic metallonucleases are versatile metal ion catalysts that use multiple catalytic strategies for the cleavage of RNA. Recent work in the design of more active metallonucleases combines a single metal ion with functional groups that interact with RNA, including amino acid fragments or additional metal ions. Rate enhancements by multifunctional catalysts for cleavage of simple model substrates with good leaving groups are as high as 10(6) but somewhat lower (10(5)) for real RNA. However, cleavage of RNA substrates is complicated by different binding modes and steric interactions that can interfere with catalysis. Antisense oligonucleotides, peptides and small molecules that act as RNA recognition agents increase the strength of substrate binding, but not necessarily the catalytic rate constant. In general, catalytic strategies used by synthetic metallonucleases are probably not optimized. A better grasp of the mechanism of RNA cleavage by metal ions and more effort on positioning the metal ion complex with respect to the cleavage site may lead to improved catalysts.     

Towards single-molecule DNA sequencing: assays with low nonspecific adsorption

New DNA sequencing techniques are currently being developed using single-molecule fluorescence-based detection of enzymatic double-strand synthesis. Such application requires surface architectures on which single-stranded templates can be immobilized. A further important attribute is a very low tendency to attract fluorescently labeled bases nonspecifically. On this account, the adsorption behaviour of Cy5-dNTPs on a variety of surface coatings was studied by performing real-time measurements of the DNA synthesis using a supercritical angle fluorescence biosensor. It is demonstrated that polyacrylic acid coatings are an excellent choice to minimize the nonspecific binding of the bases.     

Progress towards single-molecule DNA sequencing: a one color demonstration

Single molecules of fluorescently labeled nucleotides were detected during the cleavage of individual DNA fragments by a processive exonuclease. In these experiments, multiple (10-100) strands of DNA with tetramethyl rhodamine labeled dUMP (TMR-dUMP) incorporated into the sequence were anchored in flow upstream of the detection region of an ultra sensitive flow cytometer. A dilute solution of Exonuclease I passed over the microspheres. When an exonuclease attached to a strand, processive digestion of that strand began. The liberated, labeled bases flowed through the detection region and were detected at high efficiency at the single-molecule level by laser-induced fluorescence. The digestion of a single strand of DNA by a single exonuclease was discernable in these experiments. This result demonstrates the feasibility of single-molecule DNA sequencing. In addition, these experiments point to a new and practical means of arriving at a consensus sequence by individually reading out identical sequences on multiple fragments.     

Lesion recognition and cleavage by endonuclease V: a single-molecule study

Endonuclease V (endo V) recognizes and cleaves deoxyinosine in deaminated DNA. These enzymatic activities are precursors of DNA repair and are fueled by metal ions such as Ca2+ and Mg2+, with the former being associated with protein binding and the latter with DNA cleavage. Using the technique of fluorescence resonance energy transfer (FRET), we determined the single-molecule kinetics of endo V in a catalytic cycle using a substrate of deoxyinosine-containing single-stranded DNA (ssDNA). The ssDNA was labeled with TAMRA, a fluorescence donor, while the endo V was labeled with Cy5, a fluorescence acceptor. The time lapses of FRET, resulting from the sequential association, recognition, and dissociation of the deoxyinosine by the endo V, were determined at 5.9, 14.5, and 9.1 s, respectively, in the presence of Mg2+. In contrast, the process of deoxyinosine recognition appeared little affected by the metal type. The prolonged association and dissociation events in the presence of the Ca2+-Mg2+ combination, as compared to that of Mg2+ alone, support the hypothesis that endo V has two metal binding sites to regulate its enzymatic activities.