Male-biased adult sex ratios in a red squirrel population

T. Andrew Hurly

doi:10.1139/z87-201

Adult sex ratio influences mate choice in Darwin’s finches

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1903838116 ◽

2019 ◽

Vol 116 (25) ◽

pp. 12373-12382 ◽

Cited By ~ 10

Author(s):

Peter R. Grant ◽

B. Rosemary Grant

Keyword(s):

Mate Choice ◽

Sex Ratio ◽

Phylogenetic Analyses ◽

Sex Ratios ◽

Differential Mortality ◽

Sexual Imprinting ◽

Darwin's Finches ◽

Darwin’S Finches ◽

Adult Sex Ratio ◽

Geospiza Fortis

The adult sex ratio (ASR) is an important property of populations. Comparative phylogenetic analyses have shown that unequal sex ratios are associated with the frequency of changing mates, extrapair mating (EPM), mating system and parental care, sex-specific survival, and population dynamics. Comparative demographic analyses are needed to validate the inferences, and to identify the causes and consequences of sex ratio inequalities in changing environments. We tested expected consequences of biased sex ratios in two species of Darwin’s finches in the Galápagos, where annual variation in rainfall, food supply, and survival is pronounced. Environmental perturbations cause sex ratios to become strongly male-biased, and when this happens, females have increased opportunities to choose high-quality males. The choice of a mate is influenced by early experience of parental morphology (sexual imprinting), and since morphological traits are highly heritable, mate choice is expressed as a positive correlation between mates. The expected assortative mating was demonstrated when theGeospiza scandenspopulation was strongly male-biased, and not present in the contemporaryGeospiza fortispopulation with an equal sex ratio. Initial effects of parental imprinting were subsequently overridden by other factors when females changed mates, some repeatedly. Females of both species were more frequently polyandrous in male-biased populations, and fledged more offspring by changing mates. The ASR ratio indirectly affected the frequency of EPM (and hybridization), but this did not lead to social mate choice. The study provides a strong demonstration of how mating patterns change when environmental fluctuations lead to altered sex ratios through differential mortality.

Effects of phytoseiid predators on the sex ratio of the spider mite Panonychus ulmi

Canadian Journal of Zoology ◽

10.1139/z91-031 ◽

1991 ◽

Vol 69 (1) ◽

pp. 208-212 ◽

Cited By ~ 3

Author(s):

Dan L. Johnson ◽

Heather C. Proctor

Keyword(s):

Population Density ◽

Sex Ratio ◽

Spider Mite ◽

Total Population ◽

Panonychus Ulmi ◽

Encounter Rate ◽

Male Mortality ◽

Adult Sex Ratio ◽

Biased Sex Ratio ◽

Male Activity

The effect of predator presence on the adult sex ratio of a spider mite (Panonychus ulmi) was examined in a field experiment. Phytoseiid predators (chiefly Typhlodromus occidentalis) were removed from 32 trees harboring P. ulmi populations, and allowed to remain at natural levels on 32 other trees. Both total population density and proportion of males in the prey population were significantly higher in predator-free trees. Mechanisms that could explain the increase in the proportion of males are examined. The most probable is that greater male activity results in a higher encounter rate between predator and prey, and that subsequent higher male mortality when predators are present exaggerates the female-biased sex ratio. The theoretical effects of sex-biased predation on diplo-diploid and haplo-diploid organisms are discussed.

Is biasing offspring sex ratio adaptive? A test of Fisher's principle across multiple generations of a wild mammal in a fluctuating environment

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2018.1251 ◽

2018 ◽

Vol 285 (1891) ◽

pp. 20181251 ◽

Cited By ~ 1

Author(s):

Andrea E. Wishart ◽

Cory T. Williams ◽

Andrew G. McAdam ◽

Stan Boutin ◽

Ben Dantzer ◽

...

Keyword(s):

Sex Ratio ◽

Tamiasciurus Hudsonicus ◽

Red Squirrels ◽

Offspring Sex Ratio ◽

Offspring Sex ◽

Adult Sex Ratio ◽

Secondary Sex Ratio ◽

North American Red Squirrels ◽

Negative Frequency Dependent Selection ◽

Fisher’S Principle

Fisher's principle explains that population sex ratio in sexually reproducing organisms is maintained at 1 : 1 owing to negative frequency-dependent selection, such that individuals of the rare sex realize greater reproductive opportunity than individuals of the more common sex until equilibrium is reached. If biasing offspring sex ratio towards the rare sex is adaptive, individuals that do so should have more grandoffspring. In a wild population of North American red squirrels ( Tamiasciurus hudsonicus ) that experiences fluctuations in resource abundance and population density, we show that overall across 26 years, the secondary sex ratio was 1 : 1; however, stretches of years during which adult sex ratio was biased did not yield offspring sex ratios biased towards the rare sex. Females that had litters biased towards the rare sex did not have more grandoffspring. Critically, the adult sex ratio was not temporally autocorrelated across years, thus the population sex ratio experienced by parents was independent of the population sex ratio experienced by their offspring at their primiparity. Expected fitness benefits of biasing offspring sex ratio may be masked or negated by fluctuating environments across years, which limit the predictive value of the current sex ratio.

Recruitment sex ratios in gray-tailed voles (Microtus canicaudus) in response to density, sex ratio, and season

Canadian Journal of Zoology ◽

10.1139/z03-116 ◽

2003 ◽

Vol 81 (8) ◽

pp. 1306-1311 ◽

Cited By ~ 7

Author(s):

Monica L Bond ◽

Jerry O Wolff ◽

Sven Krackow

Keyword(s):

Population Density ◽

Sex Ratio ◽

Resource Competition ◽

Sex Ratios ◽

Female Offspring ◽

High Population ◽

Reproductive Value ◽

High Population Density ◽

Adult Sex Ratio ◽

Sex Ratio Adjustment

We tested predictions associated with three widely used hypotheses for facultative sex-ratio adjustment of vertebrates using eight enclosed populations of gray-tailed voles, Microtus canicaudus. These were (i) the population sex ratio hypothesis, which predicts that recruitment sex ratios should oppose adult sex-ratio skews, (ii) the local resource competition hypothesis, which predicts female-biased recruitment at low adult population density and male-biased recruitment at high population density, and (iii) the first cohort advantage hypothesis, which predicts that recruitment sex ratios should be female biased in the spring and male biased in the autumn. We monitored naturally increasing population densities with approximately equal adult sex ratios through the spring and summer and manipulated adult sex ratios in the autumn and measured subsequent sex ratios of recruits. We did not observe any significant sex-ratio adjustment in response to adult sex ratio or high population density; we did detect an influence of time within the breeding season, with more female offspring observed in the spring and more male offspring observed in the autumn. Significant seasonal increases in recruitment sex ratios indicate the capacity of female gray-tailed voles to manipulate their offspring sex ratios and suggest seasonal variation in the relative reproductive value of male and female offspring to be a regular phenomenon.

Sex ratios of Sitodiplosis mosellana (Diptera: Cecidomyiidae): implications for pest management in wheat (Poaceae)

Bulletin of Entomological Research ◽

10.1079/ber2004333 ◽

2004 ◽

Vol 94 (6) ◽

pp. 569-575 ◽

Cited By ~ 12

Author(s):

M.A.H. Smith ◽

I.L. Wise ◽

R.J. Lamb

Keyword(s):

Life Cycle ◽

Sex Ratio ◽

Sex Ratios ◽

Adult Emergence ◽

Differential Mortality ◽

Sitodiplosis Mosellana ◽

Single Sex ◽

Crop Resistance ◽

Wheat Midge ◽

Population Average

AbstractSex ratios of populations of the wheat midge Sitodiplosis mosellana Géhin, developing on wheat Triticum aestivum L., were determined at reproduction, adult emergence, and dispersal. The patterns of sex ratio through the life cycle of S. mosellana result from: (i) a genetic mechanism that causes all or nearly all of the progeny of individual females to be a single sex, with an overall sex ratio that is slightly biased at 54–57% females; (ii) a differential mortality during diapause that increases the sex ratio to 60–65% females; (iii) mating which occurs near the emergence site followed by female dispersal which causes the post-dispersal sex ratio to rise to nearly 100% females; and (iv) oviposition which spreads eggs among different plants and assures that the next generation has a local sex ratio close to the population average. These changes in sex ratio through the life cycle have implications for using crop resistance or pheromones to manage S. mosellana, because mating takes place quickly near emergence sites, and because mated females but not males disperse from emergence sites to oviposition sites. Crop refuges used to protect resistance genes against the evolution of virulence by S. mosellana must be interspersed to prevent assortative mating that would occur in separate blocks of resistant and susceptible plants. Monitoring or mating disruption using a pheromone would be ineffective when wheat is grown in rotation with a non-host crop.

Phenotypic and environmental predictors of reproductive success in painted turtles

10.1101/2020.11.10.377028 ◽

2020 ◽

Author(s):

Jessica M. Judson ◽

Luke A. Hoekstra ◽

Kaitlyn G. Holden ◽

Fredric J. Janzen

Keyword(s):

Body Size ◽

Reproductive Success ◽

Mate Choice ◽

Sex Ratio ◽

Sex Ratios ◽

Female Mate Choice ◽

Painted Turtles ◽

Weak Evidence ◽

Adult Sex Ratio ◽

Siring Success

ABSTRACTSexual selection is often assumed to elicit sexually dimorphic traits. However, most work on this assumption in tetrapod vertebrates has focused on birds. In this field experiment, we assessed relationships between both sexually dimorphic (body size, claw length) and non-dimorphic traits (forelimb stripe color, baseline corticosterone concentrations) and reproductive success in adult painted turtles to explicate the roles of these phenotypes in mate choice and the evolution of sexual dimorphism. We also modified adult sex ratios in experimental ponds to elucidate the role of biased sex ratios on reproductive success, which is a timely test of the potential threat of biased sex ratios on population persistence in a species with temperature-dependent sex determination. We found no strong influence of male phenotypes on male siring success, but female body size and baseline corticosterone concentrations predicted female clutch sizes. We find weak evidence that adult sex ratio influences male siring success, with a male-biased sex ratio producing lower male siring success than a female-biased sex ratio. This study offers evidence that female mate choice may not be an important selective force on male phenotypes, but that instead selection occurs on female phenotypes, particularly body size and corticosterone concentrations. Further, biased adult sex ratios can influence reproductive success of both sexes. Finally, the use of Kompetitive Allele Specific PCR (KASP) was highly successful in parentage analysis, which adds reptiles to the growing list of taxa successfully genotyped with this new technology.Lay SummaryFemale painted turtles aren’t choosy about traits of their mates. In a field experiment, we find that male traits do not predict male fitness, but key female traits (body size and stress levels) do predict female reproductive success. Further, we find weak evidence that adult sex ratio influences individual fitness in this species with environmental sex determination. Ultimately, we reject the long-assumed importance of female mate choice in this freshwater turtle.

Sex Ratio of Small Hive Beetles: The Role of Pupation and Adult Longevity

Insects ◽

10.3390/insects10050133 ◽

2019 ◽

Vol 10 (5) ◽

pp. 133 ◽

Cited By ~ 1

Author(s):

Anna Papach ◽

Jérémy Gonthier ◽

Geoffrey R. Williams ◽

Peter Neumann

Keyword(s):

Sex Ratio ◽

Field Studies ◽

Differential Mortality ◽

Adult Longevity ◽

Published Data ◽

Larval Feeding ◽

Intraspecific Interactions ◽

Adult Sex Ratio ◽

Biased Sex Ratio ◽

Small Hive Beetles

The sex ratio of sexually reproducing animal species tends to be 1:1, which is known as Fisher’s principle. However, differential mortality and intraspecific competition during pupation can result in a biased adult sex ratio in insects. The female-biased sex ratio of small hive beetles (SHBs) is known from both laboratory and field studies, but the underlying reasons are not well understood. Here, we used laboratory mass and individual pupation to test if differential mortality between sexes and/or intraspecific interactions can explain this sex ratio. The data show a significant female-biased adult sex ratio in both mass and individual rearing, even when assuming that all dead individuals were males. Our results therefore suggest that neither differential mortality during pupation nor intraspecific interactions are likely to explain the female-biased sex ratio of freshly emerged adult SHBs. We regard it as more likely that either competition during the larval feeding stage or genetic mechanisms are involved. In addition, we compared our data with previously published data on the sex ratio of both freshly emerged and field-collected SHBs to investigate possible gender differences in adult longevity. The data show a significantly greater female bias in the sex ratio upon emergence, compared to field-collected SHBs, suggesting that adult females have a shorter longevity.

Unexpected offspring sex ratios in response to habitat quality in a size-dimorphic bark beetle

Canadian Journal of Zoology ◽

10.1139/z99-027 ◽

1999 ◽

Vol 77 (4) ◽

pp. 524-529 ◽

Cited By ~ 3

Author(s):

Risa D Sargent ◽

Mary L Reid

Keyword(s):

Body Size ◽

Reproductive Success ◽

Sex Ratio ◽

Habitat Quality ◽

Bark Beetle ◽

Sex Ratios ◽

Diploid Species ◽

Differential Mortality ◽

Male Reproductive Success ◽

Offspring Sex

Facultative sex ratio manipulation has been examined in a limited number of diploid species, mainly vertebrates. We tested the prediction that mothers would preferentially place males in conditions conducive to large size in the diploid pine engraver bark beetle, Ips pini. In this species, males are the larger sex and therefore male reproductive success was expected to be more dependent on body size than female reproductive success. Because body size is largely environmentally determined in bark beetles, mothers were expected to alter sex ratios in response to habitat quality. Contrary to predictions, offspring sex ratios tended to be more female biased in situations conducive to large offspring size than in situations producing offspring of small size. We were able to rule out nonadaptive explanations such as differential mortality or development times of males and females, suggesting that the observed pattern is adaptive. This study provides a rare example of sex ratio manipulation in diploid insects. However, the unexpected direction of sex ratio biases suggests that daughters gain a yet unknown benefit from being reared in high-quality conditions that surpasses the fitness that would be gained from producing relatively larger sons.

Sex ratio variation in gastrointestinal nematodes of Svalbard reindeer; density dependence and implications for estimates of species composition

Parasitology ◽

10.1017/s0031182004006298 ◽

2004 ◽

Vol 130 (1) ◽

pp. 99-107 ◽

Cited By ~ 13

Author(s):

A. STIEN ◽

M. DALLIMER ◽

R. J. IRVINE ◽

O. HALVORSEN ◽

R. LANGVATN ◽

...

Keyword(s):

Sex Ratio ◽

Species Composition ◽

Density Dependence ◽

Sex Ratios ◽

Gastrointestinal Nematodes ◽

Late Winter ◽

Adult Males ◽

Svalbard Reindeer ◽

Ratio Variation ◽

Adult Sex Ratio

Estimates of the intensity and abundance of species provide essential data for ecological, evolutionary and epidemiological studies of gastrointestinal nematode communities. These estimates are typically derived from the species composition of adult males when only males have readily scorable species-specific morphological traits. Such estimation assumes that all species in the community have the same adult sex ratio. We evaluated this assumption for the trichostrongyle nematodes Ostertagia gruehneri and Marshallagia marshalli in infracommunities in Svalbard reindeer by identifying to species adult females using a polymerase chain reaction assay. The proportion of males was found to be slightly higher in O. gruehneri than in M. marshalli. Evidence for seasonal variation and density dependence in the adult sex ratio was only found for O. gruehneri. Possible demographic mechanisms for such sex ratio variation are discussed, and stochastic models that generate density-dependent sex ratios proposed. Sex ratio variation caused substantial bias in some male-based estimates of intensity of infection, while substantial and consistent bias in estimates of abundances was only evident in late winter samples. Our results suggest that estimating sex ratios can be particularly important in individual host level studies of nematode species of low abundance.

Some Factors that Distort the Sex Ratio of the Gypsy Moth Porthetria dispar (L.) (Lepidoptera: Lymantriidae)

The Canadian Entomologist ◽

10.4039/ent95465-5 ◽

1963 ◽

Vol 95 (5) ◽

pp. 465-474 ◽

Cited By ~ 12

Author(s):

Robert W. Campbell

Keyword(s):

New York ◽

Sex Ratio ◽

Gypsy Moth ◽

Larval Density ◽

Mortality Factor ◽

Differential Mortality ◽

Porthetria Dispar ◽

Population Consequences ◽

Adult Sex Ratio ◽

The Town

AbstractDuring a study on the population dynamics of the gypsy moth, Porthetria dispar (L.), conducted in the Town of Glenville, New York, some factors were found to affect the sexes differentially. The importance of this differential mortality is indicated by the fact that 78 per cent of the variation in the logarithm of an index of population trend (the ratio of population density from year to year) was associated with the logarithm of adult sex ratio.Disease and desiccation during instars IV-VI and among pre-pupae were strongly selective against the female insects. This differential mortality caused a change in the pupal sex ratio from about 70 per cent females where no disease occurred to less than 25 per cent female pupae following an epizoötic. Ichneumonids, on the other hand, usually killed more male pupae than females, except when host size was reduced by excessive larval density and competition. The net result from this series of factors that distort the sex ratio has been to produce adult sex ratios varying from more than 80 per cent female moths to only 2 per cent females.In this host species, as in most other animals, it seems that the population consequences of a mortality factor that kills the host sexes in different proportions should be evaluated in terms of the more critical (female) sex destroyed.