Effect of temperature on development rate and intrinsic rate of increase ofAphis gossypii reared on greenhouse cucumbers

Thermal requirements for development and life table statistics ofAphis gossypii Glover (Homoptera, Aphididae) were determined over a range of constant temperatures from 10 to 30°C. The lower development threshold and the sum of effective temperatures were 6.9°C and 90.1°C, respectively, for preimaginal development, and 5.8°C and 113.6°C from birth to the onset of reproduction. Mean total fecundity ranged from 36 larvae per female at 10°C to 76 larvae at 30°C. On a time scale of days, net reproductive rate (R _o ) increased with increasing temperature while generation time (T) decreased causing the intrinsic rate of increase (r _m ) to increase linearly from 0.115 to 0.465. On a day-degree scaler _m only varied from 0.019 to 0.028 because the growth ofR _o was compensated by an increase inT with increase in temperature. The nearly constantr _m in terms of day-degrees, over a wide range of temperatures, greatly simplifies the prediction of future population numbers ofA. gossypii.     

Effects of temperature on the development and survival of an endangered butterfly,Lycaeides argyrognomon (Lepidoptera: Lycaenidae) with estimation of optimal and threshold temperatures using linear and nonlinear models

The effects of temperature on the development and survival of Lycaeides argyrognomon were examined in the laboratory. The eggs, larvae and pupae were reared at temperatures of 15, 17.5, 20, 25, 30 and 33°C under a long‐day photoperiod of 16‐h light and 8‐h darkness. The survival rates of the first–third instars ranged from 40.0 to 82.4%. The mortalities of the fourth instar were lower than those of the first–third instars. The development time of the overall immature stage decreased from 78.33 days at 15°C to 21.07 days at 30°C, and then increased to 24.33 days at 33°C. The common linear model and the Ikemoto–Takai model were used to estimate the thermal constant (K) and the developmental zero (T₀). The values of T₀ and K for the overall immature stages were 10.50°C and 418.83 degree‐days, and 9.71°C and 451.68 degree‐days by the common model and the Ikemoto–Takai model, respectively. The upper temperature thresholds (T_max) and the optimal temperatures (T_opt) of the egg, the first–third instars and the overall immature stages were estimated by the three nonlinear models. The ranges of T_opt estimated were from 30.33°C to 32.46°C in the overall immature stages and the estimates of T_max of the overall immature stages by the Briere‐1 and the Briere‐2 models were 37.18°C and 33.00°C, respectively. The method to predict the developmental period of L. argyrognomon using the nonlinear models was discussed based on the data of the average temperature per hour.     

Growth energetics in relation to temperature for larvae of four species of necrophagous flies (Diptera: Calliphoridae)

The growth characteristics of the larvae of the major members of a necrophagous fly guild in Tasmania (Lucilia cuprina, Calliphora stygia, Calliphora vicina and Calliphora hilli) were measured to assess their competitive ability. The measurements were made at temperatures between 10 and 45°C, to cover the range of temperatures that would be encountered by larvae in carrion or myiasis under field conditions. The characteristics measured were net production and respiration. The indices K_2i (instantaneous growth efficiency), K_2c (cumulated growth efficiency) and M_i (instantaneous cost of maintenance) were calculated. Generally K_2c and K_2i are highest and M_i lowest at 25°C for all the species. A sinusoidal response in K_2c, K_2i and M_i against temperature is seen for L. cuprina, C. stygia and C. vicina. This response is‘cold’adapted in the Calliphora species and‘warm’adapted in L. cuprina. Egg size, egg caloric density and the energy content of the eggs are discussed in relation to the‘fitness’and reproductive strategies of the four species. The thermal tolerance range of L. cuprina determined here suggests that carrion may provide a significant number of this fly particularly in areas where Chrysomya spp. do not occur, and in large carcasses where temperatures are elevated.     

Temperature‐dependent development of the double‐spined spruce bark beetle Ips duplicatus (Sahlberg, 1836) (Coleoptera; Curculionidae)

相似文献   

The effects of temperature on development of the large narcissus fly (Merodon equestris)

Eggs, larvae, pupae and adults of the large narcissus fly (Merodon equestris) were reared at a series of constant temperatures between 9–24°C. Egg development required from 37 days at 9°C to 7 days at 21.5°C. The low-temperature threshold for development was 6.7°C. Larvae reared at 1424°C were fully-grown after 18 weeks, but it took much longer for such insects to pupate, and adult flies emerged only after about 45 weeks of development. Large narcissus flies enter diapause during the larval stage and overwinter as fully-fed larvae, forming pupae in the following spring. Post-winter pupation and pupal development took from 169 days at 10°C to 36 days at 21.5°C. Of this, pupal development required from 91 days at 10°C to 19 days at 21.5°C. The low-temperature threshold for post-winter pupation and pupal development was 7.1°C, and for pupal development alone, 7.2°C. Females maintained at or below 19°C laid few eggs, whereas some females kept at or above 21.5°C laid more than 100 eggs (mean 69 ± 36). Approximately 50% of females maintained at or above 21.5°C laid less than 10 eggs during their lifetime. The mean egg-laying time was 6 to 9 days. Although temperatures at or below 19°C inhibited mating, once a female had mated, such temperatures did not prevent oviposition.     

温湿度对烟青虫实验种群的影响

对烟青虫Helicoverpa assulta(Guenee)在不同温湿度条件下的发育历期、生存率、繁殖力进行了研究.在20℃、24℃、28℃、32℃和36℃恒温下,世代存活率分别为23.28%、 37.04%、44.22%、30.21%和8.28%,种群趋势指数分别为3.45、65.68、72.57、30.69 和0.卵期、1-6龄期幼虫、预蛹和蛹的发育起点温度分别是12.03℃,10.39℃、8.97℃、 8.96℃、10.87℃、11.23℃、9.16℃、11.40℃和10.69℃,有效积温分别是47.62日度、56.46 日度、44.30日度、40.57日度、26。26日度、33.94日度、64.61日度、34.50日度和202.45日度。每天4h 39℃以上高温对烟青虫的存活和繁殖不利。在28℃和32℃下,湿度可影响初龄幼虫、预蛹和蛹的存活,但对历期的影响不大。     

Temperature‐dependent development of Neoseiulus barkeri (Acari: Phytoseiidae) on Tetranychus urticae (Acari: Tetranychidae) at seven constant temperatures

Abstract The effect of seven constant temperatures of 15, 20, 25, 27, 30, 35 and 37°C on developmental time of Neoseiulus barkeri Hughes were determined in laboratory conditions under 65%± 5% RH and a photoperiod of 12 : 12 (L : D) h on nymphal stages of Tetranychus urticae Koch. Total developmental time of females (from egg to adult emergence) at the above‐mentioned temperatures was 26.59, 14.43, 6.32, 5.64, 4.59, 3.98 and 4.67 days, respectively. Developmental rate of the N. barkeri increased as temperature increased from 15 to 35°C, but declined at 37°C. A linear and two nonlinear models were fitted to developmental rate of immature stages of N. barkeri to predict the developmental rate as a function of temperature, as well as to estimate the thermal constant (K) and critical temperatures (i.e., T_min, T_opt and T_max). The estimated values of the T_min and K for total developmental time using the linear model were 12.07°C and 86.20 degree‐days (DD), respectively. The T_min and T_max estimated by the Sharpe‐Schoolfield‐Ikemoto (SSI) model were 11.90°C and 37.41°C, respectively. The estimated T_opt for overall immature stage development of N. barkeri by the Lactin and SSI models were 33.89°C and 24.51°C, respectively. Based on the biological criteria of model evaluation, the linear and SSI models were found to be the best models for describing the developmental rate of overall immature stages of N. barkeri and estimating the temperature thresholds.     

Temperature effects on the development and fecundity of <Emphasis Type="Italic">Encarsia acaudaleyrodis</Emphasis> (Hymenoptera: Aphelinidae), a parasitoid of <Emphasis Type="Italic">Bemisia tabaci</Emphasis> (Homoptera: Aleyrodidae) on cucumber

Development, reproduction, and life table parameters of the parasitoid Encarsia acaudaleyrodis Hayat parasitizing Bemisia tabaci Gennadius were studied at constant temperatures in the range of 20–32°C under laboratory conditions. Egg-to-adult developmental time decreased from 20.3 days at 20°C to 9.0 days at 32°C. An average of 189.8 day-degrees was required to complete development above the lower threshold temperature (11.5°C). Juvenile survival was 84, 88, 70 and 69% at 20, 25, 30 and 32°C, respectively. Females of E. acaudaleyrodis oviposited means of 34.2, 54.6, 30.6 and 20.1 eggs at 20, 25, 30 and 32°C, respectively, and had a mean longevity of 21.1, 14.7, 10.0 and 9.1 days at the same four temperatures. The intrinsic rate of population increase (r_m) at the different temperatures ranged from 0.082 to 0.169, with the highest value recorded at 25°C. These data indicate that E. acaudaleyrodis may be better adapted to intermediate temperatures around 25°C and, therefore, could be a useful biological control agent of B. tabaci during spring and autumn when such temperatures are prevalent in Southwestern of Iran. The result could also be useful in developing a population model for E. acaudaleyrodis under field conditions.     

Field and laboratory studies on the effects of temperature on the development of the carrot fly (Psila rosae F.)

The thermal requirements for the pre-oviposition period, egg, larval, pupal and adult stages of the carrot fly were measured under field conditions and at a range of constant temperatures in the laboratory. In the laboratory, the pre-oviposition period lasted from 4 days at 24^oC to 28 days at 9^oC. In general, female carrot flies laid about 20–40 eggs in each batch. Once the first eggs had been laid, subsequent batches were laid after an average of 3 days at 24^oC to 7 days at 11.5^oC. The numbers of days required for egg, larval and pupal development ranged from 5, 31 and 24 days respectively at 21.5^oC to 25, 145 and 84 days respectively at 9^oC. Under laboratory conditions, complete development from egg to adult required from 60 days at 21.5^oC to 254 days at 9^oC. Newly-formed carrot fly pupae were exposed to temperatures of 22–30^oC for various 5–10 day periods during pupal development. Exposure to temperatures of 24^oC and 26^oC caused some, and exposure to 28^oC and 30^oC caused all, of the pupae to delay development. Pupae were sensitive to high temperatures only for approximately 4–10 days after pupation. Under field conditions between mid-May and early September, full carrot fly development (egg-adult) took 84–100 days. The numbers of day-degrees required (base temperatures of 2^oC and 4^oC) for carrot fly development in the laboratory and in the field were similar for egg hatching but not for the pre-oviposition period or for egg-adult development. The thermal requirement for fly development in the field varied between inoculation dates, fewest day-degrees being required when development was rapid.     

Biological and ecological studies on the sugar-beet fly,Pegomyia mixta Vill. (Diptera: Anthomyiidae) on sugar-beet in Egypt

The sugar-beet fly, Pegomyia mixta Vill., is the most serious insect pest affecting sugar-beet plantations in Egypt. This study wase carried out in field in the El-Nubaria region ofEl-Behare Governorate. Peak numbers of flies were taken in sweep nets in December. Development of the fly appeared to be restricted to the months between November and May. In the hot months, adults were most active early in the morning and late in the afternoon, but in the cold months the peak of activity occurred at about midday. The flies were generally found on the upper surfaces of the leaves at temperatures below 16 °C and on the lower surfaces at temperatures above 24 °C. Females were generally more numerous than males. The eggs were observed from the first week of November to the end of April; the population was three blotches of eggs and 17 larvae/20 plants. The highest infestation of this insect in El-Nubaria was recorded at the end of March in both seasons (10 blotches of eggs, 20 larvae, and five pupae, and 12 blotches of eggs, 22 larvae, 13 pupae, respectively). The eggs are deposited in groups (3–8 eggs). The larvae bore its blotch in the leaf, about 3–7 larvae may be found in one blotch.     

The thermal constant of the onchocerciasis vector Simulium damnosum s.l. in West Africa

The minimum water temperature for development (t(0)) and the thermal constant (K) for the development of immature stages of Simulium damnosum s.l. (Diptera: Simuliidae) in West Africa were estimated as 20.1 °C and 93 day-degrees, respectively, based on analyses of published data on development rates of eggs, larvae and pupae at different water temperatures (24.0 °C and 31.5 °C). Thus, at a constant water temperature of 30.0 °C (approximately 10 °C above t(0)), adult flies would emerge about 9 days after oviposition. Analysis of a dataset probably restricted to S. damnosum s.s., but for which the temperature for the egg stage varied, revealed a much lower t(0) (16.3 °C) and a much higher K (181 day-degrees), suggesting that the insects' thermal relations may be cytoform-specific. The results will aid control decisions and predictions of possible effects of climate change on sizes and geographic distributions of populations of onchocerciasis vectors in West Africa.     

Pheromone-trap catch in relation to the phenology of codling moth (Cydia pomonella)

Relationships between a pheromone-trap catch, adult emergence and penetration of fruit by first-instar larvae of Cydia pomonella were investigated from 1975 to 1977 in an orchard in South West England. For the first generation the times of moth emergence and catch in the pheromone trap were not significantly different; nor were male and female emergence times. The catch of moths of the first generation in the pheromone trap anticipated the appearance of their larvae in the fruit by 140–169 day-degrees > 10 °C. Eggs hatched after 94 day-degrees in the laboratory but in the orchard, wind and sunshine modified the microclimate so that the number of day-degrees required for egg development, as measured by standard meteorological instruments, was affected by wind and sunshine but development lasted on average about 90 day-degrees. This indicated a lag of 50–80 day-degrees between the curves for trap catch and oviposition: the pre-oviposition period in the orchard was shorter than expected from laboratory studies. In 1975 and 1976, some larvae developed to produce a second generation of moths which gave rise to a second generation of eggs and larvae, after an interval of 161 day-degrees in 1975, but only 41 day-degrees in 1976, indicating that in 1976 some eggs were laid before moths of the second generation were trapped. These results indicate that the first insecticidal spray against first-generation larvae should be applied about 140 day-degrees after the start of the reference week in which five moths of the spring brood are caught per trap. A second spray, if required to maintain insecticidal cover, should be applied about 100 day-degrees later. A spray should be applied against second-generation larvae immediately after the reference week for second-generation moths.     

扶桑绵粉蚧寄生性天敌班氏跳小蜂生物学研究

本文对扶桑绵粉蚧Phenacoccus solenopsis Tinsley的重要天敌班氏跳小蜂Aenasius bambawalei Hayat(膜翅目:跳小蜂科)的雌雄形态特征、发育起点温度和有效积温、在长沙地区的理论发生代数进行了研究。结果表明:班氏跳小蜂是扶桑绵粉蚧若虫-成虫期寄生蜂;在28℃下,班氏跳小蜂一代的历期为17.8d;成虫、卵、幼虫和蛹的发育起点温度分别为:14.42、15.29、14.89、15.18℃,发生一代的发育起点温度为14.62℃;成虫、卵、幼虫和蛹的有效积温分别为87.92、9.74、68.41、75.84日·度,发生一代的有效积温为249.92日·度;由此预测班氏跳小蜂在长沙地区一年可发生9代。     

温度对黑纹粉蝶越冬蛹滞育后发育的影响

为了探讨温度对黑纹粉蝶Pieris melete越冬蛹滞育后发育的影响, 系统调查了越冬蛹滞育解除后在不同恒温下的发育历期及其在自然条件下春后的羽化情况。结果表明: 黑纹粉蝶雄虫和雌虫越冬蛹滞育后发育的阈值温度分别为7.1±1.5℃ 和7.4±0.4℃, 滞育后发育的有效积温分别为133.4±3.3日·度和155.7±5.3日·度。根据连续7年黑纹粉蝶越冬蛹在田间的羽化情况, 结合当年春季滞育后发育阈值以上的温度, 推算出田间50%个体成虫羽化时雄虫和雌虫获得的有效积温分别为142.2±12.2日·度和149.2±13.8日·度, 与滞育后发育的理论有效积温接近。据此, 利用该理论上的发育阈值温度和有效积温, 参照当年2-4月的气温, 可预测田间越冬蛹50%个体成虫羽化的时间。     

Manipulation of the length of the sensitive period,and the induction of pupal diapause in the flesh-fly,Sarcophaga argyrostoma

Larvae of the flesh-fly Sarcophaga argyrostoma were raised in short-day cycles (LD 12: 12) and at temperatures (18° and 20°C) in which short-day induction of pupal diapause was less than ‘saturated’. The cultures were then subjected to experimental treatments which modified the duration of larval development (the sensitive period). Overcrowding the larvae within a limited quantity of meat, premature extraction of the third instar larvae from their food, or exposure of the mature larvae to pure CO₂ for 24 h, were all found to accelerate puparium formation, thereby curtailing the sensitive period, and reducing the incidence of pupal diapause. Conversely, lengthening the sensitive period by allowing the mature larvae to wander in wet sawdust increased diapause incidence. The results are interpreted in terms of an interaction between the length of the sensitive period and the ‘required day number’, and also in the light of what is known about the endocrinological control of diapause and development in flesh flies.     

Temperature-dependent development of diapausing larvae of Chilo partellus (Swinhoe) (Lepidoptera: Crambidae)

Temperature-dependent development rate, percent diapause induction (hibernation at low temperature and aestivation at high temperature), and survival of diapausing larvae of Chilo partellus (Swinhoe, 1885) were examined on 13 constant temperatures ranging from 8 to 40 °C. Development of hibernating and aestivating larvae occurred from 10 to 25 °C and 27–38 °C, respectively. However, no development occurred at 8 °C and 40 °C. To determine actual thermal conditions that affect development and trigger both kind of diapause (hibernation and aestivation), various thermal parameters were estimated by fitting the development rate data to two linear (Ordinary equation and Ikemoto & Takai) models and thirteen non-linear models. The lower thermal thresholds (T_min) for development of diapausing larvae of C. partellus were calculated as 9.60 °C and 10.29 °C using the ordinary linear model and Ikemoto & Takai model, respectively. Similarly, the thermal constants (K) estimated using the ordinary linear model was 333.33 degree-days and that estimated with Ikemoto & Takai model was 338.92 degree-days. Among the non-linear models, Lactin-2 followed by Lactin-1 were found to be the best as these models estimated the critical temperatures (T_min, T_max and T_opt) similar to those of observed values. Conclusively, the Ikemoto & Takai linear model and Lactin-2 followed by Lactin-1 non-linear models are useful and efficient for describing temperature-dependent development and estimating the temperature thresholds of diapausing larvae of C. partellus. Our findings provided fundamental information for estimation of thermal requirement and temperature based development models for diapausing larvae of C. partellus. This information will be highly useful for predicting the occurrence, seasonal emergence, number of generations and population dynamics of C. partellus.     

松突圆蚧花角蚜小蜂的生物学

松突圆蚧花角蚜小蜂Cocvobius azumai Tachikawa是松突圆蚧Hemiberlesla pitysophila Takagi的重要寄生蜂,1987-1989年从日本引入我国广东省。对松突圆蚧花角蚜小蜂的形态、发育、繁殖、成虫寿命和取食寄主行为等生物学特征进行了观察。该蜂的雌性幼虫是松突圆蚧雌蚧的初级内寄生蜂,而雄性幼虫则是次级寄生蜂,重寄生在同种或它种膜翅目的老熟幼虫、预蛹和蛹上。雌雄两性的形态在所有发育阶段均不相同。交配过的雄蜂喜欢寄生产卵初期和盛期的雌成蚧,对巳寄生的寄主具有识别能力。在19.7℃一30.9℃变温条件下每头雌蜂平均产卵14.95粒,约60%的卵是在最初3天内产出。松突圆蚧花角蚜小蜂雌性蜂在21℃,24℃,27℃和30℃时从卵发育到成虫的平均历期分别为41.24,32.60,25.60和23.00天,发育起点温度10.1℃,有效积温448.3日度。该蜂在广东省一年发生。9-10代。     

The effect of temperature on the development times of eggs,naupliar and copepodite stages of five species of cyclopoid copepods

The duration times of eggs, combined naupliar instars and of the different copepodite stages of five species of cyclopoid copepods — Acanthocyclops robustus, Cyclops vicinus, Diacyclops bicuspidatus, Mesocyclops leuckarti, and Thermocyclops crassus — were investigated at five different temperatures. The five species can be divided in two groups: two species, C. vicinus and D. bicuspidatus, adapted to cold water conditions and three species, A. robustus, M. leuckarti and T. crassus adapted to warm water conditions. The cold water species showed a faster egg development than M. leuckarti and T. crassus at 5–15 °C. The eggs and instars of the warm water species M. leuckarti tend to develop faster than those of the former two species at higher temperatures. A. robustus showed the shortest egg and instar development at 10–25 °C. The warm water species T. crassus produced no eggs at 10 °C and temperatures below. At higher temperatures (20, 25 °C) the egg and instar duration times were similar or longer than those of the other species. When cultured in total darkness a great part of the C_IV respectively C_V copepodites of the summer forms entered arrest and the percentage of copepodites that showed an arrest of development was highest at lowest temperatures. The present results are compared with data from literature and differences are discussed.     

Suitability of Aphis craccivora (Hemiptera: Aphididae) and Bemisia tabaci (Hemiptera: Aleyrodidae) biotype-B as prey for Chrysopa pallens (Neuroptera: Chrysopidae)

The suitability of Aphis craccivora Koch (Hemiptera: Aphididae) and Bemisia tabaci Gennadius (Hemiptera: Aleyrodidae) biotype-B eggs and nymphs as prey for pre-imaginal development and survival, adult longevity, and fecundity of the lacewing, Chrysopa pallens (Rambur) (Neuroptera: Chrysopidae) was evaluated under laboratory conditions at 25±1°C, 50±10% RH and a photoperiod of 16 h L:8 h D. Survival of C. pallens from first instar to adult eclosion was significantly different between the larvae that fed on the two prey species. C. pallens fed on A. craccivora completed development from egg to adult emergence, but those fed on eggs and nymphs of B. tabaci could not complete development, resulting in abnormal pupae and no normal adults emerged. The net reproductive rate (R ₀), intrinsic rate of natural population increase (r _m ), finite rate of increase (λ), mean generation time (T), index of population trend (I), doubling time (DT), and gross reproductive of rate (GRR) of C. pallens that fed on A. craccivora were 201.9 eggs per female, 0.13/d, 1.1/d, 40.1 d, 68.5, 5.2 d, 203.1 eggs per female, respectively. These results could be useful for mass-rearing of C. pallens and for understanding its population dynamics in the field in relation to the availability of different prey species.