稻虱缨小蜂触角感器的扫描电镜观察

在稻虱缨小蜂触角上共观察到毛形感器(Ⅰ,Ⅱ型)、板状感器、捧状感器、剑状感器和蒲姆氏鬃感器等五种感器．而雄性触角上则缺少毛形感器Ⅱ型和棒状感器。各类感器的数量和分布在两性间亦存在明显差异。     

A new and phylogenetically suggestive morphotype ofKeratella lenzi (Rotifer,Monogononta), from Argentina

The morphological characteristics ofKeratella lenzi (f.ayui) f. nov. and the phylogenetic and ecological implications of the appearance of posterolateral spines inK. lenzi Hauer, 1953 are discussed. The morphotype is described after detailed observations using light and scanning electron microscopy, and compared with otherKeratella species of the superspecies valga. The pores of the lateral antennae are described, and proposed as a new character for future comparative research. Some ecological information is also given.     

Identification of Olfactory Volatiles using Gas Chromatography-Multi-unit Recordings (GCMR) in the Insect Antennal Lobe

All organisms inhabit a world full of sensory stimuli that determine their behavioral and physiological response to their environment. Olfaction is especially important in insects, which use their olfactory systems to respond to, and discriminate amongst, complex odor stimuli. These odors elicit behaviors that mediate processes such as reproduction and habitat selection^1-3. Additionally, chemical sensing by insects mediates behaviors that are highly significant for agriculture and human health, including pollination^4-6, herbivory of food crops⁷, and transmission of disease^8,9. Identification of olfactory signals and their role in insect behavior is thus important for understanding both ecological processes and human food resources and well-being.To date, the identification of volatiles that drive insect behavior has been difficult and often tedious. Current techniques include gas chromatography-coupled electroantennogram recording (GC-EAG), and gas chromatography-coupled single sensillum recordings (GC-SSR)^10-12. These techniques proved to be vital in the identification of bioactive compounds. We have developed a method that uses gas chromatography coupled to multi-channel electrophysiological recordings (termed ''GCMR'') from neurons in the antennal lobe (AL; the insect''s primary olfactory center)^13,14. This state-of-the-art technique allows us to probe how odor information is represented in the insect brain. Moreover, because neural responses to odors at this level of olfactory processing are highly sensitive owing to the degree of convergence of the antenna''s receptor neurons into AL neurons, AL recordings will allow the detection of active constituents of natural odors efficiently and with high sensitivity. Here we describe GCMR and give an example of its use.Several general steps are involved in the detection of bioactive volatiles and insect response. Volatiles first need to be collected from sources of interest (in this example we use flowers from the genus Mimulus (Phyrmaceae)) and characterized as needed using standard GC-MS techniques^14-16. Insects are prepared for study using minimal dissection, after which a recording electrode is inserted into the antennal lobe and multi-channel neural recording begins. Post-processing of the neural data then reveals which particular odorants cause significant neural responses by the insect nervous system.Although the example we present here is specific to pollination studies, GCMR can be expanded to a wide range of study organisms and volatile sources. For instance, this method can be used in the identification of odorants attracting or repelling vector insects and crop pests. Moreover, GCMR can also be used to identify attractants for beneficial insects, such as pollinators. The technique may be expanded to non-insect subjects as well.     

有瓣蝇类触角感受器形态与功能研究进展

有瓣蝇类隶属于昆虫纲双翅目,其物种多样性高,适应能力强,生态类型丰富,与人类关系密切,是开展昆虫适应演化研究的理想类群。触角是有瓣蝇类最重要的嗅觉感受器官,在其精准寻找食源,高效完成交配、产卵等生活史环节中都起着获取外界信息的关键作用。目前已有大量对于有瓣蝇类触角感受器的研究,但这些研究对触角感受器形态名词的使用存在诸多差异、混乱和歧义,使得不同研究间难以相互参考。本文统一了之前研究中有瓣蝇类触角上常见的各类感受结构的不同名词;并结合其它昆虫类群的相关研究,综述了各类感受器在形态和功能方面的研究进展;探讨了该领域中尚待解决的问题。     

Six new species of Cymatodera from Mexico and Central America and the retention of Cymatodera obliquefasciata as a valid name (Cleridae,Tillinae)

Six new Cymatodera speciesfrom the Mexican states of Jalisco and Chiapas, and the Central American countries of El Salvador, Honduras, Costa Rica and Panamá are described: Cymatodera rosalinae sp. n., Cymatodera capax sp. n., Cymatodera sinuosa sp. n., Cymatodera vittata sp. n., Cymatodera rubida sp. n. and Cymatodera limatula sp. n. Justification for retaining Cymatodera obliquefasciata within Cymatodera instead of transferring it to Bogcia is provided. Male genitalia and other characters of taxonomic value are illustrated.     

A comparative morphometric study of sensory capacity in geometrid moths

Diet breadth and the degree of capital breeding have been established as major determinants of species‐specific ecology of herbivorous insects. Both of these variables are related to resource foraging and therefore can be expected to have effects on sensory capacity. However, such effects have remained poorly studied, let alone in phylogenetically explicit multi‐species comparisons. We contribute to filling this gap in a study of 60 species of geometrid moths (Lepidoptera: Geometridae), using adult head measures (eye size, antennal length and shape, forehead width) as indices of sensory capacity. When controlled for body size, eyes of the more capital breeding species (i.e. those with low contribution of adult feeding to reproduction) were found to be smaller, and female antennae shorter, than in income breeders. Feathery (vs simple filiform) male antennae were more frequently present in the capital breeders and in larger species. Regarding diet breadth, generalist species were found to have relatively wider male foreheads than specialists. The results suggest that (a) breeding strategy rather than diet breadth predicts sensory capacity in geometrids, (b) capital breeding (vs income breeding) is related to low sensory capacity in females, and (c) in contrast, males of the capital breeding species have evolved towards elevated olfactory capacity.     

Antennal morphology of the endogean carabid genus typhlocharis (Coleoptera: Carabidae: Anillini): Description of sensilla and taxonomic implications

The antennal morphology and chaetotaxy were studied in 52 species of the endogean carabid genus Typhlocharis, using scanning electron microscopy and light microscopy. The antennae are composed of 11 antennomeres (scape, pedicel, and nine flagellomeres). We found considerable variation between species in the third antennomere, with short‐stem and long‐stem forms, and flagellomere morphology, distinguishing two morphs: rounded (subovoid, subspheric and subquadrate, morph 1) and reniform shapes (morph 2). Antennal sensilla are grouped in six types of sensilla trichodea, three types of sensilla basiconica, one type of sensilla coeloconica, and one type of sensilla campaniformia. The distribution of sensilla along the antennomeres is described. The “rings” of trichoid sensilla in the antennomere body are affected by its shape and there is interspecific variation in the pattern of sensilla coeloconica in antennomere 11°, a novelty for the genus. The types of sensilla found in Typhlocharis are compared to those described in other Carabidae and the potential functionality and taxonomic interest of those variable antennal features are discussed. A correlation between the flagellomere morphology and the presence/absence of a stridulatory organ is suggested. The study also allowed comparing the observation of antennal features by SEM and light microscopy. J. Morphol., 2013. © 2013 Wiley Periodicals, Inc.     

The divinyl-chlorophyll a/b-protein complexes of two strains of the oxyphototrophic marine prokaryote Prochlorococcus – characterization and response to changes in growth irradiance

Apoproteins of the antenna complexes of Prochlorococcus marinus clone SS120 (= CCMP 1375) and Prochlorococcus sp. clone MED4 (= CCMP 1378) cross-reacted with an antibody against the 30 kDa CP 5 complex of Prochlorothrix hollandica antenna. For the MED4 strain, which has a high divinyl-chlorophyll a to divinyl-chlorophyll b (DV-Chl a/b) ratio ranging from 11.4 to 15.0 (w/w), the major antenna proteins had an apparent molecular mass of 32.5 kDa. In contrast for the SS120 strain, which has a low DV-Chl a/b ratio ranging from 1.1 to 2.2, antenna apoproteins were observed in the range 34–38 kDa. For both strains, these apoproteins decreased at high growth irradiance but more markedly in the latter. Partially purified antenna fractions had a DV-Chl a/b ratio ca. 7-fold lower for SS120 than for MED4 at 30 mol photons m-2 s-1. For both strains, the 77 K fluorescence emission spectra of whole thylakoids displayed a major peak at 685 nm and a broad but very low shoulder above 700 nm. Energetic coupling of the antenna to both PS II and PSI reaction centers was demonstrated for SS120 by the strong contribution of DV-Chl b in both the 77 K excitation fluorescence spectra and the oxidized minus reduced absorption difference spectra of P700. The PS I to PS II ratio of Prochlorococcus SS120 was determined as being 0.7 ± 0.1 at low light.     

Interactions of pheromone with moth antennae: Adsorption,desorption and transport

Isolated antennae of the male moth Antheraea polyphemus adsorbed at least 32% of ³H-labelled pheromone molecules (E-6,Z-11 hexadecadienyl acetate) from an airstream passing the antenna. About 80% of the adsorbed molecules were caught by the long olfactory hairs (sensilla trichodea). The distal half of the hairs caught about twice as many molecules as the proximal half. About 40% of the molecules desorbed if the antennae were exposed to a clean airstream for 30 min. The adsorbed molecules were transported from the hairs towards the antennal branch. Transport due to diffusion would have a diffusion coefficient of 3 × 10^?7 cm²/s. Forty per cent of the total radioactivity per hair could be detected in receptor lymph extruded from the olfactory hairs, after an incubation time of 2 min. Dried antennae showed an increased desorption and an increased velocity of the transport along the hairs. One interpretation is that the molecules enter the receptor lymph of the intact antennae and diffuse more slowly than those on the cuticular surface. Fractional elution of fresh antennae revealed a diminishing elutability of pheromone from antennae in pentane (DEP-effect) and almost constant elutability in more polar solvents (chloroform-methanol toluene). The DEP-effect could be reversibly abolished by dehydration of the antennae. It could be shown that the DEP-effect occurs mainly on the antennal branch rather than on the hairs. Residual (uneluted) radioactivity builds up mainly on the branch.