Molecular and phenotypic analyses reveal association of diverse Colletotrichum acutatum groups and a low level of C. gloeosporioides with olive anthracnose

Anthracnose (Colletotrichum spp.) is an important disease causing major yield losses and poor oil quality in olives. The objectives were to determine the diversity and distribution pattern of Colletotrichum spp. populations prevalent in olives and their relatedness to anthracnose pathogens in other hosts, assess their pathogenic variability and host preference, and develop diagnostic tools. A total of 128 Colletotrichum spp. isolates representing all olive-growing areas in Portugal and a few isolates from other countries were characterized by molecular and phenotypic assays and compared with reference isolates. Arbitrarily primed PCR data, internal transcribed spacer of rRNA gene and beta-tubulin 2 nucleotide sequences, colony characteristics, and benomyl sensitivity showed Colletotrichum acutatum to be dominant (>97%) with limited occurrence of Colletotrichum gloeosporioides (<3%). Among C. acutatum populations, five molecular groups, A2 to A6, were identified. A2 was widely prevalent (89%), coinciding with a high incidence of anthracnose and environmental conditions suitable to disease spread. A4 was dominant in a particular region, while other C. acutatum groups and C. gloeosporioides were sporadic in their occurrence, mostly related to marginal areas of olive cultivation. C. gloeosporioides, isolated from olive fruits with symptoms indistinguishable from those of C. acutatum, showed same virulence rating as the most virulent C. acutatum isolate from group A2. C. acutatum and C. gloeosporioides isolates tested in infected strawberry fruits and strawberry and lupin plants revealed their cross-infection potential. Diagnostic tools were developed from beta-tubulin 2 sequences to enable rapid and reliable pathogen detection and differentiation of C. acutatum groups.     

Diagnosis of Clinical Bovine Mastitis by Fine Needle Aspiration Followed by Staining and Scanning Electron Microscopy in a Prototheca zopfii Outbreak

Fruit anthracnose of ugurassa caused by Colletotrichum acutatum is hereby reported for the first time in Sri Lanka and it is proposed that C. acutatum is considered together with C. gloeosporioides, as a causal agent of this disease. C. acutatum was characterised by fusiform conidia and white to orange colonies with slight shades of light mouse grey aerial mycelia. C. gloeosporioides produced grey colonies with a dark mouse grey centre and conidia were cylindrical. The other differences between the ugurassa isolate of C. acutatum and C. gloeosporioides were slower growth at temperatures ranging from 15-30 degrees C and extremely high tolerance of two fungicides, carbendazim and thiophanate methyl.     

Genotypic and phenotypic diversity in Colletotrichum acutatum, a cosmopolitan pathogen causing anthracnose on a wide range of hosts

Colletotrichum acutatum causes anthracnose on a wide range of hosts including woody and herbaceous crops, ornamentals, fruits and conifers. Almond, citrus, lupin, olive and strawberry are some of the crops in which C. acutatum diseases are economically important. With the application of molecular markers and diagnostic PCR over the last 10–15 years, C. acutatum was identified as a major pathogen on a number of hosts instead of or along with C. gloeosporioides . C. acutatum displays high levels of genotypic and phenotypic diversity. The global populations of this cosmopolitan pathogen fit into at least eight distinct molecular groups, A1–A8, which show some degree of correlation with the morphological characteristics and varying patterns of host association and geographical distribution. The pathogen has complex epidemiology, exhibiting pathogenic and non-pathogenic lifestyles on target hosts, non-target crops and weeds. C. acutatum populations also show pathogenic variability and cross-infection potential in relation to a number of hosts. Molecular genetic tools are being developed to investigate the pathogenicity mechanisms of this key pathogen. This article mainly focuses on the global population diversity in C. acutatum , pathogen epidemiology and diagnosis, host colonization processes, and the development of tools for the identification and analysis of genes associated with pathogenicity. Background information on the pathogen origin, host range, disease symptoms and disease management strategies is also provided.     

中国柱花草炭疽病原菌遗传多态性的RAPD分析

在对中国柱花草炭疽病进行广泛调查和病原采样收集的基础上,利用RAPD分子标记技术对43个代表性菌株进行了基因组DNA分析,并与276份国外菌株进行了综合聚类分析。 结果表明所用8个引物的扩增片段位于0.3～2.8kb之间, 菌株间呈现显著的DNA多态性。以柱花草起源中心——南美的柱花草炭疽菌分类为基础,中国柱花草炭疽菌可划分成3大类型即Ⅱ、Ⅲ、Ⅵ类。中国菌株与来自柱花草起源中心——南美的菌株相比之下,其生物多样性和遗传变异性则相对简单。就中国菌株而言海南菌株与广西、广东菌株相比多样性较丰富, 中国柱花草胶孢炭疽菌正在出现种内遗传分化。 从聚类结果看,通常来自于同一个地理区域或同一个寄主基因型的菌株聚成一类, 即同一RAPD聚类组内的菌株通常来自于同一寄主基因型或同一地理区域。说明来自不同寄主基因型或物种的炭疽菌在遗传基因上具有专化性,而地理上隔离的国家或地区的柱花草炭疽病原菌各自具有相对独立的进化途径。     

广东省柑橘炭疽病病原菌的形态与分子鉴定

炭疽病是柑橘的主要真菌性病害之一。2007年春,广东省德庆县名优柑橘品种贡柑炭疽病暴发流行。为了明确该县及广东省其他地区柑橘炭疽病菌的种类,为防治提供依据,对采集自广东省6个地区柑橘属10个栽培品种上的炭疽病样本进行病原菌分离,共获得柑橘炭疽病菌单孢菌株75株,对其中10株代表性的菌株进行了种类鉴定。通过培养性状和形态学特征观测、核糖体DNA(rDNA)内转录间区(ITS)序列分析、ITS区特异性引物PCR检测和系统发育关系比较等方面的研究,结果表明:10个柑橘炭疽病菌菌株均为盘长孢状刺盘孢Colletotrichum gloeosporioides,未发现国际上其他国家报道的严重危害柑橘花器和幼果部位的柑橘花后落果病病原菌——尖刺盘孢C.acutatum。     

Colletotrichum acutatum var. fioriniae (teleomorph: Glomerella acutata var. fioriniae var. nov.) infection of a scale insect

An epizootic has been reported in Fiorinia externa populations in New York, Connecticut, Pennsylvania and NewJersey. Infected insects have profuse sclerotial masses enclosing their bodies. The most commonly isolated microorganism from infected F. externa was Colletotrichum sp. A morphological and molecular characterization of this fungus indicated that it is closely related to phytopathogenic C. acutatum isolates. Isolates of Colletotrichum sp. from F. externa in areas of the epizootic were similar genetically and were named Colletotrichum acutatum var. fioriniae var. nov, based on our findings. In vitro and in planta mating observed between isolates of C. acutatum var. fioriniae could serve as a possible source of genetic variation and might give rise to new biotypes with a propensity to infect insects. Only one other strain, C. gloeosporioides f. sp. ortheziidae, has been reported to show entomopathogenic activity.     

Contribution to the study of the chemical composition of Verticillium albo-atrum secretions in liquid media

Slower growth at temperatures ranging from 15 to 32.5 °C and high tolerance of three fungicides, benomyl, carbendazim and thio- phanate methyl, were shown to be reliable characteristics in distinguishing rubber isolates of Colletotrichum acutatum from Colletotrichum gloeosporioides in addition to the characteristics reported previously. This revised version was published online in June 2006 with corrections to the Cover Date.     

Molecular and Phenotypic Analyses Reveal Association of Diverse Colletotrichum acutatum Groups and a Low Level of C. gloeosporioides with Olive Anthracnose

Anthracnose (Colletotrichum spp.) is an important disease causing major yield losses and poor oil quality in olives. The objectives were to determine the diversity and distribution pattern of Colletotrichum spp. populations prevalent in olives and their relatedness to anthracnose pathogens in other hosts, assess their pathogenic variability and host preference, and develop diagnostic tools. A total of 128 Colletotrichum spp. isolates representing all olive-growing areas in Portugal and a few isolates from other countries were characterized by molecular and phenotypic assays and compared with reference isolates. Arbitrarily primed PCR data, internal transcribed spacer of rRNA gene and β-tubulin 2 nucleotide sequences, colony characteristics, and benomyl sensitivity showed Colletotrichum acutatum to be dominant (>97%) with limited occurrence of Colletotrichum gloeosporioides (<3%). Among C. acutatum populations, five molecular groups, A2 to A6, were identified. A2 was widely prevalent (89%), coinciding with a high incidence of anthracnose and environmental conditions suitable to disease spread. A4 was dominant in a particular region, while other C. acutatum groups and C. gloeosporioides were sporadic in their occurrence, mostly related to marginal areas of olive cultivation. C. gloeosporioides, isolated from olive fruits with symptoms indistinguishable from those of C. acutatum, showed same virulence rating as the most virulent C. acutatum isolate from group A2. C. acutatum and C. gloeosporioides isolates tested in infected strawberry fruits and strawberry and lupin plants revealed their cross-infection potential. Diagnostic tools were developed from β-tubulin 2 sequences to enable rapid and reliable pathogen detection and differentiation of C. acutatum groups.     

Characterization of the membrane sensor PenJ for β-lactam antibodies from Bacillus licheniformis by amino acid substitution

Abstract The beta scanner and pattern matching software integrated in the automated microbiology identification system (AMBIS) were used to assess the relatedness of isolates of Colletotrichum acutatum, C. kahawae, C. fragariae, C. gloeosporioides and C. musae based on mitochondrial DNA restriction fragment length polymorphisms. The dendrograms generated reflected the intra-specific variation and inter-specific relationships of these species as determined by other previously reported methods. The adaptability of AMBIS as a rapid method for assessing genetic relatedness of fungal species based on DNA polymorphisms is discussed.     

Differentiation of lineages within “Colletotrichum gloeosporioides s.l.” associated with cassava anthracnose disease by BOX‐ and ERIC‐PCRs

Several molecular techniques have been used to differentiate species or genetic lineages of microorganisms prior to sequencing. Among them, BOX‐ and ERIC‐PCRs may provide specific banding patterns for different species, allowing its differentiation. Therefore, the objective of this study was to evaluate these techniques as a tool for differentiation of phylogenetic lineages belonging to the Colletotrichum gloeosporioides species complex associated with cassava anthracnose disease. Sets of BOX‐ and ERIC‐PCR primers were used to assess the differentiation of lineages belonging to the complex with 81 C. gloeosporioides sensu lato (s.l.) isolates from different cassava producing regions. Some were identified by sequencing, such as Colletotrichum fructicola, Colletotrichum tropicale, C. gloeosporioides s.s, Colletotrichum theobromicola, Colletotrichum siamense, Colletotrichum brevisporum and Colletotrichum sichuanensis. The primers were able to amplify DNA fragments from all isolates. The ERIC‐PCR presented a wider range of banding patterns in comparison to BOX‐PCR, providing better differentiation of the individuals, as well as a higher correlation with the phylogenetic data was obtained by ERIC‐PCR and the combined data set for “BOX‐/ERIC‐PCRs,” inferred by Mantel test. However, the use of concatenated data (BOX‐/ERIC‐PCRs) reduced the discriminatory capacity presented by ERIC‐PCR alone, probably due to the lowest resolution of BOX‐PCR. Therefore, ERIC‐PCR technique enabled efficient differentiation of isolates belonging to the C. gloeosporioides complex and can be used to analyse multiple isolates in a collection and also being an important tool as a guide in the decision‐making process prior to sequencing. Based on this methodology, it was possible to identify two new species associated with cassava anthracnose disease, C. brevisporum and C. sichuanensis, being the first report of these two species associated with cassava anthracnose disease in Brazil.     

香蕉炭疽菌菌株亲缘关系的RAPD分析

应用筛选的8个Operon随机引物对供试菌株的DNA进行扩增,所产生的RAPD图谱揭示了香蕉炭疽菌具有丰富的种内遗传多样性。UPGMA聚类分析的结果表明：26个香蕉炭疽菌被分为两个与地理来源相关的RAPD聚类群,它们分别由广东菌株和海南菌株为主组成。在两个香蕉菌群的外侧,两个胶胞炭疽菌菌株聚为一个小的外群。这些结果表明香蕉炭疽菌存在有与地域相关的种下类群分化。     

香蕉炭疽菌菌株亲缘关系的RAPD分析*

应用筛选的8个Operon随机引物对供试菌株的DNA进行扩增,所产生的RAPD图谱揭示了香蕉炭疽菌具有丰富的种内遗传多样性。UPGMA聚类分析的结果表明：26个香蕉炭疽菌被分为两个与地理来源相关的RAPD聚类群,它们分别由广东菌株和海南菌株为主组成。在两个香蕉菌群的外侧,两个胶胞炭疽菌菌株聚为一个小的外群。这些结果表明香蕉炭疽菌存在有与地域相关的种下类群分化。     

Vegetative Compatibility Grouping of Colletotrichum kahawae in Kenya

Vegetative compatibility using nitrate nonutilizing ( nit ) mutants was analysed between 44 isolates of Colletotrichum kahawae from Kenya, one each from Ethiopia and Malawi, one of Colletotrichum gloeosporioides and one of Colletotrichum acutatum . Another isolate of C. kahawae did not generate mutants and thus could not be utilized. The results showed that all the C. kahawae isolates, except a white sector mutant (VCG2), belonged to one vegetative compatibility group (VCG4). The other species belonged to their own unique groups (VCGs 1 and 3). Implications of the results and future research needs on the subject are discussed.     

Association of Dominant and Recessive Genes Confers Anthracnose Resistance in Stem and Leaves of Common Bean

Different genes might be involved in Colletotrichum lindemuthianum resistance in leaves and stem of common bean. This work aimed to study the genetic mechanisms of the resistance in the leaf and stem in segregating populations from backcrosses involving resistant cultivar AN 910408 and susceptible cultivar Rudá inoculated with spore suspensions of C. lindemuthianum race 83. Our results indicate that two genes which interact epistatically, one dominant and one recessive, are involved in the genetic control of leaf anthracnose resistance. As for stem anthracnose resistance, two genes also epistatic, one dominant and one recessive, explain the resistance to C. lindemuthianum race 83. The recessive gene is the same for leaf and stem resistance; however, the dominant genes are distinct and independent from each other. The three independent resistance genes of AN 910408 observed in this work could be derived from Guanajuato 31.     

Heteroduplex Mobility Assay for Identification and Phylogenetic Analysis of Anthracnose Fungi

Colletotrichum spp . are casual agents of anthracnose on various economically important crops. To cope with the pitfalls of identifying the fungi by morphotaxonomic criteria, the application of heteroduplex mobility assay (HMA) of internal transcribed spacer (ITS) regions as a biochemical tool was explored. The ITS regions of 29 Colletotrichum isolates including Colletotrichum gloeosporioides , Colletotrichum acutatum , Colletotrichum musae , Colletotrichum graminicola , Colletotrichum capsici , Colletotrichum dematium , Colletotrichum lindemuthianum and three unidentified species of Colletotrichum , were PCR amplified. Comparison of the ITS sequences from 15 Colletotrichum isolates revealed a greater DNA divergence within ITS1 region than that within ITS2. The DNA distance and sequence identity within intra-species ranged from 0.0 to 1.1% and from 98.9 to 100%, respectively; whereas those within inter-species ranged from 1.46 to 13.43% and 90.02 to 98.56%, respectively. From the correlation of DNA distance and relative heteroduplex mobility observed among 15 reference isolates, a formula for estimation of distances of a tested DNA sequence was developed for estimation of DNA distances of a compared strain. The phylogenetic analysis of ITS regions of 29 Colletotrichum isolates using DNA distance inferred from relative heteroduplex mobility divided them into 5 distinctive species groups, namely CG, CA, CC, CM and CL, similar to that assembled based on DNA sequences analysis. Our results show that HMA of ITS regions is a relatively rapid and convenient method for species-specific identification of Colletotrichum spp. The potential use of the established techniques for identification of anthracnose and even other fungal diseases are discussed.     

Local modulation of host pH by Colletotrichum species as a mechanism to increase virulence

The phytopathogenic fungus Colletotrichum gloeosporioides produces one pectate lyase (PL) that is a key virulence factor in disease development. During growth of C. gloeosporioides, Colletotrichum acutatum, and Colletotrichum coccodes in acidified yeast extract medium, the fungus secreted ammonia and increased the medium pH. Ammonia accumulation and the consequent pH change increased as a function of initial pH and buffer capacity of the medium. PL secretion by C. gloeosporioides correspondingly increased as the pH of the medium increased. The C. gloeosporioides pelB gene-disrupted mutant was able to increase ammonia accumulation and pH of the media similarly to the wild-type isolate. C. gloeosporioides in avocado, C. coccodes in tomato, and C. acutatum in apple showed ammonia accumulation in the infected area where pH increased to 7.5 to 8 and PL activity is optima. In nonhost interactions where C. gloeosporioides was inoculated in apples, the addition of ammonia-releasing compounds significantly enhanced pathogenicity to levels similar to those caused by the compatible C. acutatum-apple interaction. The results therefore suggest the importance of ammonia secretion as a virulence factor, enhancing environmental pH and pathogenicity of the Colletotrichum species.     

Molecular Analysis of Colletotrichum Species in the Carposphere and Phyllosphere of Olive

A metagenomic approach based on the use of genus specific primers was developed and utilized to characterize Colletotrichum species associated with the olive phyllosphere and carposphere. Selected markers enabled the specific amplification of almost the entire ITS1-5.8S-ITS2 region of the rDNA and its use as barcode gene. The analysis of different olive samples (green and senescent leaves, floral residues, symptomatic and asymptomatic fruits, and litter leaves and mummies) in three different phenological phases (June, October and December) enabled the detection of 12 genotypes associated with 4 phylotypes identified as C. godetiae, C. acutatum s.s., C. gloeosporioides s.s. and C. kahawae. Another three genotypes were not identified at the level of species but were associated with the species complexes of C. acutatum, C. gloeosporioides and C. boninense sensu lato. Colletotrichum godetiae and C. acutatum s.s. were by far the most abundant while C. gloeosporioides s.s. was detected in a limited number of samples whereas ther phylotypes were rarely found. The high incidence of C. acutatum s.s. represents a novelty for Italy and more generally for the Mediterranean basin since it had been previously reported only in Portugal. As regards to the phenological phase, Colletotrichum species were found in a few samples in June and were diffused on all assessed samples in December. According to data new infections on olive tissues mainly occur in the late fall. Furthermore, Colletotrichum species seem to have a saprophytic behavior on floral olive residues. The method developed in the present study proved to be valuable and its future application may contribute to the study of cycle and aetiology of diseases caused by Colletotrichum species in many different pathosystems.     

Characterization of Colletotrichum gloeosporioides isolates from avocado and almond fruits with molecular and pathogenicity tests.

One hundred twenty isolates of Colletotrichum gloeosporioides from avocado (6 U.S. and 57 Israeli isolates) and almond (57 Israeli isolates) fruits were compared by various molecular methods and a pathogenicity assay in order to determine the genetic diversity and host specificity between and among the different populations. DNA from eight additional U.S. almond anthracnose isolates were also compared. PCR amplification of genomic DNA with four primers produced uniform banding patterns for all the Israeli almond isolates from different geographic locations in Israel. DNAs from the U.S. almond isolates were distinct from DNAs of the Israeli isolates. In contrast, the avocado isolates from Israel and the United States were more diverse, with numerous arbitrarily primed-PCR phenotypes being observed. HaeIII digestion patterns of A+T-rich DNA distinguished between the almond and avocado isolates. Southern hybridization of the repetitive nuclear-DNA element GcpR1 to PstI-digested genomic DNA of almond and avocado isolates revealed no polymorphic fragments among the almond isolates, whereas polymorphic fragments were observed among the avocado isolates. Amplification and subsequent restriction enzyme digestion of the internal transcribed spacer 4 and 5 regions between the small and large nuclear subunits of DNA encoding rRNA failed to distinguish between C. gloeosporioides isolates from a diverse host range. In artificial inoculations, avocado isolates produced various lesions on avocado and almond fruits, whereas the almond isolates infected both fruits at a lower rate.