High-resolution functional mapping of the venezuelan equine encephalitis virus genome by insertional mutagenesis and massively parallel sequencing

We have developed a high-resolution genomic mapping technique that combines transposon-mediated insertional mutagenesis with either capillary electrophoresis or massively parallel sequencing to identify functionally important regions of the Venezuelan equine encephalitis virus (VEEV) genome. We initially used a capillary electrophoresis method to gain insight into the role of the VEEV nonstructural protein 3 (nsP3) in viral replication. We identified several regions in nsP3 that are intolerant to small (15 bp) insertions, and thus are presumably functionally important. We also identified nine separate regions in nsP3 that will tolerate small insertions at low temperatures (30°C), but not at higher temperatures (37°C, and 40°C). Because we found this method to be extremely effective at identifying temperature sensitive (ts) mutations, but limited by capillary electrophoresis capacity, we replaced the capillary electrophoresis with massively parallel sequencing and used the improved method to generate a functional map of the entire VEEV genome. We identified several hundred potential ts mutations throughout the genome and we validated several of the mutations in nsP2, nsP3, E3, E2, E1 and capsid using single-cycle growth curve experiments with virus generated through reverse genetics. We further demonstrated that two of the nsP3 ts mutants were attenuated for virulence in mice but could elicit protective immunity against challenge with wild-type VEEV. The recombinant ts mutants will be valuable tools for further studies of VEEV replication and virulence. Moreover, the method that we developed is applicable for generating such tools for any virus with a robust reverse genetics system.     

Rapid automated simultaneous screening of (G1691A) Factor V, (G20210A) prothrombin,and (C677T) methylenetetrahydrofolate reductase variants by multiplex PCR using fluorescence scanning technology

The Factor V Leiden mutation (G1691A), and mutations in the prothrombin (G20210A) and 5,10-methylenetetrahydrofolate reductase (C677T) genes are common hereditary risk factors associated with venous thrombosis. The aim of this study was to develop an automated, PCR-based genotyping assay for rapid simultaneous screening of these three mutations. We adapted multiplex PCR, using primer modifications to introduce cleavage sites for restriction endonucleases into the fragments bearing each of the mutations. The three mutations were analyzed in a single tube by fluorescence scanning. An internal digestion control was introduced to prevent false-negative results due to incomplete digestion or a total lack of digestion. DNA fragment analysis was carried out using an automated capillary electrophoresis instrument (ABI310). This reliable, efficient, easy-to-use assay can be applied to specimens from large clinical trials and epidemiological surveys.     

Automated constant denaturant capillary electrophoresis applied for detection of KRAS exon 1 mutations

In this study, we have applied automated constant denaturant capillary electrophoresis (ACDCE) for the detection of KRAS exon 1 mutations. Samples from 191 sporadic colon carcinomas previously analyzed for KRAS mutations with allele-specific PCR (ASPCR), temporal temperature gradient electrophoresis (TTGE), and constant denaturant capillary electrophoresis (CDCE) were analyzed. In ACDCE, an unmodified ABI Prism 310 genetic analyzer with constant denaturant conditions separated fluorescein-labeled PCR products. Temperature in combination with a chemical denaturant was used for separation. The optimal separation conditions for PCR-amplified KRAS exon 1 fragments were determined by adjusting the temperature before electrophoresis. In the ACDCE analysis, the sequence of a mutant was determined by comparing the electropherogram of the fragment to that of known mutations followed by mixing the sample with control mutations before reanalysis. In a titration experiment mixing mutant and wild-type alleles, the sensitivity for mutation detection was shown to be 0.6% in this automated CDCE technique. The automation of CDCE allowed rapid analysis of a large number of test samples over as short period of time and with a commercially available apparatus.     

Approach to analysis of single nucleotide polymorphisms by automated constant denaturant capillary electrophoresis

Melting gel techniques have proven to be amenable and powerful tools in point mutation and single nucleotide polymorphism (SNP) analysis. With the introduction of commercially available capillary electrophoresis instruments, a partly automated platform for denaturant capillary electrophoresis with potential for routine screening of selected target sequences has been established. The aim of this article is to demonstrate the use of automated constant denaturant capillary electrophoresis (ACDCE) in single nucleotide polymorphism analysis of various target sequences. Optimal analysis conditions for different single nucleotide polymorphisms on ACDCE are evaluated with the Poland algorithm. Laboratory procedures include only PCR and electrophoresis. For direct genotyping of individual SNPs, the samples are analyzed with an internal standard and the alleles are identified by co-migration of sample and standard peaks.In conclusion, SNPs suitable for melting gel analysis based on theoretical thermodynamics were separated by ACDCE under appropriate conditions. With this instrumentation (ABI 310 Genetic Analyzer), 48 samples could be analyzed without any intervention. Several institutions have capillary instrumentation in-house, thus making this SNP analysis method accessible to large groups of researchers without any need for instrument modification.     

Easy quantitative assessment of genome editing by sequence trace decomposition

The efficacy and the mutation spectrum of genome editing methods can vary substantially depending on the targeted sequence. A simple, quick assay to accurately characterize and quantify the induced mutations is therefore needed. Here we present TIDE, a method for this purpose that requires only a pair of PCR reactions and two standard capillary sequencing runs. The sequence traces are then analyzed by a specially developed decomposition algorithm that identifies the major induced mutations in the projected editing site and accurately determines their frequency in a cell population. This method is cost-effective and quick, and it provides much more detailed information than current enzyme-based assays. An interactive web tool for automated decomposition of the sequence traces is available. TIDE greatly facilitates the testing and rational design of genome editing strategies.     

High-throughput S-SAP by fluorescent multiplex PCR and capillary electrophoresis in plants

The inherent replicative mode of transposition endows retrotransposons with considerable advantages as genetic tools in plant genome analysis. Here we present a high-throughput sequence-specific amplification polymorphism (S-SAP) method based on copia-like retrotransposons to fulfill the increasing desire of screening large numbers of samples in plants. Classic approach for digestion, ligation and pre-amplification was combined with optimized fluorescent multiplex PCR for simultaneously selective amplifying S-SAP fragments, and multiple S-SAPs were subsequently detected by capillary electrophoresis using ABI PRISM 3700 capillary instruments. Comparisons of results from multiplex PCR with simplex PCR, and from capillary electrophoresis with slab-gel electrophoresis demonstrated that this method is an efficient, economical, and accurate means for high-throughput and large-scale genotyping retrotransposon variation in plants.     

Cloning of AFLP markers detected by fluorescence capillary electrophoresis

The available methods to isolate specific amplified fragment length polymorphism (AFLP) markers can be used only if markers are detected by radioactive labeling, silver staining, or ethidium bromide staining; these methods are useless if modern and automated genetic analyzers are used to detect AFLP markers by fluorescent labeling. We have developed a method that allows for isolation and cloning of specific AFLP markers obtained with a laser-induced fluorescence capillary electrophoresis system. This procedure has been tested on 5Arabidopsis thaliana polymorphic AFLP markers, and the nucleotide sequences obtained from these cloned markers were identified and located in theArabidopsis genome.     

Two-point fluorescence detection and automated fraction collection applied to constant denaturant capillary electrophoresis

Constant denaturant capillary electrophoresis (CDCE) has been shown to be a sensitive method to detect point mutations in DNA sequences of 100-bp lengths. Here, we report a significant modifications for the instrumental setup that allows a highly accurate prediction of the elution time of DNA fragments from the capillary and an efficient collection of separated fractions. Fluorescently labeled DNA fragments of TP53 exon 8 wild-type and two mutants (base pair number 14480 and 14525) are detected at two separate points of the same capillary. This permits the precise calculation of the fragment velocity after separation in the heated zone because, at room temperature, all DNA fragments of the same length have the same velocity. Such precision permits the selective collection of separated fragments using an automated fraction collector for additional CDCE analysis or sequencing. Also, the two-point detection allows one to rapidly distinguish between double-stranded and single-stranded DNA fragments of the same length, a process that cannot be achieved with a one-point detection system alone. Both modifications greatly improve the procedure to detect novel mutations by means of CDCE.     

Expanding the CRISPR toolbox for Chinese hamster ovary cells with comprehensive tools for Mad7 genome editing

The production of high-value biopharmaceuticals is dominated by mammalian production cells, particularly Chinese hamster ovary (CHO) cells, which have been widely used and preferred in manufacturing processes. The discovery of CRISPR-Cas9 significantly accelerated cell line engineering advances, allowing for production yield and quality improvements. Since then, several other CRISPR systems have become appealing genome editing tools, such as the Cas12a nucleases, which provide broad editing capabilities while utilizing short guide RNAs (gRNAs) that reduce the complexity of the editing systems. One of these is the Mad7 nuclease, which has been shown to efficiently convey targeted gene disruption and insertions in several different organisms. In this study, we demonstrate that Mad7 can generate indels for gene knockout of host cell proteins in CHO cells. We found that the efficiency of Mad7 depends on the addition of protein nuclear localization signals and the gRNAs employed for genome targeting. Moreover, we provide computational tools to design Mad7 gRNAs against any genome of choice and for automated indel detection analysis from next-generation sequencing data. In summary, this paper establishes the application of Mad7 in CHO cells, thereby improving the CRISPR toolbox versatility for research and cell line engineering.     

On-line melting of double-stranded DNA for analysis of single-stranded DNA using capillary electrophoresis

Capillary electrophoresis (CE) is a convenient, fast and non-radioactive method with possibilities for automatization. To analyse single-stranded DNA molecules in a more automated way, we developed a heating device to melt double-stranded DNA fragments in the capillary during electrophoresis. In this study we used this device to obtain single-stranded DNA, necessary for the detection of point mutations in DNA using the single-strand conformation polymorphism technique. Results show that double-stranded DNA molecules can be melted on-line into single-stranded DNA molecules, although not for 100%. In an attempt to find universal electrophoretic conditions for the analysis of single-stranded DNA, we investigated the influence of several parameters on the yield of single-stranded DNA molecules and on the resolution of the single-stranded DNA peaks. We demonstrate that this heating device is a technical adjustment of CE which contributes to more automated analyses of DNA fragments.     

Molecular characterization of ENU mouse mutagenesis and archives

The large-scale mouse mutagenesis with ENU has provided forward-genetic resources for functional genomics. The frozen sperm archive of ENU-mutagenized generation-1 (G1) mice could also provide a "mutant mouse library" that allows us to conduct reverse genetics in any particular target genes. We have archived frozen sperm as well as genomic DNA from 9224 G1 mice. By genome-wide screening of 63 target loci covering a sum of 197 Mbp of the mouse genome, a total of 148 ENU-induced mutations have been directly identified. The sites of mutations were primarily identified by temperature gradient capillary electrophoresis method followed by direct sequencing. The molecular characterization revealed that all the identified mutations were point mutations and mostly independent events except a few cases of redundant mutations. The base-substitution spectra in this study were different from those of the phenotype-based mutagenesis. The ENU-based gene-driven mutagenesis in the mouse now becomes feasible and practical.     

High-throughput single-strand conformation polymorphism analysis by capillary electrophoresis

Mutation detection plays a great role in genetic and medical research and clinical diagnosis of inherited diseases and particular cancers. Single-strand conformation polymorphism (SSCP) analysis is one of the most popular methods for detection of mutations. Recently, automated capillary electrophoresis (CE) systems have been used in SSCP analysis instead of conventional slab gel electrophoresis. SSCP analysis in combination with CE is a rapid, simple, sensitive and high-throughput mutation screening tool, and has been successfully applied for mutation detection involving human tumor suppressor genes, oncogenes and disease-causing genes. The new technique has a great potential for mutation screening of large numbers of samples in clinical diagnosis. This review discusses basic issues about the methodology of SSCP analysis based on CE and summarizes several key applications.     

The use of capillary electrophoresis for DNA polymorphism analysis

Capillary electrophoresis has advanced enormously over the last 10 yr as a tool for DNA sequencing, driven by the human and other major genome projects and by the need for rapid electrophoresis-based DNA diagnostic tests. The common need of these analyses is a platform providing very high throughput, high-quality data, and low process costs. These demands have led to capillary electrophoresis machines with multiple capillaries providing highly parallel analyses, to new electrophoresis matrices, to highly sensitive spectrofluorometers, and to brighter, spectrally distinct fluorescent dyes with which to label DNA. Capillary devices have also been engineered onto microchip formats, on which both the amount of sample required for analysis and the speed of analysis are increased by an order of magnitude. This review examines the advances made in capillary and chip-based microdevices and in the different DNA-based assays developed for mutation detection and genotype analysis using capillary electrophoresis. The automation of attendant processes such as for DNA sample preparation, PCR, and analyte purification are also reviewed. Together, these technological developments provide the throughput demanded by the large genome-sequencing projects.     

Mutation detection using Surveyor nuclease

We have developed a simple and flexible mutation detection technology for the discovery and mapping of both known and unknown mutations. This technology is based on a new mismatch-specific DNA endonuclease from celery, Surveyor nuclease, which is a member of the CEL nuclease family of plant DNA endonucleases. Surveyor nuclease cleaves with high specificity at the 3' side of any mismatch site in both DNA strands, including all base substitutions and insertion/deletions up to at least 12 nucleotides. Surveyor nuclease technology involves four steps: (i) PCR to amplify target DNA from both mutant and wild-type reference DNA; (ii) hybridization to form heteroduplexes between mutant and wild-type reference DNA; (iii) treatment of annealed DNA with Surveyor nuclease to cleave heteroduplexes; and (iv) analysis of digested DNA products using the detection/separation platform of choice. The technology is highly sensitive, detecting rare mutants present at as low as 1 in 32 copies. Unlabeled Surveyor nuclease digestion products can be analyzed using conventional gel electrophoresis or high-performance liquid chromatography (HPLC), while end labeled digestion products are suitable for analysis by automated gel or capillary electrophoresis. The entire protocol can be performed in less than a day and is suitable for automated and high-throughput procedures.     

A sequential transformation method for validating soybean genome editing by CRISPR/Cas9 system

This study was performed to evaluate the sequential transformation for soybean genome editing using the CRISPR/Cas9 system as well as to show a strategy for examining the activity of CRISPR/Cas9 constructs, especially the designed guide RNAs (gRNAs). The gRNAs for targeted mutations of an exogenous gene and multiple endogenous genes were constructed and transferred into a stably-overexpressed-Cas9 soybean line using Agrobacterium rhizogenes-mediated hairy root induction system. The targeted mutations were identified and characterized by the poly-acrylamide gel electrophoresis (PAGE) heteroduplex method and by sequencing. Induced mutations of the exogenous gene (gus) were observed in 57% of tested transgenic hairy roots, while 100% of the transgenic root lines showed targeted mutations of the endogenous (SACPD-C) gene. Multiple gRNAs targeting two endogenous genes (SACPD-C and SMT) induced mutation rates of 75% and 67%, respectively. Various indels including small and large deletions as well as insertions were found in target sites of the tested genes. This sequential transformation method could present the targeting efficacy of different gRNAs of each tested gene. Additionally, in this study differences in gRNA ratings were found between bioinformatics predictions and actual experimental results. This is the first successful application of the sequential transformation method for genome editing in soybean using the hairy root system. This method could be potentially useful for validating CRISPR/Cas9 constructs, evaluating gRNA targeting efficiencies, and could be applied for other research directions.     

HGVbase: a human sequence variation database emphasizing data quality and a broad spectrum of data sources

HGVbase (Human Genome Variation database; http://hgvbase.cgb.ki.se, formerly known as HGBASE) is an academic effort to provide a high quality and non-redundant database of available genomic variation data of all types, mostly comprising single nucleotide polymorphisms (SNPs). Records include neutral polymorphisms as well as disease-related mutations. Online search tools facilitate data interrogation by sequence similarity and keyword queries, and searching by genome coordinates is now being implemented. Downloads are freely available in XML, Fasta, SRS, SQL and tagged-text file formats. Each entry is presented in the context of its surrounding sequence and many records are related to neighboring human genes and affected features therein. Population allele frequencies are included wherever available. Thorough semi-automated data checking ensures internal consistency and addresses common errors in the source information. To keep pace with recent growth in the field, we have developed tools for fully automated annotation. All variants have been uniquely mapped to the draft genome sequence and are referenced to positions in EMBL/GenBank files. Data utility is enhanced by provision of genotyping assays and functional predictions. Recent data structure extensions allow the capture of haplotype and genotype information, and a new initiative (along with BiSC and HUGO-MDI) aims to create a central repository for the broad collection of clinical mutations and associated disease phenotypes of interest.