Temporal dynamics of Bactrocera (Zeugodacus) tau (Diptera: Tephritidae) adults in north Jiangxi,a subtropical area of China revealed by eight years of trapping with cuelure

Bactrocera (Zeugodacus) tau (Walker) (Diptera: Tephritidae), a quarantine pest of international concern, has become widespread and economically important in South and Southeast Asia. It has been introduced into north Jiangxi from Fujian, China and become a threat to local fruits and vegetables. Field trapping with cuelure (CUE) as lure is needed, not only for monitoring population dynamics of B. tau but also for direct control of population. In this study, we collected weekly tephritids from 4 CUE-baited McPhail traps every year from 2008 to 2015, analysing seasonal and inter-year B. tau population fluctuations. The total number of captured tephritids reached 7811, including B. tau (5321), B. scutellata (Hendel) (2375) and B. cucurbitae (Coquillett) (1 1 5). Among them, B. tau was the dominant species. It had 3–4 generations a year in north Jiangxi with high generation overlapping. The average number of trapped B. tau males did not differ significantly in different years, while the average monthly number showed large variation from June to December. No B. tau males were trapped before June in any year. Adult males were present from mid-June to late December, with distinct peaks between late August and mid-October. This fruit fly can withstand below 13℃ as a monthly minimal temperature under field conditions, and adult capture rates were significantly related to monthly minimal temperature and monthly total precipitation. These results can be used to predict the occurrence time and population size of B. tau in different seasons, enabling growers and extension personnel to take efficient management measures before they damage the host crops.     

Population dynamics of Bactrocera dorsalis (Diptera: Tephritidae) and analysis of factors influencing populations in Baoshanba, Yunnan, China

Population dynamics of the Oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae), were monitored year‐round using methyl eugenol‐baited traps in 2003, 2004, 2005 and 2006 in Baoshanba, Yunnan Province, China. Environmental factors including air temperature, rainfall and host‐plant species were analyzed with respect to the population dynamics. This species occurred only during April–November, with one yearly peak in August. The population fluctuation patterns with respect to season were identical in all study years. Correlation analysis and stepwise regression analysis indicated that air temperature, rainfall, sunlight hours and relative humidity were the major climatic factors that correlated with changes in the size of the fly population, and that monthly mean temperature, monthly sunlight hours and monthly relative humidity were most important. The seasonal increase in population size coincided with the fruiting period of the fly's host plants, but host fruit availability influenced the population size only when temperatures were sufficiently high. Cold temperatures may explain why there was no trap capture in the winter months. We believe that air temperature is the key factor explaining the seasonal occurrence of the fly population at Baoshanba.     

Seasonal abundance of the stable fly Stomoxys calcitrans in southwest England

The stable fly Stomoxys calcitrans (L.) is a cosmopolitan biting fly of both economic and welfare concern, primarily as a result of its painful bite, which can cause blood loss, discomfort and loss of productivity in livestock. Between June and November in 2016 and May and December in 2017, Alsynite sticky‐traps were deployed at four Donkey Sanctuary sites in southwest England, which experience recurrent seasonal biting fly problems. The aim was to evaluate the seasonal dynamics of the stable fly populations and the risk factors associated with abundance. In total, 19 835 S. calcitrans were trapped during the study period. In both years, abundance increased gradually over summer months, peaking in late August/September. There were no relationships between seasonally detrended abundance and any climatic factors. Fly abundance was significantly different between sites and population size was consistent between years at three of the four sites. The median chronological age, as determined by pteridine analysis of flies caught live when blood‐feeding, was 4.67 days (interquartile range 3.8–6.2 days) in males and 6.79 days (interquartile range 4.8–10.4 days) in females; there was no significant, consistent change in age or age structure over time, suggesting that adult flies emerge continuously over the summer, rather than in discrete age‐related cohorts. The data suggest that flies are more abundant in the vicinity of active animal facilities, although the strong behavioural association between flies and their hosts means that they are less likely to be caught on traps where host availability is high. The implications of these results for fly management are discussed.     

Investigations on the gout fly (Chlorops pumilionis Bjerk.) in Devon and Cornwall

Field observations from 1943 to 1946 on attacks by gout fly on wheat in south-west England show that there are two generations of the fly during the year, the first emerging in May from October-laid eggs and the second emerging in late July and early August. The first generation severely damages spring wheat and may also attack very late sown and backward autumn wheat; wheat not above ground before 20 October escapes attack by the second generation. In south-west England, the optimum period for drilling wheat to escape gout-fly damage is mid-October. In this area, both generations of gout fly show a marked preference for wheat; attacks on barley are negligible.     

Random amplified polymorphic DNA analysis of kinship within host-associated populations of the symbiotic water mite Unionicola foili (Acari: Unionicolidae)

Kinship relations within populations of unionicolid water mites are not well known, owing to their complex life cycles and the fact that interactions between active and resting stages for some species are transitory. A number of species of unionicolid water mites are, however, obligate symbionts of freshwater mussels and spend most of their life cycle in association with these hosts. Among these species of mites, parents and offspring are more likely to co-occur and thus provide opportunities to address questions related to the structure of the mating system. The present study employs random amplified polymorphic DNA (RAPD) analysis to address kinship within populations of Unionicola foili living in symbiotic association with the host mussel Utterbackia imbecillis. DNA was amplified from adult mites and a representative number of eggs or larvae (n = 20-30) that were removed from mussels collected on three separate occasions (July, November, and March) over a 12-month period. Parsimony analyses of the molecular data for adults and progeny collected from mussels during July, November, and March revealed distinct groupings, that for the most part, corresponded to mites collected from each of the sampling periods. Many of the genetic markers obtained for male and female U. foili were not evident among the larvae or eggs, suggesting that adults obtained from a host mussel at the time of collection were not the parents of a majority of the progeny. However, female mites and eggs collected from mussels during March and November shared more markers than did females and progeny examined during July. Furthermore, many offspring in the July sampling period were found to have one or more parents absent from the sampled population. Overall, RAPD profiling appears to have limited usage in determining kinship within populations of U. foili, due to its recruitment patterns, and the relatively large number of adults and progeny per mussel. It may, however, prove to be a useful method for assessing genetic relatedness among unionicolid mussel-mites that have substantially lower population densities.     

Estimation of climatic factors relating to occurrence of the maize orange leafhopper, Cicadulina bipunctata

The maize orange leafhopper, Cicadulina bipunctata is a serious pest of forage maize in East and Southeast Asia. In temperate Japan, the occurrence of this leafhopper fluctuates widely among years. Here, we examined effects of climatic factors (temperature, precipitation and sunlight) on the occurrence of C. bipunctata. Seasonal occurrence of adult C. bipunctata in a census field from July to August, when forage maize was most susceptible to the pest, could be described by a simple exponential function with two parameter: estimated density of C. bipunctata on 1 July (N ₀) and intrinsic rate of natural increase (r) for each year. Forward stepwise multiple regression analysis using seasonal occurrence data from 2004 to 2009 detected positive contributions of average temperatures in the previous December and February and a negative contribution of total precipitation during the previous winter to N ₀. The analysis also indicated that average temperature in July of the current year and N ₀ contributed positively and negatively to r, respectively. These results indicated that high temperature and little precipitation during winter and high temperature in early summer induced high occurrence of C. bipunctata in summer. A prediction model based on these factors supported the actual seasonal occurrence in 2010, suggesting that this prediction model is applicable to C. bipunctata forecasting. The prediction model indicated that further global warming in the future is likely to cause further outbreaks of C. bipunctata.     

Seasonal abundance, number of annual generations, and effect of an entomopathogenic fungus on Phlebotomus papatasi (Diptera: Psychodidae)

The monthly density of the sand fly, Phlebotomus Papatasi Scopoli (Diptera: Psychodidae), was monitored during 2009 at Burg El-Arab, a rural district located close to the Mediterranean coast of Egypt. The number of annual generations and the efficacy of microbial control by the entomopathogenic fungus, Metrahizium anisopliae (Metsch.) Sorok (Ma79), were determined in the laboratory under atmospheric conditions, simulating those of the animal shelters in the study area. We used two collecting techniques; CDC light traps and oiled paper traps, to quantify sand fly density inside houses and in the open field. Adult flies exhibited a seasonal range from April to December. The seasonal pattern was bimodal, with one peak in July and the second one in October. Calculations of the correlation coefficient (r) revealed a significant role of temperature and relative humidity in the monthly abundance of the sand flies in the study area. P. papatasi colony completed seven annual generations under semifield conditions, but the mean developmental time of each immature stage and the mean total duration of development from egg to adult for each generation varied according to the prevailing temperature. The longest generation time was observed in winter (the mean ± SD was 118 ± 11.70 d), and the shortest one occurred at the highest temperatures in summer (the mean ± SD was 25.21 ± 2.04 d). In microbial control studies, the entomopathogenic fungus, M. anisopliae, was used at 15 × 10(8) spores/g food as a standard dose against the second-instar larvae of P. papatasi at the different seasons during 2009. Mortality reached 100% in winter and decreased to 56.0% as the prevailing temperature increased during the summer season.     

Population dynamics of Bactrocera dorsalis (Diptera: Tephritidae) and analysis of the factors influencing the population in Ruili, Yunnan Province, China

Annual monitoring of the population dynamics of the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae) using methyl eugenol-baited traps was conducted throughout the year during 1997, 2000, 2003 and 2004 in Ruili, Yunnan Province, China. Temperature, rainfall and host-plant species were analyzed with respect to population fluctuation of the fly. During the study periods the fruit fly occurred throughout the year. Its population remained low from November to January and increased steadily from February until it reached a peak in June. Afterwards, the population declined until October. The results of stepwise regression analysis indicated that monthly mean temperature, monthly mean maximum temperature, monthly mean minimum temperature, monthly extreme maximum temperature, monthly extreme minimum temperature, and monthly raining days were the major climatic factors influencing populations. Path and decision coefficient analyses indicated that the monthly mean temperature was the crucial factor influencing population fluctuation, the monthly mean minimum temperature was the crucial limiting factor indirectly influencing increase in population, and the comprehensive factors influencing fly population dynamics, namely, the monthly raining days were the strongest of all the other factors. Generally, the monthly mean temperatures fell within the ranges of temperatures suitable for development and reproduction of the fly. But the monthly mean minimum temperatures from November to January seemed to be lower and were suggested to be responsible for the low populations in this period. Monthly rainfall and rainy days steadily increased from February through June, and this explained the increase in population observed during this period. During periods of continuous heavy rain from July through August, the fruit fly population showed a remarkable decrease. Host plant species was another essential factor influencing the population fluctuations. Abundant fruit and melon species formed the food and breeding materials for the fly during the study periods.     

Long-term study of Haematobia irritans (Diptera: Muscidae) seasonal distribution in central Argentina with focus on winter fly abundance.

The seasonal distribution of Haematobia irritans (Linnaeus, 1758) was evaluated at 31 degrees 12' S-61 degrees 29' W, Santa Fe, Argentina from November 1992 to August 2000 by weekly fly counts on 20 Holstein cows not treated against ectoparasites. The analysis was mainly focused on winter fly abundance. Two peaks of abundance were found from spring to autumn. Adults of H. irritans were consistently found on cattle during winter, with increasing numbers from the end of July to late August. The only climatic parameter soundly correlated with the four week period, before each winter fly count, was the mean air temperature with the exception of year 1998. No significant relationship was found between level of cow infestation and relative humidity, saturation deficit and rainfall. Horn fly infestation on cows was lower than 20% from end of June to end of August only in 1995, when mean air temperature was consistently lower than 11 degrees C during the four week period previous to most fly counts. Conversely, the mean temperature was higher than 12 degrees C previous to fly counts in 1998, when most cows remained infested. The results indicate that a proportion (unknown) of immature stages of H. irritans were insensitive to diapause inducing factors and developed through winter.     

Seasonal cycles of noctuid moths of the subfamily Plusiinae (Lepidoptera,Noctuidae) of the Palaearctic: Diversity and environmental control

Analysis of data on seasonal development of noctuid moths of the subfamily Plusiinae shows that the control of their seasonal cycles is poorly understood. At the same time, the available data demonstrate considerable diversity of the seasonal patterns of Plusiinae species from different regions. The homodynamic type of seasonal development has been found in Trichoplusia ni and Ctenoplusia agnata of the tribe Argyrogrammatini and in Autographa gamma of the Plusiini. The seasonal development of these southern noctuids is accompanied by regular interzonal migrations of flying adults. When spreading northwards, they can produce a different number of annual generations, depending on the local climatic conditions, and establish temporary local populations whose longevity is limited by the available thermal resources. Adults of some species may fly back southwards, but it is more likely that individuals from temporary local populations cannot survive long winters and are destined to die. The heterodynamic type of seasonal cycles allows insects to survive in the regions with pronounced seasonality of climate. This type of seasonal development includes univoltine, multivoltine, and semivoltine seasonal cycles. Univoltine seasonal cycles with obligate diapause are known in Autographa buraetica, A. excelsa, and Syngrapha ain (Plusiini). Diapause provides tolerance to both low temperatures and a prolonged period when food is unavailable. In Syngrapha ottolenguii (Plusiini), the same result is achieved by inclusion of two photoperiodically controlled diapauses (winter larval and summer adult ones) into the life cycle. The semivoltine seasonal cycle has been reported in only one species of Plusiinae, namely Syngrapha devergens. Larvae of this moth overwinter twice before pupation. Multivoltinism is common in the tribe Plusiini. Depending on the latitude, different species of this tribe can produce up to four generations per year and overwinter as middle-instar larvae in the state of facultative diapause. However, the characteristics of diapause vary substantially between the species: diapause can be deep and stable (as in Diachrysia chrysitis, Plusiini) or unstable and thus not ensuring successful overwintering and steady population growth (as in Macdunnoughia confusa, Plusiini). The seasonal adaptations known in Plusiinae include migrations, winter and summer diapauses, photoperiodic control of larval growth rates, and seasonal polyphenism of larval body coloration. In general, seasonal adaptations of Plusiinae are determined by local environmental conditions and only loosely associated with the systematic position of particular taxa. Only the tribe Abrostolini stands apart from other taxa of Plusiinae: moths of this tribe differ not only in morphology but also in peculiarities of their seasonal development, because all the species of this tribe overwinter as pupae and their seasonal cycles are therefore different from those of the rest of Plusiinae.     

Effect of photoperiod on characteristics of semen obtained by electroejaculation in stump-tailed macaques (Macaca arctoides)

Some environmental variables determining seasonal reproduction in mammals are temperature, humidity, food availability, and photoperiod. Among these, photoperiod is considered the main regulator of primates’ seasonal reproduction, thus the latitudinal distribution of primate populations is a key factor determining the appearance of seasonal reproduction. The present work presents supporting discrete seasonality in male stump-tailed macaques (Macaca arctoides). We investigated whether semen quality and testosterone covaried with Mexico City’s photoperiod and relative humidity by analyzing variations in the portions that form the ejaculate: the seminal liquid, the seminal coagulum, and the copulatory plug. Five male adult stump-tailed macaques were electroejaculated once a month, obtaining three semen samples per male, from August 2011 to July 2012 (except for December 2011) (n = 165). Our results showed that stump-tailed macaque sperm counts were significantly different between the portions of the ejaculate. The seminal coagulum contained the significantly largest number of spermatozoids, followed by the copulatory plug and the seminal fluid. Photoperiod and relative humidity had major influence on the sperm count in the seminal coagulum and the testosterone concentrations. Testosterone reached its highest values around the time when days and nights lasted the same hours, decreasing when days either grew longer or became shorter. Concerning relative humidity, sperm counts in the seminal coagulum were highly variable on dry days, but decreased as the relative humidity increased. We conclude that stump-tailed macaques have a discrete seasonality, occurring in spring and fall when macaques’ reproductive condition and readiness for postcopulatory intrasexual competition increase.     

Ecological studies of economic red algae. III. Growth and reproduction of natural and harvested populations of Gigartina stellata (Stackhouse) batters in New Hampshire

The growth in situ of populations of Gigartina stellata (Stackhouse) Batters has been recorded at three New Hampshire locations and correlated with seasonal and spatial variations of surface salinity, temperature, and nutrients. Annual growth began between February and May, depending upon the location and its hydrographic regime. Gigartina populations reached maximum biomass and size in August and September, and a general decrease in both occurred during the reproductive period from October to February. The period of fastest growth coincided with increasing summer temperatures, while maximum carpospore release occurred during the period of decreasing (coldest) temperatures. The largest plants and maximum biomass of Gigartina were found on the open coast (at a semi-exposed site) while smaller plants and reduced biomass were evident within the Great Bay Estuary System. Salinity is a dominant factor influencing both the local distribution and growth of the plant. Gigartina is primarily restricted to the littoral zone, and its maximum length and biomass occur between +0.45 and +1.0 m above M.L.W.     

Seasonal changes in seaweed deposition,seaweed fly abundance,and parasitism at the pupal stage along sandy beaches in central Japan

Seasonal relationships among stranded wrack quantity, seaweed fly abundances, and parasitism at the pupal stage were studied along three sandy beaches in central Japan. The seasonal occurrence patterns of puparia of seaweed flies Coelopa frigida and Fucellia spp. generally corresponded to seaweed deposition, which peaked in May–July and October–December. Parasitoids use fly puparia in these seasons. However, the occurrence of seaweed flies and their parasitoids varied among the three sandy beaches and did not correspond to the wrack amounts. These findings suggest that populations of seaweed flies and their parasitoids are seasonally, but not spatially, regulated by bottom‐up processes. The parasitoid assemblage of fly puparia was composed of two Aleochara (Coleoptera: Staphylinidae), two Trichopria (Hymenoptera: Diapriidae), and five pteromalid species (Hymenoptera), but the rate of parasitism was less than 20% and might have had little effect on fly populations.     

极端生理耐受性导致果蝇Zaprionus indianus 在温带地区广泛分布（英文）

在过去的十年中, Zaprionus indianus这一温带适应性果蝇已经入侵印度次大陆, 并扩大了其在该地区的分布。Z. indianus能成功入侵是由于它具有很强的适应性和对极端生理条件的耐受性。对Z. indianus (温带狭域分布种类) 和黑腹果蝇Drosophila melanogaster (全球广域分布种类)在极端温度下未成熟期和成虫期发育阈值的比较研究表明, 两者的死亡率和发育起点温度存在显著差异。为了检测越冬期间未成熟期和成虫期抗逆性和存活率的变化, 以采自印度温带和热带不同地点的Z. indianus种群进行饲养实验。在温带地区的田间养虫笼中以及恒定的实验室条件下监测这些种群的卵孵化率和成虫存活率, 直至全部成虫死亡。结果表明, 由于温带地区卵孵化率和存活率高, 导致总的孵化率和存活率在不同纬度间存在显著差异。卵至成虫发育实验结果表明, 低温条件下产下的卵在温度适中时成功发育成成虫。由此可见, 这种昆虫在未成熟期具有的气候适应性以及在成虫期具有的抗逆性可为该物种提供季节性保护。考虑到气候变暖情况, 即温度增加0.6℃, 温度的少许改变都可能导致种群存活能力的显著增强和发育历期缩短。这些结果可解释Z. indianus为什么能够轻易突破障碍并适应新的环境。     

DISTRIBUTION OF THE ORIENTAL FRUIT FLY (DIPTERA: TEPHRITIDAE) IN YUNNAN PROVINCE*

Abstract The Oriental fruit fly, Bactrocera dorsalis Hendel (Diptera: Tephritidae), is a serious pest inaect for vegetables and fruits in Yunnan Province. The trap experiments located in 12 counties of Yunnan indicated that, the geographical distribution of Oriental fruit fly there could be plotted as three distribution zones. To the south of Guannan, Yuanjiang and Rulin is the annual distribution zone. In this region, the Oriental fruit fly completed 4–5 generations per year, and infested the local vegetables and fruits all the year around. To the north of Luku, Dayiao and Qujing is the zone without the insect, where the Oriental fruit fly was not trapped and no fruits infested by the fly were found during the present study. The region between the above two zones was the seasonal distribution zone for the insect. The fruit fly occurred only during May to December in this area, and completed 2–3 generations in this period. The peak abundance of the oriental fruit fly took place from June in Jinghong to October in Yiaoan, along the altitude graduates from the south to the north. In elevation, the Oriental fruit fly was trapped at altitude of 500–2300 m above sea level, in which high trap catches appeared between 500–1000 m. It is proposed that the variations of the fruit fly distribution in altitude and latitude are principally correlated with local temperatures and host plants.     

Population-specific home ranges and migration timing of Pacific Arctic beluga whales (Delphinapterus leucas)

Two populations of beluga whales (Delphinapterus leucas), the Eastern Beaufort Sea (BS) and Eastern Chukchi Sea (ECS), make extensive seasonal migrations into the Pacific Arctic. However, the extent to which these populations overlap in time and space is not known. We quantified distribution and migration patterns for BS and ECS belugas using daily locations from whales tracked with satellite-linked transmitters. Home ranges and core areas in summer (July and August) and in each month (July–November), daily displacement, dispersal from core areas, and autumn migration timing were estimated. Distinct summer and fall distribution patterns and staggered autumn migration timing were identified for BS and ECS whales. Summer home ranges for each population had less than 10 % overlap. Monthly home ranges were also relatively distinct between populations except in September (up to 88 % home range overlap). A distinct east–west shift in focal area use occurred in September that persisted into October, with the two populations essentially switching longitudinal positions. Highest daily displacements occurred during the migratory period in September for BS whales and October for ECS whales, further indicating westward fall migration was offset between populations. Sexual segregation of males and females within a population also varied monthly. Autumn migration timing as well as differences in spatial and temporal segregation between BS and ECS beluga populations may be a result of maternally driven philopatry and population-specific adaptations to dynamically available resources. Our results contribute to the management of these populations by identifying seasonal area use and differences in migration patterns.     

Seasonal population dynamics of Draeculacephala minerva (Hemiptera: Cicadellidae) and transmission of Xylella fastidiosa

The grass sharpshooter, Draeculacephala minerva Ball (Hemiptera: Cicadellidae), is a very common and often abundant grass-feeding leafhopper in California. Its population dynamics and ability to transmit Xylella fastidiosa were monitored over a 2-yr period in California's San Joaquin Valley. Collections of individuals from natural populations in irrigated pastures and alfalfa, Medicago savita L. fields adjacent to X. fastidiosa-infected almond (Prunus spp.) orchards indicated the occurrence of three discrete generations per year that peaked during the summer. Population densities varied significantly among experimental field survey sites. Insects captured on intercepting mesh traps, yellow sticky cards, and UV-light traps indicated local movement of these insects into and surrounding X. fastidiosa-infected, almond orchards. Local movement and seasonal transmission of X. fastidiosa from infected almonds to Catharanthus roseus (L.) G. Don indicated that this insect may be partly responsible for the slow spread of almond leaf scorch now recently observed in California's San Joaquin Valley.     

云南河口县桔小实蝇生物学特性及防治

桔小实蝇Bactroceradorsalis (Hendel)在河口 1年发生 5代 ,世代重叠 ,5～ 8月为害虫发生盛期 ,以第 2和第 3代幼虫发生期对当地果蔬作物的危害最重。室内 1 8～ 30℃条件下 ,成虫日羽化高峰发生在上午 9:0 0～ 1 0 :0 0 ,卵、幼虫和蛹的历期随着温度的升高而缩短。成虫取食喜选成熟芒果的汁液。提出了防治此害虫的主要措施。     

Assessment of fitness costs of resistance against the parasitoid Leptopilina victoriae in Drosophila bipectinata

How insects evolve resistance or counter-resistance against antagonists is a basic issue in the study of host-parasitoid coevolution. One of the factors that affect their coevolution is fitness costs of resistance and counter-resistance. Here, we assess fitness costs of resistance against the parasitoid Leptopilina victoriae in Drosophila bipectinata on the basis of selection experiments. We made a base population by mixing three geographic fly populations that differed in resistance. The established base population was divided into four populations, two for selection of resistance against a L. victoriae population and two for control. Resistance increased rapidly in response to selection and reached a very high level within four generations in the selected populations, while resistance of the control populations remained low during 20 generations. High resistance of the selected populations was maintained at least for 10 generations after selection was stopped. Both selected populations had lower female longevity than the control populations, and at least one of the selected populations had shorter thorax length, lower female desiccation tolerance and adult heat tolerance than both or either of the control populations. On the other hand, the selected populations had higher male starvation tolerance and longevity than the control populations. There were no significant differences in resistance against another population of L. victoriae and two other parasitoid species between the selected and control populations. These results suggest that the resistance against the L. victoriae population in D. bipectinata may incur some but not so high costs and act parasitoid-species- and/or parasitoid-population-specifically.