Use of Pulsed Field Gel Electrophoresis and Transposon Mutagenesis to Estimate the Minimal Number of Genes Required for Motility in Caulobacter Crescentus

To facilitate the mapping of transposon insertion mutations in Caulobacter crescentus, we have used pulsed field gel electrophoresis to construct a detailed physical and genetic map of the C. crescentus genome. Restriction fragments were generated by DraI, AseI, or SpeI which cleave the C. crescentus 40, 13, and 26 times, respectively, and Tn5 insertions were used to align the restriction fragments generated by each of the enzymes. The utility of the resulting map was demonstrated by determining the chromosomal locations of a collection of flagellar mutations. As a result of this study, we were able to identify ten new flagellar genes at various locations on the chromosome. Thus, at least 48 genes are required for the assembly of a functional flagellum in C. crescentus.     

Circularity of the Caulobacter crescentus chromosome determined by pulsed-field gel electrophoresis.

Previous genetic analyses of the Caulobacter crescentus chromosome have resulted in the construction of a linear genetic map. To establish the circularity of the C. crescentus chromosome, restriction fragments generated by digestion with AseI and SpeI were analyzed by pulsed-field gel electrophoresis and Southern hybridization. The size of each fragment was calculated and used to demonstrate that C. crescentus has a genome size of approximately 4,000 kilobases. In addition, both enzymes gave rise to large DNA fragments which contained genes from both ends of the genetic map. Thus, there is physical linkage between the genes at the ends of the genetic map and the chromosome is circular. Since this region of the chromosome appears to contain the replication terminus, we propose that recombination occurs at a high frequency in the vicinity of the terminus. This high frequency of recombination would prevent genetic linkage from being observed between genes on opposite sides of the terminus. Additional experiments using insertions which introduced new AseI and DraI restriction sites into the genome allowed us to calculate the physical distance between genes located in the vicinity of the replication terminus.     

Construction of a chromosome map for the phage group II Staphylococcus aureus Ps55.

The genome size and a partial physical and genetic map have been defined for the phage group II Staphylococcus aureus Ps55. The genome size was estimated to be 2,771 kb by pulsed-field gel electrophoresis (PFGE) using the restriction enzymes SmaI, CspI, and SgrAI. The Ps55 chromosome map was constructed by transduction of auxotrophic and cryptic transposon insertions, with known genetic and physical locations in S. aureus NCTC 8325, into the Ps55 background. PFGE and DNA hybridization analysis were used to detect the location of the transposon in Ps55. Ps55 restriction fragments were then ordered on the basis of genetic conservation between the two strains. Cloned DNA probes containing the lactose operon (lac) and genes encoding staphylococcal protein A (spa), gamma hemolysin (hlg), and coagulase (coa) were also located on the map by PFGE and hybridization analysis. This methodology enabled a direct comparison of chromosomal organization between NCTC 8325 and Ps55 strains. The chromosome size, gene order, and some of the restriction sites are conserved between the two phage group strains.     

A physical map of the genome of Ureaplasma urealyticum 960T with ribosomal RNA loci.

A physical map is presented for the 900 kilobase pair genome of Ureaplasma urealyticum 960T, locating 29 sites for 6 restriction endonucleases. The large restriction fragments were separated and sized by pulsed-field agarose gel electrophoresis (PFGE). Their locations on the map were determined by probing Southern blots of digests with individual fragments isolated from other digests and by correlating the products of double digestions and partial digestions. An end-labelling technique was used to detect small fragments not readily observed by PFGE. Two loci for rRNA genes have been determined by probing with cloned DNA.     

Genetic mapping with Tn5-derived auxotrophs of Caulobacter crescentus.

Chromosomal insertions of Tn5 in Caulobacter crescentus displayed complete stability upon transduction and proved useful in strain building on complex media. RP4-primes constructed in vitro containing C. crescentus genomic sequences in the HindIII site of the kanamycin resistance gene failed to show enhanced or directed chromosome mobilization abilities. One of these kanamycin-sensitive RP4 derivatives, pVS1, was used as a mobilization vector in conjugation experiments on complex media where chromosomal Tn5 transfer to the recipient was selected. pVS1-mediated transfer of Tn5-induced auxotrophic mutations occurred at frequencies of 10(-6) to 10(-8) per donor cell. During conjugation with Tn5-encoded kanamycin resistance as the selected marker, Tn5 remained in its donor-associated locus in 85 to 100% of the transconjugants. A collection of eight temperature-sensitive donor strains bearing Tn5 insertion mutations from various regions of the C. crescentus genetic map were used to provide a rapid means for the determination of the map location of a new mutation. Use of the techniques described in this paper allowed an expansion of the C. crescentus genetic map to include the relative locations of 32 genes.     

Construction of a Combined NotI/SmaI Physical and Genetic Map of Moraxella (Branhamella) catarrhalis Strain ATCC25238

Using pulsed field gel electrophoresis (PFGE) and Southern hybridization techniques, a physical map of Moraxella catarrhalis strain ATCC25238 was constructed to provide basic genetic knowledge of this bacterium that has attracted attention in recent years as a human pathogen. Restriction endonuclease NotI cut the genome into 10 fragments and SmaI into 9, and the molecular size of the genome was estimated to be 1,940 kilobases. Location of the 12 genes participating in the biosynthesis of purine, pyrimidine and nine kinds of amino acids were determined on the circular physical map of the strain.     

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.     

Long-range mapping of the gene for the human alpha 5(IV) collagen chain at Xq22-q23.

The X-linked kidney disorder known as Alport syndrome (AS) has been shown to be due to mutations in the gene for an alpha 5 chain of type IV collagen that maps to Xq22-23. Using overlapping cDNA clones that represent approximately 90% of this gene and pulsed-field gel electrophoresis, we have constructed a 2.4-Mb long-range restriction map around the locus. All of the cDNA clones lie within a 360-kb segment of DNA bounded by CpG islands that contain sites for the rare-cutting enzymes BssHII, MluI, NotI, NruI, SalI, and SfiI. High-resolution PFGE mapping with XhoI shows that the gene is at least 110 kb in size and is one of the largest collagen genes characterized to date. This map will prove useful in the characterization of mutations in individuals affected with AS and will also provide information as to the location of other genes in the region.     

Nonspecific primer and PCR generated hybridization probes for physical ordering large restriction fragments in complex genome of S. aureus.

Pulsed field gel electrophoresis (PFGE) allows separation of large restriction fragments from bacterial genome. Restriction fragments obtained by digestion of Staphylococcus aureus DNA with rare cutting enzymes (Sma I, and Csp I) were separated by PFGE. To arrange the physical order of the fragments generated by digestion with one enzyme, probes were prepared by nonspecific priming and polymerase chain reaction (PCR), using individual fragments of the other enzymatic digest as a template. Probes were then used for Southern hybridization to the PFGE separated fragment distribution of the two infrequent cleaving enzymes (Sma I and Csp I). Using probes generated from four Sma I fragments and five Csp I fragments as individual templates, a partial physical order of Csp I fragments of the genome of S. aureus ISP8 has been determined in relation to a previously published Sma I map of S. aureus genome.     

Genome size and macrorestriction map of Xanthomonas campestris pv. glycines YR32 chromosome

Xanthomonas campestris is an important plant pathogenic bacterium which causes severe diseases in a wide variety of plant species. We have generated a macrorestriction map of the X. campestris (axonopodis) pv. glycines chromosome employing pulsed-field gel electrophoresis (PFGE). Restriction endonucleases PacI (5'-TTAATTAA), PmeI (5'-GTTTAAAC) and SwaI (5'-ATTTAAAT) digested the chromosomal DNA into three, five, and five fragments, respectively. In addition, intron-encoded restriction endonuclease I-CeuI was employed to locate the position of the 23S rRNA genes (rrlA and rrlB). All of the generated restriction fragments were aligned along the chromosome using multiple restriction enzyme digestion and two-dimensional PFGE (2-D PFGE) in conjunction with Southern hybridization analysis. This physical map construction has revealed a single circular chromosome with a size of approximately 5 Mb. Two rRNA genes were localized on the chromosome map. Several genes involved in pathogenesis (xpsD, opsX, and pat) as well as genes involved in the biosynthesis of xanthan gum (xanAB, rfbCDAB) were also localized.     

A combined genetic and physical map of the Streptomyces coelicolor A3(2) chromosome.

The restriction enzymes AseI (ATTAAT), DraI (TTTAAA), and SspI (AATATT) cut the Streptomyces coelicolor A3(2) chromosome into 17, 8, and 25 fragments separable by pulsed-field gel electrophoresis (PFGE). The sums of their lengths indicated that the chromosome consists of about 8 Mb of DNA, some 75% more than that of Escherichia coli K-12. A physical map of the chromosome was constructed for AseI and DraI, using single and double digests, linking clones, cross-hybridization of restriction fragments, and locations of genetically mapped genes, insertion sequences, prophages, and the integrated SCP1 and SLP1 plasmids on the physical map. The physical map was aligned with the previously established genetic map, revealing that the two long opposite quadrants of the genetic map that are almost devoid of markers (the silent regions at 3 o'clock and 9 o'clock) are indeed physically long rather than being hot spots for genetic exchange. They must therefore contain long stretches of DNA different in function from the remainder of the genome. Consistent with this conclusion are the locations of significant deletions in both of the silent regions. Of these, a 40-kb deletion in the 9 o'clock region accompanied or followed integration of the SCP1 linear plasmid to produce the NF fertility state. PFGE analysis of Streptomyces lividans 66, a close relative of S. coelicolor A3(2), was hampered by the previously described susceptibility of its DNA to degradation during electrophoresis. However, ZX7, a mutant derivative of S. lividans lacking the DNA modification responsible for this degradation, yielded good PFGE preparations. Not more than 7 of the 17 S. coelicolor AseI fragments could be shared by the S. lividans strain.     

Physical and genetic map of the Spiroplasma kunkelii CR2-3x chromosome

Spiroplasma kunkelii (class Mollicutes) is the characteristically helical, wall-less bacterium that causes corn stunt disease. A combination of restriction enzyme analysis, pulsed-field gel electrophoresis (PFGE), and Southern hybridization analysis was used to construct a physical and genetic map of the S. kunkelii CR2-3x chromosome. The order of restriction fragments on the map was determined by analyses of reciprocal endonuclease double digests employing I-CeuI, AscI, ApaI, EagI, SmaI, BssHII, BglI, and SalI; adjacent fragments were identified on two-dimensional pulsed-field electrophoresis gels. The size of the chromosome was estimated at 1550 kb. Oligonucleotide pairs were designed to prime the amplification of 26 S. kunkelii gene sequences in the polymerase chain reaction (PCR). Using PCR amplicons as probes, the locations of 27 S. kunkelii putative single-copy genes were positioned on the map by Southern hybridization analyses of chromosomal fragments separated in PFGE. The nucleotide sequence of the single ribosomal RNA operon was determined and its location mapped to a chromosomal segment bearing recognition sites for SalI, SmaI, EagI, and I-CeuI.     

Physical map of the chromosome of Neisseria gonorrhoeae FA1090 with locations of genetic markers, including opa and pil genes.

A physical map of the chromosome of Neisseria gonorrhoeae FA1090 has been constructed. Digestion of strain FA1090 DNA with NheI, SpeI, BglII, or PacI resulted in a limited number of fragments that were resolved by contour-clamped homogeneous electric field electrophoresis. The estimated genome size was 2,219 kb. To construct the map, probes corresponding to single-copy chromosomal sequences were used in Southern blots of digested DNA separated on pulsed-field gels, to determine how the fragments from different digests overlapped. Some of the probes represented identified gonococcal genes, whereas others were anonymous cloned fragments of strain FA1090 DNA. By using this approach, a macrorestriction map of the strain FA1090 chromosome was assembled, and the locations of various genetic markers on the map were determined. Once the map was completed, the repeated gene families encoding Opa and pilin proteins were mapped. The 11 opa loci of strain FA1090 were distributed over approximately 60% of the chromosome. The pil loci were more clustered and were located in two regions separated by approximately one-fourth of the chromosome.     

A physical map of the Salmonella typhimurium LT2 genome made by using XbaI analysis.

XbaI digestion and pulsed-field gel electrophoresis of the genome of Salmonella typhimurium LT2 yields 24 fragments: 23 fragments (total size, 4,807 kb) are from the chromosome, and one fragment (90 kb) is from the virulence plasmid pSLT. Some of the 23 fragments from the chromosome were located on the linkage map by the use of cloned genes as probes and by analysis of strains which gain an XbaI site from the insertion of Tn10. Twenty-one of the fragments were arranged as a circular physical map by the use of linking probes from a set of 41 lysogens in which Mud-P22 was stably inserted at different sites of the chromosome; fragment W (6.6 kb) and fragment X (6.4 kb) were not located on the physical map. XbaI digestion of strains with Tn10 insertions allowed the physical locations of specific genes along the chromosome to be determined on the basis of analysis of new-fragment sizes. There is good agreement between the order of genes on the linkage map, which is based primarily on P22 joint transduction and F-mediated conjugation, and the physical map, but there are frequently differences in the length of the interval from the two methods. These analyses allowed the measurement of the amount of DNA packaged in phage P22 heads by Mud-P22 lysogens following induction; this varies from ca. 100 kb (2 min) to 240 kb (5 min) in different parts of the chromosome.     

The impact of two-dimensional pulsed-field gel electrophoresis techniques for the consistent and complete mapping of bacterial genomes: refined physical map of Pseudomonas aeruginosa PAO.

The SpeI/DpnI map of the 5.9 Mb Pseudomonas aeruginosa PAO (DSM 1707) genome was refined by two-dimensional (2D) pulsed-field gel electrophoresis techniques (PFGE) which allow the complete and consistent physical mapping of any bacterial genome of interest. Single restriction digests were repetitively separated by PFGE employing different pulse times and ramps in order to detect all bands with optimum resolution. Fragment order was evaluated from the pattern of 2D PFGE gels: 1. Partial-complete digestion. A partial restriction digest was separated in the first dimension, redigested to completion, and subsequently perpendicularly resolved in the second dimension. 2D-gel comparisons of the ethidium bromide stain of all fragments and of the autoradiogram of end-labeled partial digestion fragments was nearly sufficient for the construction of the macrorestriction map. 2. Reciprocal gels. A complete restriction digest with enzyme A was run in the first dimension, redigested with enzyme B, and separated in the second orthogonal direction. The order of restriction digests was reverse on the second gel. In case of two rare-cutters, fragments were visualized by ethidium bromide staining or hybridization with genomic DNA. If a frequent and a rare cutter were employed, linking fragments were identified by end-labeling of the first digest. 3. A few small fragments were isolated by preparative PFGE and used as a probe for Southern analysis.--38 SpeI and 15 DpnI fragments were positioned on the map. The zero point was relocated to the 'origin of replication'. The anonymous mapping techniques described herein are unbiased by repetitive DNA, unclonable genomic regions, unfavourable location of restriction sites, or cloning artifacts as frequently encountered in other top-down or bottom-up approaches.     

Construction of a genomic map of Moraxella (Branhamella) catarrhalis ATCC 25238 and physical mapping of virulence-associated genes.

A physical genome map of the Moraxella catarrhalis type strain (ATCC 25238) has been constructed using pulsed field gel electrophoresis. Macrorestriction analyses of the genome of M. catarrhalis were performed by digestion with the restriction enzymes SmaI, NotI, and RsrII, which cleave the single circular chromosome into 9, 10, and 6 fragments, respectively. The chromosomal fragments generated by pulsed field gel electrophoresis were converted to a linkage map utilizing a combination of partial digestions, and cross-hybridizations. Moraxella catarrhalis, like a number of other respiratory pathogens, has a relatively small genome estimated at 1750 kilobase pairs or about 40% of the size of the Escherichia coli genome. The locations of the four ribosomal RNA operons (rrnLS) were determined by Southern hybridization and by digestion with I-CeuI endonuclease. A number of genes involved in virulence have been placed onto the physical map by Southern hybridization including those encoding the predominant outer-membrane proteins and the chromosomal gene encoding beta-lactamase.     

Construction of a Fibrobacter succinogenes Genomic Map and Demonstration of Diversity at the Genomic Level

The genomic cleavage map of the type strain Fibrobacter succinogenes S85 was constructed. The restriction enzymes AscI, AvrII, FseI, NotI, and SfiI generated DNA fragments of suitable size distribution that could be resolved by pulsed-field gel electrophoresis (PFGE). An average genome size of 3.6 Mb was obtained by summing the total fragment sizes. The linkages between the 15 AscI fragments of the genome were determined by combining two approaches: isolation of linking clones and cross-hybridization of restriction fragments. The genome of F. succinogenes was found to be represented by the single circular DNA molecule. Southern hybridization with specific probes allowed the eight genetic markers to be located on the restriction map. The genome of this bacterium contains at least three rRNA operons. PFGE of the other three strains of F. succinogenes gave estimated genome sizes close to that of the type strain. However, RFLP patterns of these strains generated by AscI digestion are completely different. Pairwise comparison of the genomic fragment distribution between the type strain and the three isolates showed a similarity level in the region of 14.3% to 31.3%. No fragment common to all of these F. succinogenes strains could be detected by PFGE. A marked degree of genomic heterogeneity among members of this species makes genomic RFLP a highly discriminatory and useful molecular typing tool for population studies. Received: 23 October 1996 / Accepted: 31 December 1996