Shotgun Optical Maps of the Whole Escherichia coli O157:H7 Genome

We have constructed NheI and XhoI optical maps of Escherichia coli O157:H7 solely from genomic DNA molecules to provide a uniquely valuable scaffold for contig closure and sequence validation. E. coli O157:H7 is a common pathogen found in contaminated food and water. Our approach obviated the need for the analysis of clones, PCR products, and hybridizations, because maps were constructed from ensembles of single DNA molecules. Shotgun sequencing of bacterial genomes remains labor-intensive, despite advances in sequencing technology. This is partly due to manual intervention required during the last stages of finishing. The applicability of optical mapping to this problem was enhanced by advances in machine vision techniques that improved mapping throughput and created a path to full automation of mapping. Comparisons were made between maps and sequence data that characterized sequence gaps and guided nascent assemblies.     

Fosmid-based physical mapping of the Histoplasma capsulatum genome

A fosmid library representing 10-fold coverage of the Histoplasma capsulatum G217B genome was used to construct a restriction-based physical map. The data obtained from three restriction endonuclease fingerprints, generated from each clone using BamHI, HindIII, and PstI endonucleases, were combined and used in FPC for automatic and manual contig assembly builds. Concomitantly, a whole-genome shotgun (WGS) sequencing of paired-end reads from plasmids and fosmids were assembled with PCAP, providing a predicted genome size of up to 43.5 Mbp and 17% repetitive DNA. Fosmid paired-end sequences in the WGS assembly provide anchoring information to the physical map and result in joining of existing physical map contigs into 84 clusters containing 9551 fosmid clones. Here, we detail mapping the Histoplasma capsulatum genome comprehensively in fosmids, resulting in an efficient paradigm for de novo sequencing that uses a map-assisted whole genome shotgun approach.     

Whole-genome shotgun optical mapping of Rhodobacter sphaeroides strain 2.4.1 and its use for whole-genome shotgun sequence assembly

Rhodobacter sphaeroides 2.4.1 is a facultative photoheterotrophic bacterium with tremendous metabolic diversity, which has significantly contributed to our understanding of the molecular genetics of photosynthesis, photoheterotrophy, nitrogen fixation, hydrogen metabolism, carbon dioxide fixation, taxis, and tetrapyrrole biosynthesis. To further understand this remarkable bacterium, and to accelerate an ongoing sequencing project, two whole-genome restriction maps (EcoRI and HindIII) of R. sphaeroides strain 2.4.1 were constructed using shotgun optical mapping. The approach directly mapped genomic DNA by the random mapping of single molecules. The two maps were used to facilitate sequence assembly by providing an optical scaffold for high-resolution alignment and verification of sequence contigs. Our results show that such maps facilitated the closure of sequence gaps by the early detection of nascent sequence contigs during the course of the whole-genome shotgun sequencing process.     

Bacterial artificial chromosome libraries for mouse sequencing and functional analysis

Bacterial artificial chromosome (BAC) and P1-derived artificial chromosome (PAC) libraries providing a combined 33-fold representation of the murine genome have been constructed using two different restriction enzymes for genomic digestion. A large-insert PAC library was prepared from the 129S6/SvEvTac strain in a bacterial/mammalian shuttle vector to facilitate functional gene studies. For genome mapping and sequencing, we prepared BAC libraries from the 129S6/SvEvTac and the C57BL/6J strains. The average insert sizes for the three libraries range between 130 kb and 200 kb. Based on the numbers of clones and the observed average insert sizes, we estimate each library to have slightly in excess of 10-fold genome representation. The average number of clones found after hybridization screening with 28 probes was in the range of 9-14 clones per marker. To explore the fidelity of the genomic representation in the three libraries, we analyzed three contigs, each established after screening with a single unique marker. New markers were established from the end sequences and screened against all the contig members to determine if any of the BACs and PACs are chimeric or rearranged. Only one chimeric clone and six potential deletions have been observed after extensive analysis of 113 PAC and BAC clones. Seventy-one of the 113 clones were conclusively nonchimeric because both end markers or sequences were mapped to the other confirmed contig members. We could not exclude chimerism for the remaining 41 clones because one or both of the insert termini did not contain unique sequence to design markers. The low rate of chimerism, approximately 1%, and the low level of detected rearrangements support the anticipated usefulness of the BAC libraries for genome research.     

Shotgun optical mapping of the entire Leishmania major Friedlin genome

Leishmania is a group of protozoan parasites which causes a broad spectrum of diseases resulting in widespread human suffering and death, as well as economic loss from the infection of some domestic animals and wildlife. To further understand the fundamental genomic architecture of this parasite, and to accelerate the on-going sequencing project, a whole-genome XbaI restriction map was constructed using the optical mapping system. This map supplemented traditional physical maps that were generated by fingerprinting and hybridization of cosmid and P1 clone libraries. Thirty-six optical map contigs were constructed for the corresponding known 36 chromosomes of the Leishmania major Friedlin genome. The chromosome sizes ranged from 326.9 to 2821.3 kb, with a total genome size of 34.7 Mb; the average XbaI restriction fragment was 25.3 kb, and ranged from 15.7 to 77.8 kb on a per chromosomes basis. Comparison between the optical maps and the in silico maps of sequence drawn from completed, nearly finished, or large sequence contigs showed that optical maps served several useful functions within the path to create finished sequence by: guiding aspects of the sequence assembly, identifying misassemblies, detection of cosmid or PAC clones misplacements to chromosomes, and validation of sequence stemming from varying degrees of finishing. Our results also showed the potential use of optical maps as a means to detect and characterize map segmental duplication within genomes.     

The genome of choristoneura fumiferana nuclear polyhedrosis virus: Molecular cloning and mapping of the EcoRI, BamHI, SmaI, XbaI and Bg1II restriction sites

The DNA genome of Choristoneura fumiferana nuclear polyhedrosis virus (CfMNPV) was extracted from purified virus preparations and analyzed with restriction endonucleases EcoRI, BamHI, HindIII, SmaI, XbaI and Bg1II. The sizes of the fragments were calculated with respect to mobilities of standard adenovirus-2 DNA fragments. The total size of the genome was calculated to be about 125 kb. Most of the CfMNPV genome was then cloned as EcoRI fragments in the plasmid vector pBR322. The clones were authenticated by electrophoretic analysis in the presence of EcoRI-digested CfMNPV DNA and by hybridization of ³²P nick-translated clones to Southern blots of different enzyme digests of the genome. Data from such hybridization experiments complemented with other mapping procedures were used to construct restriction maps for BamHI, EcoRI, XbaI, Bg1II and SmaI enzymes.     

Construction, characterization and chromosomal mapping of bacterial artificial chromosome (BAC) library of Yunnan snub-nosed monkey (Rhinopithecus bieti

We constructed a high redundancy bacterial artificial chromosome library of a seriously endangered Old World Monkey, the Yunnan snub-nosed monkey (Rhinopithecus bieti) from China. This library contains a total of 136 320 BAC clones. The average insert size of BAC clones was estimated to be 148 kb. The percentage of small inserts (50-100 kb) is 2.74%, and only 2.67% non-recombinant clones were observed. Assuming a similar genome size with closely related primate species, the Yunnan snub-nosed monkey BAC library has at least six times the genome coverage. By end sequencing of randomly selected BAC clones, we generated 201 sequence tags for the library. A total of 139 end-sequenced BAC clones were mapped onto the chromosomes of Yunnan snub-nosed monkey by fluorescence in-situ hybridization, demonstrating a high degree of synteny conservation between humans and Yunnan snub-nosed monkeys. Blast search against human genome showed a good correlation between the number of hit clones and the size of the chromosomes, an indication of unbiased chromosomal distribution of the BAC library. This library and the mapped BAC clones will serve as a valuable resource in comparative genomics studies and large-scale genome sequencing of nonhuman primates. The DNA sequence data reported in this paper were deposited in GenBank and assigned the accession number CG891489-CG891703.     

A high-resolution physical map of human chromosome 21p using yeast artificial chromosomes

The short arm of human chromosome 21 (21p) contains many different types of repetitive sequences and is highly homologous to the short arms of other acrocentric chromosomes. Owing to its repetitive nature and the lack of chromosome 21p-specific molecular markers, most physical maps of chromosome 21 exclude this region. We constructed a physical map of chromosome 21p using sequence tagged site (STS) content mapping of yeast artificial chromosomes (YACs). To this end, 39 STSs located on the short arm or near the centromere of chromosome 21 were constructed, including four polymorphic simple tandem repeats (STRs) and two expressed sequence tags (ESTs). Thirty YACs were selected from the St. Louis YAC library, the chromosome 21-enriched ICRF YAC library, and the CEPH YAC and megaYAC libraries. These were assembled in a YAC contig map ranging from the centromere to the rDNA gene cluster at 21p12. The total size of the region covered by YACs is estimated between 2.9 and 5 Mb. The integrity of the YAC contig was confirmed by restriction enzyme fingerprinting and fluorescence in situ hybridization (FISH). One gap with an estimated size of 400 kb remained near the telomeric end of the contig. This YAC contig map of the short arm of human chromosome 21 constitutes a basic framework for further structural and functional studies of chromosome 21p.     

Molecular cloning and physical mapping of the genome of fish lymphocystis disease virus

A defined and complete gene library of the fish lymphocystis disease virus (FLDV) genome was established. FLDV DNA was cleaved with EcoRI, BamHI, EcoRI/BamHI and EcoRI/HindIII and the resulting fragments were inserted into the corresponding sites of the pACYC184 or pAT153 plasmid vectors using T4 DNA ligase. Since FLDV DNA is highly methylated at CpG sequences (Darai et al., 1983; Wagner et al., 1985), an Escherichia coli GC-3 strain was required to amplify the recombinant plasmids harboring the FLDV DNA fragments. Bacterial colonies harboring recombinant plasmids were selected. All cloned fragments were individually identified by digestion of the recombinant plasmid DNA with different restriction enzymes and screened by hybridization of recombinant plasmid DNA to viral DNA. This analysis revealed that sequences representing 100% of the viral genome were cloned. Using these recombinant plasmids, the physical maps of the genome were constructed for BamHI, EcoRI, BestEII, and PstI restriction endonucleases. Although the FLDV genome is linear, due to circular permutation the restriction maps are circular.     

A YAC-based binning strategy facilitating the rapid assembly of cosmid contigs: 1.6 Mb of overlapping cosmids in Xp22

We have applied a yeast artificial chromosome (YAC)-based cosmidisolation and binning strategy to convert a YAC contig in Xp22into 1.6 Mb of overlapping cosmids. This strategy is based onthe screening of a high-density arrayed X chromosome-specificcosmid library with large YAC-derived restriction fragmentsand entire YAC probes. Cosmids selected in this way were griddedon dot blots and further mapped into bins defined by the overlapintervals of the YACs and YAC fragments. This rapid binningof cosmids simplified the subsequent assembly of cosmid contigsby restriction fingerprint hybridization. In total, we identified139 cosmids spanning the entire 1.6 Mb region with a minimaloverlap set of 53 clones. These cosmids were assigned to 17bins and 9 contigs. One of the contigs is 665 kb in length andis one of the largest uninterrupted cosmid contigs in humansreported to date. The gaps between the contigs are minor and,together, they represent less than 7% of the region covered.Two previously identified genes are contained in these cosmids,the gene for amelogenin (AMG) and the recently isolated putativechloride channel gene CICN4. In addition, two disease loci havebeen mapped to this region: X-linked ocular albinism type 1(OA1) and the microphthalmia with linear skin defects (MLS)syndrome. The assembly of the cosmid maps allowed us to determinethe size of the deletion intervals for these two loci, whichwere estimated to be 110 kb for OA1 and 570 kb for MLS. Thesecosmid contigs will greatly facilitate the positional cloningof the OA1 and MLS disease genes. Together with the Huntingtondisease gene region on chromosome 4, this region in Xp22 representsone of the best characterized large regions in the human genome.     

Molecular cloning and physical mapping of the genome of insect iridescent virus type 6: further evidence for circular permutation of the viral genome

A defined and complete gene library of the Chilo iridescent virus (CIV) genome was established. The CIV DNA was cleaved with restriction endonucleases EcoRI, NcoI, SphI, and BamHI or double digested with BamHI/SalI and the resulting DNA fragments were inserted into the corresponding sites of the bacterial vectors pACYC184, pKm2, pL-ES-C3, and pAT153 using T4 DNA ligase. All cloned fragments were identified by digestion of the recombinant plasmids with different restriction enzymes and checked by hybridization of recombinant plasmid to viral DNA. This analysis revealed that sequences representing 100% of the viral genome were cloned into the EcoRI site of pACYC184. Although the CIV genome is linear, all 32 EcoRI fragments have been cloned directly. This suggests that the CIV genome is circularly permuted. In addition, NcoI(72%), SphI(40.7%), BamHI (11.6%), and BamHI/SalI(39.7%) DNA fragments of the viral genome were inserted into the corresponding sites of pKm2, pL-ES-C3, and pAT153, respectively. The physical map of the viral genome was constructed using the established gene library for restriction enzymes ApaI, BamHI, EcoRI, NcoI, SalI, and SmaI. Although the CIV genome is linear, this analysis revealed that the restriction maps of the viral genome are circular. This finding supports the hypothesis that the CIV genome is circularly permuted.     

A marker-dense physical map of the Bradyrhizobium japonicum genome

Bacterial artificial chromosome (BAC) clones are effective mapping and sequencing reagents for use with a wide variety of small and large genomes. This report describes the development of a physical framework for the genome of Bradyrhizobium japonicum, the nitrogen-fixing symbiont of soybean. A BAC library for B. japonicum was constructed that provides a 77-fold genome coverage based on an estimated genome size of 8.7 Mb. The library contains 4608 clones with an average insert size of 146 kb. To generate a physical map, the entire library was fingerprinted with HindIII, and the fingerprinted clones were assembled into contigs using the software (; Sanger Centre, UK). The analysis placed 3410 clones in six large contigs. The ends of 1152 BAC inserts were sequenced to generate a sequence-tagged connector (STC) framework. To join and orient the contigs, high-density BAC colony filters were probed with 41 known gene probes and 17 end sequences from contig boundaries. STC sequences were searched against the public databases using and algorithms. Query results allowed the identification of 113 high probability matches with putative functional identities that were placed on the physical map. Combined with the hybridization data, a high-resolution physical map with 194 positioned markers represented in two large contigs was developed, providing a marker every 45 kb. Of these markers, 177 are known or putative B. japonicum genes. Additionally, 1338 significant results (E < 10(-4)) were manually sorted by function to produce a functionally categorized database of relevant B. japonicum STC sequences that can also be traced to specific locations in the physical map.     

Bacterial Contig Map of the 21q11 Region Associated with Alzheimer’s Disease and Abnormal Myelopoiesis in Down Syndrome

We present a high-resolution bacterial contig map of 3.4 Mb of genomic DNA in human chromosome 21q11–q21, encompassing the region of elevated disomic homozygosity in Down Syndrome-associated abnormal myelopoiesis and leukemia, as well as the markers, which has shown a strong association with Alzheimer’s Disease that has never been explained. The map contains 89 overlapping PACs, BACs, or cosmids in three contigs (850, 850, and 1500 kb) with two gaps (one of 140–210 kb and the second <5 kb). To date, eight transcribed sequences derived by cDNA selection, exon trapping, and/or global EST sequencing have been positioned onto the map, and the only two genes so far mapped to this cytogenetic region, STCH and RIP140 have been precisely localized. This work converts a further 10% of chromosome 21q into a high-resolution bacterial contig map, which will be the physical basis for the long-range sequencing of this region. The map will also enable positional derivation of new transcribed sequences, as well as new polymorphic probes, that will help in elucidation of the role the genes in this region may play in abnormal myelopoiesis and leukemia associated with trisomy 21 and Alzheimer’s Disease.     

Physical maps of SfMNPV baculovirus DNA and its genomic variants

Spodoptera frugiperda MNPV was plaque-purified, and the viral DNA from the plaque-purified isolates was analyzed with restriction endonuclease enzymes. Seven distinct variants were identified when the DNA of the isolates were analyzed by EcoRI and HindIII. The DNAs of the SfMNPV predominant type (prototype) and the variants were mapped with BamHI, BglII, BstEII, EcoRI, HindIII, KpnI, and PstI by multiple enzyme digestion and blot hybridization. The cleavage sites generated by the seven restriction enzymes were ordered, and the sites were assigned map coordinates using a least-squares procedure. Since Autographa californica MNPV-E2 EcoRI fragment I, which contains the polyhedrin gene, hybridized with SfMNPV EcoRI fragment P, the physical map of SfMNPV was oriented with EcoRI P on the left, with site 1 being the EcoRI site between fragments F and P. The calculated genome size was 121.76 kilobase pairs or 80.36 X 10(6) Da. The DNA from each variant was compared to the DNA of the prototype for insertions, deletions, and new restriction sites. Physical maps were generated for each of the variants. The differences between the variant and the prototype were confined to four regions in the SfMNPV genome representing less than 16% of the prototype genome.     

Restriction enzyme cleavage maps of the DNA of two cauliflower mosaic virus isolates

To provide a physical basis for the functional mapping of the cauliflower mosaic virus (CaMV) genome, restriction enzyme cleavage maps of the DNA of CaMV isolates NY8153 and CM4-184-OS (a variant of CM4-184) were constructed. CM4-184-OS DNA contained five EcoRI, eight HindIII six BglIII, and two BamHI cleavage sites, while NY8153 DNA contained one additional HindIII site and one fewer EcoRI site. Fragments were ordered by examination of multienzyme and partial digests. The resulting maps revealed that the CM4-184-OS genome was 5.5% smaller than that of NY8153, because CM4-184-OS was deleted for 463 +/- 10 base pairs including the HindIII site at 0.427 map unit (relative to a common EcoR1 site) and the S1 site at 0.45 map unit on NY8153 DNA. Since the deleted region did not include the two BamHI sites, this variant of the CM4-184 isolate is different from the John Innes variant of CM4-184 (R. Hull, and S. H. Howell, Virology 86, 482-493, 1978) which is deleted for a different, but overlapping region of the CaMV genome.     

Restriction analysis of the prototype strain of enteric adenovirus type 41 using exonuclease III.

Enteric adenoviruses 40 and 41 (Ad40 and Ad41) are a prominent cause of gastroenteritis in young children. Diagnosis of these enteric types by conventional means is complicated by their fastidious growth characteristics. Enteric adenovirus growth was enhanced by cocultivation. Typing of enteric isolates currently entails analysis of the extracted viral DNA with restriction enzymes. Restriction endonuclease fragments of the Ad41 strain Tak genome were ordered by (i) double digestion, (ii) release of restriction fragments from plasmids containing 84% of the Ad41 genome in EcoRI fragments A, B and C, (iii) hybridization of Southern blotted Ad41 fragments with EcoRI fragment containing plasmids and various segments of the Ad2 genome, (iv) sequential reduction of the genome beginning with terminal restriction fragments with exonuclease III and S1 nuclease. The termini of adenovirus genomes are difficult to clone and the use of exonuclease III is a useful alternative to conventional restriction mapping. DNA restriction patterns, fragment sizes and restriction maps of the Ad4 1 strain Tak with enzymes BamHI, BglII, ClaI, EcoRI, HindIII, PstI, SalI, SmaI and XhoI are presented. Prototype strain restriction maps should enable better understanding of adenovirus type 41 and its epidemiology.     

Whole-Genome Mapping: a New Paradigm in Strain-Typing Technology

Strain-typing technology in support of outbreak identification and resolution has evolved from phenotypic analysis, such as serology and biotypes, to much-more-robust molecular genetic approaches, such as pulsed-field gel electrophoresis (PFGE) and whole-genome sequencing. Whole-genome mapping (WGM) has been recently applied to subtyping analysis, and it bridges the gap between PFGE (∼20 bands sorted by size) and whole-genome sequencing. WGM utilizes restriction site analysis but arranges 200 to 500 bands in the order they appear on the chromosome. WGM is able to quickly and cost-effectively generate high-resolution, ordered whole-genome maps of bacteria.     

BAC resources for the rat genome project

Two 11-fold redundant bacterial artificial chromosome (BAC) libraries (RPCI-32 and CHORI-230) have been constructed to support the rat genome project. The first library was constructed using a male Brown Norway (BN/SsNHsd) rat as a DNA source long before plans for rat genome sequencing had been launched. The second library was prepared from a highly inbred female (BN/SsNHsd/MCW) rat in support of the rat genome sequencing project. The use of an inbred rat strain is essential to avoid problems with genome assembly resulting from the difficulty of distinguishing haplotype variation from variation among duplicons. We have demonstrated the suitability of the library by using a detailed quality assessment of large insert sizes, narrow size distribution, consistent redundancy for many markers, and long-range continuity of BAC contig maps. The widespread use of the two libraries as an integral part of the rat genome project has led to the database annotations for many clones, providing rat researchers with a rich resource of BAC clones that can be screened in silico for genes of interest.