Víctor Rubio

Design of a primer for ribosomal DNA internal transcribed spacer with enhanced specificity for ascomycetes

A primer able to amplify the internal transcribed spacers (ITS) of the ribosomal DNA (rDNA), having enhanced specificity for ascomycetes, was identified by reviewing fungal ribosomal DNA sequences deposited in GenBank. The specificity of the primer, named ITS4A, was tested with DNA extracted from several species of ascomycetes, basidiomycetes, zygomycetes, mastigomycetes and mitosporic fungi (formerly deuteromycetes) and also from plants. The PCR annealing temperature most specific for ascomycetes was found to be 62 degrees C and 64 degrees C for the primer pairs ITS5 + ITS4A and ITS1F + ITS4A, respectively. At these annealing temperatures, all ascomycetous DNA samples were amplified efficiently with the ITS4A primer. The sensitivity limit was in the range 10(-14) g of DNA. This primer could also provide useful tools in suggesting the affinities of many mitosporic fungi with their perfect states.

Primers based on specific rDNA-ITS sequences for PCR detection of Rhizoctonia solani , R. solani AG 2 subgroups and ecological types, and binucleate Rhizoctonia

We have designed primers for identification of the economically important plant pathogenic Rhizoctonia solani , for AG 2 and for each subgroup and an ecological type of AG 2. These specific primers have been designed based on specific sequences of the ITS regions in the R. solani species complex. The PCR procedure involves amplification of the 5.8S ribosomal DNA and part of the ITS regions, using the designed primers in combination with the general fungal primers ITS1F and ITS4B. Two of the primers amplify under optimal PCR conditions R. solani AG 1, AG 2, AG 3, AG 4, AG 5 and binucleate Rhizoctonia (BNR), and six more primers amplify specifically R. solani AG 2, the subgroups, AG 2–1, AG 2–2 and AG 2–3, and the ecological type AG 2-t. In this study DNAs from R. solani AG 2 and AG 4 growing on infected radish were amplified similarly to DNAs from axenic cultures. PCR detection has time saving advantages over traditional isolation methods for detection of Rhizoctonia on infected plant tissue and provides a powerful tool of identification.

Molecular phylogenetic studies on the diatrypaceae based on rDNA-ITS sequences

The order Diatrypales (Ascomycota) contains one single family, the Diatrypaceae. To obtain insight in the phylogenetic relationships within this family, the complete sequences of the ITS region (ITS1, 5.8S rRNA gene and ITS2) of 53 isolates from the five main genera in the family (Diatrype, Diatrypella, Cryptosphaeria, Eutypa and Eutypella) were determined and aligned for phylogenetic reconstruction. Sequence analysis revealed the presence of tandem repeated motifs 11 nucleotides-long, placed in homologous positions along the ITS1 region. Parsimony analysis established the existence of nine monophyletic groups and one branch with a single isolate of Eutypella quaternata. The phylogenetic relationships established by parsimony analysis did not correlate well with classical taxonomic schemes. None of the five genera included in this study was found to be monophyletic. The genera Diatrype, Eutypa and Cryptosphaeria each were divided into two groups. Isolates of Diatrype flavovirens appeared in a clade separated from the one that grouped Diatrype disciformis and the rest of Diatrype species. The Eutypa strains appeared distributed into two clades, one grouping Eutypa lata and related species (Eutypa armeniacae, Eutypa laevata, Eutypa petrakii), and another with the remaining species of the genus. Eutypella (excluding Eutypella quaternaria) appeared as an unstable monophyletic group, which was lost when the sequence alignment was subjected to neighbor-joining analysis. The genus Diatrypella was not associated with any monophyletic group, suggesting that the multisporate asci character has appeared several times during the evolution of the group. Overall, our study suggests the need to revise many of the concepts usually applied to the classification of members of the family.

Transformation in Penicillium chrysogenum

An auxotrophic mutant of Penicillium chrysogenum with a DNA rearrangement that affects the trpC region has been transformed to the Trp+ phenotype by using a plasmid that contains the trifunctional wild-type gene. A frequency of 40-80 transformants per microgram of input DNA was usually achieved. A low frequency of plasmid integration at the recipient mutated trpC gene was detected; however, most of the transformants integrated the plasmid DNA elsewhere into the genome. Some of the transformants contain multiple rearranged copies of the vector integrated in a tandem fashion.

Mating type-correlated molecular markers and demonstration of heterokaryosis in the phytopathogenic fungus Thanatephorus cucumeris (Rhizoctonia solani) AG 1-IC by AFLP DNA fingerprinting analysis

The destructive soil-borne plant pathogenic basidiomycetous fungus Thanatephorus cucumeris (Frank) Donk [anamorph: Rhizoctonia solani Kühn] is not a homogeneous species, but is composed of at least twelve anastomosis groups (AG), which seem to be genetically isolated. The genetics of several T. cucumeris anastomosis groups has been studied by analysis of heterokaryotic tuft formation in the area of contact between homokaryotic single-spore isolates, revealing that AG 1 is heterokaryotic and bipolar. To prove that tuft formation is due to heterokaryosis, AFLP DNA fingerprinting has been applied to a heterokaryotic T. cucumeris AG 1-IC isolate, its homokaryotic single spore-derived progeny, and newly formed heterokaryons. By means of AFLP markers, it is demonstrated that fluffy tufts formed upon pairing of homokaryons from different mating types are newly formed heterokaryons. Mating type-correlated markers have also been found, which will be useful for future studies of the genetics of this fungal species complex.

Secretion of the sweet-tasting protein thaumatin by recombinant strains of Aspergillus niger var. awamori

A recombinant form of the sweet-tasting protein thaumatin has been produced in the filamentous fungus Aspergillus niger var. awamori. Expression cassettes containing a synthetic gene encoding thaumatin II were prepared and used to transform Aspergillus niger var. awamori strain NRRL312. Several fungal strains capable of synthesizing and secreting thaumatin into the culture medium were generated, and their production capabilities were determined, first in shake flasks and later in a laboratory fermentor. We report the expression and secretion of thaumatin in concentrations of 5–7 mg/l. This recombinant thaumatin is sweet.

Transformation of Penicillium chrysogenum to sulfonamide resistance

Penicillium chrysogenum has been transformed to sulfonamide resistance by vectors containing the dihydropteroate synthetase gene from plasmid R388 controlled by the promoter and terminator sequences of the P. chrysogenum trpC gene. Transformation frequencies of four to ten transformants per microgram of vector DNA were obtained.

Presence of a simple tandem repeat in the ITS1 region of the Xylariales.

A Simple Tandem Repeat sequence of 11 nucleotides has been found in the ITS1 region of the rDNA of members of Order Xylariales. The number of repetitions detected ranged from one to six, and they could be found in pure tandem or interspersed. The same core sequences have also been found in DNA from other organisms, although usually not repeated in tandem. These repetitions could have been generated by slipped strand mispairing. The presence of this sequence increases the normal rate of divergence in the ITS1 of the Xylariales. The phylogenetic implications of the presence of this sequence in the molecular taxonomy of Xylariales are also discussed.

Phylogeny and intercontinental distribution of the pneumocandin-producing anamorphic fungus Glarea lozoyensis

Glarea lozoyensis is an anamorphic ascomycete that produces pneumocandin B0, the starting molecule for the synthesis of the antifungal drug caspofungin (CANCIDAS™). Glarea lozoyensis was first isolated in 1985 from a water sample from Madrid, Spain. Until now, only the original strain was known, but we have discovered new strains from Argentina and the USA. Molecular phylogenetic reference to a 28S rDNA database of antibiotic-producing fungi quickly identified these strains as being conspecific with G. lozoyensis. Bayesian inference phylogeny of ITS, 28S rDNA and α-actin gene fragments revealed that G. lozoyensis is related to species of the genus Cyathicula (Helotiales). Glarea lozoyensis was not conspecific with any of the Cyathicula species sequenced, although it appears to share a common ancestor. Glarea lozoyensis and Cyathicula strains were fermented on nutritional microarrays in 96-well plates. Cyathicula extracts did not show antifungal activity and did not produce pneumocandins, whereas potent antifungal activity and pneumocandin A0 production were confirmed for the four G. lozoyensis isolates. Also, culture morphology differed, with G. lozoyensis strains producing a dark brown, profusely sporulating mycelium with pigmented multicellular conidia accumulating in conidial masses, while all Cyathicula species tested in culture formed hyaline to light brown mycelia and lacked conidia. The chemistry and taxonomic distribution of the echinocandin class of antifungals is comprehensively reviewed.

Identification of Beijerinckia fluminensis strains CIP 106281T and UQM 1685T as Rhizobium radiobacter strains, and proposal of Beijerinckia doebereinerae sp. nov. to accommodate Beijerinckia fluminensis LMG 2819

During the course of a research project with free-living, nitrogen-fixing bacteria, we determined the 16S rRNA gene sequence of Beijerinckia fluminensis strains UQM 1685T and CIP 106281T and discovered that they were only 90.6-91.2% similar to the sequences of strains of other Beijerinckia species and subspecies. Moreover, the highest similarity to these sequences (99.7%) corresponded to strains of Rhizobium radiobacter (including Agrobacterium tumefaciens). Other diagnostic features confirmed that the two strains have the same origin but do not descend from the nomenclatural type. At the same time, B. fluminensis LMG 2819 was characterized and it was found that its properties also do not agree with the original description of the species, although it can be considered a member of the genus. Further characterization, including chemotaxonomic and other phenotypic traits, allows us to propose (i) the identification of B. fluminensis strains CIP 106281T and UQM 1685T as strains of Rhizobium radiobacter and (ii) the designation of strain LMG 2819T (=CECT 7311T) as the type strain of a novel species, Beijerinckia doebereinerae sp. nov.