湖南省几种实蝇的形态鉴别

综合比较了6种湖南省内捕获的实蝇类昆虫雄成虫的形态鉴别特征,其中离腹寡毛实蝇属(Bactrocera)5种(包括具条实蝇B.scutellata(Hendel)、南瓜实蝇B.tau(Walker)、瓜实蝇B.cucturbitae(Coquillett)、桔小实蝇B.dorsalis(Hendel)和柑橘大实蝇B.(Tetradacus)minax(Enderlein)),以及合腹寡毛实蝇属(Dacus)1种(棍腹实蝇Dacus sp.),以期为实蝇类害虫的检疫和防控提供依据.     

基于mtDNA Cytb 的六种果实蝇的分子鉴定

本研究首次对果实蝇属的桔小实蝇Bactrocera dorsalis、瓜实蝇B. cucurbitae、南瓜实蝇B. tau、番石榴实蝇B. correcta、具条实蝇B. scutellata、黑漆实蝇B. scutellaris等6种实蝇mtDNA Cytb基因进行了测序。对这6种实蝇72个个体mtDNA Cytb基因中段420 bp的碱基序列进行分析,得到38种单倍型,发现了116个变异位点,其中30个位点较为稳定。对这6种实蝇与其各自鉴别位点的对应关系研究表明,mtDNA Cytb基因可以作为这6种实蝇种类鉴别的分子标记。     

桔小实蝇和番石榴实蝇幼虫取食阶段的种内竞争

种内竞争是实蝇的重要生态学特性。本文研究比较了近缘种桔小实蝇Bactrocera dorsalis(Hendel)和番石榴实蝇B.correcta(Bezzi)在幼虫人工饲料中种内竞争的密度效应。研究结果显示,桔小实蝇和番石榴实蝇都有密度过低效应,均表现出发育历期较长、蛹较轻和成活率较低;结合蛹重和成活率两个重要参数指标,明确了桔小实蝇和番石榴实蝇的最宜密度均在5-20头虫/10 g饲料;不同生长参数之间的变化均有一定的正负相关性。当种群密度超过最宜密度,桔小实蝇和番石榴实蝇均有明显的种内竞争现象,随着种群密度的升高,种内竞争越激烈。其主要表现为化蛹率和羽化率不断下降、幼虫历期逐渐缩短、蛹历期不断延长和蛹逐渐变小;当100头虫/10 g饲料时,桔小实蝇和番石榴实蝇成活率从86.00%±4.2688%和86.00%±4.1096%分别下降到60.08%±2.5166%和76.33%±2.2333%。桔小实蝇和番石榴实蝇的种内竞争的密度效应极具相似性,推测这两种实蝇有类似的种群调节机制,但番石榴实蝇的幼虫比桔小实蝇的拥有更强的抗拥挤能力。     

桔小实蝇与木瓜实蝇杂交后代产卵管长度的表型遗传特征

桔小实蝇Bactrocera dorsalis和木瓜实蝇B.papayae同属桔小实蝇复合种,形态鉴别特征主要依据产卵管长度的差异性。近年来随着两种实蝇可杂交繁殖现象的出现,其分类地位也由此引起争议。本研究为进一步验证这两种实蝇杂交可育的持续性及其产卵管长度在杂交后代的遗传特征,观测并分析了这两种实蝇杂交第33代的产卵管长度与其亲本之间的差异性。结果表明,两种实蝇杂交后可持续繁殖,不存在严格的生殖隔离现象。不同遗传种系的产卵管长度具有差异性,但随着杂交行为的出现其差异性随之改变,表明产卵管长度在两种实蝇之间属于种群水平差异性特征。     

云南六种实蝇的RAPD快速鉴定

采用RAPD技术构建了果实蝇属（Bactrocera）的南瓜实蝇(B. tau)、黑漆实蝇(B.scutellaris)、具条实蝇(B. scutellata)、瓜实蝇(B. cucurbitae)、桔小实蝇(B. dorsalis)和番石榴实蝇(B. correcta)6种实蝇的指纹图谱.从131个引物中筛选出5个重复性好、多态性高的引物,共扩增出302条谱带,其中111条谱带具有遗传多态性.引物OPC-01、OPI-17、OPL-07、OPL-08以及OPL-16可以用于6种实蝇的分类鉴定.     

岳麓山周边地区实蝇发生动态监测

采用诱捕法于2010年7月至2011年12月对岳麓山周边地区实蝇的发生情况进行了监测,共获得实蝇类昆虫5种,包括离腹寡毛实蝇属Bactrocera 4种[具条实蝇B.scutellata (Hendel)、南瓜实蝇B.tau (Walker)、瓜实蝇B.cucturbitae (Coquillett)、桔小实蝇B.dorsalis(Hendel)]和合腹寡毛实蝇属Dacus 1种(棍腹实蝇Dacus sp.).其中,具条实蝇发生数量最大,占诱捕总数的76％,从5月到12月有2次数量高峰;其次为瓜实蝇占18％,南瓜实蝇和桔小实蝇数量最少,约各占3％;分析了不同诱剂对各种实蝇的诱捕效果,其中,Me性诱剂仅对桔小实蝇雄虫有引诱效果;Cue性诱剂可引诱具条实蝇、瓜实蝇和南瓜实蝇3种实蝇的雄虫;蛋白诱饵对具条实蝇、瓜实蝇、南瓜实蝇和桔小实蝇的雌、雄虫均有引诱效果.本研究结果可为长沙地区实蝇类害虫的监测和防控提供依据.     

基于线粒体DNA序列的广西蜜柑大实蝇与日本蜜柑大实蝇的比较研究

测定了广西蜜柑大实蝇Bactrocera(Tetradacus)cheni(Zhao)的线粒体COⅠ-COⅡ及16S rDNA的部分序列,与日本蜜柑大实蝇Bactrocera(Tetradacus)tsuneonis(Miyake)及其它近缘实蝇的序列进行了比较分析,用最大简约法及邻接法构建了系统树.结果显示广西蜜柑大实蝇和日本蜜柑大实蝇为近缘种,属于同一单源分支,自展检验置信度均为100%.二者之间的HKY85遗传距离为0.01705,大于昆士兰实蝇和小昆士兰实蝇、桔小实蝇和菲律宾实蝇、具条实蝇和石垣岛实蝇之间的遗传距离,接近于黑肩角桔实蝇与短条面包果实蝇的种间遗传距离.支持广西蜜柑大实蝇与日本蜜柑大实蝇为两个形态学和遗传学上非常接近的不同种.     

桔小实蝇与番石榴实蝇幼虫的种间竞争研究

本文研究了桔小实蝇Bactrocera dorsalis (Hendel)与番石榴实蝇Bactrocera correcta （Bezzi）幼虫在实验室2种环境温度,4种寄主及5个虫口数量比例条件下的种间竞争现象。结果显示,在温度26℃以桃和香蕉为寄主条件下,桔小实蝇存活率高于番石榴实蝇;以芒果为寄主情况下两者存活率差异不显著;以番石榴作为寄主,虫口数量较大的一方具有竞争优势。在温度33℃条件下,就所测试的各种寄主,番石榴实蝇均具有竞争优势。分析发现,温度是影响番石榴实蝇幼虫存活率的关键环境因素;虫口比例对于桔小实蝇的存活率有重要影响;在不同的寄主中,桔小实蝇与番石榴实蝇的存活率也表现出较大的变化,寄主种类与温度及虫量形成综合效应,决定了桔小实蝇与番石榴实蝇竞争的最终结局。     

Establishment and application of DNA barcoding technology for identification of the immatures and adult debris of Bactrocera dorsalis (Hendel) ( Diptera: Tephritidae)

实蝇类害虫多为国内外检疫对象,其鉴定识别方法主要依据成虫的外部形态特征,而传统的形态学识别法对口岸经常截获的幼体及残缺的虫体,则无能为力.本研究以桔小实蝇Bactrocera dorsalis的幼体(卵、幼虫、蛹)以及成虫残体(足、翅、头部、胸部、腹部)为对象,利用DNA条形码技术,构建实蝇类害虫快速鉴定技术体系,并以其他4种常见实蝇(包括番石榴实蝇B.correcta、瓜实蝇B.cucurbitae、南亚果实蝇B.tau、柑桔大实蝇B.minax)为对象对该技术体系进行应用验证.结果显示,桔小实蝇幼体以及成虫残体的碱基序列与数据库中靶标种CO Ⅰ基因碱基序列的一致性为99.51％～99.84％,其他4种实蝇相应序列与数据库中靶标种CO Ⅰ基因序列的一致性分别为100％,100％,99.81％～ 99.83％和100％;以邻接法(NJ法)构建系统发育树,靶标种实蝇均与数据库中对应种实蝇聚为一支,且置信度均为100％.以K2-P模型计算种内及种间遗传距离得出,5种实蝇的种间遗传距离为0.0597～0.2363,平均为0.1693;种内遗传距离为0.0000 ～0.0041,平均为0.0019.这些结果表明,基于DNA条形码的物种识别技术完全可用于口岸截获的实蝇类害虫幼体及残体的准确鉴定.     

不同颜色实蝇粘虫板对桔小实蝇及天敌昆虫的诱捕效果

[目的]为评价不同颜色实蝇粘虫板对桔小实蝇Bactrocera dorsalis Hendel及天敌等昆虫的诱捕效果.[方法]在梨园内,距地面1.5 m处悬挂黄色、蓝色、绿色、红色、紫色5种颜色的普通粘虫板和实蝇粘虫板(含甲基丁香酚),观察并比较了5种颜色普通粘虫板和实蝇粘虫板对桔小实蝇的诱集效应;将实蝇粘虫板上昆虫洗脱下来鉴定、分类和数量统计,进行不同颜色实蝇粘虫板对天敌等昆虫的诱集效果比较.[结果]实蝇粘虫板对桔小实蝇诱捕虫数显著高于普通粘虫板,黄色和绿色实蝇粘虫板每板每周分别诱捕(97.83±9.59)头和(50.50±4.32)头桔小实蝇,且诱虫量显著高于蓝色、红色和紫色粘虫板的.黄色实蝇粘虫板诱集到7种天敌和9种害虫,绿色实蝇粘虫板诱集到5种天敌和9种害虫;5种颜色实蝇粘虫板的益害比均较小.诱捕到的昆虫中以双翅目、鞘翅目、半翅目的昆虫为主,天敌主要有脉翅目、鞘翅目和膜翅目等昆虫,而且均不是桔小实蝇的寄生性天敌,仅有蠼螋这种极少量的捕食性天敌.[结论]黄色和绿色实蝇粘虫板诱杀桔小实蝇效果较好,对天敌的杀伤力相对较小,可在桔小实蝇发生期使用.     

Microsatellite markers for the pest fruit fly,Bactrocera papayae (Diptera: Tephritidae) and other Bactrocera species

The dorsalis complex contains some of the most economically important fruit fly pests of the Asia–Pacific regions, including Bactrocera dorsalis, Bactrocera papayae and Bactrocera carambolae. These species are morphologically indistinct and genetically very similar. We describe the development of 12 microsatellite markers isolated from a representative of the dorsalis complex, B. papayae. We show the potential utility of the B. papayae microsatellites and a set of microsatellites isolated from Bactrocera tryoni as population and species markers for the dorsalis complex.     

橘小实蝇复合体分类学研究进展

橘小实蝇复合体Bactroceradorsaliscomplex是以橘小实蝇命名的实蝇类群,已知75种,广泛分布于亚洲、澳洲及环太平洋周边地区。文章概述基于形态学和遗传学特征基础上的橘小实蝇复合体的分类鉴定及系统发育研究进展,介绍近年来分子生物学技术在橘小实蝇复合体分类及系统发育研究中的应用情况,展望系统发育和行为学研究是橘小实蝇复合体未来研究的重点领域。     

Molecular phylogeny of tephritid fruit flies in the Bactrocera tau complex using the mitochondrial COI sequences.

We compared sequences of the mitochondrial cytochrome oxidase I gene of eight species of the Bactrocera tau complex using Bactrocera dorsalis, Bactrocera pyrifoliae, Ceratitis capitata, Anopheles gambiae, and Locusta migratoria as outgroups. A 639-bp variable region was sequenced. The sequence divergence between species in the B. tau complex ranged from 0.06 to 28%, and up to 29% between the complex and its tephritid outgroups, B. dorsalis and C. capitata. According to the phylogenetic relationships, these members of the B. tau complex could be classified into four clades. Thus, species A and D form clades 1 and 3, respectively, while species C and I belong to clade 4. However, species B, E, and F form a distinct group, clade 2, and infested the fruits of non-cucurbit hosts. Host-plant shifts resulting in adaptive radiation and premating isolation among species might play an important role in species differentiation of the B. tau complex.     

Bridging the morphological and biological species concepts: studies on the Bactrocera dorsalis (Hendel) complex (Diptera: Tephritidae: Dacinae) in South-east Asia

Defining species accurately is a critical need in fundamental disciplines such as ecology and evolutionary biology and in applied arenas such as pest management. The validity of species designations depends on agreement of different methods of species diagnosis for unique biological species. The Bactrocera dorsalis complex of fruit flies provide an excellent opportunity for such a test of the congruence of different techniques (e.g. morphological, molecular, host-plant based, chemotaxonomy) used for species diagnosis. The complex contains a large number of closely-related species, is distributed over a wide geographical range in South-east Asia and considerable information has been compiled on some species. In the present study, the morphological and biological species boundaries were compared using new data from morphometric analyses of reproductive and body parts, together with a review of data on morphology, chemistry of male pheromones that are important in courtship and mating, molecular analyses, and endemic rainforest host plants. For the populations studied ( Bactrocera carambolae , Bactrocera dorsalis , Bactrocera occipitalis , Bactrocera papayae , Bactrocera philippinensis , Bactrocera kandiensis and Bactrocera invadens ) there appears to be significant congruence between the morphological and biological species boundaries.  © 2008 The Linnean Society of London, Biological Journal of the Linnean Society , 2008, 93 , 217–226.     

云南景洪果实蝇属三新种及一新纪录种记述(双翅目,实蝇科)(英文)

记述采自中国云南景洪的果实蝇属3新种和中国1新纪录种:滇黑寡鬃实蝇Bactrocera(Bactrocera)nigrifacia sp.nov.,哈迪氏果实蝇B.(B.)hardyisp.nov.,景洪果实蝇B.(B.)jinghongensis sp.nov.和黑颜面实蝇Bactrocera(Zeugodacus)vultus(Hardy,1973),3新种均符合DrewetHancock(1994)对桔小实蝇复合体的定义。模式标本保存于福建农林大学益虫研究所。滇黑寡鬃实蝇,新种Bactrocera(Bactrocera)nigrifacia sp.nov.(图1～4)新种与黑胫实蝇B.(Bactrocera)nigr of emoralis Whiteet Tsuruta相近,颜均为黑色,与后者的区别在于:2条平行的缝后侧黄色条终止于翅内鬃之前,第2腹背板橙棕色且前缘具黑色横带。正模♂,云南景洪,2010-09-02,Cue-lure引诱,张南南采。副模3♂♂,同正模。词源:新种种名根据颜面黑色而命名。哈迪氏果实蝇,新种Bactrocera(Bactrocera)hardyisp.nov.(图5～7)新种与印尼实蝇Bactrocera(Bactrocera)indonesiae Drewet Hancock相近,与后者的区别为:第3～5腹背板黑褐色,前足腿节黄褐色,且端部具黑褐色斑,中足和后足腿节为黄褐色,且端部具很短的黑褐色条纹。正模♂,云南景洪,2010-09-04,Cue-lure引诱,张南南采。副模3♂♂,同正模。词源:新种种名以双翅目分类专家DilbertE.Hardy的姓氏命名。景洪果实蝇,新种Bactrocera(Bactrocera)jinghongensis sp.nov.(图8～11)新种与基纳巴卢实蝇Bactrocera(Bactrocera)kinabalu Drewet Hancock相近,与后者的区别在于:缝后侧黄色条终止于翅内鬃之前,中足腿节端部1/2黑色。正模♂,云南景洪,2010-09-04,Cue-lure引诱,张南南采。副模4♂♂,同正模。词源:新种种名以模式产地命名。     

福州实蝇监测初报

自2005年5月29日至2006年5月28日在福州金山福建农林大学校园内进行了实蝇监测。采用甲基丁香酚(M e)、诱蝇酮(Cue)和地中海实蝇诱芯(T),诱集到橘小实蝇[Bactrocera(Bactrocera)dorsalis]、瓜实蝇[B.(Zeugodacus)cucurbi-tae]、南瓜实蝇[B.(Zeugodacus)tau]和具条实蝇(B.scutellata)4种实蝇,但未诱到地中海实蝇(Ceratitis capitata)。其中,橘小实蝇诱集量最大,8月中下旬达到高峰。本研究为掌握福州地区实蝇发生动态提供了基础资料。     

Wing shape as a potential discriminator of morphologically similar pest taxa within the Bactrocera dorsalis species complex (Diptera: Tephritidae)

Four morphologically cryptic species of the Bactrocera dorsalis fruit fly complex (B. dorsalis s.s., B. papayae, B. carambolae and B. philippinensis) are serious agricultural pests. As they are difficult to diagnose using traditional taxonomic techniques, we examined the potential for geometric morphometric analysis of wing size and shape to discriminate between them. Fifteen wing landmarks generated size and shape data for 245 specimens for subsequent comparisons among three geographically distinct samples of each species. Intraspecific wing size was significantly different within samples of B. carambolae and B. dorsalis s.s. but not within samples of B. papayae or B. philippinensis. Although B. papayae had the smallest wings (average centroid size=6.002 mm±0.061 SE) and B. dorsalis s.s. the largest (6.349 mm±0.066 SE), interspecific wing size comparisons were generally non-informative and incapable of discriminating species. Contrary to the wing size data, canonical variate analysis based on wing shape data discriminated all species with a relatively high degree of accuracy; individuals were correctly reassigned to their respective species on average 93.27% of the time. A single sample group of B. carambolae from locality 'TN Malaysia' was the only sample to be considerably different from its conspecific groups with regards to both wing size and wing shape. This sample was subsequently deemed to have been originally misidentified and likely represents an undescribed species. We demonstrate that geometric morphometric techniques analysing wing shape represent a promising approach for discriminating between morphologically cryptic taxa of the B. dorsalis species complex.     

Impact of introduction of Bactrocera dorsalis (Diptera: Tephritidae) and classical biological control releases of Fopius arisanus (Hymenoptera: Braconidae) on economically important fruit flies in French Polynesia

Oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae), was discovered on Tahiti Island in July 1996. Eradication programs were conducted from 1997 to 2001, but failed. From 1998 to 2006, B. dorsalis was recovered from 29 different host fruit from the five Society Islands: Tahiti, Moorea, Raiatea, Tahaa, and Huahine. Analysis of coinfestation patterns by B. dorsalis, Bactrocera tryoni (Froggatt), and Bactrocera kirki (Froggatt) suggested B. dorsalis had displaced these two species and become the most abundant fruit fly in coastal areas. To suppress B. dorsalis populations, a classical biological control program was initiated to introduce the natural enemy Fopius arisanus (Sonan) (Hymenoptera: Braconidae) into French Polynesia from Hawaii. Wasps were released and established on Tahiti, Moorea, Raiatea, Tahaa, and Huahine Islands. In guava, Psidium guajava L., collections for Tahiti, F. arisanus parasitism of fruit flies was 2.1, 31.8, 37.5, and 51.9% for fruit collected for 2003, 2004, 2005 and 2006, respectively. Based on guava collections in 2002 (before releases) and 2006 (after releases), there was a subsequent decrease in numbers of B. dorsalis, B. tryoni, and B. kirki fruit flies emerging (per kilogram of fruit) by 75.6, 79.3, and 97.9%, respectively. These increases in F. arisanus parasitism and decreases in infestation were similar for other host fruit. Establishment of F. arisanus is the most successful example of classical biological control of fruit flies in the Pacific area outside of Hawaii and serves as a model for introduction into South America, Africa, and China where species of the B. dorsalis complex are established.     

The current and future potential geographical distribution of the oriental fruit fly, Bactrocera dorsalis (Diptera: Tephritidae)

The oriental fruit fly, Bactrocera dorsalis (Hendel), is a major pest throughout South East Asia and in a number of Pacific Islands. As a result of their widespread distribution, pest status, invasive ability and potential impact on market access, B. dorsalis and many other fruit fly species are considered major threats to many countries. CLIMEX was used to model the potential global distribution of B. dorsalis under current and future climate scenarios. Under current climatic conditions, its projected potential distribution includes much of the tropics and subtropics and extends into warm temperate areas such as southern Mediterranean Europe. The model projects optimal climatic conditions for B. dorsalis in the south-eastern USA, where the principle range-limiting factor is likely to be cold stress. As a result of climate change, the potential global range for B. dorsalis is projected to extend further polewards as cold stress boundaries recede. However, the potential range contracts in areas where precipitation is projected to decrease substantially. The significant increases in the potential distribution of B. dorsalis projected under the climate change scenarios suggest that the World Trade Organization should allow biosecurity authorities to consider the effects of climate change when undertaking pest risk assessments. One of the most significant areas of uncertainty in climate change concerns the greenhouse gas emissions scenarios. Results are provided that span the range of standard Intergovernmental Panel on Climate Change scenarios. The impact on the projected distribution of B. dorsalis is striking, but affects the relative abundance of the fly within the total suitable range more than the total area of climatically suitable habitat.     

Multi‐gene phylogenetic analysis of south‐east Asian pest members of the Bactrocera dorsalis species complex (Diptera: Tephritidae) does not support current taxonomy

Bactrocera dorsalis sensu stricto, B. papayae, B. philippinensis and B. carambolae are serious pest fruit fly species of the B. dorsalis complex that predominantly occur in south‐east Asia and the Pacific. Identifying molecular diagnostics has proven problematic for these four taxa, a situation that cofounds biosecurity and quarantine efforts and which may be the result of at least some of these taxa representing the same biological species. We therefore conducted a phylogenetic study of these four species (and closely related outgroup taxa) based on the individuals collected from a wide geographic range; sequencing six loci (cox1, nad4‐3′, CAD, period, ITS1, ITS2) for approximately 20 individuals from each of 16 sample sites. Data were analysed within maximum likelihood and Bayesian phylogenetic frameworks for individual loci and concatenated data sets for which we applied multiple monophyly and species delimitation tests. Species monophyly was measured by clade support, posterior probability or bootstrap resampling for Bayesian and likelihood analyses respectively, Rosenberg's reciprocal monophyly measure, P(AB), Rodrigo's (P(RD)) and the genealogical sorting index, gsi. We specifically tested whether there was phylogenetic support for the four ‘ingroup’ pest species using a data set of multiple individuals sampled from a number of populations. Based on our combined data set, Bactrocera carambolae emerges as a distinct monophyletic clade, whereas B. dorsalis s.s., B. papayae and B. philippinensis are unresolved. These data add to the growing body of evidence that B. dorsalis s.s., B. papayae and B. philippinensis are the same biological species, which poses consequences for quarantine, trade and pest management.