Analysis of DNA from various species and strains of malaria parasites by restriction endonuclease fingerprinting

1. DNA from various rodent Plasmodium species and strains and from P. falciparum, the human parasite, were analysed by agarose gel electrophoresis following digestion with restriction endonucleases EcoRI, Hind III and Bam Hl. Complex patterns of ethidium-stained bands were obtained, which showed similarity but reproducible differences among the various parasite species (P. chabaudi, P. yoelii, P. berghei and P. falciparum). 2. No differences could be discerned among two cloned strains of P. yoelii (33X, and YM) and among pyrimethamine-resistant (pyrimethamine + chloroquine)-resistant and the drug-sensitive P. chabaudi clone from which the resistant clones were derived. 3. From the known complexity of Plasmodium DNA it could be concluded that the visible bands were derived from repetitive DNA fractions.     

Characterization of the DNA of rodent herpesviruses by restriction endonuclease analysis and hybridization.

Restriction endonuclease analysis, dot-blot hybridization, and dried gel hybridization were used to differentiate mouse cytomegalovirus, rat cytomegalovirus, and mouse herpesvirus strain 76. Viral DNA was obtained directly from virus-infected mouse or rat cells. Restriction endonuclease digestion was performed by standard methods with BamHI, EcoRI, HindIII, and PstI, and DNA was analyzed by electrophoresis on agarose gels. Cross-hybridization was used to determine the degree of genetic homology among the three viruses. Electrophoretic patterns revealed clear differences between mouse cytomegalovirus and rat cytomegalovirus restriction profiles. Extensive comigration of DNA was observed for rat cytomegalovirus and mouse herpesvirus strain 76. Both viruses also shared common DNA sequences. These results suggest that mouse herpesvirus strain 76 is probably a rat cytomegalovirus strain infecting mice.     

DNA-DNA hybridization and analysis of restriction endonuclease and rRNA gene patterns of atypical (catalase-weak/negative) Campylobacter jejuni from paediatric blood and faecal cultures.

Sixteen strains of atypical (catalase-weak or negative), hippurate-hydrolysing campylobacters from paediatric blood and faecal cultures were identified by DNA-DNA slot hybridization. All were closely related (greater than or equal to 67%) to Campylobacter jejuni and representative strains had G + C contents of 30 +/- 1 mol%. Numerical analysis of chromosomal DNA HaeIII digest patterns revealed two clusters of strains at the 55%S level corresponding to C. jejuni subsp. jejuni and C. jejuni subsp. doylei; most strains belonged to the latter subspecies. No two strains had identical patterns but within each subspecies two subgroups were identifiable, corresponding to Lior biotypes I and II. Southern blot hybridization analysis with a 16 + 23S rRNA cistron probe from Escherichia coli also showed differences between the various strains, and in a numerical analysis three groupings were formed at 70%S corresponding to C. jejuni subsp. jejuni Lior biotypes I and II, and C. jejuni subsp. doylei. Four of the subspecies doylei strains contained a 3.4-MDa plasmid. These analyses showed that catalase-negative C. jejuni subsp. jejuni were genomically distinguishable from C. jejuni subsp. doylei as were Lior biotypes within subsp. jejuni. Ability to produce catalase is not a feature common to all C. jejuni strains, and our results confirm that some strains of subspecies jejuni may be negative in that character although typical in other respects. DNA pattern heterogeneity was consistent with serological differences between strains.     

Relationship between genome similarity and DNA-DNA hybridization among closely related bacteria

DNA-DNA hybridization has been established as an important technology in bacterial species taxonomy and phylogenetic analysis. In this study, we analyzed how the efficiency with which the genomic DNA from one species hybridizes to the genomic DNA of another species (DNA-DNA hybridization) in microarray analysis relates to the similarity between two genomes. We found that the predicted DNA-DNA hybridization based on genome sequence similarity correlated well with the experimentally determined microarray hybridization. Between closely related strains, significant numbers of highly divergent genes (<55% identity) and/or the accumulation of mismatches between conserved genes lowered the DNA-DNA hybridization signal, and this reduced the hybridization signals to below 70% for even bacterial strains with over 97% 16S rRNA gene identity. In addition, our results also suggest that a DNA-DNA hybridization signal intensity of over 40% indicates that two genomes at least shared 30% conserved genes (>60% gene identity). This study may expand our knowledge of DNA-DNA hybridization based on genomic sequence similarity comparison and further provide insights for bacterial phylogeny analyses.     

Characterization of Dutch porcine Serpulina (Treponema) isolates by restriction endonuclease analysis and DNA hybridization.

Genomes of 55 Dutch porcine Serpulina (Treponema) hyodysenteriae and non-pathogenic Serpulina isolates were characterized by restriction endonuclease analysis (REA) and DNA hybridization. The Dutch porcine isolates were compared with American Type Culture Collection (ATCC) strains of S. hyodysenteriae and S. innocens and isolates of S. hyodysenteriae with known serotypes (reference strains). REA of the Dutch S. hyodysenteriae isolates resulted in two main patterns, while the non-pathogenic isolates had many distinct REA patterns, all different from the S. hyodysenteriae strains. The S. hyodysenteriae reference strains all had distinct REA patterns, different from the Dutch strains. Upon Southern hybridization with a S. hyodysenteriae DNA fragment encoding a flagellar protein, all S. hyodysenteriae strains could be divided in two groups. The non-pathogenic Serpulina strains had many distinct hybridization patterns and hybridized less intensely. Upon hybridization with a S. hyodysenteriae DNA fragment encoding a haemolysin, DNA of all S. hyodysenteriae strains reacted in the same band. DNA of non-pathogenic Dutch Serpulina strains and S. innocens did not hybridize. It was concluded that there are two main genotypes of S. hyodysenteriae in the Netherlands. This could be of importance for recombinant DNA vaccine development.     

DNA-DNA hybridization and analysis of restriction endonuclease and rRNA gene patterns of atypical (catalase-weak/negative) Campylobacter jejuni from paediatric blood and faecal cultures

Sixteen strains of atypical (catalase-weak or negative), hippurate-hydrolysing campylobacters from paediatric blood and faecal cultures were identified by DNA–DNA slot hybridization. All were closely related ( 67%) to Campylobacter jejuni and representative strains had G + C contents of 30 ± 1 mol%. Numerical analysis of chromosomal DNA Hae III digest patterns revealed two clusters of strains at the 55%S level corresponding to C. jejuni subsp. jejuni and C. jejuni subsp. doylei ; most strains belonged to the latter subspecies. No two strains had identical patterns but within each subspecies two subgroups were identifiable, corresponding to Lior biotypes I and II. Southern blot hybridization analysis with a 16 + 23S rRNA cistron probe from Escherichia coli also showed differences between the various strains, and in a numerical analysis three groupings were formed at 70%S corresponding to C. jejuni subsp. jejuni Lior biotypes I and II, and C. jejuni subsp. doylei . Four of the subspecies doylei strains contained a 3·4-MDa plasmid. These analyses showed that catalase-negative C. jejuni subsp. jejuni were genomically distinguishable from C. jejuni subsp. doylei as were Lior biotypes within subsp. jejuni . Ability to produce catalase is not a feature common to all C. jejuni strains, and our results confirm that some strains of subspecies jejuni may be negative in that character although typical in other respects. DNA pattern heterogeneity was consistent with serological differences between strains.     

Characterization of Actinobacillus pleuropneumoniae riboflavin biosynthesis genes.

In this paper, we report the identification, cloning, and complete nucleotide sequence of four genes from Actinobacillus pleuropneumoniae that are involved in riboflavin biosynthesis. The cloned genes can specify production of large amounts of riboflavin in Escherichia coli, can complement several defined genetic mutations in riboflavin biosynthesis in E. coli, and are homologous to riboflavin biosynthetic genes from E. coli, Haemophilus influenzae, and Bacillus subtilis. The genes have been designated A. pleuropneumoniae ribGBAH because of their similarity in both sequence and arrangement to the B. subtilis ribGBAH operon.     

DNA-DNA hybridization in the systematics of Streptomyces.

The DNA relatedness among strains in several different phenotypically defined Streptomyces species clusters was evaluated. It was found that the data from DNA-relatedness studies do not necessarily agree with the clustering generated using numerical taxonomic techniques. A study of the morphologically heterogeneous 'S. cyaneus' cluster showed that morphological criteria traditionally used to classify and identify Streptomyces species still have value, since strains in DNA-relatedness cluster groups were also similar morphologically (i.e., they had similar spore color, surface properties, and sporophore morphology). An evaluation of DNA relatedness among strains in the S. violaceusniger and S. lavendulae clusters indicated that, if anything, the genus is underspeciated, based on the number of single-member clusters observed. A study of strains of the sweet potato pathogen, S. ipomoea, collected in various locations in the United States and Japan indicated, not surprisingly, that all of the strains belong to the same species.     

Growth of Actinobacillus pleuropneumoniae is promoted by exogenous hydroxamate and catechol siderophores.

Siderophores bind ferric ions and are involved in receptor-specific iron transport into bacteria. Six types of siderophores were tested against strains representing the 12 different serotypes of Actinobacillus pleuropneumoniae. Ferrichrome and bis-catechol-based siderophores showed strong growth-promoting activities for A. pleuropneumoniae in a disk diffusion assay. Most strains of A. pleuropneumoniae tested were able to use ferrichrome (21 of 22 or 95%), ferrichrome A (20 of 22 or 90%), and lysine-based bis-catechol (20 of 22 or 90%), while growth of 36% (8 of 22) was promoted by a synthetic hydroxamate, N5-acetyl-N5-hydroxy-L-ornithine tripeptide. A. pleuropneumoniae serotype 1 (strain FMV 87-682) and serotype 5 (strain 2245) exhibited a distinct yellow halo around colonies on Chrome Azurol S agar plates, suggesting that both strains can produce an iron chelator (siderophore) in response to iron stress. The siderophore was found to be neither a phenolate nor a hydroxamate by the chemical tests of Arnow and Csaky, respectively. This is the first report demonstrating the production of an iron chelator and the use of exogenous siderophores by A. pleuropneumoniae. A spermidine-based bis-catechol siderophore conjugated to a carbacephalosporin was shown to inhibit growth of A. pleuropneumoniae. A siderophore-antibiotic-resistant strain was isolated and shown to have lost the ability to use ferrichrome, synthetic hydroxamate, or catechol-based siderophores when grown under conditions of iron restriction. This observation indicated that a common iron uptake pathway, or a common intermediate, for hydroxamate- and catechol-based siderophores may exist in A. pleuropneumoniae.     

Actinobacillus pleuropneumoniae haemolysin II is secreted from Escherichia coli by A. pleuropneumoniae pleurotoxin secretion gene products

Abstract Actinobacillus pleuropneumoniae serotype 2 secretes type II haemolysin and pleurotoxin activities. Here, the genes for type II haemolysin were cloned in Escherichia coli , but type II haemolysin antigen and haemolysin activity were only detected intracellularly and not exported to culture supernatant. It has been reported that the genes for type II haemolysin are not linked to functional secretion genes, while those for pleurotoxin are. In this report the means of secretion of type II haemolysis was examined by constructing a hybrid plasmid carrying the genes required for type II haemolysin expression, together with determinants which allow secretion of pleurotoxin and are linked to the pleurotoxin toxin genes. These genes facilitated the export of type II haemolysin from E. coli , and may perform this function in A. pleuropneumoniae .     

Preferential site-dependent cleavage by restriction endonuclease PstI.

The four identical recognition sites for the restriction endonuclease PstI in purified plasmid pSM1 DNA I are cleaved at markedly different rates. The order and relative frequencies of cleavage at these four PstI sites have been determined from the order of appearance of partial cleavage products and from an analysis of production of specific unit length linear molecules. The same pattern of preferential cleavage is also found when linear, nicked circular, or relaxed closed circular forms of the same plasmid DNa are used as substrates for PstI. Inspection of the nucleotide sequences immediately adjoining each of the PstI sites suggests that the presence of adjacent runs of G-C base pairs confers significant resistance to cleavage.     

Actinobacillus pleuropneumoniae: pathobiology and pathogenesis of infection

Actinobacillus pleuropneumoniae causes porcine pleuropneumonia, a highly contagious disease for which there is no effective vaccine. This review considers how adhesins, iron-acquisition factors, capsule and lipopolysaccharide, RTX cytotoxins and other potential future vaccine components contribute to colonisation, to avoidance of host clearance mechanisms and to damage of host tissues.     

DNA restriction patterns and DNA-DNA solution hybridization studies of Frankia isolates from Myrica pennsylvanica (bayberry)

Sixteen Frankia strains were isolated from Myrica pennsylvanica (bayberry) root nodules collected at diverse sites in New Jersey. Restriction pattern analysis of total genomic DNA was used to group the isolates into gel groups, and the genetic relatedness among the isolates was evaluated by DNA-DNA solution hybridization studies. Restriction pattern analysis provided a distinctive reproducible fingerprint for each isolate. Isolates fell into nine separate groups (strain types). More than one strain type was isolated from most sites. Isolates from two different gel groups were found in 3 of 10 nodules examined. Of the 16 isolates, 10 contained extrachromosomal DNA. Six different extrachromosomal DNA banding patterns were found. Genomically similar isolates carried related, but different, banding patterns. DNA hybridization studies indicated that isolates from a single plant species can be minimally related as determined by total genome homology. Homology ranged from 12 to 99%. Highly divergent strains were isolated from the same plant and found to cohabit the same nodule. Thus, this study demonstrated that Frankia strains which infect the same host plant are not only phenotypically different but also genetically diverse.     

DNA restriction patterns and DNA-DNA solution hybridization studies of Frankia isolates from Myrica pennsylvanica (bayberry).

Sixteen Frankia strains were isolated from Myrica pennsylvanica (bayberry) root nodules collected at diverse sites in New Jersey. Restriction pattern analysis of total genomic DNA was used to group the isolates into gel groups, and the genetic relatedness among the isolates was evaluated by DNA-DNA solution hybridization studies. Restriction pattern analysis provided a distinctive reproducible fingerprint for each isolate. Isolates fell into nine separate groups (strain types). More than one strain type was isolated from most sites. Isolates from two different gel groups were found in 3 of 10 nodules examined. Of the 16 isolates, 10 contained extrachromosomal DNA. Six different extrachromosomal DNA banding patterns were found. Genomically similar isolates carried related, but different, banding patterns. DNA hybridization studies indicated that isolates from a single plant species can be minimally related as determined by total genome homology. Homology ranged from 12 to 99%. Highly divergent strains were isolated from the same plant and found to cohabit the same nodule. Thus, this study demonstrated that Frankia strains which infect the same host plant are not only phenotypically different but also genetically diverse.