José María Díaz-Mínguez

Molecular Characterization and Identification of Biocontrol Isolates of Trichoderma spp.

ABSTRACT The most common biological control agents (BCAs) of the genusTrichoderma have been reported to be strains ofTrichoderma virens, T. harzianum, and T. viride. Since Trichoderma BCAs use different mechanisms of biocontrol, it is very important to explore the synergistic effects expressed by different genotypes for their practical use in agriculture. Characterization of 16 biocontrol strains, previously identified as “Trichoderma harzianum” Rifai and one biocontrol strain recognized asT. viride, was carried out using several molecular techniques. A certain degree of polymorphism was detected in hybridizations using a probe of mitochondrial DNA. Sequencing of internal transcribed spacers 1 and 2 (ITS1 and ITS2) revealed three different ITS lengths and four different sequence types. Phylogenetic analysis based on ITS1 sequences, including type strains of different species, clustered the 17 biocontrol strains into four groups: T. harzianum-T. inhamatum complex, T. longibrachiatum, T. asperellum, and T. atroviride-T. koningii complex. ITS2 sequences were also useful for locating the biocontrol strains inT. atroviride within the complex T. atroviride-T. koningii. None of the biocontrol strains studied corresponded to biotypes Th2 or Th4 of T. harzianum, which cause mushroom green mold. Correlation between different genotypes and potential biocontrol activity was studied under dual culturing of 17 BCAs in the presence of the phytopathogenic fungi Phoma betae,Rosellinia necatrix, Botrytis cinerea, andFusarium oxysporum f. sp. dianthi in three different media.

Plant Defense Mechanisms Are Activated during Biotrophic and Necrotrophic Development of Colletotricum graminicola in Maize

Hemibiotrophic plant pathogens first establish a biotrophic interaction with the host plant and later switch to a destructive necrotrophic lifestyle. Studies of biotrophic pathogens have shown that they actively suppress plant defenses after an initial microbe-associated molecular pattern-triggered activation. In contrast, studies of the hemibiotrophs suggest that they do not suppress plant defenses during the biotrophic phase, indicating that while there are similarities between the biotrophic phase of hemibiotrophs and biotrophic pathogens, the two lifestyles are not analogous. We performed transcriptomic, histological, and biochemical studies of the early events during the infection of maize (Zea mays) with Colletotrichum graminicola, a model pathosystem for the study of hemibiotrophy. Time-course experiments revealed that mRNAs of several defense-related genes, reactive oxygen species, and antimicrobial compounds all begin to accumulate early in the infection process and continue to accumulate during the biotrophic stage. We also discovered the production of maize-derived vesicular bodies containing hydrogen peroxide targeting the fungal hyphae. We describe the fungal respiratory burst during host infection, paralleled by superoxide ion production in specific fungal cells during the transition from biotrophy to a necrotrophic lifestyle. We also identified several novel putative fungal effectors and studied their expression during anthracnose development in maize. Our results demonstrate a strong induction of defense mechanisms occurring in maize cells during C. graminicola infection, even during the biotrophic development of the pathogen. We hypothesize that the switch to necrotrophic growth enables the fungus to evade the effects of the plant immune system and allows for full fungal pathogenicity.

Heterologous transformation of Mucor circinelloides with the Phycomyces blakesleeanus leu1 gene.

SummaryThe leu1 gene of Phycomyces blakesleeanus was isolated within a HindIII-HindIII genomic DNA fragment by heterologous hybridization screening of a cosmid library, making use of the Mucor circinelloides leuA gene as a probe. The complete nucleotide sequence of this fragment reveals a single 2070 bp ORF with no introns, which presents at least 68% homology with that of the leuA gene. The P. blakesleeanus leu1 gene has also been expressed in the M. circinelloides mutant R7B (leu-), which was used to isolate the leuA gene by complementation. The homology with other known sequences shows that the leu1 gene encodes the P. blakesleeanus α-IPM (isopropylmalate) isomerase.

Development of a strain-specific SCAR marker for the detection of Trichoderma atroviride 11, a biological control agent against soilborne fungal plant pathogens

Abstract The genus Trichoderma includes biocontrol agents (BCAs) effective against soilborne plant pathogenic fungi. Several potentially useful strains for biological control are difficult to distinguish from other strains of Trichoderma found in the field. So, there is a need to find ways to monitor these strains when applied to natural pathosystems. We have used random amplified polymorphic DNA (RAPD) markers to estimate genetic variation among sixteen strains of the species T. asperellum, T. atroviride, T. harzianum, T. inhamatum and T. longibrachiatum previously selected as BCAs, and to obtain fingerprinting patterns. Analysis of these polymorphisms revealed four distinct groups, in agreement with previous studies. Some of the RAPD products generated were used to design specific primers. Diagnostic PCR performed using these primers specifically identify the strain T. atroviride 11, showing that DNA markers may be successfully used for identification purposes. This SCAR (sequence-characterised amplified region) marker can clearly distinguish strain 11 from other closely related Trichoderma strains.

A DNA-Based Procedure for In Planta Detection of Fusarium oxysporum f. sp. phaseoli.

ABSTRACT We have characterized strains of Fusarium oxysporum from common bean fields in Spain that were nonpathogenic on common bean, as well as F. oxysporum strains (F. oxysporum f. sp. phaseoli) pathogenic to common bean by random amplified polymorphic DNA (RAPD) analysis. We identified a RAPD marker (RAPD 4.12) specific for the highly virulent pathogenic strains of the seven races of F. oxysporum f. sp. phaseoli. Sequence analysis of RAPD 4.12 allowed the design of oligonucleotides that amplify a 609-bp sequence characterized amplified region (SCAR) marker (SCAR-B310A280). Under controlled environmental and greenhouse conditions, detection of the pathogen by polymerase chain reaction was 100% successful in root samples of infected but still symptomless plants and in stem samples of plants with disease severity of >/=4 in the Centro Internacional de Agricultura Tropical (CIAT; Cali, Colombia) scale. The diagnostic procedure can be completed in 5 h and allows the detection of all known races of the pathogen in plant samples at early stages of the disease with no visible symptoms.

ISOLATION AND MOLECULAR ANALYSIS OF THE OROTIDINE-5'-PHOSPHATE DECARBOXYLASE GENE (PYRG) OF PHYCOMYCES BLAKESLEEANUS

SummaryThe pyrG gene of Phycomyces was isolated from a Phycomyces genomic library, constructed in the cosmid pHS255, by hybridization with a 170 bp fragment of the pyrG gene of Aspergillus niger. This fragment includes a consensus sequence found in almost all species in which the orotidine-5′-phosphate decarboxylase (OMPdecase) gene has been sequenced. The complete nucleotide sequence of the cloned pyrG gene from Phycomyces was determined and the transcription start sites mapped. In the predicted amino acid sequence there are regions of strong homology to the equivalent genes of Saccharomyces cerevisiae, A. niger, Schizophyllum commune and Homo sapiens. Analysis of the sequence revealed the presence of two introns. The precise length and location of these introns was determined by sequencing the pyrG cDNA and comparing it with the genomic clone. Non-coding flanking regions showed obvious homology to the consensus TATA and CAAT boxes, and the polyadenylation signal “AATAAA”. The pyrG gene is the second Phycomyces gene that has been cloned and analysed. This is the first time that introns have been reported in Phycomyces.

fost12, the Fusarium oxysporum homolog of the transcription factor Ste12, is upregulated during plant infection and required for virulence ☆

We have identified a Fusarium oxysporum homolog of the Ste12 transcription factor that regulates mating and filamentation in Saccharomyces cerevisiae. The corresponding gene, fost12, from a highly virulent strain of F. oxysporum f. sp. phaseoli, was confirmed to share a high level of similarity and possessed the STE and C2H2 domains characteristic of the fungal Ste12 transcription factor family of proteins. Disruption of fost12 resulted in no visible alterations of colony morphology or in vitro growth characteristics. However, the disruption mutants showed a substantial reduction in virulence when inoculated in common bean seedlings. In planta transcription of fost12 is drastically increased between 12 and 24h after inoculation, as detected by real-time RT-PCR. The results of the transcriptional analyses carried out in several F. oxysporum strains during axenic growth suggest that the fost12 gene product is a virulence factor required to deal with the nutritional stress confronted by the pathogen during host plant colonization.

A Fungal Effector With Host Nuclear Localization and DNA-Binding Properties Is Required for Maize Anthracnose Development.

Plant pathogens have the capacity to manipulate the host immune system through the secretion of effectors. We identified 27 putative effector proteins encoded in the genome of the maize anthracnose pathogen Colletotrichum graminicola that are likely to target the hosts nucleus, as they simultaneously contain sequence signatures for secretion and nuclear localization. We functionally characterized one protein, identified as CgEP1. This protein is synthesized during the early stages of disease development and is necessary for anthracnose development in maize leaves, stems, and roots. Genetic, molecular, and biochemical studies confirmed that this effector targets the hosts nucleus and defines a novel class of double-stranded DNA-binding protein. We show that CgEP1 arose from a gene duplication in an ancestor of a lineage of monocot-infecting Colletotrichum spp. and has undergone an intense evolution process, with evidence for episodes of positive selection. We detected CgEP1 homologs in several species of a grass-infecting lineage of Colletotrichum spp., suggesting that its function may be conserved across a large number of anthracnose pathogens. Our results demonstrate that effectors targeted to the host nucleus may be key elements for disease development and aid in the understanding of the genetic basis of anthracnose development in maize plants.

A new gene (madI) involved in the phototropic response of Phycomyces

SummaryOnly eight genes are known to be involved in the phototropic response of Phycomyces (madA-H). Mutants affected in these genes have played a major role in the analysis of photosensory transduction processes in this system. A set of new mutants isolated by Alvarez et al. (1989) that are unable to bend towards dim unilateral blue light were studied by complementation and recombination. Two of these mutants have mutations in madE, one has a mutation in madF and one is a double madE madF mutant. The three remaining mutants tested did not complement each other and showed positive complementation with strains carrying mutations in the genes madA, madB, and madC, indicating that they carried mutations in a new gene designated madI. Recombination analysis showed that madI is unlinked to madA, madB and madC.

New Virulence Groups in Fusarium oxysporum f. sp. phaseoli: The Expression of the Gene Coding for the Transcription Factor ftf1 Correlates with Virulence

Fusarium oxysporum f. sp. phaseoli strains isolated from runner bean plants showing Fusarium wilt symptoms were characterized. The analysis of the genetic diversity of these strains and the comparison with strains formerly isolated from diseased common bean plants grown in the same region of Spain indicated a close genetic similarity among them. Pathogenicity assays carried out on runner bean plants showed virulence differences that allowed the classification of these strains into three groups: super virulent, highly virulent, and weakly virulent. However, all the analyzed strains behaved as highly virulent when inoculated on common bean plants, indicating that virulence is specific of the host-pathogen interaction. We also analyzed the number of copies and expression of the gene encoding the transcription factor ftf1, which has been shown to be specific of virulent F. oxysporum strains and highly up-regulated during plant infection. In planta real-time quantitative polymerase chain reaction expression analysis showed that expression of ftf1 was correlated with the degree of virulence. The comparative analysis of the polymorphic copies of ftf1 detected in the strains here characterized and those detected in the genome sequence of F. oxysporum f. sp. lycopersici strain 4287 indicates that some of the copies are likely nonfunctional.