USE OF REPEATED DNA SEQUENCES AS CYTOLOGICAL MARKERS

The majority of DNA that is found in most of the flowering plants appears to be non-coding DNA. Much of this excess DNA consists of nucleotide sequences which exist as multiple copies throughout the genome and are designated as repetitive sequences. Those sequences which are found in moderately high to high numbers of copies are observed to be of the greatest value as cytological markers. Moderately high copies may exist as sequences which are dispersed throughout the chromosomes of some species and not dispersed in other more distantly related species. By taking advantage of this characteristic and the technique of in situ hybridization with biotinylated probes, breakpoints of chromosomal translocations may be observed between species such as wheat and rye. Many of the high copy number repetitive sequences are organized in a tandem fashion in specific loci in the chromosome. Chromosomal identification may be accomplished by using the in situ hybridization technique. Upon in situ hybridization with a repetitive sequence isolated from Aegilops squarrosa, the patterns of the sites of hybridization allowed the D-genome chromosomes to be identified. The sequence was also observed only on the D-genome chromosomes of several polyploid species indicating its usefulness as a genome specific marker. Using this genome specificity, assessment of the orientation of the D-genome chromosomal segments of hexaploid wheat carrying the sequence during interphase and prophase of mitotic root tip cells was possible. Repetitive DNA sequences, therefore, provide cytological markers necessary for studies of chromosomal identification, genome allocation, and genome orientation. The use of biotin-labeled DNA probes allows the technique of in situ hybridization to be performed much more rapidly and with a greater degree of safety and reliability.     

Detection of genome specific monomorphic loci in Bos taurus and Bubalus bubalis with oligodeoxyribonucleotide probe

A synthetic oligodeoxyribonucleotide probe (OAT36) comprising nine repeats of 5'GACA 3′ and several enzymes were used to analyse cow, (Bos taurus) and buffalo (Bubalus bubalis) genomes and a number of monomorphic loci were detected in both the species. Different animals from the same species showed an almost ‘similar’ monomorphic hybridization pattern but animals from two separate species showed a different ‘genome specific’ pattern. The overall hybridization with any enzyme and probe combination was found to be unique to one species. This forms the basis of genome specific hybridization which is substantiated by our zoo-blot hybridization studies. The evolutionary aspect of these loci in the context of sequence polymorphisms is discussed.     

Mitochondrial DNA variation in pearl millet and related species

Summary Mitochondrial DNA (mtDNA) restriction endonuclease fragment patterns and patterns of mtDNA hybridized by mitochondrial gene probes were used to study phylogenetic relationships of seven Pennisetum species, including five P. americanum (pearl millet) ecotypes and a reference species from the distantly related genus, Panicum. The restriction patterns of the pearl millet ecotypes were uniform with the exception of the ecotype collected in Ethiopia. The probe hybridization method revealed more variability, with both the Rhodesian and Ethiopian ecotypes differing from the others and from each other. Considerable restriction pattern polymorphism was noted among different species of Pennisetum, and Panicum. Significant relationships were noted of Pennisetum polystachyon to P. pedicellatum and of P. purpureum to P. squamulatum using the restriction pattern method. In addition to those relationships, the hybridization method showed relationships of pearl millet to P. purpureum and to P. squamulatum. The relationships noted between species by the hybridization method agreed more closely to the cytological data than those indicated by the restriction pattern method. Therefore, the hybridization method appeared to be the preferred method for studying species relationships. The mitochondrial genome size of pearl millet was calculated to be 407 kb and the mitochondrial genome sizes of other Pennisetum species ranged from 341 to 486 kb.Florida Agricultural Experiment Station Journal Series No. 8485.     

A repeated sequence probe for the C genome in Avena (Oats)

Summary The genus Avena consists of at least 23 species composed of three ploidy levels. Cytogenetic analysis has characterised four distinct karyotypes. These are the A, B, C and D genomes. We have isolated a repeated sequence clone that can be used for the detection of the C genome in Avena by filter hybridization techniques. This clone, termed RS-1, is a genomic DNA clone containing at least one highly repeated sequence that is abundant in Avena species containing the C genome. This sequence or a related sequence is also present, but at much reduced levels, in species that do not contain the C genome. Because of its abundance and the characteristic Southern blot pattern, we have termed this clone a C genome specific clone. We have also done similar analysis of the Avena genus using a rDNA clone from wheat. The results of these experiments demonstrate that clearly definable C genome-specific markers can be identified with both probes. These molecular probes can be useful in studying the genomic relationships of Avena and can provide some clues as to the origin of the cultivated Avena species. These results can, therefore, provide breeders with directions for the efficient transfer of desirable traits of wild Avena species into commencal varieties.     

一种能表现水稻基因组DNA分化特征的重复DNA顺序

用ＤＮＡ 复性动力学方法克隆到一个水稻中度重复顺序。Ｓｏｕｔｈｅｒｎ 杂交、限制性内切酶分析及序列分析资料表明,该重复顺序在水稻基因组中具有串联重复和散布状态两种存在方式。以该ＤＮＡ 片段作探针,用Ｓｏｕｔｈｅｒｎ 杂交方法分析了多种野生稻种和栽培稻品种的基因组分化特征。某些限制性内切酶消化过的水稻ＤＮＡ,其图谱呈现出多达４０ 条以上的杂交带,包括强杂交带和弱杂交带两种类型。重复实验结果证明,强杂交带表现为ＢＢＣＣ染色体组型特异而弱带则在栽培稻各品种间显示出丰富的多态性,表明该重复顺序片段在水稻理论研究和育种实践中可能具有重要意义     

A Repetitive DNA Sequence Showing the Characteristic of Genomic DNA Differentiation in Oryza

A moderately repetitive DNA sequence from rice had been cloned by the method of DNA renaturation kinetics. Restriction site analysis, Southern hybridization and DNA sequence analysis indicated that the sequence was mainly in tandem repeat in rice genome. A lot of wild and cultivated rice species were analyzed by Southern blot. With some restriction endonucleases digestion the hybridization pattern of rice DNA showed more than 40 bands with different intensity mainly consisting of the strong and weak hybridization bands. It was found that the strong hybridization bands were specific to the BBCC genome and the weak bands showed abundent polymorphism in cultivated rice species. These results suggested that the repetitive DNA sequence might be useful for rice breeding.     

Finding stories in noise: Mitochondrial portraits from RAD data

Mitochondrial DNA (mtDNA) has formed the backbone of phylogeographic research for many years; however, recent trends focus on genome‐wide analyses. One method proposed for calibrating inferences from noisy next‐generation data, such as RAD sequencing, is to compare these results with analyses of mitochondrial sequences. Most researchers using this approach appear to be unaware that many single nucleotide polymorphisms (SNPs) identified from genome‐wide sequence data are themselves mitochondrial, or assume that these are too few to bias analyses. Here, we demonstrate two methods for mining mitochondrial markers using RAD sequence data from three South African species of yellowfish, Labeobarbus. First, we use a rigorous SNP discovery pipeline using the program stacks , to identify variant sites in mtDNA, which we then combine into haplotypes. Second, we directly map sequence reads against a mitochondrial genome reference. This method allowed us to reconstruct up to 98% of the Labeobarbus mitogenome. We validated these mitogenome reconstructions through blast database searches and by comparison with cytochrome b gene sequences obtained through Sanger sequencing. Finally, we investigate the organismal consequences of these data including ancient genetic exchange and a recent translocation among populations of L. natalensis, as well as interspecific hybridization between L. aeneus and L. kimberleyensis.     

A moderately repeated DNA sequence of wheat and rye genomes

A 371 base pair segment (bordered by Hind III and Eco RI cutting sites) of wheat embryo nuclear DNA has been cloned and sequenced. It is AT-rich (68%), shares some sequence features with autonomously replicating sequence (ARS) elements, and occurs in approximately 7600 copies per haploid genome. When used as probe for blot hybridization to Hind III-digested wheat DNA, it gives an irregular series of hybridization bands. Essentially the same hybridization pattern was observed for rye DNA. It is concluded that this segment is distributed irregularly but, apparently, according to the same rule in both wheat and rye genomes.     

Evolution of a telomere associated satellite DNA sequence in the genome ofDrosophila tristis and related species

A highly repetitive satellite DNA sequence from the genome ofDrosophila tristis with a length of 181 bp has been cloned in the pUC plasmid. The sequence hybridizes to the telomeres of all chromosomes but the Y ofD. tristis and produces a ladderlike hybridization pattern with filterbound genomic DNA ofD. tristis digested with Eco RI or Pst I with the hybridization bands at fragment lengths in multiples of 181 bp. A similar pattern is found when the genomic DNA comes fromD. ambigua or, though less clear, fromD. microlabis. Additional bands appear in the zones of high fragment lengths, too. InD. obscura andD. kitumensis, however, the 181 bp sequence is found in fragments with a length of a few kb only. The 181 bp sequence is tandemly arranged in the genome ofD. tristis and has a copy number of about 82,000 per haploid genome (i.e. 10 per cent of the total DNA). A sequence comparison among four independently cloned copies of the family fromD. tristis and another homologous sequence fromD. obscura, found by chance, shows a one to six per cent variation in basepair composition. However, low divergence (only one per cent) between two copies ofD. tristis and between the one ofD. obscura and one ofD. tristis was observed, and high divergence (six per cent) between these two pairs. This is discussed and explained as the evolutionary consequence of an existing homogenization process by unequal crossing over.     

Detection of a 17 kb unique sequence (T-DNA) in plant chromosomes by in situ hybridization

An approach is described for the detection of a unique sequence, the T-DNA region of the Agrobacterium rhizogenes root-inducing (Ri) plasmid, in plant chromosomes by in situ hybridization. This sequence was introduced into the Crepis capillaris genome (2n=6) by infecting Crepis stem segments with A. rhizogenes. Roots growing from the infection site contain T-DNA and synthesize mannopine, which can be used as a convenient biochemical marker for T-DNA transformation. Southern analysis of DNA isolated from one transformed Crepis root line verified the presence of a single copy of T-DNA (approximate size 17 kb) per diploid Crepis genome. To localize T-DNA, both DNA and RNA probes, labelled with either tritium or biotin, were hybridized to Crepis chromosomes prepared from transformed root tips by a novel spreading method. Biotinylated probes were visualized using reflection-contrast microscopy. In the hybridization experiments described, T-DNA was detected in one homologue of chromosome 3, where it could be assigned to a paracentromeric position in the neighbourhood of the nucleolar organizing region. These results demonstrate that it is possible to localize unique sequences in plant chromosomes by in situ hybridization.     

A combined molecular and cytogenetic approach to genome evolution in Drosophila using large-fragment DNA cloning

Methods of genome analysis, including the cloning and manipulation of large fragments of DNA, have opened new strategies for uniting molecular evolutionary genetics with chromosome evolution. We have begun the development of a physical map of the genome of Drosophila virilis based on large DNA fragments cloned in bacteriophage P1. A library of 10,080 P1 clones with average insert sizes of 65.8 kb, containing approximately 3.7 copies of the haploid genome of D. virilis, has been constructed and characterized. Approximately 75% of the clones have inserts exceeding 50 kb, and approximately 25% have inserts exceeding 80 kb. A sample of 186 randomly selected clones was mapped by in situ hybridization with the salivary gland chromosomes. A method for identifying D. virilis clones containing homologs of D. melanogaster genes has also been developed using hybridization with specific probes obtained from D. melanogaster by means of the polymerase chain reaction. This method proved successful for nine of ten genes and resulted in the recovery of 14 clones. The hybridization patterns of a sample of P1 clones containing repetitive DNA were also determined. A significant fraction of these clones hybridizes to multiple euchromatic sites but not to the chromocenter, which is a pattern of hybridization that is very rare among clones derived from D. melanogaster. The materials and methods described will make it possible to carry out a direct study of molecular evolution at the level of chromosome structure and organization as well as at the level of individual genes.     

Microarray Comparative Genomic Hybridisation Analysis Incorporating Genomic Organisation,and Application to Enterobacterial Plant Pathogens

Microarray comparative genomic hybridisation (aCGH) provides an estimate of the relative abundance of genomic DNA (gDNA) taken from comparator and reference organisms by hybridisation to a microarray containing probes that represent sequences from the reference organism. The experimental method is used in a number of biological applications, including the detection of human chromosomal aberrations, and in comparative genomic analysis of bacterial strains, but optimisation of the analysis is desirable in each problem domain.We present a method for analysis of bacterial aCGH data that encodes spatial information from the reference genome in a hidden Markov model. This technique is the first such method to be validated in comparisons of sequenced bacteria that diverge at the strain and at the genus level: Pectobacterium atrosepticum SCRI1043 (Pba1043) and Dickeya dadantii 3937 (Dda3937); and Lactococcus lactis subsp. lactis IL1403 and L. lactis subsp. cremoris MG1363. In all cases our method is found to outperform common and widely used aCGH analysis methods that do not incorporate spatial information. This analysis is applied to comparisons between commercially important plant pathogenic soft-rotting enterobacteria (SRE) Pba1043, P. atrosepticum SCRI1039, P. carotovorum 193, and Dda3937.Our analysis indicates that it should not be assumed that hybridisation strength is a reliable proxy for sequence identity in aCGH experiments, and robustly extends the applicability of aCGH to bacterial comparisons at the genus level. Our results in the SRE further provide evidence for a dynamic, plastic ‘accessory’ genome, revealing major genomic islands encoding gene products that provide insight into, and may play a direct role in determining, variation amongst the SRE in terms of their environmental survival, host range and aetiology, such as phytotoxin synthesis, multidrug resistance, and nitrogen fixation.     

Specific single-cell isolation and genomic amplification of uncultured microorganisms

We in this study describe a new method for genomic studies of individual uncultured prokaryotic organisms, which was used for the isolation and partial genome sequencing of a soil archaeon. The diversity of Archaea in a soil sample was mapped by generating a clone library using group-specific primers in combination with a terminal restriction fragment length polymorphism profile. Intact cells were extracted from the environmental sample, and fluorescent in situ hybridization probing with Cy3-labeled probes designed from the clone library was subsequently used to detect the organisms of interest. Single cells with a bright fluorescent signal were isolated using a micromanipulator and the genome of the single isolated cells served as a template for multiple displacement amplification (MDA) using the Phi29 DNA polymerase. The generated MDA product was afterwards used for 16S rRNA gene sequence analysis and shotgun-cloned for additional genomic analysis. Sequence analysis showed >99% 16S rRNA gene homology to soil crenarchaeotal clone SCA1170 and shotgun fragments had the closest match to a crenarchaeotal BAC clone previously retrieved from a soil sample. The system was validated using Methanothermobacter thermoautotrophicus as single-cell test organism, and the validation setup produced 100% sequence homology to the ten tested regions of the genome of this organism.     

PSMC (pairwise sequentially Markovian coalescent) analysis of RAD (restriction site associated DNA) sequencing data

The pairwise sequentially Markovian coalescent (PSMC) method uses the genome sequence of a single individual to estimate demographic history covering a time span of thousands of generations. Although originally designed for whole‐genome data, we here use simulations to investigate its applicability to reference genome‐aligned restriction site associated DNA (RAD) data. We find that RAD data can potentially be used for PSMC analysis, but at present with limitations. The key factor is the proportion (p) of the genome that the RAD data covers. In our simulations, a proportion of 10% can still retain a substantial amount of coalescent information, whereas for 1% estimation becomes unreliable. The performance depends strongly on mutation rate (μ) and recombination rate (r) and is proportional to μ*p/r. When the value of this term is low, increasing the amount of data and number of iterations helps restoring the power of the estimation. We subsequently analyse one whole‐genome‐sequenced and 17 RAD‐sequenced three‐spined sticklebacks (Gasterosteus aculeatus) from a lake in Greenland. The whole‐genome sequence suggests a relatively recent expansion and decline within ca. 4000–40 000 generations ago, possibly reflecting postglacial expansion and founding of the lake population. RAD data, where chromosomes from 10 individuals are combined, identify a similar pattern. Our study provides guidance about the use of PSMC analysis and suggests measures that can improve its utility for RAD data. Finally, the study shows that RAD loci in general contain coalescent information that can be used for developing more targeted methods.     

Two-dimensional DNA displays for comparisons of bacterial genomes

We have developed two whole genome-scanning techniques to aid in the discovery of polymorphisms as well as horizontally acquired genes in prokaryotic organisms.First, two-dimensional bacterial genomic display (2DBGD) was developed using restriction enzyme fragmentation to separate genomic DNA based on size, and then employing denaturing gradient gel electrophoresis (DGGE) in the second dimension to exploit differences in sequence composition. This technique was used to generate high-resolution displays that enable the direct comparison of >800 genomic fragments simultaneously and can be adapted for the high-throughput comparison of bacterial genomes. 2DBGDs are capable of detecting acquired and altered DNA, however, only in very closely related strains. If used to compare more distantly related strains (e.g. different species within a genus) numerous small changes (i.e. small deletions and point mutations) unrelated to the interesting phenotype, would encumber the comparison of 2DBGDs. For this reason asecond method, bacterial comparative genomic hybridization (BCGH), was developed to directly compare bacterial genomes to identify gain or loss of genomic DNA. BCGH relies on performing 2DBGD on a pooled sample of genomic DNA from 2 strains to be compared and subsequently hybridizing the resulting 2DBGD blot separately with DNA from each individual strain. Unique spots (hybridization signals) represent foreign DNA. The identification of novel DNA is easily achieved by excising the DNA from a dried gel followed by subsequent cloning and sequencing. 2DBGD and BCGH thus represent novel high resolution genome scanning techniques for directly identifying altered and/or acquired DNA. Published: June 15, 2003     

Molecular cytogenetic analysis of repeated sequences in a long term wheat suspension culture

A rapidly growingTriticum aestivum L. (wheat) derived long term suspension culture (named TaKB1), that is probably not regenerable, was analysed for karyotype rearrangements, stability and changes in repetitive DNA. The cell line has an average chromosome number of 21 and the DNA amount of unreplicated cells of TaKB1 measured by flow cytometry is about 30% lower than an unreplicated (1C) bread wheat genome.In situ hybridization of a repetitive DNA sequence (pSc119.2), which occurs as tandemly repeated blocks (heterochromatin) in wheat, shows that chromosomes from the TakB1 line have fewer and weaker subtelomeric locations of the sequence than wheat, suggesting deletions of distal chromosome segments and a reduction in the sites and copy number of the sequence. Thein situ hybridization pattern and chromosome morphology allowed 27 chromosome types to be identified in the cell line. No two analysed cells contained the same chromosome complement, although some chromosome types were present in every cell. Using Southern hybridization the structure and copy number of a retroelement (Wis-2) and its flanking sequence was shown to be the same in the TaKB1 cell line and wheat. Anin situ analysis of rDNA in the TaKB1 cell line (using the probe pTa71) showed a reduction in number of sites and rRNA genes in each cell from that in wheat. Interphase cells of the cell line showed dispersed signal throughout the nucleolus with no evidence for clusters of condensed and inactive rRNA genes.     

Microarray detection of food-borne pathogens using specific probes prepared by comparative genomics

In order to design a method for the accurate detection and identification of food-borne pathogens, we used comparative genomics to select 70-mer oligonucleotide probes specific for 11 major food-borne pathogens (10 overlapping probes per pathogen) for use in microarray analysis. We analyzed the hybridization pattern of this constructed microarray with the Cy3-labeled genomic DNA of various food-borne pathogens and other bacteria. Our microarray showed a highly specific hybridization pattern with the genomic DNA of each food-borne pathogen; little unexpected cross-hybridization was observed. Microarray data were analyzed and clustered using the GenePix Pro 6.0 and GeneSpring GX 7.3.1 programs. The analyzed dendrogram revealed the discriminating power of constructed microarray. Each food-borne pathogen clustered according to its hybridization specificity and non-pathogenic species were discriminated from pathogenic species. Our method can be applied to the rapid and accurate detection and identification of food-borne pathogens in the food industry. In addition, this study demonstrates that genome sequence comparison and DNA microarray analysis have a powerful application in epidemiologic and taxonomic studies, as well as in the food safety and biodefense fields.     

Genomic organization of two families of highly repeated nuclear DNA sequences of maize selected for autonomous replicating activity in yeast

Maize nuclear DNA sequences capable of promoting the autonomous replication of plasmids in yeast were isolated by ligating Eco RI-digested fragments into yeast vectors unable to replicate autonomously. Three such autonomously replicating sequences (ARS), representing two families of highly repeated sequences within the maize genome, were isolated and characterized. Each repetitive family shows hybridization patterns on a Southern blot characteristic of a dispersed sequence. Unlike most repetitive sequences in maize, both ARS families have a constant copy number and characteristic genomic hybridization pattern in the inbred lines examined. Larger genome clones with sequence homology to the ARS-containing elements were selected from a lambda library of maize genomic DNA. There was typically only one copy of an ARS-homologous sequence on each 12–15 kb genomic fragment.