Characterization of <Emphasis Type="Italic">Dickeya</Emphasis> strains isolated from potato and river water samples in Finland

Plant pathogenic enterobacteria in the genera Pectobacterium and Dickeya (formerly classified as Erwinia) were isolated from diseased potato stems and tubers. The isolated bacteria were identified as P. atrosepticum, P. carotovorum and pathogens in the genus Dickeya with PCR tests. Furthermore, Dickeya strains were isolated from river water samples throughout the country. Phylogenetic analysis with 16S-23S rDNA intergenic spacer sequences suggested that the Dickeya strains could be divided into three groups, two of which were isolated from potato samples. Phylogenetic analysis with 16S rDNA sequences and growth at 39°C suggested that one of the groups corresponds to D. dianthicola, a quarantine pathogen in greenhouse cultivation of ornamentals, while two of the groups did not clearly resemble any of the previously characterised Dickeya species. Field trials with the strains indicated that D. dianthicola-like strains isolated from river samples caused the highest incidence of rotting and necrosis of potato stems, but some of the Dickeya strains isolated from potato samples also caused symptoms. The results showed that although P. atrosepticum is still the major cause of blackleg in Finland, virulent Dickeya strains were commonly present in potato stocks and rivers. This is the first report suggesting that Dickeya, originally known as a pathogen in tropical and warm climates, may cause diseases in potato in northern Europe.     

<Emphasis Type="Italic">Pectobacterium carotovorum</Emphasis> subsp. <Emphasis Type="Italic">carotovorum</Emphasis> can cause potato blackleg in temperate climates

It is well established that the pectinolytic bacteria Pectobacterium atrosepticum (Pca) and Dickeya spp. are causal organisms of blackleg in potato. In temperate climates, the role of Pectobacterium carotovorum subsp. carotovorum (Pcc) in potato blackleg, however, is unclear. In different western and central European countries plants are frequently found with blackleg from which only Pcc can be isolated, but not Pca or Dickeya spp. Nevertheless, tubers vacuum-infiltrated with Pcc strains have so far never yielded blackleg-diseased plants in field experiments in temperate climates. In this study, it is shown that potato tubers, vacuum-infiltrated with a subgroup of Pcc strains isolated in Europe, and planted in two different soil types, can result in up to 50% blackleg diseased plants.     

Symptoms and yield reduction caused by Dickeya spp. strains isolated from potato and river water in Finland

Biochemical characterisation of Dickeya strains isolated from potato plants and river water samples in Finland showed that the majority of the strains were biovar 3. They thus resembled the strains recently isolated from potato in the Netherlands, Poland and Israel and form a new clade within the Dickeya genus. About half of the Finnish isolates resembling strains within this new clade were virulent and caused wilting, necrotic lesions and rotting of leaves and stems. Similar symptoms were caused by D. dianthicola strains isolated from one potato sample and from several river water samples. Frequently, the rotting caused by the Dickeya strains was visible in the upper parts of the stem, while the stem base was necrotic from the pith but hard and green on the outside, resulting in symptoms quite different from the blackleg caused by Pectobacterium atrosepticum. The presence of Dickeya in the symptomatic plants in the field assay was verified with a conventional PCR and with a real-time PCR test developed for the purpose. The virulent Dickeya strains reduced the yield of individual plants by up to 50% and caused rotting of the daughter tubers in the field and in storage. Management of Dickeya spp. in the potato production chain requires awareness of the symptoms and extensive knowledge about the epidemiology of the disease.     

Detection of phytopathogens of the genus Dickeya using a PCR primer prediction pipeline for draft bacterial genome sequences

This study used a novel computational pipeline to exploit draft bacterial genome sequences in order to predict, automatically and rapidly, PCR primer sets for Dickeya spp. that were unbiased in terms of diagnostic gene choice. This pipeline was applied to 16 draft and four complete Dickeya genome sequences to generate >700 primer sets predicted to discriminate between Dickeya at the species level. Predicted diagnostic primer sets for both D. dianthicola (DIA‐A and DIA‐B) and ‘D. solani’ (SOL‐C and SOL‐D) were validated against a panel of 70 Dickeya reference strains, representative of the known diversity of this genus, to confirm primer specificity. The classification of the four previously sequenced strains was re‐examined and evidence of possible misclassification of three of these strains is presented.     

Genes responsible for coronatine synthesis in <Emphasis Type="Italic">Pseudomonas syringae</Emphasis> present in the genome of soft rot bacteria

Primers for the PCR amplification of homologous genes encoding polyketide coronafacic acid and coronafacic ligase in the cells of Pectobacterium atrosepticum SCRI1043 (BX950851) were developed to study the presence of these genes in the genome of Pectobacterium sp. and Dickeya sp. Coronafacic ligase catalyses the formation of coronatine from polyketide coronafacic acid and coronamic acid. Coronatine is a toxin produced by Pseudomonas syringae and is one of the major virulence factors in this bacterium. This study using several strains of P. atrosepticum, P. carotovorum subsp. carotovorum and Dickeya sp. isolated in different countries, indicated that all strains of P. atrosepticum possess genes coding coronafacic acid (cfa gene cluster) and coronafacic ligase (cfl). However, these genes were present only in the genome of five out of 50 tested P. carotovorum subsp. carotovorum strains and two out of 34 strains of Dickeya sp. tested. The PCR products homologous to the sequence of cfa7 and cfl gene fragments were sequenced in order to check the level of homology between genes of P. atrosepticum, P. carotovorum subsp. carotovorum and Dickeya sp. The sequences of the gene fragments amplified from all P. atrosepticum strains were almost identical (100% and 99.97%, respectively). The homology of the sequences obtained for P. atrosepticum and sequences of five P. carotovorum subsp. carotovorum and two Dickeya sp. was lower, between 89.69% to 95.00% for the cfl gene fragment, and about 94% for the cfa7 gene fragment.     

Evaluation of a diagnostic microarray for the detection of major bacterial pathogens of potato from tuber samples

Potato can be infected with many bacterial pathogens, the detection of which is necessary in seed certification. In this study, a diagnostic microarray previously tested for specificity of probes for detecting the potato bacteria causing blackleg and soft rot (Pectobacterium atrosepticum, Pectobacterium carotovorum, and Dickeya spp.), ring rot (Clavibacter. michiganensis subsp. sepedonicus), scab (Streptomyces scabies and Streptomyces turgidiscabies) and brown rot (Ralstonia solanacearum) from pure culture was evaluated for analytical sensitivity when testing directly from tuber samples. The microarray readily detected all the bacterial species when 100 ng of the target bacterial DNA from pure culture was mixed with DNA from soil microbes and potato. However, detection was inconsistent when total DNA isolated directly from infected tubers or enriched bacterial culture was used. While the high specificity of the probes could be confirmed from the results of the DNA cocktail experiment used as a control, the study demonstrated that the level of analytical sensitivity of the microarray under the tested condition was not sufficient to detect bacteria directly from tubers. Therefore, in addition to the cost and organizational complexities, the low analytical sensitivity and limited reproducibility of the microarray are constraints for establishing the platform for routine detection of potato bacterial pathogens from tuber samples.     

Assessment of recent outbreaks of <Emphasis Type="Italic">Dickeya</Emphasis> sp. (syn. <Emphasis Type="Italic">Erwinia chrysanthemi</Emphasis>) slow wilt in potato crops in Israel

Suspected Dickeya sp. strains were obtained from potato plants and tubers collected from commercial plots. The disease was observed on crops of various cultivars grown from seed tubers imported from the Netherlands during the spring seasons of 2004–2006, with disease incidence of 2–30% (10% in average). In addition to typical wilting symptoms on the foliage, in cases of severe infection, progeny tubers were rotten in the soil. Six strains were characterised by biochemical, serological and PCR-amplification. All tests verified the strains as Dickeya sp. The rep-PCR and the biochemical assays showed that the strains isolated from blackleg diseased plants in Israel were very similar, if not identical to strains isolated from Dutch seed potatoes, suggesting that the infection in Israel originated from the Dutch seed. The strains were distantly related to D. dianthicola strains, typically found in potatoes in Western Europe, and were similar to biovar 3 D. dadanti or D. zeae. This is the first time that the presence of biovar 3 strains in potato in the Netherlands is described. One of the strains was used for pathogenicity assays on potato cvs Nicola and Mondial. Symptoms appeared 2 to 3 days after stem inoculation, and 7 to 10 days after soil inoculation. The control plants treated with water, or plants inoculated with Pectobacterium carotovorum, did not develop any symptoms with either method of inoculation. The identity of Dickeya sp. and P. carotovorum re-isolated from inoculated plants was confirmed by PCR and ELISA.     

Studies on the interaction between the biocontrol agent,Serratia plymuthica A30, and blackleg‐causing Dickeya sp. (biovar 3) in potato (Solanum tuberosum)

Interactions between Serratia plymuthica A30 and a blackleg‐causing biovar 3 Dickeya sp. were examined. In a potato slice assay, S. plymuthica A30 inhibited tissue maceration caused by Dickeya sp. IPO2222 when co‐inoculated at a density at least 10 times greater than that of the pathogen. In glasshouse experiments, population dynamics of the antagonist and of the pathogen in planta were studied by dilution plating and confocal laser scanning microscopy (CLSM) using fluorescent protein‐tagged strains. Pathogen‐free minitubers were vacuum‐infiltrated with DsRed‐tagged Dickeya sp. IPO2222 and superficially treated during planting with a water suspension containing GFP‐tagged S. plymuthica A30. A30 reduced the blackleg incidence from 55% to 0%. Both the pathogen and the antagonist colonized the seed potato tubers internally within 1 day post‐inoculation (dpi). Between 1 and 7 dpi, the population of A30 in tubers increased from 10¹ to c. 10³ CFU g^?1 and subsequently remained stable until the end of the experiment (28 dpi). Populations of A30 in stems and roots increased from c. 10² to c. 10⁴ CFU g^?1 between 7 and 28 dpi. Dilution plating and CLSM studies showed that A30 decreased the density of Dickeya sp. populations in plants. Dilution plating combined with microscopy allowed the enumeration of strain A30 and its visualization in the vascular tissues of stem and roots and in the pith of roots, as well as its adherence to and colonization of the root surface. The implications of these finding for the use of S. plymuthica A30 as a biocontrol agent are discussed.     

Biochemical and genetical analysis reveal a new clade of biovar 3 <Emphasis Type="Italic">Dickeya</Emphasis> spp. strains isolated from potato in Europe

Sixty-five potato strains of the soft rot-causing plant pathogenic bacterium Dickeya spp., and two strains from hyacinth, were characterised using biochemical assays, REP-PCR genomic finger printing, 16S rDNA and dnaX sequence analysis. These methods were compared with nineteen strains representing six Dickeya species which included the type strains. A group of twenty-two potato strains isolated between 2005-2007 in the Netherlands, Poland, Finland and Israel were characterised as belonging to biovar 3. They were 100% identical in REP-PCR, dnaX and 16S rDNA sequence analysis. In a polyphasic analysis they formed a new clade different from the six Dickeya species previously described, and may therefore constitute a new species. The strains were very similar to a Dutch strain from hyacinth. On the basis of dnaX sequences and biochemical assays, all other potato strains isolated in Europe between 1979 and 1994 were identified as D. dianthicola (biovar 1 and 7), with the exception of two German strains classified as D. dieffenbachia (biovar 2) and D. dadantii (biovar 3), respectively. Potato strains from Peru were classified as D. dadantii, from Australia as D. zeae and from Taiwan as D. chrysanthemi bv. parthenii, indicating that different Dickeya species are found in association with potato.     

Virulence of Pectobacterium carotovorum subsp. brasiliense on potato compared with that of other Pectobacterium and Dickeya species under climatic conditions prevailing in the Netherlands

In western Europe, Pectobacterium carotovorum subsp. brasiliense is emerging as a causal agent of blackleg disease. In field experiments in the Netherlands, the virulence of this pathogen was compared with strains of other Dickeya and Pectobacterium species. In 2013 and 2014, seed potato tubers were vacuum infiltrated with high densities of bacteria (10⁶ CFU mL^?1) and planted in clay soil. Inoculation with P. carotovorum subsp. brasiliense and P. atrosepticum resulted in high disease incidences (75–95%), inoculation with D. solani and P. wasabiae led to incidences between 5% and 25%, but no significant disease development was observed in treatments with P. carotovorum subsp. carotovorum, D. dianthicola or the water control. Co‐inoculations of seed potatoes with P. carotovorum subsp. brasiliense and D. solani gave a similar disease incidence to inoculation with only P. carotovorum subsp. brasiliense. However, co‐inoculation of P. carotovorum subsp. brasiliense with P. wasabiae resulted in a decrease in disease incidence compared to inoculation with only P. carotovorum subsp. brasiliense. In 2015, seed potatoes were inoculated with increasing densities of P. carotovorum subsp. brasiliense, D. solani or P. atrosepticum (10³–10⁶ CFU mL^?1). After vacuum infiltration, even a low inoculum density resulted in high disease incidence. However, immersion without vacuum caused disease only at high bacterial densities. Specific TaqMan assays were evaluated and developed for detection of P. carotovorum subsp. brasiliense, P. wasabiae and P. atrosepticum and confirmed the presence of these pathogens in progeny tubers of plants derived from vacuum‐infiltrated seed tubers.     

Characterization of <Emphasis Type="Italic">Dickeya</Emphasis> and <Emphasis Type="Italic">Pectobacterium</Emphasis> strains obtained from diseased potato plants in different climatic conditions of Norway and Poland

Soft rot and blackleg of potato caused by pectinolytic bacteria lead to severe economic losses in potato production worldwide. To investigate the species composition of bacteria causing soft rot and black leg of potato in Norway and Poland, bacteria were isolated from potato tubers and stems. Forty-one Norwegian strains and 42 Polish strains that formed cavities on pectate medium were selected for potato tuber maceration assays and sequencing of three housekeeping genes (dnaX, icdA and mdh) for species identification and phylogenetic analysis. The distribution of the species causing soft rot and blackleg in Norway and Poland differed: we have demonstrated that mainly P. atrosepticum and P. c. subsp. carotovorum are the causal agents of soft rot and blackleg of potatoes in Norway, while P. wasabiae was identified as one of the most important soft rot pathogens in Poland. In contrast to the other European countries, D. solani seem not to be a major pathogen of potato in Norway and Poland. The Norwegian and Polish P. c. subsp. carotovorum and P. wasabiae strains did not cluster with type strains of the respective species in the phylogenetic analysis, which underlines the taxonomic complexity of the genus Pectobacterium. No correlation between the country of origin and clustering of the strains was observed. All strains tested in this study were able to macerate potato tissue. The ability to macerate potato tissue was significantly greater for the P. c. subsp. carotovorum and Dickeya spp., compared to P. atrosepticum and P. wasabiae.     

The use of two complementary DNA assays,AFLP and MLSA,for epidemic and phylogenetic studies of pectolytic enterobacterial strains with focus on the heterogeneous species Pectobacterium carotovorum

Amplified fragment length polymorphism (AFLP) markers and multilocus sequence analysis (MLSA) were used to analyse 63 bacterial strains, including 30 soft‐rot‐causing bacterial strains collected from Syrian potato fields and 33 reference strains. For the MLSA, additional sequences of 41 strains of Pectobacterium and Dickeya, available from the NCBI GenBank, were included to produce a single alignment of the 104 taxa for the seven concatenated genes (acnA, gapA, proA, icd, mtlD, mdh and pgi). The results indicate the need for a revision of the previously classified strains, as some potato‐derived Pectobacterium carotovorum strains were re‐identified as P. wasabiae. The strains that were classified as P. carotovorum during the analyses demonstrated high heterogeneity and grouped into five P. carotovorum highly supported clusters (PcI to PcV). The strains represented a wide range of host plants including potatoes, cabbage, avocados, arum lilies, sugar cane and more. Host specificity was detected in PcV, in which four of the six strains were isolated from monocotyledonous plants. The PcV strains formed a clearly distinct group in all the constructed phylogenetic trees. The number of strains phylogenetically classified as subspecies ‘P. c. subsp. brasiliensis’ in PcIV dramatically increased in size as a result of the characterization of new isolates or re‐identification of previous P. carotovorum and P. atrosepticum strains. The P. carotovorum strains from Syria were grouped into PcI, PcII and PcIV. This grouping indicates a lack of correlation between the geographical origin and classification of these pathogens.     

Development and evaluation of Taqman assays for the differentiation of Dickeya (sub)species

TaqMan assays were developed for the detection of seven Dickeya species, namely D. dianthicola, D. dadantii, D. paradisiaca, D. chrysanthemi, D. zeae, D. dieffenbachiae and D. solani. Sequences of the gene coding for dnaX were used for the design of primers and probes. In studies with axenic cultures of bacteria, the assays were highly specific and only reacted with strains of the target species, and not with non-target bacteria, including those belonging to other Dickeya species and other genera. The detection thresholds for DNA extracted from pure cultures of target strains ranged from 10 to 100 fg. The TaqMan assays for D. dianthicola and D. solani were more extensively evaluated as part of a method validation procedure. The threshold level for target bacteria added to a potato peel extract diluted ten-times in a semi-selective broth, was strain dependent and ranged from 1,000 to 100,000 cfu/ml. The coefficients of variation for repeatability and reproducibility were low and results were largely independent of the type of substrate, i.e. potato tuber or carnation leaf extracts. However, during routine testing of seed potatoes, false-positive reactions were found with the assay for D. solani. The use of the TaqMan assays for inspection of plant propagation material, ecological studies and studies on the effect of control strategies in disease management strategies is discussed.     

Application of RFLP analysis of recA, gyrA and rpoS gene fragments for rapid differentiation of Erwinia amylovora from Erwinia strains isolated in Korea and Japan

Restriction fragment length polymorphism (RFLP) analysis of the PCR amplified fragments of recA, gyrA and rpoS genes was applied for the characterization of Erwinia amylovora and Erwinia strains, which cause fire blight and Asian pear blight in orchards. Primers, constructed on the basis of the published recA, gyrA and rpoS gene sequences of Erwinia carotovora, allowed us to amplify DNA fragments for RFLP differentiation of E. amylovora and E. pyrifoliae and finally to distinguish strains within these species and relate them to pear pathogens from Japan. Three to seven restriction endonucleases were applied for RFLP analysis of each gene fragment. The electrophoretic patterns generated after PCR–RFLP for each of the tested genes, were characteristic and specific for each species and allowed their differentiation. The data show that PCR–RFLP analysis of the recA, gyrA and rpoS gene fragments may be considered as a useful tool for the identification and differentiation of E. amylovora and E. pyrifoliae. Almost identical restriction patterns of the analyzed gene fragments indicated a high relationship of E. pyrifoliae strains from Korea and pear pathogens from Japan and a divergence to E. amylovora. For quick and effective differentiation of E. amylovora strains from Erwinia strains from Asia without nucleotide sequencing we recommend the amplification of recA and rpoS gene fragments and digestion of each of them with restriction endonuclease Hin6I.     

Phenotypic diversity,host range and molecular phylogeny of <Emphasis Type="Italic">Dickeya</Emphasis> isolates from Spain

Six Dickeya spp. strains representative of a larger group of bacteria isolated from potato, onion and irrigation water in Spain between years 2003–2005, were characterised by biochemical, serological, molecular and pathogenicity assays. Biochemical and serological differences, as well as pathogenic behaviour in host range and virulence levels, were observed among the strains. They were classified into biovars 3 and 6. Phylogenetic analysis and comparison of the isolates with type strains of Dickeya species characterised to date were performed using concatenated partial sequences of the housekeeping genes gapA and mdh. One of the Spanish strains was identified as D. dieffenbachiae, whereas the other ones did not fit clearly into the previously described six Dickeya species, and may therefore constitute novel species. Isolation of dissimilar pathogenic strains in different rivers and irrigation water sources supports the idea that Dickeya species is commonly present in such an environment, and contaminated water is a potential source of inoculum for the disease in different crops.     

Pectate lyases of Erwinia chrysanthemi: Pel E-like polypeptides and pelE homologous sequences in strains isolated from different plants

Pel E, one of the four major pectate lyases produced by Erwinia chrysanthemi (Echr) strain EC16, was purified to homogeneity and was found to have an apparent molecular weight of 47 500 and a pI of 10. Antibodies produced against this preparation inhibited Pel E activity, but did not affect Pel A, Pel B or Pel C activities. Immunotitration revealed that Pel E accounted for a major fraction of the total extracellular Pel activity ranging from 40–60% in culture and potato tuber tissue. Isoelectric focusing of the extracellular Pels produced by various Echr strains indicated that while the Pel profiles of strains isolated from various hosts were different, the profiles of strains isolated from the same host were very similar. A significant proportion (ranging from 39 to 74%) of the Pel activity of these strains was inhibited by the anti-Pel E antibodies. DNA hybridization under stringent conditions indicated the presence of pelE homologous sequences in the genomes of E. chrysanthemi strains. We conclude that a Pel E-like enzyme occurs in all E. chrysanthemi strains examined.     

Distribution of <Emphasis Type="Italic">Dickeya</Emphasis> spp. and <Emphasis Type="Italic">Pectobacterium carotovorum</Emphasis> subsp. <Emphasis Type="Italic">carotovorum</Emphasis> in naturally infected seed potatoes

Detailed studies were conducted on the distribution of Pectobacterium carotovorum subsp. carotovorum and Dickeya spp. in two potato seed lots of different cultivars harvested from blackleg-diseased crops. Composite samples of six different tuber sections (peel, stolon end, and peeled potato tissue 0.5, 1.0, 2.0 and 4.0 cm from the stolon end) were analysed by enrichment PCR, and CVP plating followed by colony PCR on the resulting cavity-forming bacteria. Seed lots were contaminated with Dickeya spp. and P. carotovorum subsp. carotovorum (Pcc), but not with P. atrosepticum. Dickeya spp. and Pcc were found at high concentrations in the stolon ends, whereas relatively low densities were found in the peel and in deeper located potato tissue. Rep-PCR, 16S rDNA sequence analysis and biochemical assays, grouped all the Dickeya spp. isolates from the two potato seed lots as biovar 3. The implications of the results for the control of Pectobacterium and Dickeya spp., and sampling strategies in relation to seed testing, are discussed.     

Characterization of bacterial isolates from rotting potato tuber tissue showing antagonism to Dickeya sp. biovar 3 in vitro and in planta

Possibilities for biocontrol of biovar 3 Dickeya sp. in potato were investigated, using bacteria from rotting potato tissue isolated by dilution plating on nonselective agar media. In a plate assay, 649 isolates were screened for antibiosis against Dickeya sp. IPO2222 and for the production of siderophores. Forty‐one isolates (6·4%) produced antibiotics and 112 isolates (17·3%) produced siderophores. A selection of 41 antibiotic‐producing isolates and 41 siderophore‐producing isolates were tested in a potato slice assay for control of the Dickeya sp. Isolates able to reduce rotting of potato tuber tissue by at least 50% of the control were selected. Isolates were characterized by 16S rDNA analysis as Bacillus, Pseudomonas, Rhodococcus, Serratia, Obesumbacterium and Lysinibacillus genera. Twenty‐three isolates belonging to different species and genera, 13 producing antibiotics and 10 producing siderophores, were further characterized by testing acyl‐homoserine lactone (AHL) production, quorum quenching, motility, biosurfactant production, growth at low (4·0) and high (10·0) pH, growth at 10°C under aerobic and anaerobic conditions and auxin production. In replicated greenhouse experiments, four selected antagonists based on the in vitro tests were tested in planta using wounded or intact minitubers of cv. Kondor subsequently inoculated by vacuum infiltration with an antagonist and a GFP (green fluorescent protein)‐tagged biovar 3 Dickeya sp. strain. A potato endophyte A30, characterized as S. plymuthica, protected potato plants by reducing blackleg development by 100% and colonization of stems by Dickeya sp. by 97%. The potential use of S. plymuthica A30 for the biocontrol of Dickeya sp. is discussed.     

实时荧光定量PCR法检测十字花科细菌性黑斑病菌

为有效防控我国的检疫性有害生物十字花科细菌性黑斑病菌Pseudomonas syringae pv.maculicola在国内的传播与蔓延,通过设计1对特异性引物3539,利用132株靶标和非靶标菌为模板进行PCR扩增,建立了实时荧光定量PCR法,并进行了模拟种子带菌试验。结果显示,引物3539为只针对十字花科细菌性黑斑病菌扩增出的特异性产物;在模拟种子带菌检测中,常规PCR对菌悬液的检测限为10~5CFU/m L,实时荧光定量PCR的检测限为10~3CFU/m L,其中10~8CFU/m L菌液的Ct值最低,为22.90,10~3CFU/m L菌液的Ct值最高,为35.73,且不同浓度菌液间的Ct值均有显著差异;不同带菌率模拟种子的检测结果表明,常规PCR和实时荧光定量PCR能检测到的带菌率分别为0.5%和0.1%。研究表明,实时荧光定量PCR法不仅可用于病种的检测,也可用于病害的早期诊断。     

马铃薯疮痂病高效生防芽孢杆菌的筛选及发酵条件优化

利用已鉴定的5株拮抗马铃薯黑痣病病原菌的生防芽孢杆菌（Bacillus）,筛选其对马铃薯疮痂病病原菌的抑制作用,通过检测生防菌脂肽类抗生素合成相关基因研究其生防机制。对峙试验结果表明,5株生防菌中以QHZ-3对马铃薯疮痂病病原菌的抑制效果最佳,抑菌率为44%;抗生素合成基因检测结果显示,QHZ-1和QHZ-2具有丰原素（Fengycin）和伊枯草菌素（Iturin）合成酶基因;QHZ-4仅具有Fengycin合成酶基因;而QHZ-3与QHZ-5菌株同时具有表面活性素（surfactin）、伊枯草菌素（Iturin）和丰原素（fengycin）3种脂肽类抗生素合成酶基因。选择最具生防潜力的QHZ-3进行进一步试验,发现该菌株发酵滤液对疮痂链霉菌的抑菌圈直径达到30.4 mm,且在高温、紫外照射以及强酸强碱的条件下抑菌圈直径仍然可保持在27 mm以上。单因素试验结果表明,每瓶（250 mL）装液量60 mL,接种量6%,摇床转速180 r·min^-1,发酵时间60 h的条件下,菌株QHZ-3的生长量最高。正交试验结果显示,装液量每瓶40 mL、摇床转速170 r·min^-1、接种量6%、发酵时间48 h的组合下,QHZ-3生长状态最佳,活菌数可达到1.31×10¹⁰ cfu·mL^-1。二次固态发酵条件优化结果显示,以腐熟的牛粪有机肥为载体,在接种量为15%时,活菌数最高,达到1.14×10⁹ cfu·mL^-1。