Discovery of transgene insertion sites by high throughput sequencing of mate pair libraries

Background

Transgenesis by random integration of a transgene into the genome of a zygote has become a reliable and powerful method for the creation of new mouse strains that express exogenous genes, including human disease genes, tissue specific reporter genes or genes that allow for tissue specific recombination. Nearly 6,500 transgenic alleles have been created by random integration in embryos over the last 30 years, but for the vast majority of these strains, the transgene insertion sites remain uncharacterized.

Results

To obtain a complete understanding of how insertion sites might contribute to phenotypic outcomes, to more cost effectively manage transgenic strains, and to fully understand mechanisms of instability in transgene expression, we’ve developed methodology and a scoring scheme for transgene insertion site discovery using high throughput sequencing data.

Conclusions

Similar to other molecular approaches to transgene insertion site discovery, high-throughput sequencing of standard paired-end libraries is hindered by low signal to noise ratios. This problem is exacerbated when the transgene consists of sequences that are also present in the host genome. We’ve found that high throughput sequencing data from mate-pair libraries are more informative when compared to data from standard paired end libraries. We also show examples of the genomic regions that harbor transgenes, which have in common a preponderance of repetitive sequences.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-367) contains supplementary material, which is available to authorized users.     

Comprehensive sequence analysis of 24,783 barley full-length cDNAs derived from 12 clone libraries

Full-length cDNA (FLcDNA) libraries consisting of 172,000 clones were constructed from a two-row malting barley cultivar (Hordeum vulgare 'Haruna Nijo') under normal and stressed conditions. After sequencing the clones from both ends and clustering the sequences, a total of 24,783 complete sequences were produced. By removing duplicates between these and publicly available sequences, 22,651 representative sequences were obtained: 17,773 were novel barley FLcDNAs, and 1,699 were barley specific. Highly conserved genes were found in the barley FLcDNA sequences for 721 of 881 rice (Oryza sativa) trait genes with 50% or greater identity. These FLcDNA resources from our Haruna Nijo cDNA libraries and the full-length sequences of representative clones will improve our understanding of the biological functions of genes in barley, which is the cereal crop with the fourth highest production in the world, and will provide a powerful tool for annotating the barley genome sequences that will become available in the near future.     

Characterization of the splice sites in GT-AG and GC-AG introns in higher eukaryotes using full-length cDNAs

For the purpose of analyzing the relation between the splice sites and the order of introns, we conducted the following analysis for the GT-AG and GC-AG splice site groups. First, the pre-mRNAs of H. sapiens, M. musculus, D. melanogaster, A. thaliana and O. sativa were sampled by mapping the full-length cDNA to the genomes. Next, the consensus sequences at different regions of pre-mRNAs were analyzed in the five species. We also investigated the mononucleotide and dinucleotide frequencies in the extensive regions around the 5' splice sites (5'ss) and 3' splice sites (3'ss). As a result, differential frequencies of nucleotides at the first 5'ss in both the GT-AG and GC-AG splice site groups were observed in A. thaliana and O. sativa pre-mRNAs. The trend, which indicates that GC 5'ss possess strong consensus sequences, was observed not only in mammalian pre-mRNAs but also in the pre-mRNAs of D. melanogaster, A. thaliana and O. sativa. Furthermore, we examined the consensus sequences of the constitutive and alternative splice sites. It was suggested that in the case of the alternative GC-AG introns, the tendency to have a weak consensus sequence at 5'ss is different between H. sapiens and M. musculus pre-mRNAs.     

Construction and characterization of band-specific DNA libraries

Summary A universally primed polymerase chain reaction was developed to amplify DNA dissected from GTG-banded human chromosomes. The amplification products are cloned into plasmid vectors, which allow the rapid characterization of recombinant clones. Starting from 20–40 chromosome fragments, several thousand independent clones detecting single-copy sequences can be obtained. Although these libraries comprise only a few percent of the dissected DNA, they provide narrowly spaced anchor clones for the molecular characterization of chromosome bands and the identification of gene sequences. Here we describe the construction and characterization of DNA libraries for the Langer-Giedion syndrome chromosome region (LGCR, 8q23–24.1), Wilms tumor chromosome region 1 (WT1, 11p13), Prader-Willi syndrome/Angelman syndrome chromosome region (PWCR/ANCR, 15q11.2–12), meningioma chromosome region (MGCR, 22q12–13), and fragile X chromosome region (FRAXA, Xq27.3).     

PCR-based generation of shRNA libraries from cDNAs

Background  

The use of small interfering RNAs (siRNAs) to silence target gene expression has greatly facilitated mammalian genetic analysis by generating loss-of-function mutants. In recent years, high-throughput, genome-wide screening of siRNA libraries has emerged as a viable approach. Two different methods have been used to generate short hairpin RNA (shRNA) libraries; one is to use chemically synthesized oligonucleotides, and the other is to convert complementary DNAs (cDNAs) into shRNA cassettes enzymatically. The high cost of chemical synthesis and the low efficiency of the enzymatic approach have hampered the widespread use of screening with shRNA libraries.