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.     

Mating pheromones of the fission yeast Schizosaccharomyces pombe: purification and structural characterization of M-factor and isolation and analysis of two genes encoding the pheromone.

Conjugation in the fission yeast Schizosaccharomyces pombe is controlled by the action of mating pheromones. Here I describe the isolation and characterization of M-factor, the pheromone released by M-type cells. M-factor is a nanopeptide in which the carboxy-terminal cysteine residue is carboxy-methylated and S-alkylated, probably with a farnesyl residue: Tyr-Thr-Pro-Lys-Val-Pro-Tyr-Met-Cys(S-farnesyl)-OCH3. Evidence for this structure was obtained by amino acid analysis, mass spectrometry and tandem mass spectrometry of the native M-factor. Two genes encoding the M-factor were also identified and characterized. It appears that M-factor is synthesized as a larger precursor which is post-translationally cleaved and modified to yield the active pheromone. The proposed modifications are consistent with mechanisms known to exist in other yeast and higher eukaryotes.     

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.     

Autocrine response of Schizosaccharomyces pombe haploid cells to mating pheromones

Abstract The mating response of the fission yeast Schizosaccharomyces pombe is mediated by mating pheromones, M-factor and P-factor, produced by h⁻ and h⁺ cells, respectively. When the M-factor receptor (Map3) was ectopically expressed in h⁻ cells lacking the P-factor receptor (Mam2), they acquired mating competence in response to M-factor which they secreted. The autocrine response to P-factor in h⁺ cells was so weak that mating competence was not acquired, although expression of the pheromone-responsive gene mat1-Pm was detected. These observations support the notion that the intensity of cellular response to mating pheromones is different between h⁻ and h⁺ cells, although downstream pathways of the pheromone receptors are shared by the two mating types.     

Genes encoding farnesyl cysteine carboxyl methyltransferase in Schizosaccharomyces pombe and Xenopus laevis.

The mam4 mutation of Schizosaccharomyces pombe causes mating deficiency in h- cells but not in h+ cells. h- cells defective in mam4 do not secrete active mating pheromone M-factor. We cloned mam4 by complementation. The mam4 gene encodes a protein of 236 amino acids, with several potential membrane-spanning domains, which is 44% identical with farnesyl cysteine carboxyl methyltransferase encoded by STE14 and required for the modification of a-factor in Saccharomyces cerevisiae. Analysis of membrane fractions revealed that mam4 is responsible for the methyltransferase activity in S. pombe. Cells defective in mam4 produced farnesylated but unmethylated cysteine and small peptides but no intact M-factor. These observations strongly suggest that the mam4 gene product is farnesyl cysteine carboxyl methyltransferase that modifies M-factor. Furthermore, transcomplementation of S. pombe mam4 allowed us to isolate an apparent homolog of mam4 from Xenopus laevis (Xmam4). In addition to its sequence similarity to S. pombe mam4, the product of Xmam4 was shown to have a farnesyl cysteine carboxyl methyltransferase activity in S. pombe cells. The isolation of a vertebrate gene encoding farnesyl cysteine carboxyl methyltransferase opens the way to in-depth studies of the role of methylation in a large body of proteins, including Ras superfamily proteins.     

The sixth transmembrane region of a pheromone G-protein coupled receptor,Map3, is implicated in discrimination of closely related pheromones in Schizosaccharomyces pombe

Most sexually reproducing organisms have the ability to recognize individuals of the same species. In ascomycete fungi including yeasts, mating between cells of opposite mating type depends on the molecular recognition of two peptidyl mating pheromones by their corresponding G-protein coupled receptors (GPCRs). Although such pheromone/receptor systems are likely to function in both mate choice and prezygotic isolation, very few studies have focused on the stringency of pheromone receptors. The fission yeast Schizosaccharomyces pombe has two mating types, Plus (P) and Minus (M). Here, we investigated the stringency of the two GPCRs, Mam2 and Map3, for their respective pheromones, P-factor and M-factor, in fission yeast. First, we switched GPCRs between S. pombe and the closely related species Schizosaccharomyces octosporus, which showed that SoMam2 (Mam2 of S. octosporus) is partially functional in S. pombe, whereas SoMap3 (Map3 of S. octosporus) is not interchangeable. Next, we swapped individual domains of Mam2 and Map3 with the respective domains in SoMam2 and SoMap3, which revealed differences between the receptors both in the intracellular regions that regulate the downstream signaling of pheromones and in the activation by the pheromone. In particular, we demonstrated that two amino acid residues of Map3, F214 and F215, are key residues important for discrimination of closely related M-factors. Thus, the differences in these two GPCRs might reflect the significantly distinct stringency/flexibility of their respective pheromone/receptor systems; nevertheless, species-specific pheromone recognition remains incomplete.     

The Schizosaccharomyces pombe mam1 gene encodes an ABC transporter mediating secretion of M-factor

In the fission yeast Schizosaccharomyces pombe, cells of opposite mating type communicate via diffusible peptide pheromones prior to mating. We have cloned the S. pombe mam1 gene, which encodes a 1336-amino acid protein belonging to the ATP-binding cassette (ABC) superfamily. The mam1 gene is only expressed in M cells and the gene product is responsible for the secretion of the mating pheromone, M-factor, a nonapeptide that is S-farnesylated and carboxy-methylated on its C-terminal cysteine residue. The predicted Mam1 protein is highly homologous to mammalian multiple drug-resistance proteins and to the Saccharomyces cerevisiae STE6 gene product, which mediates export of a-factor mating pheromone. We show that STE6 can also mediate secretion of M-factor in S. pombe.     

Distal and Proximal Actions of Peptide Pheromone M-Factor Control Different Conjugation Steps in Fission Yeast

Mating pheromone signaling is essential for conjugation between haploid cells of P-type (P-cells) and haploid cells of M-type (M-cells) in Schizosaccharomyces pombe. A peptide pheromone, M-factor, produced by M-cells is recognized by the receptor of P-cells. An M-factor-less mutant, in which the M-factor-encoding genes are deleted, is completely sterile. In liquid culture, sexual agglutination was not observed in the mutant, but it could be recovered by adding exogenous synthetic M-factor, which stimulated expression of the P-type-specific cell adhesion protein, Map4. Exogenous M-factor, however, failed to recover the cell fusion defect in the M-factor-less mutant. When M-factor-less cells were added to a mixture of wild-type P- and M-cells, marked cell aggregates were formed. Notably, M-factor-less mutant cells were also incorporated in these aggregates. In this mixed culture, P-cells conjugated preferentially with M-cells secreting M-factor, and rarely with M-factor-less M-cells. The kinetics of mating parameters in liquid culture revealed that polarized growth commenced from the contact region of opposite mating-type cells. Taken together, these findings indicate that M-factor at a low concentration induces adhesin expression, leading to initial cell-cell adhesion in a type of “distal pheromone action”, but M-factor that is secreted directly in the proximity of the adhered P-cells may be necessary for cell fusion in a type of “proximal pheromone action”.     

The Schizosaccharomyces pombe mam1 gene encodes an ABC transporter mediating secretion of M-factor

In the fission yeast Schizosaccharomyces pombe, cells of opposite mating type communicate via diffusible peptide pheromones prior to mating. We have cloned the S. pombe mam1 gene, which encodes a 1336-amino acid protein belonging to the ATP-binding cassette (ABC) superfamily. The mam1 gene is only expressed in M cells and the gene product is responsible for the secretion of the mating pheromone, M-factor, a nonapeptide that is S-farnesylated and carboxy-methylated on its C-terminal cysteine residue. The predicted Mam1 protein is highly homologous to mammalian multiple drug-resistance proteins and to the Saccharomyces cerevisiae STE6 gene product, which mediates export of a-factor mating pheromone. We show that STE6 can also mediate secretion of M-factor in S. pombe. Received: 20 December 1996 / Accepted: 29 January 1997     

Yeast alpha factor is processed from a larger precursor polypeptide: the essential role of a membrane-bound dipeptidyl aminopeptidase

Alpha factor mating pheromone is a peptide of 13 amino acids secreted by Saccharomyces cerevisiae alpha cells. Nonmating ("sterile," or ste) alpha-cell mutants bearing defects in the STE13 gene do not produce normal alpha factor, but release a collection of incompletely processed forms (alpha factor) that have a markedly reduced specific biological activity. The major alpha-factor peptides have the structures H2N-GluAlaGluAla-alpha factor and H2N-AspAlaGluAla-alpha factor. The ste13 mutants lack a membrane-bound heat-stable dipeptidyl aminopeptidase (DPAPase A) that specifically cleaves on the carboxyl side of repeating -X-Ala- sequences. Absence of DPAPase A and the other phenotypes of a ste13 lesion cosegregate in genetic crosses. The cloned STE13 gene on a plasmid causes yeast cells to overproduce DPAPase A severalfold. A different cloned DNA segment, which weakly suppresses the ste13 defects, causes overproduction of a heat-labile activity (DPAPase B) by about tenfold. Other experiments indicate that DPAPase A action may be rate-limiting for alpha-factor maturation in normal alpha cells.     

Purification and characterization of new mating pheromones of the ciliate Euplotes raikovi

Cell union in mating pairs in the ciliate Euplotes raikovi is controlled by a system of multiple mating types which are inherited with alleles codominant at the genetic locus mat and expressed via diffusible mating pheromones. The mating pheromones Er-2, Er-3, and Er-11 were purified from cells homozygous for the mat-2, mat-3, and mat-11 alleles, respectively. These pheromones are proteins of similar Mr (11,000-12,000) and acidity (pI 3.7-4.0) and are active at a concentration that varies from 2.9 X 10(-12) to 1.2 X 10(-11) M. Data on amino acid composition revealed that an unusually high amount of cysteine (12-15.7%) and poor contents of basic amino acids are common to every pheromone. On the basis of this uniformity in the main biochemical traits, which also holds for the previously purified pheromone Er-1, it was concluded that E. raikovi mating pheromones are members of a family of proteins structurally diversified from each other to varying extents.     

Role of metabolism of the mating pheromone in sexual differentiation of the heterobasidiomycete Rhodosporidium toruloides.

A trypsin-type endopeptidase (Kamiya et al., Biochem. Biophys. Res. Commun. 94:855-860, 1980) responsible for the metabolism of rhodotorucine A, the farnesyl undecapeptide mating pheromone secreted by mating type A cells of Rhodosporidium toruloides, was biologically characterized. Metabolic activity was found to be present exclusively on the cell surface of the pheromone target cell. The activity was highly specific to the pheromone, and a biologically inactive analog which has the complete amino acid sequence of rhodotorucine A but lacks the farnesyl residue was not metabolized by intact cells. Pheromone metabolism was inhibited by trypsin substrates such as tosyl-L-arginine methyl ester. The presence of tosyl-L-arginine methyl ester strongly inhibited the sexual differentiation induced by the pheromone at a concentration which did not affect the vegetative growth of R. toruloides. Pheromone-induced sexual differentiation was also strongly inhibited by a metabolizable analog, rhodotorucine A S-oxide, but not by a non-metabolizable one. In mutants defective in early processes of mating, the decrease in the pheromone metabolic activity correlated well with the extent of loss of sensitivity to the pheromone. Both the pheromone metabolism and the capacity for sexual differentiation of a sterile mutant were restored concomitantly with reversion from the sterile to the fertile phenotype. These results suggested that metabolism of the mating pheromone plays an essential role in the process of sexual differentiation in R. toruloides.     

STE16, a New Gene Required for Pheromone Production by a Cells of Saccharomyces cerevisiae

Genes required for mating by a and alpha cells of Saccharomyces cerevisiae (STE, "sterile," genes) encode products such as peptide pheromones, pheromone receptors, and proteins responsible for pheromone processing. a-specific STE genes are those required for mating by a cells but not by alpha cells. To identify new a-specific STE genes, we have employed a novel strategy that enabled us to determine if a ste mutant defective in mating as a is also defective in mating as alpha without the need to do crosses. This technique involved a strain (K12-14b) of genotype mata1 HML alpha HMR alpha sir3ts, which mates as a at 25 degrees and as alpha at 34 degrees. We screened over 40,000 mutagenized colonies derived from K12-14b and obtained 28 a-specific ste mutants. These strains contained mutations in three known a-specific genes--STE2, STE6 and STE14--and in a new gene, STE16. ste16 mutants are defective in the production of the pheromone, a-factor, and exhibit slow growth. Based on the distribution of a-specific ste mutants described here, we infer that we have identified most if not all nonessential genes that can give rise to a-specific mating defects.     

Peptide and protein pheromones in amphibians

Purification, characterization and biological activity of urodele and anuran sex-pheromones were reviewed. Female-attracting pheromones obtained from the abdominal gland of Cynops pyrrhogaster and C. ensicauda males are peptides consisting of 10 amino acid residues being designated sodefrin and silefrin, respectively. Each pheromone attracted only conspecific females. Molecular cloning of cDNAs encoding sodefrin and silefrin revealed that both are generated from precursor proteins. Synthesis of these pheromones is regulated by prolactin (PRL) and androgen. Responsiveness of the female vomeronasal epithelium to sodefrin is enhanced by PRL and estrogen. The submandibular gland of the male terrestrial salamander, Plethodon jardani secretes a 22-kD proteinaceous pheromone that enhances female receptivity. It was revealed that every salamander synthesizes multiple isoforms of this pheromone, Plethodontid receptivity factor. The magnificent tree frog, Litoria splendida breed in an aquatic environment. The skin glands of the male secrete a female-attracting peptide pheromone, splendipherin, comprising 25 amino acid residues. The significance of the structure of the amphibian sex-pheromone as peptide and protein is discussed in terms of their species specificity.     

Structure-function analysis of lipopeptide pheromones from the plant pathogen Ustilago maydis

Mating of two haploid cells is a prerequisite for the successful infection of corn by the pathogenic fungus Ustilago maydis. Cell-cell recognition is mediated by small lipopeptide pheromones. Genes encoding pheromone precursors as well as pheromone receptors are located in the a mating type locus. Two pheromones are known, the tridecapeptide a1 and the nonapeptide a2, both of which contain an S-prenylated cysteine methyl ester at the C-terminus. It has previously been shown that synthetic pheromones are active in a biological test system. Here, we used the same assay to perform a detailed analysis of synthetic a1 and a2 pheromones. Testing of truncated derivatives of a1 and a2 revealed that in both cases the pheromone function is less sensitive to N-terminal than to C-terminal truncations. Replacement of each amino acid in the a1 pheromone by either alanine or the corresponding D-amino acids revealed that four positions are important for function: the two central glycines (positions 5 and 9), proline at position 7 and tyrosine at position 10. By introducing different naturally occurring as well as synthetic amino acids at position 10, we demonstrate that the presence of an aromatic side chain at this position is necessary for function. We propose a model in which a cis peptide bond at proline 7 favours the formation of a type II' beta turn of the a1 pheromone backbone with glycine 9 in position i+1 (where i refers to the first position of the beta turn). As a result, tyrosine 10, at position i+2 of the turn, would be highly exposed and could be inserted into a structurally well-defined binding pocket of the receptor. The latter may represent an important facet of receptor specificity.     

Self-compatible B mutants in coprinus with altered pheromone-receptor specificities

A successful mating in the mushroom Coprinus cinereus brings together a compatible complement of pheromones and G-protein-coupled receptors encoded by multiallelic genes at the B mating-type locus. Rare B gene mutations lead to constitutive activation of B-regulated development without the need for mating. Here we characterize a mutation that arose in the B6 locus and show that it generates a mutant receptor with a single amino acid substitution (R96H) at the intracellular end of transmembrane domain III. Using a heterologous yeast assay and synthetic pheromones we show that the mutation does not make the receptor constitutively active but permits it to respond inappropriately to a normally incompatible pheromone encoded within the same B6 locus. Parallel experiments carried out in Coprinus showed that a F67W substitution in this same pheromone enabled it to activate the normally incompatible wild-type receptor. Together, our experiments show that a single amino acid replacement in either pheromone or receptor can deregulate the specificity of ligand-receptor recognition and confer a self-compatible B phenotype. In addition, we use the yeast assay to demonstrate that different receptors and pheromones found at a single B locus belong to discrete subfamilies within which receptor activation cannot normally occur.     

Role of α-Factor and the Mfα1 α-Factor Precursor in Mating in Yeast

The peptide pheromones secreted by a and α cells (called a-factor and α-factor, respectively) are each encoded by two structural genes. For strains of either mating type, addition of exogenous pheromone does not alleviate the mating defect of mutants with disruptions of both structural genes. In addition, a particular insertion mutation in the major α-factor structural gene (MFα1) that should result in an altered product inhibits α mating. These results suggested that the pheromone precursors (the MFα1 pro region in particular) might play a second role in mating separate from the role of pheromone production. To analyze the role of α-factor and the MFα1 precursor in α mating, we have constructed two classes of mutants. The mating defects of mutants that should produce the MFα1 pro region peptide but no α-factor could not be alleviated by addition of exogenous α-factor in crosses to a wild-type a strain, indicating that the previous results were not due to an inability of the disruption mutants to produce the pro region peptide. Mutants able to produce α-factor, but with a variety of alterations in MFα1 precursor structure, mated at levels proportional to the levels of α-factor produced, suggesting that the only role of the α-factor precursor in mating is to produce α-factor. Both of these results argue against a role for the MFα1 pro region separate from its role in α-factor production. We also describe results that show that in vivo production of α-factor'' (the form of α-factor encoded by one of the two α-factor repeats of MFα2) is equivalent to the major form of α-factor for induction of all responses necessary for mating. We discuss the implications of these results on the role of the pheromones in mating.     

Mutational analysis of HIV-1 Tat minimal domain peptides: identification of trans-dominant mutants that suppress HIV-LTR-driven gene expression

The HIV-1 Tat protein is a potent trans-activator essential for virus replication. We reported previously that HIV-1 Tat peptides containing residues 37-48 (mainly region II), a possible activating region, and residues 49-57 (region III), a nuclear targeting and putative nucleic acid binding region, possess minimal but distinct trans-activator activity. The presence of residues 58-72 (region IV) greatly enhances trans-activation. We postulate that Tat mutant peptides with an inactive region II and a functional region III can behave as dominant negative mutants. We synthesized minimal domain peptides containing single amino substitutions for amino acid residues within region II that are conserved among different HIV isolates. We identify four amino acid residues whose substitution within Tat minimal domain peptides leads to defects in transactivation. Some of these mutants are trans-dominant in several peptide backbones, since they strongly inhibit trans-activation by wild-type Tat protein added to cells or expressed from microinjected plasmid. Significantly, trans-activation of integrated HIV-LTRCAT is blocked by some trans-dominant mutant peptides. These results suggest an attractive approach for the development of an AIDS therapy.