The hydroxyproline motif of male sex peptide elicits the innate immune response in Drosophila females.

Seminal fluid elicits a variety of physiological and behavioral changes in insect females. In Drosophila melanogaster females, sex peptide (SP) is the major seminal agent eliciting oviposition and reduction of receptivity. But SP also has many other effects; for example, it stimulates food intake, egg production, ovulation, juvenile hormone production and antimicrobial peptide synthesis. Thus, SP very probably has several receptors. To identify putative targets and signaling cascades, we studied the genome-wide regulation of genes by microarray analysis of RNA isolated from females after mating with wild-type males or males lacking SP, respectively. In addition, we studied the effects of SP on the proteome of females. Sex peptide regulates gene activity differentially in the head and in the abdomen. Genes coding for unspecific antimicrobial peptides are specifically transcribed in the abdomen, e.g. the antimicrobial peptide drosocin in epithelial tissues of the female genital tract (oviduct and calyx). Hence, SP elicits a systemic [Peng J, Zipperlen P & Kubli E (2005) Curr Biol15, 1690-1694] and an epithelial immune response. Ectopic expression of SP in the fat body of transgenic virgin females (with subsequent secretion into the hemolymph) does not elicit drosocin synthesis in the genital tract. Thus, the receptors for the stimulation of the systemic and the epithelial responses by SP are compartmentalized. The hydroxyproline (P*) motif of SP, P*TKFP*IP*SP*NP*, is identified as a novel elicitor of the innate immune response. We suggest that SP acts by chemical mimicry of sugar components of the bacterial cell wall. Thus, SP may induce the immune system via pattern recognition receptors.

Gradual release of sperm bound sex-peptide controls female postmating behavior in Drosophila.

BACKGROUND: In many female insects, peptides transferred in the seminal fluid induce postmating responses (PMR), such as a drastic increase of egg laying and reduction of receptivity (readiness to mate). In Drosophila melanogaster, sex-peptide (SP) elicits short- and long-term PMR, but only the latter in the presence of stored sperm (sperm effect). RESULTS: Here, we elucidate the interaction between SP and sperm by immunofluorescence microscopy. Transgenic males were used to study the effects of SP modification on the PMR of females in vivo. We report that SP binds to sperm with its N-terminal end. In females, the C-terminal part of SP known to be essential to induce the PMR is gradually released from stored sperm by cleavage at a trypsin cleavage site, thus prolonging the PMR. These findings are confirmed by analyzing the PMR elicited by males containing transgenes encoding modified SPs. SP lacking the N-terminal end cannot bind, and SP without the trypsin cleavage site binds permanently to sperm. CONCLUSION: By binding to sperm tails, SP prolongs the PMR. Thus, besides a carrier for genetic information, sperm is also the carrier for SP. Binding to sperm may protect the peptide from degradation by proteases in the hemolymph and, thus, prolong its half-life. Longer sperm tails may transfer more SP and thus increase the reproductive fitness of the male. We suggest that this could explain the excessive length of sperm tails in some Drosophila species.

The sex-peptide DUP99B is expressed in the male ejaculatory duct and in the cardia of both sexes.

Mating elicits two postmating responses in many insect females: the egg laying rate increases and sexual receptivity is reduced. In Drosophila melanogaster, two peptides of the male genital tract, sex-peptide and DUP99B, elicit these postmating responses when injected into virgin females. Here we show that the gene encoding DUP99B is expressed in the male ejaculatory duct and in the cardia of both sexes. The DUP99B that is synthesized in the ejaculatory duct is transferred, during mating, into the female genital tract. Expression of the gene is first seen in a late pupal stage. Males containing an intact ejaculatory duct, but lacking accessory glands, initiate the two postmating responses in their female partners [Xue, L. & Noll, M. (2000) Proc. Natl Acad. Sci. USA97, 3272-3275]. Although such males synthesize DUP99B in wild-type quantities, they elicit only weak postmating responses in their mating partners. Males lacking the Dup99B gene elicit the two postmating responses to the same extent as wild-type males. These results suggest that both sex-peptide and DUP99B can elicit both responses in vivo. However, sex-peptide seems to play the major role in eliciting the postmating responses, while DUP99B may have specialized for other, as yet unknown, functions.

Sex-peptide is the molecular basis of the sperm effect in Drosophila melanogaster.

Mating elicits two major changes in the reproductive behavior of many insect females. The egg-laying rate increases and the readiness to accept males (receptivity) is reduced. These postmating responses last approximately 1 week in Drosophila melanogaster. Males that do not transfer sperm but transfer seminal fluid during mating induce a short-term response of 1 day. The long-term response of 1 week requires the presence of sperm (sperm effect). Hence, sperm is essential for the long-term persistence of the postmating responses. Three seminal fluid peptides elicit postmating responses: ovulin, sex-peptide (SP), and DUP99B. Using the technique of targeted mutagenesis by homologous recombination, we have produced males with mutant SP genes. Here, we report that males lacking functional SP elicit only a weak short-term response. However, these males do transfer sperm. Thus, (i) SP is the major agent eliciting the short-term and the long-term postmating responses and (ii) sperm is merely the carrier for SP. The second conclusion is supported by the finding that SP binds to sperm. The 36-aa-encoding SP gene is the first small Drosophila gene knocked out with the method of homologous recombination.