Cloning and physical localization of male-biased repetitive DNA sequences in Spinacia oleracea (Amaranthaceae)

Spinach (Spinacia oleracea Linnaeus, 1753) is an ideal material for studying molecular mechanisms of early-stage sex chromosome evolution in dioecious plants. Degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR) technique facilitates the retrotransposon-relevant studies by enriching specific repetitive DNA sequences from a micro-dissected single chromosome. We conducted genomic subtractive hybridization to screen sex-biased DNA sequences by using the DOP-PCR amplification products of micro-dissected spinach Y chromosome. The screening yielded 55 male-biased DNA sequences with 30 576 bp in length, of which, 32 DNA sequences (12 049 bp) contained repeat DNA sequences, including LTR/Copia, LTR/Gypsy, simple repeats, and DNA/CMC-EnSpm. Among these repetitive DNA sequences, four DNA sequences that contained a fragment of Ty3-gypsy retrotransposons (SP73, SP75, SP76, and SP77) were selected as fluorescence probes to hybridization on male and female spinach karyotypes. Fluorescence in situ hybridization (FISH) signals of SP73 and SP75 were captured mostly on the centromeres and their surrounding area for each homolog. Hybridization signals primarily appeared near the putative centromeres for each homologous chromosome pair by using SP76 and SP77 probes for FISH, and sporadic signals existed on the long arms. Results can be served as a basis to study the function of repetitive DNA sequences in sex chromosome evolution in spinach.

Cloning and physical localization of male-biased repetitive DNA sequences in Spinacia oleracea (Amaranthaceae)

Spinach (Spinacia oleracea Linnaeus, 1753) is an ideal material for studying molecular mechanisms of early-stage sex chromosome evolution in dioecious plants. Degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR) technique facilitates the retrotransposon-relevant studies by enriching specific repetitive DNA sequences from a micro-dissected single chromosome. We conducted genomic subtractive hybridization to screen sex-biased DNA sequences by using the DOP-PCR amplification products of micro-dissected spinach Y chromosome. The screening yielded 55 male-biased DNA sequences with 30 576 bp in length, of which, 32 DNA sequences (12 049 bp) contained repeat DNA sequences, including LTR/Copia, LTR/Gypsy, simple repeats, and DNA/CMC-EnSpm. Among these repetitive DNA sequences, four DNA sequences that contained a fragment of Ty3-gypsy retrotransposons (SP73, SP75, SP76, and SP77) were selected as fluorescence probes to hybridization on male and female spinach karyotypes. Fluorescence in situ hybridization (FISH) signals of SP73 and SP75 were captured mostly on the centromeres and their surrounding area for each homolog. Hybridization signals primarily appeared near the putative centromeres for each homologous chromosome pair by using SP76 and SP77 probes for FISH, and sporadic signals existed on the long arms. Results can be served as a basis to study the function of repetitive DNA sequences in sex chromosome evolution in spinach.

Use of degenerate oligonucleotide primed polymerase chain reaction for detection of chicken anaemia virus contamination in avian viral vaccines

For quality control of biologicals of veterinary use, the absence of extraneous agents needs to be certified. One of the requirements for quality control of avian viral vaccines is to demonstrate freedom from extraneous and adventitious pathogenic agents, like chicken anaemia virus (CAV). In this study, a degenerate oligonucleotide primed PCR (DOP-PCR) for the detection of CAV was developed. Degenerate oligonucleotide primers were selected based on sequences corresponding to conserved regions of VP1 gene. After spiking of CAV genomic DNA to an infectious laryngotracheitis virus (ILTV) vaccine, detection limit for the test was 3.056×10-9 ng/µl. To evaluate the performance of the test, 11 avian viral vaccines including infectious bronchitis virus (IBV), newcastle disease virus (NDV), infectious bursal disease virus (IBDV) and ILTV vaccines from 5 manufacturers were screened for CAV and no contamination was detected. The test described here may provide a rapid, sensitive and specific method for contamination detection of avian viral vaccines with CAV, and may be applied for quality control of live and killed commercial vaccines.

Argo_CUDA: Exhaustive GPU based approach for motif discovery in large DNA datasets

The development of chromatin immunoprecipitation sequencing (ChIP-seq) technology has revolutionized the genetic analysis of the basic mechanisms underlying transcription regulation and led to accumulation of information about a huge amount of DNA sequences. There are a lot of web services which are currently available for de novo motif discovery in datasets containing information about DNA/protein binding. An enormous motif diversity makes their finding challenging. In order to avoid the difficulties, researchers use different stochastic approaches. Unfortunately, the efficiency of the motif discovery programs dramatically declines with the query set size increase. This leads to the fact that only a fraction of top “peak” ChIP-Seq segments can be analyzed or the area of analysis should be narrowed. Thus, the motif discovery in massive datasets remains a challenging issue. Argo_Compute Unified Device Architecture (CUDA) web service is designed to process the massive DNA data. It is a program for the detection of degenerate oligonucleotide motifs of fixed length written in 15-letter IUPAC code. Argo_CUDA is a full-exhaustive approach based on the high-performance GPU technologies. Compared with the existing motif discovery web services, Argo_CUDA shows good prediction quality on simulated sets. The analysis of ChIP-Seq sequences revealed the motifs which correspond to known transcription factor binding sites.

Improved DOP-PCR (iDOP-PCR): a robust and simple WGA method for efficient amplification of low copy number genomic DNA

Whole-genome amplification (WGA) techniques are used for non-specific amplification of low-copy number DNA, and especially for single-cell genome and transcriptome amplification. There are a number of WGA methods that have been developed over the years. One example is degenerate oligonucleotide-primed PCR (DOP-PCR), which is a very simple, fast and inexpensive WGA technique. Although DOP-PCR has been regarded as one of the pioneering methods for WGA, it only provides low genome coverage and a high allele dropout rate when compared to more modern techniques. Here we describe an improved DOP-PCR (iDOP-PCR). We have modified the classic DOP-PCR by using a new thermostable DNA polymerase (SD polymerase) with a strong strand-displacement activity and by adjustments in primers design. We compared iDOP-PCR, classic DOP-PCR and the well-established PicoPlex technique for whole genome amplification of both high- and low-copy number human genomic DNA. The amplified DNA libraries were evaluated by analysis of short tandem repeat genotypes and NGS data. In summary, iDOP-PCR provided a better quality of the amplified DNA libraries compared to the other WGA methods tested, especially when low amounts of genomic DNA were used as an input material.

DOP–PCR based painting of rye chromosomes in a wheat background

To determine the appropriateness of chromosome painting for identifying genomic elements in rye, we microdissected the 1R and 1RS chromosomes from rye (Secale cereale L. var. King II) and wheat–rye addition line 1RS, respectively. Degenerate oligonucleotide primed – polymerase chain reaction (DOP–PCR) amplification of 1R and 1RS products from dissected chromosomes were used as probes to hybridize to metaphase chromosomes of rye, wheat–rye addition lines 1R and 1RS, translocation line 1RS.1BL, and allohexaploid triticale. The results showed that (i) the hybridization signal distribution patterns on rye chromosomes using 1R-derived DOP–PCR products as the probe were similar to those using 1RS-derived DOP–PCR products as the probe; (ii) 1R and (or) 1RS could not be distinguished from other rye chromosomes solely by the hybridization patterns using 1R- and (or) 1RS-derived DOP–PCR products as the probe; (iii) rye chromosomes and (or) rye chromosome fragments could be clearly identified in wheat–rye hybrids using either 1R- or 1RS-derived DOP–PCR products as the probe and could be more accurate in the nontelomeric region than using genomic in situ hybridization (GISH). Our results suggested that 1R- and (or) 1RS-derived DOP–PCR products contain many repetitive DNA sequences, are similar on different rye chromosomes, are R-genome specific, and can be used to identify rye chromosomes and chromosome fragments in wheat–rye hybrids. Our research widens the application range of chromosome painting in plants.

Sex chromosome composition revealed in Characidium fishes (Characiformes: Crenuchidae) by molecular cytogenetic methods

The W chromosome of the fishes Characidium cf. fasciatum, Characidium sp. and Characidium cf. gomesi is heterochromatic, as is usually seen in most Characidium species. Samples of W-chromatin were collected by mechanical microdissection and amplified by DOP-PCR (degenerate oligonucleotide-primed polymerase chain reaction), to be used as painting probes (DCg and CgW) and for sequence analysis. FISH (fluorescence in situ hybridization) with DCg probe painted the whole W chromosome, the pericentromeric region of Z chromosomes and the terminal region of B chromosomes. DOP-PCR-generated fragments were cloned, sequenced and tested by in situ hybridization, but only CgW4 produced positive hybridization signals. Clone sequence analysis recovered seven distinct sequences, of which six did not reveal any similarity to other known sequences in the GenBank or GIRI databases. Only CgW9 clone sequence was recognized as probably derived from a Helitron-transposon similar to that found in the genome of the zebrafish Danio rerio. Our results show that the composition of Characidium’s W chromosome does seem rich in repetitive sequences as well as other W chromosomes found in several species with a ZW sex-determining mechanism.