Mitochondrial gene sequences alone or combined with ITS region sequences provide firm molecular criteria for the classification of Lecanicillium species

The recent revision of Verticillium sect. Prostrata led to the introduction of the genus Lecanicillium, which comprises the majority of the entomopathogenic strains. Sixty-five strains previously classified as Verticillium lecanii or Verticillium sp. from different geographical regions and hosts were examined and their phylogenetic relationships were determined using sequences from three mitochondrial (mt) genes [the small rRNA subunit (rns), the NADH dehydrogenase subunits 1 (nad1) and 3 (nad3)] and the ITS region. In general, single gene phylogenetic trees differentiated and placed the strains examined in well-supported (by BS analysis) groups of L. lecanii, L. longisporum, L. muscarium, and L. nodulosum, although in some cases a few uncertainties still remained. nad1 was the most informative single gene in phylogenetic analyses and was also found to contain group I introns with putative open reading frames (ORFs) encoding for GIY-YIG endonucleases. The combined use of mt gene sequences resolved taxonomic uncertainties arisen from ITS analysis and, alone or in combination with ITS sequences, helped in placing uncharacterised Verticillium lecanii and Verticillium sp. firmly into Lecanicillium species. Combined gene data from all the mt genes and all the mt genes and the ITS region together, were very similar. Furthermore, a relaxed correlation with host specificity -- at least for Homoptera -- was indicated for the rns and the combined mt gene sequences. Thus, the usefulness of mt gene sequences as a convenient molecular tool in phylogenetic studies of entomopathogenic fungi was demonstrated.

Molecular characterization of isolates of Beauveria bassiana obtained from overwintering and summer populations of Sunn Pest (Eurygaster integriceps)

AIM

To examine whether isolates of the entomopathogenic fungus Beauveria bassiana are more closely associated to their summer hosts compared with overwintering hosts, with recently developed molecular tools based on mitochondrial regions.

METHODS AND RESULTS

Primers for the traditional ITS1-5.8S-ITS2 region and two mitochondrial intergenic regions, namely, nad3-atp9 and atp6-rns, were used. All amplified products were sequenced, aligned and Neighbour-Joining (NJ), parsimony and Bayesian phylogenetic inference analyses were performed. The isolates examined were grouped with very good support into three distinct groups, two of them showed geographical correlation, but no clear association to their host.

CONCLUSIONS

The mitochondrial intergenic regions used were more informative than the nuclear ITS1-5.8S-ITS2 sequences. The sequence variability observed, that allowed the phylogenetic placement of the isolates into distinct groups, depended on the geographical origin of the isolates and can be exploited for designing group-specific and isolate-specific primers for their genetic fingerprinting. No clear associations with summer Sunn Pest populations were observed.

SIGNIFICANCE AND IMPACT OF THE STUDY

Studies on the genetic variability of biocontrol agents like B. bassiana are indispensable for the development of molecular tools for their future monitoring.

The complete mitochondrial genome of the entomopathogenic fungus Metarhizium anisopliae var. anisopliae: gene order and trn gene clusters reveal a common evolutionary course for all Sordariomycetes, while intergenic regions show variation

The mitochondrial genome (mtDNA) of the entomopathogenic fungus Metarhizium anisopliae var. anisopliae, with a total size of 24,673 bp, was one of the smallest known mtDNAs of Pezizomycotina. It contained the 14 typical genes coding for proteins related to oxidative phosphorylation, the two rRNA genes, a single intron that harbored an intronic ORF coding for a putative ribosomal protein (rps) within the large rRNA gene (rnl), and a set of 24 tRNA genes which recognized codons for all amino acids, except proline and valine. Gene order comparison with all known mtDNAs of Sordariomycetes illustrated a highly conserved genome organization for all the protein- and rRNA-coding genes, as well as three clusters of tRNA genes. By considering all mitochondrial essential protein-coding genes as one unit a phylogenetic study of these small genomes strongly supported the common evolutionary course of Sordariomycetes (100% bootstrap support) and highlighted the advantages of analyzing small genomes (mtDNA) over single genes. In addition, comparative analysis of three intergenic regions demonstrated sequence variability that can be exploited for intra- and inter-specific identification of Metarhizium.

Molecular and immunochemical phylogeny of Verticillium species

21 strains with all typical morphological characteristics of eight Verticillium species (Phyllachorales) were studied in this work, together with representatives from four Hypocreales species (11 strains), that were previously classified as members of the genus. The PCR products from two nuclear genes, i.e. the ITS1-5.8S-ITS2 region and RNA polymerase II largest subunit gene (rpb1), together with four mitochondrial genes, i.e. the small ribosomal rRNA subunit (rns), the two NADH dehydrogenase subunit genes (nad1 and nad3), and the cytochrome oxidase subunit III gene (cox3) were sequenced and analyzed. Similarly, antibodies raised against one strain of each of the species examined (V. nubilum and V. theobromae excluded) were used against the proteins of all other strains. The number and relative area of precipitates formed after crossed electrophoreses served to estimate the degree of immunochemical relatedness. Combined molecular and immunochemical data clarified the phylogenetic relationships of all true Verticillium species and provided a convincing insight into the evolutionary relation of the sect. Nigrescentia with members of the sect. Verticillium and sect. Prostrata that until recently were included in Verticillium.

The analysis of the complete mitochondrial genome of Lecanicillium muscarium (synonym Verticillium lecanii) suggests a minimum common gene organization in mtDNAs of Sordariomycetes: phylogenetic implications

The mitochondrial genome (mtDNA) of the entomopathogenic fungus Lecanicillium muscarium (synonym Verticillium lecanii) with a total size of 24,499-bp has been analyzed. So far, it is the smallest known mitochondrial genome among Pezizomycotina, with an extremely compact gene organization and only one group-I intron in its large ribosomal RNA (rnl) gene. It contains the 14 typical genes coding for proteins related to oxidative phosphorylation, the two rRNA genes, one intronic ORF coding for a possible ribosomal protein (rps), and a set of 25 tRNA genes which recognize codons for all amino acids, except alanine and cysteine. All genes are transcribed from the same DNA strand. Gene order comparison with all available complete fungal mtDNAs-representatives of all four Phyla are included-revealed some characteristic common features like uninterrupted gene pairs, overlapping genes, and extremely variable intergenic regions, that can all be exploited for the study of fungal mitochondrial genomes. Moreover, a minimum common mtDNA gene order could be detected, in two units, for all known Sordariomycetes namely nad1-nad4-atp8-atp6 and rns-cox3-rnl, which can be extended in Hypocreales, to nad4L-nad5-cob-cox1-nad1-nad4-atp8-atp6 and rns-cox3-rnl nad2-nad3, respectively. Phylogenetic analysis of all fungal mtDNA essential protein-coding genes as one unit, clearly demonstrated the superiority of small genome (mtDNA) over single gene comparisons.

Restriction fragment length polymorphism of mitochondrial genome of the entomopathogenic fungus Beauveria bassiana reveals high intraspecific variation

Beauveria bassiana is an entomopathogenic fungus with a growing potential for pest control in different agro-ecosystems worldwide. Such potential brings the necessity of developing a strain specific typing system. In a previous study, we reported the identification of molecular variants in mitochondrial DNA (mtDNA) polymorphism in 15 North American isolates. Results indicated a highly conserved mitochondrial genome showing only two mitochondrial genotypes (mitotypes). In this study we used whole genomic DNA from 18 isolates of B. bassiana, two unidentified Beauveria spp., and one each of B. amorpha, B. cylindrospora and B. nivea from more diverse origins. By doing single- and double-restriction enzyme digestion of total genomic DNA with EcoRI, and HindIII and then probing with BbmtE2, the predominance of mitotypes A and B was observed again, along with three newly described mitotypes (C to E). Additionally, by using whole B. bassiana mtDNA digested with HpaII as probe, we further demonstrate up to nine different mitotypes within B. bassiana. With either of the two probes, distinguished between members of the genus Beauveria and from Paecilomyces farinosus and Metarhizium anisopliae. Phylogenetic analysis could not however distinguish B. amorpha and B. nivea isolates from B. bassiana, suggesting a close genetic relation between the three species of the genus. Altogether, these results show high variability in mitochondrial genome, which can be useful as a reliable tool for the biopesticide industry for both species and isolate specific identification.

Genetic, morphological, and virulence characterization of the entomopathogenic fungus Verticillium lecanii

In order to clarify relationships among genetic diversity, virulence, and other characteristics of conidia, 46 isolates of Verticillium lecanii from various hosts and geographical locations were examined. The internal transcribed spacer (ITS) and intergenic spacer (IGS) regions of ribosomal DNA (rDNA), mitochondrial small subunit rDNA (mt-SrDNA) and beta-tubulin were analyzed by PCR-RFLP. PCR-single stranded conformational polymorphism (SSCP) was performed on regions of the mitochondrial large subunit rDNA, mt-SrDNA, beta-tubulin and histone 4. There were no relationships among the results of RFLP, SSCP, isolation source, and location. However, amplified product size of IGS did have relationships with conidia size and sporulation. Six isolates with 4.0-kb IGS products had large conidia dimensions, and yielded low numbers of conidia compared with other isolates. Three out of the six isolates were high virulence (over 90%) against green peach aphids. Furthermore, double-stranded RNA (dsRNA) was detected in 22 out of 35 V. lecanii isolates and related with the amplicon sizes of IGS, though not with virulence or isolation location. Isolates containing dsRNA were divided into six distinct types based on banding pattern. These data demonstrate the level of genetic diversity of V. lecanii, and suggest relations among the genetic properties and conidial morphology.

Isolates of Verticillium dahliae Pathogenic to Crucifers Are of at Least Three Distinct Molecular Types

ABSTRACT Diverse isolates of the soilborne wilt fungi Verticillium dahliae and V. albo-atrum were studied to understand the nature and origins of those infecting cruciferous hosts. All isolates from cruciferous crops produced microsclerotia, and the majority produced long conidia with a high nuclear DNA content; these isolates were divided into two groups by amplified fragment length polymorphism (AFLP) analysis. One group could be subdivided by other criteria such as rRNA sequences and mitochondrial DNA restriction fragment length polymorphism (RFLP) analysis. Two crucifer isolates were short spored and had a low nuclear DNA content. The results are consistent with the crucifer isolates being interspecific hybrids. The long-spored isolates are best regarded as amphihaploids (or allodiploids) with the AFLP groups probably each representing separate interspecific hybridization events. The short-spored crucifer isolates appear to be derived from interspecific hybrids and are here called 'secondary haploids'. Molecular evidence suggests that one parent in the crosses was similar to V. dahliae. The other parent of the amphihaploids seems to have been more similar to V. albo-atrum than to V. dahliae, but was distinct from all isolates of either species so far studied. The implications for the taxonomy of crucifer isolates are discussed and the use of the name V. longisporum, proposed elsewhere for just some of these isolates, is discouraged.