High throughput sequencing of microRNAs in chicken somites

High throughput Solexa sequencing technology was applied to identify microRNAs in somites of developing chicken embryos. We obtained 651 273 reads, from which 340 415 were mapped to the chicken genome representing 1701 distinct sequences. Eighty-five of these were known microRNAs and 42 novel miRNA candidates were identified. Accumulation of 18 of 42 sequences was confirmed by Northern blot analysis. Ten of the 18 sequences are new variants of known miRNAs and eight short RNAs are novel miRNAs. Six of these eight have not been reported by other deep sequencing projects. One of the six new miRNAs is highly enriched in somite tissue suggesting that deep sequencing of other specific tissues has the potential to identify novel tissue specific miRNAs.     

Small deletion variants have stable breakpoints commonly associated with alu elements

Copy number variants (CNVs) contribute significantly to human genomic variation, with over 5000 loci reported, covering more than 18% of the euchromatic human genome. Little is known, however, about the origin and stability of variants of different size and complexity. We investigated the breakpoints of 20 small, common deletions, representing a subset of those originally identified by array CGH, using Agilent microarrays, in 50 healthy French Caucasian subjects. By sequencing PCR products amplified using primers designed to span the deleted regions, we determined the exact size and genomic position of the deletions in all affected samples. For each deletion studied, all individuals carrying the deletion share identical upstream and downstream breakpoints at the sequence level, suggesting that the deletion event occurred just once and later became common in the population. This is supported by linkage disequilibrium (LD) analysis, which has revealed that most of the deletions studied are in moderate to strong LD with surrounding SNPs, and have conserved long-range haplotypes. Analysis of the sequences flanking the deletion breakpoints revealed an enrichment of microhomology at the breakpoint junctions. More significantly, we found an enrichment of Alu repeat elements, the overwhelming majority of which intersected deletion breakpoints at their poly-A tails. We found no enrichment of LINE elements or segmental duplications, in contrast to other reports. Sequence analysis revealed enrichment of a conserved motif in the sequences surrounding the deletion breakpoints, although whether this motif has any mechanistic role in the formation of some deletions has yet to be determined. Considered together with existing information on more complex inherited variant regions, and reports of de novo variants associated with autism, these data support the presence of different subgroups of CNV in the genome which may have originated through different mechanisms.     

Rearrangements of the red-cell membrane glycophorin C (sialoglycoprotein beta) gene. A further study of alterations in the glycophorin C gene.

We have cloned portions of the glycophorin C (sialoglycoprotein beta) gene from individuals with red cells of normal, Gerbich and Yus phenotypes. The clones contain up to three exons of the glycophorin C gene (designated exons 2, 3 and 4). Analysis by restriction mapping and DNA sequencing confirmed that the deletions causing the Gerbich and Yus phenotypes are located entirely within the glycophorin C gene. Sequencing of the normal gene showed that not only do exon 2 and exon 3 have related DNA sequences, but also that both the 5' and 3' flanking intronic DNA sequences are almost identical. The two variant genes each lack a different exon: the Yus type gene lacks exon 2, whereas the Gerbich-type gene lacks exon 3. We suggest that the observed deletions are due to recombination between the regions of homologous intronic repeats. We also provide evidence that an unequal cross-over mechanism may be responsible for a number of observed glycophorin C gene rearrangements, including an insertion mutation in Lewis II (Lsa)-type red cells that has not previously been reported.     

Characterization of the bovine BCL2L1 gene and related pseudogenes

We have amplified and characterized partial regions of exons 2 and 3 of the bovine BCL2L1 gene, one of the anti-apoptotic members of the B-cell lymphoma 2 gene family. Cloning and sequencing of the amplified products revealed the existence of several BCL2L1-related sequences, including the bovine BCL2L1 gene and various processed pseudogenes. The bovine BCL2L1 gene revealed two polymorphic nucleotide sequences that resulted in two protein variants, with amino acid replacements at positions 60 and 69. In addition, we report three bovine BCL2L1-related sequences (BCL2L1psi) that probably correspond to intronless processed pseudogenes. These BCL2L1psi pseudogene sequences have accumulated multiple substitutions, deletions and insertions that translated into stop codons or changed the open reading frame of the functional gene. We provide evidence suggesting that the retro-transposition event that originated these processed pseudogenes took place before the divergence of the Cervidae and Bovidae families.     

The DNA sequence of the H-2kb gene: evidence for gene conversion as a mechanism for the generation of polymorphism in histocompatibilty antigens

We have determined the DNA sequence of the H-2Kb gene of the C57B1/10 mouse. Comparison of this sequence with that of the allelic H-2Kd shows surprisingly that the exons have accumulated more mutations than their introns. Moreover, many of these changes in the exons are clustered in short regions or hot spots. Additional comparison of these sequences with the H-2Ld and H-2Db sequences shows that, in several cases, the altered sequence generated at the hot spot is identical to the corresponding region of a non-allelic H-2 gene. The clustered changes are responsible for 60% of the amino acid differences between the H-2Kb and H-2Kd genes and suggest that micro-gene conversion events occurring within the exons and involving only tens of nucleotides are an important mechanism for the generation of polymorphic differences between natural H-2 alleles.     

Hybrid survival motor neuron genes in patients with autosomal recessive spinal muscular atrophy: new insights into molecular mechanisms responsible for the disease.

Spinal muscular atrophy (SMA) is a frequent autosomal recessive neurodegenerative disorder leading to weakness and atrophy of voluntary muscles. The survival motor-neuron gene (SMN), a strong candidate for SMA, is present in two highly homologous copies (telSMN and cenSMN) within the SMA region. Only five nucleotide differences within the region between intron 6 and exon 8 distinguish these homologues. Independent of the severity of the disease, 90%-98% of all SMA patients carry homozygous deletions in telSMN, affecting either exon 7 or both exons 7 and 8. We present the molecular analysis of 42 SMA patients who carry homozygous deletions of telSMN exon 7 but not of exon 8. The question arises whether in these cases the telSMN is truncated upstream of exon 8 or whether hybrid SMN genes exist that are composed of centromeric and telomeric sequences. By a simple PCR-based assay we demonstrate that in each case the remaining telSMN exon 8 is part of a hybrid SMN gene. Sequencing of cloned hybrid SMN genes from seven patients, as well as direct sequencing and single-strand conformation analysis of all patients, revealed the same composition in all but two patients: the base-pair differences in introns 6 and 7 and exon 7 are of centromeric origin whereas exon 8 is of telomeric origin. Nonetheless, haplotype analysis with polymorphic multicopy markers, Ag1-CA and C212, localized at the 5' end of the SMN genes suggests different mechanisms of occurrence, unequal rearrangements, and gene conversion involving both copies of the SMN genes. In approximately half of all patients, we identified a consensus haplotype, suggesting a common origin. Interestingly, we identified a putative recombination hot spot represented by recombination-stimulating elements (TGGGG and TGAGGT) in exon 8 that is homologous to the human deletion-hot spot consensus sequence in the immunoglobulin switch region, the alpha-globin cluster, and the polymerase alpha arrest sites. This may explain why independent hybrid SMN genes show identical sequences.     

Detection of internal exon deletion with exon Del

Background

Exome sequencing allows researchers to study the human genome in unprecedented detail. Among the many types of variants detectable through exome sequencing, one of the most over looked types of mutation is internal deletion of exons. Internal exon deletions are the absence of consecutive exons in a gene. Such deletions have potentially significant biological meaning, and they are often too short to be considered copy number variation. Therefore, to the need for efficient detection of such deletions using exome sequencing data exists.

Results

We present ExonDel, a tool specially designed to detect homozygous exon deletions efficiently. We tested ExonDel on exome sequencing data generated from 16 breast cancer cell lines and identified both novel and known IEDs. Subsequently, we verified our findings using RNAseq and PCR technologies. Further comparisons with multiple sequencing-based CNV tools showed that ExonDel is capable of detecting unique IEDs not found by other CNV tools.

Conclusions

ExonDel is an efficient way to screen for novel and known IEDs using exome sequencing data. ExonDel and its source code can be downloaded freely at https://github.com/slzhao/ExonDel.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2105-15-332) contains supplementary material, which is available to authorized users.     

On the formation of spontaneous deletions: the importance of short sequence homologies in the generation of large deletions

Using lacl-Z fusion strains of Escherichia coli we have devised systems that detect deletions of varying lengths. We examined deletions 700-1000 base pairs long, and genetically characterized over 250 spontaneous deletions. Of these, we analyzed 24 by direct DNA sequencing and 18 by inspection of restriction fragment patterns. Deletions of this size occur almost exclusively at short repeated sequences in both (recA+ and recA- strain backgrounds, but are detected 25-fold more frequently in a recA+ background. The frequency of deletion formation correlates with the extent of homology between the short repeated sequences, although other factors may be involved. The largest hotspot, which accounts for 60% of the deletions detected, involves the largest homology in the system (14 of 17 base pairs). Altering a single base pair within this homology reduces deletion incidence by an order of magnitude. We discuss possible mechanisms of deletion formation and consider its relationship to the excision of transposable elements.     

Multiplex ligation-dependent probe amplification (MLPA) detects large deletions in the MECP2 gene of Swedish Rett syndrome patients

Mutations in the methyl-CpG-binding protein-2 (MECP2) gene on Xq28 have been found to be a cause of Rett syndrome (RS). In a previous mutation screening, we found MECP2 mutations in 81% of Swedish classical Rett women. In this study, we have analyzed 22 patients for MECP2 deletions using multiplex-ligation-dependent probe amplification (MLPA). Clinically, 11 of the patients who were classical Rett women, 3 were forme fruste, 1 was congenital RS, and 7 were Rett variants. As inclusion criteria, we used DNA from patients in whom previous sequencing results showed no mutations in coding portions of the MECP2 gene. MLPA is a method based on multiplex PCR. In one PCR, as many as 40 probes are amplified with the same primers. The specificity of the amplification products is determined by the site-specific hybridization of each probe construct, prior to amplification. Each PCR product has a unique length, which makes it possible to identify it by size separation. In 3 of 11 (27%) classical Rett women, we detected large deletions in MECP2 using MLPA. All these patients had deletions covering two exons; in 2 cases the deletion involved exons 3 and 4 and, in one case, exons 1 and 2 were missing. In the forme fruste, congenital and Rett-variant patients, we found no large deletions. We have found that MLPA is useful when it comes to finding large deletions compromising whole exons in MECP2. Used as a complementary method to DNA sequencing, it revealed new MECP2 mutations in classical RS patients.     

High-Throughput,Amplicon-Based Sequencing of the CREBBP Gene as a Tool to Develop a Universal Platform-Independent Assay

High-throughput sequencing technologies are widely used to analyse genomic variants or rare mutational events in different fields of genomic research, with a fast development of new or adapted platforms and technologies, enabling amplicon-based analysis of single target genes or even whole genome sequencing within a short period of time. Each sequencing platform is characterized by well-defined types of errors, resulting from different steps in the sequencing workflow. Here we describe a universal method to prepare amplicon libraries that can be used for sequencing on different high-throughput sequencing platforms. We have sequenced distinct exons of the CREB binding protein (CREBBP) gene and analysed the output resulting from three major deep-sequencing platforms. platform-specific errors were adjusted according to the result of sequence analysis from the remaining platforms. Additionally, bioinformatic methods are described to determine platform dependent errors. Summarizing the results we present a platform-independent cost-efficient and timesaving method that can be used as an alternative to commercially available sample-preparation kits.