基于荧光标记的怒江流域桔小实蝇（Bactrocera dorsalis）的迁移扩散

2005年7月在云南怒江流域地区,以荧光粉作为标记物,采用“标记-释放-回收”方法,对怒江流域桔小实蝇迁移扩散规律进行了研究。以释放点潞江坝为中心,东南西北4个方位设立桔小实蝇回收点,经过7d的回捕,从释放点沿潞江以北至六库沿线共回收到的标记桔小实蝇43头,最远在距释放点以北97 km 的地方回收到标记桔小实蝇5头。沿怒江在释放点以南,仅在小于29 km 的范围内回收到标记桔小实蝇17头。释放点东面和西面未能回收到标记桔小实蝇。分析释放点以北各回收点标记桔小实蝇与非标记桔小实蝇的相互关系揭示,非标记桔小实蝇与标记桔小实蝇在空间动态中具有相同的行为模式,由此推论非标记桔小实蝇与标记桔小实蝇可能来自同一种群。分析怒江流域区的自然地理发现,潞江坝桔小实蝇可借助怒江两边高大山脉形成的天然河谷通道,在适宜的气候条件下,在北上气流的携带下,实现由南向北的远距离迁移扩散;同时,由于高大山脉的阻隔,使潞江坝桔小实蝇没能向东西两个方向作远距离扩散迁移。研究首次揭示了在特定峡谷地区桔小实蝇扩散迁移现象,为桔小实蝇迁移扩散研究提供了新鲜实例,为在当地制定切实有效的桔小实蝇防治策略提供了基础信息。     

桔小实蝇飞行活动节律及其飞行能力

桔小实蝇在野外自然条件下,具有远距离扩散迁移能力。为了探讨桔小实蝇基于其生理生物学所能表达的基础飞行能力,本研究采用飞行磨系统,在实验室可控条件下,测定桔小实蝇飞行的日节律、不同食料饲养下的飞行能力以及多次飞行能力。研究表明:桔小实蝇飞行活动呈现明显的日节律,一天中呈现两个飞行时段,分别为7∶00至15∶00和17∶00至21∶00。不同食料饲养下,取食酵母糖水和糖水的桔小实蝇飞行能力显著强于取食清水。桔小实蝇经营养补充后可进行3-6 d的飞行,累计飞行可持续时间分别为4.21 h和3.74 h、最远飞行距离分别为5.74 km和5.24 km、平均飞行速度1.10 m/s和1.21 m/s。本研究为阐释桔小实蝇长距离迁移扩散成因提供了重要飞行生物学数据。     

云南西部实蝇的多样性

2005和2006年,在云南西部瑞丽、潞江坝、六库、保山、大理5个地区,采用信息素引诱法及被害瓜果内实蝇收集法对5个地区实蝇多样性进行分析.结果表明,5个地区实蝇丰富度的发生模式明显分为2种类型:瑞丽和潞江坝实蝇全年发生;六库、保山和大理实蝇季节性发生;瑞丽的实蝇种类丰富度最高,有20种,其次是潞江坝,11种,而保山、大理的实蝇种类丰富度低,分别为4种和3种;该区域实蝇优势种为桔小实蝇(Bactrocera dorsalis)和南亚果实蝇(B. tau);2年实蝇多样性指数均以六库最低,以潞江坝最高.各地实蝇种类相似性变化较大, 相似性系数在0.15～1.00 之间.结果为了解云南西部实蝇种类分布以及预防实蝇危害提供了基础数据.     

标记回收法确认我国北方地区草地螟的迁飞

为了证实草地螟Loxostege sticticalis L.（鳞翅目： 螟蛾科）由我国华北越冬区向东北迁飞危害的假说并提供直接的证据, 采用网捕成虫喷雾染料标记释放回收的方法,于2009年越冬代草地螟成虫盛发期间（6月1-4日）分别在内蒙古武川县（41.07°N, 111.42°E）和察右中旗（41.13°N, 112.58°E）的6个标放点共标记当地越冬代草地螟成虫约181万头并自然释放。标记释放后, 在东北、 西北和华北11个草地螟常发省（市、 区）组织各级监测预警部门利用虫情测报灯、 捕虫网和性诱剂诱捕器等多种器械进行回收, 先后于2009年6月7-29日在内蒙古科右中旗、 乌兰浩特、 扎兰屯分别回收到由察右中旗标记释放的成虫9头, 在辽宁省北票市回收到由武川县标记释放的成虫1头。标记释放点至回收点直线距离为725~1 117 km。这是迄今为止世界上确认的草地螟最远迁飞距离。这些证据不仅证实了我国越冬代草地螟成虫能从华北迁往东北危害, 而且为进一步了解草地螟的种群动态规律, 改善草地螟的预测预报技术提供了重要的科学依据。     

骨髓间充质干细胞在大鼠体内的迁移研究

目的:将体外预先标记的骨髓间充质干细胞(mesenchymalstemcells,MSCs)移植到大鼠脑内观察细胞的存活和转归,从在体(invivo)角度阐明MSCs在中枢神经系统疾病细胞治疗中的潜在应用前景。首先用DiI在体外标记MSCs。将标记后的MSCs分别移植到大鼠纹状体和侧脑室,在移植后2w和4w灌杀动物,进行脑组织及脊髓的冰冻切片,在荧光显微镜下观察细胞的存活与转归。结果:移植到纹状体的MSCs可沿针道向周围实质迁移,迁移的最远距离可达0.2mm。并且,在大脑皮层及其他脑实质的血管壁、血管中以及血管周围还可见到标记细胞;而移植到侧脑室的MSCs则主要沿脑室系统迁移,细胞主要分布在移植侧侧脑室,对侧脑室与第四脑室也有分布,也有少量细胞沿侧脑室向周围实质迁移,迁移的最远距离为0.23mm。还可见到沿胼胝体向对侧脑室迁移的细胞流,甚至有个别细胞迁移至脊髓腰段。所有动物在细胞移植后4周均未发现肿瘤形成。结论:MSCs脑内移植后可以在中枢神经系统内存活并迁移,无致瘤性。结果提示骨髓间充质细胞是很多疾病细胞与基因治疗的有力工具。     

基于卫星信标跟踪的斑海豹放流效果研究

利用卫星标记跟踪方法对斑海豹的野外释放效果进行了研究。2010 年和2011 年6 月分别释放了4 头和3头人工繁殖的2 龄未成年斑海豹,2011 年同时释放了3 头野外出生的救助个体。标记斑海豹在释放后,7 头人工繁殖斑海豹中的5 头信标信号持续时间较长,在信号消失前,1 头斑海豹一直在渤海海域活动,另4 头沿辽宁沿岸、朝鲜西海岸到达辽东湾斑海豹的主要度夏海域韩国白翎岛附近。研究期间,1 头人工繁殖的斑海豹在59 d内运动的距离超过1 250 km。救助斑海豹中,2 头个体的信标信号持续较长,并分别在山东半岛沿海和黄渤海活动。研究结果表明,人工繁殖的斑海豹在经过野化训练后,放归自然海域后可以正常生活洄游。     

卵表化合物对桔小实蝇产卵行为的影响

多种实蝇科害虫产卵后可释放寄主标记信息素来表明寄主果实已经被占据，从而调节自身或同种个体间的对寄主果实的产卵选择行为。为探明桔小实蝇卵表化合物的寄主标记作用，本文测定了桔小实蝇卵表甲醇提取物对桔小实蝇的产卵驱避活性，并观察了甲醇提取物处理对桔小实蝇产卵行为过程的影响。结果表明：桔小实蝇卵表甲醇提取物对桔小实蝇有明显的产卵驱避活性，且活性随浓度的增加而增强，当提取物浓度为100 mg/mL（虫卵与溶剂质量体积比，m/v）时，在选择性条件下的产卵驱避率为55-45%；非选择性条件下的产卵驱避率达到64%-79%。经卵表提取物处理后，桔小实蝇在寄主果实上的访问次数、试探产卵时间、试探产卵次数、实际产卵次数和产卵量均显著少于对照。证实了桔小实蝇卵表化合物具有明显的产卵寄主标记作用。     

桔小实蝇在中国云南省的分布(英文)

在云南 1 2个县的诱捕试验表明 ,桔小实蝇在云南的分布可以划分为 3个区域。广南、元江和瑞丽以南的地区为该虫常年发生区。在该区域内 ,桔小实蝇年发生 4- 5代 ,可对瓜果形成周年危害。位于六库、大姚和曲靖以北的地区为该虫的非分布区。本试验未能在该地区诱捕到桔小实蝇或桔小实蝇受害果。位于上述两区域之间的区域为桔小实蝇季节性分布区。桔小实蝇在该地区年发生 2 - 3代 ,出现于 5- 1 1月。桔小实蝇在分布区内不同地区的发生高峰期 ,由南向北逐渐推移 ,如在景洪为 6月而在姚安为 1 0月。在地理垂直分布上 ,该虫主要分布于海拔 50 0 - 2 30 0m范围内 ,而其在 50 0 - 1 0 0 0m范围内发生量最大。研究认为 ,桔小实蝇在上述经度和海拔范围的发生与分布 ,主要与当地气候条件与寄主植物有关。     

外来入侵植物黄顶菊在我国的地理分布格局及其时空动态

【目的】黄顶菊是20世纪90年代入侵我国的恶性外来杂草,近年来呈快速扩散蔓延趋势。全面解析黄顶菊在我国的扩散动态对制定早期监测预警等管理措施具有重要意义。【方法】通过查阅文献和标本记录及实地调查等途径重建了黄顶菊在我国扩散的历史过程,分析了其地理分布格局及其主要扩散路线,以及最早入侵地与传入途径。【结果】黄顶菊最早入侵河北省南部的邯郸、衡水,其后主要沿公路扩散蔓延,71%的分布点在距入侵地国道等主要公路2 km的范围内。目前,该杂草已从最初的入侵地向北扩散到天津市,向东扩散到山东省东营市,向西扩散到了山西省黎城市,向南扩散到了河南省开封市。黄顶菊向4个方向扩散的直线距离不等(100～350 km),这种差异与自然屏障和扩散通道相关。太行山脉是黄顶菊向西扩散的地理屏障,但这个屏障已逐渐被突破。至今,黄顶菊已入侵华北地区5个省市(河北、山东、天津、河南和山西)的100余个县。【结论】黄顶菊在我国仍处于快速扩散阶段,未来应该会继续沿公路向南和向西蔓延。因此,亟需在扩散的前沿地带开展监测预警工作,以抑制其在我国的进一步扩散。     

基于CLIMEX的桔小实蝇在中国适生区的预测

桔小实蝇Bactroceradorsalis(Hendel),属双翅目Diptera,果实蝇科Tetriphitidae,主要分布在热带和亚热带地区。温度和湿度是影响桔小实蝇分布的重要气候因子。根据桔小实蝇对温湿度等气候因子的反应,采用CLIMEX软件对桔小实蝇在中国大陆的适生区进行了预测。设置了CLIMEX中的相应参数17个:发育起点温度DV0、生长最适宜温度范围DV1～DV2、致死高温DV3、有效发育积温PDD。生长发育所需最低土壤湿度临界SM0、最适宜湿度范围SM1～SM2、最高土壤湿度临界SM3。冷胁迫日度临界DTCS及其积累速率DHCS,热胁迫临界温度TTHS及其积累速率THHS,干旱胁迫临界SMDS及其积累速率HDS,湿胁迫SMWS及其积累速率HWS。以印度和夏威夷为已知适生分布区,反复调试修正上述这些参数值,使之与已知广泛分布的地区达到最大程度的吻合。然后用优化后的参数和中国大陆85个气象站点的气象资料模拟桔小实蝇在中国大陆的适生分布,结果显示:广东、海南、香港、广西、四川、云南、湖南、湖北、福建、江西、浙江等11个省(区)是桔小实蝇的适生分布区。主要分布在我国的华南和西南大部分地区,以及华中和华东的部分地区。根据CLIMEX模拟结果的EI值大小,将桔小实蝇在我国大陆的适生分布情况进一步划分为最适宜、次适宜、适宜和非适宜4个气候区,即华南地区全部以及广西省全境是桔小实蝇的最适宜分布区,除桂林(EI=17)外,其余气象点的EI值均大于40;西南地区的四川、云南两省及福建沿海地区是桔小实蝇的次适宜分布区,平均EI值为29.7;适宜分布区包括湖南、湖北、江西、浙江的少数地区,除赣州(EI=17)外,其余点的EI值均小于10;长江以北的广大地区是桔小实蝇的非适宜区,这些地区不适合桔小实蝇生存。     

Recapture of sterile Mediterranean fruit flies (Diptera: Tephritidae) in California's Preventative Release Program

In southern California, the sterile insect technique has been used since 1994 to prevent establishment of the Mediterranean fruit fly, Ceratitis capitata (Wiedemann). This method involves the continual mass release of sterile flies, which suppress or eliminate any introduced wild fly populations. In addition, Jackson traps baited with trimedlure are deployed throughout the preventative release region for the dual purpose of detecting wild flies and monitoring released sterile flies. Sterile fly recapture data for a 3-yr period was compared with climate and to host plant (in which traps were placed). Precipitation was negatively correlated; and temperature and relative humidity were positively correlated with fly recapture levels. The highest numbers of flies were recaptured during trapping periods associated with intermediate relative humidity and temperature, and low precipitation. Flies were recaptured throughout the entire year, in traps that had been frequently relocated to host plants with fruit. This finding suggests that these flies were capable of locating acceptable fruit in a variety of abiotic conditions. However, these data do not necessarily suggest that measurements unimportant in explaining sterile fly recapture are not of value in determining other outcomes important to the goals of sterile release programs, such as reducing the likelihood of establishment of an introduced wild Mediterranean fruit fly population. Future research might build on these results in developing more precise models useful in predicting recapture of sterile flies.     

Relationship among five populations of Bactrocera dorsalis based on mitochondrial DNA sequences in western Yunnan, China

Genetic variation in the Oriental fruit fly, Bactrocera dorsalis (Hendel), was analysed using five populations from western Yunnan, China, to elucidate the distribution and likely dispersal patterns of this fly. A 503-bp portion of the mitochondrial cytochrome oxidase gene was sequenced from a minimum of seven individuals from each of five fly populations; 25 haplotypes were observed among 57 individuals in these populations. High genetic diversity within populations was detected. Genetic distances between haplotypes reached 1.2%. Mantel tests did not indicate any isolation because of geographic distance. The Ruili (RL) population was significantly isolated from the others (pairwise Fst ranging from 0.10 to 0.21, and average genetic distances being higher than for all other four population comparisons). RL is geographically separated from the other sites by the Gaoligong Mountains. The Liuku (LK) population had a close genetic relationship with the Lujiangba (LJB) population, suggesting that the LK population probably originated from LJB that is located in the same valley to the south. The Baoshan (BS) and Dali (DL) populations were also geographically isolated from the others, not originating from LJB and RL, where the fly is present year-round. The north-south orientation of mountains and valleys in western Yunnan appears to prevent latitudinal gene exchange by dispersing flies and thus divides the five populations into four relatively independent zones, namely BS, DL, LK-LJB and RL. In addition, air currents that generally flow south to north appear to assist dispersing flies, especially in valleys between the mountain chains.     

Spatial patterns of sterile Mediterranean fruit fly dispersal

The success of the sterile insect technique (SIT) for the control of the Mediterranean fruit fly or medfly, Ceratitis capitata (Wiedemann) (Diptera: Tephritidae), depends largely on the ability of sterile flies to spread in the target area and compete with the wild males for wild females. Our objectives in the present study were three‐fold: (1) to evaluate the dispersal ability of sterile male medflies and compare their spatial dispersion patterns with that of wild males, (2) to evaluate how different release methods affect subsequent spatial dispersal, and (3) to determine whether manipulating the pre‐release diet of sterile males affects their dispersal. To achieve these objectives, we conducted three experiments in the field where we quantified and analyzed the spatial and temporal dispersal patterns of sterile medflies and the dispersion of resident wild males. Overall, ca. 5% of the released sterile flies were recaptured 100 m from the release point, and ca. 2% were recaptured 200 m from the release point. The released flies rarely survived longer than 5–7 days. We repeatedly found that the spatial dispersion patterns of sterile males significantly correlated with those of wild males. Release methods strongly affected subsequent fly dispersal in the field as significantly more flies were recaptured following a scattered release vs. a central one. Finally, we show that enriching sterile fly pre‐release diet with protein did not affect subsequent dispersal in the field. We conclude that sterile males are able to match the dispersion patterns of wild males, an outcome that is highly important for SIT success. Large releases from central points distant from each other may leave many areas uncovered. Accordingly, scattered releases, repeated twice a week, will provide better coverage of all available aggregations sites. The spatial performance of protein‐fed males suggests that pre‐release diet amendments may be used without detriment as a sexual stimulant in SIT programs.     

Dispersal of mass‐reared sterile,laboratory‐domesticated and wild male Queensland fruit flies

Queensland fruit flies, Bactrocera tryoni (Froggatt) (Diptera: Tephritidae) (‘Q‐flies’) were released as sexually immature adults from a point within an orchard. Marked male Q‐flies were recaptured in the trap furthest from the release point (1087 m) by 2 weeks after release, although 98.25 ± 1.04% of recaptured males were trapped <500 m from the release point. Comparison of gamma‐irradiated (sterile), laboratory‐adapted and wild male Q‐flies indicated that dispersal distance was not significantly affected by fly type. There was no significant correlation between temperature and mean dispersal distance, but total recaptures were significantly negatively correlated with increasing daily maximum, minimum and average temperature.     

Persistence of sterile screwworm (Diptera: Calliphoridae) flies at a release site.

Studies to determine the persistence of released, sterile screwworms, Cochliomyia hominivorax (Coquerel), were conducted in Belize, Central America, in 1987-1988. A total of nine releases were made, each consisting of 4,000 females marked with a fluorescent dust. Previous similar studies with baited fly traps indicated that flies died or dispersed from the release site within 3-4 d. For this study, flies were recaptured at sentinel animals. Recapture rates varied greatly between releases, a result that was not correlated with any weather parameter. The pattern of recapture indicated a sharp drop in the released population after 9-10 d, with a few flies persisting in the release area for up to 3 wk. The results suggest that survival of released sterile flies is comparable with estimated survival rate and life span of wild, native flies.     

Understanding Bactrocera dorsalis trapping to calibrate area-wide management

Knowing the dispersal of released insects and estimating the size of field populations are keys to the successful implementation of area-wide management (AWM) programmes based on the sterile insect technique (SIT), as they determine the release strategy of sterile males. Mark–release–recapture (MRR) is a common method used to estimate field populations and spatiotemporal dynamics. However, the extent to which the pest is attracted to lures is often difficult to identify, thereby biasing extrapolation to movement patterns and population size. We performed MRR experiments on the Oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae), in a fruit-growing area in Senegal. Methyl eugenol and protein baits were used to trap males and females, respectively. After studying the suitability of marking B. dorsalis with fluorescent pigments at the laboratory, two releases of marked sterile flies were organized in the centre of an organic mango orchard, first in the late mango fruiting stage and second in the fruit setting stage. Traps were placed symmetrically along a 250 and 500 m radius from the release point. A very small fraction of the released individuals was recaptured: 0.45% in the first release and 3.08% in the second. Trapping of both sterile and wild flies was completely anisotropic. Sterile flies were mostly trapped at a relatively short distance (250 m) from the release point, in the first two days. Male trapping using methyl eugenol was highly effective, whereas the response of females to food bait traps was low. The direction of the wind was the main driver of recapture, with flies heading upwind. The results underline the importance of taking the odour plume around the traps into account when estimating populations, and the heterogeneous spread of the wild population in the landscape for the set-up of the release strategy of sterile insects for SIT-based AWM.     

Short-range dispersal of recently emerged males and females of Bactrocera tryoni (Froggatt) (Diptera: Tephritidae) monitored by sticky sphere traps baited with protein and Lynfield traps baited with cue-lure

Abstract  Dispersal of immature male and female Queensland fruit fly, Bactrocera tryoni (Froggatt) (Diptera: Tephritidae), was assessed over a period of 1 week from a single release point on three separate occasions using an array of Lynfield traps baited with cue-lure and odouriferous yellow or black sticky spheres baited with food lure (protein autolysate). Lynfield traps recaptured males; yellow or black spheres recaptured both sexes in approximately equal proportions, although at a much lower rate. As a percentage of the recapture rate for males by Lynfield traps, the mean recapture rate for yellow spheres ranged from 1.0% to 7.5% for males and 0.7% to 4.0% for females, whereas the recapture rates for black spheres ranged from 0.4% to 3.6% and 0.6% to 1.8%, respectively. The rate of recapture of sterile male flies was greater than that of unsterilised flies; this may have been due to a faster maturation rate in sterile males or because a greater proportion of them remained within the trap array rather than dispersing. There was no significant trend in recapture rate with distance from the release point to the edge of the array (88 m), except in the case of females on sticky traps where no trend was detected between 19 and 88 m. These results lend support to assumptions made about the distribution of males and females with respect to the minimum breeding density of fruit fly propagules invading a fly-free zone, and the method chosen to distribute sterile B. tryoni for the sterile insect technique.     

A mark-release-recapture experiment with Anopheles sinensis in the northern part of Gyeonggi-do,Korea

In order to study the range of flight and feeding activity of Anopheles sinensis, the dispersal experiment was conducted in Paju city, located in the northern part of Gyeonggi-do, Republic of Korea, during the period of 7th to 28th September 1998. Unfed females An. sinensis were collected in cowshed and released after being marked with fluorescent dye at 23:00 hours on the same day. Released female mosquitoes were recaptured everyday during 21 days using light traps, which were set at 10 sites in the cowsheds located 1, 3, 6, 9 and 12 km north-northwest and north-northeast and at 3 sites located 1, 6 and 9 km toward south-west from the release point. In addition, to study the longest flight distance in one night, we set the light traps at 16 and 20 km toward north-northeast from the release site. All the collected mosquitoes were placed on filter papers and observed on UV transilluminator after treatment with one drop of 100% ethanol. Out of 12,773 females of An. sinensis released, 194 marked females mosquitoes were recaptured, giving 1.52% recapture rate. Of 194, 72 mosquitoes (37.1%) were recaptured in light traps from three places set at 1 km from the release point, 57 mosquitoes (29.4%) from two places at 1-3 km, 41 mosquitoes (21.1%) from three places at 3-6 km, 20 mosquitoes (10.3%) from three places at 6-9 km, and 4 mosquitoes (2.1%) from two places at 9-12 km. Since 170 female mosquitoes (87.6%) out of 194 marked mosquitoes were captured within 6 km from the release point, this flight radius represents the main activity area. An sinensis was found to be able to fly at least 12 km during one night.