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.     

Study of intrapopulational variability of duration and temperature norms of development of the linden bug Pyrrhocoris apterus (Heteroptera, Pyrrhocoridae)

The existence of significant variability in duration and temperature norms of development between families within insect populations has been shown for the first time. This variability is inferfamily and therefore has genetic ground. Revealed for the first time is the statistically significant positive correlation between the regression coefficient of the development rate for temperature and the temperature threshold for development of eggs and larvae from different families. The greater the slope of the regression line of the development rate for temperature, the higher the temperature threshold value in this particular family. These results demonstrate for the first time the existence of genetic co-variation between the regression coefficient and the temperature threshold within the insect populations. It is suggested that the source of the interpopulational and interspecies changes in the temperature reaction norms of the insect development might be the intrapopulational hereditary variability of the development duration, regression coefficient, and the development threshold, this variability being an object of natural selection. It was shown that in all studied families and populations the values of the linear regression coefficient of development rates for temperature in eggs of the linden bug Pyrrhocoris apterus were markedly and statistically significantly higher, while the temperature threshold values—lower as compared with the corresponding parameters in larvae. These results obviously are in contradiction with the concept of the “isomorphism of development rates” (Jarosik et al., 2002), according to which the development threshold for all life cycle stages of a species should be the same, whereas only slopes of the regression lines of the development rate for temperature can differ. For the first time the absence of genetic covariation has been shown between the temperature norms of development of different life cycle stages of the species—eggs and larvae. This means that the regression coefficient as well as the sum of the degree-days and the development threshold in eggs and larvae are inherited independently and therefore they can be independently changed in evolution in correspondence with specific environmental conditions, under which these life cycle stages take place.     

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.     

温度对菊小长管蚜生长发育的影响

在15、19、22、25、28、31和35℃及RH80％的组合条件下,测定了菊小长管蚜的发育起点温度及有效积温,分析了温度与菊小长管蚜发育速率的关系．结果表明,菊小长管蚜各龄若虫的发育时间随温度的增加而缩短,4龄若虫的发育历时最长,平均为前三龄若虫历期的1．4倍．模拟分析表明,菊小长管蚜发育速率随温度的升高而加快,2、3龄若虫较1、4龄若虫对极端温度的忍耐性强,发育最适温度高．2、3龄若虫的极端温度忍耐值δ为6．70,最适发育温度为21．76℃,最高发育温度为40．97℃;1、4龄若虫极端温度忍耐值δ分别为4．70和4．50,最适发育温度分别23．76℃和22．49℃,最高发育温度为39．97℃和40．56℃;龄期越高,发育起点温度相对较低,发育所需的有效积温则越高．1～4龄若蚜的发育起点温度分别为6．93、5．02、4．58和4．46℃,有效积温分别为26．88、33．41、33．63和48．49℃·d^-1。     

温度对胡萝卜微管蚜生长发育繁殖的影响

【目标】明确温度对胡萝卜微管蚜Semiaphis heraclei(Takahashi)生长发育和繁殖的影响。【方法】在室内5个温度梯度下(19、22、25、28、31℃)观察并比较胡萝卜微管蚜的发育历期、存活率、存活寿命及产仔量。【结果】在19?31℃范围内,胡萝卜微管蚜各龄期及完整世代的发育历期均随着温度的升高而缩短,完成一个世代分别需要22.17、17.13、12.57、10.03和7.83 d。温度与发育速率呈极显著相关(P<0.01,r>0.8),温度越高发育速率越快。胡萝卜微管蚜4个若蚜期和世代的发育起点分别为14.15、13.87、13.64、15.06、12.92℃,有效积温分别为29.98、29.30、28.54、24.00和144.21日?度。建立了胡萝卜微管蚜各个发育阶段的历期预测式。在5个恒温下胡萝卜微管蚜1?4龄及世代的存活率随温度的变化而小幅波动。在19?31℃范围内,该蚜虫世代的存活率分别为40.0%、52.5%、62.5%、60.0%和47.5%。25℃该蚜虫的存活率相对较高,1?4龄及世代的存活率分别为82.5%、81.8%、92.6%、100%和62.5%。在相同温度条件下该蚜虫不同发育阶段的存活率存在差异。存活寿命随着温度的升高而缩短,19℃时寿命最长,为33.30 d,31℃时寿命最短,为15.40 d。产仔期随着温度的升高而缩短,19℃时产仔期为11.13 d,31℃时为7.57 d。在19?31℃范围内,该蚜虫的单雌产仔总量分别为26.33、27.93、32.53、27.13和17.93头。【结论】温度是影响胡萝卜微管蚜的生长发育、存活和繁殖的重要因素。25℃时胡萝卜微管蚜各龄期及世代的发育历期较短,存活率较高,单雌产仔总量最大。25℃较适合该蚜虫生长发育和繁殖。     

Development, survival and reproduction of black citrus aphid, Toxoptera aurantii (Hemiptera: Aphididae), as a function of temperature

The development, survival, and reproduction of the black citrus aphid Toxoptera aurantii (Boyer de Fonscolombe) were evaluated at ten constant temperatures (4, 7, 10, 15, 20, 25, 28, 30, 32 and 35 degrees C). Development was limited at 4 and 35 degrees C. Between 7 and 32 degrees C, developmental periods of immature stages varied from 44.2 days at 7 degrees C to 5.3 days at 28 degrees C. Overall immature development required 129.9 degree-days above 3.8 degrees C. The upper temperature thresholds of 32.3, 28.6, 29.3, 27.2, and 28.6 degrees C were determined from a non-linear biophysical model for the development of instars 1-4 and overall immature stages, respectively. Immature survivorship varied from 82.1 to 97.7% within the temperature range of 10-30 degrees C. However, immature survivorship was reduced to 26.3% at 7 degrees C and 33.1% at 32 degrees C. Mean adult longevity was the longest (44.2 days) at 15 degrees C and the shortest (6.2 days) at 32 degrees C. The predicted upper temperature limit for adult survivorship was at 32.3 degrees C. Total nymph production increased from 16.3 nymphs per female at 10 degrees C to 58.7 nymphs per female at 20 degrees C, declining to 6.1 nymphs per female at 32 degrees C. The estimation of lower and upper temperature limits for reproduction was at 8.2 and 32.5 degrees C, respectively. The population reared at 28 degrees C had the highest intrinsic rate of increase (0.394), the shortest population doubling time (1.8 days), and shortest mean generation time (9.5 days) compared with the populations reared at six other temperatures. The population reared at 20 degrees C had the highest net reproductive rate (54.6). The theoretical lower and upper temperature limits for population development, survival and reproduction were estimated at 9.4 and 30.4 degrees C, respectively. The biology of T. aurantii was also compared with three other citrus aphid species.     

红体色麦长管蚜发育起点温度和有效积温

研究观测红体色麦长管蚜Macrosiphum avenae(Fabricius)无性世代各个若虫龄期在14,17,20,23和26℃条件下的生长发育速率。结果表明,红体色麦长管蚜各龄期若虫的发育历期随着温度的上升而缩短。采用不同的方法计算得到的红体色麦长管蚜发育起点温度和有效积温不同,而直线回归法计算的变异系数较小,其结果显示红色麦长管蚜若虫期的发育起点温度和有效积温分别是4.478℃和110.662日.度。     

环境因子对真水狼蛛胚胎发育的影响

研究了温度、相对湿度和光照时间对真水狼蛛（Pirata piraticus）胚胎发育的影响。结果表明,温度不仅影响真水狼蛛胚胎发育的全过程,也对胚胎发育的各阶段有影响,在20℃-35℃范围内,随着温度的升高,胚胎发育加快,卵的发育起点温度为11.9℃,低温下,卵的孵化整齐度高温下要高,28℃时,孵化率最高。为探讨真水狼蛛胚胎发育的影响因子和合适条件,考虑温度、相对湿度和光照时间3个因子的综合作用,按照二次正交旋转组合设计的要求安排实验,得出了影响胚胎发育历期、胚胎成形率和孵化率的二次回归模型,并分析了其影响因子,利用孵化率的回归模型,得到了真水狼蛛卵孵化的最优条件为温度为27℃-28.5℃,相对湿度为94％－97％,光照时间为14－17h。     

Photoperiod-temperature interaction-a new form of seasonal control of growth and development in insects and in particular a Carabid Beetle, <Emphasis Type="Italic">Amara communis</Emphasis> (Coleoptera: Carabidae)

Amara communis larvae were found to develop significantly faster and to have higher growth rate at short-day (12 h) as compared to long-day (22 h) photoperiods at all used temperatures (16, 18, 20, and 22°C). The coefficient of linear regression of larval development rate on temperature was significantly higher at the short day than at the long day. The thermal developmental thresholds appeared similar at both photoperiods. Body weight of young beetles reared under different photoperiods was almost the same. Thus, photoperiod does not simply accelerate or decelerate insect development, but modifies the thermal reaction norm. At short days, larval development becomes faster and more temperature-dependent, which provides a timely completion of development at the end of summer. The analysis of literature data has allowed us to find the photoperiodic modification of thermal requirements for development in 5 insect orders: Orthoptera, Heteroptera, Coleoptera, Lepidoptera, and Diptera. Modification may result in significant changes in the slope of the regression line, and hence the sum of degree-days, and in the thermal developmental threshold. Consequently, the thermal requirements for development in many insects gradually vary during summer under the effect of changing day-length, which may have adaptive significance. Thus, the photoperiodic modification of thermal reaction norms acts as a specific form of seasonal control of insect development.     

Thermal requirements for the development and reproduction of Nysius huttoni White (Heteroptera: Lygaeidae)

Nysius huttoni White is an economically important pest of wheat and brassica crops in New Zealand. Because of its frequent presence in export fruit packages, it is also considered an important quarantine pest to countries that trade with New Zealand. To provide critical information for the pest risk analysis, forecast and management of N. huttoni, we investigated the effect of five consistent temperatures (10, 15, 20, 25, and 30 degrees C) on its development, survival and reproduction. At 10 degrees C both eggs and nymphs did not develop but the latter grew. Nymphs could survive 10 degrees C for >1.5 mo, with the fifth instar nymphs surviving for up to 145 d. Adults could live for at least 100 d at this temperature. This species could not complete its lifecycle at or below 15 degrees C. Between 15 and 30 degrees C, fifth instar stage was significantly longer than other nymphal stages. Egg hatch rate and total survival rate for all stages were significantly higher at 20 degrees C than at other test temperatures. The developmental rate of different life stages increased linearly with the increase of temperatures from 15 to 30 degrees C. The estimated low temperature threshold for the completion of lifecycle was 11.9 degrees C, and that for mating and oviposition was 12.3 and 16.8 degrees C, respectively. The thermal requirement for completing a life cycle of N. huttoni was 625 DD. The time needed for completing a life cycle was similar for both sexes. Temperature had little effect on adult body weight and sex ratio. Implications of the above findings are discussed.     

Photoperiod-temperature interaction--a new form of seasonal control of growth and development in insects and in particular carabid beetle, Amara communis (coleoptera: carabidae)

Amara communis larvae are found to develop significantly faster and have higher growth rate at short-day (12 h) as compared to long-day (22 h) photoperiods under all temperatures (16, 18, 20 and 22 degrees C) used. The coefficient of linear regression of larval development rate on temperature was significantly higher at short days than at long days. At that thermal developmental thresholds appeared similar at both photoperiods. Body weight of young beetles reared under different photoperiods was just the same. Thus, the photoperiodic effect does not simply accelerate or retard insect development, but modifies their thermal reaction norm. Under short days larval development becomes faster and more temperature dependent, which ensures the timely completion of the development at the end of summer. The analysis of data from literature allowed us to find photoperiodic modification of thermal requirements for development in 5 insect orders--Orthoptera, Heteroptera, Coleoptera, Lepidoptera, Diptera. Modification may result in significant changes in the slope of the regression line and hence in the sum of degree-days and thermal developmental threshold. Consequently, during summer under the influence of changing day-length the thermal requirements for development in many insects gradually vary, which may have adaptive significance. Thus, the photoperiodic modification of thermal reaction norm acts as a specific form of seasonal control of insect development.     

外来害虫双钩巢粉虱在海南的发生及温度对其发育的影响

双钩巢粉虱Paraleyrodes pseudonaranjae Martin是近年来在我国南方新发现的一种外来害虫。本文对双钩巢粉虱在海南的发生情况进行了调查,并对各虫态形态特征及温度对其生长发育的影响进行了观察。结果表明,双钩巢粉虱在海南省的各个县(市)都有发现,其在海南省的寄主植物共有20科29属37种,主要为害椰子、槟榔、番石榴、柑桔及番荔枝。双钩巢粉虱的发育经卵、若虫(分4个龄期)发育到成虫。在18～27℃条件下,双钩巢粉虱世代发育随温度的上升而加快,在27℃时最短,为16.38 d,18℃最长,需37.41 d,在30℃发育减缓,各虫态发育速率与温度呈抛物线关系。双钩巢粉虱世代的发育起点温度和有效积温分别为9.56℃和307.75日.度,在海南一年可发生16～17代。     

Effect of temperature on lipids,proteins, and carbohydrates levels during development from egg extrusion to juvenile stage of Cherax quadricarinatus (Decapoda: Parastacidae)

The influence of temperature on biochemical composition, survival and duration of development of Cherax quadricarinatus from egg extrusion to juvenile was analyzed. Berried females were individually subjected to each of 22, 25, 28 and 31 degrees C (n=5 per temperature). Egg samples were obtained every 3 days from egg extrusion to juvenile stage for biochemical analysis. Duration of development and survival decreased with increasing temperature. At 22 and 25 degrees C half of the initial lipid content was consumed during development. At 28 and 31 degrees C, 80% of the initial amount of lipids was consumed. For proteins, depletion rate was significantly lower at 25 degrees C (36% of the initial amount) than at 22, 28 and 31 degrees C (61-65% of the initial amount). For carbohydrates, a significant consumption was observed only at 22 degrees C. Total energy consumption was lower at 22 and 25 degrees C than at 28 and 31 degrees C. We conclude that 22-25 degrees C is the optimal temperature range for C. quadricarinatus egg incubation, although 25 degrees C might be better in terms of development duration in terms of survival, energy cost and protein consumption.     

CO2浓度倍增影响转Bt水稻非靶标害虫褐飞虱的生长发育及取食行为

近年来,大气CO₂浓度升高等全球气候变化和转Bt作物非靶标害虫抗虫性等问题备受关注.大气CO₂浓度升高直接或间接地影响植食性昆虫,而迄今为止有关大气CO₂浓度升高对刺吸式昆虫(同时也是转Bt作物的非靶标害虫)的影响结论不一,且对其刺吸取食行为的影响研究少有报道.本研究利用智能人工气候箱设置CO₂浓度,研究大气CO₂浓度倍增(800 μL·L^-1)对转Bt水稻的非靶标害虫褐飞虱取食行为及其生长发育和繁殖等的影响.结果表明: 大气CO₂浓度倍增对褐飞虱卵和若虫历期、成虫体质量和寿命,以及4龄和5龄若虫的刺吸取食行为等都具有显著影响,但对其繁殖力影响不显著.与对照CO₂浓度(400 μL·L^-1)相比,倍增CO₂浓度处理下褐飞虱的卵和若虫历期及雌成虫寿命分别显著缩短了4.0%、4.2%和6.6%;长翅型成虫比例显著增加了11.6%;初羽化成虫体质量降低,且雌成虫体质量显著降低了2.2%;此外,倍增CO₂浓度处理下褐飞虱4龄和5龄若虫口针的刺探效率都显著增加;其中,N4b波的持续时间分别显著延长了60.0%和50.1%,频次分别显著增加了230.0%和155.9%.可见,CO₂浓度倍增可通过提高褐飞虱的刺吸取食而促进其生长发育,并缩短其世代历期、提高长翅成虫比例,最终导致大气CO₂浓度升高下转Bt水稻的非靶标害虫褐飞虱发生危害严重,并面临其迁飞扩散为害加重的风险.     

CO2浓度倍增影响转Bt水稻非靶标害虫褐飞虱的生长发育及取食行为

近年来,大气CO₂浓度升高等全球气候变化和转Bt作物非靶标害虫抗虫性等问题备受关注.大气CO₂浓度升高直接或间接地影响植食性昆虫,而迄今为止有关大气CO₂浓度升高对刺吸式昆虫(同时也是转Bt作物的非靶标害虫)的影响结论不一,且对其刺吸取食行为的影响研究少有报道.本研究利用智能人工气候箱设置CO₂浓度,研究大气CO₂浓度倍增(800 μL·L^-1)对转Bt水稻的非靶标害虫褐飞虱取食行为及其生长发育和繁殖等的影响.结果表明: 大气CO₂浓度倍增对褐飞虱卵和若虫历期、成虫体质量和寿命,以及4龄和5龄若虫的刺吸取食行为等都具有显著影响,但对其繁殖力影响不显著.与对照CO₂浓度(400 μL·L^-1)相比,倍增CO₂浓度处理下褐飞虱的卵和若虫历期及雌成虫寿命分别显著缩短了4.0%、4.2%和6.6%;长翅型成虫比例显著增加了11.6%;初羽化成虫体质量降低,且雌成虫体质量显著降低了2.2%;此外,倍增CO₂浓度处理下褐飞虱4龄和5龄若虫口针的刺探效率都显著增加;其中,N4b波的持续时间分别显著延长了60.0%和50.1%,频次分别显著增加了230.0%和155.9%.可见,CO₂浓度倍增可通过提高褐飞虱的刺吸取食而促进其生长发育,并缩短其世代历期、提高长翅成虫比例,最终导致大气CO₂浓度升高下转Bt水稻的非靶标害虫褐飞虱发生危害严重,并面临其迁飞扩散为害加重的风险.     

Temperature-related development of the parasitoid wasp Nasonia vitripennis as forensic indicator

Development times of the forensically significant parasitic wasp Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae) from oviposition to pupation, and from oviposition to adult emergence, were studied in the laboratory at temperatures of 15-35 degrees C using host pupae of the blowfly Protophormia terraenovae (Robineau-Desvoidy) (Diptera: Calliphoridae). Total developmental time of N. vitripennis from oviposition to adult emergence (mean+/-SD) was 43.5+/-2.4, 22.5+/-1.1, 14.8+/-1.7 and 11.3+/-0.9 days when reared at 15, 20, 25 and 30 degrees C, respectively. At 35 degrees C, N. vitripennis did not develop successfully. The rate of total immature development (1/days) increased with temperature. From linear regression of development rates, it was determined that the minimum threshold (tL) for total immature development was 9.8 degrees C (approximately 10 degrees C). Above this threshold, the overall thermal constant (K) for N. vitripennis was found to be 224.3+/-1.7 degree-days.     

低温对小菜蛾实验种群的影响

研究了低温(<8℃)对小菜蛾的发育、存活和繁殖的影响结果表明,卵和蛹在4℃和6℃下死亡率随处理时间的延长而增加,在分别处理55d和70d后,卵和蛹全部死亡;经4℃和6℃处理的蛹,在16℃下羽化成虫的平均产卵量随处理时间的延长而减少,处理45d时,产卵量均为0小菜蛾幼期各虫态在0℃以下,死亡率随低温强度加大和处理时问的延长而增高就耐寒力而言,3龄幼虫和蛹最强,其次是2龄和4龄幼虫,卵和1龄幼虫的耐寒力最弱不同低温和时间处理小菜蛾幼期虫态对其后继虫态的发育历期有较大影响,总体说来,经过处理的小菜蛾幼期虫态,其后继虫态的发育历期普遍延长,一般处理某一虫态对其相邻虫态发育历期的影响最大小菜蛾蛹经低温处理后其羽化成虫的产卵量随着蛹期所经历低温强度的增强和时间延长而减少。     

Phenotypic effects of thermal mean and fluctuations on embryonic development and hatchling traits in a lacertid lizard, Takydromus septentrionalis

How fluctuating temperatures influence reptilian embryos and hatchlings has attracted increasing scientific attention, but is poorly known. We conducted an incubation experiment with a factorial design of two mean temperatures (24 vs. 28 degrees C) and three diel thermal fluctuations (0, +/-3, +/-6 degrees C) to determine the effects of diel thermal fluctuations and mean temperature on incubation duration and hatchling phenotypes. Both diel thermal fluctuations and mean temperature significantly affected incubation duration, but not hatching success. Incubation duration increased with increasing temperature fluctuations at a mean temperature of 24 degrees C, but not at a mean temperature of 28 degrees C. The significant interaction between diel thermal fluctuations and mean temperature on hatchling morphology indicated that the effect of thermal fluctuations depended on the mean temperature. Hatchling mass differed significantly between 24+/-6 and 28+/-6 degrees C, but not between the two constant temperatures or the temperatures with +/-3 degrees C fluctuations. At a mean temperature of 24 degrees C, the effect of thermal fluctuations on hatchling size was marginally significant, with relatively large hatchlings at the constant temperature; at a mean temperature of 28 degrees C, thermal fluctuations had no impact on hatchling size. The locomotor performances were significantly affected by mean temperature rather than diel thermal fluctuations. Therefore, diel thermal fluctuations around a given mean temperature do not affect hatchling phenotypes in a relatively large magnitude, but the influence of diel thermal fluctuations may differ with changing mean temperatures.     

Temperature dependent development of Lygus hesperus (Hemiptera: Miridae) nymphs

Lygus hesperus Knight (Hemiptera: Miridae) is a key pest of fruit and vegetable crops, forages, and cotton (Gossypium spp.) in the western United States. Accurate models describing relationships between temperature and L. hesperus development are critical to the study of seasonal L. hesperus population dynamics. Development of L. hesperus nymphs was assessed at nine constant temperatures from 10 to 37.8 degrees C. The relationships between temperature and development for each L. hesperus instar, and for the entire nymphal stage, were best described by six-parameter biophysical models indicating both low- and high-temperature inhibition of development. Development rates asymptotically approached zero with decreasing temperature in the lower thermal range, and decreased with increasing temperatures above 32.2 degrees C. Nymphs did not survive from egg hatch to adulthood at either 10 or 37.8 degrees C, and nymph mortality was > 90% at both 12.8 and 35.0 degrees C. The fifth instar exhibited the longest stadium, whereas the shortest stadia were associated with the second and third instars. Development rates of males and females did not differ, and the ratio of males to females was not different from 1:1 at any temperature. Our temperature-dependent development rate models for L. hesperus nymphs will facilitate control of insect physiological age in controlled laboratory experiments, and should be useful in planning and interpreting field studies on L. hesperus population dynamics.     

温度对椰心叶甲实验种群生长的影响

在不同温度(16、20、2、28和32 ℃)条件下观察椰心叶甲的发育、存活及繁殖情况.结果表明,椰心叶甲在32 ℃恒温下不能存活,在16～28 ℃世代发育起点温度为11.08 ℃,有效积温为966.22日·度,在海南省儋州市1年可发生4～5代.椰心叶甲世代存活率在28 ℃时最高,达92.5%.净增殖率、内禀增长率及周限增长率均在28 ℃时最高,分别为54.1、0.0260和1.0263.平均世代历期和种群加倍时间分别以20 ℃和28 ℃时最短,前者为123.1 d,后者为26.7 d.种群趋势指数以28 ℃时最高,为50.8,表明24～28 ℃为椰心叶甲种群生长的适合温度.