Comparison of DNAs of Crypthecodinium cohnii-like Dinoflagellates from Widespread Geographic Locations*

SYNOPSIS. We have examined various properties of DNAs from 7 dinoflagellate isolates of wide geographic distribution; all of the isolates are superficially indistinguishable from a laboratory strain of Crypthecodinium cohnii originally isolated at Woods Hole, Massachusetts (WHd strain). Two isolates, one from Puerto Rico and the other from Honduras, are clearly distinguishable from WHd and the other isolates by their DNA buoyant density values. WHd and the other 5 isolates we have examined are indistinguishable from one another in terms of DNA buoyant densities and melting temperatures. The relationship among the various isolates, including WHd, were evaluated at a finer level through restriction endonuclease cleavage and molecular hybridization to compare ribosomal RNA gene structure in the several DNAs. All the isolates could be further categorized by this method, the patterns of restriction endonuclease cleavage of ribosomal RNA genes in the isolates paralleling exactly their sexual compatibilities established from breeding experiments by Beam & Himes. The DNAs were also treated with a restriction endonuclease sensitive to the presence of the modified base 5-methylcytosine. In all isolates, cytosine residues in both total DNA and DNA specifically containing the ribosomal RNA genes were found to be extensively methylated, as was previously shown for the WHd strain.     

Genetic diversity and temporal variation in the cyanophage community infecting marine Synechococcus species in Rhode Island's coastal waters

The cyanophage community in Rhode Island's coastal waters is genetically diverse and dynamic. Cyanophage abundance ranged from over 10(4) phage ml(-1) in the summer months to less then 10(2) phage ml(-1) during the winter months. Thirty-six distinct cyanomyovirus g20 genotypes were identified over a 3-year sampling period; however, only one to nine g20 genotypes were detected at any one sampling date. Phylogenetic analyses of g20 sequences revealed that the Rhode Island cyanomyoviral isolates fall into three main clades and are closely related to other known viral isolates of Synechococcus spp. Extinction dilution enrichment followed by host range tests and PCR restriction fragment length polymorphism analysis was used to detect changes in the relative abundance of cyanophage types in June, July, and August 2002. Temporal changes in both the overall composition of the cyanophage community and the relative abundance of specific cyanophage g20 genotypes were observed. In some seawater samples, the g20 gene from over 50% of isolated cyanophages could not be amplified by using the PCR primer pairs specific for cyanomyoviruses, which suggested that cyanophages in other viral families (e.g., Podoviridae or Siphoviridae) may be important components of the Rhode Island cyanophage community.     

Characterization of a novel T4-type Stenotrophomonas maltophilia virulent phage Smp14

Stenotrophomonas maltophilia (Sm), with most of the isolates being resistant to multidrugs, is an opportunistic bacterium causing nosocomial infections. In this study, a novel virulent Sm phage, Smp14, was characterized. Electron microscopy showed that Smp14 resembled members of Myoviridae and adsorbed to poles of the host cells during infection. It lysed 37 of 87 clinical Sm isolates in spot test, displayed a latent period of ca. 20 min, and had a burst size of ca. 150. Its genome (estimated to be 160 kb by PFGE), containing m4C and two unknown modified bases other than m5C and m6A as identified by HPLC, resisted to digestion with many restriction endonucleases except MseI. These properties indicate that it is a novel Sm phage distinct from the previously reported phiSMA5 which has a genome of 250 kb digestible with various restriction enzymes. Sequencing of a 16 kb region revealed 12 ORFs encoding structural proteins sharing 15-45% identities with the homologues from T4-type phages. SDS-PAGE displayed 20 virion proteins, with the most abundant one being the 39 kDa major capsid protein (gp23), which had the N-terminal 52 amino acids removed. Phylogenetic analysis based on gp23 classified Smp14 into a novel single-membered T4-type subgroup.     

Phylogenetic Diversity of Marine Cyanophage Isolates and Natural Virus Communities as Revealed by Sequences of Viral Capsid Assembly Protein Gene g20

In order to characterize the genetic diversity and phylogenetic affiliations of marine cyanophage isolates and natural cyanophage assemblages, oligonucleotide primers CPS1 and CPS8 were designed to specifically amplify ca. 592-bp fragments of the gene for viral capsid assembly protein g20. Phylogenetic analysis of isolated cyanophages revealed that the marine cyanophages were highly diverse yet more closely related to each other than to enteric coliphage T4. Genetically related marine cyanophage isolates were widely distributed without significant geographic segregation (i.e., no correlation between genetic variation and geographic distance). Cloning and sequencing analysis of six natural virus concentrates from estuarine and oligotrophic offshore environments revealed nine phylogenetic groups in a total of 114 different g20 homologs, with up to six clusters and 29 genotypes encountered in a single sample. The composition and structure of natural cyanophage communities in the estuary and open-ocean samples were different from each other, with unique phylogenetic clusters found for each environment. Changes in clonal diversity were also observed from the surface waters to the deep chlorophyll maximum layer in the open ocean. Only three clusters contained known cyanophage isolates, while the identities of the other six clusters remain unknown. Whether or not these unidentified groups are composed of bacteriophages that infect different Synechococcus groups or other closely related cyanobacteria remains to be determined. The high genetic diversity of marine cyanophage assemblages revealed by the g20 sequences suggests that marine viruses can potentially play important roles in regulating microbial genetic diversity.     

Phylogenetic diversity of marine cyanophage isolates and natural virus communities as revealed by sequences of viral capsid assembly protein gene g20

In order to characterize the genetic diversity and phylogenetic affiliations of marine cyanophage isolates and natural cyanophage assemblages, oligonucleotide primers CPS1 and CPS8 were designed to specifically amplify ca. 592-bp fragments of the gene for viral capsid assembly protein g20. Phylogenetic analysis of isolated cyanophages revealed that the marine cyanophages were highly diverse yet more closely related to each other than to enteric coliphage T4. Genetically related marine cyanophage isolates were widely distributed without significant geographic segregation (i.e., no correlation between genetic variation and geographic distance). Cloning and sequencing analysis of six natural virus concentrates from estuarine and oligotrophic offshore environments revealed nine phylogenetic groups in a total of 114 different g20 homologs, with up to six clusters and 29 genotypes encountered in a single sample. The composition and structure of natural cyanophage communities in the estuary and open-ocean samples were different from each other, with unique phylogenetic clusters found for each environment. Changes in clonal diversity were also observed from the surface waters to the deep chlorophyll maximum layer in the open ocean. Only three clusters contained known cyanophage isolates, while the identities of the other six clusters remain unknown. Whether or not these unidentified groups are composed of bacteriophages that infect different Synechococcus groups or other closely related cyanobacteria remains to be determined. The high genetic diversity of marine cyanophage assemblages revealed by the g20 sequences suggests that marine viruses can potentially play important roles in regulating microbial genetic diversity.     

Free-range layer chickens as a source of <Emphasis Type="Italic">Campylobacter</Emphasis> bacteriophage

Bacteriophage specific for Campylobacter were isolated from chicken excreta collected from established free-range layer breed stock. Bacteriophage were either propagated on a Campylobacter jejuni host with broad susceptibility to bacteriophage (NCTC 12662) or on Campylobacter isolates from the same samples. Campylobacters were confirmed as being C. jejuni and or C. coli, using a combination of standard biochemical tests and PCR analysis with genus and species specific primers. The bacteriophage displayed differential patterns of susceptibility against reference NCTC strains and contemporary C. jejuni /C. coli isolates from chicken excreta. Electron microscopy demonstrated that the phage possessed icosahedral heads and rigid contractile tails. Pulsed-field gel electrophoresis revealed the bacteriophage genomes to be double stranded DNA in the range of 140 kb in size and the restriction enzyme patterns of the DNAs indicate they are genetically related members of the Myoviridae family. This study showed that Campylobacter bacteriophage could easily be isolated from free-range chickens and form part of their normal microbiological biota of environmentally exposed birds.     

Molecular characterization of Vibrio harveyi bacteriophages isolated from aquaculture environments along the coast of India

Seven bacteriophages specific to Vibrio harveyi, the causative agent of luminous vibriosis in shrimp, were isolated from coastal aquaculture systems like shrimp farms, hatcheries and tidal creeks along the east and west coast of India. All the seven phages were found to have the typical head and tail morphology with double-stranded DNA as genetic material. Morphologically, six phages were grouped under family Siphoviridae and one under Myoviridae. These phages were further characterized with respect to host range, morphology and structural proteins. Genomic fingerprinting was carried out using restriction fragment length polymorphism (RFLP) and randomly amplified polymorphic DNA (RAPD). Major capsid proteins of all the phages detected by SDS-PAGE were distinct from one another. All the phages were found to be highly lytic for V. harveyi and had different lytic spectrum for the large number of isolates tested. Six of the seven phages isolated had a broad lytic spectrum and could be potential candidates for biocontrol of V. harveyi in aquaculture systems.     

Genetic Diversity and Temporal Variation in the Cyanophage Community Infecting Marine Synechococcus Species in Rhode Island's Coastal Waters

The cyanophage community in Rhode Island's coastal waters is genetically diverse and dynamic. Cyanophage abundance ranged from over 10⁴ phage ml⁻¹ in the summer months to less then 10² phage ml⁻¹ during the winter months. Thirty-six distinct cyanomyovirus g20 genotypes were identified over a 3-year sampling period; however, only one to nine g20 genotypes were detected at any one sampling date. Phylogenetic analyses of g20 sequences revealed that the Rhode Island cyanomyoviral isolates fall into three main clades and are closely related to other known viral isolates of Synechococcus spp. Extinction dilution enrichment followed by host range tests and PCR restriction fragment length polymorphism analysis was used to detect changes in the relative abundance of cyanophage types in June, July, and August 2002. Temporal changes in both the overall composition of the cyanophage community and the relative abundance of specific cyanophage g20 genotypes were observed. In some seawater samples, the g20 gene from over 50% of isolated cyanophages could not be amplified by using the PCR primer pairs specific for cyanomyoviruses, which suggested that cyanophages in other viral families (e.g., Podoviridae or Siphoviridae) may be important components of the Rhode Island cyanophage community.     

New bacteriophages active on strains of Hyphomicrobium

Fifty-five lytic bacteriophages isolated from water and soil samples were active on many strains of the genus Hyphomicrobium. The optimal isolation procedure was an adsorption method in which samples from a habitat similar to that of the respective host bacterium were used as the phage inoculum. According to the morphology and nucleic acid type these bacteriophages belonged to different families: Myoviridae (type A1: five phages); Styloviridae (type B1: 33 phages; type B2: eight phages) and Podoviridae (type C1: nine phages). The Styloviridae (type B1) appeared in two morphological variants (tails flexible or rigid). All phages investigated were specific for the genus Hyphomicrobium and were unable to lyse members of other genera of hyphal, budding bacteria (e.g. Hyphomonas, Pedomicrobium, genus D, genus T). The host specificity of 42 phages was tested with 156 Hyphomicrobium strains: 122 strains were lysed by at least one of these phages, but 34 Hyphomicrobium strains were not susceptible. Morphotype B1 phages with identical morphology could be distinguished according to their host-range properties on prophage-containing Hyphomicrobium strains. With regard to differences in morphology and host range, 25 phages were selected for more detailed investigations. From these phages DNA was isolated; the melting transition midpoints (Tm) ranged from 67 to 93 degrees C. The upper and higher values suggested the presence of DNA modifications. Six different adsorption patterns could be distinguished among the Hyphomicrobium phages. Preferred attachment sites were the proximal pole of the mother cell, the hyphal tip, the distal pole of the bud, and the distal pole of the swarmer cell.     

Characteristics of two marine nitrite oxidizing bacteria,Nitrospina gracilis nov. gen. nov. sp. and Nitrococcus mobilis nov. gen. nov. sp.

Summary Two new nitrite oxidizing bacteria for which the names Nitrococcus mobilis and Nitrospina gracilis are proposed were isolated from the marine environment. Nitrococcus mobilis was cultured from South Pacific waters and it is a large motile coccus with unique tubular cytomembranes. Nitrospina gracilis was isolated from South Atlantic waters and it is a long slender rod which lacks an extensive cytomembrane system. Both are obligate marine organisms and both are obligate chemoautotrophs. The fine structure of these organisms is detailed.Contribution No. 2631 from the Woods Hole Oceanographic Institution, Woods Hole, Massachusetts 02543.     

Sexual Isolation and Genetic Diversification Among Some Strains of Crypthecodinium cohnii-like Dinoflagellates Evidence of Speciation

SYNOPSIS. Nine new isolates of Crypthecodinium-like dinoflagellates from diverse geographic locations, together with 3 established strains from Woods Hole and Puerto Rico, were analyzed for sexual compatibility by means of a complementation test using motility mutants. The results indicate that 5 of the 12 are mutually compatible and thereby represent one species. Five others are clearly reproductively isolated from this group and from each other and therefore may belong to separate species. The position of 2 other isolates remains uncertain. Only one, MC-5, is markedly distinct morphologically from all the others. It is also sympatric with one of the others, strain G, and its separation from Crypthecodinium cohnii seems therefore more fully justified than that of the other sexually isolated strains. G and MC-5 would be considered "good" species by an evolutionary biologist. The others are from widely separate geographic origins and. though still poorly characterized, all superficially resemble C. cohnii . Comparison of many characters (DNA profile, radiation response, drug sensitivity, macroalgal association, etc.) of the incompatible strains show significant disparities which are discussed in considering speciation.     

Three Bacillus anthracis bacteriophages from topsoil

Three Bacillus anthracis bacteriophages from Iowa topsoil are characterized as to latent period, morphology, structural proteins, DNA size, and restriction endonuclease digestion. Electron micrographs indicate that the three isolates include two members of the Myoviridae and one smaller phage belonging to the Podoviridae. Phages Nk and DB resemble Myoviridae phage SP50 in morphology, but host range studies, protein, and DNA analysis indicate that both differ from SP50. Phage MH is very similar to phage phi 29, but differs in terms of host range, structural protein, and DNA characteristics.     

Plasmids from bacterial endosymbionts of hump-killer paramecia

Six isolates ofCaedibacter taeniospiralis, collected from four continents, were screened for plasmid DNA. Plasmid DNA species containing between 41.5 and 49.5 kilobase pairs (kb) were observed in all strains. Physical maps of plasmids were constructed by determining relative positions of the restriction endonuclease (BamHI,SalI,XhoI,SacI,PstI,AvaI, andEcoRI) recognition sequences in each plasmid. The physical map of the smallest plasmid (41.5 kb), pKAP30, is reflected in each of the plasmids isolated from the other strains ofC. taeniospiralis. Plasmid DNA from three of the isolates (strains 51 and 116 both from Indiana and strain 169 from Japan) each contain 43 kb, where 41.5 kb appear to be identical to pKAP30 (obtained from the Australian strain, A30). The extra 1.5 kb present in pKAP51, pKAP116, and pKAP169 is included as a single polynucleotide sequence. The 1.5-kb inclusion is located at apparently identical positions in pKAP116 and pKAP169 and at a totally different position in pKAP51. The two remaining plasmids, pKAP47 (from California strain 47) and pKAP298 (from Panama strain 298), both contain 49 kb to include a continuous 41.5-kb sequence that is apparently identical to pKAP30. The results indicate that the polynucleotide sequences of these plasmids are highly conserved and that the observed variations among them may be accounted for by transposable elements.     

Isolation and characterization of novel giant Stenotrophomonas maltophilia phage phiSMA5

Stenotrophomonas maltophilia is one of the most prevalent opportunistic bacteria causing nosocomial infections. It has become problematic because most of the isolates are resistant to multiple antibiotics, and therefore, development of phage therapy has attracted strong attention. In this study, eight S. maltophilia phages were isolated from clinical samples including patient specimens, catheter-related devices, and wastewater. These phages can be divided into four distinct groups based on host range and digestibility of the phage DNAs with different restriction endonucleases. One of them, designated phiSMA5, was further characterized. Electron microscopy showed it resembled Myoviridae, with an isometric head (90 nm in diameter), a tail (90 nm long), a baseplate (25 nm wide), and short tail fibers. The phiSMA5 double-stranded DNA, refractory to digestion by most restriction enzymes, was tested and estimated to be 250 kb by pulsed-field gel electrophoresis. This genome size is second to that of the largest phage, phiKZ of Pseudomonas aeruginosa. In sodium dodecyl sulfate-polyacrylamide gel electrophoresis, 25 virion proteins were visualized. N-terminal sequencing of four of them suggested that each of them might have had its N terminus cleaved off. Among the 87 S. maltophilia strains collected in this study, only 61 were susceptible to phiSMA5, indicating that more phages are needed toward a phage therapy strategy. Since literature search yielded no information about S. maltophilia phages, phiSMA5 appears to be the first reported.     

Analysis of mer Gene Subclasses within Bacterial Communities in Soils and Sediments Resolved by Fluorescent-PCR-Restriction Fragment Length Polymorphism Profiling

Bacterial mer (mercury resistance) gene subclasses in mercury-polluted and pristine natural environments have been profiled by Fluorescent-PCR-restriction fragment length polymorphism (FluRFLP). For FluRFLP, PCR products were amplified from individual mer operons in mercury-resistant bacteria and from DNA isolated directly from bacteria in soil and sediment samples. The primers used to amplify DNA were designed from consensus sequences of the major subclasses of archetypal gram-negative mer operons within Tn501, Tn21, pDU1358, and pKLH2. Two independent PCRs were used to amplify two regions of different lengths (merRT(Delta)P [ca. 1 kb] and merR [ca. 0.4 kb]) starting at the same position in merR. The oligonucleotide primer common to both reactions (FluRX) was labelled at the 5(prm1) end with green (TET) fluorescent dye. Analysis of the mer sequences within databases indicated that the major subclasses could be differentiated on the basis of the length from FluRX to the first FokI restriction endonuclease site. The amplified PCR products were digested with FokI restriction endonuclease, with the restriction digest fragments resolved on an automated DNA sequencing machine which detected only those bands labelled with the fluorescent dye. For each of the individual mer operon sources examined, this single peak (in bases) position was observed in separate digests of either amplified region. These peak positions were as predicted on the basis of DNA sequence. mer PCR products amplified from DNA extracted directly from soil and sediment bacteria were studied in order to determine the profiles of the major mer subclasses present in each natural environment. In addition to peaks of the expected sizes, extra peaks were observed which were not predicted on the basis of DNA sequence. Those appearing in the restriction endonuclease digests of both study regions were presumed to be novel mer types. Genetic heterogeneity within and between mercury-polluted and pristine sites has been studied by this technique. Profiles generated were highly similar for samples taken within the same soil type. The profiles, however, changed markedly on crossing from one soil type to another, with gradients of the different groupings of mer genes identified.     

Seasonal Variations in Virus-Host Populations in Norwegian Coastal Waters: Focusing on the Cyanophage Community Infecting Marine Synechococcus spp.

Viruses are ubiquitous components of the marine ecosystem. In the current study we investigated seasonal variations in the viral community in Norwegian coastal waters by pulsed-field gel electrophoresis (PFGE). The results demonstrated that the viral community was diverse, displaying dynamic seasonal variation, and that viral populations of 29 different sizes in the range from 26 to 500 kb were present. Virus populations from 260 to 500 kb and dominating autotrophic pico- and nanoeukaryotes showed similar dynamic variations. Using flow cytometry and real-time PCR, we focused in particular on one host-virus system: Synechococcus spp. and cyanophages. The two groups covaried throughout the year and were found in the highest amounts in fall with concentrations of 7.3 × 10⁴ Synechococcus cells ml⁻¹ and 7.2 × 10³ cyanophage ml⁻¹. By using primers targeting the g20 gene in PCRs on DNA extracted from PFGE bands, we demonstrated that cyanophages were found in a genomic size range of 26 to 380 kb. The genetic richness of the cyanophage community, determined by denaturing gradient gel electrophoresis (DGGE) of PCR-amplified g20 gene fragments, revealed seasonal shifts in the populations, with one community dominating in spring and summer and a different one dominating in fall. Phylogenetic analysis of the sequences originating from PFGE and DGGE bands grouped the sequences into three groups, all with homology to cyanomyoviruses present in cultures. Our results show that the cyanophage community in Norwegian coastal waters is dynamic and genetically diverse and has a surprisingly wide genomic size range.     

Isolation and Characterization of a Novel Bacteriophage φ4D Lytic Against Enterococcus faecalis Strains

In recent years, Enterococcus faecalis has emerged as an important opportunistic nosocomial pathogen capable of causing dangerous infections. Therefore, there is an urgent need to develop novel antibacterial agents to control this pathogen. Bacteriophages have very effective bactericidal activity and several advantages over other antimicrobial agents and so far, no serious or irreversible side effects of phage therapy have been described. The objective of this study was to characterize a novel virulent bacteriophage φ4D isolated from sewage. Electron microscopy revealed its resemblance to Myoviridae, with an isometric head (74 ± 4 nm) and a long contractile tail (164 ± 4 nm). The φ4D phage genome was tested using pulsed-field gel electrophoresis and estimated to be 145 ± 2 kb. It exhibited short latent period (25 min) and a relatively small burst size (36 PFU/cell). Tests were conducted on the host range, multiplicities of infection (MOI), thermal stability, digestion of DNA by restriction enzymes, and proteomic analyses of this phage. The isolated phage was capable of infecting a wide spectrum of enterococcal strains. The results of these investigations indicate that φ4D is similar to other Myoviridae bacteriophages (for example φEF24C), which have been successfully used in phagotherapy.     

PCR-based RFLP analysis of DNA sequence diversity in the gastric pathogen Helicobacter pylori.

DNA sequence diversity among 60 independent isolates of the gastric pathogen Helicobacter pylori was assessed by testing for restriction fragment length polymorphisms (RFLPs) in several PCR-amplified gene segments. 18 Mbol and 27 HaeIII RFLPs were found in the 2.4 kb ureA-ureB (urease) segment from the 60 strains; this identified 44 separate groups, with each group containing one to four isolates. With one exception, each isolate not distinguished from the others by RFLPs in ureA-ureB was distinguished by Mbol digestion of the neighboring 1.7 kb ureC-ureD segment. The 1.5 kb flaA (flagellin) gene, which is not close to ure gene cluster, was also highly polymorphic. In contrast, isolates from initial and followup biopsies yielded identical restriction patterns in each of the three cases tested. The potential of this method for detecting population heterogeneity was tested by mixing DNAs from different strains before amplification: the arrays of restriction fragments obtained indicated co-amplification from both genomes in each of the five pairwise combinations tested. These results show that H. pylori is a very diverse species, that indicate PCR-based RFLP tests are almost as sensitive as arbitrary primer PCR (RAPD) tests, and suggest that such RFLP tests will be useful for direct analysis of H. pylori in biopsy and gastric juice specimens.     

Diversity of carbofuran-degrading soil bacteria and detection of plasmid-encoded sequences homologous to the mcd gene

Abstract: Fifty-five bacterial isolates, from English and French soils with different histories of carbofuran field treatment, which hydrolysed the N -methylcarbamate insecticide carbofuran to carbofuran 7-phenol were characterised phenotypically and genetically. The isolates were compared by using 125 physiological tests and morphological features, plasmid profiles and restriction fragment length polymorphism (RFLP) patterns of total DNA using the rRNA operon of Escherichia coli as a DNA probe. Cluster analysis of both phenotypic characters and RFLP patterns showed a high degree of diversity amongst the bacteria. Ten distinct plasmid profiles with 2–4 plasmids ranging in size from 84 to about 438 kb were visualised in 50 isolates. The majority of isolates had one of two types of plasmid profiles. Plasmid profiles and Eco RI restricted total DNA patterns were hybridised with an internal fragment of the carbofuran hydrolase ( mcd ) gene and 22 diverse soil isolates exhibited sequence homology with this gene probe. Our results indicate that sequences homologous to the mcd gene are located on a conserved Eco RI fragment (12 or 14 kb) of a plasmid (100, 105, 115 or 124 kb) found in diverse soil isolates from geographically distant areas. Thirty-three isolates did not exhibit detectable homology to the mcd gene probe and the hydrolase enzymes and genes in these isolates need further investigation.