Geographical variation in insect developmental period: effect of host plant phenology on the life cycle of the bruchid seed feeder shape Kytorhinus sharpianus

The voltinism of the bruchid Kytorhinus sharpianus Bridwell (Coleoptera: Bruchidae) and the phenology of its host plant Sophora flavescens Aiton (Leguminosae) were observed at four latitudes: Aomori (40°46' N), Obanazawa (38°37' N), Kujiranami (37°21' N) and Mitsuma (36°05' N) in northeastern Honshu (Japan). Kytorhinus sharpianus life cycle ranged from bivoltine and partially trivoltine in the south to univoltine and partially bivoltine in the north. Sophora flavescens started growing later in spring at higher latitudes. However, the relative growth rate was higher in the north (Aomori) than in the south (Mitsuma). In parallel with this, the first-generation of adult K. sharpianus appeared later at higher latitudes. When the four local populations were reared at 24 °C, L16:D8 and 65% r.h., males developed faster than females. The mean developmental time showed a saw-toothed latitudinal cline. The reversion in the latitudinal trend of variation corresponded to the change in the major type of life cycles from univoltine to bivoltine. Two heat units throughout the year and post-fruiting period were calculated as the sums of degree-days above the developmental threshold (12 °C) of K. sharpianus. Both heat units decreased in parallel with each other with increasing latitude. The greater growth rate of hosts in the northern population compensated for the smaller heat units. In addition, when the heat units were divided by the degree-days needed to complete development, the numerical value was the approximate number of generations observed in each locality.     

Optimal seasonal timing of univoltine and bivoltine insects

This study examines the optimal seasonal timing of the life cycle for univoltine and bivoltine insects, assuming that resource availability has a peak in the middle of a year and is symmetric around it. Results show that if the growth rate increases in proporrion to the bodyweight, bivoltine life cannot be optimal. If the growth rate is a power function of the bodyweight with a power smaller than unity, a symmetric bivoltine solution can be the optimal provided that the resource availability has a plateau in the middle of the season. If the resource availability has a sharp peak, the optimal pattern is an asymmetric bivoltine solution in which the larval periods of two generations differ in length. The bivoltine life cycle is more likely to be superior to the univoltine one if: growth is fast, suitable growing season is long, biomass loss during nonlarval stages is small, and egg size is small.     

The coadaptation of female morphology and offspring size: a comparative analysis in crickets

Few studies of invertebrates have considered combinations of morphological and life history traits in the context of the evolution of reproductive strategies. Cricket species that exploit habitats harsh with respect to egg survival have evolved a long ovipositor, presumably because laying deep in the soil reduces egg mortality. Yet hatchling mortality increases with laying depth, and the ability of hatchlings to climb through the soil increases with egg size. Thus a conflict may exist between survival of the egg and that of the hatchling, inducing a positive covariation between egg size and ovipositor length across species evolving under contrasting selective habitats. We used the phylogenetic autocorrelation method and a path analysis to assess whether egg size coevolved with ovipositor length across 40 species of crickets, and whether egg size was affected by body size or ecological factors that influence egg mortality. Body size and ovipositor length were affected by taxonomic association, whereas common ancestry had no significant effect on egg size, diapausing strategy, and oviposition preference for soil types. The path model indicated that 29.11% of the variance in egg size was explained by independent evolution. As expected, ovipositor length was positively correlated with egg size, and species diapausing in the egg stage produced larger eggs than crickets diapausing in the nymphal stage or with no diapause. Ovipositor length and diapausing strategy were the first and second most important traits, respectively, in term of the proportion of variance in egg size explained by specific values. These results support the hypothesis that the ability of hatchlings to climb through the soil, and variation in diapause strategies, are general selective factors affecting the evolution of egg size in crickets. Phylogeny explained 51.01% of the variance in egg size. Egg size in a current cricket species, however, was not directly determined by egg size in its ancestor. Instead, it was strongly related to the phylogenetic values of body size and ovipositor length. Such indirect phylogenetic effects of body size and ovipositor length may have arisen because clades originating from ancestors with different ovipositor lengths experienced different selective pressures on egg size. Recelived: 13 October 1995 / Accepted: 30 September 1996     

Ground crickets singing in volcanic warm “islets” in snowy winter: Their seasonal life cycles,photoperiodic responses and origin

The ground cricket Dianemobius nigrofasciatus overwinters as an egg in Japan, being univoltine in Hokkaido and northern Honshu and bivoltine farther south. In Hokkaido, however, this cricket is heard singing in winter in several fumarolic fields covered with moss and grasses locally known as “bokke”. In such warm “islets” the adult density was high in early summer and again in autumn, indicating that the cricket is bivoltine in contrast to the univoltine life cycle outside the bokke habitats in Hokkaido. Eggs laid by females collected at regular intervals from a bokke habitat showed a clear seasonal cycle of diapause incidence. At 26°C, the bokke strains produced non‐diapause eggs under long days and diapause eggs under short days as in the southern bivoltine populations, although the critical day‐length was longer than in the south. Several strains derived from non‐bokke habitats in Hokkaido and northern Honshu produced high percentages of diapause eggs under long days as well as short days as expected for the univoltine life cycle. Winter adults singing in bokke habitats could be either survivors of the autumn generation or individuals derived from eggs laid in autumn and then matured in response to the high soil temperature. In the laboratory, the proportion of egg diapause in short days was decreased by selection only for several generations. Phylogenetic trees of bokke and non‐bokke populations, based on both the nucleotide sequence of the mitochondrial COI gene and four allozyme loci, suggest that bokke populations have not been isolated from non‐bokke populations for an evolutionarily significant time.     

Life‐history traits related to diapause in univoltine and bivoltine populations of Ypthima multistriata (Lepidoptera: Satyridae) inhabiting similar latitudes

In most temperate insects, diapause strategies and voltinism generally exhibit latitudinal clines, supporting the concept that they represent adaptations to climate. In contrast, in the satyrine butterfly Ypthima multistriata Butler, local populations with different voltinism patterns are geographically intermingled, suggesting that life‐history traits related to diapause may differ even between geographically and phylogenetically close populations. In this study, we experimentally examined the critical photoperiod for diapause induction and the larval developmental period in two univoltine and two bivoltine populations of Y. multistriata, all of which inhabit virtually the same latitude (34.652–34.750°N). We found that the critical photoperiod for diapause induction was longer in the univoltine populations than in the bivoltine populations. Moreover, the larval period under the long day length treatment was different among populations in both sexes, although significant differences were also detected between populations with the same voltinism. These results indicate that in Y. multistriata, life‐history traits related to diapause can not be attributed merely to climatic conditions such as temperature or day length, which depend largely on latitude. Therefore, we suggest that biotic elements, such as leaf toughness, as well as abiotic elements should be taken into account in attempts to explain the enigmatic pattern of geographic variation in the diapause strategies of Y. multistriata.     

ADAPTATION TO SEASONALITY IN A CRICKET: PATTERNS OF PHENOTYPIC AND GENOTYPIC VARIATION IN BODY SIZE AND DIAPAUSE EXPRESSION ALONG A CLINE IN SEASON LENGTH

This paper investigates patterns of phenotypic variation in the striped ground cricket (Allonemobious fasciatus) along a cline in season length and tests the hypothesis that variation in body size and diapause propensity is the result of diversifying selection due to different local conditions. We examined 83 populations and found that A. fasciatus produced a single generation per year (univoltine) north of 37°N latitude and was bivoltine south of 35°30′N. Body size generally increased with increasing season length, with a sudden drop in the region corresponding to the transition from univoltine to bivoltine life cycles, reflecting the division of total season length in two within-bivoltine populations. We reared ten populations in our laboratory and found that much of the interpopulation variance in body size observed in the field could be attributed to genetic differences. Diapause expression also varied significantly among populations and was strongly correlated with season length. The heritability of body size did not differ between populations, but full-sib estimates greatly exceeded parent–offspring estimates suggesting that there are important nonadditive genetic effects. The heritability of diapause expression, determined from analysis of full sibs, varied significantly between populations (0.33 ± 0.10 to 1.31 ± 0.21) with an average of 0.74 ± 0.16. Body size and diapause expression were genetically correlated in transition-zone populations, but not in univoltine or bivoltine populations. Our findings support the suggestion that clinal variation in body size and diapause expression in the striped ground cricket reflect adaptation to season length.     

Ecological and genetic correlates of range expansion in Coenonympha tullia

Range expansion by the North American butterfly species Coenonympha tullia is associated with dramatic changes in life history and in genetic and morphological variation. Eight of ten independent, variable loci exhibit step-clines in allele frequency; step-clines also occur in four wing pattern characters. Populations from the old part of the range are univoltine, and have significantly less genetic and morphological variation than populations from the recently colonized ranger, which arc bivoltine. The concordance of life history with genetic and morphological variation suggests that differences between univoltine and bivoltine populations are maintained by selection. Increased electrophoretic variation in the recently colonized range may have arisen by selection on rare variants within the old part of the range.     

Climatic adaptation and species status in the lawn ground cricket

Summary The cricket tentatively identified as Pteronemobius taprobanensis shows a saw-toothed pattern of variation in adult size along the latitudinal gradient of the Japanese Islands. A slight but abrupt increase in adult size at about 28° N indicates the replacement of the subtropical form by the temperate one. The body size of the latter slightly decreases north to about 33° N, then conspicuously increases to about 39° N and again decreases to the northern extreme. This pattern of variation seems to be related to the local adjustment of nymphal development by means of the photoperiodic response and genetic variation, since the adult size varies as a function of the duration of nymphal development. Multiple regression analysis of the variance between local populations reared at various photoperiods suggests, however, that the decrease in body size due to selection for shorter development in cooler climates is to a certain extent counteracted by selection for a higher rate of growth. The latter component of climatic selection is possibly due to greater egg production by larger-sized females within the shorter reproductive season. This hypothesis may also account for the divergence in size between the two climatic forms of this nominal species.Contribution No. 74 from the Laboratory of Entomology, Hirosaki University     

Quantitative genetics of oviposition behaviour and interactions among oviposition traits in the sand cricket

We performed a quantitative genetic study of oviposition behaviours and oviposition traits in the sand cricket Gryllus firmus. Egg survival in crickets depends on the depth at which they are inserted into the soil with the ovipositor. We examined whether egg depth depends on ovipositor length alone, or on both morphological and behavioural traits associated with oviposition. Heritability estimates were high (h² >0.5) for ovipositor length and small (h²=0.2) for oviposition behaviours. Negative genetic correlations between ovipositor length and some behavioural traits (digging depth and the behavioural component of egg depth) indicated compensation between oviposition traits on egg depth. Because of behavioural compensation, females with different ovipositor lengths subject to stabilizing selection on egg depth could have equal fitnesses. Females laid their eggs deeper, and their eggs were marginally more evenly distributed in dry than in wet sand. This suggests adaptive phenotypic plasticity in laying behaviour, but may also result from physical constraints of the substrate on the insertion of the ovipositor. The absence of significant between-family variation in oviposition traits in response to sand moisture indicates low evolutionary potential for phenotypic plasticity in oviposition traits according to soil moisture. In highly unpredictable environments, females could spread the risk of desiccation by laying eggs at different depths independently of environmental conditions (bet hedging). Our results show significant additive genetic influences on the ability of a female to spread risks as measured by genetic variation in egg distribution, suggesting that a bet-hedging strategy of egg laying has the potential to evolve in this population. Copyright 2002 The Association for the Study of Animal Behaviour. Published by Elsevier Science Ltd. All rights reserved.     

Experiments on the effects of food and density on voltinism in a stream-dwelling water strider (Aquarius remigis)

1. The stream water strider Aquarius remigis shows a latitudinal pattern of variation in voltinism. In general, populations with shorter growing seasons (e.g. in eastern Canada) tend to be univoltine (animals that reach adulthood in the summer overwinter before reproducing in the following spring), whereas populations with somewhat longer growing seasons (e.g. in the north-eastern United States) tend to be bivoltine. 2. This pattern was broken at our study site in the south-eastern United States (Kentucky) where A. remigis had a long growing season, but was almost always univoltine. In summer 1993, however, adult A. remigis in central Kentucky displayed a bivoltine reproductive cycle; i.e. individuals in some pools began breeding shortly after maturing to the adult stage. 3. A field survey documented a negative relationship between local water strider density and reproductive activity in prediapause adults. A laboratory experiment manipulating food availability and density, revealed that animals held at low density with high food levels displayed greater mating activity and egg production than did their counterparts at higher density or lower food levels. 4. A laboratory experiment also showed that high water strider density resulted in a greater frequency of very short pair durations (< 10 min). 5. Although the observed effects of density and food availability on mating activity of prediapause adults seem intuitively reasonable, they differ from the patterns observed in overwintered adults. The difference in reproduction patterns might be due to differences in selective pressures on prediapause vs. post-diapause adults.     

Effect of variation in photoperiodic response on diapause induction and developmental time in the willow leaf beetle, Plagiodera versicolora

The willow leaf beetle, Plagiodera versicolora (Coleoptera: Chrysomelidae) overwinters in adult diapause. In this study, the photoperiodic responses for diapause induction and developmental time were examined in the Ishikari (Hokkaido, Japan) population of P. versicolora. All females entered reproductive diapause under short daylength (L10:D14), but 31.7% of females did not enter diapause under long daylength (L16:D8). The developmental time from oviposition to adult emergence was significantly longer at L10:D14 than that at L16:D8. Norm of reaction curves illustrated variation among families in the photoperiodic responses for diapause induction and for developmental time. ANOVA indicated significant family × photoperiod interactions in the developmental time. At L16:D8, developmental time was positively correlated with the incidence of diapause in females. This means that a female having a longer developmental time tends to have a longer critical photoperiod. Such variation may be maintained by differences in selection pressures on the growth rate and the critical photoperiod for diapause induction between univoltine and bivoltine genotypes because Ishikari is located in a transitional area between populations with univoltine and bivoltine life cycles.     

Variability of photosensitive period and voltinism among populations of a butterfly,Ypthima multistriata,inhabiting similar latitudes and altitudes

In Ypthima multistriata Butler (Lepidoptera: Nymphalidae), there are univoltine and bivoltine populations in adjacent areas with similar climatic conditions. A previous study revealed that larvae of both univoltine and bivoltine populations diapause under a constant short day (i.e., a constant short light period; L13:D11), but not under a constant long‐day condition (L16:D8). However, in both types of populations, adults of an overwintering generation appear and oviposit in June and soon thereafter larvae hatch. Therefore, the younger larvae (at least the first instars) of both types of populations experience a long day; nevertheless, the larvae of univoltine populations diapause in nature. To resolve this inconsistency, we set up two hypotheses: (1) the photosensitive stage of larvae is the second instar or later, and (2) the photosensitive stage of univoltine populations is later than that of bivoltine populations. To test these hypotheses, we performed rearing experiments with two univoltine populations and two bivoltine ones. The results indicated that the photosensitive stage was the second or third instar and that the photosensitive stage was later in one univoltine population than in the two bivoltine populations. Larvae of the other univoltine population diapaused under all conditions. The former result supports our hypothesis, and the latter result indicates that the response to photoperiod is different among univoltine populations. In addition, larval development was slower in one univoltine population than in the bivoltine populations, which also delays the timing of the diapause decision in this univoltine population. Larvae that experienced a long day during the first and middle instars but experienced a short day at the end of their larval stage developed faster than larvae that experienced a constant long day. This may be an adaptation to enable emergence before the start of a cold season that is unsuitable for reproduction.     

Testing hypotheses of adaptive variation in cricket ovipositor lengths

We experimentally tested a series of hypotheses proposed by Masaki (1979, 1986) for the evolution of ovipositor length in crickets. Female crickets use the ovipositor to bury eggs in the soil, where it was hypothesized to protect their eggs from desiccation, cold and other disturbance. However, we found no effect of depth on the overwinter survival of eggs of three species of Nemobiinae. The probability of hatchlings reaching the soil surface was negatively correlated with depth documenting a significant cost to females laying eggs deep in the soil. Hatchling survival may be an important agent of selection on ovipositor length in habitats of different soil moistures. Hatchling survival in the soil was also correlated with body size, which may impose a constraint on egg-size fecundity trade-offs. Females of a bivoltine population of Allonemobius socius lay eggs at shallower depths when reared under summer compared to fall conditions and, therefore, may be able to respond to selection through behavioral plasticity when morphological adaptation is constrained by allometry.     

Diapause and diapause dynamics of Colias alexandra (Lepidoptera: Pieridae)

Summary The mechanisms and adaptations involved in the obligate third instar larval diapause of Colias alexandra, a native Rocky Mountain and intermountain region butterfly, are examined. Generally univoltine throughout its distribution, scattered, isolated bivoltine populations occur. Factors influencing continuous development were investigated under laboratory conditions on a single generation of offspring from a univoltine population each year from 1976–1979. If exposed to mean temperatures >24°C during the second instar, a significant number of larvae fail to diapause. These results are interpreted in the context of the actual environmental conditions experienced by the univoltine source population and a bivoltine population. A high degree of individual variability in response to continuous development conditions is shown. Variation in certainty of diapause, within an originally univoltine population, could be the evolutionary starting point for evolving a genuine multivoltine cueing system and provide the mechanism for ecological range expansion.     

Latitudinal clines in alternative life histories in a geometrid moth

The relative roles of genetic differentiation and developmental plasticity in generating latitudinal gradients in life histories remain insufficiently understood. In particular, this applies to determination of voltinism (annual number of generations) in short‐lived ectotherms, and the associated trait values. We studied different components of variation in development of Chiasmia clathrata (Lepidoptera: Geometridae) larvae that originated from populations expressing univoltine, partially bivoltine or bivoltine phenology along a latitudinal gradient of season length. Indicative of population‐level genetic differentiation, larval period became longer while growth rate decreased with increasing season length within a particular phenology, but saw‐tooth clines emerged across the phenologies. Indicative of phenotypic plasticity, individuals that developed directly into reproductive adults had shorter development times and higher growth rates than those entering diapause. The most marked differences between the alternative developmental pathways were found in the bivoltine region suggesting that the adaptive correlates of the direct development evolve if exposed to selection. Pupal mass followed a complex cline without clear reference to the shift in voltinism or developmental pathway probably due to varying interplay between the responses in development time and growth rate. The results highlight the multidimensionality of evolutionary trajectories of life‐history traits, which either facilitate or constrain the evolution of integrated traits in alternative phenotypes.     

Changes in brain monoamine contents in diapause pupae of Antheraea pernyi when activated under long-day and by chilling

The contents of biogenic monoamines in the brain-subesophageal ganglion complex were measured in both bivoltine and univoltine strains of the Chinese oak silkmoth, Antheraea pernyi using HPLC-ECD. The contents in the bivoltine strain were monitored every five days under LD 12:12 and 16:8, photoperiods maintaining and terminating diapause, respectively at 25°C. The univoltine strain was chilled at 2°C and the monoamine contents were measured at 10-day intervals. Dopamine, norepinephrine and epinephrine-like peaks were detected from the crude homogenate and the eluate from the alumina oxide column. The contents of both dopamine and epinephrine-like compounds dropped significantly before the ecdysteroid surge at LD 16:8 and steadily decreased during cold storage. In contrast, 5-HT increased sharply in parallel with the surge of ecdysteroid. Cold storage also strongly affected indolamine metabolism. After cold storage, 5-HT was more predominantly metabolized by N-acetyltransferase than by monoamine oxidase, since 5-HIAA dropped significantly, while N-acetylserotonin increased during cold storage. A dual regulatory system consisting of the ecdysiotropin inhibitory pathway by catecholamaine metabolism and the ecdysiotropin stimulatory pathway by indolamine metabolism is proposed for the regulation of pupal diapause in this species.     

Fitness consequences of alternative life histories in water striders,Aquarius remigis (Heteroptera: Gerridae)

Using field and laboratory observations and experiments over 3 years, I investigated whether reproductive trade-offs shape individual life histories in two natural populations of the water strider, Aquarius remigis, in which univoltine and bivoltine life cycles coexist. Both later eclosion dates and food shortages, even after adult eclosion, induced diapause in females, thus deferring reproduction to the following spring. Adult body size was positively affected by food availability during juvenile development. Higher food levels also increased the reproductive output of females, but not their longevity or oviposition period. When compared to spring breeders (univoltine life cycle), direct (summer) breeders (bivoltine life cycle) experienced reduced lifetime egg numbers and longevity, as well as reduced survivorship of their second-summer-generation offspring; these reproductive costs offset, at least in part, the advantage in non-decreasing populations of having two generations per year. Fecundity was correlated with body size, and among summer-generation females direct breeders were larger than non-breeders. The time remaining before the onset of winter and/or the time since adult eclosion augmented cumulative energy uptake, and consequently the lipid reserves and winter survival probability of non-breeding (diapausing) summer adults approaching hibernation. Overwintered spring reproductives died at faster rates than non-reproductive summer individuals despite greater food availability in spring, indicating a mortality cost of reproduction. Body length correlated with absolute and not with proportional lipid content but showed no consistent relationship with survivorship in the field. These results are in agreement with current theory on the evolution of insect voltinism patterns, and further indicate high degrees of life history flexibility (phenotypic plasticity) in the study populations in response to variable environmental factors (notably photoperiod and food availability). This may be related to their location in a geographic transition zone from uni- to bivoltine life cycles.     

Univoltine and bivoltine life cycles in insects: A model with density-dependent selection

Selection for univoltine and bivoltine life cycles in insects under resource-limited but favourable temperature conditions is analyzed with a difference equation model including density-dependent population dynamics based on the conceptual framework of an evolutionarily stable strategy. The model predicts that the bivoltine type can spread in a univoltine population when the fraction of density-independent rate of annual increase by producing a second generation exceeds the survival rate during diapause of the univoltine type, but monopoly of the bivoltine type is not possible unless it attains an equilibrium population density exceeding that of the univoltine type. The applicability of the model prediction in explaining the occurrence of a partial bivoltine cycle in predominantly univoltine population in the temperate zones is discussed.     

亚洲玉米螟化性与繁殖力的关系

通过对发生在吉林省的一、二化性玉米螟的繁殖能力研究得出,不同化性越冬代玉米螟的产卵期、成虫寿命、单雌产卵量和最大产卵量差异显著,一化性越冬代玉米螟的产卵量比二化性玉米螟高４５％以上。经虫体大小和重量比较得出,一化性越冬代玉米螟的蛹重比二化性玉米螟的蛹重高３５％以上,人工饲养的一化性玉米螟Ｆ_1代的蛹重也比二化性的蛹重高１０％左右。     

Alternative life histories in the water strider Gerris lacustris: time constraint on wing morph and voltinism

The wing dimorphic water strider Gerris lacustris L. (Heteroptera: Gerridae) switches to a bivoltine life cycle under favorable climatic conditions. The switch in voltinism is accompanied by a reduction of wing development in the directly reproducing midsummer generation, while the diapausing generation has a high fraction of long‐winged individuals. We investigated whether the thermal energy (degree‐days) available in natural habitats constrains the combination of developmental pathway and wing morph. Offspring of G. lacustris were reared under quasi‐natural conditions at two temperature regimes to determine the thermal constant k required to complete adult development in either wing morph. The thermal constant for egg‐to‐adult development of the short‐winged morph was about 20% lower than of the long‐winged morph. Based on the results from the outdoor laboratory experiment, we calculated the total degree‐days necessary to complete the possible combinations of wing morph pattern and voltinism. Comparison of these estimates with the thermal energy actually available during the reproductive season of 2004 for various natural habitats (sun‐exposed field ponds and shaded forest ponds) suggests that voltinism as well as wing morph pattern is strongly limited by the number of degree‐days available in these habitats. On forest ponds, only univoltine life cycles were possible, whereas on field ponds temperature allowed bivoltine life cycles. However, only the eggs laid at the very beginning of the season had the potential to accumulate enough degree‐days to complete a bivoltine life cycle with both generations long‐winged. We conclude that thermal energy is the main environmental constraint limiting voltinism of populations in the two habitat types. Furthermore, the available thermal energy also seems to influence the determination of the seasonal wing pattern in G. lacustris.