Restriction endonucleases for pulsed field mapping of bacterial genomes

New tools for the physical and genetic mapping of Lactococcus strains

Tools for the genetic and physical analysis of the Lactococcus lactis subsp. lactis genome were developed. Plasmid pRC1 does not replicate in Gram+ bacteria; it contains unique ApaI, NotI and SmaI restriction sites and an erythromycin-resistance (ErR) encoding gene, ermAM, functional in L. lactis subsp. lactis. When a chromosomal L. lactis subsp. lactis DNA fragment was cloned into this vector, the resulting plasmid became integrated, after transformation, into the bacterial chromosome by homologous recombination in a Campbell-like manner. The integration lead to the generation of new rare restriction sites near to the host fragment. This procedure allows precise mapping of cloned genes onto the chromosomal restriction map. The mapping of the his operon of L. lactis subsp. lactis provides an illustration. The cloning into pRC1 of an IS element able to transpose into the chromosome of the target cell, gave rise to an integration plasmid able to insert randomly rare restriction sites onto the bacterial chromosome. The L. lactis IS element, ISS1RS, was cloned into pRC1, yielding pRL1. Pulsed-field gel electrophoresis analysis of ErR clones obtained after transformation with pRL1, showed that this plasmid was stably integrated at a number of different sites in the L. lactis subsp. lactis chromosome, via transposition. Plasmids pRC1 and pRL1 can greatly facilitate the construction of the physical and genetic map of the chromosome of lactococcal strains.

Vectors with segmented multiple cloning sites (SMCS) for easy monitoring of restriction digests and post-cloning orientation reversal of genes

A novel approach is described, through which the transcriptional orientation of cloned genes is manipulated without further subcloning. This is achieved through a restriction/ligation process (without changing the test tube) leading to approx. 1:1 mixture of both possible orientations. The plasmid containing the reversed orientation is easily distinguished from the wild type by built-in restriction-indicator sites for SpeI. Additionally, a large marker fragment is incorporated into the segmented multiple cloning site (SMCS) regions to facilitate monitoring the progress and/or efficiency of vector restrictions. The marker fragment is released upon appropriate double digestion, thus acting as an indicator for complete restriction-enzyme digestion. We have equipped some existing plasmids, commonly used in molecular biology, with these features and demonstrated their superiority to plasmids having regular MCS sequences.

Differentiation of Listeria monocytogenes, Listeria innocua, Listeria ivanovii, and Listeria seeligeri by pulsed-field gel electrophoresis

Clamped homogeneous electric field analysis of Listeria DNA with ApaI, AscI, SmaI, or NotI revealed species- and serotype-specific differences in genomic fingerprints. Clamped homogeneous electric field analysis may prove useful, therefore, in epidemiologic studies. Also, the summation of individually sized AscI fragments of genomic DNA from L. monocytogenes serotype 4b 101M and Scott A indicated genome lengths of 2,925 and 3,046 kb, respectively.

New approaches in genome analysis by pulsed-field gel electrophoresis: application to the analysis of Pseudomonas species

A general method for the evaluation of macrorestriction fragment patterns is presented and its applicability to the taxonomy of bacteria is demonstrated for 32 Pseudomonas species. Strains were differentiated at the species and subspecies level by genome size and macrorestriction fragment fingerprints of the chromosome that had been separated on pulsed-field gels. The relatedness of bacteria was ascertained from the similarity of AsnI, DraI, SpeI, SspI or XbaI fragment patterns. In general, the dendrograms calculated from the genome fingerprints corresponded with the phylogenetic classification obtained from phenotypic marker or nucleic acid hybridization analysis, but several exceptions were noted. The techniques and algorithms presented herein are generally applicable to the genome analysis of bacteria, lower eukaryotes, and DNA fragments cloned in yeast artificial chromosomes.

Proposal of Afipia gen. nov., with Afipia felis sp. nov. (formerly the cat scratch disease bacillus), Afipia clevelandensis sp. nov. (formerly the Cleveland Clinic Foundation strain), Afipia broomeae sp. nov., and three unnamed genospecies

On the basis of phenotypic characterization and DNA relatedness determinations, the genus Afipia gen. nov., which contains six species, is described. The type species is Afipia felis sp. nov. (the cat scratch disease bacillus). Afipia clevelandensis sp. nov., Afipia broomeae sp. nov., and three unnamed not associated with cat-borne disease. All but one strain (Afipia genospecies 3) were isolated from human wound and respiratory sources. All Afipia species are gram-negative, oxidase-positive, nonfermentative rods in the alpha-2 subgroup of the class Proteobacteria. They are motile by means of a single flagellum. They grow on buffered charcoal-yeast extract agar and nutrient broth, but rarely on MacConkey agar, at 25 and 30 degrees C. They are urease positive; but they are negative in reactions for hemolysis, indole production, H2S production (triple sugar iron agar), gelatin hydrolysis, esculin hydrolysis, and peptonization of litmus milk. They do not produce acid oxidatively from D-glucose, lactose, maltose, or sucrose. The major cell wall fatty acids are 11-methyloctadec-12-enoic (CBr19:1), cis-octadec-11-enoic (C18:1omega7c), and generally, 9,10-methylenehexadecanote and 11,12-methyleneoctadecanoate; and there are only trace amounts of hydroxy acids. The guanineplus-cytosine content is 61.5 to 69 mol%. A. felis is positive for nitrate reduction and is delayed positive for acid production from D-xylose, but it is catalase negative. A. clevelandensis is negative in all of these tests. A. broomeae is weakly positive for catalase production and acid production from D-xylose, but it is negative for nitrate reduction.

Nosocomial infections from contaminated endoscopes: a flawed automated endoscope washer. An investigation using molecular epidemiology

Approximately 1 year after purchase of one manufacturer's automated endoscope washing machine, we began to detect heavy contamination of upper gastrointestinal (UGI) endoscopes cultured after cleaning and disinfection in the washer. During the first 6 months of 1988, 77% of surveillance cultures (20-mL flush through the biopsy channel) were positive for gram-negative bacilli (median concentration, 10(5) cfu/mL), most frequently Pseudomonas aeruginosa serotype 10. During the first 19 months of use of the washer, nosocomial post-UGI endoscopy colonization or infections with P. aeruginosa increased 36%. Investigations show that endoscope contamination derives from a flaw in the design of the EW-10 washer: the detergent holding tank, inlet water hose, and air vents cannot be reliably disinfected and contain heavy biofilms that recontaminate the machine after it has been disinfected, as specified by the manufacturer, with glutaraldehyde. Only by rinsing machine-cleansed endoscopes with 70% alcohol followed by forced air drying has reliable disinfection been achieved. Since adaptation of terminal alcohol treatment and drying, post-UGI endoscopy colonization or infection by P. aeruginosa has declined threefold (p less than 0.001). Testing in other centers using the manufacturer's EW-10 or EW-20 washer has shown similar contamination. In three centers, including our own, postendoscopy infections by machine-associated type 10 P. aeruginosa have been confirmed by demonstrating concordance between isolates from contaminated machines or endoscopes and from infected patients by immunoblot of whole cell lysates and by pulsed-field electrophoresis of DraI endonuclease-digested genomic DNA. This problem reaffirms the vulnerability to microbial contamination of water-containing apparatus and equipment in patient care and points up the critical importance of engineering design to prevent contamination.

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 modified method of genomic DNA preparation in agarose inserts for pulse field gel electrophoresis

According to standard protocol, DNA in agarose inserts is prepared by first embedding the cell in agarose. This is then incubated in the required enzyme (lysozyme, lysostaphin, or zymolase) depending on the cell type (bacterial or plants), for spheroplast formation. Subsequent treatment of the spheroplast with proteinase K allows the isolation of large genomic DNA in agarose suitable for pulse field gel electrophoresis. An efficient and rapid method of preparation of spheroplast is described. In this method a low concentration of enzyme required for spheroplast formation was added before embedding the cell in agarose, which facilitated the digestion of cell wall by the enzyme and allowed use of a low amount of enzyme. Digestion of DNA in agarose inserts prepared by this method, with rare cutting restriction enzyme and pulse field gel electrophoresis, showed that the quality of DNA was as good as obtained by the standard method.

Assessment of inhomogeneities in an E. coli physical map

A statistical method based on r-fragments, sums of distances between (r + 1) consecutive restriction enzyme sites, is introduced for detecting nonrandomness in the distribution or too markers in sequence data. The technique is applicable whenever large numbers of markers are available and will detect clumping, excessive dispersion or too much evenness of spacing of the markers. It is particularly adapted to varying the scale on which inhomogeneities can be detected, from nearest neighbor interactions to more distant interactions. The r-fragment procedure is applied primarily to the Kohara et al. (1) physical map of E. coli. Other applications to DAM methylation sites in E. coli and NotI sites in human chromosome 21 are presented. Restriction sites for the eight enzymes used in (1) appear to be randomly distributed, although at widely differing densities. These conclusions are substantially in agreement with the analysis of Churchill et al. (3). Extreme variability in the density of the eight restriction enzyme sites cannot be explained by variability in mono-, di- or trinucleotide frequencies.

Complete physical map of the Bacillus subtilis 168 chromosome constructed by a gene-directed mutagenesis method

All the SfiI sites and most of the NotI sites were located precisely on the chromosome of Bacillus subtilis 168 by a novel method, termed gene-directed mutagenesis. The stepwise elimination of these restriction sites by this method allowed not only the physical connection of the restriction fragments but also the accurate determination of the position of the restriction sites themselves. The resulting physical map of the 4165 x 10(3) base-pair B. subtilis chromosome has been correlated with the genetic map by determination of the exact location of known genes. The complete physical map provides a rapid and accurate way for mapping of new genes as well as analysis of large DNA rearrangements on the chromosome. The novel strategy is, in principle, applicable to the analysis of the genome of other organisms.

Electrophoretic separation of the three Rhizobium meliloti replicons

The megaplasmids and the chromosome from the bacterium Rhizobium meliloti 1021 were separated in preparative quantities by using transverse alternating-field gel electrophoresis. The genetic content of each electrophoretically separated band was determined by Southern hybridization with replicon-specific probes and by comparison with Agrobacterium tumefaciens transconjugants harboring either pSym-a or pSym-b megaplasmids. Pulsed-field gel electrophoresis analyses of PacI (5'-TTAATTAA-3') and SwaI (5'-ATTTAAAT-3') digests of the whole genome and of the separated replicons were used to calculate genome sizes in two R. meliloti strains. In these strains, PacI digestion yielded only four fragments for the entire genome. The sizes of the PacI fragments from R. meliloti 1021 in megabase pairs (Mb) were 3.32 +/- 0.30, 1.42 +/- 0.13, 1.21 +/- 0.10, and 0.55 +/- 0.08, for a total genome size of 6.50 +/- 0.61 Mb. Southern hybridization with replicon-specific probes assigned one PacI fragment to the chromosome of R. meliloti 1021, one to pRme1021a, and two to pRme1021b. PacI digestion of A. tumefaciens pTi-cured, pSym transconjugants confirmed these assignments. In agreement with PacI data, the addition of the six SwaI fragments from R. meliloti 1021 gave a genome size of 6.54 +/- 0.43 Mb. pRme1021a was calculated to be 1.42 +/- 0.13 Mb, 1.34 +/- 0.09 Mb, and 1.38 +/- 0.12 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021a, respectively. pRme1021b was calculated to be 1.76 +/- 0.18 Mb, 1.65 +/- 0.10 Mb, and 1.74 +/- 0.13 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021B, respectively. The R. meliloti 1021 chromosome was calculated to be 3.32 +/- 0.30 Mb, 3.55 +/- 0.24 Mb, and 3.26 +/- 0.46 Mb on the basis of PacI data, SwaI data, and the migration of uncut chromosome, respectively.

Nisin biosynthesis genes are encoded by a novel conjugative transposon

Genes for biosynthesis of the lactococcal peptide antibiotic nisin were shown to be encoded by a novel chromosomally located transposon Tn5301. The element is 70 kb in size and lacks inverted repeats at its termini. Although a copy of the insertion sequence IS904 is located near to one end, this did not appear to be involved in the transposition process. The integrated element is flanked by the directly repeated sequence 5'-TTTTTG-3'. Analysis of ten independent transconjugants revealed that Tn5301 integration is site-specific; two chromosomal targets were identified and shown to have some sequence homology. The element shares features with the Tn916 family of conjugative transposons and with Tn554 but is also exhibits some unique properties. Tn5301 is thus considered to be the prototype of a novel class of conjugative transposon.

DNA polymorphism in strains of Listeria monocytogenes

DNA polymorphism in 35 Listeria monocytogenes strains belonging to serovars 1/2a, 1/2b, 1/2c, and 4b was studied by genomic DNA digestion. The restriction endonucleases ApaI and NotI, which cleave DNA at rare sequences, were used, and DNA fragments were analyzed by pulsed-field gel electrophoresis. Restriction fragment length polymorphism varied among different serovars and was used for epidemiological studies, but serovar 1/2c isolates could not be analyzed because their restriction patterns were indistinguishable. The genome sizes were calculated by addition of the sizes of the ApaI fragments and were found to be about 2,660 kb for serovar 1/2a strains, 2,640 kb for serovar 1/2b strains, and 2,710 kb for serovar 4b strains but only 2,340 kb for serovar 1/2c strains. This last group therefore appears to differ from the other serovar strains by the absence of restriction fragment length polymorphism and a chromosome that is 15% shorter, suggesting that strains of serovar 1/2c have quite recently emerged.

Molecular typing of Shigella strains using pulsed field gel electrophoresis and genome hybridization with insertion sequences

The genomes of 18 independent Shigella isolates (9 Shigella sonnei, 5 Shigella dysenteriae and 4 Shigella flexneri) as well as of 4 epidemic S. flexneri strains were analysed by pulsed field gel electrophoresis (PFGE) and by the distribution of insertion sequences (IS1, IS2 and IS911). Despite the close relatedness observed among the 9 independent S. sonnei, all of them could be differentiated from each other. The 4 independent S. flexneri isolates showed clearly distinguishable DNA profiles. Nearly complete genetic identity was detected within the 4 epidemic S. flexneri when analysed by PFGE or for IS1 and IS2 patterns. However, IS911 was found to be too mobile in these epidemic S. flexneri to be used as a typing probe. The 5 S. dysenteriae isolates could also be distinguished by the techniques used. The diversity found within this species is striking: of the 5 investigated isolates, 3 completely different DNA profiles were revealed. In conclusion, both PFGE and IS probing demonstrated their potential usefulness in molecular epidemiology and in typing of Shigella strains. The degree of differentiation given by these two methods was generally comparable, although IS probes showed better discrimination of the isolates.

Characterization of the opa (class 5) gene family of Neisseria meningitidis

Class 5 outer membrane proteins of Neisseria meningitidis show both phase- and antigenic variation of expression. The proteins are encoded by a family of opa genes that share a conserved framework interspersed with three variable regions, designated the semivariable (SV) region and hypervariable regions 1 (HV1) and 2 (HV2). In this study, we determined the number and DNA sequence of all of the opa genes of meningococcal strain FAM18, to assess the structural and antigenic variability in the family of proteins made by one strain. Pulsed field electrophoresis and Southern blotting showed that there are four opa genes in the FAM18 chromosome, and that they are not tightly clustered. DNA sequence analysis of the four cloned genes showed a modest degree of diversity in the SV region and more extensive differences in the HV1 and HV2 regions. There were four versions of HV1 and three versions of HV2 among the four genes. Each of the FAM18 opa loci contained a gene with a unique combination of SV, HV1, and HV2 sequences. We used lambda gt11 cloning and synthetic peptides to demonstrate that HV2 sequences completely encode the epitopes for two monoclonal antibodies specific for different class 5 proteins of FAM18.

Physical map of the Brucella melitensis 16 M chromosome

We present the first restriction map of the Brucella melitensis 16 M chromosome obtained by Southern blot hybridization of SpeI, XhoI, and XbaI fragments separated by pulsed-field gel electrophoresis. All restriction fragments (a total of 113) were mapped into an open circle. The main difficulty in mapping involved the exceedingly high number of restriction fragments, as was expected considering the 59% G + C content of the Brucella genome. Several cloned genes were placed on this map, especially rRNA operons which are repeated three times. The size of the B. melitensis chromosome, estimated as 2,600 kb long in a previous study, appeared longer (3,130 kb) by restriction mapping. This restriction map is an initial approach to achieve a genetic map of the Brucella chromosome.

Pulsed field gel electrophoresis as a new epidemiological tool for monitoring methicillin-resistant Staphylococcus aureus in an intensive care unit

Pulsed field gel electrophoresis (PFGE) of bacterial DNA was used in a 1-month epidemiological study of methicillin-resistant Staphylococcus aureus (MRSA) in a 15-bed Intensive Care Unit (ICU). Patient and hospital staff carriage as well as distribution of MRSA in the ICU environment were investigated, and a total of 3802 samples produced 175 isolates. The stability and the reproducibility of the PFGE method were satisfactory. Moreover, the plasmid content of the strains so far examined had no influence on the PFGE profiles of the MRSA strains. The polymorphic profiles observed also account for the use of this method as an epidemiological tool for investigating MRSA. Among 30 patients who stayed more than 4 days in the unit, PFGE analysis showed 11 episodes of colonization in nine patients, whereas lysotyping and plasmid DNA analysis demonstrated only eight and seven such episodes in the same patients, respectively. The combination of PFGE with lysotyping and plasmid analysis may provide a greater discriminatory capacity between MRSA isolates.

Enzymatic cleavage of a bacterial chromosome at a transposon-inserted rare site

The sequential use of the methylase M.Xbal (5'.TCTAGm6A) and the methylation-dependent endonuclease Dpnl (5'-Gm6A decreases TC) results in cleavage at 5'.TCTAGA decreases TCTAGA. This recognition sequence was introduced into a transposon derived from the Mu bacteriophage and transposed into the genome of the bacterium Salmonella typhimurium. M.Xbal methylation was provided in vivo by a plasmid containing the M.Xbal gene and the S. typhimurium genome was cleaved to completion by Dpnl at one or more sites, depending on the number of transposon insertions. The resulting genomic fragments were resolved by pulsed-field electrophoresis. The potential use of single M.Xbal/Dpnl cleavage sites as reference positions to map rare restriction sites is discussed.

Physical and genetic map of the Methanococcus voltae chromosome

A physical map of the Methanococcus voltae chromosome was constructed on the basis of restriction mapping and cross-hybridization experiments, employing total and partial digests obtained with rarely cutting restriction enzymes. On the basis of the sum of the fragment sizes of digests with seven enzymes the chromosome length was calculated to be approximately 1900 kb. The derived map is circular. Hybridization of gene probes to mapped restriction fragments has led to a genetic map of genes for structural RNAs as well as proteins, including enzymes involved in the methanogenic pathway.

Pulsed-field gel electrophoretic analysis of leptospiral DNA

The genomic structures of spirochete species are not well characterized, and genetic studies on these organisms have been hampered by lack of a genetic exchange mechanism in these bacteria. In view of these observations, pulsed-field gel electrophoresis was used to examine the genomes of Leptospira species. Live cells, prepared in agarose plugs, were lysed in situ, and the DNA was analyzed under different electrophoretic conditions. Pulsed-field gel electrophoresis of DNA digested with infrequently cutting restriction enzymes showed that the genome of Leptospira interrogans serovar canicola is approximately 3.1 Mb, while that of the saprophytic L. biflexa serovar patoc I is 3.5 Mb. DNA forms of approximately 2,000 and 350 kb which were present in samples from L. interrogans serovars were not readily detected in nonpathogenic serovars. Three distinct populations, designated type alpha, beta, and gamma, of L. interrogans DNA molecules were further analyzed with two-dimensional gel electrophoresis. Evidence suggested that two of these DNA forms, type alpha and gamma, were linear structures. Pulsed-field gel electrophoresis has proven to be a valuable tool with which to size bacterial genomes and to take the first steps toward characterization of a form of leptospiral DNA which behaves as a linear molecule and which may be related to the virulence of L. interrogans.

The genomes of the family Rhizobiaceae: size, stability, and rarely cutting restriction endonucleases

The lack of high-resolution genetic or physical maps for the family Rhizobiaceae limits our understanding of this agronomically important bacterial family. On the basis of statistical analyses of DNA sequences of the Rhizobiaceae and direct evaluation by pulsed-field agarose gel electrophoresis (PFE), five restriction endonucleases with AT-rich target sites were identified as the most rarely cutting: AseI (5'-ATTAAT-3'), DraI (5'-TTTAAA-3'), SpeI (5'-ACTAGT-3'), SspI (5'-AATAAT-3'), and XbaI (5'-TCTAGA-3'). We computed the sizes of the genomes of Bradyrhizobium japonicum USDA 424 and Rhizobium meliloti 1021 by adding the sizes of DNA fragments generated by SpeI digests. The genome sizes of R. meliloti 1021 and B. japonicum USDA 424 were 5,379 +/- 282.5 kb and 6,195 +/- 192.4 kb, respectively. We also compared the organization of the genomes of free-living and bacteroid forms of B. japonicum. No differences between the PFE-resolved genomic fingerprints of free-living and mature (35 days after inoculation) bacteroids of B. japonicum USDA 123 and USDA 122 were observed. Also, B. japonicum USDA 123 genomic fingerprints were unchanged after passage through nodules and after maintenance on a rich growth medium for 100 generations. We conclude that large-scale DNA rearrangements are not seen in mature bacteroids or during free-living growth on rich growth media under laboratory conditions.

Methylation of intact chromosomes by bacterial methylases in agarose plugs suitable for pulsed-field electrophoresis. Methylation of intact chromosomes in agarose by methylases

Conditions were determined for the methylation of intact yeast chromosomes by EcoRI, HhaI, and MspI bacterial methylases using an endonuclease protection assay while the chromosomes were embedded in agarose plugs suitable for transverse-field electrophoresis. Parameters were also established for the methylation of human chromosomes by EcoRI methylase. Methylation of embedded chromosomes by EcoRI methylase required prewashes with EDTA. EcoRI, HhaI, and MspI methylases showed optimal activity when nonacetylated bovine serum albumin, high levels of S-adenosylmethionine, and high levels of methylase were used. The use of bacterial methylases for methylation of embedded chromosomes will allow investigators to normalize variations in cellular DNA methylation prior to restriction and create new and rare endonuclease recognition sites which will facilitate the detection of chromosomal alterations and deletions.

Size and physical map of the Campylobacter jejuni chromosome

The chromosome of Campylobacter jejuni is circular and approximately 1700 kb in circumference. The size of the genome was determined by field inversion gel electrophoresis of restriction endonuclease fragments using lambda DNA concatamers and yeast chromosomes to calibrate the size of the fragments. In view of the low (32-35%) G + C content of the campylobacter genome, enzymes that recognizes GC-rich sequences were used. Of the enzymes tested BssHII (G/C(G)CGC), NciI (CC/CGCG) and SalI (G/TCGAC) appeared to be usable. Hybridization of labeled fragments with two or more fragments from digests with a different restriction enzyme gave the information to order the fragments on the C jejuni chromosome. The localization on the genome of the flagellin and ribosomal gene clusters was determined.

Pulsed-Field Gel Electrophoresis of Sma I Digests of Lactococcal Genomic DNA, a Novel Method of Strain Identification

The pulsed-field gel electrophoresis (PFGE) pattern of Sma I digests of 29 strains of Lactococcus lactis subsp. lactis and subsp. cremoris were determined. Unrelated strains yielded markedly different patterns of digestion products. Bacteriophage-resistant derivatives of four strains, generated by a method analogous to that used regularly in some cheese factories, yielded patterns that were identical or almost identical to that of the parent strain. It is proposed that a 16-h PFGE run with a pulse time increasing linearly from 1 to 20 s, which separates fragments between 50 and 240 kilobase pairs (kbp) and produces a pattern containing around 15 bands, can be used as a reliable procedure for strain identification in the lactococci. Sma I digests of 24 of the strains were analyzed by PFGE at three different pulse times to determine accurately the sizes of fragments bigger than 8 kbp. The sum of the sizes of all of the fragments in the digest of a strain provided an estimate of the genome size of the strain. For all the strains analyzed, this estimate was within the range of 2.0 to 2.7 Mbp, with no apparent difference between L. lactis subsp. lactis, L. lactis subsp. lactis biovar diacetylactis and L. lactis subsp. cremoris strains.

Use of pulsed-field agarose gel electrophoresis to size genomes of Campylobacter species and to construct a SalI map of Campylobacter jejuni UA580

To determine the physical length of the chromosome of Campylobacter jejuni, the genome was subjected to digestion by a series of restriction endonucleases to produce a small number of large restriction fragments. These fragments were then separated by pulsed-field gel electrophoresis with the contour-clamped homogeneous electric field system. The DNA of C. jejuni, with its low G+C content, was found to have no restriction sites for enzymes NotI and SfiI, which cut a high-G+C regions. Most of the restriction enzymes that were used resulted in DNA fragments that were either too numerous or too small for genome size determination, with the exception of the enzymes SalI (5' ... G decreases TCGAG ... 3'), SmaI (5' .... CCC decreases GGG .... 3'), and KpnI (5' ... GGTAC decreases C .... 3'). With SalI, six restriction fragments with average values of 48.5, 80, 110, 220, 280, and 980 kilobases (kb) were obtained when calibrated with both a lambda DNA ladder and yeast Saccharomyces cerevisiae chromosome markers. The sum of these fragments yielded an average genome size of 1.718 megabases (Mb). With SmaI, nine restriction fragments with average values ranging from 39 to 371 kb, which yielded an average genome size of 1.726 Mb were obtained. With KpnI, 11 restriction fragments with sizes ranging from 35 to 387.5 kb, which yielded an average genome size of 1.717 Mb were obtained. A SalI restriction map was derived by partial digestion of the C. jejuni DNA. The genome sizes of C. laridis, C. coli, and C. fetus were also determined with the contour-clamped homogeneous electric field system by SalI, SmaI, and KpnI digestion. Average genome sizes were found to be 1.714 Mb for C. coli, 1.267 Mb for C. fetus subsp. fetus, and 1.451 Mb for C. laridis.

Epidemiologic study of Taylorella equigenitalis strains by field inversion gel electrophoresis of genomic restriction endonuclease fragments

Contagious equine metritis (CEM), a sexually transmitted bacterial disease, was first described in thoroughbred horses. It also occurs in nonthoroughbred horses, in which it produces isolated, apparently unrelated outbreaks. Thirty-two strains of Taylorella equigenitalis, the causative agent of CEM, from all over the world were characterized by field inversion gel electrophoresis of fragments of genomic DNA obtained by digestion with low-cleavage-frequency restriction enzymes. This resulted in a division into five clearly distinct groups. Strains from thoroughbred horses from all continents belonged to one group. Strains from nonthoroughbred horses from various countries were different from strains from thoroughbred horses; four groups could be determined. Two groups contained both streptomycin-resistant and streptomycin-susceptible strains. The data indicate that CEM in nonthoroughbreds did not originate from the thoroughbred population; also, the reverse was not demonstrated. Thus, extensive international transportation directives regarding the testing of nonthoroughbred horses for CEM may need reconsideration.

Genome size of Myxococcus xanthus determined by pulsed-field gel electrophoresis

Genomic DNA of the myxobacterium Myxococcus xanthus was digested with the rare cutting restriction endonuclease AseI or SpeI, and the restriction products were separated by pulsed-field gel electrophoresis. Transposons Tn5-132 and Tn5 lac, which contain AseI restriction sites, were used to determine the number of restriction fragments in each band. The size of the genome was determined by adding the molecular sizes of the restriction products. The genomes of strains DK101, MD2, and DZF1 have identical restriction patterns and were estimated to be 9,454 +/- 101 kilobase pairs from the AseI digestions and 9,453 +/- 106 kilobase pairs from the SpeI digestions. DK1622, which was derived from DK101 by treatment with UV light, has suffered a 220- to 222-kilobase-pair deletion that removed an AseI and an SpeI restriction site. The deleted DNA may consist exclusively of Mx alpha-associated sequences.

Taxonomic differentiation of 101 lactococcal bacteriophages and characterization of bacteriophages with unusually large genomes

Sixty-three virulent bacteriophages of Lactococcus lactis were differentiated by DNA-DNA hybridization. The results, including those of a previous classification of 38 phages of the same bacterial species (P. Relano, M. Mata, M. Bonneau, and P. Ritzenthaler, J. Gen. Microbiol. 133:3053-3063, 1987) show that 48% of the phages analyzed belong to a unique DNA homology group (group III). Phages of this most abundant group had small isometric heads. Group I comprised 29% of the phages analyzed and was characterized by a small phage genome (19 to 22 kilobases) and a particular morphology with a prolate head. Like group III, this group contained representative phages of other classifications. Group II (21%) included virulent and temperate phages with small isometric heads. Two large isometric-headed phages, phi 109 and phi 111, were not related to the three DNA homology groups I, II, and III. The genome of phi 111 was unusually large (134 kilobases) and revealed partial DNA homology with another large isometric phage, 1289, described by Jarvis (type e) (A. W. Jarvis, Appl. Environ. Microbiol. 47:343-349, 1984). The protein compositions of phi 111 and 1289 were similar (three common major proteins of 21, 28, and 32 kilodaltons).

Physical map of the Bacillus cereus chromosome

A physical map of the Bacillus cereus chromosome has been constructed by aligning 11 NotI fragments, ranging in size from 200 to 1,300 kilobases. The size of the chromosome is about 5.7 megabases. This is the first Bacillus genome of which a complete physical map has been described.

Determination of genome size of Pseudomonas aeruginosa by PFGE: analysis of restriction fragments

Genomic DNA size was measured in three strains of Pseudomonas aeruginosa, ATCC 29260 (exotoxin A), ATCC 33467 (type I smooth) and ATCC 33468 (type 2 mucoid) by transverse alternating field electrophoresis of restriction fragments. Because of the high (67%) G + C content of Pseudomonas aeruginosa, restriction enzymes that recognize sequences with at least 4 AT base pairs were expected to be rare cutters. Eight enzymes produced fragments greater than 200 kb in size: Dral (TTT/AAA), Asnl (ATT/AAT), Hpal (GTT/AAC), AfIII (C/TTAAG), Xbal (T/CTAGA), Spel (A/CTAGT), Sspl (AAT/ATT) and Ndel (CA/TATG). All eight enzymes recognized one of three rare tetranucleotide sequences, TTAA, CTAG or ATAT. Pseudomonas aeruginosa strain 29260 has a genomic DNA size of 5573 kb. Strains 33467 and 33468 have identical restriction patterns and a possible deletion with a genomic size of 5407 kb.

Achilles' heel cleavage: creation of rare restriction sites in lambda phage genomes and evaluation of additional operators, repressors and restriction/modification systems

A novel technique for the creation of rare restriction sites was described by Koob et al. [Science 241 (1988) 1084-1086]. This technique, Achilles' heel cleavage (AC), relies on the use of a bound repressor molecule to protect only one of many identical restriction sites from a modification methyltransferase that inactivates all other restriction sites. The technique was applied to a small plasmid and shown to work efficiently with two repressor/operator systems: lac repressor/lacO operator and lambda repressor/lambda oL1 operator. Here, we have extended these results to a lac operator carried by a much larger vector, namely a 44-kb phage lambda construct. In addition, we have evaluated the effect of altering the stability of the lac repressor/lac operator complex by varying both the operator and the repressor. We have also evaluated several more restriction/modification systems (MboI, Dam, MspI and AluI) in addition to HhaI and HaeII used earlier. Finally, we extended the AC technique to a third system, that of the phage 434 repressor and a synthetic 434 operator. From our results we conclude that the AC method should be applicable to the mapping of large genomes and to measuring the strength of operator-repressor interactions. AC could also be applied to identifying and evaluating many different DNA-binding proteins and their sites of action.

The apparent specificity of NotI (5'-GCGGCCGC-3') is enhanced by M.FnuDII or M.BepI methyltransferases (5'-mCGCG-3'): cutting bacterial chromosomes into a few large pieces

The restriction endonuclease (ENase) NotI is blocked by methylation within its recognition sequence at 5'-GCGGCmCGC-3'. This sensitivity to methylation can be used to enhance the specificity of NotI in vivo and in vitro. Modification by M.FnuDII or M.BepI methyltransferases (MTase) (5'-mCGCG-3') will block NotI (5'-GCGGCCGC-3') cleavage at overlapping MTase/ENase sites 5'-CGCGGCCGC-3' (equivalent to 5'-GCGGCCGCG-3'), and increase the apparent cleavage specificity of NotI about twofold. This 'cross-protection' procedure reduces the number of NotI fragments in the genomes of Escherichia coli and Bacillus subtilis, as resolved by pulsed field electrophoresis. Application of this method to large DNAs in vitro requires the preparation of highly purified DNA MTases.

Cleavage at the twelve-base-pair sequence 5'-TCTAGATCTAGA-3' using M.Xbal (TCTAGm6A) methylation and DpnI (Gm6A/TC) cleavage

The DNA methylase M.Xbal was isolated from an E. coli recombinant clone. We deduce that the enzyme methylates at the sequence 5'-TCTAGm6A-3'. In combination with the methylation-dependent restriction endonuclease, DpnI (5'-Gm6A/TC-3'), DNA cleavage occurs at the sequence 5'-TCTAGA/TCTAGA-3'. This twelve-base-pair site should occur once every 16,000,000 base pairs in a random sequence of DNA. The exceptional rarity of the M.XbaI/DpnI sequence makes it an ideal candidate for transpositional integration of a unique cleavage site into bacterial genomes. Retrotransposition into mammalian genomes is also an attractive possibility.

Size of the Streptococcus mutans GS-5 chromosome as determined by pulsed-field gel electrophoresis

Rare cutting restriction endonucleases were used to cut the Streptococcus mutans chromosome into large fragments. Restriction enzymes utilizing recognition sites containing 6-, 7-, or 8-base-pair sequences with only G and C nucleotides produced few fragments, most of which were greater than 100 kilobase pairs in size. Addition of the fragments from digests of SmaI, NotI, ApaI, RsrII, and EagI yielded a molecular size for the S. mutans GS-5 genome of 2,819 +/- 60 kilobase pairs.

Rapid field inversion gel electrophoresis in combination with an rRNA gene probe in the epidemiological evaluation of staphylococci

A rapid field inversion gel electrophoresis (FIGE) protocol was combined with an rRNA gene probe in the analysis of staphylococci that were difficult to study epidemiologically by conventional means. The following groups of clinical isolates were examined: (i) predominantly antibiotic-susceptible Staphylococcus aureus strains containing no detectable plasmids and unresponsive to bacteriophage typing and (ii) methicillin-resistant Staphylococcus epidermidis strains carrying a single plasmid ca. 30 kilobases in size. The results indicated that strain interrelationships could be established on the basis of SmaI-generated chromosomal restriction fragment length polymorphisms (RFLPs) analyzed by FIGE. RFLP analysis of strains known to be unrelated established the importance of minor differences in DNA banding patterns as indicators of strain dissimilarities. Hybridization studies with an rRNA gene probe confirmed this conclusion. These results suggest that FIGE analysis of chromosomal RFLPs (especially in combination with molecular probes) is an important addition to the armamentarium of molecular epidemiology.

The distribution of restriction enzyme sites in Escherichia coli

A statistical analysis of physical map data for eight restriction enzymes covering nearly the entire genome of E. coli is presented. The methods of analysis are based on a top-down modeling approach which requires no knowledge of the statistical properties of the base sequence. For most enzymes, the distribution of mapped sites is found to be fairly homogeneous. Some heterogeneity in the distribution of sites is observed for the enzymes Pstl and HindIII. In addition, BamHI sites are found to be more evenly dispersed than we would expect for random placement and we speculate on a possible mechanism. A consistent departure from a uniform distribution, observed for each of the eight enzymes, is found to be due to a lack of closely spaced sites. We conclude from our analysis that this departure can be accounted for by deficiencies in the physical map data rather than non-random placement of actual restriction sites. Estimates of the numbers of sites missing from the map are given, based both on the map data itself and on the site frequencies in a sample of sequenced E. coli DNA. We conclude that 5 to 15% of the mapped sites represent multiple sites in the DNA sequence.

Expression of CFA/I fimbriae is positively regulated

Production of the plasmid-coded fimbrial antigen CFA/I of Escherichia coli requires both CFA/I region 1 and CFA/I region 2, which are separated by about 40 kb on the wildtype plasmid. The nucleotide sequence of region 2 was determined and contains an open reading frame (cfa d), encoding a protein of 265 amino acids. The protein has no signal sequence and upon sequence analysis appeared to be a DNA-binding protein. A plasmid was constituted, with a promoterless beta-galactosidase gene preceded by the promoter of region 1. Introduction of a plasmid, carrying the cfa d gene, into a strain containing this construct enhanced expression of beta-galactosidase by at least five-fold indicating that the cfa d protein was enhancing expression from the promoter of region 1. The cfa d gene sequence differed at 28 positions from the Rns gene, which encodes a protein that is a positive regulator of the expression of CS1 or CS2 fimbriae. It was shown that the cfa d gene and the Rns gene can functionally substitute each other in regulating fimbrial synthesis.

Chromosome map of the thermophilic archaebacterium Thermococcus celer

A physical map for the chromosome of the thermophilic archaebacterium Thermococcus celer Vu13 has been constructed. Thirty-four restriction endonucleases were tested for their ability to generate large restriction fragments from the chromosome of T. celer. Of these, the enzymes NheI, SpeI, and XbaI yielded the fewest fragments when analyzed by pulsed-field electrophoresis. NheI and SpeI each gave 5 fragments, while XbaI gave 12. The size of the T. celer chromosome was determined from the sum of the apparent sizes of restriction fragments derived from single and double digests by using these enzymes and was found to be 1,890 +/- 27 kilobase pairs. Partial and complete digests allowed the order of all but three small (less than 15 kilobase pairs) fragments to be deduced. These three fragments were assigned positions by using hybridization probes derived from these restriction fragments. The positions of the other fragments were confirmed by using hybridization probes derived in the same manner. The positions of the 5S, 16S, and 23S rRNA genes as well as the 7S RNA gene were located on this map by using cloned portions of these genes as hybridization probes. The 5S rRNA gene was localized 48 to 196 kilobases from the 5' end of the 16S gene. The 7S RNA gene was localized 190 to 504 kilobases from the 3' end of the 23S gene. These analyses demonstrated that the chromosome of T. celer is a single, circular DNA molecule. This is the first such demonstration of the structure of an archaebacterial chromosome.

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.

Cloning of the complete Mycoplasma pneumoniae genome

The complete genome of Mycoplasma pneumoniae was cloned in an ordered library consisting of 34 overlapping or adjacent cosmids, one plasmid and two lambda phages. The genome size was determined by adding up the sizes of either the individual unique EcoRI restriction fragments of the gene bank or of the XhoI fragments of genomic M. pneumoniae DNA. The values from these calculations, 835 and 849 kbp, are in good agreement. An XhoI restriction map was constructed by identifying adjacent DNA fragments by probing with selected cosmid clones.

Use of low-frequency-cleavage restriction endonucleases for DNA analysis in epidemiological investigations of nosocomial bacterial infections

Epidemiological investigations of bacterial infections are generally based on multiple phenotypic markers that are often difficult to verify. A more general and reliable method is genomic DNA analysis by restriction endonucleases. However, the commonly used endonucleases produce too many fragments for correct separation by agarose electrophoresis. In contrast, simple electrophoretic patterns are obtained after genomic DNA digestion by low-frequency-cleavage restriction endonucleases and pulsed-field gel electrophoresis, making it easier to compare numerous strains from the same species. This technique was used to investigate an Acinetobacter calcoaceticus outbreak in a urologic department and bronchial colonization of artificially ventilated patients by Pseudomonas aeruginosa in an intensive care unit. The method allowed a clear distinction between epidemic and self-contaminating strains in these different epidemiological situations.