共查询到19条相似文献,搜索用时 160 毫秒
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在昆虫系统学中,传统分类学作为昆虫分类的主要方法,在昆虫形态分类中发挥着重要的作用,但是对于近缘种分类上却没有明确的界限。生物学技术的发展,在昆虫系统学中应用核糖体DNA序列分析的方法,有效的解决了传统分类学的局限性,在昆虫种、属和种群水平的研究中发挥了重要作用。本文对核糖体DNA序列分析的方法进行分析,探讨其在昆虫系统学中的应用。 相似文献
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小分子化合物种类繁多,在众多生化过程中发挥关键作用,具有重要的检测意义与价值,其快速灵敏可视化检测技术的开发是当前的研究热点。基于核糖开关的生物传感器因具有识别特性高、操作简便、成本低等优势,为小分子检测提供了一条新途径。对核糖开关的来源、构成、调控机制、体内外筛选,特别是对基于小分子靶标的核糖开关生物传感器分类进行了介绍,并从核糖开关的筛选、裁剪、理性设计、核糖开关无细胞传感器的应用等几个方向提出了展望,以期为小分子靶标的核糖开关生物传感器的发展和应用提供理论依据。 相似文献
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弯齿琵甲Blaps femoralis Fischervon Waldheim是中国北方的优势土壤昆虫,其防御腺分泌物用于御敌和引起本种群体的集结,体外具有一定毒性,民间将该虫作为药用昆虫资源利用年代久远。由该虫防御腺体获得分泌物并经气相色谱-质谱联用技术(GC-MS)分析,共计获得14种小分子化合物,其中以2-甲基苯醌、1-十三碳烯和2,4-二甲基-3-呋喃乙酮含量较高,苯醌、苯二酚、3,5-二羟基甲苯和十二烷醛等小分子化合物次之。研究证实该分泌物具有较明显的抑菌能力。研究结果为今后进一步深入开展弯齿琵甲的防御腺化学分泌物天然产物的研究积累了工作。 相似文献
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线粒体DNA序列特点与昆虫系统学研究 总被引:50,自引:9,他引:41
昆虫线粒体DNA是昆虫分子系统学研究中应用最为广泛的遗传物质之一。线粒体DNA具有进化速率较核DNA快 ,遗传过程不发生基因重组、倒位、易位等突变 ,并且遵守严格的母系遗传方式等特点。本文概述了mtDNA中的rRNA、tRNA、蛋白编码基因和非编码区的一般属性 ,分析了它们在昆虫分子系统学研究中的应用价值 ,以及应用DNA序列数据来推导分类阶 (单 )元的系统发育关系时 ,基因或DNA片段选择的重要性 相似文献
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双翅目昆虫分为长角亚目和短角亚目,前者主要类群包括蚊、蠓、蛉和蚋,后者主要类群为虻类和蝇类。国内外学者对双翅目昆虫形态分类和分子系统发育关系研究均较多。本文整理总结了几种主要核基因在双翅目昆虫进化和系统发育关系的研究资料,结果显示:双翅目的单系性得到了众多形态学、生物学和分子数据的支持,多数系统发育研究认为传统的长角亚目为并系,短角亚目是一个单系,其主要类群舞虻下目、环裂类、有缝组和有瓣蝇类均为单系,但非环裂类、无缝组为并系,无瓣类可能为并系;基本搞清了有重要医学意义和与环境关系密切的类群,特别是有瓣蝇类各科类群分类系统的进化关系;双翅目昆虫发生辐射进化的三个分支节点时间即:低等双翅目(蚊类)2.2亿年、低等短角亚目(虻类)1.8亿年、有缝组(蝇类)6500万年;大量双翅目昆虫自然生命史历经吸血性、植食性和寄生性,有2.6亿年以上的演化历程。从相关核基因研究中总结出:18SrRNA、28SrRNA和CAD基因能很好的解决高级阶元从目到属的系统发育问题;EF-1ɑ基因和White基因更适合从科到属水平的分类阶元;ITS基因一般应用在从属到种水平的低级分类阶元,并被广泛应用到双翅目昆虫分子系统学研究中。 相似文献
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昆虫核酸分子系统学研究进展 总被引:6,自引:0,他引:6
本文从研究对象、方法、类群、内容等方面综述了近十年来昆虫核酸分子系统学研究进展概况。文中首先介绍了RFLPA、探针杂交及DNA指纹、PCR与RAPD-PCR、顺序分析方法及应用情况,列举了在双翅目、膜翅目、同翅目、直翅目等目昆虫中的研究进展,并从居群遗传结构、分类学研究、系统发育和分子进化4个方面总结了昆虫核酸分子系统学的研究内容和主要成果,最后指出RAPD-PCR与RFLP联合用于测序是近期昆虫分子系统学上最有应用价值的方法。 相似文献
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ITS序列的特点及其在昆虫学研究中的应用 总被引:1,自引:0,他引:1
随着PCR技术和DNA测序技术的成熟及广泛应用,分子数据的分析和利用逐渐成为生物学研究的重要手段。基因组中含有丰富的遗传信息,运用核基因序列或将核基因与线粒体基因序列相结合作为遗传标记,研究昆虫的系统发育,已成为分子系统学领域的发展趋势。由于长度适中、易于扩增、进化速度快、变异性高等优点,核糖体基因中内转录间隔区(ITS)已在昆虫系统学研究中得到广泛的应用。本文介绍了ITS序列的结构特点,重点对ITS序列在近缘种及种型快速鉴定、属及属上高级阶元系统学研究、谱系生物地理学及与其它基因联合分析昆虫系统进化关系等研究中的应用及前景进行了综述。 相似文献
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核基因序列在昆虫分子系统学上的应用 总被引:16,自引:2,他引:14
核基因中含有更加丰富的生物学信息,运用核基因序列或将核基因序列与线粒体基因序列相结合研究昆虫的系统发育正成为分子系统学领域的一种发展趋势.核糖体基因中18S rDNA、28S rDNA、ITS已在昆虫分子系统学中得到了广泛的应用.与核糖体基因相比,虽然编码蛋白的核基因应用于昆虫分子系统学的种类不少,但大部分都是应用于双翅目和鳞翅目昆虫的分子系统学研究中,能够成功地普遍用于多个目昆虫的系统学研究的核基因并不多.本文简要介绍了应用于昆虫分子系统学的核中核糖体基因和编码蛋白的核基因,并分析了核基因序列在分子系统学应用上的局限性和应用前景. 相似文献
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昆虫标本馆建设与昆虫系统学的未来 总被引:6,自引:0,他引:6
昆虫标本馆是昆虫标本的保藏、研究和科学教育的实体,代表国家或者区域水平,致力于研究昆虫多样性、揭示昆虫进化规律,为国民经济建设持续发展服务。昆虫系统学研究是昆虫标本馆研究人员的主要任务,它的发展与昆虫标本馆的建设唇齿相依。本文阐述了昆虫标本馆的功能与作用,建设昆虫标本馆的重要性和迫切性;展望了昆虫系统学的未来以及昆虫系统学发展的机遇。 相似文献
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Satoshi Takeda 《Entomological Science》2013,16(2):125-135
In recent years, research on “insect properties” has been attracting much attention for industrial applications of insect technology. This is a new field of research that attempts to analyze specific physiological properties of insects to develop technology for helping humankind. The term “insect properties” has been used to refer to “specific biological functions of insects” since around 1986, and it is now widely accepted in Japan. From 1996, the National Institute of Sericultural and Entomological Science (NISES) promoted “Research for utilization of insect properties” as a “Center of Excellence (COE)” project funded by the Science and Technology Agency. At this point, a new research field called “Research for utilization of insect properties” was initiated, and this led to the recognition of this field by the academic community. In the 21st century, remarkable results, including the development of transgenic silkworms and the full decoding of the silkworm genome, have been achieved. It is expected that this advanced technology will be a powerful tool for progress of research on the use of insect properties. This review presents an overview of the current state of research on use of insect properties as a new technology. 相似文献
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Mechanics and aerodynamics of insect flight control 总被引:8,自引:0,他引:8
GRAHAM K. TAYLOR 《Biological reviews of the Cambridge Philosophical Society》2001,76(4):449-471
Insects have evolved sophisticated fight control mechanisms permitting a remarkable range of manoeuvres. Here, I present a qualitative analysis of insect flight control from the perspective of flight mechanics, drawing upon both the neurophysiology and biomechanics literatures. The current literature does not permit a formal, quantitative analysis of flight control, because the aerodynamic force systems that biologists have measured have rarely been complete and the position of the centre of gravity has only been recorded in a few studies. Treating the two best-known insect orders (Diptera and Orthoptera) separately from other insects, I discuss the control mechanisms of different insects in detail. Recent experimental studies suggest that the helicopter model of flight control proposed for Drosophila spp. may be better thought of as a facultative strategy for flight control, rather than the fixed (albeit selected) constraint that it is usually interpreted to be. On the other hand, the so-called 'constant-lift reaction' of locusts appears not to be a reflex for maintaining constant lift at varying angles of attack, as is usually assumed, but rather a mechanism to restore the insect to pitch equilibrium following a disturbance. Differences in the kinematic control mechanisms used by the various insect orders are related to differences in the arrangement of the wings, the construction of the flight motor and the unsteady mechanisms of lift production that are used. Since the evolution of insect flight control is likely to have paralleled the evolutionary refinement of these unsteady aerodynamic mechanisms, taxonomic differences in the kinematics of control could provide an assay of the relative importance of different unsteady mechanisms. Although the control kinematics vary widely between orders, the number of degrees of freedom that different insects can control will always be limited by the number of independent control inputs that they use. Control of the moments about all three axes (as used by most conventional aircraft) has only been proven for larger flies and dragonflies, but is likely to be widespread in insects given the number of independent control inputs available to them. Unlike in conventional aircraft, however, insects' control inputs are likely to be highly non-orthogonal, and this will tend to complicate the neural processing required to separate the various motions. 相似文献
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David Baracchi Leonardo Dapporto Serafino Teseo Rosli Hashim Stefano Turillazzi 《Journal of Zoological Systematics and Evolutionary Research》2010,48(2):109-114
The Stenogastrinae wasps have been proposed as a key group for an understanding of social evolution in insects, but the phylogeny of the group is still under discussion. The use of chemical characters, in particular cuticular hydrocarbons, for insect taxonomy is relatively recent and only a few studies have been conducted on the cuticular polar substances. In this work, we ascertain, by the matrix‐assisted laser desorption ionization‐time of flight mass spectrometry technique, that different species of primitively eusocial hover wasps have different compositions of the epicuticular polar compounds ranging from 900 to 3600 Da. General linear model analysis and discriminant analysis showed that the average spectral profiles of this fraction can be diagnostic for identification of the species. Moreover, for the first time we show population diversification in the medium MW polar cuticular mixtures in insects. In conclusion, the results demonstrate that the chemical characters are consistent with the physical characters and the study support the importance of medium MW polar substances as powerful tools for systematics (chemosystematics) and chemical ecology (fertility signal and population characterization) in a primitively social insect taxon. 相似文献
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Recording semi-isolated insect heartbeat at one time was anart only to be attempted by the most patient of research workers.Thanks to modern advances in biomedical instrumentation, insectheartbeat measurement by impedance conversion and contact thermographyallows not only heartbeat recordings, but recording of accessorypulsatile organs and diaphragm movements. The characteristicheartbeat patterns as recorded from adult insects vary enormouslyfrom very regular in orthopteroids to highly irregular in Diptera.Pupal stages in holometabolous insects are characterized bya heartbeat which appears to have little or no nervous influenceand is punctuated by cessation for periods up to several hoursin some insects. The controversy over nervous and/or hormonalcontrol of insect heartbeat has never been completely resolved.There is now a good deal of evidence for nervous control ofthe heartbeat of Dipteran adults, Lepidopteran adults, Orthopterannymphs and adults, Dictyopteran nymphs and adults, and Hymenopteranadults. The evidence of hormonal control of heartbeat remainsinferential, and is based mostly on the responses of semi-isolatedheart preparations. One of the most important events in recentyears in this field has been Brian Brown's elucidation of Proctolinin cooperation with Alvin Starratt in Canada. Proctolin is asuspected neurohormone or neurohumor of the proctodeum whichmay also be used to regulate heartbeat in insects. 相似文献
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Sabrina Simon Bernd Schierwater Heike Hadrys 《Molecular phylogenetics and evolution》2010,54(2):651-656
Pterygota are traditionally divided in two lineages, the “Palaeoptera” and Neoptera. Despite several efforts neither morphology nor molecular systematics have resolved the phylogeny of the pterygote insects. Too few markers have yet been identified for adequately tracking mesozoic-aged divergences. We tested the Elongation factor-1α for its phylogenetic value in pterygote insect systematics. This highly conserved nuclear protein-coding gene has previously been reported to be useful in other groups for phylogenetic analyses at the intraordinal level as well as at the interordinal level. The analyses suggest that EF-1α DNA sequences as well as intron positions provide informative markers for pterygote phylogenetics. 相似文献
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Insect pests of cereal crop plants are among the most destructive and devastating factors limiting world food production. Insects often inflict losses of 15 to 50% of the yield of some crops in various parts of the world. Insects also provide infection courts for various pathogens that inflict even greater damage. The nature of these losses is especially tragic for poor farmers in the tropics since the insects consume dry matter already produced using limited resources. Reduction of these losses would enhance the world food supply available to man, even if actual production remains the same, by allotting to man and animals that proportion of production now consumed by insects. Control of insect‐inflicted damage on a world‐wide basis is a very difficult task. Chemical control is effective and readily available in some, but not all, countries. However, chemical control is often unavailable, ineffective, too expensive, and likely to create environmental and safety hazards that make it unsuitable for many parts of the world. Several excellent examples of biological control of insects also attest to the potential usefulness of this method of reducing insect‐inflicted losses, but this method also has been ineffective for certain major insect pests due to lack of effective identification, distribution, and maintenance of biological control agents. On the whole, host plant resistance (HPR) to insects has been the most successful and widely used method of control. HPR has been used successfully in a number of major crop species to help control damage inflicted by major insect pests. However, problems with identifying sources of resistance and transferring it to usable varieties have often been difficult to overcome. Also, once resistance is deployed, changes in insect populations which allow them to overcome the resistance sometimes eliminate the potential advantages of resistant varieties. However, methods to quantify host‐insect interactions have improved significantly over the past few years, and the prospects for developing and maintaining usable levels of resistance to several major insect pests of most major crops are good. Studies of the biochemical and biophysical mechanisms of insect resistance have added a new dimension to HPR work. Knowledge of specific factors that contribute to insect resistance can be extremely useful to plant breeders and entomologists. The ability to identify and select for one specific plant component or group of components can speed the development of resistant varieties. Studies of the effect of such resistance components on insect development and behavior can help determine the likelihood of insects being able to overcome the resistance factors. Studies of the effect of the resistance factors on host plant yield, performance, or quality may help plant breeders overcome the problems often associated with the development of high yielding and high quality resistant varieties. Identification of several different mechanisms of resistance could provide breeders the opportunity to adjust levels of several resistance components in order to arrive at a proper blend of resistance, quality, and yield. Furthermore, development of varieties with multiple mechanisms of resistance should slow the development of new biotypes of insects that could overcome the HPR since the insects would have to simultaneously or sequentially develop the ability to overcome several resistance factors. Therefore, knowledge of mechanisms of insect resistance could facilitate the development of more stable and long‐lasting types of resistance. 相似文献
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昆虫的RNA干扰 总被引:2,自引:0,他引:2
RNA干扰(RNAi)是一种强有力的分子生物学技术, 在昆虫研究中得到了较多的应用。目前, RNAi技术主要应用于昆虫功能基因和功能基因组研究, 已在多个目的19种昆虫上实现了RNAi。在昆虫上实现RNAi的方法主要有注射、浸泡、喂食、转基因和病毒介导等方法, 这些方法各有特点, 其中喂食法因其简单而最有应用前景。昆虫RNAi的系统性较为复杂, 只有部分昆虫具有RNAi的系统性。昆虫中RNAi信号传导的基因可能是sid-1, 但昆虫RNAi的系统性机理还不是很清楚。转基因植物产生的dsRNA实现了对作物的保护, 证实了RNAi技术可用于害虫控制, 为害虫控制开辟了新领域。昆虫的RNAi研究处在起步阶段, 研究昆虫RNAi的机理, 特别是RNAi在昆虫体内的系统性扩散机理, 改进实现RNAi的方法, 提高RNAi技术在昆虫研究中的应用, 有利于昆虫基因功能鉴定和害虫控制, 促进昆虫学科的发展。 相似文献