SfiI genomic cleavage map of Escherichia coli K-12 strain MG1655

Temperate bacteriophages affect pulsed-field gel electrophoresis patterns of Campylobacter jejuni

The recently sequenced genome of Campylobacter jejuni RM1221 revealed the presence of three integrated bacteriophage-like elements. In this study, genes from the first element, a Mu-like bacteriophage, were amplified by PCR and used to probe pulsed-field gels of clinical C. jejuni strains obtained from a waterborne outbreak (Ontario, Canada, 2000). These highly similar strains differed only by their pulsed-field gel electrophoresis (PFGE) patterns due to an apparent insertion or deletion of a 40-kb fragment. Bacteriophage probes hybridized to these different bands in Southern blot analysis, indicating that homologues of bacteriophage genes were present in the outbreak strains. Investigation of the bacteriophage insertion sites in these isolates suggested that bacteriophage acquisition, loss, or transposition was responsible for the PFGE pattern variation. The bacteriophage gene sequences were similar, but not identical, in the outbreak strains and RM1221, indicating that differences may exist between the bacteriophages.

Pulsed field gel electrophoresis to rapidly detect the presence of IncJ conjugative transposon-like elements

AIMS

To develop a screening method to detect the presence of the IncJ group of integrating conjugative transposon-like elements upon transfer to Escherichia coli.

METHODS AND RESULTS

The unique insertion site of known IncJ elements, the prfC gene, is located in a region of the E. coli chromosome between 98.5 and 100 min on the E. coli genetic map. Using pulsed field gel electrophoresis and the rare cutting restriction enzymes SfiI and XbaI insertions of IncJ elements and an estimate of their size could be determined physically.

CONCLUSIONS

This method allows initial screening of putative IncJ conjugative transposon-like elements by physical determination of their integration.

SIGNIFICANCE AND IMPACT OF THE STUDY

IncJ-like elements, which appear to be highly homologous to the prototype IncJ element R391, have been found associated with recent epidemic outbreaks of cholera in a number of locations worldwide. Because of their integrative biology this method provides the first initial screening method to physically determine their presence upon transfer to E. coli.

Definition of the Escherichia coli MC4100 genome by use of a DNA array

We have used an Escherichia coli K-12 whole-genome array based on the DNA sequence of strain MG1655 as a tool to identify deletions in another E. coli K-12 strain, MC4100, by probing the array with labeled chromosomal DNA. Despite the continued widespread use of MC4100 as an experimental system, the specific genetic relationship of this strain to the sequenced K-12 derivative MG1655 has not been resolved. MC4100 was found to contain four deletions, ranging from 1 to 97 kb in size. The exact nature of three of the deletions was previously unresolved, and the fourth deletion was altogether unknown.

Tn7 transposes proximal to DNA double-strand breaks and into regions where chromosomal DNA replication terminates

We report that the bacterial transposon Tn7 can preferentially transpose into regions where chromosomal DNA replication terminates. DNA double-strand breaks are associated with the termination of chromosomal replication; therefore, we directly tested the effect of DNA breaks on Tn7 transposition. When DNA double-strand breaks are induced at specific sites in the chromosome, Tn7 transposition is stimulated and insertions are directed proximal to the induced break. The targeting preference for the terminus of replication and DNA double-strand breaks is dependent on the Tn7-encoded protein TnsE. The results presented in this study could also explain the previous observation that Tn7 is attracted to events associated with conjugal DNA replication during plasmid DNA transfer.

CTnscr94, a conjugative transposon found in enterobacteria

Conjugational transposons are important for horizontal gene transfer in gram-positive and gram-negative bacteria, but have not been reported yet for enteric bacteria. Salmonella senftenberg 5494-57 has previously been shown to transfer by conjugation genes for a sucrose fermentation pathway which were located on a DNA element called scr-94. We report here that the corresponding scr genes for a phosphoenolpyruvate-dependent sucrose:phosphotransferase system and a sucrose metabolic pathway are located on a large (ca. 100 kb) conjugative transposon renamed CTnscr94. The self-transmissible element integrates at two specific attachment sites in a RecA-independent way into the chromosome of Escherichia coli K-12 strains. One site was identified within pheV, the structural gene for a tRNA(Phe). Sequencing of both ends of CTnscr94 revealed the presence of the 3' part of pheV on one end such that after integration of the element, a complete pheV gene is retained. CTnscr94 represents, to our knowledge, the first conjugational transposon found in enteric bacteria.

Nonadaptive mutations occur on the F' episome during adaptive mutation conditions in Escherichia coli

One of the most studied examples of adaptive mutation is a strain of Escherichia coli, FC40, that cannot utilize lactose (Lac-) but that readily reverts to lactose utilization (Lac+) when lactose is its sole carbon source. Adaptive reversion to Lac+ occurs at a high rate when the Lac- allele is on an F' episome and conjugal functions are expressed. It was previously shown that nonselected mutations on the chromosome did not appear in the Lac- population while episomal Lac+ mutations accumulated, but it remained possible that nonselected mutations might occur on the episome. To investigate this possibility, a second mutational target was created on the Lac- episome by mutation of a Tn1O element, which encodes tetracycline resistance (Tetr), to tetracycline sensitivity (Tets). Reversion rates to Tetr during normal growth and during lactose selection were measured. The results show that nonselected Tetr mutations do accumulate in Lac- cells when those cells are under selection to become Lac+. Thus, reversion to Lac+ in FC40 does not appear to be adaptive in the narrow sense of the word. In addition, the results suggest that during lactose selection, both Lac+ and Tetr mutations are created or preserved by the same recombination-dependent mechanism.

Heterogeneity of genome sizes among natural isolates of Escherichia coli

Comparisons of the genetic maps of Escherichia coli K-12 and Salmonella typhimurium LT2 suggest that the size and organization of bacterial chromosomes are highly conserved. Employing pulsed-field gel electrophoresis, we have estimated the extent of variation in genome size among 14 natural isolates of E. coli. The BlnI and NotI restriction fragment patterns were highly variable among isolates, and genome sizes ranged from 4,660 to 5,300 kb, which is several hundred kilobases larger than the variation detected between enteric species. Genome size differences increase with the evolutionary genetic distance between lineages of E. coli, and there are differences in genome size among the major subgroups of E. coli. In general, the genomes of natural isolates are larger than those of laboratory strains, largely because of the fact that laboratory strains were derived from the subgroup of E. coli with the smallest genomes.

Comparative genome mapping with mobile physical map landmarks

We describe a method for comparative macrorestriction mapping of the chromosomes of Escherichia coli strains. In this method, a series of physically tagged E. coli K-12 alleles serve as mobile landmarks for mapping DNAs from other strains. This technique revealed evidence of strain-specific chromosomal additions or deletions in a pathogenic isolate and can be applied to most strains, yielding information on genealogy as well as virulence. In theory, the same strategy can be used to map and compare genomic DNAs from a wide variety of species.

Non-cloning amplification of specific DNA fragments from whole genomic DNA digests using DNA 'indexers'

A highly systematic, non-cloning method of distinguishing and isolating every fragment in a class-IIS or interrupted palindrome restriction digest has been developed in our laboratory. These enzymes produce informative, non-identical cohesive ends which can be selectively modified by ligation to individual synthetic oligodeoxyribonucleotides with the corresponding complementary ends. In this way, polymerase chain reaction and sequencing primer sites and labels can be introduced specifically into a single fragment in a total genomic digest. Known and unknown fragments from genomes of the complexity of Escherichia coli can be isolated directly in sequencable form without the necessity of synthesizing unique primers. Human DNA has also been assessed in this way. Problems intrinsic to cloning (selective fragment loss, mutation and sequence rearrangement) are avoided. Systematic characterization of DNA fragments by their cohesive ends and length provides tremendous power and flexibility for analysis of any DNA molecule without specific clones, probes or libraries. We report proof of principle of this remarkable system and indicate potential applications in DNA sequence tagged site and restriction mapping, sequencing, restriction-fragment-length polymorphism analysis and DNA diagnostics.

Bacterial genomics

During the last decade, great advances have been made in the study of bacterial genomes which is perhaps better described by the term bacterial genomics. The application of powerful techniques, such as pulsed-field gel electrophoresis of macro-restriction fragments of genomic DNA, has freed the characterisation of the chromosomes of many bacteria from the constraints imposed by classical genetic analysis. It is now possible to analyse the genome of virtually every microorganism by direct molecular methods and to construct detailed physical and gene maps. In this review, the various practical approaches are compared and contrasted, and some of the emerging themes of bacterial genomics, such as the size, shape, number and organisation of chromosomes are discussed.

Comparison and genomic sizing of Escherichia coli O157:H7 isolates by pulsed-field gel electrophoresis

Genomic DNAs of Escherichia coli O157:H7 strains isolated from patients and food samples were analyzed by pulsed-field gel electrophoresis. The rare-cutting endonucleases SfiI and XbaI generated 6 and 10 distinct genomic profiles, respectively, for the 22 strains analyzed, indicating that this technique may find application for epidemiologic studies. Summation of XbaI fragments from five E. coli O157:H7 strains estimated the genomic length at ca. 4.7 Mb.

The XbaI-BlnI-CeuI genomic cleavage map of Salmonella typhimurium LT2 determined by double digestion, end labelling, and pulsed-field gel electrophoresis

Endonuclease digestion of the 4,800-kb chromosome of Salmonella typhimurium LT2 yielded 24 XbaI fragments, 12 BlnI fragments, and 7 CeuI fragments, which were separated by pulsed-field gel electrophoresis. The 90-kb plasmid pSLT has one XbaI site and one BlnI site. The locations of the fragments around the circular chromosome and of the digestion sites of the different endonucleases with respect to each other were determined by excision of agarose blocks containing fragments from single digestion, redigestion with a second enzyme, end labelling with 32P by using T7 DNA polymerase, reelectrophoresis, and autoradiography. Forty-three cleavage sites were established on the chromosome, and the fragments and cleavage sites were designated in alphabetical order and numerical order, respectively, around the chromosome. One hundred nine independent Tn10 insertions previously mapped by genetic means were located by pulsed-field gel electrophoresis on the basis of the presence of XbaI and BlnI sites in Tn10. The genomic cleavage map was divided into 100 units called centisomes; the endonuclease cleavage sites and the genes defined by the positions of Tn10 insertions were located by centisome around the map. There is very good agreement between the genomic cleavage map, defined in centisomes, and the linkage map, defined in minutes. All seven rRNA genes were located on the map; all have the CeuI digestion site, all four with the tRNA gene for glutamate have the XbaI and the BlnI sites, but only four of the seven have the BlnI site in the 16S rRNA (rrs) gene. Their inferred orientation of transcription is the same as in Escherichia coli. A rearrangement of the rrnB and rrnD genes with respect to the arrangement in E. coli, observed earlier by others, has been confirmed. The sites for all three enzymes in the rrn genes are strongly conserved compared with those in E. coli, but the XbaI and BlnI sites outside the rrn genes show very little conservation.

Physical genome analysis of bacteria

Pulsed-field gel electrophoresis (PFGE) is a general analytical tool to separate large DNA molecules and may therefore be applied to problems from all areas of bacteriology. The genome size of bacteria covers the range of 0.6 to 10 megabase pairs. For genome fingerprinting, the bacterial chromosome is cleaved with a restriction endonuclease that gives a resolvable and informative number of five to one hundred fragments on the PFGE gel. Restriction enzymes are chosen according to GC content, degree of methylation, and codon usage of the respective bacterial genus. Macrorestriction fingerprinting allows the identification of bacterial strains and the distinction between related and unrelated strains. If fragment patterns of several restriction digestions are quantitatively evaluated, strains can be classified according to genetic relatedness at the level of genus, species, and biovar. In particular, members of a clonal lineage can be uncovered. Hence, any problem from applied, environmental, and clinical microbiology may be addressed by PFGE restriction analysis where the spatiotemporal spread of a bacterial clone is of interest. In bacterial genomics, PFGE is employed for the top-down construction of macrorestriction maps of the chromosome which yields data about genome organization, mobile genetic elements, and the arrangement of gene loci and gene families. The genomic diversity of a bacterial species is elucidated by comparative chromosome mapping. Map positions of restriction sites and gene loci of interest serve as landmarks to assess the extent of gross chromosomal modification, namely insertions, deletions and inversions. Intra- and interspecies comparisons of genome organization provide insights into the structure and diversity of bacterial populations and the phylogeny of bacterial taxa.