The first proof of a possibility of change of temperature norms of insect development as a result of artificial selection for fast or slow development by the example of the red soldier bug <Emphasis Type="Italic">Pyrrhocoris apterus</Emphasis> (Heteroptera,Pyrrhocoridae)

For 3–4 generations, selection of the nymphs most rapidly and slowly developing at 28°C was performed in four families of the red soldier bug Pyrrhocoris apterus L. In each generation, duration of development of nymphs was determined at 5 constant temperatures from 20°C to 28°C. From these data the linear regression coefficient of the development rate against temperature (the development thermolability coefficient) for each generation was calculated. As a result of the selection the average duration of the nymph development was shortened or increased statistically significantly depending on its direction. The artificial selection for the development duration has been established to change not only this parameter, but also the temperature norms of the insect development. At selection for fast development the regression straight line slope (i.e., the regression coefficient value) increased statistically significantly, i.e., development became more dependent on temperature. As a rule, the temperature threshold of development increased. At selection for slow development the values of the regression coefficient and of the threshold decreased, but these differences were not statistically significant. The effect of artificial selection for the development duration on temperature norms of insect development has been revealed for the first time.     

The first proof of a possibility of change of temperature norms of insect development as a result of artificial selection for rapid or slow development by the example of the red soldier bug Pyrrhocoris apterus (Heteroptera: Pyrrhocoridae)

For 3-4 generations, selection of the most rapidly and slowly developing nymphs at 28 degrees C was performed on four families of the red soldier bug Pyrrhocoris apterus L. In each generation, duration of development of nymphs was determined at 5 constant temperatures from 20 degrees C to 28 degrees C. From these data there were calculated the linear regression coefficient of the development rate for temperature (the coefficient of the thermolability of development) and the temperature development threshold for each generation. As a result of the selection the mean duration of the nymph development was shortened or increased statistically significantly depending on its direction. The artificial selection for the development duration has been established to change not only this parameter, but also the temperature norms of the insect development. At selection for rapid development the regression line scope (i. e., the regression coefficient value) increased statistically significantly, i. e., development became more dependent on temperature. The temperature threshold of development increased. At selection for slow development the values of the regression coefficient and of the threshold decrease, but these differences were not statistically significant. The effect of artificial selection for duration of development on temperature norms of insect development has been revealed for the first time.     

Comparative study of thermal reaction norms for development in ants

This is the first compilation of our research and data from the literature on the duration and thermal reaction norms for development in ants. Altogether, 97 regression lines characterizing the linear dependence of ant brood (egg, larval, prepupal and pupal) development on temperature were obtained for 33 species from 15 genera and three subfamilies. Significant positive correlations between the durations of different immature stages were revealed. We found differences between thermal reaction norms for development for various immature stages, some taxonomic groups, and southern and northern groups of species. All immature stages appeared to be shorter on average at 25°C in northern ants compared to southern species; this difference is insignificant only for eggs. Highly significant negative correlations were revealed between the temperature threshold for development (TTD) and the sum of degree‐days (SDD) for all immature stages. The latitudinal trends in intraspecific variation of thermal constants appeared to be opposite to those we observed at the interspecific level. At the latter, the coefficient of thermal sensitivity of development (i.e. the coefficient of linear regression of development rate on temperature) and TTD tends to decrease and SDD to increase from the south to the north. In contrast, at the intraspecific level, development became more temperature‐sensitive in northern populations, i.e. characterized by higher slopes of regression lines of development rate on temperature, and higher TTDs. The species of the genus Formica are characterized by the shortest and the most temperature‐sensitive immature development among all the ant species studied.     

Resistance to thermal stress in preadult Drosophila buzzatii: variation among populations and changes in relative resistance across life stages

Resistance to a short term exposure to a high temperature stress was examined in eggs, larvae and pupae of Drosophila buzzfltii from seven localities. Across development, pupae were most resistant, followed by eggs, and then first and third-instar larvae. Variation among populations for resistance to heat stress was significant in all life stages. However, there was much less variation among populations where measured as eggs and pupae than for both first and third instar larvae. Older larvae showed large changes both in viability and developmental time, while exposure of young larvae to heat stress led to a decline in viability without delayed development. Populations that had the shortest developmental time at 25^oC were relatively the most resistant to heat stress as larvae. High relative resistance at one preadult life stage was not necessarily associated with relatively high resistance at another, or with previous measurements of resistance for adults from these populations. Comparison of populations that were more similar in their pattern of change in resistance across development suggested a relationship with the climate of origin. The possibility that developmental variation in the expression of heat shock proteins may cause variation in resistance to thermal stress for different life stages is discussed.     

The seasonal development cycle of <Emphasis Type="Italic">Aphantopus hyperantus</Emphasis> (L.) (Lepidoptera,Nymphalidae: Satyrinae) in Leningrad Province

The simultaneous influence of the photoperiodic and temperature conditions on pre-diapause and postdiapause larval development of the ringlet Aphantopus hyperantus was studied. At the short day (12 h of light a day) all larvae reached the III instar and entered diapause at all the temperatures tested (18–24°C). At the long day (22 h) the number of diapausing larvae increased with decreasing temperature, and the larvae diapaused at the III and IV instars. The I and II instar larvae (before winter) developed and grew faster under short-day, and the hibernated larvae, under long-day conditions. At the short day the growth rate of the I and II instar larvae did not depend on the temperature, and at the long day it decreased as the temperature increased. After hibernation the growth rate of the IV instar larvae increased with the temperature under long-day conditions, and did not depend on the temperature under short-day ones. Thus, acceleration or deceleration of development, depending on the photoperiodic and temperature conditions, regulated the timing of diapause in the overwintering stage (the III instar larva) and maintained the univoltine seasonal cycle. The males of A. hyperantus developed and grew faster than females while their weight at the larval and pupal stages was smaller. The thermal reaction norms for development (the lower temperature threshold and the coefficient of thermal sensitivity of development) were calculated for the eggs, IV and V instar larvae, and pupae. The coefficient of thermal sensitivity of development for the IV and V instar larvae taken together was lower, and the threshold was higher than the corresponding values for eggs and pupae. The thermal reaction norms for development of the latter stages were the same. The larvae of A. hyperantus retained their sensitivity to the photoperiod after hibernation. Resumption of development after cold reactivation occurred only under long-day conditions, whereas under short-day ones the overwintered larvae entered a repeated diapause. The possibility of photoperiodic reactivation and the absence of spontaneous resumption of development in these larvae were demonstrated.     

Genetic variation in the life‐history traits of Epiphyas postvittana: population structure and local adaptation

The light brown apple moth, Epiphyas postvittana (Walker) shows high intraspecific variability in morphological, physiological, demographic and behavioural characters. To gain insight into the extent of adaptation and evolutionary changes in response to environmental heterogeneity in this species, quantitative genetic analyses of life‐history variation were conducted for two natural populations under two thermal conditions (23°C and 28°C). Paternal half‐sib heritability and genetic correlation in six life‐history traits (i.e. development time, adult body weight, adult lifespan, age at first reproduction, the number of eggs laid during the first 5 days after emergence, and total fecundity) were compared. Significant heritabilities were shown consistently in development time; this is also true for adult body weight, except for the Canberra population at 23°C. However, neither population differences nor the effect of temperature were statistically detectable for any of these heritabilities, confirming the genetically determined flexibility. Positive genetic correlations between development time and adult body weight, and negative genetic correlations between the number of eggs laid during the first 5 days and adult lifespan were present for these populations at both temperatures, indicating the presence of genetic constraints. Pairwise comparisons of genetic correlations revealed the heterogeneity of the two populations and across temperatures. These results suggest that the structure of genetic covariance might have changed significantly during the divergence of natural populations and in response to the alteration of environmental conditions in E. postvittana.     

Old wine in new bottles: reaction norms in salmonid fishes

Genetic variability in reaction norms reflects differences in the ability of individuals, populations and ultimately species to respond to environmental change. By increasing our understanding of how genotype × environment interactions influence evolution, studies of genetic variation in phenotypic plasticity serve to refine our capacity to predict how populations will respond to natural and anthropogenic environmental variability, including climate change. Given the extraordinary variability in morphology, behaviour and life history in salmonids, one might anticipate the research milieu on reaction norms in these fishes to be empirically rich and intellectually engaging. Here, I undertake a review of genetic variability in continuous and discontinuous (threshold) norms of reaction in salmonid fishes, as determined primarily (but not exclusively) by common-garden experiments. Although in its infancy from a numerical publication perspective, there is taxonomically broad evidence of genetic differentiation in continuous, threshold and bivariate reaction norms among individuals, families and populations (including inter-population hybrids and backcrosses) for traits as divergent as embryonic development, age and size at maturity, and gene expression. There is compelling inferential evidence that plasticity is heritable and that population differences in reaction norms can reflect adaptive responses, by natural selection, to local environments. As a stimulus for future work, a series of 20 research questions are identified that focus on reaction-norm variability, selection, costs and constraints, demographic and conservation consequences, and genetic markers and correlates of phenotypic plasticity.     

From a descriptive toward an explicative growth-based model on immature Oulema duftschmidi (Coleoptera: Chrysomelidae) development at different temperatures

The developmental rates of Oulema duftschmidi (Redtenbacher) eggs, larvae, and pupae were studied at different constant temperatures. A linear regression model was fitted to the data obtained in this and in a previous study within a temperature range where the rate proportionally increases with temperature. Ratios of SEs to the mean thermal constant and to the mean developmental threshold indicated that reliable estimates have been obtained for the three life stages. Within the framework provided by the metabolic theory of ecology, a growth-based model was evaluated to explain developmental rates in the entire temperature range permissive of development of the three life stages. The model is based on component functions describing growth patterns through time, temperature-dependent consumption rates of biomass, transformation of consumed food into body biomass change, and respiration rates with respect to temperature. Experimental data were used for the selection and validation of models and for the estimation of the parameters of different regression models. Limitations and opportunities for using the growth-based model to explain developmental rates are discussed. An empirical function was used to describe the variability of developmental rates.     

温度对巨膜长蝽生长发育与繁殖的影响

【目的】近年来巨膜长蝽Jakowleffia setulosa (Jakovlev)由稳定种群的荒漠昆虫上升为暴发性发生并迁移至农区危害的农业害虫。由于缺乏巨膜长蝽生物学基础研究,给监测预警及综合防治带来许多困难。本研究旨在探明温度对巨膜长蝽发育和繁殖的影响。【方法】本实验以白茎盐生草Halogeton arachnoideus Moq.为寄主植物,分别在7个恒温（13,18,23,28,33,35和37℃）下研究了温度对巨膜长蝽各虫态平均发育历期、发育速率、成活率、产卵量和种群参数的影响。【结果】在13~37℃范围内,各虫态的发育历期随温度的升高而缩短,13℃完成一个世代发育需要82.63 d,37℃只需要14.61 d。各虫态的发育速率（V）与温度（T）的关系均符合多项式回归模型,且极显著相关。采用直接最优法分析,巨膜长蝽世代的发育起点温度为8.30℃,有效积温为555.77日·度,在宁夏一年可发生2代。巨膜长蝽世代存活率均在33℃时最高,为35.44%。28～37℃之间单雌产卵量较多,达到10粒以上,通过方程拟合得到理论上雌虫产卵最适温度为34.59℃,产卵量最高可达到16.73粒/雌;种群趋势指数在13℃为零,18～23℃小于1,种群呈负增长;28～37℃大于1,且33℃时最高,为2.77;净增殖率、内禀增长率及周限增长率均在37℃时最高,分别为7.24, 0.3912和1.4787;种群世代周期以13℃时最长,为45.8936 d,37℃时最短,为5.0608。【结论】巨膜长蝽在28～35℃下存活率、增长指数和繁殖力较高,说明该温度范围是巨膜长蝽生长发育和繁殖的适宜温度。本研究为有效开展巨膜长蝽的监测预报及综合防控提供了科学依据。     

不同温度对三叶虫萤卵孵化和初孵幼虫发育的影响

本文研究了三叶虫萤Emeia pseudosauteri在不同恒温设置和室内变温条件下卵孵化率和初孵幼虫存活率,并通过直接最优法和直线回归法计算出了三叶虫萤卵的发育起点温度和有效积温。结果表明:12~30℃恒温条件下,卵的孵化率随着温度升高显著下降(P<0.05),且均低于室内变温条件(P<0.05)下的孵化率;初孵幼虫在恒温15℃下的存活率最高,为73.13%;低于12℃和高于30℃恒温中初孵幼虫均无法存活;在恒温条件12~30℃下,卵的发育历期随温度升高而缩短,其中恒温12℃下最长,发育历期为42.96 d(n=3),恒温30℃下最短,发育历期仅12.75 d(n=3)。通过直接最优法计算出三叶虫萤卵的发育起点温度为3.52℃,有效积温分别为382.20 d·℃。上述结果为三叶虫萤的人工繁育提供了参考。     

桃小食心虫的发育起点温度和有效积温

在17～29℃、RH80%±7%和光周期L:D=15:9的条件下,测定了桃小食心虫Carposina sasakii Matsumura各虫态的发育历期,计算了桃小食心虫卵、幼虫、蛹和全世代的发育起点温度和有效积温。结果表明,各虫态的发育历期随着温度的升高而缩短,各虫态的发育速率与温度之间具有良好的线性关系。桃小食心虫卵、幼虫、结茧前期、蛹及生殖前期的发育起点温度分别为10.02、9.44、10.58、10.09和9.51℃,有效积温分别为87.3、238.6、10.7、156.9和31.6日·度,全世代的发育起点温度和有效积温分别为9.22℃和543.2日·度。     

Ontogenetic changes in genetic variances of age-dependent plasticity along a latitudinal gradient

The expression of phenotypic plasticity may differ among life stages of the same organism. Age-dependent plasticity can be important for adaptation to heterogeneous environments, but this has only recently been recognized. Whether age-dependent plasticity is a common outcome of local adaptation and whether populations harbor genetic variation in this respect remains largely unknown. To answer these questions, we estimated levels of additive genetic variation in age-dependent plasticity in six species of damselflies sampled from 18 populations along a latitudinal gradient spanning 3600 km. We reared full sib larvae at three temperatures and estimated genetic variances in the height and slope of thermal reaction norms of body size at three points in time during ontogeny using random regression. Our data show that most populations harbor genetic variation in growth rate (reaction norm height) in all ontogenetic stages, but only some populations and ontogenetic stages were found to harbor genetic variation in thermal plasticity (reaction norm slope). Genetic variances in reaction norm height differed among species, while genetic variances in reaction norm slope differed among populations. The slope of the ontogenetic trend in genetic variances of both reaction norm height and slope increased with latitude. We propose that differences in genetic variances reflect temporal and spatial variation in the strength and direction of natural selection on growth trajectories and age-dependent plasticity. Selection on age-dependent plasticity may depend on the interaction between temperature seasonality and time constraints associated with variation in life history traits such as generation length.     

温度对产虫茶昆虫紫斑谷螟生长发育的影响

为探明温度对贵州主要产虫茶昆虫紫斑谷螟Pyralis farinalis (Linnaeus)生长发育的影响, 本研究以白茶Litsea coreana为寄主植物, 分别设置5个恒温（19, 22, 25, 28和31℃）条件, 研究温度对紫斑谷螟卵、 幼虫、 蛹和未成熟期平均发育历期、 发育速率和存活率的影响, 计算各虫态发育起点温度和有效积温。 结果表明： 温度对紫斑谷螟各虫态发育历期、 发育速率和存活率影响显著。 在19 ~ 31℃范围内, 各虫态的平均发育历期均随温度的升高而缩短, 卵期、 幼虫期、 蛹期及未成熟期均在31℃达到最小值, 分别为4.56±0.24, 43.33±1.50, 7.89±0.20和55.78±1.69 d。 紫斑谷螟各虫态发育速率与温度呈二次回归关系, 且极显著相关。 此外, 温度显著影响各虫态存活率, 卵的存活率在28℃时最高, 为93%; 幼虫和蛹的存活率则在25℃最高, 分别为88%和93%; 温度过高或过低均不利于其生长发育。 由直接最优法计算得到紫斑谷螟卵期、 幼虫期、 蛹期及未成熟期的发育起点温度分别为13.30, 15.48, 13.19和14.82℃, 有效积温依次为88.36, 679.51, 159.73和952.04日·度。 这些结果为紫斑谷螟的繁殖提供了基础参考数据, 对指导虫茶生产有实用参考价值。     

Thermal requirements of Galleria mellonella L. (Lepidoptera: Pyralidae) immature stages

The rearing of Galleria mellonella L. in laboratory is important for multiplication of entomopathogenic nematodes, mandatory for biological control studies. The objective of this study was to evaluate the effect of three thermal profiles on development stages of this insect, allowing synchronization of cycle production. Two distinct rearing phases were done: firstly, using nucleous of incubation for development of eggs and, secondly, using circular-aluminum manifolds for development of larvae and pupae. The time necessary for development of the immature stages decreased with higher temperatures. Incubation periods lasted 13.4 days at 22 degrees C, 8.3 at 27 degrees C and 6.8 days at 32 degrees C, while periods for larvae development lasted 40.4, 27.2, and 23.4 days, respectively, for the same temperatures. Development to pupal stage was observed 18.2, 15.0, and 12.2 days, respectively, for the same temperatures. Larval survival was higher at 32 degrees C, however embryonic stages and pupae survival were higher at 27 degrees C. and 22 degrees C, respectively. The threshold temperature was 11.209167 degrees C for the embryonic development stage, 7.695869 degrees C for larval stage, and 1.943050 degrees C for pupal stage of G. mellonella. Thermal constants were 138.380533 DG (degree day) for egg, 554.968830 DG for larvae, and 369.054080 DG for pupae.     

Temperature effects on the anchoveta <Emphasis Type="Italic">Engraulis ringens</Emphasis> egg development: do latitudinal differences occur?

We assessed differences in the development rates among anchoveta, E. ringens populations from the extremes of its range under different temperatures. Time to hatch decreased with increasing temperature but there was no difference in the temperature–development time relationship between eggs from different localities. These results and observations of hatching success differences between populations at lower temperatures support the hypothesis that inter-population differences in the earlier life stages occur along the distribution range of anchoveta, although the current genetic evidence suggests substantial gene flow between localities.     

Effects of temperature on the development and reproduction of sugarcane top borer Scirpophaga excerptalis (Lepidoptera: Pyralidae)

To determine the effects of temperature on the development and reproduction of top borer Scirpophaga excerptalis Walker (Lepidoptera: Pyralidae), the durations of different developmental stages and reproductive capacity of S. excerptalis were measured at 20, 23, 26, 29 and 32℃. The results showed that the average durations of various developmental stages of S. excerptalis shortened with increasing temperatures from 20 to 32℃. The durations to complete one life cycle were 113.17 days at 20℃, and 39.50 days at 32℃. The developmental rate of each stage and generation was positively correlated with the temperature, which was consistent with the Logistic regression model. The temperature thresholds for egg, larval, pupal and preoviposition stages and the total cycle were 13.73, 14.73, 13.91, 13.66 and 14.10℃, respectively. The effective accumulative temperature was 112.62, 370.01, 188.17, 23.82 and 718.07 degree-days (DD), respectively. The adult longevity shortened with increasing temperatures, and the highest number of eggs laid per female was 204.74 eggs at 29℃. The survival rates of eggs, larvae and the whole generation were the highest at 26℃, which were 87.25%, 56.67% and 37.21%, respectively while the highest survival rate of the pupa was 76.69% at 29℃. There was no significant difference for the total cycle at 23-29℃. The results indicated that temperature was the key factor affecting the development and reproduction of S. excerptalis, and the optimum temperature for development and reproduction ranged from 23 to 29℃.     

Egg allocation by Bracon hylobii Ratz., the principal parasitoid of the large pine weevil (Hylobius abietis L.), and implications for host suppression

1 The braconid parasitoid Bracon hylobii Ratz. is one of the few specialist natural enemies of the large pine weevil, Hylobius abietis L., a destructive pest of conifer transplants. An assessment of its role as an agent of biological control requires a detailed knowledge of the allocation of its reproductive effort. 2 Parasitoid females were continuously observed in laboratory culture with individually reared host larvae in bark discs. The outcome of sequential parasitoid–host encounters was recorded by subsequent examination of hosts and by rearing all parasitoids. 3 Parasitoids avoided ovipositing on host larvae < 100 mg fresh weight, even though such larvae represented sufficient biomass for complete parasitoid development. All larger larvae were vulnerable to attack, which leaves a window of vulnerability for parasitoids of about 90% of weevil larval life. 4 Parasitoids presented with a range of host sizes showed no preference above 100 mg for the size of host first attacked, but allocated more eggs and a greater total handling time to larger hosts. 5 Most eggs were deposited on the first host attacked, with progressively fewer allocated to subsequent hosts. However, oviposition experience did not affect the time spent on the next host. 6 From these results it is anticipated that when weevil larval size is reduced by less favourable feeding substrates, fewer parasitoid eggs will be allocated to each but more host larvae will ultimately be attacked. 7 Generation time, host finding, oviposition rate, clutch size, life expectancy and diapause induction are strongly affected by temperature. Life expectancy is substantially shorter for parasitoids deprived of non‐host food supplement. At 15 and 20 °C the number of hosts attacked and the number of eggs deposited decreased with female age. 8 Bracon hylobii is inevitably poorly synchronized with a variable life‐cycle host; it is egg‐limited and can enter diapause at a relatively high field temperature. None of these characteristics suggest that it could stabilize the abundance of its host below an economically acceptable threshold density. However, the reproductive potential of the parasitoid suggests that it could make a significant contribution to larval mortality and suppress adult recruitment, thus complementing other control strategies.     

Development, survival, and oviposition of the rabbit tick, Haemaphysalis leporispalustris (Packard) (Acari: Ixodidae), at constant temperatures

The relationship between development, survival, and oviposition rates, and five constant temperatures is described for the developing and reproductive life stages of the rabbit tick, Haemaphysalis leporispalustris (Packard). Development was most rapid at 29.7 C for egg and larvae, and 35.6 C for nymphs. Survival was greatest between 14.7 and 29.7 C, but was reduced at 35.6 C for eggs and larvae. Oviposition was optimal between 19.9 and 29.7 C with a maximum mean daily oviposition of 253 eggs/female/day on the third day of oviposition at 29.7 C. Maximum mean total eggs per female produced was 1,157 with a range of 277 to 3,327. The total number of eggs produced per female correlated with the weight of the engorged female. Both linear and sigmoid curve equations were used to approximate the relationship between the temperature and development rates of eggs, larvae, and nymphs. The nymphs had the highest heat requirements of the 3 development stages. Comparisons with field host-parasite data indicate that the rabbit tick has a 2-yr life cycle in southwestern Nova Scotia.     

Modelling temperature-dependent development and survival of Otiorhynchus sulcatus (Coleoptera: Curculionidae)

Abstract 1 We conducted a laboratory experiment to quantify the stage‐specific effects of temperature on development time and survival of Otiorhynchus sulcatus (Fabricius) (Coleoptera: Curculionidae), a serious economic pest of horticultural crops. Quantification of the relationship between stage development and temperature is required to predict seasonal occurrence of particular life stages and to optimize the timing of monitoring and control tactics. 2 Temperature‐dependent survival rate was quantified using an extreme value function and showed a skewed bell shape, due to the vulnerability of the insect to high temperature in all stages. 3 The development times of O. sulcatus decreased with increasing temperature up to 27 °C for eggs and 24 °C for larvae and pupae. The nonlinear relationship between development rate and temperature was described using the Logan model, and enabled us to estimate the optimum temperature for development. 4 The inherent variation of development time was estimated from the cumulative frequency of stage emergence, which was modelled using the cumulative Weibull function. 5 The stage emergence model, which simulated the transition from one stage to the next in relation to temperature and cohort age, was constructed by incorporating stage‐specific survival and development rate submodels with the Weibull model of stage frequency. 6 Our results show a difference in optimal temperature regime among developmental stages of O. sulcatus.     

红棕象甲发育起点温度及有效积温的测定

在室内恒温条件下,观察了不同温度对棕榈红棕象甲Rhynchophorus ferrugineus Fabricius生长发育的影响,并用直线回归法测得产卵前期、卵、幼虫、蛹和全世代的发育起点温度分别为(16.11±1.44)、(14.10±0.56)、(15.28±0.21)、(14.89±0.24)和(14.15±0.54)℃;有效积温分别为(31.86±1.65)、(748.60±15.79)、(417.94±20.80)和(1215.50±28.56)日·度。红棕象甲的各虫态和全世代发育历期随温度的升高而缩短,在测定的温度范围内,全世代发育历期与温度的关系符合指数函数:y=3343e-0.1279x。