High-frequency occurrence of virus-like particles with double-stranded RNA genome in Fusarium poae

Mycovirus associated hypovirulence, a potential method for biological control of Fusarium species

Fusarium is a large genus of filamentous fungi belongs to the division Ascomycota and was first described as Fusisporium. Innumerable members of this genus act as pathogens, endophytes and saprophytes and can be recovered from plants and soils worldwide. Many of these members are known to be phytopathogens. It is among the most diverse and widely dispersed phyto-pathogenic fungi which cause economically important blights, rots, wilts and cankers of many ornamental, field, horticultural and forest crops both in agricultural commodities and natural ecosystems. Some species, e.g. F. graminearum and F. verticillioides have a narrow host range and mainly infect the cereals, whereas F. oxysporum has effects on both monocotyledonous and dicotyledonous plants. Attempts have been made to control the diseases caused by Fusarium sp. and to minimize crop yield losses. Till date, effective and eco-friendly methods have not been devised for the control of this devastating pathogen. A new potential of using mycovirus associated hypovirulence as biocontrol method against Fusarium species has been proposed. The present review taking into account of worldwide researches to provide possible insights for Fusarium-mycovirus coevolution.

Two Novel Relative Double-Stranded RNA Mycoviruses Infecting Fusarium poae Strain SX63

Two novel double-stranded RNA (dsRNA) mycoviruses, termed Fusarium poae dsRNA virus 2 (FpV2) and Fusarium poae dsRNA virus 3 (FpV3), were isolated from the plant pathogenic fungus, Fusarium poae strain SX63, and molecularly characterized. FpV2 and FpV3, with respective genome sequences of 9518 and 9419 base pairs (bps), are both predicted to contain two discontinuous open reading frames (ORFs), ORF1 and ORF2. A hypothetical polypeptide (P1) and a RNA-dependent RNA polymerase (RdRp) are encoded by ORF1 and ORF2, respectively. Phytoreo_S7 domain (pfam07236) homologs were detected downstream of the RdRp domain (RdRp_4; pfam02123) of the ORF2-coded proteins of both FpV2 and FpV3. The same shifty heptamers (GGAAAAC) were both found immediately before the stop codon UAG of ORF1 in FpV2 and FpV3, which could mediate programmed –1 ribosomal frameshifting (–1 PRF). Phylogenetic analysis based on RdRp sequences clearly place FpV2 and FpV3 in a taxonomically unassigned dsRNA mycovirus group. Together, with a comparison of genome organization, a new taxonomic family termed Fusagraviridae is proposed to be created to include FpV2- and FpV3-related dsRNA mycoviruses, within which FpV2 and FpV3 would represent two distinct virus species.

Insight into mycoviruses infecting Fusarium species

Most of the major fungal families including plant-pathogenic fungi, yeasts, and mushrooms are infected by mycoviruses, and many double-stranded RNA (dsRNA) mycoviruses have been recently identified from diverse plant-pathogenic Fusarium species. The frequency of occurrence of dsRNAs is high in Fusarium poae but low in other Fusarium species. Most Fusarium mycoviruses do not cause any morphological changes in the host but some mycoviruses like Fusarium graminearum virus 1 (FgV1) cause hypovirulence. Available genomic data for seven of the dsRNA mycoviruses infecting Fusarium species indicate that these mycoviruses exist as complexes of one to five dsRNAs. According to phylogenetic analysis, the Fusarium mycoviruses identified to date belong to four families: Chrysoviridae, Hypoviridae, Partitiviridae, and Totiviridae. Proteome and transcriptome analysis have revealed that FgV1 infection of Fusarium causes changes in host transcriptional and translational machineries. Successful transmission of FgV1 via protoplast fusion suggests the possibility that, as biological control agents, mycoviruses could be introduced into diverse species of fungal plant pathogens. Research is now needed on the molecular biology of mycovirus life cycles and mycovirus-host interactions. This research will be facilitated by the further development of omics technologies.

Structure of Fusarium poae virus 1 shows conserved and variable elements of partitivirus capsids and evolutionary relationships to picobirnavirus

Filamentous fungus Fusarium poae is a worldwide cause of the economically important disease Fusarium head blight of cereal grains. The fungus is itself commonly infected with a bisegmented dsRNA virus from the family Partitiviridae. For this study, we determined the structure of partitivirus Fusarium poae virus 1 (FpV1) to a resolution of 5.6Å or better by electron cryomicroscopy and three-dimensional image reconstruction. The main structural features of FpV1 are consistent with those of two other fungal partitiviruses for which high-resolution structures have been recently reported. These shared features include a 120-subunit T=1 capsid comprising 60 quasisymmetrical capsid protein dimers with both shell and protruding domains. Distinguishing features are evident throughout the FpV1 capsid, however, consistent with its more massive subunits and its greater phylogenetic divergence relative to the other two structurally characterized partitiviruses. These results broaden our understanding of conserved and variable elements of fungal partitivirus structure, as well as that of vertebrate picobirnavirus, and support the suggestion that a phylogenetic subcluster of partitiviruses closely related to FpV1 should constitute a separate taxonomic genus.

The use of tri5 gene sequences for PCR detection and taxonomy of trichothecene-producing species in the Fusarium section Sporotrichiella

Purified DNA from isolates of Fusarium poae, Fusarium sporotrichioides, Fusarium kyushuense and Fusarium langsethiae was used as a template to amplify a 658-bp fragment from the trichodiene synthase (tri5) gene of these fungi with the gene-specific PCR primer pair Tox5-1/Tox5-2. Fragments obtained were isolated and sequenced. DNA sequence alignments revealed high similarity between the sequences derived from F. sporotrichioides and F. langsethiae (98.7%) and less similarity between the latter species and F. poae (90.9%). Phylogenetic analysis of the aligned sequences using the tri5 sequence of Fusarium pseudograminearum as an outgroup revealed clear separation between one group consisting of F. poae and F. kyushuense and another consisting of F. sporotrichioides and F. langsethiae. The two latter species could not be distinguished phylogenetically on the basis of their tri5 sequences. Taxon-specific reverse primers were designed from the aligned sequences and combined with the tri5 gene-specific forward primer Tox5-1. The new reverse primers enabled specific amplification of a fragment of approximately 400 bp from DNA isolated from F. sporotrichioides, F. poae, F. langsethiae and F. kyushuense, respectively. All primers were tested for cross-reactivity with DNA from 26 fungal species potentially capable of producing trichothecenes. Only the primer designed for F. langsethiae cross-reacted with F. sporotrichioides. PCR assays were applied in analysis of artificially and naturally infected samples of barley and oats. On artificially infected barley, species were selectively detected by the corresponding primers. In naturally infected oats, F. langsethiae was identified by the combination of two PCR assays designed for detection of F. sporotrichioides and F. langsethiae, respectively.

Diversity and vertical transmission of double-stranded RNA elements in root rot pathogens of trees, Helicobasidium mompa and Rosellinia necatrix

The diversity and vertical transmission of double-stranded (ds) RNA in Helicobasidium mompa and Rosellinia necatrix was examined by electrophoresis and Northern hybridization. These two fungi share the similar niche as root rot pathogens of trees in forests and orchards, and had diverse dsRNAs. The detection frequency of dsRNA in both fungi was different; in H. mompa, 68.4% (132 out of 193 MCGs; mycelial compatibility groups) had dsRNA, whereas 20.9% (53 out of 254 MCGs) in R. necatrix. dsRNA banding patterns and Northern blot analyses revealed the presence of various dsRNA elements in both fungi. Hyphal tip isolation was mostly unsuccessful to remove dsRNA with some exceptions. Sexual reproduction functioned to remove dsRNA in both fungi since dsRNA was not detected from single sexual spore cultures. Possible explanations for the difference in the detection frequency of dsRNA are discussed in terms of the differences in their sexual reproduction and other factors.

Presence of double-stranded RNA and virus-like particles in Rhizopus isolates

Fungal isolates belonging to four Rhizopus species were screened for the presence of double-stranded RNA (dsRNA) molecules. Five (two R. stolonifer, two R. microsporus, and one R. oryzae) of the 27 isolates examined harboured such genetic elements. Electrophoresis of the nucleic acids revealed five RNA patterns, with 1-5 discrete dsRNA bands. The molecular sizes corresponding to these bands were 2.2-14.8 kb. Gel electrophoresis of purified virus-like particles (VLPs) indicated only one capsid of similar size in all virus-harbouring strains; when investigated by electron microscopy, they were found to be polyhedral VLPs 40 nm in diameter. In one of the R. microsporus isolates an uncapsidated large dsRNA segment (14.8 kb) was observed. No phenotypic differences were observed between uninfected and virus-harbouring Rhizopus isolates.

Group specific PCR-detection of potential trichothecene-producing Fusarium-species in pure cultures and cereal samples

A PCR based assay (Tox5 PCR) which analyses Fusarium species potentially producing trichothecenes was developed using a pair of primers derived from the DNA-sequence of the trichodiene synthase gene (tri5). The primer pair was tested using DNA isolated from a variety of strains representing 64 species and varieties of Fusarium as well as from other fungi, bacteria and cereals. A 658 bp PCR fragment was specifically amplified with DNA isolated from strains of species belonging to the Fusarium sections Discolor, Sporotrichiella, Arthrosporiella, Gibbosum, and "Dlaminia". PCR products obtained were sequenced. Alignment to tri5 sequences given in the literature revealed a high degree of homology. Results of the PCR developed correlated well with literature data on the trichothecene producing capabilities of the respective species. Potential trichothecene producing fusaria were detected in contaminated cereals and malts using the Tox5 PCR assay. Intensity of the signals produced were well correlated with the concentration of deoxynivalenol (DON) in samples of wheat.

Screening of fungi for the presence of the trichodiene synthase encoding sequence by hybridization to the Tri5 gene cloned from Fusarium poae

A trichodiene synthase gene (Tri5) was amplified from F. poae by polymerase chain reaction using synthetic primers constructed on the basis of the coding portion of the same gene from F. sporotrichioides. Sequence analysis showed a high degree of similarity with other trichodiene synthase genes. A 378 bp HindIII fragment of the gene that contains the genetic information for the putative active site of the trichodiene synthase enzyme was radiolabelled and used for dot blot analysis. This probe could detect Tri5 hybridization in 1-10 ng DNA of fusaria that have the genetic potentiality to synthesize toxic trichothecene compounds, but gave no reaction with trichothecene nonproducing members of the genus. When other fungi reported to produce trichothecenes (Myrothecium, Stachybotrys, Trichoderma, Trichothecium spp.) were tested, only strains of Myrothecium and Stachybotrys gave strong positive reaction. Faint but consistent hybridization signals were obtained in four species (F. semitectum, F. tricinctum, Trichoderma viride and Trichothecium roseum) indicating the presence of nonhomologous evolutionary variants or inactive remnants of the Tri5 gene in these fungi.

Assignment of a PCR-amplified chitinase sequence cloned from Trichoderma hamatum to resolved chromosomes of potential biocontrol species of Trichoderma

A 1424 bp DNA sequence containing the genetic determinants of the chitinase enzyme was identified in Trichoderma humatum by PCR amplification. High levels of similarity were observed between this sequence, named Th-ch (T. hamatum chitinase), and the 42 kDa chitinase genes known from T. harzianum. Chromosome-sized DNAs of five potential biocontrol species of Trichoderma were separated by pulsed-field gel electrophoresis. The total number of chromosomes was six in all the species, with sizes ranging from 3.7 to 7.7 Mb; estimated genome sizes were between 30.5 and 35.8 Mb. When fractionated chromosomes of the five species were probed with radiolabelled Th-ch, strong hybridization signals developed in all cases, but the physical position of these signals varied among species indicating a polymorphic chromosomal location of the highly conserved 42 kDa chitinase gene within the genus Trichoderma.