Identification and structural characterization of a cDNA clone encoding a membrane-bound form of the polypeptide pheromone Er-1 in the ciliate protozoan Euplotes raikovi.

Miceli, Cristina; Terza, Antonietta La; Bradshaw, Ralph A.; Luporini, Pierangelo

doi:10.1073/pnas.89.5.1988

Cited by 55 publications

(44 citation statements)

References 36 publications

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“…This peculiar organization of the E. nobilii pheromone genes probably reflects a conserved inclusion of intron sequences, whose splicing might have a fundamental role in the mechanism of expression of these genes. This hypothesis receives support in particular from previous functional analysis of E. raikovi pheromone genes [26,27], showing that the primary transcripts of these genes undergo intron splicing (at not canonical sites) to generate membranebound pheromone isoforms that cells use as autocrine pheromone receptors [9]. Its assessment, in addition to being crucial to elucidate the mechanism of expression of the E. nobilii pheromone gene family, may also contribute insightful information on the more general problem of the functional organization of the sub-chromosomic, gene-sized macronuclear genomes of the hypotrich ciliates.…”

Section: Discussionsupporting

confidence: 51%

“…As is the case in pheromone genes of other species of Euplotes [14,26,27], these functions are presumably correlated with the inclusion of intron sequences the splicing of which results in the expression of new ORF's and the synthesis of new and functionally diversified pheromone isoforms. This possibility is supported by the common conservation in the 5' regions of, (i) multiple ATG start codons, (ii) A + T rich sequences, and (iii) consensus donor GT (5') and acceptor AG (3') splice-site junctions [28,29].…”

Section: Nucleotide Sequencesmentioning

confidence: 99%

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Characterization of the pheromone gene family of an Antarctic and Arctic protozoan ciliate, Euplotes nobilii

Vallesi¹,

Alimenti²,

Terza³

et al. 2009

Marine Genomics

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Allelic genes encoding water-borne signal proteins (pheromones) were amplified and sequenced from the somatic (macronuclear) sub-chromosomic genome of Antarctic and Arctic strains of the marine ciliate, Euplotes nobilii. Their open reading frames appeared to be specific for polypeptide sequences of 83 to 94 amino acids identifiable with cytoplasmic pheromone precursors (pre-pro-pheromones), requiring two proteolytic steps to remove the pre-and pro-segments and secrete the mature pheromones. Differently from most of the macronuclear genes that have so far been characterized from Euplotes and other hypotrich ciliates, the 5' and 3' non-coding regions of all the seven E. nobilii pheromone genes are much longer than the coding regions (621 to 700 versus 214 to 285 nucleotides), and the 5' regions in particular show nearly identical sequences across the whole set of pheromone genes. These structural peculiarities of the non-coding regions are likely due to the presence of intron sequences and provide presumptive evidence that they are site of basic, conserved activities in the mechanism that regulates the expression of the E. nobilii pheromone genes. AbstractAllelic genes encoding water-borne signal proteins (pheromones) were amplified and sequenced from the somatic (macronuclear) sub-chromosomic genome of Antarctic and Arctic strains of the marine ciliate, Euplotes nobilii. Their open reading frames appeared to be specific for polypeptide sequences of 83 to 94 amino acids identifiable with cytoplasmic pheromone precursors (pre-propheromones), requiring two proteolytic steps to remove the pre-and pro-segments and secrete the mature pheromones. Differently from most of the macronuclear genes that have so far been characterized from Euplotes and other hypotrich ciliates, the 5' and 3' non-coding regions of all the seven E. nobilii pheromone genes are much longer than the coding regions (621 to 700 versus 214 to 285 nucleotides), and the 5' regions in particular show nearly identical sequences across the whole set of pheromone genes. These structural peculiarities of the non-coding regions are likely due to the presence of intron sequences and provide presumptive evidence that they are site of basic, conserved activities in the mechanism that regulates the expression of the E. nobilii pheromone genes.3

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Section: Discussionsupporting

confidence: 51%

Section: Nucleotide Sequencesmentioning

confidence: 99%

Characterization of the pheromone gene family of an Antarctic and Arctic protozoan ciliate, Euplotes nobilii

Vallesi¹,

Alimenti²,

Terza³

et al. 2009

Marine Genomics

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“…In the ciliate Euplotes raikovi, mating pheromones (euplomones) are synthesized constitutively throughout the entire clonal life cycle and in growing cells (Miceli et al, 1989;Luporini et al, 1992;Miceli et al, 1992;Vallesi et al, 1995;Luporini et al, 1995;Ortenzi et al, 2000). The gene encoding each pheromone generates at least two distinct molecules by alternative splicing, one of which is the soluble pheromone and the other a membrane-bound pheromone isoform.…”

Section: Discussionmentioning

confidence: 99%

Developmentally and environmentally regulated expression of gamone 1: the trigger molecule for sexual reproduction inBlepharisma japonicum

Sugiura

Kawahara

Iio

et al. 2005

Journal of Cell Science

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Sexual reproduction (conjugation) in protozoan ciliates is induced by specific cell-cell interactions between cells of complementary mating types. The ancestral ciliate Blepharisma japonicum has two mating types, I and II. The substances that act as signaling molecules in this extracellular interaction for conjugation are called gamones. The glycoprotein gamone 1, produced by mating type I cells, is a key factor that triggers this interaction. We have previously isolated gamone 1 and determined its complete amino acid sequence. To elucidate the mechanism of initiation of conjugation in ciliates, we investigated the transcription of the gamone 1 gene and found that it is controlled by various internal and external factors. The gamone 1 gene transcript appeared specifically when sexually mature mating type I cells were starved. It was not detected in immature cells, mating type II cells or proliferating cells. The level of transcription was markedly increased in type I cells when they were stimulated with gamone 2, which is secreted by type II cells. This is the first report that the transcription of gamone genes in ciliates is strictly regulated by developmental and environmental factors. This study suggests that the onset of transcription of gamone 1 is linked to the switching mechanism that converts mitotically proliferating cells to differentiated preconjugants, the mechanism of differentiation from immature to mature cells in clonal development, and the mechanism that ensures mating type-specific gene silencing.

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“…The second transcript includes the prepropheromone sequence and a novel N-terminal sequence. When its translation product is processed, the entire C-terminal prepropheromone is retained as an extracellular peptide anchored to the cell surface through the "pre" transmembrane segment, and the N terminus is intracellular (13,20). It is this membrane-bound pheromone isoform that cells utilize as a specific pheromone receptor (24).…”

mentioning

confidence: 99%

“…When cells bind a nonself pheromone from another cell type, they temporarily arrest their growth and develop competence for uniting in mating pairs (23). We refer to the response to self pheromones as an autocrine response and the response to nonself pheromones as a paracrine response.The field addressing the issue of how cells can discriminate between autocrine and paracrine pheromone binding and accordingly mount a growth or mating response was advanced by the identification of the pheromone receptors as part of a study of pheromone gene structure and expression (20). These genes, which are transcriptionally active in thousands of copies in the somatic cell macronucleus (15), generate primary transcripts that undergo a process of alternative splicing that creates two closely related transcripts, one of which codes for the prepropheromone.…”

mentioning

confidence: 99%

Autocrine, Mitogenic Pheromone Receptor Loop of the Ciliate Euplotes raikovi : Pheromone-Induced Receptor Internalization

et al. 2005

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The ciliate Euplotes raikovi produces a family of diffusible signal proteins (pheromones) that function as prototypic growth factors. They may either promote cell growth, by binding to pheromone receptors synthesized by the same cells from which they are secreted (autocrine activity), or induce a temporary cell shift from the growth stage to a mating (sexual) one by binding to pheromone receptors of other, conspecific cells (paracrine activity). In cells constitutively secreting the pheromone Er-1, it was first observed that the expression of the Er-1 receptor "p15," a type II membrane protein of 130 amino acids, is quantitatively correlated with the extracellular concentration of secreted pheromone. p15 expression on the cell surface rapidly and markedly increased after the removal of secreted Er-1 and gradually decreased in parallel with new Er-1 secretion. It was then shown that p15 is internalized through endocytic vesicles following Er-1 binding and that the internalization of p15/Er-1 complexes is specifically blocked by the paracrine p15 binding of Er-2, a pheromone structurally homologous to, and thus capable of fully antagonizing, Er-1. Based on previous findings that the p15 pheromone-binding site is structurally equivalent to Er-1 and that Er-1 molecules polymerize in crystals following a pattern of cooperative interaction, it was proposed that p15/Er-1 complexes are internalized as a consequence of their unique property (not shared by p15/Er-2 complexes) of undergoing clustering.In association with the evolution of systems of multiple cell (mating) types controlling self/nonself recognition phenomena, species of Euplotes synthesize families of structurally homologous soluble proteins that confer on cells a chemical specificity, with each protein representing a diffusible chemical signal (pheromone) that distinguishes one cell type from all the others (17). Euplotes raikovi is the species with which these pheromones, designated Er-1, Er-2, and so forth, have been better characterized with regard to their structure and function. Pheromones are small molecules of 38 to 50 amino acids with a common architecture based on a bundle of three ␣-helices fastened together by three conserved disulfide bonds (16,26,35). They have at least two activities each, acting as both prototypic autocrine growth factors and paracrine mating (sexual) signals (31). Upon binding their own pheromones, which cells constitutively secrete into the extracellular environment throughout the cell cycle, cells grow vegetatively and divide mitotically. When cells bind a nonself pheromone from another cell type, they temporarily arrest their growth and develop competence for uniting in mating pairs (23). We refer to the response to self pheromones as an autocrine response and the response to nonself pheromones as a paracrine response.The field addressing the issue of how cells can discriminate between autocrine and paracrine pheromone binding and accordingly mount a growth or mating response was advanced by the identification of the pher...

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Identification and structural characterization of a cDNA clone encoding a membrane-bound form of the polypeptide pheromone Er-1 in the ciliate protozoan Euplotes raikovi.

Cited by 55 publications

References 36 publications

Characterization of the pheromone gene family of an Antarctic and Arctic protozoan ciliate, Euplotes nobilii

Characterization of the pheromone gene family of an Antarctic and Arctic protozoan ciliate, Euplotes nobilii

Developmentally and environmentally regulated expression of gamone 1: the trigger molecule for sexual reproduction inBlepharisma japonicum

Autocrine, Mitogenic Pheromone Receptor Loop of the Ciliate Euplotes raikovi : Pheromone-Induced Receptor Internalization

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