Using Human Sera to Identify a 52-kDa Exoantigen of <Emphasis Type="Italic">Penicillium chrysogenum</Emphasis> and Implications of Polyphasic Taxonomy of Anamorphic Ascomycetes in the Study of Antigenic Proteins

We are interested in isolating and identifying antigenic fungal proteins from species that grow on damp building materials. The indoor clade of Penicillium chrysogenum, the so-called Fleming clade, is the most common species of Penicillium on moldy building materials. We have identified a 52-kDa marker protein for the indoor clade of P. chrysogenum not present in a taxonomically diverse selection of fungi. It is found in high concentrations in protein extracted from the fungus grown on paper-faced gypsum wallboard. During this process, we illuminated the variability in response to patient sera and of strains of the fungus collected over a wide geographic area. From a collection of sera from all over the USA, 25 of the 48 patients reacted to the 52-kDa protein from this prescreened collection of sera. Most strain/antibody combinations had proportionate ELISA response associated with the presence of the target. However, approximately 25% of the strain/patient serum combinations included people who responded to many common allergens from the Penicillia. All the P. chrysogenum strains tested produced the target protein. However, there was considerable variability in patient IgG response to 32-, 30-, and 18-kDa antigens and in their production by the various clade 4 strains. The target protein was not found in spores or culture extracts of a wide selection of relevant fungi. It appears that the previous studies have been conducted on strains of the fungus from the three clades not those associated with the built environment.     

A MAT1–2 wild‐type strain from Penicillium chrysogenum: functional mating‐type locus characterization,genome sequencing and mating with an industrial penicillin‐producing strain

In heterothallic ascomycetes, mating is controlled by two nonallelic idiomorphs that determine the ‘sex’ of the corresponding strains. We recently discovered mating‐type loci and a sexual life cycle in the penicillin‐producing fungus, Penicillium chrysogenum. All industrial penicillin production strains worldwide are derived from a MAT1‐1 isolate. No MAT1‐2 strain has been investigated in detail until now. Here, we provide the first functional analysis of a MAT1‐2 locus from a wild‐type strain. Similar to MAT1‐1, the MAT1‐2 locus has functions beyond sexual development. Unlike MAT1‐1, the MAT1‐2 locus affects germination and surface properties of conidiospores and controls light‐dependent asexual sporulation. Mating of the MAT1‐2 wild type with a MAT1‐1 high penicillin producer generated sexual spores. We determined the genomic sequences of parental and progeny strains using next‐generation sequencing and found evidence for genome‐wide recombination. SNP calling showed that derived industrial strains had an uneven distribution of point mutations compared with the wild type. We found evidence for meiotic recombination in all chromosomes. Our results point to a strategy combining the use of mating‐type genes, genetics, and next‐generation sequencing to optimize conventional strain improvement methods.     

Species-specific PCR to describe local-scale distributions of four cryptic species in the Penicillium chrysogenum complex

Penicillium chrysogenum is a ubiquitous airborne fungus detected in every sampled region of the Earth. Owing to its role in Alexander Fleming's serendipitous discovery of Penicillin in 1928, the fungus has generated widespread scientific interest; however its natural history is not well understood. Research has demonstrated speciation within P. chrysogenum, describing the existence of four cryptic species. To discriminate the four species, we developed protocols for species-specific diagnostic PCR directly from fungal conidia. 430 Penicillium isolates were collected to apply our rapid diagnostic tool and explore the distribution of these fungi across the London Underground rail transport system revealing significant differences between Underground lines. Phylogenetic analysis of multiple type isolates confirms that the ‘Fleming species’ should be named Penicillium rubens and that divergence of the four ‘Chrysogenum complex’ fungi occurred about 0.75 million yr ago. Finally, the formal naming of two new species, Penicillium floreyi and Penicillium chainii, is performed.     

Characterization of a 52 kDa Exoantigen of <Emphasis Type="Italic">Penicillium chrysogenum</Emphasis> and Monoclonal Antibodies Suitable for its Detection

The indoor clade of Penicillium chrysogenum, the so-called Fleming clade, is the most common species of Penicillium on moldy building materials. In a previous study, we identified a 52 kDa human antigen characteristic of the indoor clade of P. chrysogenum not present in a taxonomically diverse selection of fungi. Further investigations revealed that it is a modestly glycosylated mature protein with a pI 5.3. The protein is apparently identical to a glucoamylase previously reported from an aluminum-tolerant P. chrysogenum mutant. Based on sequence similarity, molecular weight, and pI, it is distinct from a number of other glucoamylases from domesticated strains of Aspergillus oryzae and A. niger used to produce industrial enzymes. Surprisingly, it had not been reported as an allergen. The monoclonal antibodies developed have the potential for use in assays of P. chrysogenum antigens in spores and spore/mycelial fragments in dust.     

Sex, drugs and recombination: the wild life of Aspergillus

Throughout the eukaryotes, sexual reproduction is an almost universal phenomenon. However, within the Kingdom Fungi, this relationship is not so clear‐cut. Fungi exhibit a spectrum of reproductive modes and life‐cycles; amongst the better known species, sexual reproduction is often facultative, can be rare, and in over half of the known Ascomycota (the moulds) is unknown ( Taylor et al. 1999 ). However, over the last decade, it has become apparent that many of these asexual mitosporic taxa undergo cryptic recombination via unobserved mechanisms and that wholly asexual fungi are, in fact, a rarity ( Taylor et al. 1999, 2001 ; Heitman 2010 ). This revolution in our understanding of fungal sexuality has come about in two ways: Firstly, sexual reproduction leaves an imprint on fungal genomes by maintaining genes required for mating and by generating patterns of mutation and recombination restricted to meiotic processes. Secondly, scientists have become better at catching fungi in flagrante delicto. The genus Aspergillus is one such fungus where a combination of population genetics, genomics and taxonomy has been able to intuit the existence of sex, then to catch the fungus in the act and formally describe their sexual stages. So, why are sexy moulds exciting? One species in particular, Aspergillus flavus, is notorious for its ability to produce a diverse array of secondary metabolites, of which the polyketide aflatoxins (AF) are carcinogenic and others (such as cyclopiazonic acid) are toxigenic. Because of the predilection of A. flavus to grow on crops, such as peanuts, corn and cotton, biocontrol is widely used to mitigate infection by pre‐applying nonaflatoxigenic (AF?) strains to competitively exclude the wild‐type AF+ strains. However, the eventual fate in nature of these biocontrol strains is not known. In this issue of Molecular Ecology, Olarte et al. (2012) make an important contribution by using laboratory crosses of A. flavus to show that not only is AF highly heritable, but AF? strains can become AF+ via crossing over during meiosis. This observation has raised the spectre of cross‐breeding and non‐mendelian inheritance of AF between native and biocontrol strains of the fungus, leading to an increase in the natural diversity of the fungus with perhaps unanticipated consequences.     

Regulation of mating genes during arbuscular mycorrhizal isolate co-existence—where is the evidence?

A recent study published by Mateus et al. [1] claimed that 18 “mating-related” genes are differentially expressed in the model arbuscular mycorrhizal fungus (AMF) Rhizophagus irregularis when genetically distinct fungal strains co-colonize a host plant. To clarify the level of evidence for this interesting conclusion, we first aimed to validate the functional annotation of these 18 R. irregularis genes using orthology predictions. These analyses revealed that, although sequence relationship exists, only 2 of the claimed 18 R. irregularis mating genes are potential orthologues to validated fungal mating genes. We also investigated the RNA-seq data from Mateus et al. [1] using classical RNA-seq methods and statistics. This analysis found that the over-expression during strain co-existence was not significant at the typical cut-off of the R. irregularis strains DAOM197198 and B1 in plants. Overall, we do not find convincing evidence that the genes involved have functions in mating, or that they are reproducibly up or down regulated during co-existence in plants.Subject terms: Microbiology, Environmental sciences     

T‐DNA insertion,plasmid rescue and integration analysis in the model mycorrhizal fungus Laccaria bicolor

Ectomycorrhiza is a mutualistic symbiosis formed between fine roots of trees and the mycelium of soil fungi. This symbiosis plays a key role in forest ecosystems for the mineral nutrition of trees and the biology of the fungal communities associated. The characterization of genes involved in developmental and metabolic processes is important to understand the complex interactions that control the ectomycorrhizal symbiosis. Agrobacterium‐mediated gene transfer (AMT) in fungi is currently opening a new era for fungal research. As whole genome sequences of several fungi are being released studies about T‐DNA integration patterns are needed in order to understand the integration mechanisms involved and to evaluate the AMT as an insertional mutagenesis tool for different fungal species. The first genome sequence of a mycorrhizal fungus, the basidiomycete Laccaria bicolor, became public in July 2006. Release of Laccaria genome sequence and the availability of AMT makes this fungus an excellent model for functional genomic studies in ectomycorrhizal research. No data on the integration pattern in Laccaria genome were available, thus we optimized a plasmid rescue approach for this fungus. To this end the transformation vector (pHg/pBSk) was constructed allowing the rescue of the T‐DNA right border (RB)–genomic DNA junctions in Escherichia coli. Fifty‐one Agrobacterium‐transformed fungal strains, picked up at random from a larger collection of T‐DNA tagged strains (about 500), were analysed. Sixty‐nine per cent were successfully rescued for the RB of which 87% were resolved for genomic integration sequences. Our results demonstrate that the plasmid rescue approach can be used for resolving T‐DNA integration sites in Laccaria. The RB was well conserved during transformation of this fungus and the integration analysis showed no clear sequence homology between different genomic sites. Neither obvious sequence similarities were found between these sites and the T‐DNA borders indicating non‐homologous integration of the transgenes. Majority (75%) of the integrations were located in predicted genes. Agrobacterium‐mediated gene transfer is a powerful tool that can be used for functional gene studies in Laccaria and will be helpful along with plasmid rescue in searching for relevant fungal genes involved in the symbiotic process.     

Hybridization between Japanese and North American Chlamydomonas reinhardtii (Volvocales,Chlorophyceae)

The microalga Chlamydomonas reinhardtii is a model organism whose whole genome has been sequenced. Although considered a cosmopolitan species, only eastern North American isolates of C. reinhardtii were available before 2010, when new Japanese isolates were reported. In the study describing the new Japanese isolates, zygote formation between Japanese and North American strains was shown, but germination was not demonstrated. In this study, the germination of intercontinental hybrid zygotes was examined using wild‐type Japanese strains and mutant American strains that cannot utilize nitrate. Several clonal progeny strains were established, and the progeny strains were screened based on mating type and nitrate utilization to confirm their hybrid nature. The establishment of four intercontinental hybrid strains with different phenotypic combinations was confirmed by sequencing mating type‐specific and nitrate reductase‐related genes. The potential for hybrid formation between Japanese and North American strains suggests the existence of a worldwide mating population of C. reinhardtii.     

Comparative and population genomic landscape of Phellinus noxius: A hypervariable fungus causing root rot in trees

The order Hymenochaetales of white rot fungi contain some of the most aggressive wood decayers causing tree deaths around the world. Despite their ecological importance and the impact of diseases they cause, little is known about the evolution and transmission patterns of these pathogens. Here, we sequenced and undertook comparative genomic analyses of Hymenochaetales genomes using brown root rot fungus Phellinus noxius, wood‐decomposing fungus Phellinus lamaensis, laminated root rot fungus Phellinus sulphurascens and trunk pathogen Porodaedalea pini. Many gene families of lignin‐degrading enzymes were identified from these fungi, reflecting their ability as white rot fungi. Comparing against distant fungi highlighted the expansion of 1,3‐beta‐glucan synthases in P. noxius, which may account for its fast‐growing attribute. We identified 13 linkage groups conserved within Agaricomycetes, suggesting the evolution of stable karyotypes. We determined that P. noxius has a bipolar heterothallic mating system, with unusual highly expanded ~60 kb A locus as a result of accumulating gene transposition. We investigated the population genomics of 60 P. noxius isolates across multiple islands of the Asia Pacific region. Whole‐genome sequencing showed this multinucleate species contains abundant poly‐allelic single nucleotide polymorphisms with atypical allele frequencies. Different patterns of intra‐isolate polymorphism reflect mono‐/heterokaryotic states which are both prevalent in nature. We have shown two genetically separated lineages with one spanning across many islands despite the geographical barriers. Both populations possess extraordinary genetic diversity and show contrasting evolutionary scenarios. These results provide a framework to further investigate the genetic basis underlying the fitness and virulence of white rot fungi.     

Genetic isolation among sympatric vegetative compatibility groups of the aflatoxin‐producing fungus Aspergillus flavus

Aspergillus flavus, a fungal pathogen of animals and both wild and economically important plants, is most recognized for producing aflatoxin, a cancer‐causing secondary metabolite that contaminates food and animal feed globally. Aspergillus flavus has two self/nonself recognition systems, a sexual compatibility system and a vegetative incompatibility system, and both play a role in directing gene flow in populations. Aspergillus flavus reproduces clonally in wild and agricultural settings, but whether a cryptic sexual stage exists in nature is currently unknown. We investigated the distribution of genetic variation in 243 samples collected over 4 years from three common vegetative compatibility groups (VCGs) in Arizona and Texas from cotton using 24 microsatellite loci and the mating type locus (MAT) to assess population structure and potential gene flow among A. flavus VCGs in sympatric populations. All isolates within a VCG had the same mating type with OD02 having MAT1‐2 and both CG136 and MR17 having MAT1‐1. Our results support the hypothesis that these three A. flavus VCGs are genetically isolated. We found high levels of genetic differentiation and no evidence of gene flow between VCGs, including VCGs of opposite mating‐type. Our results suggest that these VCGs diverged before domestication of agricultural hosts (>10 000 yr bp ).     

Various characteristics of gene localization in eukaryotic chromosomes. Formulation of a problem and analysis of non-random localization of mating type loci in fungi

We have denoted two possible models of gene order evolution as the "card" and "chess" models. The first suggests random shuffling of genes during evolution, the second--non-random gene transposition, gene order being checked by natural selection. We discuss here localization of the mating type locus in fungal genomes. In 8 of 10 genetically well studied species of ascomycetous fungi, the mating type locus is linked to a centromere; in one species, it segregates regularly during the second meiotic division, and only one species does not show any regularity in the mating type locus segregation. Centromeric linkage of the mating type locus maintains heterozygosity of all centromeric genome regions during intratetrad fertilization observed in some fungi. Non-random localization of mating type locus can be considered as the means for conservation of heterozygosity.     

Sequence analysis and gene amplification study of the penicillin biosynthesis gene cluster from different strains of <Emphasis Type="Italic">Penicillium chrysogenum</Emphasis>

Industrial strains of Penicillium chrysogenum possess many genomic changes leading to higher levels of penicillin. In this work several production and wild-type strains of Penicillium chrysogenum were used in comparative nucleotide sequence analysis of the biosynthesis cluster. The alignments confirmed sequence conservation not only in promoter regions of the biosynthesis genes but also throughout the entire 44.7-kbp genomic fragment comprising the whole biosynthesis cluster with 15.5-kbp and 13.1-kbp flanking regions. As another titre-enhancing mechanism we subsequently examined gene dosage in two production strains introduced here, NMU2/40 and B14. Quantitative real-time PCR and Southern blot analysis showed the amplification of the biosynthesis genes in both these strains. Through the real-time PCR method the exact copy number was estimated for each of the pcbAB, pcbC and penDE genes. The equal pool of all three genes per genome was confirmed for the both production strains indicating that in these strains the entire penicillin cluster has been amplified as an intact element. Penicillium chrysogenum NMU2/40 was found to carry four copies of the cluster, while six copies were estimated for B14. This also proves the contribution of the additional titre-enhancing mechanisms in both strains, since the industrial data referred much higher production of these strains compared with the single copy reference strain NRRL 1951.     

Assessment ofGibberella fujikuroi mating type by PCR

Mating type (MAT)-specific fragments of the two idiomorphs ofGibberella fujikuroi (anamorph,Fusarium moniliforme) were obtained by PCR amplification using primers to conserved regions ofMAT homologs from other fungal species and used to assign mating type by molecular criteria rather than the arbitrary historical designation. Mating type—strains of mating populations A-E and a mating type+strain of mating population F carry an α-box motif and should therefore be designatedMAT-1. Mating type+strains of mating populations A-E and a mating type—strain of mating population F carry an HMG-box motif and should be designatedMAT-2. Thus, assessment of mating type ofG. fujikurol strains can be easily achieved usingMAT-specific primers.     

Molecular evidence for host-adapted races of the fungal endophyte Epichloë bromicola after presumed host shifts

Abstract.— Host shifts of plant‐feeding insects and parasites promote adaptational changes that may result in the formation of host races, an assumed intermediate stage in sympatric speciation. Here, we report on genetically differentiated and host‐adapted races of the fungal endophyte Epichloë bromicola, which presumably emerged after a shift from the grass Bromus erectus to other Bromus hosts. Fungi of the genus Epichloë (Ascomycota) and related anamorphs of Neotyphodium are widespread endophytes of cool‐season grasses. Sexually reproducing strains sterilize the host by formation of external fruiting structures (stromata), whereas asexual strains are asymptomatic and transmitted via seeds. In E. bromicola, strains infecting B. erectus are sexual, and strains from two woodland species, B. benekenii and B. ramosus, are asexual and seed transmitted. Analyses of amplified fragment length polymorphism fingerprinting and of intron sequences of the tub2 and tef1 genes of 26 isolates from the three Bromus hosts collected at natural sites in Switzerland and nearby France demonstrated that isolates are genetically differentiated according to their host, indicating that E. bromicola does not form a single, randomly mating population. Phylogenetic analyses of sequence data did not unambiguously resolve the exact origin of asexual E. bromicola strains, but it is likely they arose from within sexual populations on B. erectus. Incongruence of trees derived from different genes may have resulted from recombination at some time in the recent history of host strains. Reciprocal inoculations of host plant seedlings showed that asexual isolates from B. benekenii and B. ramosus were incapable of infecting B. erectus, whereas the sexual isolates from B. erectus retained the assumed ancestral trait of broad compatibility with Bromus host seedlings. Because all isolates were interfertile in experimental crosses, asexual strains may not be considered independent biological species. We suggest that isolates infecting B. benekenii and B. ramosus represent long‐standing host races or incipient species that emerged after host shifts and that may evolve through host‐mediated reproductive isolation toward independent species.     

Genetic variability among <Emphasis Type="Italic">Pholiota aurivella</Emphasis> isolates from a small natural population

Genetic differences between 36 Pholiota aurivella wild isolates collected from 13 decayed logs of Salicaceae trees distributed along about 1200 m of a streambed in a forest were characterized by somatic incompatibility and mating tests, and by restriction fragment length polymorphism (RFLP) analysis of mitochondrial DNA (mtDNA). There was a perfect correlation between somatic incompatibility and mating type groups, and isolates could be divided into 15 genets (genetically identical clones). Because the mtDNAs of the 36 wild isolates have 14 different EcoRI RFLP patterns, they likely originated from at least 14 distinct wild strains, indicating that multiple wild strains with distinct genetic compositions coexist in the forest investigated in this study. mtDNA variation of P. aurivella is apparently very high despite the close proximity of sample collection sites within the forest. The territories of single P. aurivella genets within a host log are apparently larger than other nonpathogenic wood-decaying basidiomycetes reported previously, such as Flammulina velutipes and Lentinula edodes.