Occurrence of Colletotrichum graminicola on wheat in Pakistan

Abstract

During a survey of foliar spot of wheat in different agro-ecological wheat production zones, conducted in 2005, Collectotrichum graminicola was found to cause anthracnose in wheat with other foliar diseases like leaf blotch. Pathogenicity has been carried out to fulfill Koch's postulates.     

禾谷炭疽菌RGS蛋白生物信息学分析

【目的】明确禾谷炭疽菌中存在的典型RGS,及其信号肽、跨膜区、二级结构特征,明确该菌RGS与其他病菌之间的关系,最终为深入开展RGS定位、功能研究打下坚实的理论基础,也为进一步开展其他炭疽菌的研究提供重要的理论指导。【方法】基于酿酒酵母中已经报道的4个典型RGS序列,利用BLASTp以及关键词对禾谷炭疽菌蛋白质数据库进行比对、搜索,以及通过SMART保守结构域分析。同时,通过对禾谷炭疽菌中典型RGS氨基酸序列进行细胞信号肽、跨膜区结构以及二级结构等生物信息学分析,此外,通过对禾谷炭疽菌中的典型RGS与其他物种中的同源序列进行遗传关系比较分析。【结果】明确禾谷炭疽菌存在6个典型的RGS,上述RGS在蛋白质二级结构中均含有较高比例的α螺旋结构,而在信号肽方面,除CgRGS6含有明显的信号肽序列外,其他RGS则没有;6个RGS中3个定位在细胞核中,其他则定位在质膜、内质网、线粒体上。【结论】禾谷炭疽菌中的RGS与C.higginsianum、C.gloeosporioides Cg-14/Nara gc5、C.orbiculare等炭疽菌属中的病菌具有较高的同源序列,以及较近的亲缘关系。     

Root Infection and Systemic Colonization of Maize by Colletotrichum graminicola

Colletotrichum graminicola is a filamentous ascomycete that causes anthracnose disease of maize. While the fungus can cause devastating foliar leaf blight and stalk rot diseases, little is known about its ability to infect roots. Previously published reports suggest that C. graminicola may infect maize roots and that root infections may contribute to the colonization of aboveground plant tissues, leading to disease. To determine whether C. graminicola can infect maize roots and whether root infections can result in the colonization of aboveground plant tissues, we developed a green fluorescent protein-tagged strain and used it to study the plant root colonization and infection process in vivo. We observed structures produced by other root pathogenic fungi, including runner hyphae, hyphopodia, and microsclerotia. A mosaic pattern of infection resulted from specific epidermal and cortical cells becoming infected by intercellular hyphae while surrounding cells were uninfected, a pattern that is distinctly different from that described for leaves. Interestingly, falcate conidia, normally restricted to acervuli, were also found filling epidermal cells and root hairs. Twenty-eight percent of plants challenged with soilborne inoculum became infected in aboveground plant parts (stem and/or leaves), indicating that root infection can lead to asymptomatic systemic colonization of the plants. Many of the traits observed for C. graminicola have been previously reported for other root-pathogenic fungi, suggesting that these traits are evolutionally conserved in multiple fungal lineages. These observations suggest that root infection may be an important component of the maize anthracnose disease cycle.     

Characterization of two divergent beta-tubulin genes from Colletotrichum graminicola

We have cloned and sequenced two beta-tubulin genes, TUB1 and TUB2, from the phytopathogenic fungus, Colletotrichum graminicola. The nucleotide sequences of the coding regions of the two genes are only 72.8% homologous. This divergence is reflected in the deduced amino acid (aa) sequences which differ at 94 aa residues. Comparison with the aa sequences of other fungal beta-tubulins indicates that the C. graminicola TUB2 gene encodes a conserved isotype, whereas the C. graminicola TUB1 product is highly divergent. Both genes contain six identically placed introns and the position of each intron is conserved in other fungal beta-tubulin genes. Also typical of other fungal beta-tubulin genes, there is a pronounced bias in codon usage in the C. graminicola TUB2 gene; there is a lesser codon bias in TUB1 from C. graminicola. Both C. graminicola beta-tubulin genes are transcribed and yield similar sized messages.     

Size and complexity of the nuclear genome of Colletotrichum graminicola.

DNA reassociation was used to estimate GC content, size, and complexity of the nuclear genomes of Colletotrichum from maize and sorghum. Melting-temperature analysis indicated that the GC content of the maize pathotype DNA was 51% and that the GC content of the sorghum pathotype was 52%. DNA reassociation kinetics employing S1 nuclease digestion and an appropriately modified second-order equation indicated that the genome sizes of the maize and sorghum pathotypes were 4.8 x 10(7) bp, and 5.0 x 10(7) bp, respectively. Genomic reconstruction experiments based on Southern blot hybridization between a cloned single-copy gene, PYR1 (orotate phosphoribosyl transferase), and maize-pathotype DNA confirmed the size of the nuclear genome. The single-copy component of the genomes of both pathotypes was estimated at about 90%. For both pathotypes, ca. 7% of the genome represented repetitive DNA, and 2 to 3% was foldback DNA.     

Population structure and mating-type genes of Colletotrichum graminicola from Agrostis palustris

Eighty-seven isolates of Colletotrichum graminicola, mostly from Agrostis palustris, were collected in grass fields, most of which were in Ontario, Canada. Specific primers were designed to amplify the mating-type (MAT) genes and, among 35 isolates tested, all yielded a band of the expected size for MAT2. For six isolates, the MAT2 PCR products were sequenced and found to be similar to that reported for MAT2 of C. graminicola from maize. Based on 119 polymorphic bands from 10 random amplified polymorphic DNA primers, analyses of genetic distances were found to generally cluster isolates by host and geographic origin. Among 42 isolates from a grass field in Ontario, significant spatial autocorrelation was found to occur within a 20-m distance, implying that this is the effective propagule dispersal distance. Although clonal propagation was observed in the 87 isolates with 67 unique genotypes, the extent of genetic variation in local populations implies some occurrence of sexual or asexual recombination.     

The hemibiotrophic lifestyle of Colletotrichum species

Colletotrichum species infect several economically important crop plants. To establish a compatible parasitic interaction, a specialized infection cell, the melanized appressorium, is differentiated on the cuticle of the host. After penetration, an infection vesicle and primary hyphae are formed. These structures do not kill the host cell and show some similarities with haustoria formed by powdery mildews and rust fungi. Therefore, this stage of infection is called biotrophic. Later in the infection process, necrotrophic secondary hyphae spread within and kill the host tissue. The lifestyle of Colletotrichum species is called hemibiotrophic, as biotrophic and necrotrophic developmental stages are sequentially established. As most Colletotrichum species are accessible to molecular techniques, genes can be identified and functionally characterized. Here we demonstrate that Agrobacterium tumefaciens-mediated transformation is a well-suited method for tagging of genes mediating compatibility in the Colletotrichum graminicola-maize interaction.     

Quantification of substratum contact required for initiation of Colletotrichum graminicola appressoria

Colletotrichum graminicola, like many plant pathogenic fungi develop appressoria on germling apices, to facilitate penetration of their host. Induction of these structures occurs after contact with the host surface has been established by the germling. Surface contact and subsequent development of appressoria by germlings of C. graminicola was assessed using interference-reflection microscopy (IRM) and microfabricated pillared silicon substrata. Observations with IRM revealed that under low nutrient conditions, 90% of the germlings developed appressoria once they established 4.5 microm of continuous contact with the substratum. Substrata bearing pillars < or =5 microm in width supported < or =10% appressoria; however, as pillar width was increased the percentage of appressoria formed increased in a sigmoid fashion to a maximum of 80%. The percentage of appressoria produced experimentally on these surfaces was compared to data sets generated from a model designed to calculate the probability of appressorium development on similar pillar arrays at various germ tube contact lengths. These results indicate that germ tubes of C. graminicola require more than 4microm of continuous contact with a hydrophobic substratum for induction of appressoria.     

Restriction enzyme-mediated integration used to produce pathogenicity mutants of Colletotrichum graminicola

We have developed a restriction enzyme-mediated insertional mutagenesis (REMI) system for the maize pathogen Colletotrichum graminicola. In this report, we demonstrate the utility of a REMI-based mutagenesis approach to identify novel pathogenicity genes. Use of REMI increased transformation efficiency by as much as 27-fold over transformations with linearized plasmid alone. Ninety-nine transformants were examined by Southern analysis, and 51% contained simple integrations consisting of one copy of the vector integrated at a single site in the genome. All appeared to have a plasmid integration at a unique site. Sequencing across the integration sites of six transformants demonstrated that in all cases the plasmid integration occurred at the corresponding restriction enzyme-recognition site. We used an in vitro bioassay to identify two pathogenicity mutants among 660 transformants. Genomic DNA flanking the plasmid integration sites was used to identify corresponding cosmids in a wild-type genomic library. The pathogenicity of one of the mutants was restored when it was transformed with the cosmids.     

The Colletotrichum graminicola striatin orthologue Str1 is necessary for anastomosis and is a virulence factor

Striatin family proteins are key regulators in signalling pathways in fungi and animals. These scaffold proteins contain four conserved domains: a caveolin‐binding domain, a coiled‐coil motif and a calmodulin‐binding domain at the N‐terminus, and a WD‐repeat domain at the C‐terminus. Fungal striatin orthologues are associated with sexual development, hyphal growth and plant pathogenesis. In Fusarium verticillioides, the striatin orthologue Fsr1 promotes virulence in the maize stalk. The relationship between fungal striatins and pathogenicity remains largely unexplored. In this study, we demonstrate that the Colletotrichum graminicola striatin orthologue Str1 is required for full stalk rot and leaf blight virulence in maize. Pathogenicity assays show that the striatin mutant strain (Δstr1) produces functional appressoria, but infection and colonization are attenuated. Additional phenotypes of the Δstr1 mutant include reduced radial growth and compromised hyphal fusion. In comparison with the wild‐type, Δstr1 also shows a defect in sexual development and produces fewer and shorter conidia. Together with the fact that F. verticillioides fsr1 can complement Δstr1, our results indicate that C. graminicola Str1 shares five phenotypes with striatin orthologues in other fungal species: hyphal growth, hyphal fusion, conidiation, sexual development and virulence. We propose that fungal striatins, like mammalian striatins, act as scaffolding molecules that cross‐link multiple signal transduction pathways.     

Vacuolar system of ungerminated Colletotrichum graminicola conidia: convergence of autophagic and endocytic pathways

Vacuoles of ungerminated Colletotrichum graminicola conidia engulf cytoplasmic structures by a process analogous to microautophagy, demonstrated by using a vacuolar membrane acid phosphatase marker. Fusion of vesicles with vacuoles, without deposition of the acid phosphatase reaction product has been observed, suggesting other pathways of material delivery to vacuoles than microautophagy. Plasma membrane invaginations, multivesicular bodies and retention of neutral red into small vesicles, which were internalized by the vacuole, were verified. These results provided evidence for endocytosis and an active endosomal system. Together, our findings with C. graminicola demonstrated that vacuoles are very dynamic compartments, playing roles in autophagy and endocytic processes.     

The role of a fadA ortholog in the growth and development of Colletotrichum graminicola in vitro and in planta

A transposon-based split-marker protocol was used to produce insertional mutations in the fadA ortholog of the maize anthracnose pathogen Colletotrichum graminicola. The mutants grew more slowly in culture, produced fewer oval spores, produced fusiform rather than falcate phialospores, lost their normal clockwise spiral growth pattern in culture, and were significantly reduced in their pathogenicity to maize stalks and leaves. The differential effect of the fadA mutation on oval spore versus phialospore production suggests that there are differences in the signaling pathways that regulate these two types of sporulation. It has been suggested that oval spores function in anthracnose lesion extension. In maize stalks, production of oval spores appeared to be relatively unaffected in the mutant strains, but production of vegetative hyphae and elongation of primary lesions were both reduced. This suggests that vegetative hyphae play a more important role than oval spores in primary lesion development. However, production of discontinuous secondary lesions in maize stalks infected by mutant strains did not appear to be seriously affected, and thus oval spores may play a more important role in that process.     

Identification of virulence genes in the corn pathogen Colletotrichum graminicola by Agrobacterium tumefaciens-mediated transformation

A previously developed Agrobacterium tumefaciens-mediated transformation (ATMT) protocol for the plant pathogenic fungus Colletotrichum graminicola led to high rates of tandem integration of the whole Ti-plasmid, and was therefore considered to be unsuitable for the identification of pathogenicity and virulence genes by insertional mutagenesis in this pathogen. We used a modified ATMT protocol with acetosyringone present only during the co-cultivation of C. graminicola and A. tumefaciens. Analysis of 105 single-spore isolates randomly chosen from a collection of approximately 2000 transformants, indicated that almost 70% of the transformants had single T-DNA integrations. Of 500 independent transformants tested, 10 exhibited attenuated virulence in infection assays on whole plants. Microscopic analyses primarily revealed defects at different pre-penetration stages of infection-related morphogenesis. Three transformants were characterized in detail. The identification of the T-DNA integration sites was performed by amplification of genomic DNA ends after endonuclease digestion and polynucleotide tailing. In one transformant, the T-DNA had integrated into the 5'-flank of a gene with similarity to allantoicase genes of other Ascomycota. In the second and third transformants, the T-DNA had integrated into an open reading frame (ORF) and into the 5'-flank of an ORF. In both cases, the ORFs have unknown function.     

Screening of turfgrass species and cultivars for NaCl tolerance

Summary Information regarding the relative levels of salt tolerance between cultivars of Kentucky bluegrass (Poa pratensis L.) is lacking. The objectives of this study were to 1) develop a simple, quick and sensitive method of screening turfgrass species for NaCl tolerance and 2) to compare the relative salt tolerance of five cultivars of Kentucky bluegrass (Ram I, Adelphi, Baron, Bensun, and Nassau) to other known salt tolerant turfgrass species such as alkalaigrass (Puccinellia distans (L.) Parl. cv. Fults) and two cultivars of red fescue (Festuca rubra L. Dawson, and Checker).Alkalaigrass and both cultivars of red fescue retained a high level of salt tolerance compared to the Kentucky bluegrass cultivars. Significant variability in salt tolerance was apparent among the Kentucky bluegrass cultivars with Adelphi and Ram I exhibiting the best overall tolerance.