Chemical defense against predation in an insect egg

The larva of the green lacewing (Ceraeochrysa cubana) (Neuroptera, Chrysopidae) is a natural predator of eggs of Utetheisa ornatrix (Lepidoptera, Arctiidae), a moth that sequesters pyrrolizidine alkaloids from its larval foodplant (Fabaceae, Crotalaria spp.). Utetheisa eggs are ordinarily endowed with the alkaloid. Alkaloid-free Utetheisa eggs, produced experimentally, are pierced by the larva with its sharp tubular jaws and sucked out. Alkaloid-laden eggs, in contrast, are rejected. When attacking an Utetheisa egg cluster (numbering on average 20 eggs), the larva subjects it to an inspection process. It prods and/or pierces a small number of eggs (on average two to three) and, if these contain alkaloid, it passes “negative judgement” on the remainder of the cluster and turns away. Such generalization on the part of the larva makes sense, because the eggs within clusters differ little in alkaloid content. There is, however, considerable between-cluster variation in egg alkaloid content, so clusters in nature can be expected to range widely in palatability. To check each cluster for acceptability must therefore be adaptive for the larva, just as it must be adaptive for Utetheisa to lay its eggs in large clusters and to apportion alkaloid evenly among eggs of a cluster.

Feeding specialization and host-derived chemical defense in Chrysomeline leaf beetles did not lead to an evolutionary dead end

Combination of molecular phylogenetic analyses of Chrysomelina beetles and chemical data of their defensive secretions indicate that two lineages independently developed, from an ancestral autogenous metabolism, an energetically efficient strategy that made the insect tightly dependent on the chemistry of the host plant. However, a lineage (the interrupta group) escaped this subordination through the development of a yet more derived mixed metabolism potentially compatible with a large number of new host-plant associations. Hence, these analyses on leaf beetles document a mechanism that can explain why high levels of specialization do not necessarily lead to “evolutionary dead ends.”

Army equipment data sheets : chemical defense equipment.

Includes index.

Chemical defense : protecting our soldiers : 1990's, 1980's, 1970's /

Shipping list no.: 85-1041-P.

A comparative analysis of the chemical nature of defensive secretions of Gonyleptidae (Arachnida : Opiliones : Laniatores)

The arachnids of the order Opiliones (harvestmen) produce substances used in defense. In the present paper, we analyzed 22 species of Gonyleptidae to explore the use of defensive substances in taxonomy and evolutionary biology. Thirty-seven different compounds were detected, 18 of which were preliminarily identified. These compounds were mapped onto a phylogenetic tree showing the relationships within the Gonyleptidae. Data from Cosmetidae were used as an outgroup. Five ketones and six alkyl phenols were reported for the first time in harvestmen. (c) 2005 Elsevier Ltd. All rights reserved.

The relationship between alkaloid-based chemical defenses and diet in dendrobatid poison frogs

Chemical defenses are common among organisms and represent some of the most complex adaptations for avoiding predation, yet our understanding of the ecological nature of these systems remains incomplete. Poison frogs are a group of chemically defended organisms that are dependent entirely on diet for chemical defense. In this study, I identified the dietary arthropods responsible for chemical defense in poison frogs, described spatial and temporal patterns in alkaloid composition of poison frogs, and established links between patterns of variation in alkaloid defense and arthropod diet in poison frogs. Identifying dietary sources and studying patterns of variation in alkaloid composition is fundamental to understanding the ecology and evolution of chemical defense in poison frogs. ^ The dendrobatid poison frog Oophaga pumilio shares many alkaloids in common with other poison frogs and is known to vary in alkaloid composition throughout its geographic range. I designed my dissertation to take advantage of these characteristics and use O. pumilio as a model species for the study of chemical defense in poison frogs. Here, I identified siphonotid millipedes as a source for spiropyrrolizidine alkaloids, formicine ants as a source for pumiliotoxin alkaloids, and oribatid mites as dietary sources for the majority of alkaloids found in poison frogs. I found that alkaloid composition varied spatially and temporally, on both small and large scales, within and among populations of O. pumilio. Alkaloid variation between populations was related to geographic distance, and closer populations tended to have alkaloid compositions more similar to each other than to distant populations. ^ The findings of my study suggest that oribatid mites are the most important dietary source of alkaloids in poison frogs. However, overall alkaloid defense in poison frogs is based on a combination of dietary arthropods, including mites, ants, millipedes, and beetles. Variation in chemical defenses of poison frogs is due to (1) spatial and temporal differences in the presence of alkaloids in certain arthropods and (2) differences in the availability of certain alkaloid-containing arthropods, which are likely the result of differences as well as successional changes in forest structure among locations and through time. ^

Avaliação da defesa química e da influência dos corais invasores Tubastraea coccinea e Tubastraea tagusensis na estruturação das comunidades bentônicas da Baía da Ilha Grande RJ

A introdução de espécies invasoras marinhas tem causado danos econômicos e ecológicos consideráveis em todo o mundo. Algumas destas espécies incluindo corais escleractíneos possuem adaptações, tais como metabólitos secundários utilizados para evitar a predação e competição por espaço por outros organismos. Este arsenal químico e as interações entre espécies invasoras e nativas podem causar alterações na distribuição das espécies e na estrutura das comunidades de costões rochosos tropicais. Os objetivos deste estudo foram (1) caracterizar os metabólitos secundários produzidos pelos corais invasores Tubastraea tagusensis e T. coccinea na Baía da Ilha Grande, Brasil, (2) detectar os compostos químicos liberados pelos tecidos de Tubastraea tagusensis in situ utilizando um aparelho submersível; (3) testar no campo os extratos metanólicos produzidos por ambas as espécies de Tubastraea contra a predação por peixes generalistas e assentamento de outros organismos, (4) testar no campo se os compostos químicos produzidos por ambos os corais invasores variaram na concentração ou tipo quando os corais foram colocados próximos de competidores nativos e (5) determinar como as comunidades de costões rochosos da Baía da Ilha Grande foram afetadas pela expansão de Tubastraea coccinea e T. tagusensis em 8 locais estudados durante 2 anos. As principais classes de substâncias encontradas nos extratos metanólicos de Tubastraea foram identificados como esteróis, ácidos graxos, hidrocarbonetos, alcalóides, ésteres e alcoóis, entretanto, o aparelho submersível identificou somente hidrocarbonetos liberados por Tubastraea na água do mar. O extrato metanólico de T. tagusensis reduziu a predação por peixes generalistas e já os extratos de ambas as espécies mostraram efeitos espécie-específicos sobre organismos incrustantes no campo. No experimento de interação competitiva foi detectada a presença de necrose nos tecidos do coral endêmico Mussismilia hispida e isso provocou variação nas concentrações de esteróis, alcalóides e ácidos graxos nos tecidos de Tubastraea. Em contraste, a esponja Desmapsamma anchorata cresceu sobre os tecidos das colônias de ambos os corais invasores. A presença de Tubastraea nas comunidades bentônicas causou uma dissimilaridade média de 4,8% nas comunidades invadidas. Uma forte relação positiva foi encontrada entre a cobertura de Tubastraea e a mudança na estrutura da comunidade da Baía da Ilha Grande. Portanto, os efeitos negativos de ambos os corais invasores são suficientes para acarretar mudanças na estrutura das comunidades bentônicas tropicais.

Vivendo com o inimigo: competição entre os corais invasores Tubastraea spp. e a esponja Desmapsamma anchorata na Baía de Ilha Grande, RJ

Espécies invasoras têm transformado muitos ecossistemas através de mudanças na estrutura das comunidades, cadeia trófica, ciclagem de nutrientes e sedimentação. A competição interespecífica ocorre frequentemente entre espécies nativas e introduzidas, e constitui um processo determinante na eficiência da invasão. Essa competição pode acarretar em alterações no papel das espécies dentro da comunidade e alterar os processos ecossistêmicos. Os corais Tubastraea coccinea e T. tagusensis invadiram o Brasil na década de 80, e são favorecidos pela carência de predadores na biota local, sendo a esponja Desmapsamma anchorata o único organismo identificado como inibidor do crescimento e desenvolvimento desses corais. O presente estudo tem como objetivo: 1) Quantificar e classificar em cinco categorias de interação: sobrecrescimento, contorno, contato periférico, encontro com até cinco cm de distância e encontro de cinco ate dez cm de distância entre as esponjas e Tubastraea spp. na Baía de Ilha Grande, temporalmente; 2) Descrever os mecanismos utilizados na competição entre a esponja D. anchorata e os corais Tubastraea (físicos ou químicos?); 3) Descrever a dinâmica do crescimento da esponja D. anchorata com relação a fatores abióticos. Foram encontradas 37 espécies de esponjas interagindo com Tubastraea spp, sendo que apenas 12 dessas espécies interagiram mais de 10 % no total de interações. O contato periférico e a interação de até 5 cm de distância foram os tipos de interação mais encontrados. D. anchorata foi a esponja que mais teve o contato de sobreposição. Não foi observado efeitos significativos dos extratos de Tubastraea spp. sobre D. anchorata e nem dos extratos de D. anchorata sobre o metabolismo dos corais. A sobreposição foi a principal ferramenta utilizada na defesa contra o competidor, enquanto que os corais Tubastraea spp. utilizaram defesa física e provavelmente química. D. anchorata não apresentou relação entre seu crescimento e os fatores abióticos medidos e mostrou crescimento em taxas diferentes durante os meses analisados, com um pico no mês de setembro diminuindo até a sua morte, no mês de dezembro. No caso da competição entre os invasores Tubastraea spp. e a esponja D. anchorata, a hipótese de controle biótico não pode ser levada em consideração, já que os corais Tubastraea spp. têm demonstrado capacidade de se expandir e colonizar novos locais muito rapidamente. Porém, como observado no presente estudo, e em outros trabalhos, pontualmente a esponja vence na competição com os corais invasores

Rational conversion of substrate and product specificity in a Salvia monoterpene synthase: structural insights into the evolution of terpene synthase function

Terpene synthases are responsible for the biosynthesis of the complex chemical defense arsenal of plants and microorganisms. How do these enzymes, which all appear to share a common terpene synthase fold, specify the many different products made almost entirely from one of only three substrates? Elucidation of the structure of 1,8-cineole synthase from Salvia fruticosa (Sf-CinS1) combined with analysis of functional and phylogenetic relationships of enzymes within Salvia species identified active-site residues responsible for product specificity. Thus, Sf-CinS1 was successfully converted to a sabinene synthase with a minimum number of rationally predicted substitutions, while identification of the Asn side chain essential for water activation introduced 1,8-cineole and alpha-terpineol activity to Salvia pomifera sabinene synthase. A major contribution to product specificity in Sf-CinS1 appears to come from a local deformation within one of the helices forming the active site. This deformation is observed in all other mono- or sesquiterpene structures available, pointing to a conserved mechanism. Moreover, a single amino acid substitution enlarged the active-site cavity enough to accommodate the larger farnesyl pyrophosphate substrate and led to the efficient synthesis of sesquiterpenes, while alternate single substitutions of this critical amino acid yielded five additional terpene synthases.

Chemistry and biology of maculalactone A from the marine cyanobacterium Kyrtuthrix maculans

Maculalactone A is the most abundant secondary metabolite in Kyrtuthrix maculans, a marine cyanobacterium found in the mid-high shore of moderately exposed to sheltered rocky shores in Hong Kong and South East Asia. This species appears to survive as pure colonies forming distinct black zones on the rock. Maculalactone A may provide K. maculans with a chemical defense against several marine organisms, including the common grazer, Chlorostoma argyrostoma and settlement by larvae of the barnacles, Tetraclita japonica, Balanus amphitrite and Ibla cumingii. The natural concentration of maculalactone A varied with season and also with tidal height on the shore and although a strong positive linear correlation was observed between maculalactone A concentration and herbivore grazing pressure, manipulative experiments demonstrated that grazing pressure was not directly responsible for inducing the biosynthesis of this metabolite. The potential of maculalactone A as a natural marine anti-fouling agent (i.e. as an alternative to environmentally-damaging copper- and tin-based anti-fouling paints) was investigated after achieving a gram-scale synthesis of this compound. Preliminary field trials with anti-fouling paints which contained synthetic maculalactone A as the active principle have confirmed that this compound seems to have a specific activity against molluscan settlers.

A diversidade de lagartos na Caatinga é mediada pelos térmitas?

Intending to explain the extraordinary lizard coexistence levels found in Australian deserts, Morton & James (1988) figured out a hypothesis which defends that the termite diversity would bring about lizard radiation. This study aims to verify the validation of that hypothesis in Caatinga lizard assemblages. This study also objectives verifying if the termite defense mechanisms influence their consuming levels by lizards and if this pattern differs between different lizard lineages. Termites were collected using a standardized sampling protocol of termites. Besides using haphazard sampling, we collect lizards with 108 pitfall traps in each area. Intending to check the linkage between the termite and lizard assemblages, the lizard stomach contents were analyzed and then a canonical correspondence analysis was performed. The presence of nonrandom patterns of diet overlap among the lizard species was also examined. Aiming to check if the defense mechanisms of termite influence their consuming pattern by lizards it was performed a laboratory experiment where termite with different defense mechanisms were offered to lizards of two different lineages. We verified that lizard assemblages do not consume termites according to termite abundance in ecosystems. Furthermore, mean niche overlap lizard species did not differ significantly from that expected by chance. We found that termite chemical defense mechanism does influence the termite s pattern consuming by lizards. These results do not corroborate premises which support Morton & James hypothesis (1988) and point out that lizard do not chose termites based on their abundance, but, trying to avoid consuming termites which exhibit chemical defense mechanisms. This defense mechanism, however, may not be the only explanation to patterns of termite s consuming by lizards.

Ultramorphology of digestive tract of Anticarsia gemmatalis (Hubner, 1818) (Lepidoptera : Noctuidae) at final larval development

The digestive tract of insects is an important natural, physical, and chemical defense barrier against pathogen invasion. Certain. lepidopteran caterpillars are serious pests of agricultural crops and their biology has received much attention, but little is known about the larval noctuid gut. The morphological analysis of the digestive tract in Anticarsia gemmatalis under scanning electron microscopy (SEM) is a good model for studies about its defense mechanism. The material was fixed (2,5% glutaraldehyde solution; 0.1 M-phosphate buffer, pH 7.3), post-fixed (1% osmium tetroxide in the same buffer), dried at critical point, gold coated and analyzed in a SEM 515-Philips. A. gemmatalis digestive tract consists of a straight duct of varying length and diameter, subdivided in three main regions: the foregut formed by the oral cavity, pharynx, esophagus, and crop; the midgut that is the largest portion of the digestive tract without noticeable morphological differentiation along its length; and the hindgut that is morphologically differentiated in pylorus, ileum, colon, and rectum. Although the general morphology of the A. gemmatalis digestive tract is quite similar to the other Lepidoptera species, the anatomical array of the crop muscular layers is quite different comparing with the description for other larval insect.