Proctolin in the antennal circulatory system of lower Neoptera: a comparative pharmacological and immunohistochemical study

Neuropeptides are important with respect to almost all physiological processes and behavioural patterns in an organism. In the present study, muscle bioassays, immunohistochemistry and matrix‐assisted laser desorption ionization time‐of‐flight (MALDI‐TOF) mass spectrometry are used to investigate the distribution and efficacy of proctolin in the antennal heart of 36 species of lower Neoptera. In total, 20 species of Dictyoptera (cockroaches, termites, praying mantids), eight species of Saltatoria (crickets and grasshoppers) and eight species of Phasmatodea (stick insects) are investigated. The antennal heart of all tested Blattoidea, including the termite Mastotermes darwiniensis Froggatt, exhibit a strong proctolin‐like immunoreactivity, as well as a high sensitivity to proctolin, whereas members of the second clade of cockroaches (Blaberoidea) are largely insensitive to proctolin and show only a weak proctolin‐like immunoreactivity. The antennal heart of praying mantids (Mantodea) also contains only few proctolin‐like immunoreactive fibres but is highly sensitive to proctolin. Such a high sensitivity is found also in Phasmatodea, although the antennal heart of these insects does not have proctolin‐like immunoreactive fibres. These findings are supported by MALDI‐TOF mass spectrometry; no trace of proctolin is detected in antennal heart preparations of Phasmatodea. In Saltatoria, only weak (or no) effects of proctolin are observed and, in most subtaxa, no proctolin‐like immunoreactivity is visible in the antennal heart preparations. Only in Grylloidea is strong proctolin‐like immunostaining found in processes of the antennal heart. In these species, weak or moderate effects of proctolin are observed in the antennal heart bioassay. In general, the differences in distribution of proctolin and effects on the antennal heart within the basal Neoptera cannot be deduced from their phylogenetic position, although they show conformity within each (sub)taxon.     

Mechanisms underlying insect freeze tolerance

Freeze tolerance – the ability to survive internal ice formation – has evolved repeatedly in insects, facilitating survival in environments with low temperatures and/or high risk of freezing. Surviving internal ice formation poses several challenges because freezing can cause cellular dehydration and mechanical damage, and restricts the opportunity to metabolise and respond to environmental challenges. While freeze‐tolerant insects accumulate many potentially protective molecules, there is no apparent ‘magic bullet’ – a molecule or class of molecules that appears to be necessary or sufficient to support this cold‐tolerance strategy. In addition, the mechanisms underlying freeze tolerance have been minimally explored. Herein, we frame freeze tolerance as the ability to survive a process: freeze‐tolerant insects must withstand the challenges associated with cooling (low temperatures), freezing (internal ice formation), and thawing. To do so, we hypothesise that freeze‐tolerant insects control the quality and quantity of ice, prevent or repair damage to cells and macromolecules, manage biochemical processes while frozen/thawing, and restore physiological processes post‐thaw. Many of the molecules that can facilitate freeze tolerance are also accumulated by other cold‐ and desiccation‐tolerant insects. We suggest that, when freezing offered a physiological advantage, freeze tolerance evolved in insects that were already adapted to low temperatures or desiccation, or in insects that could withstand small amounts of internal ice formation. Although freeze tolerance is a complex cold‐tolerance strategy that has evolved multiple times, we suggest that a process‐focused approach (in combination with appropriate techniques and model organisms) will facilitate hypothesis‐driven research to understand better how insects survive internal ice formation.     

Reduction of oviposition time and enhanced larval feeding: two potential benefits of aggregative oviposition for the viburnum leaf beetle

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Prey preferences of aquatic insects: potential implications for the regulation of wetland mosquitoes

Wetlands are potential sites for mosquito breeding and are thus important in the context of public health. The use of chemical and microbial controls is constrained in wetlands in view of their potential impact on the diverse biota. Biological control using generalist aquatic insects can be effective, provided a preference for mosquito larvae is exhibited. The mosquito prey preferences of water bugs and larvae of odonate species were evaluated using chironomid larvae, fish fingerlings and tadpoles as alternative prey. Manly's selectivity (α_i) values with 95% confidence intervals (CIs) were estimated to judge prey preference patterns. Multivariate analysis of variance (manova) and standardized canonical coefficients were used to test the effects of density on prey selectivity. The α_i values indicated a significant preference (P < 0.05) in all of the insect predators tested for mosquito larvae over the alternative prey as a density‐dependent function. On a comparative scale, chironomid larvae had the highest impact as alternative prey. In a multiple‐prey experiment, predators showed a similar pattern of preference for mosquito larvae over alternative prey, reflecting a significant (P < 0.05) niche overlap. The results suggest that, in a laboratory setting, these insect predators can effectively reduce mosquito density in the presence of multiple alternative prey.     

Edible insects in China: Utilization and prospects

The use of edible insects has a long history in China, where they have been consumed for more than 2000 years. In general, the level of acceptance is high for the consumption of insects in China. Many studies on edible insects have been conducted in the last 20 years, and the scope of the research includes the culture of entomophagy and the identification, nutritional value, farming and breeding of edible insects, in addition to food production and safety. Currently, 324 species of insects from 11 orders are documented that are either edible or associated with entomophagy in China, which include the common edible species, some less commonly consumed species and some medicinal insects. However, only approximately 10 to 20 types of insects are regularly consumed. The nutritional values for 174 species are available in China, including edible, feed and medicinal species. Although the nutritional values vary among species, all the insects examined contain protein, fat, vitamins and minerals at levels that meet human nutritional requirements. Edible insects were, and continue to be, consumed by different ethnic groups in many parts of China. People directly consume insects or food products made from insects. The processing of products from insect protein powder, oil and chitin, and the development of healthcare foods has been studied in China. People also consume insects indirectly by eating livestock that were fed insects, which may be a more acceptable pathway to use insects in human diets. Although limited, the data on the food safety of insects indicate that insects are safe for food or feed. Incidences of allergic reactions after consuming silkworm pupae, cicadas and crickets have been reported in China. Insect farming is a unique breeding industry in rural China and is a source of income for local people. Insects are reared and bred for human food, medicine and animal feed using two approaches in China: the insects are either fully domesticated and reared completely in captivity or are partially raised in captivity, and the insect habitat is manipulated to increase production. Depending on the type of relationship the insect has with humans, plants and the environment, different farming strategies are used. The social and scientific communities must work together to promote the use of insects as food and feed.     

Screening Subterranean Clover (Trifolium spp.) Germplasm for Resistance to Meloidogyne species

This study was conducted to identify lines of subterranean clover (Trifolium spp.) with resistance to Meloidogyne arenaria (Neal, 1989) Chitwood, 1949, race 1; M. incognita (Kofoid and White, 1919) Chitwood, 1949, race 3; and M. javanica (Treub, 1885) Chitwood, 1949. A collection of 134 subterranean clover lines was evaluated and all had intermediate to high susceptibility. Root galling was negatively correlated with both seed and dry matter yields. Soil fumigation significantly reduced the nematode population in the field. Results indicate there is limited genetic resistance to root-knot nematodes among subterranean clover lines. Alternative sources of variation for this trait should be investigated.     

Revision of fossil Metretopodidae (Insecta: Ephemeroptera) in Baltic amber – Part 2: Description of a new species of Metretopus Eaton, 1901

In the second part of the revision of fossil Metretopodidae, a new species of the genus Metretopus Eaton, 1901 is described and illustrated based on a male imago. Metretopus dividussp. nov. is the second fossil species of the genus. Distinguishing characters for its separation from other fossil and recent representatives of Metretopus are discussed. http://www.zoobank.org/urn:lsid:zoobank.org:act:BCC5CB69-8014-4DA1-A0DA-DCF714969081     

The fine structure of the sperm bundles of the coccid,Aspidiotus perniciosus Cumst., and sperm movement

The mature sperm of A. perniciosus are organized into bundles, about 350 μm long by 9–10 μm wide. Each bundle contains 32 sperm enclosed by a common sheath. The sperm contains an elongated ‘central core’, representing nuclear material, surrounded by a spiral microtubular sheath and cytoplasm. The electron-dense nuclear material is localized in the more pointed half of the sperm. The spiral microtubular sheath is composed of 30— 100 microtubules (depending on the cross-sectional level), situated parallel to the longitudinal axis of the sperm. On the basis of this ultrastructural organization, the motility of the sperm and sperm bundle as a whole is discussed. The sperm of A. perniciosus provide strong evidence that the microtubules arranged asymmetrically represent the elements directly involved in sperm motility.     

铜污染对昆虫生长发育及繁殖影响的研究进展

铜(Cu)是生物体生长发育所必需的微量营养元素,参与或构成许多含铜酶及含铜生物活性蛋白质,但是过度摄入Cu会对生物体产生危害。Cu中毒由许多因素而定,如物种、遗传、年龄和食物等。在生态系统中昆虫种类多,数量大,分布广,往往会取食、转移和代谢环境中的Cu,从而对自身生长发育及繁殖造成影响。通常表现为发育历期延长,体重下降,体长变短,化蛹率、羽化率、产卵率、孵化率、存活率降低,种群数量减少等。本文以近几年Cu2+胁迫对昆虫生长发育及繁殖影响的研究进行综述。     

昆虫与寄主植物营养关系的DNA分子追踪

农田生态系统中昆虫与寄主植物的食物营养关系错综复杂,利用田间直接观察法、肠道内含物形态学分析、同位素标记等方法都难于全面解析,常造成营养关系的缺失。近年来,DNA分子追踪技术迅速发展,利用一段较短的DNA序列能有效鉴别植食性昆虫取食寄主植物的种类,为这一领域研究提供了新方法。本文全面介绍了3种DNA分子追踪技术——诊断PCR技术、克隆测序技术和下一代测序技术(next generation sequencing,NGS)。其中诊断PCR技术包括单一PCR技术和多重PCR技术,适用于目标昆虫与已知寄主植物之间的营养关系分析;克隆测序技术能够在寄主植物种类未知的前提下,解析目标昆虫完整的寄主植物种类信息;下一代测序技术实现了短时间内对混合样品的测序,加之昆虫与植物DNA条形码序列数据库大量扩增,有效地提高寄主植物的鉴别能力。诊断PCR技术和克隆测序技术已在追踪地下害虫的取食行为、植食性昆虫取食范围及其在寄主植物间的转移与选择习性等方面被广泛应用,且进展明显。综合考虑各种技术的优缺点,本文提出将DNA分子追踪技术与同位素标记等其他方法相结合的研究策略,以便系统解析农田生态系统中昆虫与寄主植物之间的营养关系。