Abstract
All social insects with obligate reproductive division of labor evolved from strictly monogamous ancestors, but multiple queen-mating (polyandry) arose de novo, in several evolutionarily derived lineages. Polyandrous ant queens are inseminated soon after hatching and store sperm mixtures for a potential reproductive life of decades. However, they cannot re-mate later in life and are thus expected to control the loss of viable sperm because their lifetime reproductive success is ultimately sperm limited. In the leaf-cutting ant Atta colombica,, the survival of newly inseminated sperm is known to be compromised by seminal fluid of rival males and to be protected by secretions of the queen sperm storage organ (spermatheca). Here we investigate the main protein-level interactions that appear to mediate sperm competition dynamics and sperm preservation. We conducted an artificial insemination experiment and DIGE-based proteomics to identify proteomic changes when seminal fluid is exposed to spermathecal fluid followed by a mass spectrometry analysis of both secretions that allowed us to identify the sex-specific origins of the proteins that had changed in abundance. We found that spermathecal fluid targets only seven (2%) of the identified seminal fluid proteins for degradation, including two proteolytic serine proteases, a SERPIN inhibitor, and a semen-liquefying acid phosphatase. In vitro, and in vivo, experiments provided further confirmation that these proteins are key molecules mediating sexual conflict over sperm competition and viability preservation during sperm storage. In vitro, exposure to spermathecal fluid reduced the capacity of seminal fluid to compromise survival of rival sperm in a matter of hours and biochemical inhibition of these seminal fluid proteins largely eliminated that adverse effect. Our findings indicate that A. colombica, queens are in control of sperm competition and sperm storage, a capacity that has not been documented in other animals but is predicted to have independently evolved in other polyandrous social insects.
Highlights
All social insects with obligate reproductive division of labor evolved from strictly monogamous ancestors, but multiple queen-mating arose de novo in several evolutionarily derived lineages
Our results confirm that the key interaction effects between male Seminal fluid (SF) and queen spermathecal fluid (SpF) are driven by the protein containing (HMW) fractions of these secretions (Fig. 3A), and that the proteomic interactions between these secretions are essential for understanding the molecular mechanisms of sexual conflict in A. colombica
Proteins involved in DNA replication, amino acid biosynthesis/metabolism, ATP-binding, and metal ion binding were identified in greater number in the SpF proteome than in the SF proteome (Fisher’s exact probability test, two tailed, p Ͻ 0.05), whereas proteins involved in glycan processing, signaling, and carbohydrate turnover were identified in greater number in the SF proteome
Summary
Sexual conflicts continue after insemination because reproductive interests of the sexes differ when females mate with multiple males. In the ant Atta colombica, exposure to male seminal fluid proteins harms rival sperm, but queens are expected to neutralize this damage because they cannot re-mate later in life. In the leaf-cutting ant Atta colombica, the survival of newly inseminated sperm is known to be compromised by seminal fluid of rival males and to be protected by secretions of the queen sperm storage organ (spermatheca). We first show that the in vitro incapacitation effects of SF on sperm of other males are due to proteins [20] and that the interactions between SF and spermathecal fluid (SpF) are protein based This implies that proteins play crucial roles in the phenotypic expression of sperm competition and its termination. The experimental procedures and results are presented in this order in the sections below
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