Egg incubation temperature differently affects female and male hatching dynamics and larval fitness in a leafhopper

Temperature effects on ectotherms are widely studied particularly in insects. However, the life-history effects of temperature experienced during a window of embryonic development, that is egg stage, have rarely been considered. We simulated fluctuating temperatures and examined how this affects the operational sex ratio (OSR) of hatching as well as nymph and adult fitness in a leafhopper, Scaphoideus titanus. Specifically, after a warm or cold incubation we compared males and females hatching dynamics with their consequences on the sex ratio in the course of time, body size, weight, and developmental rate of the two populations, all reared on the same posthatching temperature. Males and females eggs respond differently, with females more sensitive to variation in incubation temperature. The different responses of both sexes have consequences on the sex ratio dynamic of hatchings with a weaker protandry after warm incubation. Temperatures experienced by eggs have more complex consequences on posthatching development. Later nymphal instars that hatched from eggs exposed to warm temperature were larger and bigger but developmental rate of the two populations was not affected. Our study demonstrates how incubation temperature could affect operational sex ratio and posthatching development in an insect and how this may be critical for population growth.     

Ecology and Physiology of Nesting and Early Development of the American Alligator

Ambient temperatures were significantly correlated with alligator(Alligator mississippiensis) nesting activity. Nesting occurredearliest when March-April-May ambient temperatures were highest.Rainfall had no significant relationship with time of nestingactivity although water levels did affect the degree of nesting.The bulk of the nesting took place within a 2-week period eachyear. Nesting chronology and factors affecting nesting were investigatedat Rockefeller Refuge from 1964 through 1987. Courtship activitiesgenerally began in early April and progressively intensifieduntil early June. From late May through the first week of Junecourtship and copulation were intense, the females ovulated,and the high point of spermatogenesis occurred. Factors whichseriously affected nesting success were floods, droughts, andpredation. Salinity levels affected nesting densities alongthe coast. Nesting success (% of nests which produced live hatchlings)averaged 68.3% for 266 nests followed during a 4-yr study. Hatchingsuccess (% of eggs which hatched) averaged 58.2% for 154 nestsfollowed during two nesting seasons. Habitat selection, home ranges, and daily movements were delineatedfor adult males and females. Courtship occurs in deep open waterduring springtime. Adult females selectively seek out densevegetation adjacent to isolated ponds for nesting during thesummer. Adult and sub-adult males tend to prefer open waterall year round and only occasionally venture into the more secludedand heavily vegetated areas used by the females. Home rangesizes and daily movements were much larger for adult males thanfor adult females. Laboratory studies evaluated the effectsof four different egg incubation temperatures on hatching success,sex determination, size at hatching, and growth rates to 18mo of age. The results indicate that incubation temperaturecan have a profound effect on sex ratios, hatchling size, andpost-hatching growth. No significant differences were observedin hatching success at the four different temperatures.     

孵化水热环境对渔异色蛇孵化卵和孵出幼体的影响

渔异色蛇卵孵化时能从环境中吸收水分导致质量增加,卵质量的增加与初始卵质量和孵化基质湿度有关。较大幅度的孵化基质湿度变化对孵化期、孵化成功率、胚胎动用孵内物质和能量、孵出幼体的性比、大小和质量无显著影响。孵化期随温度升高而缩短,并显示极强的窝间差异。温度对孵出幼体的性别无影响,但显著影响孵化成功率、胚胎对卵内物质和能量的动用、幼体的大小和质量、躯干和剩余卵黄的质量。孵出幼体总长的两性差异不显著,但雌体体长大于雄体而尾长小于雄体。３２℃不适于孵化渔异色蛇卵,该温度下孵出的幼体躯干发育不良,剩余孵黄较多,尾部均呈畸形,孵化过程中能量转化率较低。２４℃和２６℃中孵出的幼体躯干发育良好,孵化过程中能量转化率较高,各项被测定的幼体特征指标均极相似。     

Incubation temperatures, sex ratios and sex determination in a population of Nile crocodiles (Crocodylus niloticus)

A demographic study of the Nile crocodile Crocodylus niloticus at Lake Ngezi, Zimbabwe, revealed that females predominated in all size classes and among embryos. The sex of C. niloticus was shown to be determined by the temperature of egg incubation in constant temperature laboratory experiments. At 31 °C and below only females were produced. The threshold temperature for maleness was between 31 ° and 34 °C, but appeared to vary between clutches. The duration of the incubation period varied with temperature and was 110 days at 28 °C, falling to 85 days at 34 °C. Incubation temperature affected hatchling length, but not mass. Hatchlings from incubation at 34 °C were shorter on average than those from incubation at 28 °C and 31 °C, but by three months had outgrown them. There was no sex-related difference in length in a random sample of 200 two-year-old C. niloticus on a crocodile farm. Mean temperatures in wild nests were consistently lower than 31 °C and therefore the male threshold as determined in the laboratory. Embryonic development was slow and hatching success poor. The shallowest eggs in a nest had higher mean temperatures and more advanced embryos than the deepest eggs. They also experienced daily temperature fluctuations of up to 10 °C during which the maximum occasionally rose to 35 °C. Constant temperature incubation was not a good model of field conditions, but the correlation between nest temperatures and embryonic sex is consistent with temperature-dependent sex determination in the wild.     

Brood sex ratio in the Kentish plover

How and why do the mating opportunities of males and femalesdiffer in natural population of animals? Previously we showedthat females have higher mating opportunities than males inthe Kentish plover Charadrius alexandrinus. Both parents incubatethe eggs, and males provide more brood care than females; thusit is not obvious why the females find new mates sooner thanthe males. In this study we investigated whether the sex-biasedmating opportunities stem from biased offspring sex ratios.We determined the sex of newly hatched, precocial chicks usingCHD gene markers. Among fully sexed broods, 0.461 ± 0.024(SE) of chicks (454 chicks in 158 broods) were male, and thissex ratio was not significantly different from unity. The proportionof males at hatching decreased significantly over the breedingseason, which occurred consistently in all 3 years of the study.Large chicks were more likely to be males than females. Neitherparental age nor body size of male and female parents was relatedto brood sex ratio. We also sexed a number of chicks that werecaught after they left their nest (range of estimated ages 0–17days) and found that the proportion of males increased withbrood age. This relationship remained highly significant whencontrolling statistically for hatching date. As brood size decreaseddue to mortality after the chicks left their nest, these resultssuggest that the mortality of daughters was higher than thatof the sons shortly after hatching. Taken together, our resultsshow that the female-biased mating opportunities in the Kentishplover are not due to biased brood sex ratio at hatching but,at least in part, are due to female-biased chick mortality soonafter hatching.     

Fine structure of the subitaneous eggshell of the sessile rotifer Stephanoceros millsii (Monogononta) with observations on vesicle trafficking in the integument during ontogeny

Rotifers that engage in cyclical parthenogenesis produce two types of eggs: subitaneous eggs that hatch as clonal females and meiotic eggs that hatch as haploid males, or if fertilized, as females after a period of diapause (resting eggs). The ultrastructure of resting eggshells is known for some motile species, but there are limited data on subitaneous eggshells, and no data on any eggshells of sessile rotifers. Here, we investigated the ultrastructure of the subitaneous eggshell of the sessile rotifer Stephanoceros millsii and its potential origins of secretion, the maternal vitellarium and embryonic integument. We also explored secretory activity in the larval and adult integuments to determine whether activity changes during ontogeny. The eggshell consists of a single layer with two sublayers: an external granular sublayer apparently derived from the maternal vitellarium, and an internal flocculent sublayer secreted by the embryonic integument that may form a hatching membrane or glycocalyx. Secretory activity remains high in both the larva and adult and appears to be the source of the thickening glycocalyx. Altogether, the subitaneous eggshell of S. millsii is the thinnest among monogonont rotifers. Thin eggshells may have evolved in response to the added protection provided by the mother’s extracorporeal tube.     

Complex sex allocation in the laughing kookaburra

In groups of the cooperatively breeding laughing kookaburra(Dacelo novaeguineae), offspring sex varied with the type ofsocial group and with hatch rank. Groups with female helpers,especially if all helpers were female, had male-biased clutchand fledging sex ratios. Groups without female helpers (unassistedpairs or male-only helpers) had female-biased clutch and fledgingsex ratios. Breeding females responded facultatively to increasesin the number of female helpers in their group by producingmore male eggs. These biases may occur if breeding femalestry to limit the number of daughters recruited into their groupbecause unlike male helpers, female helpers depress the breedingsuccess of their parents. Across all nests, two-thirds of first-hatchedyoung were male, two-thirds of second-hatched young were female, and the sex ratio of third-hatched young was even. Hatch ranksex ratios also varied dramatically between different typesof social groups, from 16.7% for second-hatched nestlings ofunassisted pairs to 100% for first-hatched nestlings of groupswith only female helpers. A corollary of the relationship betweenhatch rank and sex was that hatching sex sequences were distributed nonrandomly: all groups avoided hatching a daughter first followedby a son (FM). Sibling competition is aggressive and sometimesfatal. Since females grow to be 15% larger than males the hatchingsequence of sexes could affect nestling growth and mortality.However, an exhaustive analysis found little evidence thatgrowth or survival of males was compromised if hatched aftera sister. The small number of FM sequences may only have occurredin nests that were able to ameliorate any negative consequences.Alternatively, when clutch size is small and fledging successunpredictable because of brood reduction, the preferred broodsex ratio may be contingent on the number of fledged young,making it advantageous to order the sexes in the brood.     

Sex-specific effects of yolk testosterone on survival, begging and growth of zebra finches

Yolk androgens affect offspring hatching, begging, growth and survival in many bird species. If these effects are sex-specific, yolk androgen deposition may constitute a mechanism for differential investment in male and female offspring. We tested this hypothesis in zebra finches. In this species, females increase yolk-testosterone levels and produce male-biased sex ratios when paired to more attractive males. We therefore predicted that especially sons benefit from elevated yolk androgens. Eggs were injected with testosterone or sesame oil (controls) after 2 days of incubation. Testosterone had no clear effect on sex-specific embryonic mortality and changed the pattern of early nestling mortality independent of offspring sex. Testosterone-treated eggs took longer to hatch than control eggs. Control males begged significantly longer than females during the first days after hatching and grew significantly faster. These sex differences were reduced in offspring from testosterone-treated eggs due to prolonged begging durations of daughters, enhanced growth of daughters and reduced growth of sons. The results show that variation in maternal testosterone can play an important role in avian sex allocation due to its sex-specific effects on offspring begging and growth.     

Sex differences in embryo development periods and effects on avian hatching patterns

Competitive interactions among siblings are an important determinantof parental fitness. These are strongly influenced by relativeoffspring size and therefore also by the extent to which parentscan influence offspring size hierarchies. The temporal patternof hatching in an avian clutch has a large effect on size anddevelopmental disparities among chicks. Hatching spread is generallyassumed to be mainly determined by the onset of incubation inrelation to egg laying. However, the extent to which factorsother than incubation onset, such as development rate, alsoinfluence timing of hatching has received little empirical investigation.We compared incubation periods of male and female black guillemot(Cepphus grylle) embryos to ascertain whether the time takenfor an egg to hatch varies with embryo sex. Laying date andegg mass had no significant effect on incubation time, but maleembryos hatched on average a day sooner than did females. Theonset of incubation and hatching spread vary in black guillemots.However, in mixed-sexed clutches in which the first-laid embryois male, a faster development time of males should mean asynchronoushatching regardless of parental incubation regime. This wassupported by empirical investigation. These results demonstratethat factors other than incubation behavior can be importantin establishing avian hatching patterns. Whether these sex differencesin development rate are a result of constraints on the degreeof parental control, or an adaptive strategy to manipulate hatchingpatterns, remains to be established.     

Adaptive sex allocation in relation to hatching synchrony and offspring quality in house wrens

Increased variance in the reproductive success of males relative to females favors mothers that optimally allocate sons and daughters to maximize their fitness return. In altricial songbirds, one influence on the fitness prospects of offspring arises through the order in which nestlings hatch from their eggs, which affects individual mass and size before nest leaving. In house wrens (Troglodytes aedon), the influence of hatching order depends on the degree of hatching synchrony, with greater variation in nestling mass and size within broods hatching asynchronously than in those hatching synchronously. Early-hatching nestlings in asynchronous broods were heavier and larger than their later-hatching siblings and nestlings in synchronous broods. The effect of hatching order was also sex specific, as the mass of males in asynchronous broods was more strongly influenced by hatching order than the mass of females, with increased variation in the mass of males relative to that of females. As predicted, mothers hatching their eggs asynchronously biased first-laid, first-hatching eggs toward sons and late-laid, late-hatching eggs toward daughters, whereas females hatching their eggs synchronously distributed the sexes randomly among the eggs of their clutch. We conclude that females allocate the sex of their offspring among the eggs of their clutch in a manner that maximizes their own fitness.     

Hatching order and size-dependent mortality in relation to brood sex ratio composition in chinstrap penguins

The differential environmental sensitivity of the sexes hasstrong implications in the evolutionary history of species asit can alter sexual size dimorphism, population sex ratios,and the faculty of parents to manipulate offspring sex in relationto environmental conditions. We studied sexual differences inhatching patterns and evaluated sex- and size-related mortalityin relation to hatching order and brood sex ratios in the chinstrappenguin Pygoscelis antarctica, a moderately size-dimorphic species,with a modal clutch size of 2 eggs. We found that male, second-hatched,and large eggs showed shorter hatching periods than female,first-hatched, and small eggs. We also found a male-biased mortalityof nestlings in the colony. However, male mortality patternsdiffered depending on the brood sex ratio composition. Mortalityof male chicks in all-male broods was higher than in mixed broodsand higher than female mortality in all-female broods. Contrary,females from mixed brood showed higher mortality than theirmale nest mates and higher too than females in all-female broods.Second-hatched chicks also suffered from higher mortality thanfirst-hatched chicks. Our results indicate that both the superiorcompetitive capacity and the higher energy demand of the largersex constitute 2 causal factors explaining patterns of sex-biasedmortality. Both factors occur in the same species and in differentsituations of sibling competition shaped by brood sex ratiocomposition. This study constitutes a good example of how patternsof sex-related mortality can vary depending on nest environmentalcircumstances. Furthermore, our study suggests that hatchingperiod can be a mechanism underlying sexual differences in theembryonic period of birds.     

Development of intraspecific size variation in black coucals,white-browed coucals and ruffs from hatching to fledging

Most studies on sexual size dimorphism address proximate and functional questions related to adults, but sexual size dimorphism usually develops during ontogeny and developmental trajectories of sexual size dimorphism are poorly understood. We studied three bird species with variation in adult sexual size dimorphism: black coucals (females 69% heavier than males), white-browed coucals (females 13% heavier than males) and ruffs (males 70% heavier than females). Using a flexible Bayesian generalized additive model framework (GAMM), we examined when and how sexual size dimorphism developed in body mass, tarsus length and bill length from hatching until fledging. In ruffs, we additionally examined the development of intrasexual size variation among three morphs (Independents, Satellites and Faeders), which creates another level of variation in adult size of males and females. We found that 27–100% of the adult inter- and intrasexual size variation developed until fledging although none of the species completed growth during the observational period. In general, the larger sex/morph grew more quickly and reached its maximal absolute growth rate later than the smaller sex/morph. However, when the daily increase in body mass was modelled as a proportion, growth patterns were synchronized between and within sexes. Growth broadly followed sigmoidal asymptotic models, however only with the flexible GAMM approach, residual distributions were homogeneous over the entire observation periods. These results provide a platform for future studies to relate variation in growth to selective pressures and proximate mechanisms in these three species, and they highlight the advantage of using a flexible model approach for examining growth variation during ontogeny.     

Temporal difference between testis and ovary determinations with possible involvement of testosterone and aromatase in gonadal differentiation in TSD lacking lizard, Calotes versicolor

In the garden lizard, Calotes versicolor, which lacks identifiable sex chromosomes, incubation temperature also does not have a deterministic effect on the gender. However, the embryos reared at high temperature (33-35 degrees C) have a shorter duration of incubation as well as gonadal differentiation. In contrast, exogenous application of the male hormone testosterone to embryos at ambient temperature (28 degrees C) results in almost all individuals with only testis. Thus the testosterone treatment reverts genic females to males and accelerates the differentiation of testis, a feature similar to the high-temperature treatment. Treatment of eggs with estradiol shows no difference from that seen in the untreated eggs. The present series of experiments was done to establish the "window" of testosterone sensitivity and to understand the interaction between sex hormones and high temperature on gonadal differentiation. The period between day 5 and 15 of embryonic development was the window period of testosterone sensitivity for sex reversal. This period coincided with the formation of the genital ridge and its differentiation into cortex and medulla. Treatment of the 33 degrees C-reared embryos with testosterone resulted in hatchlings of both the sexes, in contrast to only males at the ambient temperature. In contrast, at the same temperature (33 degrees C), all the dihydrotestosterone (nonaromatisable testosterone)-treated embryos hatched into males. However, those given estradiol showed no sex bias regardless of the day of application and the concentration of drug. Eggs were also treated with aromatase inhibitor, CGS 16949 A, at ambient temperature and at 33 degrees C. All the 33 degrees C eggs to which the drug was given on day 25 hatched into males. These results suggest that though high temperature has no direct effect on sex determination in this species, it may have a stimulatory effect on aromatase activity, leading to the conversion of the exogenously applied testosterone into estradiol and permitting ovarian differentiation in the genic females. It also follows from the present report that the pathway of testis formation in Calotes versicolor is triggered much earlier, and irreversibly, than that for the ovary.     

Interspecific and intraspecific variations in egg hatching for British populations of the stoneflies Siphonoperla torrentium and Chloroperia tripunctata (Plecoptera: Chloroperiidae)

SUMMARY 1. The objective was to compare variations in egg hatching between the two species (interspecific variations) and between populations of the same species (intraspecific variations). There were significant interspecific, but not intraspecific, differences in female size, adult life-span, egg production, hatching success, incubation periods and hatching periods.
2. The optimum temperature for hatching success within the range 3.8–22.1°C in the laboratory and the range over which at least 50% of the eggs hatched were lower for Chloroperia tripunctata (Scopoli) (8.5°C, 4.2–17.3°C) than for Siphonoperla torrentium (Pictet) (12.8°C, 6.1–19.4°C). Few eggs hatched at 22.r°C.
3. The relationship between incubation period (d days) and water temperature (T°C) was given by: d=1219/T^1.368 for S. torrentium , d=253/T^0.459 for C. tripunctata . Both equations successfully predicted incubation periods for eggs placed in a stream. The period over which eggs hatched was much longer for C. tripunctata than for S. torrentium at all temperatures.
4. The shorter incubation period (at r>5.6°C) and shorter hatching period for S. torrentium ensure that larvae of this species are already growing when eggs of C. tripunctata start to hatch, but the prolonged hatching period of the latter species ensures a long period of larval recruitment to the population. These differences in egg hatching may reduce competition between the two closely-related species.     

Lethal combat and sex ratio evolution in a parasitoid wasp

Sex allocation theory provides excellent opportunities for testinghow behavior and life histories are adjusted in response toenvironmental variation. One of the most successful areas fromthis respect is Hamilton's local mate competition theory. Aspredicted by theory, a large number of animal species have beenshown to adjust their offspring sex ratios (proportion male)conditionally, laying less female-biased sex ratios as the numberof females that lay eggs on a patch increases. However, recentstudies have shown that this predicted pattern is not followedby 2 parasitoid species in the genus Melittobia, which alwaysproduce extremely female-biased sex ratios. A possible explanationfor this is that males fight fatally and that males producedby the first female to lay eggs on a patch have a competitiveadvantage over later emerging males. This scenario would negatethe advantage of later females producing a less female-biasedsex ratio. Here we examine fatal fighting and sex ratio evolutionin another species, Melittobia acasta. We show that femalesof this species also fail to adjust their offspring sex ratioin response to the number of females laying eggs on a patch.We then show that although earlier emerging males do have anadvantage in winning fights, this advantage 1) can be reducedby an interaction with body size, with larger males more likelyto win fights and 2) only holds for a brief period around thetime at which the younger males emerge from their pupae. Thissuggests that lethal male combat cannot fully explain the lackof sex ratio shift observed in Melittobia species. We discussalternative explanations.     

Against the odds? Nestling sex ratio variation in green-rumped parrotlets

We investigated nestling sex ratio variation in the green-rumpedparrotlet (Forpus passerinus), a small neotropical parrot breedingin central Venezuela. There are strong theoretical reasons topredict a female-biased sex ratio in this system according tothe local resource hypothesis; juvenile males are philopatricand there are high levels of competition between male siblingsfor access to breeding females. Data were collected from twobreeding sites over a 14-year period incorporating 564 broodswith a total of 2728 nestlings. The mean percentage of malenestlings across years was 51%. Despite extreme hatching asynchronyin this system and increased survival of earlier hatched offspring,there was no bias in sex allocation associated with egg sequence.Patterns in sex allocation were not associated with clutch size,age, or size of the breeding female or breeding site. The potentialfor selective resorption of eggs was considered; however, nosignificant relationship was found between extended laying intervalsand the sex of subsequent eggs. Together, these results suggestthat female parrotlets are unable to regulate the sex ratioof their clutch at laying or that facultative manipulation ofnestling sex ratio may not confer a fitness benefit to breedersin these populations.     

The Function of Embryonic Vocalization in the Little Tern (Sterna albifrons)

Various functional explanations can be proposed for the evolution of bird embryonic vocalizations during the pre-hatching period, namely: 1. To elicit switching of parents from incubation to parental behaviour typical of the chick period; 2. To allow thermoregulation of embryos by soliciting parents to incubate; or 3. To establish parent—offspring individual recognition. In this paper, we present the results of field experiments designed to test hypotheses 1 and 3 in the colonial, ground-nesting little tern. Parents that had their hatching eggs cross-fostered with foreign eggs at the same hatching stage exhibited a parental behaviour similar to unmanipulated controls. Parents that incubated foreign eggs up to a stage in which embryos were not yet vocalizing, and were challenged with their own hatching eggs that had been incubated in foster nests, performed less efficient parental cares than unmanipulated control pairs and pairs that had cross-fostered hatching eggs. The results do not support the hypothesis of early individual recognition and suggest that embryonic vocalizations in little terns have the function of promoting switching of parents from incubation to accepting and feeding hatchlings. Similar to other tern and gull species, the duration of incubation period in the little tern varies markedly among pairs and years. In these species, embryonic vocalizations can be adaptive since they provide parents a cue to switch at a proper time from incubation to parental cares typical of the chick period.     

Hatching order and sex ratio in Southern Grey Shrike Lanius meridionalis in relation to clutch size

Despite major advances in sex ratio theory, how offspring sex should vary with hatching order remains unclear. We examine nestling sex ratio in the Southern Grey Shrike Lanius meridionalis according to hatching order and clutch size. Southern Grey Shrike nestlings present a different sex ratio with body‐mass rank order depending on clutch size. When the clutch size was five eggs (with a very low risk of brood reduction; 13%) the less costly sex (male) was found at the end of the body mass hierarchy. However, when clutch size was six eggs (with a high risk of brood reduction; 42%) the larger sex (female) was found at intermediate positions in the hatching order, possibly to decrease competitive asymmetries.