Construction of a bacterial artificial chromosome library containing large Eco RI and Hin dIII genomic fragments of lettuce

 Existing bacterial artificial chromosome (BAC) vectors were modified to have unique EcoRI cloning sites. This provided an additional site for generating representative libraries from genomic DNA digested with a variety of enzymes. A BAC library of lettuce was constructed following the partial digestion of genomic DNA with HindIII or EcoRI. Several experimental parameters were investigated and optimized. The BAC library of over 50,000 clones, representing one to two genome equivalents, was constructed from six ligations; average insert sizes for each ligation varied between 92.5 and 142 kb with a combined average insert size of 111 kb. The library was screened with markers linked to disease resistance genes; this identified 134 BAC clones from four regions containing resistance genes. Hybridization with low-copy genomic sequences linked to resistance genes detected fewer clones than expected from previous estimates of genome size. The lack of hybridization to chloroplast and mitochondrial sequences demonstrated that the library was predominantly composed of nuclear DNA. The unique EcoRI site in the BAC vector should allow the integration of BAC cloning with other technologies that utilize EcoRI digestion, such as AFLP^TM markers and RecA-assisted restriction endonuclease (RARE) cleavage, to clone specific large EcoRI fragments from genomic DNA. Received: 5 August 1996 / Accepted: 23 August 1996     

Organization of a family of highly repetitive sequences within the human genome

Recombinant clones containing the highly repetitive human DNA sequence approximately 340 base-pairs in length obtained after EcoRI digestion (αRI-DNA) were cloned in plasmid pAT153. Two clones contained a single copy of the αRI-DNA sequence, and the third had an insert with two copies of the sequence in tandem. When radioactive recombinant DNA was hybridized to total human DNA partially digested with EcoRI, a series of multiple bands was obtained up to 22 repeats in length, demonstrating that the αRI-DNA sequences occur in tandem arrays in the genomic DNA. A reassociation analysis using isolated insert DNA from one of the recombinant clones showed that the family of sequences is repeated 22,000 times in the human genome. Clones containing the αRI-DNA sequence were also isolated from a library of human genomic DNA in bacteriophage λ. Using these clones it was shown that, in at least some cases, the repetitive element is bounded by DNA less abundant than the αRI sequence.     

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.     

Genomic Subtraction Recovers Rye-Specific DNA Elements Enriched in the Rye Genome

Repetitive DNA sequence families have been identified in methylated relic DNAs of rye. This study sought to isolate rye genome-specific repetitive elements regardless of the level of methylation, using a genomic subtraction method. The total genomic DNAs of rye-chromosome-addition-wheat lines were cleaved to short fragments with a methylation-insensitive 4-bp cutter, MboI, and then common DNA sequences between rye and wheat were subtracted by annealing with excess wheat genomic DNA. Four classes of rye-specific repetitive elements were successfully isolated from both the methylated and non-methylated regions of the genome. Annealing of the DNA mixture at a ratio of the enzyme-restricted fragments:the sonicated fragments (1:3–1:5) was key to this success. Two classes of repetitive elements identified here belong to representative repetitive families: the tandem 350-family and the dispersed R173 family. Southern blot hybridization patterns of the two repetitive elements showed distinct fragments in methylation-insensitive EcoO109I digests, but continuous smear signals in the methylation-sensitive PstI and SalI digests, indicating that both of the known families are contained in the methylated regions. The subtelomeric tandem 350-family is organized by multimers of a 380-bp-core unit defined by the restriction enzyme EcoO109I. The other two repetitive element classes had new DNA sequences (444, 89 bp) and different core-unit sizes, as defined by methylation-sensitive enzymes. The EcoO109I recognition sites consisting of PyCCNGGPu-multi sequences existed with high frequency in the four types of rye repetitive families and might be a useful tool for studying the genomic organization and differentiation of this species.     

New families of site-specific repetitive DNA sequences that comprise constitutive heterochromatin of the Syrian hamster (Mesocricetus auratus, Cricetinae, Rodentia)

We molecularly cloned new families of site-specific repetitive DNA sequences from BglII- and EcoRI-digested genomic DNA of the Syrian hamster (Mesocricetus auratus, Cricetrinae, Rodentia) and characterized them by chromosome in situ hybridization and filter hybridization. They were classified into six different types of repetitive DNA sequence families according to chromosomal distribution and genome organization. The hybridization patterns of the sequences were consistent with the distribution of C-positive bands and/or Hoechst-stained heterochromatin. The centromeric major satellite DNA and sex chromosome-specific and telomeric region-specific repetitive sequences were conserved in the same genus (Mesocricetus) but divergent in different genera. The chromosome-2-specific sequence was conserved in two genera, Mesocricetus and Cricetulus, and a low copy number of repetitive sequences on the heterochromatic chromosome arms were conserved in the subfamily Cricetinae but not in the subfamily Calomyscinae. By contrast, the other type of repetitive sequences on the heterochromatic chromosome arms, which had sequence similarities to a LINE sequence of rodents, was conserved through the three subfamilies, Cricetinae, Calomyscinae and Murinae. The nucleotide divergence of the repetitive sequences of heterochromatin was well correlated with the phylogenetic relationships of the Cricetinae species, and each sequence has been independently amplified and diverged in the same genome.     

Gene identification in a complex chromosomal continuum by local genomic cross-referencing

Most higher plants have complex genomes containing large quantities of repetitive DNA interspersed with low-copy-number sequences. Many of these repetitive DNAs are mobile and have homology to RNAs in various cell types. This can make it difficult to identify the genes in a long chromosomal continuum. It was decided to use genic sequence conservation and grass genome co-linearity as tools for gene identification. A bacterial artificial chromosome (BAC) clone containing sorghum genomic DNA was selected using a maize Adh1 probe. The 165 kb sorghum BAC was tested for hybridization to a set of clones representing the contiguous 280 kb of DNA flanking maize Adh1. None of the repetitive maize DNAs hybridized, but most of the low-copy-number sequences did. A low-copy-number sequence that did cross-hybridize was found to be a gene, while one that did not was found to be a low-copy-number retrotransposon that was named Reina. Regions of cross-hybridization were co-linear between the two genomes, but closer together in the smaller sorghum genome. These results indicate that local genomic cross-referencing by hybridization of orthologous clones can be an efficient and rapid technique for gene identification and studies of genome organization.     

Construction of two BAC libraries from cucumber (Cucumis sativus L.) and identification of clones linked to yield component quantitative trait loci

Two bacterial artificial chromosome (BAC) libraries were constructed from an inbred line derived from a cultivar of cucumber (Cucumis sativus L.). Intact nuclei were isolated and embedded in agarose plugs, and high-molecular-weight DNA was subsequently partially digested with BamHI or EcoRI. Ligation of double size-selected DNA fragments with the pECBAC1 vector yielded two libraries containing 23,040 BamHI and 18,432 EcoRI clones. The average BamHI and EcoRI insert sizes were estimated to be 107.0 kb and 100.8 kb, respectively, and BAC clones lacking inserts were 1.3% and 14.5% in the BamHI and EcoRI libraries, respectively. The two libraries together represent approximately 10.8 haploid cucumber genomes. Hybridization with a C₀t-1 DNA probe revealed that approximately 36% of BAC clones likely carried repetitive sequence-enriched DNA. The frequencies of BAC clones that carry chloroplast or mitochondrial DNA range from 0.20% to 0.47%. Four sequence-characterized amplified region (SCAR), four simple sequence repeat, and an randomly amplified polymorphic DNA marker linked with yield component quantitative trait loci were used either as probes to hybridize high-density colony filters prepared from both libraries or as primers to screen an ordered array of pooled BAC DNA prepared from the BamHI library. Positive BAC clones were identified in predicted numbers, as screening by polymerase chain reaction amplification effectively overcame the problems associated with an overabundance of positives from hybridization with two SCAR markers. The BAC clones identified herein that are linked to the de (determinate habit) and F (gynoecy) locus will be useful for positional cloning of these economically important genes. These BAC libraries will also facilitate physical mapping of the cucumber genome and comparative genome analyses with other plant species.     

Isolation and characterization of genome-specific DNA sequences in Triticeae species

Two contrasting genome-specific DNA sequences were isolated from Aegilops speltoides (wild goat grass) and Hordeum chilense (wild barley), each representing more than 1 % of the genomes. These repetitive DNA fragments were identified as being genome-specific before cloning by genomic Southern hybridization (using total genomic DNA as a probe), and hence extensive screening of clones was not required. For each fragment, up to six recombinant plasmid clones were screened and about half were genome-specific. Clone pAesKB52 from Ae. speltoides was a 763 by EcoRI fragment, physically organized in simple tandem repeats and shown to localize to sub-telomerec chromosome regions of species with the Triticeae S-genome by in situ hybridization to chromosomes. The sequence data showed an internal duplication of some 280 bp, which presumably occurred before sequence amplification and dispersion, perhaps by unequal crossing-over or reciprocal translocation. In situ hybridization showed that the sequence distribution varied between closely related (S-genome) species. Clone pHcKB6 was a 339 by DraI fragment from H. chilense, also tandemly repeated but more variable; loss of the DraI site resulting in a ladder pattern in Southern blots which had little background smear. In situ hybridization showed that the tandem repeats were present as small clusters dispersed along all chromosome arms except at a few discrete regions including the centromeres and telomeres. The clone hybridized essentially specifically to the H-genome of H. chilense and hence was able to identify the origin of chromosomes in a H. chilense x Secale africanum hybrid by in situ hybridization. It has a high A + T content (66%), small internal duplications, and a 50 by degenerate inverted repeat. We speculate that it has dispersed by retrotransposition in association with other sequences carrying coding domains. The organization and evolution of such sequences are important in understanding long-range genome organization and the types of change that can occur on evolutionary and plant breeding timescales. Genome-specific sequences are also useful as markers for alien chromatin in plant breeding.     

Maize DNA enrichment by representational difference analysis in a maize chromosome addition line of oat

 The recent recovery of maize (Zea mays L.) single-chromosome addition lines of oat (Avena sativa L.) from oat x maize crosses has provided novel source materials for the potential isolation of maize chromosome-specific sequences for use in genetic mapping and gene cloning. We report here the application of a technique, known as representational difference analysis (RDA), to selectively isolate maize sequences from a maize chromosome-3 addition line of oat. DNA fragments from the addition line and from the oat parent were prepared using BamHI digestion and primer ligation followed by PCR amplification. A subtractive hybridization technique using an excess of the oat parental DNA was employed to reduce the availability for amplification of DNA fragments from the addition lines that were in common with the ones from the oat parental line. After three rounds of hybridization and amplification, the resulting DNA fragments were cloned into a plasmid vector. A DNA library containing 400 clones was constructed by this method. In a test of 18 clones selected at random from this library, four (22%) detected maize-specific repetitive DNA sequences and nine (50%) showed strong hybridization to genomic DNA of maize but weak hybridization to genomic DNA of oat. Among these latter nine clones, three detected low-copy DNA sequences and two of them detected DNA sequences specific to chromosome 3 of maize, the chromosome retained in the source maize addition line of oat. The other eight out of the 13 clones that had strong hybridization to maize DNA detected repetitive DNA sequences or high-copy number sequences present on most or all maize chromosomes. We estimate that the maize DNA sequences were enriched from about 1.8% to over 72% of the total DNA by this procedure. Most of the isolated DNA fragments detected multiple or repeated DNA sequences in maize, indicating that the major part of the maize genome consists of repetitive DNA sequences that do not cross-hybridize to oat genomic sequences. Received: 18 November 1997 / Accepted: 12 March 1998     

Isolation and mapping of ribosomal RNA genes of Caulobacter crescentus

Ribosomal DNA fragments of 1.0, 3.4, 3.7 and 6.1 kb² produced by EcoRI digestion of the Caulobacter crescentus genome were identified by hybridization to a labeled ribosomal RNA probe. These genomic sequences were further characterized by the isolation of 13 hybrid λ Charon 4 phages with rDNA inserts, and two of the recombinant phages, Ch4Cc773 and Ch4Cc1880, were examined extensively. The Cc773 insert contains EcoRI fragments of 1.0 kb, 3.4 kb and 3.7 kb and the Cc1880 insert contains EcoRI fragments of 1.0 kb, 3.4 kb and 6.1 kb that hybridized to ³²P-labeled rRNA. Thus, the two clones contain different DNA inserts which together account for all of the rDNA fragments detected in digests of the C. crescentus genome. Hybridization with isolated transfer RNA and individual rRNA species indicated that the arrangement of genes in both units is 16 S-spacer tRNA(s)-23 S-5 S, tRNA(s). Homology between the DNA inserts is largely restricted to the rRNA coding regions, which suggests that the two rDNA units are located in different regions of the chromosome. Results of quantitative hybridization experiments are most consistent with a single Cc1880 and Cc773 unit per genome equivalent of 2.7 × 10⁹ daltons. The relatively simple organization of rDNA sequences in the C. crescentus chromosome compared to Escherichia coli is discussed.     

Characterization of an <Emphasis Type="Italic">Eco</Emphasis>RI family of satellite DNA from two species

We have cloned and sequenced a 321bp band of repetitive DNA from Eptesicus fuscus and E. serotinus observed after gel electrophoresis of EcoRI digested genomic DNA in both species. Southern blot analysis of genomic DNA (from both species) digested with the same enzyme showed the existence of a ladder pattern indicating that the repetitive DNA is arrayed in tandem. The repetitive sequences have a monomer unit of 321bp which is composed of two subunits of 160bp, suggested by the existence of a 160bp band in the ladder of E. fuscus and by the presence of some direct repeats found in the analysis of the consensus sequence. Analysis of the methylation status demonstrated that cytosines in CCGG sequences in this satellite DNA are methylated in E. fuscus but not in the E. serotinus. Alignment of the sequenced clones showed that several nucleotide positions are diagnostic species-specific and consequently the phylogenetic analysis grouped the monomer units from both species in two clearly separated groups.     

Molecular analysis of human Chromosome 16 cosmid clones containing NotI sites

To test the feasibility of using cloned NotI sites as markers for physical mapping, we have screened for cosmid clones spanning the NotI sites on human Chromosome (Chr) 16. Fluorescence in situ hybridization analysis of these clones confirms the previously reported cluster of NotI sites on 16p13.3. Methylation status of the cloned NotI sites on genomic DNA was established by hybridization of the cosmids to Southern blots containing EcoRI and EcoRI/NotI digest of genomic DNA. These results indicated that four of six clones included in our study can be used as linking clones for physical mapping. Two clones have NotI sites which are not cleavable in the cell lines tested. In one clone, the NotI site exists as an isolated rare-cutting restriction enzyme site, whereas in the other clone the NotI site appears to be island-related.     

Regional localization and molecular characterization of a DNA sequence on the long arm of chromosome 22

Summary A human genomic DNA fragment, p22hom13 (D22S16), was isolated from a chromosome 22-specific library. After elimination of repetitive sequences, a single copy BamHI-EcoRI fragment was subcloned into pTZ18. By using mouse/human somatic cell hybrids and in situ hybridization, the new DNA probe was mapped to chromosome 22q13-qter. Its application in the analysis of the distal part of chromosome 22 and its diagnostic use in translocations are discussed.     

Isolation of A/D and C genome specific dispersed and clustered repetitive DNA sequences from Avena sativa.

DNA gel-blot and in situ hybridization with genome-specific repeated sequences have proven to be valuable tools in analyzing genome structure and relationships in species with complex allopolyploid genomes such as hexaploid oat (Avena sativa L., 2n = 6x = 42; AACCDD genome). In this report, we describe a systematic approach for isolating genome-, chromosome-, and region-specific repeated and low-copy DNA sequences from oat that can presumably be applied to any complex genome species. Genome-specific DNA sequences were first identified in a random set of A. sativa genomic DNA cosmid clones by gel-blot hybridization using labeled genomic DNA from different Avena species. Because no repetitive sequences were identified that could distinguish between the A and D gneomes, sequences specific to these two genomes are refereed to as A/D genome specific. A/D or C genome specific DNA subfragments were used as screening probes to identify additional genome-specific cosmid clones in the A. sativa genomic library. We identified clustered and dispersed repetitive DNA elements for the A/D and C genomes that could be used as cytogenetic markers for discrimination of the various oat chromosomes. Some analyzed cosmids appeared to be composed entirely of genome-specific elements, whereas others represented regions with genome- and non-specific repeated sequences with interspersed low-copy DNA sequences. Thus, genome-specific hybridization analysis of restriction digests of random and selected A. sativa cosmids also provides insight into the sequence organization of the oat genome.     

Drosophila genome project: One-hit coverage in yeast artificial chromosomes

We present a strategy for assembling a physical map of the genome of Drosophila melanogaster based on yeast artificial chromosomes (YACs). In this paper we report 500 YACs containing inserts of Drosophila DNA averaging 200 kb that have been assigned positions on the physical map by means of in situ hybridization with salivary gland chromosomes. The cloned DNA fragments have randomly sheared ends (DY clones) or ends generated by partial digestion with either NotI (N clones) or EcoRI (E clones). Relative to the euchromatic portion of the genome, the size distribution and genomic positions of the clones reveal no significant bias in the completeness or randomness of genome coverage. The 500 mapped euchromatic clones contain an aggregate of approximately 100 million base pairs of DNA, which is approximately one genome equivalent of Drosophila euchromatin.by W. Hennig     

Construction of a swine YAC library allowing an efficient recovery of unique and centromeric repeated sequences

A swine DNA genomic library was constructed in yeast artificial chromosome (YAC) using the pYAC4 vector and the AB1380 strain. The DNA prepared from two Large White males was partially digested with EcoRI and size selected after both digestion and ligation. The YAC library contained 33792 arrayed clones with an average size of 280 kb as estimated by analysis of 2% of the clones, thus representing a threefold coverage of the swine haploid genome. The library was organized in pools to facilitate the PCR screening. The complexity of the library was tested both for unique and centromeric repeated sequences. In all, 20 out of 22 primer sets allowed the characterization of one to six clones containing specific unique sequences. These sequences are known to be on Chromosomes (Chrs) 1, 2, 5, 6, 7, 8, 13, 14, 15, 17, and X. Eight additional clones carrying centromeric repeat units were also isolated with a single primer set. The sequencing of 37 distinct repeat units of about 340 bp subcloned from these eight YACs revealed high sequence diversity indicating the existence of numerous centromeric repeat unit subfamilies in swine. Furthermore, the analysis of the restriction patterns with selected enzymes suggested a higher order organization of the repeat units. According to preliminary FISH experiments on a small number of randomly chosen YACs and YACs carrying specific sequences, the chimerism appeared to be low. In addition, primed in situ labeling experiments favored the idea that the YACs with centromeric repeat sequences were derived from a subset of metacentric and submetacentric chromosomes. Received: 14 July 1996 / Accepted: 24 October 1996     

A family of dispersed repeats in the genome of Vicia faba: structure, chromosomal organization, redundancy modulation, and evolution

A family of repeated DNA sequences of about 1200 bp in length and bordered by well-conserved, 18 bp inverted repeats (VfB family) was found in the nuclear genome of Vicia faba. The structure, chromosomal organization, redundancy modulation and evolution of these sequences were investigated. They are enriched in A+T base pairs (about 40% G+C) and lack any obvious internally repeated motif. A 64%–73% nucleotide sequence identity was found when pairwise comparisons between VfB sequences were carried out (average 69%). Direct repeats were not found to flank the inverted repeats that border these DNA sequences. The results obtained by hybridizing VfB repeats to Southern blots of V. faba genomic DNA digested with EcoRI indicated that these DNA elements are interspersed in the genome. The appearance of bands in these Southern blots and comparison of the structure of the sequences that flank different VfB elements showed that these repeats might be part of other, longer repeated DNA sequences. A high degree of dispersion throughout the genome was confirmed by cytological hybridization, which showed VfB sequences to be scattered along the length of all chromosomes and to be absent or rare only at heterochromatic chromosomal regions. These sequences contribute to intraspecific alterations of genomic size. Indeed, dot-blot hybridizations proved that their redundancy, which is positively correlated with the overall amount of nuclear DNA in each accession, varies between V. faba land races (27×10³–230×10³ copies per 1C DNA). Southern blot hybridization of VfB repeats to restriction endonuclease-digested genomic DNAs of V. faba, V. narbonensis, V. sativa, Phaseolus coccineus, Populus deltoides, and Triticum durum revealed nucleotide sequence homology of these DNA elements, whatever the stringency conditions, only to the DNAs of Vicia species, and to a reduced extent to the DNAs of V. narbonensis and V. sativa compared with that of V. faba. It is concluded that VfB repeats might be descended from mobile DNA elements and contribute to change genomic size and organization during evolution. Received: 10 September 1998; in revised form: 12 May 1999 / Accepted: 19 May 1999     

Construction and Characterization of Two Bacterial Artificial Chromosome Libraries of Grass Carp

Bacterial artificial chromosome (BAC) library is an important tool in genomic research. We constructed two libraries from the genomic DNA of grass carp (Ctenopharyngodon idellus) as a crucial part of the grass carp genome project. The libraries were constructed in the EcoRI and HindIII sites of the vector CopyControl pCC1BAC. The EcoRI library comprised 53,000 positive clones, and approximately 99.94% of the clones contained grass carp nuclear DNA inserts (average size, 139.7 kb) covering 7.4× haploid genome equivalents and 2% empty clones. Similarly, the HindIII library comprised 52,216 clones with approximately 99.82% probability of finding any genomic fragments containing single-copy genes; the average insert size was 121.5 kb with 2.8% insert-empty clones, thus providing genome coverage of 6.3× haploid genome equivalents of grass carp. We selected gene-specific probes for screening the target gene clones in the HindIII library. In all, we obtained 31 positive clones, which were identified for every gene, with an average of 6.2 BAC clones per gene probe. Thus, we succeeded in constructing the desired BAC libraries, which should provide an important foundation for future physical mapping and whole-genome sequencing in grass carp.     

Organization of the Euplotes crassus Micronuclear Genome1

Euplotes crassus, like other hypotrichous ciliated protozoa, eliminates most of its micronuclear chromosomal DNA in the process of forming the small linear DNA molecules that comprise the macronuclear genome. By characterizing randomly selected lambda phage clones of E. crassus micronuclear DNA, we have determined the distribution of repetitive and unique sequences and the arrangement of macronuclear genes relative to eliminated DNA. This allows us to compare the E. crassus micronuclear genome organization to that of another distantly related hypotrichous ciliate, Oxytricha nova. The clones from E. crassus segregate into three prevalent classes: those containing primarily eliminated repetitive DNA (Class I); those containing macronuclear genes in addition to repetitive sequences (Class II); and those containing only eliminated unique sequence DNA (Class III). All of the repetitive sequences in these clones belong to the same highly abundant repetitive element family. Our results demonstrate that the sequence organization of the E. crassus and O. nova micronuclear genomes is related in that the macronuclear genes are clustered together in the micronuclear genome and the eliminated unique sequences occur in long stretches that are uninterrupted by repetitive sequences. In both organisms a single repetitive element family comprises the majority of the eliminated interspersed middle repetitive DNA and appears to be preferentially associated with the macronuclear sequence clusters. The similarities in the sequence organization in these two organisms suggest that clustering of macronuclear genes plays a role in the chromosome fragmentation process.