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.     

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.     

Remarkably simple sequence requirement of the M-factor pheromone of Schizosaccharomyces pombe

The mating reaction is triggered by specific pheromones in a wide variety of organisms. Small peptides are used as mating pheromones in yeasts and fungi. In the fission yeast Schizosaccharomyces pombe, M-factor is a C terminally farnesylated nonapeptide secreted from M-cells, and its counterpart, P-factor, is a simple peptide composed of 23 amino acids. The primary structure requirements for the biological activity of pheromone peptides remain to be elucidated. Here, we conducted comprehensive substitution of each of the amino acids in M-factor peptide and inspected the mating ability of these missense mutants. Thirty-five sterile mutants were found among an array of 152 mutants with single amino acid substitutions. Mapping of the mutation sites clearly indicated that the sterile mutants were associated exclusively with four amino acid residues (VPYM) in the carboxyl-terminal half. In contrast, the substitution of four amino-terminal residues (YTPK) with any amino acid had no or only a slightly deleterious effect on mating. Furthermore, deletion of the three N-terminal residues caused no sterility, although truncation of a fourth residue had a marked effect. We conclude that a farnesylated hexapeptide (KVPYMC(Far)-OCH(3)) is the minimal M-factor that retains pheromone activity. At least 15 nonfunctional peptides were found to be secreted, suggesting that these mutant M-factor peptides are no longer recognized by the cognate receptor.     

Specific and Common Epitopes in Mating Pheromones of Euplotes raikovi Revealed by Monoclonal Antibodies

Polypeptide mating pheromones Er-1 and Er-2, purified from the supernatant of Euplotes raikovi cultures of mating type I and mating type II, respectively, were used to immunize mice and obtain monoclonal antibodies. Five hybridoma clones producing antibodies specific to the mating pheromones were selected. They were analyzed for immunospecificity by immunoperoxidase assay, immunoblotting, and for their efficacy in inhibition of mating pheromone activity. Monoclonal antibodies from two hybridoma clones recognized only the mating pheromone used as antigen; those from the other three clones reacted, to comparable extents, with both mating pheromones. On the basis of these results it was assumed that two immunogenic sites exist in Er-1 and Er-2, one specific and the other common to both mating pheromones.     

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.     

Purification, characterization, and amino acid sequence of the mating pheromone Er-10 of the ciliate Euplotes raikovi

The mating pheromone Er-10 from mat-10 homozygous Euplotes raikovi was purified by a three-step purification procedure with an overall yield of 62%. It was identified as a protein of molecular weight 8000 having an isoelectic point of 3.9. Its complete primary structure was determined by automated Edman degradation of the whole protein after performic acid oxidation and of peptides generated by cyanogen bromide and Staphylococcus aureus V8 protease. The proposed sequence is Asp1-Leu-Cys-Glu-Gln-Ser-Ala-Leu-Gln-Cys10-Asn-Glu-Gln-Gly-Cys-His -Asn-Phe-Cys- Ser20-Pro-Glu-Asp-Lys-Pro-Gly-Cys-Leu-Gly-Met30-Val-Trp-Asn- Pro-Glu-Leu-Cys- Pro38. The calculated molecular weight of 4191.7, which is in good agreement with the value of m/z 4190.7 obtained by fission fragment ionization mass spectrometry, suggests that the native structure is a dimer with three intrachain disulfide bonds in each subunit. The amino acid sequence is 43% identical with that of the E. raikovi mating pheromone Er-1, with the identities concentrated in the amino-terminal half. The half-cystine locations are conserved, but Er-10 is two residues shorter than Er-1. Prediction of the secondary structure suggests that Er-10 may also contain a helical structure at the amino terminus. These results indicate that the mating pheromones of E. raikovi form a homologous family.     

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.     

Mating Pheromones of Saccharomyces kluyveri: Pheromone Interactions Between Saccharomyces kluyveri and Saccharomyces cerevisiae

Saccharomyces kluyveri is a heterothallic yeast with two allelic mating types denoted as a-k and alpha-k by analogy with Saccharomyces cerevisiae and from the work described here. S. kluyveri produces mating pheromones analogous to those of S. cerevisiae, but which appear to have different specificity. S. kluyveri thus differs from S. cerevisiae, Hansenula wingei, and Schizosaccharomyces pombe in that it exhibits both strong constitutive agglutination and mating pheromones. alpha-k cells produce a pheromone ("alpha-k-factor") which causes a-k cells to arrest in the G1 phase of the cell cycle and to undergo a morphological change. After a period of time dependent on the concentration of alpha-k-factor, cells exposed to the factor resume cell division. alpha-k-factor has no effect on a-k/alpha-k diploids or on alpha-k cells, but at high concentration does induce G1 arrest of S. cerevisiaea cells (a-c). a-k cells produce a pheromone ("a-k-factor") which causes alpha-k cells to exhibit a morphological change. In addition, a-k cells exhibit the Bar phenotype with respect to alpha-k-factor. Partially purified preparations of S. cerevisiae alpha-factor are more active in inducing G1 arrest of a-k cells than of a-c cells. A more purified preparation of alpha-c-factor is less active against a-k cells than a-c cells, suggesting that an additional factor (KRE, kluyveri response enhancer) may be lost during purification. Attempts to mate S. kluyveri and S. cerevisiae cells by prototroph selection and by cell-to-cell mating have been unsuccessful with all combinations of mating types. Thus, S. cerevisiae and S. kluyveri are incompatible for mating even though their pheromones exhibit some physiological cross-reaction.     

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.     

Specific and common epitopes in mating pheromones of Euplotes raikovi revealed by monoclonal antibodies.

Polypeptide mating pheromones Er-1 and Er-2, purified from the supernatant of Euplotes raikovi cultures of mating type I and mating type II, respectively, were used to immunize mice and obtain monoclonal antibodies. Five hybridoma clones producing antibodies specific to the mating pheromones were selected. They were analyzed for immunospecificity by immunoperoxidase assay, immunoblotting, and for their efficacy in inhibition of mating pheromone activity. Monoclonal antibodies from two hybridoma clones recognized only the mating pheromone used as antigen: those from the other three clones reacted, to comparable extents, with both mating pheromones. On the basis of these results it was assumed that two immunogenic sites exist in Er-1 and Er-2, one specific and the other common to both mating pheromones.     

MID1, a novel Saccharomyces cerevisiae gene encoding a plasma membrane protein,is required for Ca2+ influx and mating.

By establishing a unique screening method, we have isolated yeast mutants that die only after differentiating into cells with a mating projection, and some of them are also defective in Ca2+ signaling. The mutants were classified into five complementation groups, one of which we studied extensively. This mutation defines a new gene, designated MID1, which encodes an N-glycosylated, integral plasma membrane protein with 548 amino acid residues. The mid1-1 mutant has low Ca2+ uptake activity, loses viability after receiving mating pheromones, and escapes death when incubated with high concentrations of CaCl2. The MID1 gene is nonessential for vegetative growth. The efficiency of mating between MATa mid1-1 and MAT alpha mid1-1 cells is low. These results demonstrate that MID1 is required for Ca2+ influx and mating.     

Cell aging-induced methionine oxidation causes an autocrine to paracrine shift of the pheromone activity in the protozoan ciliate, Euplotes raikovi

Ciliates of the genus Euplotes rely on the autocrine (self) and paracrine (non-self) activities of their water-borne protein pheromones to control the two fundamental phenomena of their life cycle, i.e. vegetative (mitotic) growth and sex manifested as cell union in mating pairs. We observed that cell aging determines the synthesis of increasing concentrations of pheromones that are oxidized at the level of methionine residues which are more exposed on the molecular surface. The oxidized form of the E. raikovi pheromone Er-1 was purified and its interactions with its source cells were shown no longer to be of autocrine type directed to promote cell growth, but changed to interactions of the paracrine type directed to induce cell unions in mating pairs of the selfing type (i.e. involving genetically identical cells). These pairs generate viable offspring, like pairs formed between genetically different cells. It was therefore concluded that aging cells may paradoxically gain beneficial effects from the synthesis of oxidized forms of their pheromones. By undergoing mating in response to the interactions with these forms, they can re-initiate a new life cycle and, in fact, rejuvenate.     

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.     

Changes in mate recognition through alterations of pheromones and receptors in the multisexual mushroom fungus Schizophyllum commune

Schizophyllum commune has thousands of mating types defined in part by numerous lipopeptide pheromones and their G-protein-coupled receptors. These molecules are encoded within multiple versions of two redundantly functioning B mating-type loci, B alpha and B beta. Compatible combinations of pheromones and receptors, produced by individuals of different B mating types, trigger a pathway of fertilization required for sexual development. Analysis of the B beta 2 mating-type locus revealed a large cluster of genes encoding a single pheromone receptor and eight different pheromones. Phenotypic effects of mutations within these genes indicated that small changes in both types of molecules could significantly alter their specificity of interaction. For example, a conservative amino acid substitution in a pheromone resulted in a gain of function toward one receptor and a loss of function with another. A two-amino-acid deletion from a receptor precluded the mutant pheromone from activating the mutant receptor, yet this receptor was activated by other pheromones. Sequence comparisons provided clues toward understanding how so many variants of these multigenic loci could have evolved through duplication and mutational divergence. A three-step model for the origin of new variants comparable to those found in nature is presented.     

Crossing the boundary between the Balpha and Bbeta mating-type loci in Schizophyllum commune

In this study, genes of the Schizophyllum commune Balpha and Bbeta mating-type loci are shown to be within a few kilobases of each other. The region between the nearest Balpha and Bbeta genes contains many short direct repeats. Predicted amino acid sequences and activity spectra of three pheromones encoded in the Balpha3 mating-type specificity are presented along with a re-evaluation of pheromone activity of many previously reported S. commune lipopeptide pheromones. This analysis showed that S. commune pheromones belong to five subtypes. Several pheromones activate both a Bbeta receptor and a Balpha receptor, a phenomenon previously unrecognized. Clues from mating tests and DNA hybridization led to the cloning of bar8, the gene encoding the Balpha8 pheromone receptor, Bar8. Bar8 is similar in sequence to Bbr1, the Bbeta1 pheromone receptor, and functionally identical to it. These data begin to elucidate the enigmatic recombination patterns previously encountered at the B mating-type complex.     

Polyisoprenylation of the CAAX motif--an in vitro protein synthesis study

A number of proteins, including most nuclear lamins, certain fungal mating pheromones, G-protein gamma-subunits and ras proteins, contain a C-terminal cysteine-aliphatic-aliphatic-undefined amino acid (CAAX) motif which is thought to be a roughly defined consensus sequence capable of directing a series of posttranslational events, beginning with the addition of a polyisoprene moiety to the cysteine. So far such a motif has been found in every protein known to have this type of modification. We have utilized the rabbit reticulocyte lysate translation system, which is capable of carrying out the polyisoprene modification in vitro, to investigate features of the C-terminal motif which affect its suitability as a substrate. We demonstrate that a cysteine is only isoprenylated when situated at position -4 from the C-terminus. We further show that the presence of a glycine at position -3 or a terminal aromatic residue, features typical of some G-protein alpha subunits, cause a reduction and abolition respectively of isoprenylation.     

Expression profiling reveals differential gene induction underlying specific and non-specific memory for pheromones in mice

Memory for the mating male’s pheromones in female mice is thought to require synaptic changes in the accessory olfactory bulb (AOB). Induction of this memory depends on release of glutamate in response to pheromonal exposure coincident with release of norepinephrine (NE) in the AOB following mating. A similar memory for pheromones can also be induced artificially by local infusion of the GABA_A receptor antagonist bicuculline into the AOB. The natural memory formed by exposure to pheromones during mating is specific to the pheromones sensed by the female during mating. In contrast, the artificial memory induced by bicuculline is non-specific and results in the female mice recognizing all pheromones as if they were from the mating male. Although protein synthesis has been shown to be essential for development of pheromone memory, the gene expression cascades critical for memory formation are not known. We investigated changes in gene expression in the AOB using oligonucleotide microarrays during mating-induced pheromone memory (MIPM) as well as bicuculline-induced pheromone memory (BIPM). We found the set of genes induced during MIPM and BIPM are largely non-overlapping and Ingenuity Pathway Analysis revealed that the signaling pathways in MIPM and BIPM also differ. The products of genes induced during MIPM are associated with synaptic function, indicating the possibility of modification at specific synapses, while those induced during BIPM appear to possess neuron-wide functions, which would be consistent with global cellular changes. Thus, these results begin to provide a mechanistic explanation for specific and non-specific memories induced by pheromones and bicuculline infusion respectively.     

Purification to apparent homogeneity of the mating pheromone of mat-1 homozygous Euplotes raikovi

Mating type-specific mating pheromones autonomously released into the environment control cell-cell union in conjugation of the marine ciliate Euplotes raikovi. The mating pheromone, termed euplomone r-1, of cells of the homozygous mating type determined by the mat-1/mat-1 genotype was purified by means of a three-stage purification procedure which provides a yield of 79%. Starting from 10 liters of supernatant, 3.3 mg of euplomone r-1 were regularly recovered. Euplomone r-1 was identified with a protein showing a molecular weight of 12,000, an isoelectric point of 3.7, and unusually high contents of cysteine (15%) and tyrosine (5.8%). It appeared active at a concentration of 3.4 +/- 0.5 X 10(-12) M. Carbohydrate and a small colored compound, not yet identified, occurred in association with partially purified euplomone r-1 samples, whereas they were not detected in samples of the final product of purification. An acidic shift was apparently capable of destroying the carbohydrate/euplomone r-1 association, suggesting that it does not involve covalent bonds.