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.     

Physical and genetic mapping of the genomes of five Mycoplasma hominis strains by pulsed-field gel electrophoresis.

We present the complete maps of five Mycoplasma hominis genomes, including a detailed restriction map and the locations of a number of genetic loci. The restriction fragments were resolved by field inversion gel electrophoresis or by the contour-clamped homogeneous-electric-field system of pulsed-field gel electrophoresis. All the ApaI, SmaI, BamHI, XhoI, and SalI restriction sites (total of 21 to 33 sites in each strain) were placed on the physical map, yielding an average resolution of 26 kb. The maps were constructed using three different approaches: (i) size determination of DNA fragments partially or completely cleaved with one or two restriction enzymes, (ii) hybridization analysis with purified restriction fragments and specific probes, and (iii) use of linking clones. A genetic map was constructed by hybridization with gene-specific probes for rpoA, rpoC, rrn, tuf, gyrB, hup, ftsY, the unc operon, the genes for two M. hominis-specific antigenic membrane proteins, and one gene encoding a protein with some homology to Escherichia coli alanyl-tRNA synthetase. The positions of mapped loci were partially conserved in the five strains except in one strain in which a 300-kb fragment was inverted. The numbers and order of mapped restriction sites were only partly conserved, and this conservation was restricted to certain regions. The gene order was compared with the gene order established for other bacteria and was found to be identical to that of the phylogenetically related Clostridium perfringens. The genome size of the M. hominis strains varied from 704 to 825 kb.     

The Use of Restriction Fragment Length Polymorphisms and DNA Duplications to Study the Organization of the Actin Multigene Family in DICTYOSTELIUM DISCOIDEUM

The techniques of restriction fragment length polymorphism analysis and examination of gene copy number in duplication-bearing Dictyostelium discoideum strains have been used to map four actin genes of the wild-type strain NC4 to specific linkage groups. In part, this was accomplished by identification of restriction fragments corresponding to particular cloned actin genes using gene-specific probes from unique sequence 5' and 3' untranslated regions. Cloned gene Actin 8 (designation act-8) maps to linkage group I; Actins 12 (act-12) and M6 (actM6) to linkage group II. An uncloned gene (act-100) also maps to linkage group II in the same region as actM6, as defined by a chromosomal duplication. From analysis of other wild isolates of D. discoideum, it was determined that in these isolates at least two actin genes map to linkage group I and at least four map to linkage group II. These results demonstrate the utility of molecular techniques in genetic analysis of Dictyostelium, particularly for developmentally regulated genes that have been cloned but that have no identified mutant phenotypes.     

HindII, HindIII, and HpaI restriction fragment maps of bacteriophage lambda DNA

The site-specific restriction endonucleases isolated from Hemophilus influenzae strains Rc (HincII) and Rd (HindII + III), and Hemophilus parainfluenzae (HpaI) were used to digest bacteriophage lambda DNA into 34, 40, and 15 specific fragments, respectively. The sites cleaved by each of these enzymes were localized on the lambda physical map and the fragments resulting from these cleavages were electrophoretically identified on gels by (1) analysis of the digestion profiles of deletion and transducing derivatives of lambda; and (2) digesting individual fragments produced by one restriction endonuclease with another restriction endonuclease. This paper presents the HindII, HindIII, and HpaI restriction fragment maps for the entire lambda genome, and the data used to derive these maps for the region of the lambda genome between the attachment site (at 57.3% lambda) and the right vegetative end (100% lambda). The data for mapping the left arm of lambda may be found in the accompanying paper (Robinson and Landy, 1977).     

Cloning and linkage analysis of Neisseria gonorrhoeae DNA methyltransferases.

We have cloned DNA methyltransferases (MTases) from various strains of Neisseria gonorrhoeae. Each of these clones represents a single specificity, indicating that the multiple gonococcal MTase specificities are encoded by monospecific MTases. The DNAs of five strains (FA5100, F62, MS11, Pgh3-2, and WR302) were digested with NheI, SpeI, or NheI plus SpeI and subjected to pulsed-field gel electrophoresis. The DNA MTase clones were used to probe Southern blots of these pulsed-field gels to determine whether the MTase genes are linked and whether there are strain-to-strain differences. The results indicate that none of these genes are closely linked, but variable hybridization patterns indicate that there exist restriction fragment length polymorphisms between the strains tested. Most of the chromosomal regions containing these restriction fragment length polymorphisms are clustered in regions containing gonococcal genes known or suspected to antigenically vary via genetic recombination.     

A physical genome map of Pseudomonas aeruginosa PAO.

A complete macrorestriction map of the 5.9 Mb genome of Pseudomonas aeruginosa PAO (DSM 1707) was constructed by the combination of various one- and two-dimensional pulsed field gel electrophoresis techniques. A total of 51 restriction sites (36 SpeI sites, 15 DpnI sites) were placed on the physical map yielding an average resolution of 110 kb. Several genes encoding virulence factors and enzymes of metabolic pathways were located on the anonymous map by Southern hybridization. Distances between the gene loci were similar on the genetic and physical maps, suggesting an even distribution of genome mobility throughout the bacterial chromosome. The four rRNA operons were organized in pairs of inverted repeats. The two-dimensional macro-restriction techniques described herein are generally applicable for the genome mapping of any prokaryote and lower eukaryote which yields resolvable fragment patterns on two-dimensional pulsed field gels.     

The complete AvrII restriction map of the Escherichia coli genome and comparisons of several laboratory strains.

The complete 13 site AvrII restriction map of the genome of E coli strain MG1655 is presented and compared with several other E. coli strains. The map was determined primarily by isolating individual AvrII fragments from pulsed-field gels, and hybridizing these large probes to a battery of mapped E. coli clones in lambda vectors. AvrII restriction patterns for eight other laboratory strains were determined and maps for seven of them deduced from the gel and comparisons between the strain genotypes, the MG1655 map, and AvrII sites in E. coli sequences taken from Genbank.     

High-resolution alignment of a 1-megabase-long genome region of three strains of Rhodobacter capsulatus.

A detailed restriction map of the genome of Rhodobacter capsulatus SB1003 was constructed recently by using an ordered set of overlapping cosmids. Pulsed-field gel electrophoresis-generated restriction patterns of the chromosomes of 14 other R. capsulatus strains were compared. Two of them, St. Louis and 2.3.1, were chosen for high-resolution alignment of their genomes with that of SB1003. A 1-Mb segment of the R. capsulatus SB1003 cosmid set was used as a source of ordered probes to group cosmids from the other strains. Selected cosmids were linked into one 800-kb contig and two smaller contigs of 100 kb each. EcoRV and BamHI restriction maps of the newly ordered cosmids were constructed by using lambda terminase. Long-range gene order in the new strains was mainly conserved for the regions studied. However, one large genome rearrangement inverted a 470-kb DNA fragment of the St. Louis strain between the rrnA and rrnB operons. A 50-kb deletion covering three SB1003 probes was found in strain 2.3.1 near rrnB. Conservation of about 50% of the positions of restriction sites in all these strains and nearly 80% for the pair 2.3.1- St. Louis made it possible to produce high-resolution alignment of the contiguous 800-kb genome segment. Ten deletions of 2 to 27 kb, one 30-kb inversion, and three translocations were found in this region. Strong clustering of the positions of polymorphic restriction sites was observed. For a 50-kb size interval, two patterns of the distribution of restriction sites were found, one with about 90% and the other with 5 to 30% conservation of sites. This structure may be explained by independent acquisition of these divergent regions from other Rhodobacter strains.     

Physical map of the Salmonella typhimurium histidine transport operon: correlation with the genetic map.

A detailed restriction map of a 12.4-kilobase EcoRI fragment of Salmonella typhimurium deoxyribonucleic acid (DNA) containing the entire histidine transport operon and the argT gene is presented. Subclones of specific regions of the transport operon of S. typhimurium were constructed in plasmid vectors. An accurate correlation between the restriction map and the location of genetically defined deletions was obtained by hybridizing restriction digests of chromosomal DNA from strains carrying each deletion with cloned transport operon DNA as a probe. These data were used to position the histidine transport genes on the cloned 12.4-kilobase fragment of DNA.     

NotI genomic cleavage map of Escherichia coli K-12 strain MG1655.

Several approaches were used to construct a complete NotI restriction enzyme cleavage map of the genome of Escherichia coli MG1655. The approaches included use of transposable element insertions that created auxotrophic mutations and introduced a NotI site into the genome, hybridization of NotI fragments to the ordered lambda library constructed by Kohara et al. (BioTechniques 10:474-477, 1991), Southern blotting of NotI digests with cloned genes as probes, and analysis of the known E. coli DNA sequence for NotI sites. In all, 22 NotI cleavage sites were mapped along with 26 transposon insertions. These sites were localized to clones in the lambda library and, when possible, sequenced genes. The map was compared with that of strain EMG2, a wild-type E. coli K-12 strain, and several differences were found, including a region of about 600 kb with an altered restriction pattern and an additional fragment in MG1655. Comparison of MG1655 with other strains revealed minor differences but indicated that this map was representative of that for many commonly used E. coli K-12 strains.     

Mapping genes within a YAC by computer-assisted interpretation of partial restriction digestions.

Partial restriction digestion is used to map restriction sites and the location of genes within yeast artificial chromosomes (YACs). Locus-specific probes are hybridised to the partially digested YAC DNA and the fragments to which they hybridise are compared with the pattern of partial digestion products that include each map region. A least squares criterion is presented which allows for error in fragment length determination. This rapidly defines the most likely location of a marker within the restriction map and permits the combination of results from digestions with different restriction enzymes. Approximate confidence intervals may be assigned to gene locations, and tests of goodness-of-fit of the data may be performed. Since the number of erroneously matched fragments increases in proportion to the square of the number of sites, denser maps are not necessarily more informative. Simulations indicate that the optimal number of internal restriction sites given typical experimental error (1% of YAC length) is about five sites; the associated broad support interval (on average one third of YAC length) may be reduced by combining results from different enzyme digestions. Application of a computer implementation of this model to experimental data showed that the model fitted well, and estimates of location were found to be consistent with other evidence.     

Identification and differentiation of Heterotardigrada and Eutardigrada species by riboprinting

In the last decades, the number of known tardigrade species has considerably increased to more than 960 species with new ones being discovered every year. However, the study of tardigrade species presents a general problem which is frequently encountered during the work with invertebrates: small size and remarkable degrees of phenotypic plasticity may sometimes not permit a definite identification of the species. In this investigation we have used riboprinting, a tool to study rDNA sequence variation, in order to distinguish tardigrade species from each other. The method combines a restriction site variation approach of ribotyping with amplified DNAs. In eight investigated species of heterotardigrades and eutardigrades we have amplified the genes for the small subunit ribosomal RNA (SSU; 18S) and subsequently sequenced the genes. Virtual riboprints were used for identification of restriction sites from ten already published 18S rDNA sequences and seven new 18S rDNA sequences. On the basis of the obtained sequences, diagnostic restriction fragment patterns can be predicted with only 11 restriction enzymes. The virtual digestion confirmed the obtained restriction fragment patterns and restriction sites of all amplified and digested tardigrade DNAs. We show that the variation in positions and number of restriction sites obtained by standard restriction fragment analysis on agarose gels can be used successfully for taxonomic identification at different taxonomic levels. The simple restriction fragment analysis provides a fast and convenient method of molecular barcoding for species identification in tardigrades.     

Size and physical map of the chromosome of Haemophilus influenzae.

A variation of pulse-field electrophoresis, field-inversion gel electrophoresis, was used to determine the size and physical map of the chromosome of Haemophilus influenzae. The DNA of H. influenzae had a low G + C content (39%) and no restriction sites for the enzymes NotI or SfiI. However, a number of restriction enzymes (SmaI, ApaI, NaeI, and SacII) that recognized 6-base-pair sequences containing only G and C nucleotides were found to generate a reasonable number of DNA fragments that were separable in agarose gels by field-inversion gel electrophoresis. The sizes of the DNA fragments were calibrated with a lambda DNA ladder and lambda DNA restriction fragments. The sum of fragment sizes obtained with restriction digests yielded a value for the chromosome of 1,980 kilobase pairs. Hybridization of a labeled fragment with two or more fragments from a digest with a different restriction enzyme provided the information needed to construct a circular map of the H. influenzae chromosome.     

Physical maps of the genomes of three Bacillus cereus strains.

NotI restriction maps of the chromosomes from Bacillus cereus ATCC 10876, ATCC 11778, and the B. cereus type strain ATCC 14579 have been established and compared with the previously established map of B. cereus ATCC 10987. Between 10 and 14 NotI fragments were observed, ranging from 15 to 1,300 kb, in digests of DNA from the various strains. The sizes of the genomes varied between 5.4 and 6.3 Mb. The maps were constructed by hybridization of 42 random probes, prepared from B. cereus ATCC 10987 libraries, to fragments from partial and complete NotI digests, separated by pulsed-field gel electrophoresis. Nine probes were specific for ATCC 10987 only. Probes for five B. subtilis and five B. cereus genes were also used. The NotI restriction fragment patterns of the four strains were strikingly different.     

The molecular organization of the H-2K region of two t-haplotypes: implications for the evolution of genetic diversity.

The genetic diversity between the t12 and tw5 haplotype chromosomes was studied by analyzing the molecular organization of the H-2K region. Twenty-one cosmid clones spanning over 150 kb of the H-2K region of both t-haplotypes were defined, and high resolution restriction maps were determined. Detailed comparison of the t12 and tw5 restriction maps revealed the following. (i) The H-2K regions of both t-haplotypes retain a very similar molecular organization to that reported for B10, BALB/c and AKR. The nucleotide sequence diversity estimated from restriction site polymorphism is 0.68% between the t12 and tw5 haplotypes; these two t-haplotypes are no more similar to one another than BALB/c is to AKR. (ii) Genetic recombination is strongly implicated in generating H-2 polymorphism. (iii) Genetic polymorphisms, defined as small restriction fragment size differences, are observed at multiple sites along the H-2K region. An Alu-like B2 sequence and BAM5-R homologous sequence were identified as the inserted/deleted DNA segments of two of these sites, suggesting that insertion/deletion of mobile elements is a general mechanism for generating genetic diversity.     

Mapping of sequenced genes (700 kbp) in the restriction map of the Escherichia coli chromosome

This paper describes software (written in Pascal and running on Macintosh computers) allowing localization of unknown DNA fragments from the Escherichia coli chromosome on the restriction map established by Kohara et al. (1987). The program identifies the segment's map position using a restriction pattern analysis obtained with all, or some, of the eight enzymes used by Kohara et al. (1987). Therefore, the sequenced genes available in the EMBL library may be localized on the E. coli chromosome restriction map. This allowed correction of the map (mainly by introducing missing sites in the published maps) at the corresponding positions. Analysis of the data indicates that there is only a very low level of polymorphism, at the nucleotide level, between the E. coli K12 strains used by the various laboratories involved in DNA sequencing. The program is versatile enough to be used with other genomes.     

Physical mapping of genes to specific chromosomes in Dictyostelium discoideum.

Cloned genes were used to probe a highly redundant library of large cloned fragments of the Dictyostelium discoideum genome carried in yeast artificial chromosomes (YACs). Each gene recognized several independent YAC clones, thereby grouping them into a contig. Individual YACs were arranged within the contig by positioning genes relative to rare restriction sites and the YAC ends. Genes that had been previously assigned to one of the six linkage groups by parasexual genetics were used to establish physically mapped regions on specific chromosomes. Previously unmapped genes were assigned to specific chromosomes when they recognized members of a mapped contig. Linkage was confirmed by congruence of large-scale restriction maps centered on either the previously mapped or the newly mapped genes. At present, the chromosome-assigned map segments comprise approximately 50% of the genome. About half of each map segment is covered by overlapping YACs.     

A consensus linkage map for swine chromosome 7

The First International Workshop on Swine Chromosome 7 (SSC7) was held in Minnesuing, Wisconsin, USA on 21–24 September 1995. The objective was to develop a comprehensive linkage map for porcine chromosome 7 by combining genotypic data from four swine reference populations. Contributions of genotypic data were made from the US Meat Animal Research Center, the University of Minnesota, the PiGMaP consortium and the Scandinavian consortium. Primers for selected sequence tagged site markers, to be genotyped across the reference populations, were exchanged to integrate individual maps of SSC7. Eighty-six loci were genotyped; these loci represented microsatellite, minisatellite, single-strand conformation polymorphism, restriction fragment length polymorphism, erythrocyte antigen and protein polymorphisms. Eighteen genes were mapped, including 12 markers within class I, class II and class III regions (four markers in each class) of the swine major histocompatibility complex. Forty-two markers were either genotyped on more than one population or were included in a haplotype system and used to develop skeletal linkage maps that spanned 147·6, 212·7 and 179·5 cM for the male, female and sex-average maps, respectively. A comprehensive linkage map was developed incorporating those markers with more than 30 informative meioses. The comprehensive map was slightly longer than the skeletal map, at 153·3, 215·3 and 183·8 cM, respectively, with only three intervals greater than 10 cM. These results significantly improve the genetic resolution of the porcine chromosome 7 map and represent an accurate approach for the merging of genetic maps produced in different reference populations.     

Achlya mitochondrial DNA: gene localization and analysis of inverted repeats

Summary Mitochondrial DNA from four strains of the oomycete Achlya has been compared and nine gene loci mapped, including that of the ribosomal protein gene, var1. Examination of the restriction enzyme site maps showed the presence of four insertions relative to a map common to all four strains. All the insertions were found in close proximity to genic regions. The four strains also cotained the inverted repeat first observed in A. ambisexualis (Hudspeth et al. 1983), allowing an examination by analysis of retained restriction sites of the evolutionary stability of repeated DNA sequences relative to single copy sequences. Although the inverted repeat is significantly more stable than single copy sequences, more detailed analysis indicated that this stability is limited to the portion encoding the ribosomal RNA genes. Thus, the apparent evolutionary stability of the repeat does not appear to derive from the inverted repeat structure per se.Abbreviations ATPase 6, 9 genes for ATPase subunits 6 and 9 - COI, II, III genes for cytochrome oxidase subunits 1, 2, and 3 - COB gene for apocytochrome b - L-, S-RNA genes for the mitochondrial large and small ribosomal RNAs - mtDNA mitochondrial DNA - var1 gene for the S. cerevisiae mitochondrially, encoded ribosomal protein - m.u. map units - bp base pairs - kb kilobase pairs