Comparative analysis of <Emphasis Type="Italic">Pasteurella pneumotropica</Emphasis> isolates from laboratory mice and rats

Selected biochemical and genetic characteristics of the wild-type strains of Pasteurella pneumotropica isolated from mice and rats were investigated and compared in order to determine the significant differences among the isolates. The isolates were divided into six groups on the basis of the patterns of carbon source utilization in the host rodents. The genome sizes were determined by electrophoretic analysis, and the mean genome size of the isolates from mice was larger than that of the isolates from rats (P < 0.05). Cluster analysis of the rpoB sequences discriminated five clusters; the differences might have correlated with the host associations. Principal component analysis (PCA) based on both the biochemical and genetic characteristics revealed total 44 strains discriminated into three groups comprising the host-dependent and host-independent groups. Although the P. pneumotropica isolates were mainly classified on the basis of the host rodents by the examinations, the existence of isolates that could not be discriminated on the basis of the host rodents alone was confirmed by the PCA. These results indicated that the P. pneumotropica isolates could be further classified by taxonomic analysis and also suggested the existence of a host-independent group in addition to the host-dependent groups.     

Seedling and adult plant peaetions of Brassica napus-B. juncea recombinant lines towards A- and B-group isolates of Leptosphaeria maculans

The Brassica napus-B. juncea recombinant lines MX and MXS carrying a B. juncea major gene (JLml) in the genetic background of a spring- or a winter type B. napus cultivar, respectively, were tested for their resistance level to Leptosphaeria maculans under controlled conditions. Inoculation with three A-and four B-group individual isolates and with different mixtures of isolates realised within or between these groups was performed on cotyledons, leaves and stems. Cotyledons and leaves of the two recombinant lines were more resistant to A-group isolates than those of B. napus cultivars, except for one isolate recovered from the MX line. The recombinant lines were susceptible at cotyledon stage and resistant on leaves to B-group isolates, as were B. napus cultivars. On stems, severe cortical damage was usually produced on B. napus cultivars by some A-group isolates, whereas B-group isolates induced pith blackening on all genotypes. Stems of the MX line and the resistant donor species (B. juncea cv. Picra) were more resistant than those of the susceptible B. napus (cv. Westar) to the individual A-group isolates. Cultivar Picra was the most susceptible genotype to pith infection caused by the B-group isolates. The consequence of the host pathogen differential interactions on the durability of the monogenic resistance to L. maculans introduced from B. juncea into B. napus is discussed.     

Host Specificity and Genetic Diversity of Didymella bryoniae from Cucurbitaceae in Brazil

Thirty‐seven isolates of Didymella bryoniae from three Cucurbitaceae species were collected in Brazil and tested for pathogenicity to watermelon. All isolates were pathogenic but differed in aggressiveness levels. Seven representative isolates were used in cross‐pathogenicity tests against 10 cucurbitaceous hosts. Most isolates were pathogenic to most host species tested, except to Sechium edule. Among the susceptible species, Citrullus and Cucumis species were the most susceptible hosts, while pumpkin and Luffa purgans were the most resistant. Host of origin affected the pattern of aggressiveness on each host. Isolates from watermelon were very aggressive to their original host, but much less aggressive or not pathogenic at all to some Cucurbita. Two previously described random‐amplified polymorphic DNA (RAPD)‐specific primers indicated that 81% of the isolates could be classified into the so‐called RG I group, while the remaining isolates could not be classified into any of the described RG groups. All 37 isolates were further characterized by RAPD fingerprinting and compared with three US isolates representative of RG I and RG II groups. The Brazilian D. bryoniae isolates could be separated into genetically similar clusters. The majority of the isolates were grouped in cluster DB Ia, which contained only isolates of Citrullus lanatus and Cucumis melo. Two of the American isolates used as controls clustered with this group at 68% similarity level. The DB Ib cluster included three Brazilian isolates obtained from melon and watermelon and the American representative for RG II, at a lower similarity level (43%). Two isolates from watermelon clustered with one isolate from melon in a separate group (DB II), while one single isolate from pumpkin (DB III) showed the lowest genetic similarity to all other isolates. Didymella bryoniae isolates from Brazil showed, therefore, a level of genetic diversity higher than previously reported for the species. RAPD fingerprinting allowed for geographical distinction of D. bryoniae isolates but no correlation between genetic distance, aggressiveness or origin of the isolate was found.     

Host ranges and serological properties of eight isolates of parsnip yellow fleck virus belonging to the two major serotypes

Isolates of parsnip yellow fleck virus (PYFV) from parsnip (P-121), celery (CV506 and CV065) and Heracleum sphondylium (Hs2) were serologically close to each other but distant from isolates from carrot (Dc2 and Dc5) and Anthriscus sylvestris (A-421 and As2), which were in turn close to each other serologically. The two groups of isolates also differed from each other in host range. Minor differences in immunological reactions and in host range and symptomatology were observed between isolates in each group. Particles of all eight isolates had similar RNA and protein compositions. The data confirm that PYFV isolates fall into two major serotypes, those from parsnip, celery and H. sphondylium belonging to the P-121 serotype and those from carrot and A. sylvestris belonging to the A-421 serotype.     

Laboratory evaluation of the virulence of Beauveria bassiana isolates to the sorghum shoot borer Chilo partellus Swinhoe (Lepidoptera: Pyralidae) and their characterization by RAPD-PCR

Beauveria bassiana has long been used as a mycopesticide. It has a wide host range; isolates have been reported to differ in host range and virulence to a given insect species. Identification of a molecular marker linked to a virulent phenotype to a target pest would be useful in screening for isolates effective against it. Twenty B. bassiana isolates were tested for their virulence to the second instar larvae of Chilo partellus Swinhoe in laboratory bioassays and their DNA fingerprints were generated by RAPD-PCR. Three arbitrary categories of aggressiveness were chosen; isolates that caused >70%, between 70 and 40% and <40% larval mortality were grouped as highly, medium and less aggressive types, respectively. In the random amplified polymorphic DNA (RAPD) analysis a 30% variability was observed among the isolates; which clustered into three major groups. The groups based on virulence rating did not match with the RAPD clusters. One of the highly aggressive isolates clustered with less aggressive isolates in one cluster and the other grouped along with the medium aggressive isolates in a different cluster. The B. bassiana isolates were classified phenotypically based on the taxonomic order of the original insect host and the climatic zone (tropical/temperate) from which they were isolated. No correlation between the aggressiveness of the isolate and the relatedness of the original insect host to the tested insect was observed; both the highly aggressive isolates were from coleopteran insects. A correlation was found between the RAPD grouping and the phenotypic classification of the isolates. All the lepidopteran isolates grouped into one major cluster, most sub clusters were constituted by isolates from the same climatic zone.     

A strain of cassava latent virus occurring in coastal districts of Kenya

A strain of cassava latent geminivirus (CLV) was isolated from mosaic-affected cassava plants from coastal districts of Kenya. This virus (CLV-C) did not infect Nicotiana clevelandii, a diagnostic host of the type strain (CLV-T); experimental host range was very restricted and CLV-C only infected N. benthamiana and N. rustica out of several solanaceous hosts readily infected by CLV-T. CLV-C was also isolated from naturally infected Jatropha multifida (Euphorbiaceae) and Hewittia sublobata (Convolvulaceae). CLV-C was propagated in N. benthamiana with difficulty and only those isolates derived from cassava plants infected with severe mosaic symptoms were maintained more or less successfully; these sources usually contained a higher concentration of CLV than plants with mild symptoms. Symptom variants generally remained unchanged when grafted into a highly susceptible South American cassava variety. CLV-C and CLV-T seemed to occur respectively only in coastal and western districts but their ranges overlapped in central Kenya where they could have been introduced in infected material. CLV-C could be purified satisfactorily with the method used for CLV-T but only after modifying the procedure by substituting phosphate for borate in the extraction buffer, n-butanol for n-butanol/chloroform in clarification of extracts, and phosphate for borate buffer when resuspending concentrated virus. A virus serologically indistinguishable from CLV-T was isolated from mosaic- affected material obtained from Nigeria; East African and Nigerian isolates were essentially similar in host range and symptomatology. In gel-diffusion serology tests, pronounced precipitation spurs developed between CLV-T and CLV-C indicating that the isolates were related but not identical serologically. Symptoms typical of cassava mosaic disease appeared in only three of 105 plants in experiments on transmission of CLV-C and CLV-T by whiteflies, when attempted acquisition of either clarified CLV-infective sap or purified CLV was made through ‘Parafilm’ membranes. Because it is possible that the three infections resulted from contamination, they cannot constitute proof of transmission. The presence of CLV in relation to the etiology of cassava mosaic thus remains unresolved.     

Variation in pathogenicity among isolates of Elsinoe phaseoli from Phaseolus species

Expanding primary leaves of 11 cultivars of Phaseolus vulgaris, and one each of Phaseolus coccineus, Phaseolus lunatus and Vigna unguiculata were inoculated with 23 isolates of Elsinoe phaseoli from Phaseolus spp. and one from Vigna unguiculata. On the basis of the macroscopic and microscopic appearance of the lesions, symptoms were placed into five classes. Spore yields from the lesions in each class were used to classify the types of lesions as representing resistance or susceptibility to each isolate. There was a differential response of cultivars to isolates. According to the reaction of five cultivars of P. vulgaris to infection, isolates were placed in four pathogenicity groups. In addition to the differential reaction of cultivars, there was some evidence of host specificity among the isolates. Thus, P. lunatus was susceptible to most of the P. vulgaris isolates but resistant to the ones from P. coccineus. Vigna unguiculata was susceptible only to the V. unguiculata isolate and was resistant to all the isolates from Phaseolus spp. The isolate from V. unguiculata failed to infect any of the bean cultivars or the other Phaseolus spp. The need to select suitable isolates for challenging cultivars in a breeding programme is stressed.     

Arabis mosaic and Prunus necrotic ringspot viruses in hop (Humulus lupulus L.)

Purified virus preparations made from nettlehead-diseased hop plants, or from Chenopodium quinoa, to which the virus was transmitted by inoculation of sap, contained polyhedral virus particles of 30 mμ diameter which were identified serologically as arabis mosaic virus (AMV). There were serological differences between AMV isolates from hop and from strawberry, and also differences in host range and in symptoms caused in C. quinoa and C. amaranticolor. AMV was always associated with nettlehead disease. The nematode Xiphinema diversicaudatum occurred in small numbers in most hop gardens, but was numerous where nettlehead disease was spreading rapidly. Preparations from nettlehead-affected hops also contained a second virus, serologically related to Prunus necrotic ringspot virus (NRSV), in mild and virulent forms which infected the same range of test plants but showed some serological differences. Mild isolates did not protect C. quinoa plants against infection by virulent isolates. Hop seedlings inoculated with virulent isolates of NRSV developed symptoms indistinguishable from those of split leaf blotch disease. Latent infection with NRSV was prevalent in symptomless hop plants. Nettlehead disease is apparently associated with dual infection of AMV and virulent isolates of NRSV. An unnamed virus with rod-shaped particles 650 mμ long was common in hop and was transmitted by inoculation of sap to herbaceous plants. Cucumber mosaic virus was obtained from a single plant of Humulus scandens Merr.     

Studies on Bacteriophage Distribution

Twenty-eight bacteriophage strains active on one or more species of Enterobacteriaceae were isolated from sewage and were classified into seven host range groups. Two isolates resemble S13, three isolates appear to be closely related to T₁, and one seems to be related to T even phages. Members of one host range group are active on three bacterial species, viz., Escherichia coli, Salmonella typhimurium, and Shigella sonnei. Some of the E. coli K12 strains selected for resistance to phage HK019 are sensitive to S13 but not to φ×174.     

Aggressiveness and diversity of Phytophthora capsici on vegetable crops in Georgia

Phytophthora blight induced by Phytophthora capsici causes significant yield loss in a number of vegetable crops. It is imperative to understand the diversity and aggressiveness of the pathogen to design more efficient disease management programs. A collection of P. capsici strains isolated from different vegetable crops in Georgia, USA, were characterised in this study. Of the 49 isolates tested, 24 were A1 and 25 were A2 mating type, respectively, with both mating types found in the same fields. Variability of the isolates was assessed in terms of their aggressiveness on six pepper genotypes. The isolates differed in their aggressiveness on different pepper cultivars with 10 pathotypes identified. No correlation between aggressiveness of the isolates and their host origin or geographical location of isolation was observed. Randomly amplified polymorphic DNA (RAPD) analysis was used to evaluate genetic variability among P. capsici populations. RAPD analysis using 15 random primers resulted in 133 reproducible bands and cluster analysis separated the isolates into 5 groups. Analysis of molecular variance showed that there was moderate genetic differentiation associated with host origin and geographical location of the isolates. No correlation was found between RAPD groups and pathotypes or mating types. These results indicate that P. capsici populations infecting vegetable crops in Georgia were genetically diverse, which should be taken into account in developing resistant cultivars or other disease management programmes.     

Genetic Diversity and Pathogenic Variability of Colletotrichum truncatum Causing Anthracnose of Pepper in Malaysia

Colletotrichum truncatum was initially described from pepper and has been reported to infect 180 host genera in 55 plant families worldwide. Samples were collected from pepper plants showing typical anthracnose symptoms. Diseased samples after isolation were identified as C. truncatum based on morphological characters and ITS‐rDNA and β‐tubulin sequence data. Intersimple sequence repeat (ISSR) markers were used to estimate genetic diversity in C. truncatum from Malaysia. A set of 3 ISSR primers revealed a total 26 allele from the amplified products. Cluster analysis with UPGMA method clustered C. truncatum isolates into two main groups, which differed with a distance of 0.64. However, the genetic diversity of C. truncatum isolates showed correlation between genetic and geographical distribution, but it failed to reveal a relationship between clustering and pathogenic variability. Phylogenetic analyses discriminated the C. truncatum isolates from other reference Colletotrichum species derived from GenBank. Among the morphological characters, shape, colour of colony and growth rate in culture were partially correlated with the ISSR and phylogenetic grouping. Pathogenicity tests revealed that C. truncatum isolates were causal agents for pepper anthracnose. In the cross‐inoculation assays, C. truncatum isolates were able to produce anthracnose symptoms on tomato, eggplant, onion, lettuce and cabbage. A pathogenicity and cross‐inoculation studies indicated the potential of C. truncatum for virulence and dominancy on plant resistance.     

Genetic identity of free‐living Symbiodinium obtained over a broad latitudinal range in the Japanese coast

The dinoflagellate Symbiodinium is well known to engage symbiosis with various marine animals, including corals. Recent records of environmental Symbiodinium (occurring in the environment and separately from host animals; usually referred to as ‘free‐living’ Symbiodinium) are of special interest, since these environmental populations are essential as symbiont sources for many host animals. In the present study, we carried out a phylogenetic analysis of environmental Symbiodinium isolates (culture strains) from sand, tide pools, or macroalgal surfaces, and environmental DNA clones extracted from the water‐column, at numerous sites around Japan. Our phylogenetic analysis based on the nuclear rRNA gene (internal transcribed spacers ‐1, ‐2, and 5.8S), indicated that most of the environmental isolates form monophyletic subclades within the Clade‐A lineage, and separate from a host‐associated Clade‐A population with high bootstrap values. Results of the partial nuclear 28S rDNA phylogeny and thecal‐plate observations revealed that these environmental isolates were closely related to a previously‐described ‘planktonic species’, Symbiodinium natans Gert Hansen et Daugbjerg, which was isolated from a plankton‐net sample from the Northeast‐Atlantic Ocean. On the other hand, the environmental DNA clones were also noted to be mostly nested within host‐associated Symbiodinium groups scattered in various clades. These results led to the assumption that the environmental Symbiodinium can be divided into two groups. One group, as typified by environmental isolates in the present study and previous reports, may be exclusively free‐living; the other group exists transiently in free‐living forms, possibly having been expelled from animal hosts. The populations within the latter group probably represent environmental sources of viable symbionts, because these are normally host‐associated. However, the Symbiodinium in the former group are not expected to engage in stable symbioses with host cnidarians.     

Genetic diversity of the ectomycorrhizal fungus Pisolithus tinctorius based on RAPD-PCR analysis

 Twenty Pisolithus tinctorius isolates from different geographic locations and different hosts were characterized by the random amplified polymorphic DNA technique. Thirteen arbitrary primers generated 87 DNA fragments, all of them polymorphic. These data were used to calculate genetic distances among the isolates. The pairwise genetic distances ranged from 1 to 100%, with an average of 58.7%. Cluster analysis based on the amplified fragments grouped the isolates according to their host and geographical origins. Group I contained isolates collected in Brazil and group II those collected in the Northern Hemisphere. In addition to the diversity seen at the molecular level, the isolates also showed host specificity. Greenhouse experiments demonstrated that isolates from the Northern Hemisphere colonized mainly Pinus whereas isolates from Brazil colonized only Eucalyptus. The molecular data suggest that the Pisolithus tinctorius isolates analyzed belong to two distinct groups. The data also suggest new guidelines for future investigations on the taxonomy and systematic of this important fungus species. Furthermore, these results support future experiments aimed at the selection and development of improved isolates of P. tinctorius. Accepted: 3 October 1997     

Potential of Cactoblastis cactorum as a Vector for Fungi Pathogenic to Pricklypear, Opuntia inermis

In Australia, fungi associated with larvae of the biological control agent Cactoblastis cactorum may contribute to the control of the exotic weed pricklypear (Opuntia inermis). C. cactorum larvae were assessed for their ability to vector pathogenic fungi into O. inermis by the infestation of larvae with fungal suspensions. Six fungal isolates caused disease after being carried into the host on external surfaces of larvae, and propagules of one isolate (UQ5109) initiated disease after being transferred from the cladode epidermis into the host by larvae feeding on the plant. Scanning electron microscopy revealed extensive hyphal growth on the external surfaces of larvae infested with several of the isolates. Fungi isolated from field-grown O. inermis cladodes were tested for pathogenicity to this plant in an in vivo plant assay. In total, 152 isolates were screened, 22 of which infected the host in pathogenicity tests. Only 1 (UQ5115) infected undamaged host tissue, whereas the remainder required the host to be wounded before infection could proceed. The majority of isolates were only weakly pathogenic, even when inoculated via wounds, suggesting that most were either saprophytes or weak parasites. This study demonstrates that it is possible for larvae of C. cactorum to transmit fungal pathogens into O. inermis tissue and it has provided a sound basis for future field work to determine the contribution that fungi make to the control of O. inermis.     

Comparison of Some Isolates of Potato Leaf Roll Virus in Poland

18 PLRV isolates differed in severity of symptoms induced on Physalis floridana and on three potato cultivars (Osa, Pola, and Giewont). Reactions of potato cultivars to individual isolates were not always related. Some isolates induced more severe symptoms than others in all host plants. Isolates producing more severe symptoms reached a higher concentration in potato cultivars (evaluated with ELISA test) and were more virulent to Capsella bursa-pastoris. An interaction between PLRV isolates and host plants could be demonstrated. In general, the severity of the reaction of cv. Pola was related to that of P. floridana but not to the reaction of cvs. Osa and Giewont. The reactions of cvs. Osa and Giewont were closely related. All six isolates selected for a more detailed study could infect C. bursa-pastoris with obvious disease symptoms if potato cv. Osa served as source of the virus. Some isolates failed to infect this plant when other cultivars were used.     

Pathogenic interactions between variants of cauliflower mosaic virus and Arabidopsis thaliana

Pathogenic interactions between genetic variants of cauliflower mosaic virus (CaMV) and Arabidopsis thaliana were characterized to identify combinations potentially useful in molecular genetic analysis. Infections of a glabrous mutant (gl1) of Arabidopsis ecotype Columbia (Col-0 gl1) by 30 CaMV isolates were assessed by recording symptom character. Thirteen isolates failed to cause symptoms; the remainder induced symptoms that varied between mild and very severe. Some CaMV isolates produced symptoms in Arabidopsis that differed significantly in severity or character from those produced in a standard host Brassica rapa (turnip). A greater variety of symptom types was observed in a single Arabidopsis ecotype infected with a range of CaMV isolates than was found in a range of Arabidopsis ecotypes infected with a single, typical CaMV isolate (Cabb B-JI). One isolate, Bari-1, that was asymptomatic but accumulated virus in Arabidopsis ecotype Col-0 gl1, caused mild symptoms in ecotype Ler gl1. A hybrid virus constructed from CaMV isolates Cabb B-JI and Bari-1 produced symptoms in Arabidopsis variants that were more severe than in either parental isolate. From a screen of EMS-mutagenized Arabidopsis, one mutant (Col-0 dv1) with a pale-green, dark-vein phenotype which had an altered symptom response to CaMV, was isolated. From this, a phenotypically near-normal revertant (Col-0 dv1R) spontaneously arose, but which showed altered responses to CaMV. Infection of Col-0 dv1R by CaMV isolate Bari-1 elicited symptoms unlike the parent Arabidopsis ecotype (Col-0 gl1). Also, Col-0 dv1 and Col-0 dv1R expressed an uncharacteristic necrotic reaction to CaMV.     

Molecular Characterization of the 3'-Terminal Region of Turnip mosaic virus Isolates from Eastern China

Turnip mosaic virus (TuMV; genus Potyvirus, family Potyviridae) causes great losses to cruciferous crop production worldwide. The 3′‐terminal genomic sequences of eight TuMV isolates from eastern China were compared with those of 74 other Chinese TuMV isolates of known host origin in the GenBank and isolated during the past 25 years. The reported sequences of the eight TuMV isolates are 1125 or 1126‐nucleotides (nt) long excluding the poly(A) tail. They all contain one partial open reading frame of 912 nt, encoding 304 amino acids, followed by a stop codon and a non‐translated region of 209–210 nt. Results of phylogenetic analyses showed that Chinese TuMV isolates clustered into three groups: basal‐BR, Asian‐BR and world‐B. The ratios of non‐synonymous and synonymous substitutions and results of amino acid alignment provided evidence for purifying or negative selection in TuMV populations of China.     

Determination of genetic diversity among Indian isolates of Rhizoctonia bataticola causing dry root rot of chickpea

Genetic diversity among 27 isolates (23 from chickpea and 4 from other host crops) of Rhizoctonia bataticola representing 11 different states of India was determined by random amplified polymorphic DNA (RAPD), internal transcribed spacer restriction fragment length polymorphism (ITS-RFLP) and ITS sequencing. The isolates showed variability in virulence test. Unweighted paired group method with arithmetic average cluster analysis was used to group the isolates into distinct clusters. The clusters generated by RAPD grouped all the isolates into six categories at 40% genetic similarity. High level of diversity was observed among the isolates of different as well as same state. Some of the RAPD (OPN 4, OPN 12, and OPN 20) markers clearly distinguished majority of the isolates into the area specific groups. The ITS I, 5.8rDNA and ITS II regions of 11 isolates representing different RAPD groups were amplified with primers ITS 1 and ITS 4 and digested with seven restriction enzymes. The restriction enzymes DraI, MboI, RsaI, and AluI were found to be suitable for differentiating the isolates into five categories by showing isolate specific ITS-RFLP patterns. The isolates were variable in their nucleotide sequences of the ITS regions. This is the first study on genetic diversity among chickpea isolates of R. bataticola.     

Race Differentiation in Fusarium oxysporum f.sp. chrysanthemi

The pathogenicity of different isolates of Fusarium oxysporum obtained from plants of Gerbera (Gerbera jamesonii), Chrysanthemum (Chrysanthemum morifolium), Paris daisy (Argyranthemum frutescens) and African daisy (Osteospermum sp.), all in the family Asteraceae, was tested on different cultivars of these hosts, to assess their pathogenicity. The reactions were compared with those of isolates of F. oxysporum f. sp. chrysanthemi and of f.sp. tracheiphilum obtained from the American Type Culture Collection. We found that isolates of F. oxysporum f. sp. chrysanthemi can be distinguished as three physiological races on the basis of their pathogenicity to the panel of differential cultivars. Sequencing of the intergenic spacer (IGS) region of ribosomal DNA (rDNA) and phylogenetic analysis showed that the Fusarium races fell into three phylogenetic groups, which coincided with those observed in pathogenicity tests. Analysis of the IGS sequences revealed a high degree of similarity among strains from Italy and Spain from different host species, suggesting that recent outbreaks in these ornamentals were probably caused by introduction of infected nursery material from a common origin.     

Prevalence of genetically similar Flavobacterium columnare phages across aquaculture environments reveals a strong potential for pathogen control

Intensive aquaculture conditions expose fish to bacterial infections, leading to significant financial losses, extensive antibiotic use and risk of antibiotic resistance in target bacteria. Flavobacterium columnare causes columnaris disease in aquaculture worldwide. To develop a bacteriophage-based control of columnaris disease, we isolated and characterized 126 F. columnare strains and 63 phages against F. columnare from Finland and Sweden in 2017. Bacterial isolates were virulent on rainbow trout (Oncorhynchus mykiss) and fell into four previously described genetic groups A, C, E and G, with genetic groups C and E being the most virulent. Phage host range studied against a collection of 227 bacterial isolates (from 2013 to 2017) demonstrated modular infection patterns based on host genetic group. Phages infected contemporary and previously isolated bacterial hosts, but bacteria isolated most recently were generally resistant to previously isolated phages. Despite large differences in geographical origin, isolation year or host range of the phages, whole-genome sequencing of 56 phages showed high level of genetic similarity to previously isolated F. columnare phages (Ficleduovirus, Myoviridae). Altogether, this phage collection demonstrates a potential for use in phage therapy.