福建省柑橘褐斑病菌的分离、鉴定和系统进化分析

为明确在福建省南平市的橘柚和三明市的温州蜜橘上发现的疑似柑橘褐斑病的病原菌种类,采用组织分离法获得纯化菌株,通过回接法验证菌株的致病性,利用形态学特征对病原菌进行初步鉴定,并采用最大似然法以多聚半乳糖醛酸酶基因endoPG为靶标对本研究以及国内外已报道的链格孢菌株构建系统发育树,分析其遗传多样性。结果表明,从病组织中共分离获得26株纯培养菌株,经形态学鉴定均为链格孢菌Alternaria spp.。利用分生孢子液接种橘柚离体嫩叶发现,有22株菌株能侵染橘柚叶片并产生与田间相似的褐斑病症状,确认该病害为链格孢引起的柑橘褐斑病。系统发育树分析结果显示,分离所得的26株菌株均聚在已报道的4个柑橘链格孢进化分支Clade1～Clade4中,其中21株菌株聚在国内特有的分支Clade4中,有3株菌株和1株菌株分别聚在国内外兼有的分支Clade3和Clade1中,1株菌株聚在国外特有的分支Clade2中,表明在福建省采集的这些柑橘褐斑病菌均为链格孢菌,且遗传多样性较丰富。     

Polygalacturonase-inhibiting protein (PGIP) from Japanese pear: possible involvement in resistance against scab

Venturia nashicola is the causal agent of scab, a fungal disease affecting Asian pears. The Japanese pear cv. ‘Kousui’ is highly susceptible to the race 1 of this fungus whereas the cv. ‘Kinchaku’ and the non-host European pear cv. ‘Flemish Beauty’ are resistant. The aim of this work is to investigate the role of polygalacturonase-inhibiting proteins (PGIPs) of pear during the interactions with V. nashicola leading to susceptibility or resistance. PGIP protein was detected from immature fruit of Kousui and Kinchaku. It showed a molecular mass of 42 kDa that shifted to 35 kDa after chemical deglycosylation. The gene pgip was amplified by PCR using genomic DNA and/or cDNA from young leaves of Kousui, Kinchaku, and European pear cvs. Flemish Beauty, ‘Bartlett’, and an Asian wild pear strain ‘Mamenashi 12’, then sequenced after sub-cloning. Some conserved variations were identified in the sequence indicating that gene family also exists in pgip of Japanese pear and confirmed by Southern blot analysis. The expression of PGIP was studied in scab-inoculated leaves of the susceptible Kousui and the resistant Kinchaku and Flemish Beauty. pgip Gene and its encoding protein were highly and rapidly activated in these resistant plants. In addition, PGIP extracts derived from Kinchaku and Flemish Beauty partially inhibited the activity of polygalacturonase (PG) from V. nashicola suggesting a possible role of PGIP in limiting fungal growth frequently observed in these resistant cultivars.     

Gel detection of Allium porrum polygalacturonase-inhibiting protein reveals a high number of isoforms

Polygalacturonase inhibiting proteins (PGIPs) are leucine-rich repeat glycoproteins, localized in the cell wall of most plant species, capable of countering the activity of endo-polygalacturonases (endo-PGs) produced by phytopathogenic fungi. The PGIP from Allium porrum leaves was analysed to ascertain the presence of different molecular forms of PGIP. Leek PGIP was separated into two fractions: a soluble and an ionically wall-bound PGIP, each of which was then purified by cation-exchange chromatography. Two and three peaks of PGIP activity were obtained, respectively. PGIP isoforms contained in each peak were separated by isoelectrofocusing (IEF) on a polyacrylamide gel. Following the separation, the gel was first overlaid with sodium polygalacturonate and then treated with the endo-PG from either Sclerotinia sclerotiorum, Fusarium moniliforme or Botrytis aclada. The endo-PG(s) hydrolyse the overlaid substrate except where active inhibitors are present. The presence of PGIPs is revealed by ruthenium red staining of the nonhydrolysed substrate. Each PGIP peak following IEF separation revealed several PGIP isoforms with pIs between 5.0 and 7.0. More than 20 isoforms were detected in total, with considerable differences in their inhibitory activity. While similar PGIP isoform patterns were obtained by developing the IEF gels with the endo-PGs of S. sclerotiorum and B. aclada, less intense PGIP bands were observed with the endo-PG from B. aclada, consistent with inhibition assays performed in solution. The endo-PG from F. moniliforme, which is not inhibited at all by leek PGIP in solution, consistently showed no PGIP band on the gel assay.     

Involvement of carbon catabolite repression on regulation of endopolygalacturonase gene expression in citrus fruit

 The Acpg1 gene of Alternaria citri encodes an extracellular endopolygalacturonase that is important for virulence in citrus fruits. Expression of Acpg1 is regulated by substrate induction and carbon catabolite repression. A green fluorescent protein (GFP) gene was employed as a reporter gene to define 813 bases upstream of the translation start site comprising the Acpg1 promoter. This upstream sequence contains five putative binding sequences of catabolite repressive element A (CreA), a cis-acting zinc finger repressor involved in carbon catabolite repression. We constructed each CreA-binding site-deleted Acpg1 promoters with GFP reporter gene and transformed them to A. citri. The construct PGPDL4 deleted from −401 to −813 showed both substrate induction and catabolite repression, whereas PGPDL5 additionally deleted from −1 to −84, including one putative CreA-binding site, resulted in a loss of catabolite repression function. Green fluorescence of PGPDL4 was induced by pectin in the peel but was repressed completely in the juice sac area of citrus fruit. However, green fluorescence of PGPDL5 was induced in both the peel and juice sac area, indicating that repression of Acpg1 in the juice sac area is likely accomplished by carbon catabolite repression. Received: October 4, 2002 / Accepted: October 31, 2002 Acknowledgments The authors thank Drs. D. Cullen, A. Van den Wymelenberg, and J. Andrews, University of Wisconsin, for providing pTEFEGFP containing GFP and Dr. T. Tsuge, Nagoya University, for providing transformation vector pSH75. The nucleotide sequence data of Acpg1 promoter region in the DDBJ, EMBL, and GenBank sequence databases is under accession number AB047543. This research was supported in part by grants to K.A. from the Ministry of Education, Culture, Sports, Science, and Technology of Japan.     

Study of Defense-related Gene Expression in Grapevine Leaves and Berries Infected with Botrytis cinerea

Defense responses of grapevine towards Botrytis cinerea were investigated. The expression of genes coding for proteins involved in defense were studied: (a) phenylalanine ammonia-lyase (PAL) and stilbene synthase (StSy), (b) an acidic chitinase (VCH3) and a basic chitinase (VCHIT1b), and (c) a polygalacturonase inhibitor protein (PGIP). Since no PGIP was known in grapevine, a complete cDNA sequence was first characterized by PCR and RACE-PCR amplifications. RNAs isolated from infected leaves and infected berries were analysed by semi-quantitative and real-time RT-PCRs. In infected leaves, the expression of PAL, StSy, PGIP and VCH3 genes occurred 6hours post inoculation (hpi). Increase of VCHIT1b gene expression was delayed (24hpi). Maximum levels of induction of these genes were observed at 48hpi, except for the VCH3 gene (24hpi). Activation of these defense responses was not sufficient to stop B. cinerea spread. In berries, no VCH3 gene expression was detected. Maximum levels of induction were observed in stage 3 (loss of berry colour and abundant production of conidia) for the PAL and PGIP genes, and in stage 4 (shrivelled berry) for the StSy and VCHIT1b genes.     

Green Fluorescent Detection of Fungal Colonization and Endopolygalacturonase Gene Expression in the Interaction of Alternaria citri with Citrus

ABSTRACT Alternaria citri, a postharvest pathogen, produces endopolygalacturonase (endoPG) and causes black rot on citrus fruit. We previously described that an endoPG-disrupted mutant of Alternaria citri was significantly reduced in its ability to macerate plant tissue and cause black rot symptoms on citrus. In order to investigate colonization of citrus fruit tissues by Alternaria citri, pTEFEGFP carrying a green fluorescent protein (GFP) gene was introduced into wild-type Alternaria citri and its endoPG-disrupted mutant (M60). Green fluorescence was observed in spores, germ tubes, appressoria, and infection hyphae of transformants G1 (derived from wild type) and GM4 (derived from M60). Hyphae of G1 but not GM4 vertically penetrated the peel, but the hyphae of both G1 and GM4 spread equally in the juice sac area of citrus fruit. Green fluorescence of Alternaria citri transformant EPG7 carrying a GFP gene under control of the endoPG gene promoter of Alternaria citri was induced by pectin in the peel during the infection stage, but repressed completely in the juice sac area, likely by carbon catabolite repression by sugars in the juice.     

Polygalacturonase inhibiting proteins fromAllium porrumL. and their role in plant tissue against fungal endo-polygalacturonases

Five endo-polygalacturonases (PGs), three produced in culture filtrate byFusarium moniliforme, Sclerotium cepivorumandBotrytis aclada,respectively, and two (one acidic and one basic isoform) obtained fromSclerotinia sclerotiorumsoybean infected hypocotyls, were purified in order to characterize the activity of polygalacturonase inhibitor(s) (PGIP(s)) from leek stalk tissue (Allium porrumL.). Three apparently different PGIPs (PGIP-I, PGIP-II and PGIP-III) were purified from the leek tissue. The two more abundant PGIPs (PGIP-I and PGIP-III), although possessing similar pIs of about 6.5, differed in chromatographic behaviour, their molecular mass (39 and 42 kDa, respectively), and specific activity when assayed with the fungal endo-PGs. In addition, PGIP-I was solubilized from tissue homogenate with a low-salt buffer whilst PGIP-III needed a high-salt buffer for extraction (behaving as an ionically wall-bound protein). PGIP-II had very similar properties to PGIP-I, but was extracted using the high-salt buffer. The purified PGIPs and the crude leek extract showed similar inhibition activity patterns against the five fungal endo-PGs. The maximum inhibition activity was observed against the basic endo-PG fromS. sclerotiorum,followed by the acidic endo-PG ofS. sclerotiorumand the endo-PG fromB. aclada.In contrast, no inhibition of endo-PGs fromS. cepivorumandF. moniliformewas observed. Four different concentrations of the five fungal endo-PGs were incubated separately with slices of leek stalk, and the galacturonides released in the incubation mixture were measured. At every level used the endo-PGs ofF. moniliformeandS. cepivorumshowed the maximum activity in uronide releasing. The endo-PGs ofS. sclerotiorum(acidic PG) andB. acladawere active only when high levels were used while the basic endo-PG ofS. sclerotiorumwas not active in combustion with any level of PGIP. These results indicate that a close relationship exists between PGIP activityin vitroand the ability of PGIP to protect leek tissue from endo-PG degradation.     

Overexpression of a Gene Encoding a Catabolite Repression Element in Alternaria citri Causes Severe Symptoms of Black Rot in Citrus Fruit

ABSTRACT A gene (AcCreA) encoding a catabolite repression element (CreA) with (two zinc fingers of the Cys(2)His(2) type was isolated from the postharvest fungal pathogen Alternaria citri. The AcCreA overexpression mutant AcOEC2 of A. citri showed normal growth on pectin medium and on segments of peel or the juice sac area from citrus fruit. Production of endopolygalacturonase, an essential virulence factor of this pathogen, was similar in AcOEC2 and the wild type in pectin-containing media. However, addition of glucose to the medium showed that carbon catabolite repression of endopolygalacturonase gene (Acpg1) expression, as well as endopolygalacturonase production, was lost in AcOEC2. The wild-type strain of A. citri causes rot mainly in the central axis of citrus fruit without development of rotting in the juice sac area; however, AcOEC2 caused severe black rot symptoms in both the central axis and juice sac areas. These results indicate that AcCreA-mediated catabolite repression controls the virulence or infection of this pathogen, and that the wild-type A. citri does not cause symptoms in the juice sac area due to carbon catabolite repression by sugars in the juice of the juice sac area.     

Lack of host specificity of Colletotrichum spp. isolates associated with anthracnose symptoms on mango in Brazil

The aim of the present study was to analyse the genetic and pathogenic variability of Colletotrichum spp. isolates from various organs and cultivars of mango with anthracnose symptoms, collected from different municipalities of São Paulo State, Brazil. Colletotrichum gloeosporioides isolates from symptomless citrus leaves and C. acutatum isolates from citrus flowers with post‐bloom fruit drop symptoms were included as controls. Sequencing of the ITS region allowed the identification of 183 C. gloeosporioides isolates from mango; only one isolate was identified as C. acutatum. amova analysis of ITS sequences showed larger genetic variability among isolates from the same municipality than among those from different populations. fAFLP markers indicated high levels of genetic variability among the C. gloeosporioides isolates from mango and no correlation between genetic variability and isolate source. Only one C. gloeosporioides mango isolate had the same genotype as the C. gloeosporioides isolates from citrus leaves, as determined by ITS sequencing and fAFLP analysis. Pathogenicity tests revealed that C. gloeosporioides and C. acutatum isolates from either mango or citrus can cause anthracnose symptoms on leaves of mango cvs Palmer and Tommy Atkins and blossom blight symptoms in citrus flowers. These outcomes indicate a lack of host specificity of the Colletotrichum species and suggest the possibility of host migration.     

A Virulence-Reducing Mutation in the Postharvest Citrus Pathogen Alternaria citri

ABSTRACT Alternaria citri causes Alternaria black rot, a postharvest fruit disease, on a broad range of citrus cultivars. We previously described that an endopolygalacturonase minus mutant of A. citri caused significantly less black rot in citrus fruit. To search for other essential factors causing symptoms in addition to endopolygalacturonase, a random mutation analysis of pathogenicity was performed using restriction enzyme-mediated integration. Three isolates among 1,694 transformants of A. citri had a loss in pathogenicity in a citrus peel assay, and one of these three mutants was a histidine auxotroph. Gene AcIGPD that encodes imidazole glycerol phosphate dehydratase, the sixth enzyme in the histidine biosynthetic pathway, was cloned, and the mutant containing the disrupted target gene, AcIGPD, caused less black rot.     

A functional XopAG homologue in Xanthomonas fuscans pv. aurantifolii strain C limits host range

Citrus canker is caused by two Xanthomonas species, Xanthomonas citri, which has become the primary pathogen where citrus canker occurs (type A citrus canker, Xc‐A), and X. fuscans pv. aurantifolii (Xfa), which consists of strains B and C. The B strain is less pathogenic than the A strain, but produces symptoms in all citrus species. The C‐type cankers only infect Key lime (Citrus aurantifolia) and produce a hypersensitive reaction (HR) in grapefruit (Citrus paradisi) leaves. An avirulence gene, avrGf2, was identified in a C strain that was responsible for the HR in grapefruit. AvrGf2 is a member of XopAG effector family and shares 45% identity at amino acid level with another member of the same family, AvrGf1 from strain Xc‐A^w, which was previously shown to elicit an HR in grapefruit. AvrGf2 shares sequence identity with other XopAG effectors present in Xanthomonas vasculorum, Xanthomonas campestris pv. musacearum and Pseudomonas syringae pv. tomato. Mutagenesis of avrGf2 in C strain resulted in a compatible reaction in grapefruit. There was no observable effect on virulence when Xc‐A transconjugants containing either avirulence gene were inoculated on Key lime. Expression of avrGf1 or avrGf2 in Xc‐A resulted in a similar phenotype following infiltration into grapefruit leaves, although the avrGf2 transconjugant elicited a faster HR and lower populations than the transconjugant containing avrGf1. Also, it was shown that all Xfa‐B strains tested contain a transposon in avrGf2 that helps to explain the differences in host range between B and C strains.     

Polygalacturonase-inhibiting protein activity in cantaloupe fruit as a function of fruit maturation and tissue origin

Netted cantaloupe (Cucumis melo var. cantalupensis cv. Magnum 45) were harvested from 5 to 35 days postanthesis. The fruit of each age group were divided into exocarp, outer mesocarp, mid mesocarp, inner mesocarp, placenta, and seed. Each tissue was extracted and assayed for polygalacturonase-inhibiting protein (PGIP) activity against polygalacturonases (PGs) from three fungal pathogens of cantaloupe fruit. The PGIP activity of all tissues except placenta was high from the flower stage through the first week of fruit development but decreased markedly between 5 and 10 days postanthesis. PGIP activity against Phomopsis cucurbitae PG remained high and nearly constant in placental tissue throughout fruit development. However in this same tissue, PGIP activity against Fusarium solani PG decreased during fruit development to about 25% of its level in the 5-day-old fruit. This differential change in PGIP activity toward the two PGs suggests that different forms of the inhibitor are expressed between early and late stages of cantaloupe fruit development. The results also illustrate the importance of using multiple pathogen enzyme systems that can provide an opportunity for more accurate elucidation of mechanisms involved in the host–pathogen interaction. Mention of trade names or commercial products in this article is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the US Department of Agriculture. All programs and services of the US Department of Agriculture are offered on a nondiscriminatory basis without regard to race, color, national origin, religion, sex, age, marital status, or handicap. The article cited was prepared by a USDA employee as part of his/her official duties. Copyright protection under US copyright law is not available for such works. Accordingly, there is no copyright to transfer. The fact that the private publication in which the article appears is itself copyrighted does not affect the material of the US Government, which can be freely reproduced by the public.     

Bacteria from the citrus phylloplane can disrupt cell–cell signalling in Xanthomonas citri and reduce citrus canker disease severity

Xanthomonas citri subsp. citri (Xcc) is the causal agent of citrus canker, a disease that affects almost all types of citrus crops. Production of particular Xcc pathogenicity factors is controlled by a gene cluster rpf, which encodes elements of a cell–cell communication system called quorum sensing (QS), mediated by molecules of the diffusible signal factor (DSF) family. Interference with cell–cell signalling, also termed quorum quenching, either by signal degradation or over‐production, has been suggested as a strategy to control bacterial disease. In this study, three bacterial strains were isolated from citrus leaves that displayed the ability to disrupt QS signalling in Xcc. Pathogenicity assays in sweet orange (Citrus sinensis) showed that bacteria of the genera Pseudomonas and Bacillus also have a strong ability to reduce the severity of citrus canker disease. These effects were associated with alteration in bacterial attachment and biofilm formation, factors that are known to contribute to Xcc virulence. These quorum‐quenching bacteria may represent a highly valuable tool in the process of biological control and offer an alternative to the traditional copper treatment currently used to treat citrus canker disease.