Detection of Erwinia herbicola pv. gypsophilae in gypsophila plants by PCR

Three PCR primer pairs, based on the cytokinins (etz) or IAA biosynthetic genes, were used for detecting Erwinia herbicola pv. gypsophilae in Gypsophila paniculata plants. The primers were specific to all gall-forming E. herbicola strains and distinguished them from saprophytic strains associated with gypsophila plants or from other gall-forming bacteria. In pure culture of the pathogen, less than one bacterial cell was detected with nested PCR using the etz primers - an increase of 100-fold in sensitivity as compared with single-round PCR. In the presence of plant extract a reduction of tenfold in sensitivity was observed by nested PCR. When cells were grown on a semi-selective medium prior to PCR (Bio-PCR), five cells from pure culture of the pathogen were detected. The bacteria could be detected by nested-PCR or Bio-PCR in symptomless gypsophila cuttings after 7 days. The Bio-PCR procedure described in this study can be used to establish disease-free nuclear stock of mother plants of gypsophila.     

Molecular diagnostic procedures for production of pathogen-free propagation material

Production of disease-free propagation material is a major means of controlling most bacterial diseases of plants, particularly when neither resistant clones nor effective chemical treatments are available. For this purpose sensitive, specific and rapid detection methods are required. The advent of molecular biology and, in particular, the polymerase chain reaction (PCR) has opened new ways for the characterization and identification of plant pathogens and the development of disease-management strategies. PCR-based detection methods rely on the development of primers for the specific detection of the pathogen. The use of pathogenicity genes as targets for primer design is the preferred procedure for obtaining specific primers but other procedures may also be useful for this purpose. In the present review we describe four examples of procedures for detecting four important bacterial pathogens in Israel: Erwinia herbicola pv gypsophilae in gypsophila, Xanthomonas campestris pv pelargonii in geranium, Agrobacterium tumefaciens in asters and roses, and Xanthomonas campestris pv campestris in crucifers. Procedures for constructing specific PCR primers for each bacterium are illustrated and discussed as well as the combination of PCR with other methods.     

Pathogenicity and aggressiveness in populations of <Emphasis Type="Italic">Pseudomonas syringae</Emphasis> from Belgian fruit orchards

The pathogenicity of 99 Belgian Pseudomonas syringae strains representative of the genetic diversity encountered in Belgian fruit orchards was evaluated by using 17 pathogenicity tests conducted on pear, cherry, plum, lilac, sugar beet and wheat. The P. syringae pv. morsprunorum strains were pathogenic to stone fruit species but the race 1 strains possessing the cfl gene involved in coronatine production were pathogenic in more tests than those lacking the gene. Also, sweet cherry twigs were a better material to detect pathogenic strains of race 1 and sour cherry twigs of race 2, which accorded with race 2 presence in sour cherry orchards in Belgium. Three groups were defined in the pv. syringae based on pathogenicity. One group pathogenic in 71.1% of the tests and to lilac included toxic lipodesipeptide-producing (TLP+) strains. The second group pathogenic in 26.8% of the tests and non-pathogenic to lilac included TLP+ strains. The thirth group pathogenic in 9.1% of the tests and almost specifically pathogenic to pear included TLP− strains. The three groups were genetically heterogeneous. Although strain-host relationships were noted within the pv. syringae, aptata and atrofaciens when considering the strain origins, such relationships were not found in the pathogenicity tests, suggesting that pathogenicity tests could probably not reproduce all the aspects of the host-pathogen interactions. None of the pathogenicity tests was able to provide all the information provided by the complete study. A test on pear buds indicated that strains different from the pv. syringae were pathogenic to pear.     

The type III effector PthG of <Emphasis Type="Italic">Pantoea agglomerans</Emphasis> pv. <Emphasis Type="Italic">gypsophilae</Emphasis> modifies host plant responses to auxin,cytokinin and light

Pantoea agglomerans pvs. gypsophilae and betae are related gall-forming bacteria. While P. agglomerans pv. beta initiates gall formation on both beet and gypsophila, the gypsophila pathovar causes gall formation only on gypsophila. PthG is a type III effector determining host range of these pathogens, initiating the hypersensitivity response in beet, but is a virulence factor in gypsophila. The role of PthG and its mode of action in pathogenicity remain unclear. Transgenic Nicotiana tabacum plants expressing pthG were created. PthG over-expression was often lethal, and surviving pthG-bearing lines showed morphological and developmental abnormalities such as leaf deformation and abnormal vascular branching, dwarf stature, loss of apical dominance, seedling apical meristem loss, rapid germination, reduced fertility, plants which cease growth for several weeks later producing a new lateral shoot, and loss of endophyte resistance (bearing unusual saprophyte populations). Some transformants required light for seed germination and showed rapid seedling greening. In in vitro assays PthG expression modified responses to auxin and cytokinin, inhibiting root and shoot production but not callus formation. In vitro differentiation responses to light were modified by PthG expression. This effector may interfere in the plant auxin signalling pathways resulting in higher observed auxin and ethylene levels, and subsequent blockage of root and shoot development. Apparently PthG tunes the host response to high hormone levels, changing the developmental response. Since shoot and root development are delayed, we hypothesize that callus/gall formation is supported by this activity. However, interference by PthG with hormone and light signalling does not explain all the responses observed in pthG-bearing lines.     

Bacterial leaf blight of strawberry (Fragaria (x) ananassa) caused by a pathovar of Xanthomonas arboricola, not similar to Xanthomonas fragariae Kennedy & King. Description of the causal organism as Xanthomonas arboricola pv. fragariae (pv. nov., comb. nov.)

A new bacterial disease of strawberry is described. This disease, called bacterial leaf blight of strawberry, is characterized by dry, brown necrotic leaf spots and large brown V-shaped lesions along the leaf margin, midrib and major veins. Symptoms are different from angular leaf spot of strawberry caused by the bacterium Xanthomonas fragariae . Strains of the bacterial leaf blight pathogen were characterized in a polyphasic approach by biochemical tests, fatty acid analysis, protein electrophoresis, serology, PCR, pigment analysis, ice-nucleation activity, AFLP analysis, DNA:DNA hybridization, pathogenicity and host range tests, and compared with a number of reference strains of X. fragariae and other Xanthomonas species. Bacterial leaf blight strains formed a homogeneous group in all tests, completely different from X. fragariae . They were the only strains causing leaf blight of strawberry upon artificial inoculation into strawberry. Fatty acid and protein electrophoretic analysis showed that the strains belong to the phenon X. campestris ( sensu latu , including pathovars now classified as belonging to X. arboricola ). AFLP analysis and DNA:DNA hybridization further clarified their taxonomic position as belonging to X. arboricola. The name X. arboricola pv. fragariae is proposed for the bacterium causing leaf blight of strawberry with strain PD2780 (LMG 19145) as pathovar type strain. Criteria for routine identification are given and the taxonomic status is discussed.     

Description of the Bacterium Causing Blight of Leek as Pseudomonas syringae pv. porri (pv. nov.)

ABSTRACT Forty bacterial strains isolated from leek blight (Allium porrum) in France and other countries were studied by conventional biochemical methods, serological reactions, numerical taxonomy, DNA-DNA hybridization, and ice nucleation activity, as well as by pathogenicity on leek and other host plants. They were compared with reference strains of Pseudomonas, mainly pathotype strains of P. syringae pathovars and strains of P. syringae pv. syringae isolated from various host plants including onions. Leek strains sorted with P. syringae species (sensu lato) by LOPAT tests (production of levan-sucrase, oxidase, pectinase, arginine dihydrolase, and hypersensitive reaction on tobacco). Leek strains were pathogenic to leek and produced symptoms identical to those observed in the field. They were the only strains in our study that could cause blight of leek. Thus, our results justify the creation of a new pathovar. Leek strains constituted a highly homogeneous DNA group and a discrete phenon by numerical taxonomy, and they belonged to O-serogroup POR. The name of P. syringae pv. porri is proposed for the bacterium causing leek blight. Criteria for routine identification are presented and taxonomic status is discussed.     

Genetic diversity of Pseudomonas syringae pv. lachrymans strains isolated from cucumber leaves collected in Poland

Several strains of Pseudomonas syringae pathovar (pv.) lachrymans and related bacterial pathogens were isolated from cucumber ( Cucumis sativus ) leaves collected in central and southern Poland in 2001 and 2002. Twenty five original strains, together with five reference strains of P. syringae pv. lachrymans , pv. syringae and pv. tomato , were genetically characterized by PCR-RFLP (polymerase chain reaction − restriction fragment length polymorphism), ADSRRS (amplification of DNA fragments surrounding rare restriction sites), and PCR-MP (PCR − melting profiles) fingerprinting techniques. Genetic similarity analyses of the PCR-RFLP and ADSRRS fingerprints showed that strains of P. syringae pv. lachrymans form distinct clusters. The results also indicated that the ADSRRS and the PCR-MP fingerprinting techniques may serve as more efficient tools for evaluating genetic similarity among pathovars and strains of P. syringae than PCR-RFLP. The 25 strains showed diverse pathogenicity to cucumber seedlings and biochemical tests were varied. The syrB gene was identified in four cucumber strains, characterized as P. syringae pv. syringae .     

Pseudomonas syringae pv. avii (pv. nov.), the Causal Agent of Bacterial Canker of Wild Cherries (Prunus avium) in France

Bacterial strains isolated from cankers of wild cherry trees (Prunus avium) in France were characterized using numerical taxonomy of biochemical tests, DNA–DNA hybridization, repeat sequence primed-PCR (rep-PCR) based on REP, ERIC and BOX sequences, heteroduplex mobility assay (HMA) of internal transcribed spacer (ITS) as well as pathogenicity on wild cherry trees and other species of Prunus. They were compared to reference strains of Pseudomonas syringae pathovars isolated from wild and sweet cherry and various host plants. Wild cherry strains were closely related to P. syringae (sensu lato) in LOPAT group Ia (+ - - - +). Wild cherry strains were pathogenic to wild cherry trees and produced symptoms similar to those observed in orchards. They were pathogenic also, but at a lesser extent, to sweet cherry trees (cv. Napoléon). The wild cherry strains were collected from five different areas in France and appeared to constitute a very homogeneous group. They showed an homogenous profile of a biochemical and physiological characteristics. They were closely related by DNA–DNA hybridization and belonged to genomospecies 3 `tomato'. Rep-PCR showed that wild cherry strains constitute a tight group distinct from P. s. pv. morsprunorum races 1 and 2 and from other P. syringae pathovars. HMA profiles indicated that the ITS of all wild cherry strains were identical but different from P. s. pv. persicae strains since the two heteroduplex bands with reduced mobility were generated by hybridization with the P. s. pv. persicae pathotype strain CFBP 1573. The 8 genomospecies of Gardan et al. (1999) have not been converted into formal species as they cannot be differentiated by biochemical tests. Therefore, the pathovar system within P. syringae was currently used. P. syringae pv. avii is proposed for this bacterium causing a wild cherry bacterial canker and strain CFBP 3846 (NCPPB 4290, ICMP 14479) is designated as the pathotype.     

Characterization of phenotypically distinct strains of Xanthomonas axonopodis pv. citri from Southwest Asia

Strains of Xanthomonas axonopodis pv. citri were isolated from Mexican lime (Citrus aurantifolia) trees in several countries in southwest Asia. These strains produced typical erumpent bacterial canker lesions on Mexican lime but not on grapefruit (C. paradisi). Lesions on grapefruit were watersoaked and blister-like in contrast to the typical erumpent lesions seen after artificial inoculation with all described pathotypes of X. axonopodis pv. citri. This group of strains hydrolysed gelatin and casein and grew in the presence of 3% NaCl as is typical of X. axonopodis pv. citri pathotype A. RFLP analyses and DNA probe hybridization assays also gave results consistent with X. axonopodis pv. citri pathotype A. Metabolic fingerprints prepared with the Biolog® system showed similarities as well as differences to X. axonopodis pv. citri pathotype A. In spite of the physiological and genetic similarities to pathotype A of X. axonopodis pv. citri, these strains had no or very little affinity for polyclonal antiserum prepared against any of the reference strains of X. axonopodis pv. citri and also did not react with monoclonal antibody A1, an antibody that detects all strains of pathotype A of X. axonopodis pv. citri. These strains were also insensitive to bacteriophage Cp3 like X. axonopodis pv. citri pathotype A and unlike X. axonopodis pv. citri pathotype B. We conclude that these strains, designated Xcc-A*, represent a variant of X. axonopodis pv. citri pathotype-A with pathogenicity limited to C. aurantifolia. The existence of extensive genotypic and phenotypic variation within pathotype A of X. axonopodis pv. citri was unexpected and further complicates the systematics of this species.     

Consequences of the taxonomic revision of Xanthomonas axonopodis pv. dieffenbachiae and of the analysis of its associated pathogenicity for the recommendation of regulation (EPPO A2 List)

Xanthomonas axonopodis pv. dieffenbachiae, the causal agent of bacterial blight of Araceae (aroids), is a regulated pest in several countries and is included in the EPPO A2 List. Reference strains of Xanthomonas axonopodis pv. dieffenbachiae have recently been reclassified into the species Xanthomonas phaseoli, Xanthomonas citri and Xanthomonas euvesicatoria on the basis of different features, including multilocus sequence analysis, average nucleotide identity and homology in DNA–DNA hybridization analyses. Based on pathogenicity tests, Constantin et al. (2017) proposed naming the pathogens on aroids as X. phaseoli pv. dieffenbachiae, X. phaseoli pv. syngonii and X. citri pv. aracearum. Recommendations are made on how to deal with these changes for the group of pathogenic bacteria for Araceae. The name Xanthomonas axonopodis pv. dieffenbachiae on the EPPO List should be adjusted to the names proposed in the taxonomic study by Constantin et al. (2016). The current EPPO Diagnostic Standard is directed at strains pathogenic on Anthurium. They mainly belong to X. phaseoli pv. dieffenbachiae, but some also to X. citri pv. aracearum that are not detected by the EPPO Diagnostic Standard. Xanthomonas phaseoli pv. syngonii strains are also aggressive, but with a host range restricted to Syngonium. The pathogenicity specific to aroids of the bacterial isolates reclassified as Xanthomonas euvesicatoria was not confirmed and no pathovar epithet has been retained for these strains.     

Xanthomonas translucens from Small Grains: Diversity and Phytopathological Relevance

ABSTRACT Sixty-eight presumptive Xanthomonas translucens strains isolated from 15 small grains or grass species were studied by pathogenicity tests on barley, bread wheat, oat, and bromegrass species, and also by AFLP, analysis of fatty acid methyl esters (FAME), and sodium dodecyl sulfate-polyacrylamide gel electrophoresis of protein extracts. The X. translucens strains were divided into three pathogenicity types based on differences observed on barley and bread wheat. Two unspeciated strains producing atypical symptoms formed a fourth pathogenicity type. Pathogenicity on oat and bromegrass species varied within these types. Clusterings observed by AFLP analysis and, to a lesser extent, by FAME analysis were consistent with these pathogenicity groupings. The current results, as well as those of previous restriction fragment length polymorphism analyses of the same strains, support the recent reclassification of X. translucens pv. translucens and X. translucens pv. hordei as true synonyms. X. translucens pv. cerealis, X. translucens pv. translucens, and X. translucens pv. undulosa cluster in different groups by AFLP and FAME analyses. Even though distinction by simple biochemical tests is not clear-cut, the data indicate that the pathovars cerealis, translucens, and undulosa correspond to true biological entities.     

木薯细菌性萎蔫病菌的检疫方法研究

本文对木薯细菌性萎蔫病菌的致病性测定、细菌的分离、细菌的培养条件和培养基选择、细菌的生理生化测定、分子生物学鉴定方法等方面进行了系统研究，确定了该病菌的菌落鉴定特征，建立了从木薯繁殖材料上进行病原菌检测的快速、灵敏、准确的PCR检测方法。     

Scanning electron microscopy of the interactions betweenerwinia herbicola pv.gypsophilae andgypsophila paniculata

Ultrastructural studies of interactions betweenErwinia herbicola pv.gypsophilae and gypsophila plants showed that the bacterial pathogen multiplied rapidly and colonized gypsophila cuttings within 2 days. Fourteen days after inoculation, the plant tissue turned tumorigenic and a gall formed. Scanning electron microscopy showedE. gypsophilae cells densely occupying the plant xylem elements. Bacteria were found in association with fibrils which might be used by bacterial cells for attachment to plant cells. Substantial numbers of fibrils were also clearly seen on calli cell surfaces.     

Detection of Xylophilus ampelinus in grapevine cuttings using a nested polymerase chain reaction

A sensitive and specific assay was developed to detect bacterial blight of grapevine caused by Xylophilus ampelinus (Panagopoulos, 1969) comb. nov. in grapevine cuttings. The 16S−23S rDNA intergenic spacer region of X. ampelinus was sequenced and pathogen-specific primers were designed from a region in the spacer between the tRNA (Ala) and the 23S genes. A nested PCR (n-PCR) reaction was applied with a first-stage PCR using universal primers within the ends of the 16S and 23S genes, followed by a second-stage PCR with nested primers specific to the X. ampelinus spacer region. A 277-bp fragment was amplified from 38 Xylophilus strains tested, but not from saprophytes associated with grapevine or phylogenetically related phytobacteria. The 277-bp product was shown to be derived from the X. ampelinus spacer region by restriction with Dra I, Sau 3AI, Taq I and Msp I, Southern hybridization and genomic DNA dot blots. When the (n-PCR) procedure was applied in the absence of nontarget DNA, the limit of detection was less than 10 colony-forming units (CFU) per µ L. The same number of  X. ampelinus CFU could be detected in the presence of 1·5 × 10⁵ CFU  µ L⁻¹ of Erwinia herbicola cells using the n-PCR procedure.     

Phenotypic and Genetic Diversity in Strains of Common Blight Bacteria (Xanthomonas campestris pv. phaseoli and X. campestris pv. phaseoli var. fuscans) in a Secondary Center of Diversity of the Common Bean Host Suggests Multiple Introduction Events

ABSTRACT Common bacterial blight (CBB) disease of the common bean (Phaseolus vulgaris) is caused by Xanthomonas campestris pv. phaseoli and the brown-pigmented variant X. campestris pv. phaseoli var. fuscans. CBB first was described in Castilla y León County, Spain, in 1940, and is now a major constraint on common bean production. In this secondary center of diversity of the common bean, large-seeded Andean cultivars predominate, although medium-seeded Middle American cultivars also are grown. Xanthomonad-like bacteria associated with CBB in Castilla y León were characterized on the basis of carbohydrate metabolism, brown pigment production, genetic analyses (repetitive-element polymerase chain reaction [rep-PCR] and random amplified polymorphic DNA [RAPD]) and pathogenicity on cultivars representing the two common bean gene pools (Andean and Middle American). X. campestris pv. phaseoli was more prevalent (80%) than X. campestris pv. phaseoli var. fuscans (20%). Patterns of carbohydrate metabolism of Spanish CBB bacteria were similar to those of known strains; and only X. campestris pv. phaseoli var. fuscans strains utilized mannitol as a sole carbon source. rep-PCR and RAPD analyses revealed relatively little genetic diversity among Spanish X. campestris pv. phaseoli strains, and these strains were placed together with New World strains into a large cluster. Similar to other New World strains, representative Spanish X. campestris pv. phaseoli strains were highly pathogenic on bean cultivars of both gene pools, showing no gene pool specialization such as that found in certain East African strains. Genetic analyses and pathogenicity tests confirmed and extended previous results, indicating that these East African strains represent distinct xanthomonads that independently evolved to be pathogenic on common bean. X. campestris pv. phaseoli var. fuscans strains were more closely related and genetically distinct from X. campestris pv. phaseoli strains. However, two distinct clusters of X. campestris pv. phaseoli var. fuscans strains were identified, one having the most New World strains and the other having the most African strains. Spanish strains were placed in both clusters, but all strains tested were highly pathogenic on bean cultivars of both gene pools. Together, our results are consistent with multiple introductions of CBB bacteria into Spain. These findings are discussed in terms of breeding for CBB resistance and the overall understanding of the genetic diversity and evolution of CBB bacteria.     

Genetic Diversity of Xanthomonas campestris pv. vitians, the Causal Agent of Bacterial Leafspot of Lettuce

ABSTRACT Bacterial leafspot of lettuce (BLS), caused by Xanthomonas campes-tris pv. vitians, has become more prevalent in many lettuce-growing areas of the world over the past decade. To gain insight into the nature of these outbreaks, the genetic variation in X. campestris pv. vitians strains from different geographical locations was examined. All strains were first tested for pathogenicity on lettuce plants, and then genetic diversity was assessed using (i) gas-chromatographic analysis of bacterial fatty acids, (ii) polymerase chain reaction analysis of repetitive DNA sequences (rep-PCR), (iii) DNA sequence analysis of the internal transcribed spacer region 1 (ITS1) of the ribosomal RNA, (iv) restriction fragment length polymorphism (RFLP) analysis of total genomic DNA with a repetitive DNA probe, and (v) detection and partial characterization of plasmid DNA. Fatty acid analysis identified all pathogenic strains as X. campestris, but did not consistently identify all the strains as X. campestris pv. vitians. The rep-PCR fingerprints and ITS1 sequences of all pathogenic X. campestris pv. vitians strains examined were identical, and distinct from those of the other X. campestris pathovars. Thus, these characteristics did not reveal genetic diversity among X. campestris pv. vitians strains, but did allow for differentiation of X. campestris pathovars. Genetic diversity among X. campestris pv. vitians strains was revealed by RFLP analysis with a repetitive DNA probe and by characterization of plasmid DNA. This diversity was greatest among strains from different geographical regions, although diversity among strains from the same location also was detected. The results of this study suggest that these X. campestris pv. vitians strains are not clonal, but comprise a relatively homogeneous group.     

Infection of horse chestnut (Aesculus hippocastanum) by Pseudomonas syringae pv. aesculi and its detection by quantitative real-time PCR

Pseudomonas syringae pv. aesculi is a pathogenic bacterium causing bleeding canker disease of horse chestnut ( Aesculus hippocastanum ). This is a serious disease which has been affecting horse chestnut in several European countries over the last five years; however, very little is known about the biology of the causal agent. One of the obstacles to studying this pathogen is the lengthy procedure associated with confirming its presence on the host. In this study, P. syringae pv. aesculi was isolated from lesions on different parts of horse chestnut and its pathogenicity confirmed on horse chestnut saplings using two inoculation techniques. Real-time PCR primers were developed based on gyrase B gene sequence data for the specific detection of P. syringae pv. aesculi . Primer specificity was tested on isolates of the target pathogen as well as on a broad range of related non-target bacteria and other bacterial spp. which inhabit horse chestnut. The real-time primers reliably amplified P. syringae pv. aesculi down to 1 pg of extracted DNA, with and without the presence of host DNA, and also amplified unextracted DNA in whole cells of the bacterium down to at least 160 colony forming units. Detection and quantification of the target pathogen in phloem and xylem of both naturally infected and inoculated horse chestnut tissues was also demonstrated. This quantitative real-time PCR assay provides the facility to study several important aspects of the biology of P. syringae pv. aesculi on horse chestnut including its potential for dissemination in different substrates.     

含hrp基因的克隆片段在水稻白叶枯病菌不同小种中的功能和同源性

 将从水稻白叶枯病菌(Xanthomonas campestris pv.oryzae Dye,简称Xco)小种3菌株JXOⅢ中克隆的hrp基因片段(pNAX3103),用三亲交配法向病菌其它小种及其毒性基因突变体转移,结果表明pNAX3103可以进入其它小种,但对不同小种毒性基因突变体的转移能力则不同。功能互补分析表明;该hrp基因片段在不同小种中对病菌的生长,以及蛋白酶、果胶酶和纤维素酶的产生和分泌无明显影响;在野生型菌株中能增加亲本菌株对水稻品种IR26的致病力(JXO I)或亲和性(JXO V),对于毒性基因突变体,pNAX3103虽能进入JXO I经Tn5诱变的毒性基因突变体XcoM1107,但不能恢复其致病性和淀粉酶阴性反应。用hrp基因片段作为探针,对10个来源不同的小种或菌系群进行DNA同源性分析,结果与所有Xco菌株都有明显的同源性杂交带,但杂交带型不同,与甘蓝黑腐病菌、水稻细菌性条斑病菌、柑桔溃疡病菌、大白菜。软腐病菌的DNA有同源杂交带,但与水稻基腐病菌DNA无同源性。     

水稻白叶枯病菌毒性基因的克隆和功能分析

 通过DNA重组,用载体质粒pBR322和水稻白叶枯病菌(Xanthomonas campestris pv.oryzae Dye)毒性基因突变体XcoM3105带有转座子Tn5的毒性基因片段,构建了11.6kb的探针质粒pVIRl。用α-32P-dATP标记该探针,从构建在粘粒pSa747上的病菌野生型菌株JXO Ⅲ染色体基因文库中,通过菌落原位杂交和Southern杂交,筛选了8个毒性基因的克隆(pNAX3101~3108。将其中一个毒性基因克隆pNAX3103通过三亲交配接合法转移到XcoM3105中,接合频率为2.06×10^-7。功能互补分析表明,pNAX3103可以互补突变体XcoM3105,恢复致病性,同时也能互补其淀粉酶(Amy)活性表型,由原来的淀粉酶阳性恢复为阴性反应。因此可以认为,被克隆的毒性基因片段具有完整的致病功能,毒性基因与淀粉酶基因之间可能存在着某种负调控关系。