Determination of genome size of Haemophilus influenzae Sb: analysis of DNA restriction fragments.

Genomic DNA size was measured in clinical isolates of Haemophilus influenzae by Pulsed-Field Gel Electrophoresis of DNA restriction fragments. Because of the high (64%) A+T content of H. influenzae DNA, restriction enzymes that recognize sequences with at least four GC base pairs were expected to be rare cutters. Five enzymes that produced fragments greater than 200 kb in size were used to digest intact chromosomes and fragments resolved by TAFE and/or FIGE: ApaI (GGGCCC), EagI (CGGCCG), NotI (GCGGCCGC), RsrI (CGGA/TCCG), and SmaI (CCCGGG). All five had recognition sequences with at least six GC base pairs. The genomic DNA size of H. influenzae serotype b, estimated with ApaI, EagI, NotI, RsrII, and SmaI, is 1,950 kb.     

Restriction fragment fingerprint and genome sizes of Staphylococcus species using pulsed-field gel electrophoresis and infrequent cleaving enzymes.

Large restriction fragments of genomic DNA from Staphylococcus species were separated by pulsed-field gel electrophoresis (PFGE). Five different strains of S. aureus (ISP8, SAU3A, PS96, ATCC 6538, ATCC 15564) and three representative strains of S. haemolyticus SM102, S. warneri MCS4, S. cohnii LK478 from human hosts, and one strain of S. aureus (ATCC 8432) from an avian host were used in this study. Since Staphylococcus is A + T rich (approximately 67%), restriction fragments were obtained by digesting chromosomal DNA with endonucleases that recognize GC-rich sequences. Five enzymes Csp I, Sma I, Ecl XI, Ksp I, or Sac II were used for generation of few (7 to 16) distinctly separated fragments, with average sizes in the range of 200-300 kb. The size distribution of restriction fragments for each enzyme for each strain produced a strain-identifying fingerprint, and the genome size of each strain was determined from such restriction fragments separated by PFGE.     

Genome analysis of Pseudomonas aeruginosa by field inversion gel electrophoresis

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

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.     

A 'Southern Cross' method for the analysis of genome organization and the localization of transcription units

A 'Southern Cross' hybridization method is described which permits the rapid restriction mapping of DNA molecules, up to 40 kb in size, for at least ten enzymes in a single operation. The procedure allows the full set of 32P-end-labelled fragments derived from one restriction enzyme digest to intersect and attempt to hybridize to the gel-separated fragments of as many as ten unlabelled digests immobilized on parallel sheets of filter paper. A two-dimensional array of hybridization spots is revealed on each recipient paper, indicating which radioactive and non-radioactive DNA fragments have sequences in common. A restriction map can then be directly and simply deduced from the matrix of hybridization spots in each cross-blot. The method affords advantages over other procedures for obtaining restriction maps in terms of the time required, the number of restriction enzymes that can be mapped, and the potential for eliminating ambiguity. It is also sufficiently sensitive to detect DNA rearrangements and restriction-site polymorphisms in moderately complex genomes. Furthermore, the procedure is applicable to other aspects of the study of genome organization: for example, the exon and intron areas of a segment of cloned genomic DNA can be identified by cross-hybridizing a set of radioactive restriction fragments from the genomic clone against immobilized RNA from a cell type of interest.     

Genetic heterogeneity among keto-acid-producing strains of Gluconobacter oxydans

The genomes of four keto-acid-producing Gluconobacter oxydans strains (ATCC9937, IFO3293, IFO12258 and DSM2343) were analysed by pulse-field gel electrophoresis (PFGE). PFGE of undigested DNA allowed the detection of plasmids in the following strains: ATCC9937 (3 plasmids; 8, 27, 31 kb), IFO3293 (9 kb), DSM2343 (21 kb). The three plasmids in ATCC9937 showed no homology to each other or to plasmids in the other strains. Seventeen restriction enzymes were tested for use in PFGE analysis of the G. oxydans strains and XbaI was chosen for restriction fragment analysis of the genomes. Fairly good resolution of restriction fragments at all size ranges was achieved by using three different pulse–time programs. The genome sizes of the four strains were estimated to be between 2240 kb and 3787 kb. The XbaI restriction patterns of the four strains showed no similarities to each other. Ten random cosmid clones of ATCC9937 were used as hybridization probes against the four strains, but, with the exception of one clone, hybridization signals were only observed with ATCC9937 itself. These data show that the four strains are not closely related.     

Sizing of the Leptospira genome by pulsed-field agarose gel electrophoresis

Pulsed-field gel electrophoresis allowed the determination of the size of the genome of Leptospira, a bacterium of the spirochete family. The three restriction enzymes, NotI (5'GC/GGCCGC), NheI (5'G/CTAGC), ApaI (5'-GGGCC/C) generated DNA fragments of suitable size. The results are compatible with a size of 5000 kb for the chromosome of both the pathogenic and the saprophytic species of Leptospira.     

Physical and genetic mapping of the Rhodobacter sphaeroides 2.4.1 genome: genome size, fragment identification, and gene localization.

Four restriction endonucleases, AseI (5'-ATTAAT), SpeI (5'-ACTAGT), DraI (5'-TTTAAA), and SnaBI (5'-TACGTA), generated DNA fragments of suitable size distributions for mapping the genome of Rhodobacter sphaeroides by transverse alternating field electrophoresis. AseI produced 17 fragments, ranging in size from 3 to 1,105 kilobases (kb), SpeI yielded 16 fragments (12 to 1,645 kb), DraI yielded at least 25 fragments (6 to 800 kb), and SnaBI generated 10 fragments (12 to 1,225 kb). A total genome size of approximately 4,400 +/- 112 kb was determined by summing the fragment lengths in each of the digests generated by using the different restriction endonucleases. The total genomic DNA consisted of chromosomal DNA (3,960 +/- 112 kb) and the five endogenous plasmids (approximately 450 kb total) whose cognate DNA fragments have been unambiguously identified. A number of genes have been physically mapped to the AseI-generated restriction endonuclease fragments of total genomic DNA by Southern hybridization analysis with either homologous or heterologous specific gene probes or, in the case of several auxotrophic and pigment-biosynthetic mutants apparently generated by Tn5, a Tn5-specific probe. Other genes have been mapped by a comparison with wild-type patterns of the electrophoretic banding patterns of the AseI-digested genomic DNA derived from mutants generated by the insertion of either kanamycin or spectinomycin-streptomycin resistance cartridges. The relative orientations, distance, and location of the pufBALMX, puhA, cycA, and pucBA operons have also been determined, as have been the relative orientations between prkB and hemT and between prkA and the fbc operon.     

A combined physical and genetic map of Pseudomonas aeruginosa PAO

A combined physical and genetic map of Pseudomonas aeruginosa PAO was constructed by pulsed-field gel electrophoresis and Southern hybridization using cosmid clones from a genomic library carrying known genes. A total of 37 SpeI restriction fragments have been mapped on the 5862 kb genome, and fragment contiguity demonstrated by hybridization with clones from a SpeI junction fragment library and fragments obtained by partial SpeI digestion, both derived from the P. aeruginosa PAO chromosome.     

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

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

Identification of a plasmid-borne parathion hydrolase gene from Flavobacterium sp. by southern hybridization with opd from Pseudomonas diminuta.

Parathion hydrolases have been previously described for an American isolate of Pseudomonas diminuta and a Philippine isolate of Flavobacterium sp. (ATCC 27551). The gene which encodes the broad-spectrum organophosphate phosphotriesterase in P. diminuta has been shown by other investigators to be located on a 66-kilobase (kb) plasmid. The intact gene (opd, organophosphate-degrading gene) from this degradative plasmid was cloned into M13mp10 and found to express parathion hydrolase under control of the lac promoter in Escherichia coli. In Flavobacterium sp. strain ATCC 27551, a 43-kb plasmid was associated with the production of parathion hydrolase by curing experiments. The M13mp10-cloned fragment of the opd gene from P. diminuta was used to identify a homologous genetic region from Flavobacterium sp. strain ATCC 27551. Southern hybridization experiments demonstrated that a genetic region from the 43-kb Flavobacterium sp. plasmid possessed significant homology to the opd sequence. Similar hybridization did not occur with three other native Flavobacterium sp. plasmids (approximately 23, 27, and 51 kb) present within this strain or with genomic DNA from cured strains. Restriction mapping of various recombinant DNA molecules containing subcloned fragments of both opd plasmids revealed that the restriction maps of the two opd regions were similar, if not identical, for all restriction endonucleases tested thus far. In contrast, the restriction maps of the cloned plasmid sequences outside the opd regions were not similar. Thus, it appears that the two discrete bacterial plasmids from parathion-hydrolyzing soil bacteria possess a common but limited region of sequence homology within potentially nonhomologous plasmid structures.     

Genome map of Campylobacter fetus subsp. fetus ATCC 27374

Abstract A physical map of the chromosome of Campylobacter fetus subsp. fetus was constructed by using pulsed-field gel electrophoresis of restriction fragments generated by Sal I, Sma I and Not I. Digestion of the type strain ATCC 27374 with these restriction endonucleases resulted in generating 4–14 fragments. The order of the fragments was deduced from hybridization of these restriction fragments to Southern blots of pulsed-field gel electrophoresis gels generated by the other two enzymes. The estimated genome size was 1160 kb. The position of several homologous and heterologous genes was determined on the circular map. These included the 2.8-kb sapA gene, encoding the 97-kDa surface array protein. Three copies of ribosomal RNA genes for which the 16S, 23S and 5S rRNA appeared to be located in close proximity in each of the three regions. The RNA polymerase genes rpoA , rpoB , and rpoD were mapped and appeared to be situated close together in one region. The flagellin genes ( flaAB ) of C. jejuni and the gyrase genes gyrA and gyrB of C. perfringens and Bacillus subtilis , respectively, were used to identify the locations of flaAB , the gyrA and the gyrB genes on the ATCC 27374 chromosome.     

Identification of Campylobacter jejuni ATCC 43431-specific genes by whole microbial genome comparisons

This study describes a novel approach to identify unique genomic DNA sequences from the unsequenced strain C. jejuni ATCC 43431 by comparison with the sequenced strain C. jejuni NCTC 11168. A shotgun DNA microarray was constructed by arraying 9,600 individual DNA fragments from a C. jejuni ATCC 43431 genomic library onto a glass slide. DNA fragments unique to C. jejuni ATCC 43431 were identified by competitive hybridization to the array with genomic DNA of C. jejuni NCTC 11168. The plasmids containing unique DNA fragments were sequenced, allowing the identification of up to 130 complete and incomplete genes. Potential biological roles were assigned to 66% of the unique open reading frames. The mean G+C content of these unique genes (26%) differs significantly from the G+C content of the entire C. jejuni genome (30.6%). This suggests that they may have been acquired through horizontal gene transfer from an organism with a G+C content lower than that of C. jejuni. Because the two C. jejuni strains differ by Penner serotype, a large proportion of the unique ATCC 43431 genes encode proteins involved in lipooligosaccharide and capsular biosynthesis, as expected. Several unique open reading frames encode enzymes which may contribute to genetic variability, i.e., restriction-modification systems and integrases. Interestingly, many of the unique C. jejuni ATCC 43431 genes show identity with a possible pathogenicity island from Helicobacter hepaticus and components of a potential type IV secretion system. In conclusion, this study provides a valuable resource to further investigate Campylobacter diversity and pathogenesis.     

Genome analysis of Clostridium botulinum type A by pulsed-field gel electrophoresis.

Genomic DNA from type A Clostridium botulinum was digested with restriction endonucleases that cut at rare sites, and the large fragments were separated by pulsed-field gel electrophoresis. Of 15 restriction enzymes tested, MluI, RsrII, SmaI, NruI, KspI, NaeI, and XhoI generated satisfactory digestion patterns of genomic DNA of various C. botulinum strains, enabling the use of the method for genomic fingerprinting. The genomes of four group I (type A) C. botulinum strains examined had similar restriction patterns. However, each strain had unique digestion patterns, reflecting genotypic differences. The genome size of C. botulinum strain 62A was estimated to be 4,039 +/- 40 kbp from the summation of restriction fragments from MluI, RsrII, and SmaI digestions. Genes encoding proteins involved in the toxinogenicity of C. botulinum, including neurotoxin, hemagglutinin A, and genes for a temperate phage, as well as various transposon Tn916 insertion sites in C. botulinum 62A, were mapped by pulsed-field gel electrophoresis. The genes encoding neurotoxin and hemagglutinin A-1, were located on the same fragment in several cases, indicating their probable physical linkage. The macrorestriction analysis established here should be useful for genetic and epidemiological studies of C. botulinum.     

Macrorestriction Analysis of Caenorhabditis Elegans Genomic DNA

The usefulness of genomic physical maps is greatly enhanced by linkage of the physical map with the genetic map. We describe a ``macrorestriction mapping' procedure for Caenorhabditis elegans that we have applied to this endeavor. High molecular weight, genomic DNA is digested with infrequently cutting restriction enzymes and size-fractionated by pulsed field gel electrophoresis. Southern blots of the gels are probed with clones from the C. elegans physical map. This procedure allows the construction of restriction maps covering several hundred kilobases and the detection of polymorphic restriction fragments using probes that map several hundred kilobases away. We describe several applications of this technique. (1) We determined that the amount of DNA in a previously uncloned region is <220 kb. (2) We mapped the mes-1 gene to a cosmid, by detecting polymorphic restriction fragments associated with a deletion allele of the gene. The 25-kb deletion was initially detected using as a probe sequences located ~400 kb away from the gene. (3) We mapped the molecular endpoint of the deficiency hDf6, and determined that three spontaneously derived duplications in the unc-38-dpy-5 region have very complex molecular structures, containing internal rearrangements and deletions.     

Detection of elastase production in Escherichia coli with the elastase structural gene from several non-elastase-producing strains of Pseudomonas aeruginosa.

The elastase structural gene from Pseudomonas aeruginosa IFO 3455 has been cloned and sequenced. Using this gene as a probe, we cloned the DNA fragments (pEL3080R, pEL10, and pEL103R) of the elastase gene from non-elastase-producing strains (P. aeruginosa IFO 3080, N-10, and PA103 respectively). These three Pseudomonas strains showed no detectable levels of elastase antigenicity by Western blotting (immunoblotting) or by elastase activity. When elastase structural genes about 8 kb in length were cloned into pUC18, an Escherichia coli expression vector, we were able to detect both elastase antigenicity and elastolytic activity in two bacterial clones (E. coli pEL10 and E. coli pEL103R). However, neither elastolytic activity nor elastase antigenicity was detected in the E. coli pEL3080R clone, although elastase mRNA was observed. The partial restriction map determined with several restriction enzymes of these three structural genes corresponded to that of P. aeruginosa IFO 3455. We sequenced the three DNA segments of the elastase gene from non-elastase-producing strains and compared the sequences with those from the elastase-producing P. aeruginosa strains IFO 3455 and PAO1. In P. aeruginosa N-10 and PA103, the sequences were almost identical to those from elastase-producing strains, except for several nucleotide differences. These minor differences may reflect a microheterogeneity of the elastase gene. These results suggest that two of the non-elastase-producing strains have the normal elastase structural gene and that elastase production is repressed by regulation of this gene expression in P. aeruginosa. Possible reasons for the lack of expression in these two strains are offered in this paper. In P. aeruginosa IFO 3080, the sequence had a 1-base deletion in the coding region, which should have caused a frameshift variation in the amino acid sequence. At present, we have no explanation for the abnormal posttransciptional behavior of this strain.     

Pulsed-field gel electrophoresis analysis of the genome of Streptomyces ambofaciens strains

The genome of four Streptomyces ambofaciens strains from different geographical origins (ATCC15154, DSM40697, ETH9247 and ETH 11317) was analysed by pulsed-field gel electrophoresis (PFGE). The PFGE technique has allowed the study of the extrachromosomal content of these strains and the characterization of their genomic DNA by restriction analyses. Electrophoretic migration of undigested DNA allowed us to detect a 80 kb-length linear molecule with concatemeric forms in S. ambofaciens ATCC15154. These extrachromosomal molecules were shown to be homologous to the circular plasmid pSAM1 (80 kb) suggesting that pSAM1 could exist not only in circular form but also in linear form. In the same way a 45 kb-length linear molecule was detected in S. ambofaciens ETH9427 and ETH11317. In contrast, no extrachromosomal DNA could be detected in S. ambofaciens DSM40697. The analysis of the macrorestriction patterns using the rate-cutting enzymes AseI and DraI indicated a close relationship between the DSM- and ETH- strains. Indeed, three types of restriction patterns were distinguished: while S. ambofaciens ETH9427 and ETH11317 were characterized by the same pattern and share more than 75% of comigrating fragments with the strain DSM40697, S. ambofaciens ATCC15154 exhibited a restriction pattern different from the other three. The total genome sizes of S. ambofaciens ATCC15154, DSM40697, ETH9427 and ETH11317 were estimated to be about 6500, 8000, 8200 and 8200 kb, respectively.     

Organization of delta-crystallin genes in the chicken.

Double-stranded DNA was synthesized from delta-crystallin mRNA prepared from lens fibers of 15-day-old chick embryos and cloned at the Pst I site of the plasmid pBR322. Using the cloned cDNA and single-stranded cDNA as hybridization probes, a number of genomic DNA fragments containing delta-crystallin gene sequences have been cloned from the partial and complete EcoRI digests of chick brain DNA. One of the clones from the partial digests contains a DNA fragment that consists of four EcoRI fragments of 7.6 kb, 4.0 kb, 2.6 kb, and 0.8 kb. The gene sequences reside in the (5')7.6 kb - 0.8 kb - 4.0 kb (3') fragments. Electron microscopy has provided evidence that the cloned DNA fragment includes the entire gene sequences complementary to delta-crystallin mRNA except for the 3' terminal poly(A) tail, and that the delta-crystallin gene is interrupted by at least 13 intervening sequences. Another clone contains a genomic fragment that consists of two EcoRI fragments of 3.0 kb and 11 kb. The DNA fragment in the latter clone represents a different delta-crystallin gene, as judged by restriction endonuclease mapping and by electron microscopy.     

Distribution of potential type II restriction sites (palindromes) in prokaryotes

Restriction-modification systems are used as a defensive mechanism against inappropriate invasion of foreign DNA. The recognition sequences for the common type II restriction enzymes and their corresponding methylases are usually palindromes. In this study, we identified the most over- and underrepresented words in DNA of four bacteria: Escherichia coli, Bacillus subtilis, Clostridium perfringens, and Pseudomonas aeruginosa. Using maximum order Markov chain analysis, we found that palindromic words were most often more underrepresented than their non-palindromic counterparts. No strict rule for the intragenic palindrome content could be derived, but for three of the bacteria there was a weak correlation between codon usage bias and palindrome content. A clear drop in palindrome counts was observed in the Shine-Dalgarno region for B. subtilis and C. perfringens, but not in E. coli or P. aeruginosa. It was also shown that palindromes in eubacteria and archaebacteria seem to occur slightly more infrequently than expected on the basis of the genomic GC-content, but some exceptions to this principle exist.     

Sheep elastin genes. Isolation and preliminary characterization of a 9.9-kilobase genomic clone

A sheep genomic library containing sheep DNA in the bacteriophage vector Charon 4A was screened for elastin-gene sequences with partially purified, 32P-labelled elastin mRNA (mRNAE). A recombinant containing a 9.9-kb (kilobase) insert was selected from several positive clones by secondary and tertiary screening for further characterization. Positive identification of this elastin clone, designated SE1, was made with radiolabelled mRNAE by hydridization-selected translation and Southern blotting of restriction-enzyme fragments of SE1 DNA. Hybridization of either mRNAE or elastin complementary DNA to restriction fragments of SE1 showed that most of these fragments of SE1 contained elastin-coding sequences. Orientation of the insert was established by preferential hybridization of a short complementary elastin DNA to restriction fragments adjacent to the right arm of Charon 4A. Reciprocal hybridizations of nick-translated SE1 and sheep genomic DNA on Southern blots showed that two restriction fragments of SE1 contained sequence elements which were repeated at high frequency in a restriction-endonuclease-EcoR1 digest of total sheep genomic DNA. In the accompanying paper [Davidson, Shibahara, Boyd, Mason, Tolstoshev & Crystal (1984) Biochem. J. 220, 653-663], it is shown that a subcloned fragment of this elastin gene quantitatively and specifically hybridized to mRNAE sequences in sheep tissue RNA. Electron microscopy of SE1-mRNAE hybrids indicated the presence of at least seven large R-loops. Measurements of these structures indicated that SE1 is likely to contain less than 2 kb of coding sequence and more than 8 kb of intervening sequence, with an average exon size of 120 base-pairs. Thus the elastin gene is distributed over an extended region of the sheep genome and contains numerous intervening and coding sequences.