Food affects the potential reproductive rates of sand goby females but not of males

The interspawning interval of female sand gobies, Pomatoschistusminutus, a batch-spawning fish with paternal care, was significantlyshorter when the fish were fed daily than when they were fedevery fourth day. The incubation time of males was not affectedby feeding, nor was the interbrood interval Males have an equalor higher potential reproductive rate than females. As femalesreproduce more slowly when food is scarce than when it is abundant,and males do not, the difference between the sexes in potentialreproductive rate increases when there is food shortage. Becauseof this difference, both male bias in operational sex ratioand intensity in male-male competition for mates are predictedto increase as food availability decreases. Furthermore, a tradeoffbetween current and future reproduction is demonstrated to operateonly when resources are limited, because the correlation betweenegg number of the first and second clutch was positive amonghigh-food females but negative among low-food females. The numberof eggs per female clutch did, however, not differ between treatmentsin first or second dutch. I conclude that operational sex ratioand sexual selection are expected to vary within and betweensand goby populations in accordance with prey availability     

Sex-role reversal revisited: choosy females and ornamented, competitive males in a pipefish

In the pipefish Syngnathus typhle sex roles are reversed, thatis, females compete more intensely than males over mates. However,competition over mates among individuals of one sex does notnecessarily prevent members of that same sex from being choosy,and choosiness in the other sex does not prevent competitionwithin it. In an experiment we allowed a female pipefish tochoose freely between two males, after which we released themales and let the three interact. Comparisons with earlier resultsshow that both sexes courted partners and competed with consexuals.However, females courted more often than did males, and courtshipwas more frequent in treatments involving large individualsthan in treatments with small individuals. Males competed amongthemselves for access to mates but for a shorter duration thanfemales in the same situation. Males displayed an ornament towardsfemales but not to males during mating competition. Females,however, used their ornament in both contexts. Females did notalways mate with the male of their previously made choice, whichwe interpret as females being constrained by male-male competition,male motivation to mate, or both. Thus, in this sex-role reversedspecies, mate choice in the more competitive sex may be circumventedand even overruled by mate competition and mating willingnessin the least competitive sex. Hence, sex roles should not beconsidered as sexes being either choosy or competitive but ratherthat males and females may exhibit different combinations ofchoice and competition.     

Additional evidence for the genomic imprinting model of sex determination in the haplodiploid wasp Nasonia vitripennis: isolation of biparental diploid males after X-ray mutagenesis

The primary sex-determining signal in the haplodiploid wasp Nasonia vitripennis is not known. In haplodiploid reproduction, unfertilized eggs typically develop into uniparental haploid males and fertilized eggs into biparental diploid females. Although this reproductive strategy is common to all Hymenoptera, sex-determination is not strictly specified by the number of genome copies inherited. Furthermore, primary sex-determining signals differ among haplodiploid species. In the honeybee, for example, the primary signal is the genotype at a single, polymorphic locus: diploid animals that are homozygous develop into males while heterozygotes develop into females. Sex determination in Nasonia cannot be explained by this mechanism. Various lines of evidence show that the inheritance of a paternal genome is required for female sexual development and suggest a genomic imprinting mechanism involving an imprinted gene, expressed only from a paternal copy, that triggers female sexual development. In this model, haploid or diploid uniparental embryos develop into males due to a maternal imprint that silences this locus. The genomic imprinting model predicts that a loss-of-function mutation in the paternal copy of the imprinted gene would result in male sexual development in a biparental diploid embryo. In support of this model, we have identified rare biparental diploid males in the F1 progeny of X-ray mutagenized haploid males. Although uniparental diploid male progeny of virgin triploid females have been previously described, this is the first report of biparental diploid males in Nasonia. Our work provides a new, independent line of evidence for the genomic imprinting model of Nasonia sex determination.     

Sex differences in life history drive evolutionary transitions among maternal,paternal, and bi‐parental care

Evolutionary transitions among maternal, paternal, and bi‐parental care have been common in many animal groups. We use a mathematical model to examine the effect of male and female life‐history characteristics (stage‐specific maturation and mortality) on evolutionary transitions among maternal, paternal, and bi‐parental care. When males and females are relatively similar – that is, when females initially invest relatively little into eggs and both sexes have similar mortality and maturation – transitions among different patterns of care are unlikely to be strongly favored. As males and females become more different, transitions are more likely. If females initially invest heavily into eggs and this reduces their expected future reproductive success, transitions to increased maternal care (paternal → maternal, paternal → bi‐parental, bi‐parental → maternal) are favored. This effect of anisogamy (i.e., the fact that females initially invest more into each individual zygote than males) might help explain the predominance of maternal care in nature and differs from previous work that found no effect of anisogamy on the origin of different sex‐specific patterns of care from an ancestral state of no care. When male mortality is high or male egg maturation rate is low, males have reduced future reproductive potential and transitions to increased paternal care (maternal → paternal, bi‐parental → paternal, maternal → bi‐parental) are favored. Offspring need (i.e., low offspring survival in the absence of care) also plays a role in transitions to paternal care. In general, basic life‐history differences between the sexes can drive evolutionary transitions among different sex‐specific patterns of care. The finding that simple life‐history differences can alone lead to transitions among maternal and paternal care suggests that the effect of inter‐sexual life‐history differences should be considered as a baseline scenario when attempting to understand how other factors (mate availability, sex differences in the costs of competing for mates) influence the evolution of parental care.     

Sexual selection and the evolution of exclusive paternal care in arthropods

Internal fertilization and anisogamy are thought to impede the evolution of exclusive paternal care by reducing paternity assurance and increasing male promiscuity. The potential role of sexual selection in easing these constraints is currently being examined in vertebrates but has not been seriously studied in most arthropods. To distinguish the effects of sexual from natural selection on the evolution of arthropod paternal care, I tested predictions of the state of several life history and behavioural traits under both forms of selection across all known taxa with exclusive paternal care. The results suggest parallels between prezygotic nuptial gifts and exclusive postzygotic paternal care and support the hypothesis that, in arthropods, male behaviours that enhance female reproductive success either directly by releasing females from the fecundity constraints of maternal care (enhanced fecundity hypothesis) or indirectly by identifying mates with superior genes (handicap principle) are traits on which sexual selection has acted. Under such conditions males willing to guard young become preferred mates for gravid females and enjoy greater promiscuity than males unable or unwilling to guard. Females use nest construction or the act of guarding another female's eggs as honest signals of paternal intent and quality. Copyright 2000 The Association for the Study of Animal Behaviour.     

PATERNAL CONDITION DRIVES PROGENY SEX‐RATIO BIAS IN A LIZARD THAT LACKS PARENTAL CARE

Sex‐allocation theory predicts that females in good condition should preferentially produce offspring of the sex that benefits the most from an increase in maternal investment. However, it is generally assumed that the condition of the sire has little effect on progeny sex ratio, particularly in species that lack parental care. We used a controlled breeding experiment and molecular paternity analyses to examine the effects of both maternal and paternal condition on progeny sex ratio and progeny fitness in the brown anole (Anolis sagrei), a polygynous lizard that lacks parental care. Contrary to the predictions of sex‐allocation theory, we found no relationship between maternal condition and progeny sex ratio. By contrast, progeny sex ratio shifted dramatically from female‐biased to male‐biased as paternal condition increased. This pattern was driven entirely by an increase in the production of sons as paternal condition improved. Despite strong natural selection favoring large size and high condition in both sons and daughters, we found no evidence that progeny survival was related to paternal condition. Our results emphasize the importance of considering the paternal phenotype in studies of sex allocation and highlight the need for further research into the pathways that link paternal condition to progeny fitness.     

Paternity in the Australian brush-turkey, Alectura lathami, a megapode bird with uniparental male care

Male Australian brush-turkeys, Alectura lathami, provide allparental care by building and tending large incubation mounds.Females visit and lay eggs in the mounds of several males sequentially,but they provide no parental care after laying. Because malesand females meet only briefly at mounds to copulate and lay,males have no obvious means of ensuring paternity. I used DNAfingerprinting techniques to determine paternity for 65 brush-turkeychicks. Eighteen chicks (27.7%) did not match the mound-tendingmale. Some of these paternity exclusions were evidently causedby females switching rapidly from one mound to another, butthe majority (23.1% of eggs) appeared to result from femalescopulating with males other than the one in whose mound theywere currently laying. However, the frequency of these copulations(43%) was much lower than the estimated frequency with whichthey fertilized eggs, perhaps because their timing during theovulatory cycle differed relative to most other copulations.The percentage of eggs excluded in paternity analyses rangedfrom 20.0% to 43.8% for individual males but did not appearto affect male parental care. Several factors favor male parentalcare regardless of paternity. Males can accommodate eggs fromseveral females in one mound, which increases the opportunitiesfor additional matings without increasing the cost of parentalcare. In addition, paternity appears to be unpredictable andhard to assess, and a facultative reduction in care would bedifficult without abandoning a mound entirely.     

Using upper limits of "bateman gradients" to estimate the opportunity for sexual selection

The widespread use of molecular markers to estimate parentagemakes possible a new index of the opportunity for sexual selection.After demonstrating the need for a new measure, I develop onebased on the upper limit on sexual selection. I describe whatsets the upper limit for each sex by showing how maximum fecundityincreases with number of mates, accounting for the amount ofenergy (or critical resources) available for reproduction andlevels of parental care. For females the upper limit on sexualselection is set by the value of paternal investment that comeswith each mating. For males, the upper limit on sexual selectionis set by the fecundity of their mates (including any boostto female fecundity from paternal investment). Sex-roles aremost likely to reverse (making males choosy and females competitive)when the amount of reproductive energy investment made by eachsex is low, irrespective of the level of paternal investment.Finally, I propose that we use the difference between male andfemale upper limits on sexual selection to quantify sex differencesin the opportunity for sexual selection. Using upper limitsto estimate the opportunity for sexual selection is more intuitivethan older methods (e.g., standardized variance in mating success),it is experimentally measurable, and it is valuable in understandingthe evolution of mating systems.     

Female‐dependent transmission of paternal mtDNA is a shared feature of bivalve species with doubly uniparental inheritance (DUI) of mitochondrial DNA

Several species from a number of bivalve molluscan families are known to have a paternally transmitted mitochondrial genome, along with the standard maternally transmitted one. The main characteristic of the phenomenon, known as doubly uniparental inheritance (DUI), is the coupling of sex and mtDNA inheritance: males receive both genomes but transmit only the paternal to their progeny; females either do not have the paternal genome or, if they do, they do not transmit it to their progeny. In the families Mytilidae and Veneridae, both of which have DUI, a female individual is either female‐biased (it produces only, or nearly so, female progeny), male‐biased (it produces mainly male progeny) or non‐biased (it produces both genders in intermediate frequencies). Here we present evidence for a same pattern in the freshwater mussel, Unio delphinus (Unionidae). These results suggest that the maternal control of whether a fertilized egg will develop into a male or a female individual (and the associated feature of whether it will inherited or not inherit the paternal mtDNA) is a general characteristic of species with DUI.     

Sex-specific effects of hybridization on reproductive fitness in Mytilus

Blue mussels of the genus Mytilus form extensive hybrid zones in the North Atlantic and elsewhere where the distributions of different species overlap. Mytilus species transmit both maternal and paternal mtDNA through egg and sperm, respectively, a process known as doubly uniparental inheritance (DUI), and some females produce offspring with extremely biased sex ratios. These two traits have been shown to be linked and maternally controlled, with sex determination involving nuclear–cytoplasmic interactions. Hybridization has been shown to disrupt DUI mitochondrial inheritance and sex ratio bias; however, the effect of hybridization on reproductive fitness has not previously been examined. We investigated this effect in M. edulis × M. trossulus crosses through histological examination of mature F1 progeny, and spawning of F1 hybrids to monitor survival of their progeny through to the D stage of larval development. For progeny produced from mothers with a strong bias toward female offspring (often 100%) in pure-bred crosses, there was a clear breakdown in female dominance of progeny and significantly more hermaphrodites in the hybrid crosses produced from sperm with the M-tr1 mitotype. We also found significant sex-specific differences among hybrid progeny, with females producing normal eggs while males and hermaphrodites evidenced impaired gonadal development with significantly greater numbers of Sertoli cells, phagocytic hemocytes, and degenerating germ cells, all associated with gonad resorption. Males from crosses where DUI was disrupted and where male progeny were homoplasmic for the female mtDNA were the most severely compromised. Allelic incongruity between maternal and paternal mitotypes in hybrid crosses was associated with significant disruption of male gonadal development.     

Female egg dumping and the effect of sex ratio on male egg carrying in a coreid bug

Phyllomorpha laciniata Vill (Heteroptera, Coreidae) is uniqueamong terrestrial insects in that females glue eggs on the backsof other conspecifics. Egg carrying byP. laciniatamales haspreviously been considered as paternal care. We explored femaleoviposition with respect to previous mating experience of femalesand tested whether sex ratio affects male egg-carrying. Thehypothesis that male egg-carrying is a form of paternal carepredicts that a male should always accept eggs after matingwith a female. However, if male egg-carrying is a form of postcopulatorymate guarding rather than paternal care, egg carrying shouldincrease in the presence of other males. When two couples wereplaced together, females laid eggs on the backs of all individualsenclosed, including the backs of other females. However, whena female was accompanied by 2 males, 22 out of 26 females ovipositedon their mating partner. Thus, sexual competition rather thanpaternity alone, affects a male's eagerness to carry eggs. However,even if males sometimes carry their own eggs, females lay eggson the backs of all conspecifics they can easily acquire. Thus,egg carrying in P. laciniata is partially voluntary and partiallythe result of female egg dumping     

The origin of parental care in relation to male and female life history

The evolution of maternal, paternal, and bi‐parental care has been the focus of a great deal of research. Males and females vary in basic life‐history characteristics (e.g., stage‐specific mortality, maturation) in ways that are unrelated to parental investment. Surprisingly, few studies have examined the effect of this variation in male and female life history on the evolution of care. Here, we use a theoretical approach to determine the sex‐specific life‐history characteristics that give rise to the origin of paternal, maternal, or bi‐parental care from an ancestral state of no care. Females initially invest more into each egg than males. Despite this inherent difference between the sexes, paternal, maternal, and bi‐parental care are equally likely when males and females are otherwise similar. Thus, sex differences in initial zygotic investment do not explain the origin of one pattern of care over another. However, sex differences in adult mortality, egg maturation rate, and juvenile survival affect the pattern of care that will be most likely to evolve. Maternal care is more likely if female adult mortality is high, whereas paternal care is more likely if male adult mortality is high. These findings suggest that basic life‐history differences between the sexes can alone explain the origin of maternal, paternal, and bi‐parental care. As a result, the influence of life‐history characteristics should be considered as a baseline scenario in studies examining the origin of care.     

Reproductive effort of both male and female Bar‐throated Apalis Apalis thoracica is predicted by ornamentation of self and mate

Melanin‐based plumage ornaments have been shown to play an important role in male–male competition, but also influence inter‐sexual communication. Consequently, ornaments may be associated with reproductive effort of both males and females. Females mated to males with larger melanin ornaments may acquire access to better territories or benefit from increased paternal care. Here we investigated whether the melanin‐based breast‐band of male and female Bar‐throated Apalis Apalis thoracica is a signal of information about its bearer and is associated with male and female reproductive effort. Breast‐band size was a highly variable morphometric trait in both sexes, but only in males was it associated with body mass. We then assessed whether male and female breast‐band size predicted maternal and paternal investment. Egg mass increased with male breast‐band size, but decreased with female breast‐band size. Whether females adjust maternal hormone allocation in response to their partner's ornamentation remains a contentious issue. We found that yolk testosterone and androstenedione concentrations were not predicted by male ornamentation or body mass. Finally, males with larger breast‐bands provided their mates with more food, allowing those females to spend more time incubating. Reproductive effort of both parents is therefore predicted by their own and their mate's ornamentation in Bar‐throated Apalis, and thus breast‐band size potentially acts as a signal of reproductive performance in both sexes. These results highlight the need for more comprehensive analyses of a relationship between melanin‐based ornaments and fitness, incorporating multiple behavioural variables associated with reproductive effort.     

Estrous female goats use testosterone-dependent cues to assess mates

In a promiscuous species like the domestic goat (Capra hircus), in which maternal investment is greater than paternal investment, a female may mate selectively with a more-fit male to improve her reproductive fitness. Testosterone (T) controls a large suite of male-typical behaviors and morphological characteristics. High T concentrations may be energetically costly or even detrimental to survival; thus, preventing lower quality males from falsely advertising their fitness. Three preference studies were conducted to examine if females use T-dependent cues to assess potential mates. For Experiment 1, females were given a choice between a pair of morphologically similar males, bucks (intact males) and stags (post-pubertally castrated males), during the breeding and non-breeding seasons. In both seasons, females preferred the bucks compared to stags. In Experiment 2, females were given a choice between bucks, stags and wethers (pre-pubertally castrated males) during the non-breeding season. For some comparisons, castrated males received 25 mg testosterone propionate (TP) or were untreated. Females preferred TP-treated males compared to untreated males and showed no preference when given a choice between either two TP-treated or two untreated males. In Experiment 3, females were given a choice between a pair of bucks and a pair of stags treated with 25 mg TP during monthly tests in the breeding season. At each monthly test, females preferred the males with higher T concentrations near the time of the behavior test. These studies suggest that females use T-dependent cues to assess potential mates, and T concentrations may indicate a male's overall fitness.     

Females prefer mating males in the carmine triplefin,Axoclinus carminalis,a paternal brood-guarder

Synopsis This study investigates the role of male mating status in female choice patterns in the carmine triplefin, Axoclinus carminalis, a tripterygiid fish that exhibits paternal care. The distribution of daily reproductive activity is clumped, with many males receiving no mates and some receiving three or more. Females in this species do not prefer larger males, and characteristics of the oviposition site appear to have minimal effects on male mating success. When a female is removed from a male early in the daily spawning period, that male attracts fewer additional females for the remainder of the spawning period than does a control male. These changes in mating success are temporary, and do not affect mating success on subsequent days. A preference for mating males or males that are guarding eggs could provide asymmetric benefits for males to defend oviposition sites. This preference for males with eggs could be acting alone or with other factors such as high variance in oviposition site quality to favor the evolution of paternal care in fishes.     

Have your cake and eat it too: male sand gobies show more parental care in the presence of female partners

Traditionally, male parental effort and mate attraction effortare expected to be in conflict as they compete for the sameresource budget. However, the quality of care provided by themale may be of a direct benefit to females and may provide animportant mate choice cue. In a laboratory experiment, we examinedhow males modified their parental behavior with respect to matingopportunity by allowing male sand gobies to mate with a singlefemale either in a big or small nest (a constraint on futuremating potential). We then exposed half of these males to thevisual stimulus from additional females and recorded male eggfanning and nest building (two components of care), courtshipbehavior, and reproductive success through out the brood cycle.We found that males fanned longer and more frequently and didmore nest construction in the presence of females and in bignests. Males guarding large nests courted females more thandid males guarding small nests. All males consumed eggs duringthe brood cycle, but complete clutch cannibalism was most frequentwhen males were guarding small nests in the absence of females.The pattern of filial cannibalism that we observed suggeststhat males prematurely terminated care when their reproductivepotential was low, that is, when there was little nest spacefor additional mating and no mates present. We found no supportfor a trade-off between mate attraction and parental care. Indeed,taken together our results suggest that males may use parentalcare as a courtship strategy and that males who invest in mateattraction also have higher parental effort.     

Can females gain extra paternal investment by mating with multiple males? A game theoretic approach

Although females may require only one mating to become inseminated, many female animals engage in costly mating with multiple males. One potential benefit of polyandrous mating is gaining parental investment from multiple males. We developed two game theoretic models to explore this possibility. Our first model showed that male care of multiple females' offspring evolves when male help substantially increases offspring fitness, future mating opportunity is limited, and group size is small. In our second model, we assumed that males invest in the offspring of former mates and evaluated the fitness consequences of female monogamous and polyandrous mating strategies. Females benefit only from limited polyandry, that is, mating with several males. Polyandry is discouraged because females must share male investment with other polyandrous females, and paternal care is likely to experience diminishing returns. Females may enhance their access to male investment by competing with rival females and monopolizing investment, however. The results support the argument that females can gain paternal investment by mating with several males in small social groups (e.g., dunnocks Prunella modularis). The results do not support the argument that females can gain paternal investment from pronounced multiple mating in large social groups, however, as observed in many primate species.     

Female extrapair mate choice in a cooperative breeder: trading sex for help and increasing offspring heterozygosity

Sexual conflict between males and females over mating is common. Females that copulate with extrapair mates outside the pair-bond may gain (i) direct benefits such as resources or increased paternal care, (ii) indirect genetic benefits for their offspring, or (iii) insurance against infertility in their own social mate. Few studies have been able to demonstrate the different contexts in which females receive varying types of benefits from extrapair mates. Here, I examined sexual conflict, female extrapair mate choice, and patterns of extrapair paternity in the cooperatively breeding superb starling Lamprotornis superbus using microsatellite markers. Although extrapair paternity was lower than many other avian cooperative breeders (14% of offspring and 25% of nests), females exhibited two distinct mating patterns: half of the extrapair fertilizations were with males from inside the group, whereas half were with males from outside the group. Females with few potential helpers copulated with extrapair mates from within their group and thereby gained direct benefits in the form of additional helpers at the nest, whereas females paired to mates that were relatively less heterozygous than themselves copulated with extrapair mates from outside the group and thereby gained indirect genetic benefits in the form of increased offspring heterozygosity. Females did not appear to gain fertility insurance from copulating with extrapair mates. This is the first study to show that individuals from the same population mate with extrapair males and gain both direct and indirect benefits, but that they do so in different contexts.     

Attracting mates: Effects of paternal investment on mate attraction strategies

It is proposed here that mate-attraction strategies among females and among males vary facultatively with expectations about paternal investment. The following four hypotheses are argued and tested: 1. Females who expect to find investing mates will be more likely than other females to emphasize their need for investment by suppressing their resources and appearance of competence. 2. Females who expect to find investing mates will try to attract them by acting chaste and emphasizing their fidelity, while females who expect non-investing mates will flaunt their sexuality in order to get pre-reproductive investment from as many males as possible. 3. Males who think it is appropriate to invest heavily in offspring will be more likely than other males to attract mates by emphasizing their ability and willingness to invest. 4. Investing males will be more likely than non-investing males to emphasize chastity and fidelity, whereas non-investing males will flaunt their sexuality and sexual attractiveness to females.These hypotheses were evaluated among undergraduates by administering questionnaires measuring (a) attitudes toward paternal investment and (b) reported tactics used to attract mates. Hypotheses 2–4 were supported by the data, while hypothesis 1 received only partial support. The mixed results for hypothesis 1 indicate that self-deprecating acts and deferential acts may be signaling different things.     

Brood desertion in Kentish plover: sex differences in remating opportunities

To understand the evolution of parental care, one needs to estimatethe payoffs from providing care for the offspring and the payoffsfrom terminating care and deserting them. These payoffs arerarely known. In this study we experimentally estimated therewards from brood desertion in a species that has a variablepattern of parental care. In particular, either the female or themale parent may desert the brood in Kentish plover Charadrius alexandrinus,so some broods are attended by one parent of either sex, whereasin other broods both parents stay with the brood until the chicks fledge.We created single males and single females by experimentallyremoving the other parent and the clutch. The expected rematingtime of males was significantly higher (median: 25.4 days) thanthat of the females (5.3 days, p <.0001). The expected rematingtime tended to increase over the breeding season in both sexes,although the increase was significant only in females. The newnest of remated males was closer to their previous territory (mean± SE, 46 ± 8 m) than that of the remated females(289 ± 57 m, p <.001). Hatching success of new nestswas not different between remated males and females. Our resultsdemonstrate that the remating opportunities are different formale and female Kentish plovers and these opportunities varyover the season. We propose that the remating opportunitieswere influenced by the male-biased adult sex ratio and the seasonaldecrease in the number of breeders. However, we stress thatmeasuring remating times is a more direct measure of matingopportunities than calculating the operational sex ratio.