Methods for rapid cloning and detection for sequencing of cloned inverse PCR-generated DNA fragments adjacent to known sequences in bacterial chromosomes.

Since the invention of PCR, many adaptation techniques have been developed for sequencing DNA fragments flanking known sequences. Of them, inverse PCR is a matter of interest because of the simplicity of its principle. However, the protocols for inverse PCR introduced so far consist of some time-consuming procedures, and with them, we cannot "walk" chromosomes too far since the number of suitable restriction enzymes is limited. Our experiments led to confirming simpler technical approaches applicable to the case of bacterial chromosomes, that is, designing two end-specific "contextual" sequences with which we can quickly detect the desired clones of targeted DNA fragments by simply analyzing PCR products, employing "the minimum value of the desired fragments" as a "discriminating minimum" value to decrease contaminant DNA fragments, and creating a new tandem of two cleaved end fragments of a known sequence ("reordering") for PCR amplification in combination with cloning of the inverse PCR-generated DNA. With the improvements, we could both simplify the procedures and broaden the capacity of the inverse PCR in "walking" chromosomes.     

Phylogeographic inferences from chloroplast DNA: quantifying the effects of mutations in repetitive and non-repetitive sequences

Phylogeographic inference can be a powerful tool in reconstructing species’ evolutionary histories; however, although inferred phylogeographic patterns should depend in part on the underlying types and rates of mutations, the effects of different types of mutations have seldom been quantified. In this study we identified two chloroplast minisatellites in the common reed Phragmites australis, and showed that these are more variable than chloroplast microsatellites. We then recreated parsimony networks of the global phylogeography of P. australis based on data that either included or excluded repetitive sequences (minisatellites and microsatellites), thereby illustrating the influence that these repetitive sequences can have on large‐scale phylogeographic inference. The resulting networks differed in the numbers of mutational steps, degrees of uncertainty, and total numbers of haplotypes. In addition, the suggested ancestor‐descendant relationships among lineages changed substantially depending on whether repetitive sequences were included. We therefore caution against the inclusion of repetitive sequences in large‐scale networks because of their high potential for homoplasy. Nevertheless, we advocate the inclusion of repetitive sequences in other analyses: specifically, we show that the ratio of mutations in repetitive vs. non‐repetitive regions can provide insight into the relative ages of lineages.     

Preparation of genome-wide DNA fragment libraries using bisulfite in polyacrylamide gel electrophoresis slices with formamide denaturation and quality control for massively parallel sequencing by oligonucleotide ligation and detection

Bisulfite sequencing is widely used for analysis of DNA methylation status (i.e., 5-methylcytosine [5mC] vs. cytosine [C]) in CpG-rich or other loci in genomic DNA (gDNA). Such methods typically involve reaction of gDNA with bisulfite followed by polymerase chain reaction (PCR) amplification of specific regions of interest that, overall, converts C→T (thymine) and 5mC→C and then capillary sequencing to measure C versus T composition at CpG sites. Massively parallel sequencing by oligonucleotide ligation and detection (SOLiD) has recently enabled relatively low-cost whole genome sequencing, and it would be highly desirable to apply such massively parallel sequencing to bisulfite-converted whole genomes to determine DNA methylation status of an entire genome, which has heretofore not been reported. As an initial step toward achieving this goal, we have extended our ongoing interest in improving bisulfite conversion sample preparation to include a human genome-wide fragment library for SOliD. The current article features novel use of formamide denaturant during bisulfite conversion of a suitably constructed library directly in a band slice from polyacryamide gel electrophoresis (PAGE). To validate this new protocol for 5mC-protected fragment library conversion, which we refer to as Bis-PAGE, capillary-based size analysis and Sanger sequencing were carried out for individual amplicons derived from single-molecule PCR (smPCR) of randomly selected library fragments. smPCR/Capillary Sanger sequencing of approximately 200 amplicons unambiguously demonstrated greater than 99% C→T conversion. All of these approximately 200 Sanger sequences were analyzed with a previously published web-accessible bioinformatics tool (methBLAST) for mapping to human chromosomes, the results of which indicated random distribution of analyzed fragments across all chromosomes. Although these particular Bis-PAGE conversion and quality control methods were exemplified in the context of a fragment library for SOLiD, the concepts can be generalized to include other genome-wide library constructions intended for DNA methylation analysis by alternative high-throughput or massively parallelized methods that are currently available.     

Molecular and cytogenetic characterization of repetitive DNA sequences from Lolium and Festuca: applications in the analysis of Festulolium hybrids

Summary A set of species-specific repetitive DNA sequences was isolated from Lolium multiflorum and Festuca arundinacea. The degree of their species specificity as well as possible homologies among them were determined by dot-blot hybridization analysis. In order to understand the genomic organization of representative Lolium and Festuca-specific repetitive DNA sequences, we performed Southern blot hybridization and in situ hybridization to metaphase chromosomes.Southern blot hybridization analysis of eight different repetitive DNA sequences of L. multiflorum and one of F. arundinacea indicated either tandem and clustered arrangements of partially dispersed localization in their respective genomes. Some of these sequences, e.g. LMB3, showed a similar genomic organization in F. arundinacea and F. pratensis, but a slightly different organization and degree of redundancy in L. multiflorum. Clones sequences varied in size between 100 bp and 1.2 kb. Estimated copy number in the corresponding haploid genomes varied between 300 and 2×10⁴. Sequence analysis of the highly species-specific sequences from plasmids pLMH2 and pLMB4 (L. multiflorum specific) and from pFAH1 (F. arundinacea specific) revealed some internal repeats without higher order. No homologies between the sequences or to other repetitive sequences were observed. In situ hybridization with these latter sequences to metaphase chromosomes from L. multiflorum, F. arundinacea and from symmetric sexual Festulolium hybrid revealed their relatively even distribution in the corresponding genomes. The in situ hybridization thus also allowed a clearcut simple identification of parental chromosomes in the Festulolium hybrid.The potential use of these species-specific clones as hybridization probes in quantitative dot-blot analysis of the genomic make-up of Festulolium (sexual and somatic) hybrids is also demonstrated.Abbreviations bp Base pair (s) - CMA chromomycin A₃ - DAPI 4,6-diamidino-2-phenylindole - IPTG isopropyl -D-thio-galactopyranoside - kb kilobase pair(s) - NBT nitroblue tetrazolium chloride - X-gal 5-bromo-4-chloro-3-inonyl -D-galactopyranoside