A class-V myosin required for mating, hyphal growth, and pathogenicity in the dimorphic plant pathogen Ustilago maydis

In the early stages of plant infection, yeast-like haploid sporidia of Ustilago maydis respond to pheromone secreted by compatible partners by forming conjugation tubes. These then fuse to generate a dikaryotic hypha that forms appressoria to penetrate the host plant. As a first step toward understanding the structural requirements for these transitions, we have identified myo5, which encodes a class-V myosin. Analysis of conditional and null mutants revealed that Myo5 plays nonessential roles in cytokinesis and morphogenesis in sporidia and is required for hyphal morphology. Consistent with a role in morphogenesis, a functional green fluorescent protein-Myo5 fusion protein localized to the bud tip and the hyphal apex as well as to the septa and the spore wall during later stages of infection. However, the loss of Myo5 did not affect the tip growth of hyphae and sporidia. By contrast, Myo5 was indispensable for conjugation tube formation. Furthermore, myo5 mutants were impaired in the perception of pheromones, which indicates a particular importance of Myo5 in the mating process. Consequently, few mutant hyphae were formed that penetrated the plant epidermis but did not continue invasive growth. These results indicate a crucial role of Myo5 in the morphogenesis, dimorphic switch, and pathogenicity of U. maydis.     

Morphological Transitions in the Life Cycle of Ustilago maydis and Their Genetic Control by the a and b Loci

Banuett, F., and Herskowitz, I. 1994. Morphological transitions in the life cycle of Ustilago maydis and their genetic control by the a and b loci. Experimental Mycology 18: 247-266. Two forms characterize the life cycle of Ustilago maydis: a haploid yeast-like form and a filamentous dikaryotic form. Dimorphism and other aspects of the life cycle (including tumor induction) are governed by two mating type loci, a and b . Here we report characterization of two different morphological transitions in the life cycle of U. maydis. First, we describe an assay for conjugation tube formation in which cellular response is rapid and occurs synchronously and uniformly in the population. Using this assay, we demonstrate that different alleles of the a locus (but not the b locus) are necessary for conjugation tube formation. We also show that the b locus determines the type of filament formed after cell fusion: different b alleles lead to formation of true filaments, whereas identical b alleles result in production of pseudofilaments. Second, we analyze the role of a and b in postfusion events leading to filament formation in diploid strains. We show that diploid strains heterozygous for both a and b are capable of a dimorphic transition from yeast-like to filamentous growth when shifted from rich medium to low-nitrogen medium. This transition has two components: the first is dependent on the a locus and generates structures similar to conjugation tubes; the second is dependent on the b locus and produces true hyphal structures. We surmise that similar events take place in formation of the dikaryotic filament.     

The a mating type locus of U. maydis specifies cell signaling components.

The a mating type locus of the phytopathogenic fungus U. maydis controls fusion of haploid cells and filamentous growth of the dikaryotic mycelium. The a locus exists in two alleles, termed a1 and a2, which are defined by nonhomologous DNA regions comprising 4.5 kb for a1 and 8 kb for a2, flanked by identical sequences. Based on functional assays, mutants, and sequencing, we demonstrate that the mating type in each allele is determined by a set of two genes. One encodes a precursor for a lipopeptide mating factor, and the other specifies the receptor for the pheromone secreted by cells of opposite mating type. Thus, U. maydis employs a novel strategy to determine its mating type by providing the primary determinants of cell-cell recognition directly from the mating type locus.     

The cell type ofRhodosporidium toruloides after protoplast fusion between strains of identical and opposite mating type

Protoplast fusions between strains of identical and of opposite mating type were performed. Sexual crosses and protoplast fusions inRhodosporidium toruloides led to different hybrid types. Sexual crosses gave rise exclusively to a dikaryotic mycelium. In protoplast fusions between strains of identical mating type (A ora), monokaryotic yeast-like hybrids which sustained the parental mating type were obtained. In protoplast fusions between strains of opposite mating type, the majority of the hybrids belonged to theMyc ⁺ type, i.e., the hybrids grew like yeasts, able to switch over spontaneously to mycelial growth. In addition to theMyc ⁺ types, up to 10% real yeast hybrids and less than 5% dikaryotic mycelia were obtained. Obviously the cell type inR. toruloides is under the control of the mating type alleles.     

Leucosporidium gen. n., the heterobasidiomycetous stage of several yeasts of the genusCandida

Investigation of yeasts from Antarctic regions revealed that certain species ofCandida have heterobasidiomycetous life cycles. Two distinct but overlapping groups of species were found: heterothallic and self-sporulating species.Candida scottii is a heterothallic species with the following life cycle: opposite mating types will conjugate and develop a dikaryotic mycelium with clamp connections. Karyogamy occurs in the teliospore which germinates and produces a promycelium. Meiosis takes place in the promycelium, followed by development of haploid sporidia to complete the life cycle. In addition,C. scottii has a self-sporulating phase. From a single cell, in the apparent absence of mating, a uninucleate mycelium is produced that lacks clamp connections. Teliospores, promycelia and sporidia develop that appear similar to those produced from dikaryotic mycelium.The self-sporulating species have life histories similar to the self-sporulating phase ofC. scottii; except that heterothallism has not been observed.Based on these life histories the new genusLeucosporidium is proposed with two heterothallic species (Leu. scottii andLeu. capsuligenum) and five self-sporulating species (Leu. antarcticum, Leu. frigidum, Leu. gelidum, Leu. nivalis andLeu. stokesii. Leu. antarcticum) andLeu. stokesii have not been described under the genusCandida.Contribution No. 1138 from the Institute of Marine Sciences, University of Miami, Fla.This study was supported by the National Science Foundation through the Office of Antarctic Programs, Grant GA-3957. The authors are grateful to Dr. E. Marelli for editing the Latin diagnosis.     

Selfing versus outcrossing propensity of the fungal pathogen Microbotryumviolaceum across Silenelatifolia host plants

In the fungal pathogen Microbotryumviolaceum mating (i.e. conjugation between cells of opposite mating type) is indispensable for infection of its host plant Silenelatifolia. Since outcrossing opportunities are potentially rare, selfing may be appropriate to ensure reproduction. On the other hand, outcrossing may create genetic variability necessary in the coevolutionary arms race with its host. We investigated the propensity of M. violaceum to outcross vs. self in different host environments. We used haploid sporidia from each of three strains from five fungal populations for pairwise mixtures of opposite mating type, representing either selfing or outcrossing combinations. Mixtures were exposed to leaf extract from seven S. latifolia plants. The proportion of conjugated sporidia quantified mating propensity. The identity of both fungal strains and host influenced conjugation. First, individual strains differed in conjugation frequency by up to 30%, and strains differed in their performance across the different hosts. Second, selfing combinations produced, on average, more conjugations than did outcrossing combinations. Selfing appears to be the predominant mode of reproduction in this fungus, and selfing preference may have evolved as a mechanism of reproductive assurance. Third, individual strains varied considerably in conjugation frequency in selfing and outcrossing combinations across different hosts. This indicates that conjugation between outcrossing partners could be favoured at least in some hosts. Since the dikaryon resulting from conjugation is the infectious unit, conjugation frequency may correspond with infection probability. This assumption was supported by an inoculation experiment, where high infectious sporidial dosage resulted in higher infections success than did low dosage. We therefore predict that sexual recombination can provide this pathogen with novel genotypes able to infect local resistant hosts.     

Ustilago maydisMating Hyphae Orient Their Growth toward Pheromone Sources

Snetselaar, K. M., Bölker, M., and Kahmann, R. 1996.Ustilago maydismating hyphae orient their growth toward pheromone sources.Fungal Genetics and Biology20,299–312. When small drops ofUstilago maydissporidia were placed 100–200 μm apart on agar surfaces and covered with paraffin oil, sporidia from one drop formed thin hyphae that grew in a zig-zag fashion toward the other drop if it contained sporidia making the appropriate pheromone. For example,a2b2mating hyphae grew towarda1b1anda1b2mating hyphae, and the filaments eventually fused tip to tip. Time-lapse photography indicated that the mating hyphae can rapidly change orientation in response to nearby compatible sporidia. When exposed to pheromone produced by cells in an adjacent drop, haploid sporidia with thea2allele began elongating before sporidia with thea1allele. Sporidia without functional pheromone genes responded to pheromone although they did not induce a response, and sporidia without pheromone receptors induced formation of mating hyphae although they did not form mating hyphae. Diploid sporidia heterozygous atbbut not ataformed straight, rigid, aerial filaments when exposed to pheromone produced by the appropriate haploid sporidia. Again, thea2a2b1b2strain formed filaments more quickly than thea1a1b1b2strain. Taken together, these results suggest that thea2pheromone diffuses less readily or is degraded more quickly than thea1pheromone.     

Pheromones trigger filamentous growth in Ustilago maydis.

Cell recognition and mating in the smut fungus Ustilago maydis have been proposed to involve specific pheromones and pheromone receptors. The respective structural genes are located in the a mating type locus that exists in the alleles a1 and a2. We demonstrate that binding of pheromone to the receptor can induce a morphological switch from yeast-like to filamentous growth in certain strains. Using this as biological assay we were able to purify both the a1 and a2 pheromone. The structure of the secreted pheromones was determined to be 13 amino acids for a1 and nine amino acids for a2. Both pheromones are post-translationally modified by farnesylation and carboxyl methyl esterification of the C-terminal cysteine. An unmodified a1 peptide exhibits dramatically reduced activity. The pheromone alone is able to induce characteristic conjugation tubes in cells of opposite mating type and confers mating competence; even cells of the same mating type undergo fusion. We discuss the role of pheromones in initiating filamentous growth and pathogenic development.     

The Pheromone Cell Signaling Components of the Ustilago a Mating-Type Loci Determine Intercompatibility between Species

The MAT region of Ustilago hordei, a bipolar barley pathogen, harbors distinct mating functions (a and b loci). Here, we show that the b locus is essential for mating and pathogenicity, and can induce pathogenicity when introduced into a strain carrying a b locus of opposite specificity. Transformation experiments using components of the a1 locus and analysis of resulting dual mating phenotypes revealed that this locus harbors a pheromone receptor gene (Uhpra1) and a pheromone gene (Uhmfa1). These U. hordei a1 genes, when introduced by transformation, are necessary and sufficient to make U. maydis, a tetrapolar corn pathogen, intercompatible with U. hordei MAT-2, but not MAT-1, strains. U. hordei strains transformed with the U. maydis a1 locus also become intercompatible with U. maydis a2, but not a1, strains. The interspecies hybrids produced dikaryotic hyphae but were not fully virulent on either corn or barley. Partial, natural intercompatibility was shown to exist between the sugarcane smut U. scitaminea and both U. hordei and U. maydis. These results show that the signal transduction pathway for mating responses is conserved between different smut species. We conclude that, apart from intraspecies compatibility, the Ustilago a locus also dictates intercompatibility in this group of fungi.     

Pep1, a Secreted Effector Protein of Ustilago maydis,Is Required for Successful Invasion of Plant Cells

The basidiomycete Ustilago maydis causes smut disease in maize. Colonization of the host plant is initiated by direct penetration of cuticle and cell wall of maize epidermis cells. The invading hyphae are surrounded by the plant plasma membrane and proliferate within the plant tissue. We identified a novel secreted protein, termed Pep1, that is essential for penetration. Disruption mutants of pep1 are not affected in saprophytic growth and develop normal infection structures. However, Δpep1 mutants arrest during penetration of the epidermal cell and elicit a strong plant defense response. Using Affymetrix maize arrays, we identified 116 plant genes which are differentially regulated in Δpep1 compared to wild type infections. Most of these genes are related to plant defense. By in vivo immunolocalization, live-cell imaging and plasmolysis approaches, we detected Pep1 in the apoplastic space as well as its accumulation at sites of cell-to-cell passages. Site-directed mutagenesis identified two of the four cysteine residues in Pep1 as essential for function, suggesting that the formation of disulfide bridges is crucial for proper protein folding. The barley covered smut fungus Ustilago hordei contains an ortholog of pep1 which is needed for penetration of barley and which is able to complement the U. maydis Δpep1 mutant. Based on these results, we conclude that Pep1 has a conserved function essential for establishing compatibility that is not restricted to the U. maydis / maize interaction.     

Role for RNA-binding proteins implicated in pathogenic development of Ustilago maydis

Ustilago maydis causes smut disease on corn. Successful infection depends on a number of morphological transitions, such as pheromone-dependent formation of conjugation tubes and the switch to filamentous dikaryotic growth, as well as different types of mycelial structures during growth within the host plant. In order to address the involvement of RNA-binding proteins during this developmental program, we identified 27 open reading frames from the genome sequence encoding potential RNA-binding proteins. They exhibit similarities to RNA-binding proteins with Pumilio homology domains (PUM), the K homology domain (KHD), the double-stranded RNA binding motif (DSRM), and the RNA recognition motif (RRM). For 18 of these genes, we generated replacement mutants in compatible haploid strains. Through analysis of growth behavior, morphology, cyclic AMP response, mating, and pathogenicity, we identified three candidates with aberrant phenotypes. Loss of Khd1, a K homology protein containing three KHDs, resulted in a cold-sensitive growth phenotype. Deletion of khd4 encoding a protein with five KHDs led to abnormal cell morphology, reduced mating, and virulence. rrm4Delta strains were affected in filamentous growth and pathogenicity. Rrm4 is an RRM protein with a so far unique domain organization consisting of three N-terminal RRMs as well as a domain found in the C terminus of poly(A)-binding proteins. These results indicate a role for RNA-binding proteins in regulation of morphology as well as in pathogenic development in U. maydis.     

Ustilago maydis Mating Hyphae Orient Their Growth toward Pheromone Sources

Snetselaar, K. M., Bolker, M., and Kahmann, R. 1996. Ustilago maydis mating hyphae orient their growth toward pheromone sources. Fungal Genetics and Biology 20, 299-312. When small drops of Ustilago maydis sporidia were placed 100-200 μm apart on agar surfaces and covered with paraffin oil, sporidia from one drop formed thin hyphae that grew in a zig-zag fashion toward the other drop if it contained sporidia making the appropriate pheromone. For example, a2b2 mating hyphae grew toward a1b1 and a1b2 mating hyphae, and the filaments eventually fused tip to tip. Time-lapse photography indicated that the mating hyphae can rapidly change orientation in response to nearby compatible sporidia. When exposed to pheromone produced by cells in an adjacent drop, haploid sporidia with the a2 allele began elongating before sporidia with the a1 allele. Sporidia without functional pheromone genes responded to pheromone although they did not induce a response, and sporidia without pheromone receptors induced formation of mating hyphae although they did not form mating hyphae. Diploid sporidia heterozygous at b but not at a formed straight, rigid, aerial filaments when exposed to pheromone produced by the appropriate haploid sporidia. Again, the a2a2b1b2 strain formed filaments more quickly than the a1a1b1b2 strain. Taken together, these results suggest that the a2 pheromone diffuses less readily or is degraded more quickly than the a1 pheromone.     

Sexual conjugation in yeast. Cell surface changes in response to the action of mating hormones

In the yeast Saccharomyces cerevisiae, sexual conjugation between haploid cells of opposite mating type results in the formation of a diploid zygote. When treated with fluorescently labeled concanavalin A, a zygote stains nonuniformly, with the greatest fluorescence occurring at the conjugation bridge between the two haploid parents. In the mating mixture, unconjugated haploid cells often elongate to pear-shaped forms ("shmoos") which likewise exhibit asymmetric staining with the most intense fluorescence at the growing end. Shmoo formation can be induced in cells of one mating type by the addition of a hormone secreted by cells of the opposite mating type; such shmoos also stain asymmetrically. In nearly all cases, the nonmating mutants that were examined stained uniformly after incubation with the appropriate hormone. Asymmetric staining is not observed with vegetative cells, even those that are budded. These results suggest that, before and during conjugation, localized cell surface changes occur in cells of both mating types; the surface alterations facilitate fusion and are apparently mediated by the hormones in a manner that is mating-type specific.     

Structural requirements for activity of the pheromones of Ustilago hordei

Ustilago hordei, the cause of barley-covered smut, initiates mating with pheromones. Gene sequence analysis suggested that these pheromones, Uhmfa1 and Uhmfa2, would be farnesylated peptides. Although isolation of mating-type-specific activity was rarely possible, chromatographic separations of culture supernatants yielded fractions that stimulated or inhibited mating. Based on predicted amino acid sequences and mass spectra of stimulating fractions, a series of pheromone analogs were synthesized and their activities were determined. Underivatized Uhmfa1 (PGKSGSGLGYSTC) or Uhmfa2 (EGKGEPAPYC) peptides were inactive, while peptides that were farnesylated and/or methyl esterified specifically induced conjugation tubes by cells of the opposite mating type. Uhmfa1 truncated from the amino terminus beyond the lysine lost activity, while truncated Uhmfa2 remained partially active. In mating bioassays, a pheromone concentration-dependent default mating response was observed. In competition studies, shorter Uhmfa1 peptides lacking pheromone activity inhibited activity of full-length peptides most effectively when both had the same functional groups.     

Ultrastructure of primary sporidia of a wheat-bunt fungus,Tilletia caries,during ontogeny and mating

Summary Primary sporidia ofTilletia caries (DC.) Tul. are borne on denticles at the tips of promycelia. The promycelia contain many small vacuoles and mitochondria and numerous lipid bodies. As the primary sporidia develop, the promycelial cytoplasm passes into the nascent cells. Septa develop between the bases of mature sporidia and the tips of the denticles. Sporidia that abscise from the denticles commonly have prominent birth scars at their bases. The sporidia have very thin walls, few vacuoles, attenuated mitochondria, and numerous lipid bodies. Conjugation pegs are generally produced by both members of a conjugating pair of sporidia and there are bud scars where they emerge from the sporidia. The sporidial walls are apparently hydrolyzed during emergence of the pegs. Vesicles are sometimes present at the tips of the conjugation pegs and, before fusion, electron-dense accumulations are sometimes observed between the tips of adjacent pegs. The approaching conjugation pegs are precisely aligned prior to fusion, suggesting polar communication. The walls of the conjugation pegs fuse and then are hydrolyzed. Fused sporidia are relatively homogeneous in content. The nucleus in a sporidum is often close to the conjugation tube and occasionally is partly within the fusion tube.Cooperative investigations of the Oregon Agricultural Experiment Station, Brigham Young University, and Science and Education Administration-Agricultural Research, U.S. Department of Agriculture. Technical Paper No. 4,934 of the Oregon Agricultural Experiment Station. Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products that may be suitable.     

The life cycle of the smut fungus Moesziomyces penicillariae is adapted to the short-cycle of the host, Pennisetum glaucum

Moesziomyces penicillariae (Brefield) Vànky is a basidiomycete fungus responsible for smut disease on pearl millet, an important staple food in the sub-Sahelian zone. We revisited the life cycle of this fungus. Unlike other Ustilaginales, mating of sporidia was never observed and monoclonal cultures of monokaryotic sporidia were infectious in the absence of mating with compatible partner. These data argued for an atypical monokaryotic diploid cell cycle of M. penicillariae, where teliospores only form solopathogenic sporidia. After inoculation of monoclonal solopathogenic strains on spikelets, the fungus infects the ovaries and induces the folding of the micropilar lips, as observed during early pollination steps. The infected embryo then becomes disorganized and the fungus invades peripheral ovary tissues before sporulating. We evaluated the systemic growth abilities of the fungus. After root inoculation, mycelium was observed around and inside the roots. As argued by transmission electron microscopy (TEM) observations and polymerase chain reaction (PCR) detection using specific primers for M. penicillariae, the fungus can grow from roots to the caulinar meristems. In spite of this systemic growth, no sori were formed on the varieties of pearl millet tested after root inoculation. All together, these data suggest that the reduced life cycle of M. penicillariae – i.e. dispersal of ‘ready to infect’ solopathogenic sporidia, floral infection – is an adaptation to the aetiology of this disease to short-cycle pearl millet varieties from the sub-Sahel.     

Sorosporium consanguineum: Relation between variable nuclear condition and dissociation

Saprophytic development of Sorosporium consanguineum and its nuclear cycle were studied on laboratory media. During vegetative reproduction, the nuclei of the monokaryotic sporidia were shown to first migrate into developing bud cells where division occurs, one nucleus returning to the parent cell prior to completion of cell division. Following fusion of sporidia of opposite mating type and subsequent formation of infection hyphae, dikaryons eventually dissociated, giving rise to sporidia of both sex groups in the process. As a result of dissociation, shown to occur in several ways, "satellite" sporidial colonies characteristically formed in advance of the parent colony and fusions again occurred between sporidia of opposite mating type. Reports of variable nuclear condition of mycelia in other species of smut fungi in culture are discussed in light of these findings.     

A Simplified and efficient method for transformation and gene tagging of Ustilago maydis using frozen cells

Ustilago maydis is an important model fungal organism for diverse studies. Little improvement has been made in the method for its transformation since the PEG-mediated transfection of spheroplasts that was reported more than 20 years ago. We have constructed binary T-DNA vectors carrying Hygromycin and Nourseothricin resistance gene cassettes and have developed a highly efficient method for transformation of this fungus based on Agrobacterium tumefaciens-mediated transformation (ATMT). Through a series of optimization, at least 1 × 10⁴ Hygromycin B resistant colony forming units (CFU) have been achieved on each 90 mm agar plate using 10⁶ sporidia. Optimal pH value for ATMT is approximately 5.6. Approximately 96% Hygromycin B-resistant transformants contain a single-copy T-DNA inserted into the nuclear genome. Analysis of 204 T-DNA flanking sequences showed that 15.2% of them were found in the coding sequences and a further 37.25% within 0.5 kb from the coding sequences at the 5′ UTR or promoter regions. In addition, a method for preparation and preservation of transformation-ready T-DNA donor and receptor cells has been developed allowing gene tagging experiments to be performed on-demand. An initial screening of 5000 mutants resulted in the identification of a putative farnesyl transferase beta subunit and a PRE6 homologue as new players of sexual mating in U. maydis.     

Fuz1, a MYND domain protein, is required for cell morphogenesis in Ustilago maydis

Abstract: Ustilago maydis is a Basidiomycete fungus that exhibits a yeast-like nonpathogenic form and a dikaryotic filamentous pathogenic form. Generation of these two forms is controlled by two mating type loci, a and b. The fungus undergoes additional morphological transitions in the plant that result in formation of a third cell type, the teliospore. The fuz1 gene is necessary for this developmental program. Here we report cloning and sequencing of fuz1 and show that it contains an open reading frame with coding capacity for a protein of 1421 amino acids. The Fuz1 protein belongs to the family of MYND Zn finger domain proteins. We generate a null mutation in strains of opposite mating type and show that fuz1 is necessary for conjugation tube formation, a morphological transition that occurs in response to pheromones. We generate fuz1- diploid strains heterozygous at a and b and show that fuz1 is also necessary for postfusion events (maintenance of filamentous growth). We also demonstrate that fuz1 is necessary for cell morphogenesis of the yeast-like cell: normal cell length, location and number of septa, cell separation and constriction of the neck region. Fuz1 is also required for cell wall integrity and to prevent secretion of a dark pigment. We propose that the MYND domain may interact with different proteins to regulate cell morphogenesis.