Encephalitozoon cuniculi (Microspora) genome: physical map and evidence for telomere-associated rDNA units on all chromosomes

A restriction map of the 2.8-Mb genome of the unicellular eukaryote Encephalitozoon cuniculi (phylum Microspora), a mammal-infecting intracellular parasite, has been constructed using two restriction enzymes with 6 bp recognition sites (BssHII and MluI). The fragments resulting from either single digestions of the whole molecular karyotype or double digestions of 11 individual chromosomes have been separated by two-dimensional pulsed field gel electrophoresis (2D-PFGE) procedures. The average distance between successive restriction sites is ~19 kb. The terminal regions of the chromosomes show a common pattern covering ~15 kb and including one 16S–23S rDNA unit. Results of hybridisation and molecular combing experiments indicate a palindromic-like orientation of the two subtelomeric rDNA copies on each chromosome. We have also located 67 DNA markers (clones from a partial E.cuniculi genomic library) by hybridisation to restriction fragments. Partial or complete sequencing has revealed homologies with known protein-coding genes for 32 of these clones. Evidence for two homologous chromosomes III, with a size difference (3 kb) related to a subtelomeric deletion/insertion event, argues for diploidy of E.cuniculi. The physical map should be useful for both the whole genome sequencing project and studies on genome plasticity of this widespread parasite.     

Genomic organization of telomeric and subtelomeric sequences of Leishmania (Leishmania) amazonensis

Telomeres are DNA-protein complexes that protect linear chromosomes from degradation and fusions. Telomeric DNA is repetitive and G-rich, and protrudes towards the end of the chromosomes as 3'G-overhangs. In Leishmania spp., sequences adjacent to telomeres comprise the Leishmania conserved telomere associated sequences (LCTAS) that are around 100 bp long and contain two conserved sequence elements (CSB1 and CSB2), in addition to non-conserved sequences. The aim of this work was to study the genomic organization of Leishmania (Leishmania) amazonensis telomeric/subtelomeric sequences. Leishmania amazonensis chromosomes were separated in a single Pulsed Field Gel Electrophoresis (PFGE) gel as 25 ethidium bromide-stained bands. All of the bands hybridized with the telomeric probe (5'-TTAGGG-3')3 and with probes generated from the conserved subtelomeric elements (CSB1, CSB2). Terminal restriction fragments (TRF) of L. amazonensis chromosomes were analyzed by hybridizing restriction digested genomic DNA and chromosomal DNA separated in 2D-PFGE with the telomeric probe. The L. amazonensis TRF was estimated to be approximately 3.3 kb long and the telomeres were polymorphic and ranged in size from 0.2 to 1.0 kb. Afa I restriction sites within the conserved CSB1 elements released the telomeres from the rest of the chromosome. Bal 31-sensitive analysis confirmed the presence of terminal Afa I restriction sites and served to differentiate telomeric fragments from interstitial internal sequences. The size of the L. amazonensis 3' G-overhang was estimated by non-denaturing Southern blotting to be approximately 12 nt long. Using similar approaches, the subtelomeric domains CSB1 and CSB2 were found to be present in a low copy number compared to telomeres and were organized in blocks of 0.3-1.5 kb flanked by Hinf I and Hae III restriction sites. A model for the organization of L. amazonensis chromosomal ends is provided.     

Variation in genomic alu repeat density as a basis for rapid construction of low resolution physical maps of human chromosomes

Human DNA restriction fragments containing high numbers of Alu repeat sequences can be preferentially detected in the presence of other human DNA restriction fragments in DNA from human:rodent somatic cell hybrids when the DNA is fragmented with enzymes that cleave mammalian DNA infrequently. This ability to lower the observed human DNA complexity allowed us to develop an approach to order rapidly somatic hybrid cell lines retaining overlapping human genomic domains. The ordering process also generates a relative physical map of the human fragments detected with Alu probe DNA. This process can generate physical mapping information for human genomic domains as large as an entire chromosome (100,000 kb). The strategy is demonstrated by ordering Alu-detected NotI fragments in a panel of mouse:human hybrid cells that span the entire long arm of human chromosome 17.by L. Manuelidis     

A physical and genetic map of Neisseria meningitidis B1940

A physical map of the chromosome of Neisseria meningitidis B1940 has been constructed by one- and two-dimensional pulsed-field gel electrophoresis techniques. Complete macrorestriction maps for the enzymes Nhe I (16 sites), Sgf I (13 sites), Sfi I (11 sites) and I-Ceu I (4 sites), as well as a partial restriction map for the restriction enzyme Spe I (15 of c. 28 sites) could be established. Altogether, 59 restriction sites were mapped on a single circular chromosome of 2.3 Mbp. By restriction endonuclease digestion and Southern hybridization of cloned genetic markers, 39 genetic loci were assigned to this map. Comparison with the metabolic maps of Neisseria gonorrhoeae MS11-N198 and FA1090 revealed a high degree of conservation in the arrangement of gene loci among these two species, although four out of 24 genetic loci are located at different chromosomal positions, indicating several genomic rearrangements.     

Construction of a Not I restriction map of the fission yeast Schizosaccharomyces pombe genome.

Pulsed field gel electrophoresis and large DNA technology were used to construct a Not I restriction map of the entire genome of the fission yeast Schizosaccharomyces pombe. There are 14 detectable Not I sites in S. pombe 972h: 9 sites on chromosome I and 5 sites on chromosome II, while no Not I sites were found on chromosome III. The 17 fragments (including intact chromosome III) generated by Not I digestion were resolved by PFG electrophoresis. These fragments ranged in size from 4.5 kb to approximately 3.5 Mb. Various strategies were applied in determining, efficiently, the order of the fragments on the chromosomes. The genomic size measured by adding all the fragments together is about 14 Mb and the sizes of the three chromosomes are I, 5.7 Mb, II, 4.6 to 4.7 Mb, and III, 3.5 Mb. These are generally somewhat smaller than estimated previously.     

Remi-RFLP Mapping in the Dictyostelium Genome

A set of 147 Dictyostelium discoideum strains was constructed by random integration of a vector containing rare restriction sites. The strains were generated by transformation using restriction enzymemediated integration (REMI) which results in the integration of linear DNA fragments into randomly distributed genomic restriction sites. Restriction fragment length polymorphism (RFLP) was generated in a single genomic site in each strain. These REMI-RFLP strains were used to confirm gene linkages previously supported by two other physical mapping techniques: yeast artificial chromosome (YAC) contig construction, and megabase-scale restriction mapping. New linkages were uncovered when two or more hybridization probes identified the same RFLP fragments. Probes for 100 genes have marked 53% of the RFLPs, representing greater than 22 Mb of the 40 Mb Dictyostelium genome. Alignment of these and other large fragments along each chromosome should lead to a complete physical map of the Dictyostelium genome.     

In-gel DNA radiolabelling and two-dimensional pulsed field gel electrophoresis procedures suitable for fingerprinting and mapping small eukaryotic genomes

A simple method for complete genome radiolabelling is described, involving long-wave UV exposure of agarose-embedded chromosomal DNA and [α-³²P]dCTP incorporation mediated by the Klenow fragment. Experiments on the budding yeast genome show that the labelling procedure can be coupled with two new two-dimensional pulsed field gel electrophoresis (2D-PFGE) protocols of genome analysis: (i) the KARD (karyotype and restriction display)-PFGE which provides a complete view of the fragments resulting from a single restriction of the whole genome and (ii) the DDIC (double digestion of isolated chromosome)-PFGE which is the eukaryotic counterpart of complete/complete 2D-PFGE in bacterial genomics.     

Physical and genetic mapping of the Rhodobacter sphaeroides 2.4.1 genome: presence of two unique circular chromosomes.

A macrorestriction map representing the complete physical map of the Rhodobacter sphaeroides 2.4.1 chromosomes has been constructed by ordering the chromosomal DNA fragments from total genomic DNA digested with the restriction endonucleases AseI, SpeI, DraI, and SnaBI. Junction fragments and multiple restriction endonuclease digestions of the chromosomal DNAs derived from wild-type and various mutant strains, in conjunction with Southern hybridization analysis, have been used to order all of the chromosomal DNA fragments. Our results indicate that R. sphaeroides 2.4.1 carries two different circular chromosomes of 3,046 +/- 95 and 914 +/- 17 kilobases (kb). Both chromosome I (3,046 kb) and chromosome II (914 kb) contain rRNA cistrons. It appears that only a single copy of the rRNA genes is contained on chromosome I (rrnA) and that two copies are present on chromosome II (rrnB, rrnC). Additionally, genes for glyceraldehyde 3-phosphate dehydrogenase (gapB) and delta-aminolevulinic acid synthase (hemT) are found on chromosome II. In each instance, there appears to be a second copy of each of these genes on chromosome I, but the extent of the DNA homology is very low. Genes giving rise to enzymes involved in CO2 fixation and linked to the gene encoding the form I enzyme (i.e., the form I region) are on chromosome I, whereas those genes representing the form II region are on chromosome II. The complete physical and partial genetic maps for each chromosome are presented.     

The unstable region of Streptomyces ambofaciens includes 210 kb terminal inverted repeats flanking the extremities of the linear chromosomal DNA

Physical maps of the chromosomes of three strains of Streptomyces ambofaciens were constructed by ordering Ase I fragments generated from the genomic DNA as a single linear chromosome of about 8 Mb. The physical maps of the three strains were very similar. For strain DSM40697, a Dra I map was obtained by positioning the Dra I sites relative to the Ase I map. Eighteen genetic markers as well as the deletable and amplifiable region were assigned to the Ase I and Dra I fragments in this strain. The resulting genetic map resembled that of Streptomyces coelicolor A3(2). The twoterminal Ase I fragments exhibited retarded pulsed-field gel electrophoresis mobility, demonstrating that proteins are covalently bound at this position. A restriction map of this region was made using four additional endonucleases. Repeated sequences present at both ends of the chromosome were mapped as long terminal inverted repeats stretching over 210 kb. This corresponds to the longest terminal inverted repeats so far characterized. The deletable region of S. ambofaciens was localized at the chromosomal extremities.     

Bacterial genome mapping by two-dimensional pulsed-field gel electrophoresis (2D-PFGE)

Macrorestriction mapping is often the first step toward a thorough physical and genetic characterization of a bacterial genome. The problem of deducing the order of partially or completely digested macrorestriction fragments to yield a physical genome map may readily be solved by applying twodimensional pulsed-field gel electrophoresis (2D-PFGE) techniques. These powerful methods are quick and technically easy to perform; specifically, they are independent of DNA probes and should therefore be applicable to any bacterial species irrespective of its prior genetic characterization. In this article, detailed step-by-step protocols are given to set up, run, and evaluate 2D pulsed-field gels. Two basic methods are described: partial/complete 2D gels of one restriction enzyme and complete/complete 2D gels of two different restriction enzymes. Other topics include preparation of bacterial genomic DNA, screening for suitable rare-cutting restriction enzymes and determination of optimal running conditions. Accompanied by many notes, these protocols are meant to offer the novice a sound and rapid access to these important methods.     

A physical and genetic map of theCorynebacterium glutamicum ATCC 13032 chromosome

A combined physical and genetic map of theCorynebacterium glutamicum ATCC 13032 chromosome was constructed using pulsed-field gel electrophoresis (PFGE) and hybridizations with cloned gene probes. Total genomic DNA was digested with the meganucleasesSwaI (5′-ATTTAAAT-3′),PacI (5′-TTAATTAA-3′), andPmeI (5′-GTTTAAAC-3′) yielding 26, 27, and 23 fragments, respectively. The chromosomal restriction fragments were then separated by PFGE. By summing up the lengths of the fragments generated with each of the three enzymes, a genome size of 3082 +/- 20 kb was determined. To identify adjacentSwaI fragments, a genomic cosmid library ofC. glutamicum was screened for chromosomal inserts containingSwaI sites. Southern blots of the PFGE gels were hybridized with these linking clones to connect theSwaI fragments in their natural order. By this method, about 90% of the genome could be ordered into three contigs. Two of the remaining gaps were closed by cross-hybridization of blottedSwaI digests using as probesPacI andPmeI fragments isolated from PFGE gels. The last gap in the chromosomal map was closed by hybridization experiments using partialSwaI digestions, thereby proving the circularity of the chromosome. By hybridization of gene probes toSwaI fragments separated by PFGE about 30 genes, including rRNA operons, IS element and transposon insertions were localized on the physical map.     

Tandem repeats within the inverted terminal repetition of vaccinia virus DNA

A tandemly repeated sequence within the genome of vaccinia virus is cut to fragments of approximately 70 bp by Hinf I, Taq I or Mbo II. The 70 bp repetition was localized within the much larger (10,300 bp) inverted terminal repetition by restriction analysis of cloned DNA fragments and by hybridization of the purified 70 bp repeat to vaccinia virus DNA restriction fragments. The molar abundance of the 70 bp fragment corresponds to a 30 fold repetition at each end of the genome. The repeating restriction endonuclease sites were mapped by agarose gel electrophoresis of partial Hinf I digests of the terminally labeled cloned DNA fragment. The first of 13 repetitive Hinf I sites occurred approximately 150 bp from the end of the cloned DNA. After an intervening sequence of approximately 435 bp, a second series of 17 repetitive Hinf I sites occurred. The DNA between the two blocks of repetitions has a unique sequence containing single Dde I, Alu I and Sau 3A sites. Tandem repeats within the inverted terminal repetition could serve to accelerate self-annealing of single strands of DNA to form circular structures during replication.     

Physical map of the Myxococcus xanthus chromosome.

The genome of Myxococcus xanthus, which is 9,454 kbp, is one of the largest bacterial genomes. The organization of the DNA and the distribution of genes encoding social and developmental behaviors were examined by using pulsed field gel electrophoresis. Intact genomic DNA was digested with AseI into 16 restriction fragments, which were separated by contour-clamped homogeneous electric field electrophoresis, purified, and radiolabeled. Each AseI fragment was hybridized to SpeI-digested DNA and to an M. xanthus genomic library contained in yeast artificial chromosomes. Some SpeI restriction fragments and yeast artificial chromosome clones contained AseI sites and hybridized with two different AseI restriction fragments, providing evidence for the juxtaposition of these AseI restriction fragments in the chromosome. The deduced AseI physical map is circular, suggesting that this bacterium contains a single, circular chromosome. Transposable elements shown by transduction to be in or near genes of interest were located on specific AseI restriction fragments by restriction analysis and Southern hybridization. Most AseI restriction fragments contained genes involved in social and developmental behaviors.     

Physical and genetic map of Streptococcus thermophilus A054.

The three restriction endonucleases SfiI, BssHII, and SmaI were found to generate fragments with suitable size distributions for mapping the genome of Streptococcus thermophilus A054. A total of 5, 8, and 24 fragments were produced with SfiI, BssHII, and SmaI, respectively. An average genome size of 1,824 kb was determined by summing the total fragment sizes obtained by digestions with these three enzymes. Partial and multiple digestions of genomic DNA in conjunction with Southern hybridization were used to map SfiI, BssHII, and SmaI fragments. All restriction fragments were arranged in a unique circular chromosome. Southern hybridization analysis with specific probes allowed 23 genetic markers to be located on the restriction map. Among them, six rrn loci were precisely located. The area of the chromosome containing the ribosomal operons was further detailed by mapping some of the ApaI and SgrAI sites. Comparison of macrorestriction patterns from three clones derived from strain A054 revealed two variable regions in the chromosome. One was associated with the tandem rrnD and rrnE loci, and the other was mapped in the region of the lactose operon.     

Genome analysis of Pseudomonas aeruginosa by field inversion gel electrophoresis

Abstract The genome of Pseudomonas aeruginosa was analysed by digestion with rare-cutting restriction endonucleases and subsequent field inversion gel electrophoresis (FIGE). P. aeruginosa strain PAO and the 17 IATS strains were investigated. Each strain displayed a unique pattern of restriction fragments. Digestion with Dra I and Ssp I yielded, respectively 7–11 and 2–5 fragments of more than 130 kb in size, indicating the non-random occurrence of AT-rich sequences in the P. aeruginosa genome. The genome size of P. aeruginosa PAO was estimated to be (2.2 ± 0.3) × 10⁶ bp. The applications of DNA fingerprinting for gene cloning, construction of a physical chromosome map, and epidemiological studies, are discussed.     

Global methylation screening in the Arabidopsis thaliana and Mus musculus genome: applications of virtual image restriction landmark genomic scanning (Vi-RLGS)

Understanding the role of ‘epigenetic’ changes such as DNA methylation and chromatin remodeling has now become critical in understanding many biological processes. In order to delineate the global methylation pattern in a given genomic DNA, computer software has been developed to create a virtual image of restriction landmark genomic scanning (Vi-RLGS). When using a methylation- sensitive enzyme such as NotI as the restriction landmark, the comparison between real and in silico RLGS profiles of the genome provides a methylation map of genomic NotI sites. A methylation map of the Arabidopsis genome was created that could be confirmed by a methylation-sensitive PCR assay. The method has also been applied to the mouse genome. Although a complete methylation map has not been completed, a region of methylation difference between two tissues has been tested and confirmed by bisulfite sequencing. Vi-RLGS in conjunction with real RLGS will make it possible to develop a more complete map of genomic sites that are methylated or demethylated as a consequence of normal or abnormal development.     

Construction of an EcoRI restriction map of Mycoplasma pneumoniae and localization of selected genes.

A restriction map of the genome of Mycoplasma pneumoniae, a small human pathogenic bacterium, was constructed by means of an ordered cosmid library which spans the complete bacterial chromosome. The positions of 143 endonuclease EcoRI restriction fragments were determined and aligned with the physical map. In addition, restriction sites for the rare-cutting enzymes XhoI (25 sites), ApaI (13 sites), NotI (2 sites), and SfiI (2 sites) were included. The resulting map consists of 185 restriction sites, has a mean resolution of 4.4 kbp, and predicts a genome size of 809 kbp. In addition, several genes were identified and mapped to their respective genomic EcoRI restriction fragments.     

Physical map of the Streptomyces lividans 66 genome and comparison with that of the related strain Streptomyces coelicolor A3(2).

A physical map of the chromosome of Streptomyces lividans 66 ZX7 was constructed by ordering the macrorestriction fragments generated from the genomic DNA with the restriction enzymes AseI and DraI. AseI and DraI linking cosmids (i.e., recombinant cosmids including either AseI or DraI sites) were isolated from a gene bank and used as hybridization probes against Southern transfers of pulsed-field gel electrophoresis (PFGE) restriction patterns. The DraI sites were precisely mapped by PFGE analyses of AseI-DraI double digests and hybridization with the AseI junctions. The 16 AseI and 7 DraI fragments were aligned as a single chromosome of about 8,000 kb. The data supported the interpretation that the chromosome is a linear structure. The related strain Streptomyces coelicolor A3(2) M145, recently mapped by H. Kieser, T. Kieser, and D. A. Hopwood (J. Bacteriol. 174:5496-5507, 1992), was compared with S. lividans at the level of the genomic structure by hybridizing the linking cosmids to Southern transfers of PFGE patterns. In spite of little apparent similarity in their restriction patterns, the comparison of the physical maps revealed a common structure with an identical ordering of the cosmid sequences. This conservation of the map order was further confirmed by assigning genetic markers (i.e., cloned genes and DNA elements relevant to the unstable region) to the AseI fragments.     

Progress towards construction of a total restriction fragment map of a human chromosome.

We present an approach to the construction of an overlapping restriction fragment map of a single human chromosome. A genomic cosmid library genome was constructed from a mouse-human hybrid cell line containing chromosome 17 as its only human genetic component. Cosmids containing human inserts were isolated by hybridisation to a human Alu sequence. DNAs from ninety-six randomly chosen cosmids were digested with either EcoRI or HindIII, end-labelled with 35S-dATP and analysed using agarose gel electrophoresis. Comparison of the restriction fragment patterns revealed two pairs of overlapping clones, that were confirmed by cross-hybridization of the overlapping fragments. The two pairs of cosmids both mapped to human chromosome 17, as shown by hybridization to a panel of somatic cell hybrids. These data demonstrate that the generation of an overlapping cosmid map along a human chromosome is feasible, representing an intermediate step towards the complete sequencing of a human chromosome.