Molecular and physiological diversity among Verticillium fungicola var. fungicola

The genetic and physiological variability of Verticillium fungicola var. aleophilum responsible for Agaricus bisporus dry bubble disease in North America is well documented but little is known about the var. fungicola affecting European crops. Variability was assessed within this variety and compared with that reported for the var. aleophilum. Eighteen isolates of V. fungicola var. fungicola and four var. aleophilum isolates were analysed for DNA polymorphism, mycelial growth, response to biochemicals produced by A. bisporus, fungicide resistance, and pathogenicity assessed by direct inoculation on sporophore or casing contamination. RAPD and AFLP markers delineated three French isolates from a homogeneous group containing the other var. fungicola isolates, but no correlation could be drawn between DNA polymorphism and the various traits studied. The var. fungicola isolates were more susceptible than the var. aleophilum isolates to the antibiosis effect of A. bisporus. Only mycelial growth rate at 23 °C could explain the variability in aggressiveness among the European isolates. The putative effect of the post-incubation temperature on contamination during mushroom cultivation was discussed. This work emphasized that, like the American var. aleophilum, the var. fungicola in Europe is genetically homogeneous, but physiological diversity exists, especially in France where it could be related to less standardized cultural practices.     

Absence of induced resistance in Agaricus bisporus against Lecanicillium fungicola

Lecanicillium fungicola causes dry bubble disease and is an important problem in the cultivation of Agaricus bisporus. Little is known about the defense of mushrooms against pathogens in general and L. fungicola in particular. In plants and animals, a first attack by a pathogen often induces a systemic response that results in an acquired resistance to subsequent attacks by the same pathogen. The development of functionally similar responses in these two eukaryotic kingdoms indicates that they are important to all multi-cellular organisms. We investigated if such responses also occur in the interaction between the white button mushroom and L. fungicola. A first infection of mushrooms of the commercial A. bisporus strain Sylvan A15 by L. fungicola did not induce systemic resistance against a subsequent infection. Similar results were obtained with the A. bisporus strain MES01497, which was demonstrated to be more resistant to dry bubble disease. Apparently, fruiting bodies of A. bisporus do not express induced resistance against L. fungicola.     

Lecanicillium fungicola: causal agent of dry bubble disease in white‐button mushroom

Lecanicillium fungicola causes dry bubble disease in commercially cultivated mushroom. This review summarizes current knowledge on the biology of the pathogen and the interaction between the pathogen and its most important host, the white‐button mushroom, Agaricus bisporus. The ecology of the pathogen is discussed with emphasis on host range, dispersal and primary source of infection. In addition, current knowledge on mushroom defence mechanisms is reviewed. Taxonomy: Lecanicillium fungicola (Preuss) Zare and Gams: Kingdom Fungi; Phylum Ascomycota; Subphylum Pezizomycotina; Class Sordariomycetes; Subclass Hypocreales; Order Hypocreomycetidae; Family Cordycipitaceae; genus Lecanicillium. Host range: Agaricus bisporus, Agaricus bitorquis and Pleurotus ostreatus. Although its pathogenicity for other species has not been established, it has been isolated from numerous other basidiomycetes. Disease symptoms: Disease symptoms vary from small necrotic lesions on the caps of the fruiting bodies to partially deformed fruiting bodies, called stipe blow‐out, or totally deformed and undifferentiated masses of mushroom tissue, called dry bubble. The disease symptoms and severity depend on the time point of infection. Small necrotic lesions result from late infections on the fruiting bodies, whereas stipe blow‐out and dry bubble are the result of interactions between the pathogen and the host in the casing layer. Economic importance: Lecanicillium fungicola is a devastating pathogen in the mushroom industry and causes significant losses in the commercial production of its main host, Agaricus bisporus. Annual costs for mushroom growers are estimated at 2–4% of total revenue. Reports on the disease originate mainly from North America and Europe. Although China is the main producer of white‐button mushrooms in the world, little is known in the international literature about the impact of dry bubble disease in this region. Control: The control of L. fungicola relies on strict hygiene and the use of fungicides. Few chemicals can be used for the control of dry bubble because the host is also sensitive to fungicides. Notably, the development of resistance of L. fungicola has been reported against the fungicides that are used to control dry bubble disease. In addition, some of these fungicides may be banned in the near future. Useful websites: http://www.mycobank.org ; http://www.isms.biz ; http://www.cbs.knaw.nl     

Occurrence of Verticillium fungicola var. fungicola on Agaricus bitorquis Mushroom Crops in Spain

Diseased fruit bodies of Agaricus bitorquis, with similar symptoms to those caused by dry bubble on Agaricus bisporus, were observed in some Spanish crops during summer 1999. Isolates of Verticillium fungicola from A. bitorquis and A. bisporus were submitted to different temperatures and to prochloraz–Mn sensitivity tests. All the isolates collected from A. bitorquis and A. bisporus were identified as V. fungicola var. fungicola. Artificial infections of A. bisporus and A. bitorquis with V. fungicola var. fungicola are also described in the present study. The appearance of natural infections of V. fungicola var. fungicola in A. bitorquis crops could well be due to the growing temperatures used in Spain, which are considerably below those used in other countries.     

In vitro sensitivity of Verticillium fungicola to selected fungicides

Twenty isolates of Verticillium fungicola var. fungicola collected from diseased fruit-bodies of Agaricus bisporus from prochloraz-treated crops, were exposed to a range of concentrations of six chemicals (benomyl, chlorothalonil, formaldehyde, iprodione, prochloraz-Mn-complex and prochloraz + carbendazim) in vitro. EC₅₀ values were determined for each fungus-fungicide combination. All isolates were more sensitive to prochloraz-Mn-complex (EC₅₀ values less than 5 mg 1^–1) than to the remainder fungicides, and only seven isolates were moderately sensitive (EC₅₀ values between 5 and 50 mg 1^–1) to prochloraz + carbendazim. All isolates were moderately sensitive to formaldehyde, whereas the majority of isolates were very resistant to the other three fungicides (benomyl, chlorothalonil and iprodione).     

Colonization of root tissues and protection against Fusarium wilt of rye (Secale cereale) by nonpathogenic rhizosphere strains of Fusarium culmorum

Colonization of rye (Secale cereale) tissues by nonpathogenic rhizosphere Fusarium culmorum isolates DEMFc2 and DEMFc5 and a pathogenic strain DEMFc37, and their effect on plant fresh weight were studied in pot experiments. Both rhizosphere isolates colonized the epidermis and the cortex but were not found in vessels, while the pathogen colonized all three layers of root cells. The numbers of pathogen CFU isolated from plant tissues were much higher than those of the rhizosphere isolates in spite of the same number of macroconidia used as inoculum (1 × 10⁵ g⁻¹ of soil). Inoculation of seedlings with DEMFc2 resulted in a 20% increase, with DEMFc5 in more than a 20% reduction, and with DEMFc37 in a 38% reduction of shoot fresh weight of 14-day-old plants. Pre-colonization of plants with (either of) the rhizosphere isolates and subsequent inoculation with the pathogen resulted in plant weights the same as those observed in plants inoculated with the rhizosphere strain alone. The disease severity index for shoots of plants pre-colonized with DEMFc2 was reduced from class 4 (86% diseased plants) observed for plants inoculated with the pathogen alone to class 2 (average of 8% diseased plants) when pre-treated with the rhizosphere strain. The CFU number of the pathogen isolated from the interior of roots of plants pre-colonized with the rhizosphere isolates was as low as 10% of the number isolated from plants inoculated with the pathogen alone. A study of in vitro interactions between the rhizosphere isolates and the pathogen suggests that changes in plant colonization by the pathogen and its effect on fresh weight of plants pre-colonized with the rhizosphere isolates were not connected with inhibition of its growth by a direct action of the rhizosphere isolates. The results suggest that strain DEMFc2 can be considered as a potential biocontrol agent.     

Comparison of partial sequence of the cap binding protein (eIF4E) isolated from Agaricus bisporus and its pathogen Verticillium fungicola

The 3 regions of the gene encoding the cap binding protein eIF4E were successfully isolated from Agaricus bisporus and Verticillium fungicola using a degenerate primer within the eIF4E gene and an anchored oligo d(T) primer. The deduced amino acid sequences contained 173 residues for A. bisporus and 171 residues V. fungicola. Analysis of these sequences shows that despite conserved regions of homology, centering around tryptophan residues, A. bisporus and V. fungicola are very diverse at the amino acid and DNA level. Percentage homology between the two fungi is low at the nucleotide, 35%, and amino acid level, 29%. The highest degree of similarity between the A. bisporus sequence and other published sequences is with the Homo sapiens eIF4E sequence (32%). V. fungicola exhibited highest homology with the eIF4E sequence from Caenorhabditis elegans (34%). Southern analysis of genomic DNA indicated a single copy of the gene within the A. bisporus genome.This revised version was published online in October 2005 with corrections to the Cover Date.     

Variation in aggressiveness among isolates of Cercospora zeae-maydis inlow-, medium- and high-altitude maize agro-ecologies of Tanzania

The objective of this study was to assess the aggressiveness and adaptation of Cercospora zeae-maydis the causal of grey leaf spot of maize in low-, mid- and high-altitude maize agro-ecologies. Field and laboratory studies were carried out to assess components of resistance, pathogen aggressiveness, sporulation, culture variations and morphological features of C. zeae-maydis isolates. Pathogen aggressiveness and morphological features differed among 30 isolates of C. zeae-maydis collected at different altitudes (p ≤ 0.05). Conidiophores per stroma between isolates ranged from 3.3 to 9.2 μ, conidiophore length 22.4–93.2 μ and colony growth rate ranged from 1.2 to 3.9 mm^?1. High-altitude isolates grew 0.25 mm per day faster (9.3%), formed 1.1 cm longer lesions (25.9%), produced 1.1 × 10⁴ more spores per cm² of the lesion (13.6%) and formed symptoms 1 day earlier than low-altitude isolates. Prevalence of high numbers of aggressive isolates in low-altitude agro-ecologies indicates increased adaptation of C. zeae-maydis to warmer conditions.     

The effect of tibia morphology on vector competency of mushroom sciarid flies

Mushroom sciarid flies Lycoriella ingenua (Dufour) and Bradysia ocellaris (Comstock) are major pests of cultivated mushrooms, Agaricus bisporus (Lange) Imbach. The economic threshold of these pests is very low because they vector pathogens across mushroom beds, e.g. Verticillium fungicola which causes ‘dry bubble’ disease. Under controlled conditions, B. ocellaris transported more V. fungicola spores than L. ingenua from infected to sterile culture plates. Similar results were obtained when L. ingenua and B. ocellaris were collected from a growing room infected with V. fungicola then introduced onto sterile culture plates for 90 min. The external morphology of B. ocellaris and L. ingenua was examined using scanning electron microscopy. The micrographs showed clusters of V. fungicola spores attached to the inner side of a comb‐like row of bristles on the fore tibia of B. ocellaris whereas L. ingenua does not possess an equivalent structure on the fore tibia. These morphological differences are the most probable explanation for the greater competence of B. ocellaris as a vector of V. fungicola compared with L. ingenua.     

Tolerance to dry bubble disease (Lecanicillium fungicola) in Iranian wild germplasm of button mushroom (Agaricus bisporus)

Agaricus bisporus is the most widely cultivated mushroom. The mushroom crop is subjected to several fungal diseases. Dry bubble disease caused by Lecanicillium fungicola is among notorious diseases of A. bisporus. This study aimed to assess phenotypic resistance to dry bubble disease among A. bisporus wild strains, collected from Iran regions. The reliability of resistance evaluations regarding disease incidence and intensity was well documented. The extraordinary tolerance of some wild strains to even high degrees of inoculum concentrations (10⁷ and 10⁸ spore/m² mushroom growth bed) of the pathogen in compare to commercial cultivars approved potentials of the wild germplasm in breeding programs for resistance. Also, the potential of some Microsatellite loci for the molecular-based rapid screening of tolerance was established by attributing SSR loci of phenotypically tolerant strains to QTLs for dry-bubble resistance-related traits.     

Isolation of a gram-positive bacterium effective in suppression of brown blotch disease of cultivated mushrooms,Pleurotus ostreatus andAgaricus bisporus, caused byPseudomonas tolaasii

A Gram-positive bacterium was isolated from a rottingPleurotus ostreatus fruiting body that markedly reduced the level of extracellular toxins (i.e., tolaasins) produced byPseudomonas tolaasii, the most destructive pathogen of cultivated mushrooms. The isolated bacterium is saprophytic but not parasitic nor pathogenic toP. ostreatus. A low ratio, ca. 10⁻³ cells of the isolated bacterium for oneP. tolaasii cells, was sufficient for detoxification in vitro. Inoculation of the isolated bacterium prevents the development of bacterial disease inP. ostreatus andAgaricus bisporus. The suppression of the disease development, however requires the initial cell density equivalent to ca. 10⁻¹ cells of the isolated bacterium for one cells of the pathogen. The effects is ascribed to the inactivation of tolaasin by the live, suppressive bacterial cells, and not to metabolites secreted from the organism into culture media. Examination by conventional bacteriological tests and with testing kits, i.e., MicroStation^TMSystem Release 3.5 (Biolog Inc., Hayward, CA), ATB Expression (bioMerieux Inc. Japan) and VITEK (bioMerieux Inc. Japan), failed to assign the organism to any defined bacterial genus. The suppressive bacterium may be useful in future for the development of biocontrol system and/or the construction of genetically modified edible fungi resistant to the disease caused byP. tolaasii.     

Biological control of rice bacterial blight by Lysobacter antibioticus strain 13-1

Bacterial leaf blight (BB) is a worldwide destructive rice disease caused by pathogen Xanthomonas oryzae pv. oryzae (Xoo). A novel strain of Lysobacter antibioticus, which was isolated from the rhizosphere of rice in Yunnan Province of China, can significantly inhibit the growth of various phytopathogenic bacteria and fungi, especially BB pathogen Xoo. In greenhouse experiments, whole bacterial broth culture (WBC) of strain 13-1 was more effective in reducing BB than other components of the culture, with disease suppression efficiency up to 69.7%. However, bacterial cells re-suspended in water, cell-free culture extracts, and heated cultures also significantly reduced BB severity. Suppression efficiencies ranged from 79.0% to 61.8% for undiluted to 100-fold dilution treatments and from 57.6% to 31.7% when the WBC of strain 13-1 (10⁸ CFU/mL) was applied at 3 days and 7 days prior to pathogen inoculation, respectively. In three field trials, strain 13-1 reduced BB incidence by 73.5%, 78.3%, and 59.1%, respectively. Disease suppression by strain 13-1 varied significantly among different rice cultivars, although efficacy was not directly related to the susceptibility level of the cultivars. Efficacy of biocontrol was also affected by different pathogen isolates, with some isolates of Xoo being more sensitive to 13-1 suppression than others. These results suggest that antibiotics and density of colonization on leaves may be involved for biological control of rice BB by strain 13-1. To our knowledge, this is the first report of L. antibioticus being a potential biocontrol agent for rice bacterial blight.     

Characterization of Kenyan Isolates of Fusarium udum from Pigeonpea [Cajanus cajan (L.) Millsp.] by Cultural Characteristics, Aggressiveness and AFLP Analysis

Isolates of Fusarium udum from pigeonpea (Cajanus cajan) plants with wilt symptoms were collected from various districts in Kenya and were characterized using cultural characteristics, aggressiveness and amplified fragment length polymorphism (AFLP). The 56 isolates of F. udum showed a high level of variability in aerial mycelia growth, pigmentation and radial mycelia growth (colony diameter) on potato dextrose agar. The aggressiveness of 17 isolates of F. udum on seven pigeonpea varieties varied and five aggressive groups were observed in the present study. There were no relationships among cultural characteristics and aggressiveness. AFLP analysis of the 56 isolates was tested for genetic variability using seven primer combinations. A total of 326 fragments was generated of which 121 were polymorphic. Ten AFLP groups were identified among the Kenyan isolates and, although they were not genetically distinct, six AFLP subgroups were genetically distinct. AFLP had no relationship with cultural characteristics, aggressiveness and geographical origin of the isolates. This is the first report on the study of genetic variability of F. udum using DNA analysis.     

Effects of Caenorhabditis elegans (Nematoda: Rhabditidae) on yield and quality of the cultivated mushroom Agaricus bisporus

Thirteen species of saprobic rhabditid nematodes (11 genera) were identified from samples of compost and casing material collected from mushroom farms in the British Isles. Caenorhabditis elegans, the most frequently found saprobe, was mass-produced monoxenically and its effects on the cultivated mushroom, Agaricus bisporus (strain U3) were studied. C. elegans did not multiply in well-prepared, pasteurised, spawned compost, whereas casing material proved to be a highly suitable environment for its reproduction. An initial casing inoculum of 10⁶ nematodes/crate of compost (7.5 kg), caused a significant reduction in mushroom yield. Losses in total mushroom yields of 11%, 20% and 26% were caused by initial inoculum rates of 10⁶, 10⁷and 2 × 10⁷ nematodes/crate, respectively. Yields were negatively correlated with the initial nematode inoculation level and regression equations were derived. The nematode treatments caused fewer mushrooms to be produced and an absence of the usual distinctive flushing patterns. C. elegans caused considerable deterioration in mushroom quality and characteristic distortion of mushrooms. Individual sporophores were mis-shapen, notched and had brown or violet coloured grills. Up to 3.8%, 6.7% and 10.8% of total weight and 3.5%, 5.4% and 8% of total numbers of mushrooms were distorted at the three highest nematode inoculum rates tested. Weights and numbers of distorted mushrooms were positively correlated with the initial nematode population. C. elegans commonly colonised sporophores.     

Effect of the fungicide Prochloraz-Mn on the cell wall structure of <Emphasis Type="Italic">Verticillium fungicola</Emphasis>

The chemical structure of the cell wall of two isolates of Verticillium fungicola collected from diseased fruit bodies of the commercial mushroom Agaricus bisporus treated with the fungicide Prochloraz-Mn was analyzed. The isolates were obtained during different periods of time and grown in the absence and presence of the LD₅₀ values of the fungicide for V. fungicola. In addition, another V. fungicola isolate collected previous to the routine utilization of Prochloraz-Mn but grown under the same conditions was also analyzed. The overall chemical composition of the cell wall from the three isolates showed detectable differences in their basic components, with a significant decrease in the protein content in fungicide-treated cells. This inhibitory effect was partially compensated by an increase in neutral and/or aminated carbohydrates and was accompanied by appreciable modifications of polysaccharide structure, as deduced after methylation analysis and gas-liquid chromatography-mass spectrometry (GLC-MS). Moreover, differences in hyphal morphology caused by the fungicide were observed by transmission electron microscopy (TEM). Accepted 2 May 2002 Electronic Publication     

Variation in Aggressiveness Components in the Hemileia vastatrix Population in Brazil

The Pucciniomycete fungus Hemileia vastatrix causes leaf rust on coffee trees. The pathogen is responsible for considerable yield losses in susceptible coffee cultivars if appropriate management strategies are not implemented. Rapid spread and epidemics of rust fungi are usually associated with the emergence of new races of the pathogen that overcome resistance or with the emergence of more aggressive populations of the pathogen. In Brazil, coffee production is dominated by susceptible cultivars of Coffea arabica and Coffea canephora. We assessed aggressiveness in 46 populations of H. vastatrix from Minas Gerais and Espírito Santo, two of the most important coffee‐producing states in Brazil. We observed a significant difference in the incubation period between the populations from Minas Gerais and Espírito Santo when 183 single‐pustule isolates were inoculated onto Catuaí Vermelho IAC 44, a susceptible C. arabica cultivar. Variation in aggressiveness components was observed between and within localities. Isolates with longer incubation periods also tended to have longer latent periods, although there was only a low correlation between these two aggressiveness components (r² = 0.34, P = 2.2 × 10^?16). Low‐sporulating isolates also had significantly longer incubation and latent periods. The H. vastatrix population from Minas Gerais and Espírito Santo is structured by the formation of groups of individuals with differential level of aggressiveness. Our results indicate that the variation in aggressiveness of the Brazilian H. vastatrix population may be associated with the geographic coffee‐producing areas.     

Pathogenicity Determinants of Sclerotinia sclerotiorum and Their Association to Its Aggressiveness on Brassica juncea

White rot or stem rot caused by Sclerotinia sclerotiorum is one of the most destructive fungal diseases that have become a serious threat to the successful cultivation of oilseed Brassicas. The study was designed with an aim to investigate the association between the pathogenic aggressiveness and pathogenicity determinants of this pathogen specifically in Brassica for the first time. For this, a total of 58 isolates of S. sclerotiorum from different geographical regions were collected and purified. These isolates were inoculated on a Brassica juncea cv. RL-1359 and they exhibited high level of variation in their disease progression. The isolates were grouped and then 24 isolates were selected for the biochemical analysis of pathogenicity determinants. The isolates varied significantly with respect to their total organic acids, oxalic acid production and pectin methyl esterase and polygalacturonase activity. The oxalic acid production corresponded to the disease progression of the isolates; the isolates with higher oxalic acid production were the more aggressive ones and vice-versa. This is, in our knowledge, the first study to establish a correlation between oxalic acid production and pathogenic aggressiveness of S. sclerotiorum on B. juncea. However, the pectinases’ enzyme activity did not follow the trend as of disease progression. These suggest an indispensable role of oxalic acid in pathogenicity of the fungus and the potential to be used as biochemical marker for preliminary assessment of pathogenic aggressiveness of various isolates before incorporating them in a breeding program.     

Formulation of the Biocontrol FungusCladorrhinum foecundissimumto Reduce Damping-Off Diseases Caused byRhizoctonia solaniandPythium ultimum

Five isolates ofCladorrhinum foecundissimum, added to soilless mix as 10-day-old fresh bran preparations (1.0% w/w), significantly reduced (P≤ 0.05) damping-off of eggplant and pepper caused byRhizoctonia solanistrain R-23. After 4 weeks of growth, plant stands in the biocontrol-amended, pathogen-infested treatments (>80%) were comparable to those in the noninfested controls. Since plant stands were similar at 2 and 4 weeks, most of the disease was preemergence damping-off. The bran preparations also reduced saprophytic growth of the pathogen, and there was an inverse correlation (r²= −0.94) between saprophytic growth and eggplant stand. Added to soilless mix at a rate of 2.0% (w/w), alginate prill containing 20% fermentor-produced biomass of six biocontrol isolates ofC. foecundissimumreduced (P≤ 0.05) damping-off of eggplant caused byR. solani, but only the prill with biomass of isolates Cf-1 or Cf-2 yielded plant stands (>80%) comparable to that in the noninfested control. As with the bran preparations, there was also an inverse correlation (r²= −0.80) between saprophytic growth of R-23 and eggplant stand with the alginate prills. Alginate prill with biomass of Cf-1 or Cf-2 also reduced (P≤ 0.05) damping-off of eggplant and pepper caused by other isolates (195, NG-2, DPR-1) ofR. solani, but only the stands (>80%) of pepper were similar to that in the noninfested control. Alginate prill formulations ofC. foecundissimum(Cf-1, Cf-2, and Cf-3) also reduced (P≤ 0.05) populations of the pathogen and damping-off of eggplant and pepper caused byPythium ultimum(PuZ3). However, although the plant stands in the treatments were not as high as those in the noninfested controls, they were higher than those in the pathogen-infested controls. The treatments also reduced populations ofP. ultimumin the soilless mix so that there were inverse correlations between the pathogen population and eggplant stand (r²= −0.81) and pepper stand (r²= −0.78). Extruded flour/clay granules containing 5.0% biomass of Cf-1 and Cf-2, added toR. solani-infested soilless mix (2.0%), reduced (P≤ 0.05) damping-off of eggplant and pepper. However, only the Cf-2 treatments resulted in stands (>80%) equal to those in the noninfested controls for the crops after 4 weeks of growth. The influence of bran and alginate prill of Cf-1 or Cf-2 on the spatial spread ofR. solaniand its ability to incite damping-off of eggplant showed that prill with Cf-1 or Cf-2 and bran with Cf-2 were equally effective in reducing the spread of the pathogen from the point source of the inoculum to the center of the flats.     

乌鳢源杀鱼爱德华菌的分离鉴定及药敏特性研究

[背景] 江苏省扬州市某乌鳢养殖场发生疾病,给养殖户造成了严重的经济损失。[目的] 确定病因并筛选出敏感药物,为乌鳢相关疾病的防治提供参考。[方法] 从患病乌鳢体内分离致病菌,并从形态、生理生化特征、16S rRNA和gyrB基因序列及特异性PCR检测等方面对分离菌株进行鉴定,同时开展人工感染试验分析其致病性,通过纸片扩散法进行药敏特性分析。[结果] 从患病乌鳢体内分离获得优势菌株SHL,经形态特征、理化特性、16S rRNA和gyrB基因序列及特异性PCR检测鉴定为杀鱼爱德华菌。进一步人工感染试验证实其对乌鳢有较强的致病性,LD₅₀为1.6×10⁵ CFU/g,发病症状与自然发病症状相似。药敏试验结果显示,该菌株对青霉素、氯霉素、四环素等28种抗菌药物高度敏感,对红霉素中度敏感,对苯唑西啉、克拉霉素、万古霉素等6种药物耐药。[结论] 引起江苏省扬州市某养殖场的乌鳢体表溃烂及死亡的病原菌为杀鱼爱德华菌,这是我国首次从淡水鱼类中检出致病性杀鱼爱德华菌,表明该菌的感染谱在扩大,需引起水产养殖领域的重视,在养殖过程中可根据药敏实验结果选用合适的国标渔药进行防治。