Isolation of pheromone precursor genes of Magnaporthe grisea.

In heterothallic ascomycetes one mating partner serves as the source of female tissue and is fertilized with spermatia from a partner of the opposite mating type. The role of pheromone signaling in mating is thought to involve recognition of cells of the opposite mating type. We have isolated two putative pheromone precursor genes of Magnaporthe grisea. The genes are present in both mating types of the fungus but they are expressed in a mating type-specific manner. The MF1-1 gene, expressed in Mat1-1 strains, is predicted to encode a 26-amino-acid polypeptide that is processed to produce a lipopeptide pheromone. The MF2-1 gene, expressed in Mat1-2 strains, is predicted to encode a precursor polypeptide that is processed by a Kex2-like protease to yield a pheromone with striking similarity to the predicted pheromone sequence of a close relative, Cryphonectria parasitica. Expression of the M. grisea putative pheromone precursor genes was observed under defined nutritional conditions and in field isolates. This suggests that the requirement for complex media for mating and the poor fertility of field isolates may not be due to limitation of pheromone precursor gene expression. Detection of putative pheromone precursor gene mRNA in conidia suggests that pheromones may be important for the fertility of conidia acting as spermatia.     

The Neurospora crassa pheromone precursor genes are regulated by the mating type locus and the circadian clock

Pheromones play important roles in female and male behaviour in the filamentous ascomycete fungi. To begin to explore the role of pheromones in mating, we have identified the genes encoding the sex pheromones of the heterothallic species Neurospora crassa. One gene, expressed exclusively in mat A strains, encodes a polypeptide containing multiple repeats of a putative pheromone sequence bordered by Kex2 processing sites. Strains of the opposite mating type, mat a, express a pheromone precursor gene whose polypeptide contains a C-terminal CAAX motif predicted to produce a mature pheromone with a C-terminal carboxy-methyl isoprenylated cysteine. The predicted sequences of the pheromones are remarkably similar to those encoded by other filamentous ascomycetes. The expression of the pheromone precursor genes is mating type specific and is under the control of the mating type locus. Furthermore, the genes are highly expressed in conidia and under conditions that favour sexual development. Both pheromone precursor genes are also regulated by the endogenous circadian clock in a time-of-day-specific fashion, supporting a role for the clock in mating.     

Role of the Mf1-1 pheromone precursor gene of the filamentous ascomycete Cryphonectria parasitica

Site-directed recombination was used to obtain a Cryphonectria parasitica strain carrying deletions at the Mf1-1 gene locus. Macroscopic features such as growth rate and conidia production were unaffected by Mf1-1 deletions, but, when a strain containing a complete deletion of Mf1-1 was used as spermatia it was male sterile. The same strain was fully competent as a female parent. Deletion of three of the seven putative pheromone peptide repeats within the gene had no effect on mating. Male fertility of the complete deletion strain was restored when an ectopic copy of the Mf1-1 gene was returned by transformation. Expression of the mating type specific pheromone precursor gene Mf1-1 was stimulated by growth in nutritionally poor liquid media. It was found that age and source of inoculum of liquid cultures influences pheromone precusor gene expression, i.e., conidia did not express Mf1-1 and cultures derived from conidia were significantly delayed in expression of this gene, as were cultures derived from young mycelium. Cultures inoculated with older hyphae, however, expressed Mf1-1 within 1 day after inoculation.     

A putative pheromone signaling pathway is dispensable for self-fertility in the homothallic ascomycete Gibberella zeae

Gibberella zeae, a homothallic ascomycetous fungus, does not seek a partner for mating. Here, we focused on the role(s) of putative pheromone and receptor genes during sexual development in G. zeae. Orthologs of two pheromone precursor genes (GzPPG1 and GzPPG2), and their cognate receptor genes (GzPRE2 and GzPRE1) were transcribed during sexual development. The expression of these genes was controlled by the mating-type (MAT) locus and a MAP kinase gene, but not in a MAT-specific manner. Targeted gene deletion and subsequent outcrosses generated G. zeae strains lacking these putative pheromone/receptor genes in various combinations (from single to quadruple deletions). All G. zeae deletion strains were similar to the self-fertile progenitor in both male- and female fertility and other traits. Sometimes, the deletions including ΔGzPPG1;ΔGzPRE2 caused increased numbers of immature perithecia. Taken together, it is clear that these putative pheromones/receptors play a non-essential role in the sexual development of G. zeae.     

Expression of A mating type genes of Coprinus cinereus in a heterologous basidiomycete host

The A mating factor of Coprinus cinereus determines compatibility in mating by regulating part of a developmental sequence that leads to dikaryon formation. The A genes that trigger development encode two different classes of homeodomain proteins, and for a successful mating, a protein of one class, HD 1, must interact with a protein of the other class, HD 2. In this report we show that C. cinereus A genes that encode HD 2 proteins, a2-1 and b2-1, can elicit A-regulated development in the heterologous host C. bilanatus. Transformation rates were very low, suggesting that the genes were poorly transcribed. The fact that the HD 2 genes are functionally expressed implies successful heteromultimeric association of putative DNA-binding proteins coded by the two Coprinus species. This interaction was sufficient to satisfy the need for different A factors in the formation of a fertile C. bilanatus dikaryon, but fertile dikaryons were more readily produced in matings with the a2-1 gene transformants. The C. cinereus A genes, b1-1 and d1-1, which encode HD1 proteins, were either not expressed or their proteins were non-functional in C. bilanatus. These experiments raise some interesting questions regarding HD1–HD2 protein interactions.     

Mating type‐dependent partner sensing as mediated by VEL1 in Trichoderma reesei

Sexual development in the filamentous model ascomycete Trichoderma reesei (syn. Hypocrea jecorina) was described only a few years ago. In this study, we show a novel role for VELVET in fungi, which links light response, development and secondary metabolism. Vel1 is required for mating in darkness, normal growth and conidiation. In light, vel1 was dispensable for male fertility but essential for female fertility in both mating types. VEL1 impacted regulation of the pheromone system (hpr1, hpr2, hpp1, ppg1) in a mating type‐dependent manner and depending on the mating partner of a given strain. These partner effects only occurred for hpp1 and hpr2, the pheromone precursor and receptor genes associated with the MAT1‐2 mating type and for the mating type gene mat1‐2‐1. Analysis of secondary metabolite patterns secreted by wild type and mutants under asexual and sexual conditions revealed that even in the wild type, the patterns change upon encounter of a mating partner, with again distinct differences for wild type and vel1 mutants. Hence, T. reesei applies a language of pheromones and secondary metabolites to communicate with mating partners and that this communication is at least in part mediated by VEL1.     

Isolation of the Mating-Type Genes of the Phytopathogenic Fungus Magnaporthe Grisea Using Genomic Subtraction

Using genomic subtraction, we isolated the mating-type genes (Mat1-1 and Mat1-2) of the rice blast fungus, Magnaporthe grisea. Transformation of M. grisea strains of one mating type with a linearized cosmid clone carrying the opposite mating-type gene resulted in many ``dual maters,' strains that contain both mating-type genes and successfully mate with both Mat1-1 and Mat1-2 testers. Dual maters differed in the frequency of production of perithecia in pure culture. Ascospores isolated from these homothallic crosses were either Mat1-1 or Mat1-2, but there were no dual maters. Most conidia from dual maters also had one or the other of the mating-type genes, but not both. Thus, dual maters appear to lose one of the mating-type genes during vegetative growth. The incidence of self-mating in dual maters appears to depend on the co-occurrence of strains with each mating type in vegetative cultures. In rare transformants, the incoming sequences had replaced the resident mating-type gene. Nearly isogenic pairs produced from three M. grisea laboratory strains were mated to investigate their fertility. One transformant with switched mating type appears to have a mutation that impairs the development of asci when its mating partner has a similar genetic background. The M. grisea Mat1-1 and Mat1-2 genes are idiomorphs approximately 2.5 and 3.5 kb in length, respectively.     

Microarray and real-time PCR analyses reveal mating type-dependent gene expression in a homothallic fungus

Sordaria macrospora is a homothallic ascomycete which is able to form fertile fruiting bodies without a mating partner. To analyze the molecular basis of homothallism and the role of mating products during fruiting body development, we have deleted the mating type gene Smta-1 encoding a high-mobility group domain (HMG) protein. The ΔSmta-1 deletion strain is morphologically wild type during vegetative growth, but it is unable to produce perithecia or ascospores. To identify genes expressed under control of Smta-1, we performed a cross-species microarray analysis using Neurospora crassa cDNA microarrays hybridized with S. macrospora targets. We identified 107 genes that are more than twofold up- or down-regulated in the mutant. Functional classification revealed that 81 genes have homologues with known or putative functions. Comparison of array data from ΔSmta-1 with those from three phenotypically similar mutants revealed that only a limited set of ten genes is deregulated in all mutants. Remarkably, the ppg2 gene encoding a putative lipopeptide pheromone is 500-fold down-regulated in the ΔSmta-1 mutant while in all other sterile mutants this gene is up-regulated. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

(−) Mating Type-Specific Mutants ofPhycomycesDefective in Sex Pheromone Biosynthesis

Sutter, R. P., Grandin, A. B., Dye, B. D., and Moore, W. R. 1996. (−) Mating type-specific mutants ofPhycomycesdefective in sex pheromone biosynthesis.Fungal Genetics and Biology20,268–279. We have isolated the first mating type-specific mutants in mucoraceous fungi. Both mutants inPhycomyces blakesleeanusappear to be defective in the same gene. The gene, present in both mating types, is necessary only in cultures of the (−) mating type. The gene codes for an enzyme in sex pheromone biosynthesis. The pheromone precursor made by the mutants is detectable only in cross-feeding experiments. The biological and solubility properties of the precursor suggest the precursor is 4-dihydrotrisporin, a metabolite of β-carotene. Separate studies with β-carotene-deficient mutants and Compound-P, a new chemically synthesized precursor of the pheromones, imply the constitutive level of enzymes for pheromone biosynthesis inPhycomycesis extremely low. In comparison, the level of enzymes for pheromone conversion to trisporic acid is higher. The mating type-specific mutants also catalyze the conversion of (+) pheromone to trisporic acid. This finding was unexpected because literature models predicted this reaction was catalyzed by the same enzyme which catalyzed the conversion of 4-dihydrotrisporin to (−) pheromone—a reaction missing in the (−) mating type-specific mutants. Thus, we propose a revised model for trisporic acid biosynthesis.     

Molecular analysis of the pheromone and pheromone receptor genes of Ustilago hordei

Cell-cell signaling is an integral part of the sexual and disease cycles of the smut fungi, which must mate to be pathogenic. This study reports the cloning and characterization of the pheromone genes Uhmfa1 and Uhmfa2 from MAT-1 and MAT-2 mating types of U. hordei, respectively, and the pheromone receptor gene Uhpra2 from MAT-2 cells. Similar to other fungal pheromone genes, Uhmfa1 and Uhmfa2 encode precursor peptides. Uhpra2 encodes a protein with sequence similarity to the 7-transmembrane class of G-protein coupled receptors. Deletion of Uhmfa1 and Uhpra1, and their subsequent replacement, confirmed the role of these genes in initiation of the sexual cycle. Uhmfa1 and Uhmfa2 were differentially expressed in various cell types and when opposite mating-type cells were grown together. The predicted mature pheromones of each mating type were synthesized, and each specifically induced conjugation tube formation in cells of the opposite mating type.     

Evidence for Gene Duplication and Allelic Codominance (not Hierarchical Dominance) at the Mating‐Type Locus of the Ciliate,Euplotes crassus

The high‐multiple mating system of Euplotes crassus is known to be controlled by multiple alleles segregating at a single locus and manifesting relationships of hierarchical dominance, so that heterozygous cells would produce a single mating‐type substance (pheromone). In strain L‐2D, now known to be homozygous at the mating‐type locus, we previously identified two pheromones (Ec‐α and Ec‐1) characterized by significant variations in their amino acid sequences and structure of their macronuclear coding genes. In this study, pheromones and macronuclear coding genes have been analyzed in strain POR‐73 characterized by a heterozygous genotype and strong mating compatibility with L‐2D strain. It was found that POR‐73 cells contain three distinct pheromone coding genes and, accordingly, secrete three distinct pheromones. One pheromone revealed structural identity in amino acid sequence and macronuclear coding gene to the Ec‐α pheromone of L‐2D cells. The other two pheromones were shown to be new and were designated Ec‐2 and Ec‐3 to denote their structural homology with the Ec‐1 pheromone of L‐2D cells. We interpreted these results as evidence of a phenomenon of gene duplication at the E. crassus mating‐type locus, and lack of hierarchical dominance in the expression of the macronuclear pheromone genes in cells with heterozygous genotypes.     

Overexpression of fIbA, an early regulator of Aspergillus asexual sporulation, leads to activation of brIA and premature initiation of development

Aspergillus nidulans reproduces asexually by forming thousands of mitotically derived spores atop highly specialized multicellular organs termed conidiophores. We have identified a gene called flbA (for fluffy low brlA expression) that is required for initiation of A. nidulans conidiophore development. flbA mutants form abnormal colonies that have a distinct fluffy phenotype characterized by tightly interwoven aerial hyphae that autolyse as the colony matures. The requirement for fIbA in conidiophore development precedes activation of brlA, a primary regulator of conidiophore development. The wild-type flbA gene was isolated and found to encode a 3.0 kb mRNA that is expressed throughout the A. nidulans asexual life cycle. Overexpression of fIbA using an Inducible promoter resulted in misscheduled expression of brlA in vegetative ceils and caused hyphal tips to differentiate into spore-producing structures. Sequence analysis of a nearly full-length fIbA cDNA clone showed that fibA is predicted to encode a 717-amino-acid polypeptide with 30% identity to the Saccharomyces cerevisiae SST2 protein. SST2 is required by yeast cells for resuming growth following prolonged exposure to yeast mating pheromone and for mating partner discrimination. We propose that fIbA plays a related role in a signalling pathway for Aspergillus conidiophore development.     

香菇B交配型位点的分子遗传学结构研究II.一个香菇单核体的B位点结构的分子解析

在先前的工作中,曾经运用简并PCR和染色体步行的方法从香菇中获得了1个信息素受体编码基因和1个信息素前体编码基因。根据香菇135菌株的原生质体单核体的全基因组测序信息,设计了4对引物,用于扩增香菇苏香菌株的原生质体单核体SUP2中的信息素受体编码基因STE-3的同源物及其侧翼保守基因。实验结果共获得了33,655bp的DNA序列,运用BlastX搜索对所获得的序列进行同源性分析后,发现了7个推定基因,其中有3个为信息素受体编码基因。再根据信息素前体所具有的保守基序特征,在2个信息素受体编码基因附近发现了4个信息素前体编码基因。首次对香菇的B交配型位点的分子遗传学结构有了比较全面的了解。     

Genetic Analysis of Plasmid-specific Pheromone Signaling Encoded by pPD1 in Enterococcus faecalis

Certain plasmids in Enterococcus faecalis encode a mating response to recipient-produced peptide sex pheromones. Targeted disruption of tra genes on pPD1 suggested that TraA plays a central role in the plasmid-specific pheromone signaling pathway. TraA functioned as a negative regulator for the pheromone-inducible conjugal transfer. Complementation analysis of pPD1 tra gene mutants by pAD1 suggested that the pheromone binding function of TraC was non-specific between these plasmids, but the function of TraA and the pheromone shutdown function of TraB are plasmid-specific.     

Identification of Differentially Expressed Genes in the Pheromone Glands of Mated and Virgin Bombyx mori by Digital Gene Expression Profiling

Background

Mating decreases female receptivity and terminates sex pheromone production in moths. Although significant progress has been made in elucidating the mating-regulated inactivation of pheromone biosynthesis-activating neuropeptide (PBAN) secretion, little is known about the mating induced gene expression profiles in pheromone glands (PGs). In this study, the associated genes involved in Bombyx mori mating were identified through digital gene expression (DGE) profiling and subsequent RNA interference (RNAi) to elucidate the molecular mechanisms underlying the mating-regulated gene expression in PGs.

Results

Eight DGE libraries were constructed from the PGs of mated and virgin females: 1 h mating (M1)/virgin (V1) PGs, 3 h mating (M3)/virgin (V3) PGs, 24 h mating (M24)/virgin (V24) PGs and 48 h mating (M48)/virgin (V48) PGs (M48 and V48). These libraries were used to investigate the gene expression profiles affected by mating. DGE profiling revealed a series of genes showing differential expression in each set of mated and virgin female samples, including immune-associated genes, sex pheromone synthesis-associated genes, juvenile hormone (JH) signal-associated genes, etc. Most interestingly, JH signal was found to be activated by mating. Application of the JH mimics, methoprene to the newly-emerged virgin females leaded to the significant reduction of sex pheromone production. RNAi-mediated knockdown of putative JH receptor gene, Methoprene tolerant 1 (Met1), in female pupa resulted in a significant decrease in sex pheromone production in mature females, suggesting the importance of JH in sex pheromone synthesis.

Conclusion

A series of differentially expressed genes in PGs in response to mating was identified. This study improves our understanding of the role of JH signaling on the mating-elicited termination of sex pheromone production.     

A constitutively active GPCR governs morphogenic transitions in Cryptococcus neoformans

Sex in fungi is driven by peptide pheromones sensed through seven‐transmembrane pheromone receptors. In Cryptococcus neoformans, sexual reproduction occurs through an outcrossing/heterothallic a ‐ sexual cycle or an inbreeding/homothallic – unisexual mating process. Pheromone receptors encoded by the mating‐type locus ( MAT ) mediate reciprocal pheromone sensing during opposite‐sex mating and contribute to but are not essential for unisexual mating. A pheromone receptor‐like gene, CPR2 , was discovered that is not encoded by MAT and whose expression is induced during a ‐ mating. cpr2 mutants are fertile but have a fusion defect and produce abnormal hyphal structures, whereas CPR2 overexpression elicits unisexual reproduction. When heterologously expressed in Saccharomyces cerevisiae , Cpr2 activates pheromone responses in the absence of any ligand. This constitutive activity results from an unconventional residue, Leu²²², in place of a conserved proline in transmembrane domain six; a Cpr2^L222P mutant is no longer constitutively active. Cpr2 engages the same G‐protein activated signalling cascade as the Ste3 a /α pheromone receptors, and thereby competes for pathway activation. This study established a new paradigm in which a naturally occurring constitutively active G protein‐coupled receptor governs morphogenesis in fungi.     

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.     

Expression and function of sex pheromones and receptors in the homothallic ascomycete Gibberella zeae

In heterothallic ascomycete fungi, idiomorphic alleles at the MAT locus control two sex pheromone-receptor pairs that function in the recognition and chemoattraction of strains with opposite mating types. In the ascomycete Gibberella zeae, the MAT locus is rearranged such that both alleles are adjacent on the same chromosome. Strains of G. zeae are self-fertile but can outcross facultatively. Our objective was to determine if pheromones retain a role in sexual reproduction in this homothallic fungus. Putative pheromone precursor genes (ppg1 and ppg2) and their corresponding pheromone receptor genes (pre2 and pre1) were identified in the genomic sequence of G. zeae by sequence similarity and microsynteny with other ascomycetes. ppg1, a homolog of the Saccharomyces alpha-factor pheromone precursor gene, was expressed in germinating conidia and mature ascospores. Expression of ppg2, a homolog of the a-factor pheromone precursor gene, was not detected in any cells. pre2 was expressed in all cells, but pre1 was expressed weakly and only in mature ascospores. ppg1 or pre2 deletion mutations reduced fertility in self-fertilization tests by approximately 50%. Deltappg1 reduced male fertility and Deltapre2 reduced female fertility in outcrossing tests. In contrast, Deltappg2 and Deltapre1 had no discernible effects on sexual function. Deltappg1/Deltappg2 and Deltapre1/Deltapre2 double mutants had the same phenotype as the Deltappg1 and Deltapre2 single mutants. Thus, one of the putative pheromone-receptor pairs (ppg1/pre2) enhances, but is not essential for, selfing and outcrossing in G. zeae whereas no functional role was found for the other pair (ppg2/pre1).