Biochemical, Molecular and Functional Analysis of Volatile Terpene Formation in Arabidopsis Roots

Huh, Jung-Hyun

25 August 2011

Plants produce secondary (or specialized) metabolites to respond to a variety of environmental changes and threats. Especially, volatile compounds released by plants facilitate short and long distance interaction with both beneficial and harmful organisms. Comparatively little is known about the organization and role of specialized metabolism in root tissues. In this study, we have investigated the root-specific formation and function of volatile terpenes in the model plant Arabidopsis. As one objective, we have characterized the two root-specific terpene synthases, TPS22 and TPS25. Both enzymes catalyze the formation of several volatile sesquiterpenes with (E)-β-farnesene as the major product. TPS22 and TPS25 are expressed in the root in distinct different cell type-specific patterns and both genes are induced by jasmonic acid. Unexpectedly, both TPS proteins are localized to mitochondria, demonstrating a subcellular localization of terpene specialized metabolism in compartments other than the cytosol and plastids. (E)-β-Farnesene is produced at low concentrations suggesting posttranslational modifications of the TPS proteins and/or limited substrate availability in mitochondria. We hypothesize that the mitochondrial localization of TPS22 and TPS25 reflects evolutionary plasticity in subcellular compartmentation of TPS proteins with emerging or declining activity. Since (E)-β-farnesene inhibits Arabidopsis root growth in vitro, mitochondrial targeting of both proteins may fine tune (E)-β-farnesene concentrations to prevent possible autotoxic or inhibitory effects of this terpene in vivo. We further investigated the role of volatile terpenes in Arabidopsis roots in interaction with the soil-borne oomycete, Pythium irregulare. Infection of roots with P. irregulare causes emission of the C11-homoterpene (or better called C4-norterpene) 4,8-dimethylnona-1,3,7-triene (DMNT), which is a common volatile induced by biotic stress in aerial parts of plants but was not previously known to be produced in plant roots. We demonstrate that DMNT is synthesized by a novel, root-specific pathway via oxidative degradation of the C30-triterpene, arabidiol. DMNT exhibits inhibitory effects on P. irregulare mycelium growth and oospore germination in vitro. Moreover, arabidiol and DMNT biosynthetic mutants were found to be more susceptible to P. irregulare infection and showed higher rates of Pythium colonization in comparison to wild type plants. Together, our studies demonstrate differences and plasticity in the metabolic organization and function of terpenes in roots in comparison to aboveground plant tissues. / Ph. D.

secondary (specialized) metabolism

plant volatiles

terpene synthase

soil-borne pathogen

oomycete

Pythium

sesquiterpene

root chemical defense

Chemically-mediated interactions in salt marshes: mechanisms that plant communities use to deter closely associated herbivores and pathogens

Sieg, Robert Drew

25 March 2013

Herbivores and pathogens pose a consistent threat to plant productivity. In response, plants invest in structural and/or chemical defenses that minimize damage caused by these biotic stressors. In salt marshes along the Atlantic coast of the United States, a facultative mutualism between snails (Littoraria irrorata) and multiple species of fungi exert intense top-down control of the foundation grass species Spartina alterniflora. Since exposure to herbivores and pathogens are tightly coupled in this system, I investigated whether S. alterniflora utilizes chemical and/or structural defenses to deter both snails and fungi, and examined how plant defenses varied among S. alterniflora individuals and populations. I also assessed how other marsh plants prevent snails from establishing farms, and considered whether interspecific variation in plant chemical defenses influences marsh community structure. Initial experiments revealed that S. alterniflora chemical defenses inhibited L. irrorata and two fungi that snails commonly farm. A caging experiment determined that production of chemical defenses could not be induced in the presence of snails and fungi, nor relaxed in their absence. Through separations chemistry guided by ecological assays, I isolated two distinct classes of chemical defenses from short form S. alterniflora, one of which inhibited fungal growth and the other decreased plant palatability. In a community context, the chemical defenses produced by S. alterniflora were relatively weak compared to those of four other salt marsh plant species, which produced compounds that completely inhibited L. irrorata grazing and strongly hindered fungal growth in lab assays. Nutritional and structural differences among marsh plants did not influence feeding preferences, suggesting that plant secondary chemistry was the primary driver for food selection by snails. It appears that S. alterniflora produces weak chemical defenses that slow down or limit fungal growth and snail herbivory, and may compensate for tissue losses by producing new growth. In contrast, less abundant marsh plants express chemical defenses that completely inhibit fungal farming and deter snail grazing, but doing so may come at a cost to growth or competitive ability. As marsh dieback continues with rising herbivore densities and compounding abiotic stressors, the ecosystem services that salt marshes provide may be lost. Therefore, understanding how and under what conditions salt marsh plants resist losses to herbivores and pathogens will help predict which marsh communities are most likely to be threatened in the future. Initial experiments revealed that S. alterniflora chemical defenses inhibited L. irrorata and two fungi that snails commonly farm. A caging experiment determined that production of chemical defenses could not be induced in the presence of snails and fungi, nor relaxed in their absence. Through separations chemistry guided by ecological assays, I isolated two distinct classes of chemical defenses from short form S. alterniflora, one of which inhibited fungal growth and the other decreased plant palatability. In a community context, the chemical defenses produced by S. alterniflora were relatively weak compared to those of four other salt marsh plant species, which produced compounds that completely inhibited L. irrorata grazing and strongly hindered fungal growth in lab assays. Nutritional and structural differences among marsh plants did not influence feeding preferences, suggesting that differences in plant chemistry were the primary driver for food selection by snails. It appears that S. alterniflora produces weak chemical defenses that slow down or limit fungal growth and snail herbivory, and may compensate for tissue losses by producing new growth. In contrast, less abundant marsh plants express chemical defenses that completely inhibit fungal farming and deter snail grazing, but doing so may come at a cost to growth or competitive ability against S. alterniflora. As marsh dieback continues with rising herbivore densities and compounding abiotic stressors, the ecosystem services that salt marshes provide may be lost. Therefore, understanding how and under what conditions salt marsh plants resist losses to herbivores and pathogens will help predict which marsh communities are most likely to be threatened in the future.

Pathogen

Chemical defense

Herbivore

Spartina alterniflora

Salt marsh

Chemical ecology

Marine chemical ecology

Salt marsh ecology

Salt marshes

Functional identification and initial characterization of a fish co-receptor involved in aversive signaling

Cohen, Staci Padove

18 May 2009

Chemoreception plays an important role in predator-prey interactions and feeding dynamics. While the chemoreception of attractant or pleasant tasting compounds has been well studied, aversive chemoreceptive signaling has been difficult to investigate behaviorally in an ecological context because these interactions are species- and context- specific and deterrent compounds vary among prey. Using the coral reef system, this thesis explores on a molecular level the deterrent mechanism underlying detection by fish predators of an aversive compound, in order to gain a greater understanding of predator-prey interactions in this community. Like other organisms that are sessile or slow-moving, marine sponges have special mechanisms for defense from predation, commonly containing aversive-tasting compounds that defend these organisms from predation. To this end, we sought to identify and characterize a fish chemoreceptor that detects one or more of these compounds. We isolated a single cDNA clone encoding RAMP-like triterpene glycoside receptor (RL-TGR), a novel co-receptor involved in the signaling of triterpene glycosides. This co-receptor appears to be structurally and functionally related to receptor activity-modifying proteins (RAMPs), a family of co-receptors that physically associate with and modify the activity of G protein-coupled receptors (GPCRs). Expression in Xenopus oocytes showed that it responds to triterpene glycosides in a receptor-mediated manner and requires co-expression of a GPCR to enable signaling in oocytes; both of these receptors may be components of a larger signaling complex. A 40 bp portion of the gene is conserved across multiple fish species, but is not found in any other organism with a sequenced genome, suggesting that the expression of this receptor is limited to fish species. RL-TGR is the first identified gene encoding a co-receptor that responds to a chemical defense. This finding may lead the way for the identification of many other receptors that mediate chemical defense signaling in both marine and terrestrial environments, as this protein has the potential to represent the first of an entire family of co-receptors that respond to aversive compounds.

Chemical defense

Chemical ecology

Chemoreception

Taste receptor

Fish

Marine sponges

Chemical senses

Chemoreceptors

Taste buds

Predation (Biology)

Triterpenoid saponins

Estudo de semioquímicos de opiliões (Laniatores: Arachnida) da família Gonyleptidae : caracterização, síntese e biossíntese / Study of semiochemicals from harvestman (Laniatores: Arachnida) belonging to the family Gonyleptidae : characterization, synthesis and biosynthesis

Rocha, Daniele Fernanda de Oliveira, 1982-

23 August 2018

Orientador: Anita Jocelyne Marsaioli / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-23T22:59:17Z (GMT). No. of bitstreams: 1 Rocha_DanieleFernandadeOliveira_D.pdf: 6414836 bytes, checksum: 154b421c3fabef860e5439b2a47d4972 (MD5) Previous issue date: 2013 / Resumo: Opiliões são aracnídeos encontrados em todos os continentes, com mais de 6000 espécies descritas, e secretam uma mistura de compostos voláteis que atuam principalmente como defesa contra predadores naturais. A família Gonyleptidae, pertence à subordem Laniatores, é a mais diversa química e morfologicamente e está presente em todo o território brasileiro. Assim, o estudo da identidade e da origem biossintética dos compostos presentes no exudato de espécimes desta família fornece informações filogenéticas, além de ser uma fonte de novos produtos naturais. Neste trabalho foram caracterizados os exudatos de cinco espécies de opiliões de diferentes subfamílias. As espécies Cobania picea, Roeweria virescens e Serracutisoma proximum secretam uma mistura benzoquinonas. Por outro lado, Iporangaia pustulosa e Neosadocus maximus produzem 1-hepten-3-ona e 1-(6-butil-3,4-diidro-2H-piran-2-il)-pentan-1-ona. Este último foi descrito pela primeira vez na literatura, revelando uma nova classe de compostos com esqueleto piranil em opiliões, originados da reação de hetero-Diels-Alder in vivo de duas moléculas de vinil cetona. Também foi determinada a configuração absoluta da (R)-4-metil-1-hexen-3-ona produzida por Acanthogonyleptes pulcher e Gonyleptes saprophilus. Outras 4-metil-3-cetonas de insetos possuem configuração (S). Adicionalmente foi realizado o primeiro estudo biossintético com opiliões através da incorporação de precursores marcados com C e espectroscopia de RMN de C. Foram estudados I. pustulosa, que produz vinil cetona, e Magnispina neptunus, que produz benzoquinona, revelando que ambas as classes químicas são formadas através de unidades acetato e propionato pela via policetídica / Abstract: Harvestmen are arachnids widespread in all continents, with more than 6,000 described species. They secrete a mixture of volatiles compounds with the main function of defense against natural predators. The family Gonyleptidae belongs to the suborder Laniatores, is the most diverse in chemistry and morphology and is predominant in Brazil. Therefore, studying the identity and biosynthetic origin of this family exudate components gives phylogenetic information and is a source of new natural products. In this work five species exudate from different subfamilies were characterized. The species Cobania picea, Roeweria virescens and Serracutisoma proximum secrete a mixture of benzoquinones, while Iporangaia pustulosa and Neosadocus maximus produce 1-hepten-3-one and 1-(6-butil-3,4-dihydro-2H-piran-2-yl)-pentan-1-one. The latter was described for the first time, and belongs to a new class of harvestman metabolites with piranyl moiety in harvestmen, which were rationalized as the hetero-Diels-Alder adduct of two vinyl ketone molecules. Additionally the absolute configuration of (R)-4-methyl-1-hexen-3-one from Acanthogonyleptes pulcher and Gonyleptes saprophilus was determined. Analogous 4-methyl-3-cetones from insects have S configuration. It was also performed the first biosynthetic investigation with harvestmen by C labeled precursors incorporation and C NMR. The studied species were /.pustulosa and Magnispina neptunus, which produce vinyl ketones and benzoquinones, respectively. The results revealed that these chemical classes are biosynthesized with acetate and propionate units via polyketide pathway / Doutorado / Quimica Organica / Doutora em Ciências

Produtos naturais

Defesa química

Diels-Alder, Reação de

Biossíntese

Ressonância magnética nuclear

Natural products

Chemical defense

Diels-Alder, Reaction

Biosynthesis

NMR

Interclonal Variation of Primary and Secondary Chemistry in Western Quaking Aspen and its Influence on Ungulate Selection

Winter, Damon A.

01 December 2010

Quaking aspen (Populus tremuloides) clones within close proximity to one another can exhibit drastically different levels of browsing by ungulates. The objectives of this study were to (1) determine interclonal differences in plant chemistry between adjacent clones exhibiting different degrees of herbivory which may influence the browsing behavior and patterns of ungulates, and (2) determine if correlation exists in the levels of salicortin and tremulacin between current year's suckers and current year's growth on older trees. This second objective was meant to indicate a protocol for land managers for identifying clones meriting increased protection from herbivory after treatment and wildfire. In July of 2005, 6 pairs of clones were identified on the Dixie National Forest, Utah, and on Cedar Mountain, east of Cedar City, Utah. Pairs consisted of 2 clones within the same pasture and/or grazing allotment and within a minimal distance from one another; one clone displaying moderate to high levels of ungulate utilization of aspen suckers, and one exhibiting minimal to no ungulate utilization of aspen suckers. Soil samples were taken at each clone and leaf tissues were sampled to determine genet. Aspen suckers were sampled for nutrient content, combined phenolic glycoside concentration (salicortin and tremulacin), condensed tannins, and the presence of extra floral nectaries (EFNs), at intervals throughout the growing season (August 3-6, August 31-September 2, and October 12-14). Current year's growth from representative mature trees was sampled for phenolic glycoside concentration at these times as well. All tests demonstrated high levels of insignificance for both leaves and stems.Sucker nitrogen values may have been elevated during portions of the sampling year in clones displaying moderate to high levels of ungulate utilization, possibility indicating an ungulate preference for nitrogen, but due to missing values, this is far from conclusive. P-values for forest floor factors were also highly non-significant with the exception of forest floor C (0.04) in the regenerating clones. Two post-project hypotheses are postulated in an attempt to explain the differences of forest floor carbon in terms of factors that may be influencing ungulate herbivory.

chemical defense

extrafloral nectaries

herbivory

phenolic glycoside

quaking aspen

ungulate

range management

Natural Resources Management and Policy

Plant Sciences

The spittlebug Mahanarva fimbriolata (Stål) produces foam as a thermoregulatory and defensive strategy / A cigarrinha Mahanarva fimbriolata (Stål) produz espuma como estratégia termorregulatória e defensiva

Tonelli, Mateus

16 April 2019

Insects of the family Cercopidae are easily identified by the spit-like foam that they produce to surround themselves during the nymphal stage. Known as spittlebugs, these insects can be observed developing in a wide range of host plants. Among the functions attributed to the foam, there are the protection of nymphs against high temperatures, desiccation and natural enemies. However, experimental evidence to confirm these hypotheses are sparse. Mahanarva fimbriolata is an economically important spittlebug in Brazilian sugarcane crops, especially after the harvest with burning had been prohibited. The nymphs of M. fimbriolata develop on the soil surface or below ground where they suck the xylem content of exposed sugarcane roots, blocking the water and nutrients transport, eventually causing physiological disorder. In this thesis, it was evaluated the importance of foam for the thermoregulation of M. fimbriolata nymphs, its bacterial microbiome and the protective action against predators. The thesis was divided into four chapters. The Chapter 1 presented an introduction to the bioecological aspects of M. fimbriolata and the possible role of foam produced by the nymphs, which was explored in details along the other chapters. The Chapter 2 examined the importance of foam and its chemical compounds in the thermoregulation of nymphs. The Chapter 3 explored the diversity and composition of bacterial community present in the foam, in the gut of nymphs, and in the soil close to the foam. The Chapter 4 investigated whether the foam acts in protecting the nymphs against the predatory ants Solenopsis invicta, and its topical irritancy to the cockroaches Periplaneta americana. It was demonstrated that the foam produced by M. fimbriolata: (i) serves as an important thermal microhabitat, maintaining the temperature close to the ideal for the nymphs development; (ii) harbor a diversity of bacteria previously reported as protective symbionts of insects, which are probably originated from the nymphs\'s gut; and (iii) is a repellent to predators and topical irritant to another arthropod (roaches). Taken together, the foam produced by M. fimbriolata is a thermoregulatory and defensive strategy to the nymphs. In addition, this thesis serves as a background for future research that aims to investigate the importance of foam for the growth and development of spittlebugs. / Os insetos da família Cercopidae são facilmente reconhecidos pela espuma que produzem durante o desenvolvimento ninfal para recobrir o próprio corpo. Essas ninfas, conhecidas como cigarrinhas, podem ser observadas em uma ampla gama de plantas hospedeiras. Dentre as funções atribuídas à espuma estão a proteção contra elevadas temperaturas, dessecação e inimigos naturais. Contudo, evidências experimentais para confirmar estas hipóteses são escassas. Mahanarva fimbriolata é uma cigarrinha de importância econômica em áreas de produção de cana-de-açúcar no Brasil, especialmente após a proibição da colheita da cana com queima prévia. As ninfas de M. fimbriolata se desenvolvem nas raízes de cana-de-açúcar expostas na superfície ou abaixo do solo, onde sugam a seiva do xilema, bloqueando o transporte de água e nutrientes e causando desordens fisiológicas. Nesta tese foi avaliada a importância da espuma para a termorregulação de ninfas de M. fimbriolata, seu microbioma bacteriano e sua ação protetora contra predadores. A tese foi dividida em quatro capítulos. O Capítulo 1 apresenta uma introdução sobre os aspectos bioecológicos de M. fimbriolata e o possível papel da espuma produzida pelas ninfas, o qual foi explorado em detalhes ao longo dos demais capítulos. O Capítulo 2 examinou a importância da espuma e de seus compostos químicos na termorregulação das ninfas. O Capítulo 3 explorou a diversidade e composição da comunidade bacteriana presente na espuma, no intestino das ninfas, e no solo próximo à espuma. O Capítulo 4 investigou se a espuma atua na sua proteção das ninfas contra formigas predadoras Solenopsis invicta, e sua irritação tópica a baratas Periplaneta americana. A espuma produzida por M. fimbriolata demonstrou: (i) servir como um importante microhabit térmico, mantendo a temperatura próxima da ideal para o desenvolvimento das ninfas; (ii) abrigar uma diversidade de bactérias previamente reportadas como simbiontes protetivos de insetos e que, provavelmente, são provenientes do intestino das ninfas; e (iii) ser repelente a formigas predadoras e irritante a outro artrópode (baratas). Tomados em conjunto, a espuma produzida por M. fimbriolata serve como uma estratégia termorregulatória e defensiva para as ninfas. Ademais, esta tese serve como base para futuras pesquisas que visam investigar a importância da espuma para o crescimento e desenvolvimento das cigarrinhas.

Chemical defense

Chemical ecology

Cigarrinha-das-raízes

Defesa química

Ecologia química

Irritação tópica

Microbioma

Microbiome

Predação

Predation

Spittlebug

Termorregulação

Thermoregulation

Topical irritancy

Prospecção de moléculas com potencial inseticida derivadas de genótipos de mandioca (Manihot esculenta Crantz) /

Barilli, Diandro Ricardo

January 2019

Orientador: Guilherme Duarte Rossi / Resumo: As plantas apresentam diversos metabólitos secundários em seus mecanismos de defesa que podem ser produzidos de forma constitutiva ou induzida. Esses metabólitos apresentam propriedades antinutritivas, repelentes ou tóxicas a insetos herbívoros. Plantas de mandioca são conhecidas por sua rusticidade e produção de compostos de defesa contra herbívoros tais como os compostos cianogênicos. Mesmo assim, plantas de mandioca podem ser colonizadas e utilizadas por uma série de insetos específicos. Na busca de formas de reduzir o impacto negativo desses insetos sobre as plantas de mandioca, genótipos que resultam em interferências negativas sobre o desenvolvimento de insetos foram identificados. Porém, pouco se sabe a respeito da composição química das folhas de plantas de mandioca e, sobretudo, dos genótipos com maiores efeitos negativos no desenvolvimento dos insetos. Com isso, o presente trabalho foi realizado para conhecer diferenças químicas entre as folhas de mandioca de genótipos selecionados de forma a esclarecer como a composição química desses genótipos pode ser relacionada com as influências observadas no desenvolvimento de insetos pragas. Foi realizada avaliação do desenvolvimento do herbívoro-modelo Spodoptera frugiperda (J.E. Smith, 1797) (Lepidoptera: Noctuidae) alimentado com seis genótipos de mandioca (IAC-14, IAC-90, IAC-12, IAC-Caapora, Baianinha e MEcu 72). A análise da composição química desses genótipos foi realizada pela quantificação de fenóis totais e saponin... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Plants have several secondary metabolites that may be associated with plant-herbivore interactions. Some of these metabolites are antinutrient, repellent or toxic to herbivores. Cassava plants are rustic and produce defense compounds against herbivores such as cyanogenic compounds. Nevertheless, cassava plants can be colonized and used by a number of specific herbivores. In search of ways to reduce the negative impact of these insects on cassava plants, genotypes that result in negative interferences on the development of insects were identified. However, there is a lack of information about the chemical composition of the cassava leaves, mainly, from genotypes with large negative effects on insect development. Thus, the present work was carried out to evaluate the chemical differences between cassava leaves of selected genotypes in order to clarify how the chemical composition of these genotypes can be related to the influences observed in the development of insect pests. The development of the model herbivore Spodoptera frugiperda (JE Smith, 1797) (Lepidoptera: Noctuidae) was assessed by feeding larvae with leaves from six cassava genotypes (IAC-14, IAC-90, IAC-12, IAC-Caapora, Baianinha and MEcu 72). We performed the analysis of the chemical composition of these genotypes by quantification of total phenols and steroidal saponins. Analyzes by GC-MS were performed for the IAC-Caapora, Baianinha and MEcu 72 genotypes. A study was carried out to evaluate if S. frugiperda infes... (Complete abstract click electronic access below) / Doutor

Cromatografia gasosa

Cromatografia liquida.

Defesa química

Fitormônios

Metabolômica.

Produtos naturais.

Resistência induzida

Chemical defense

Gas chromatography

Induced resistance

Liquid chromatography

Metabolomics

Natural products

Phytohormones

Bactericidal Mechanisms of Escapin, A Protein in the Ink of a Sea Hare

Ko, Kochun

07 May 2011

@font-face { font-family: "Arial"; }@font-face { font-family: "ＭＳ 明朝"; }@font-face { font-family: "Calibri"; }p.MsoNormal, li.MsoNormal, div.MsoNormal { margin: 0in 0in 0.0001pt; text-indent: 0.5in; line-height: 200%; font-size: 11pt; font-family: "Times New Roman"; }p.MsoBodyText, li.MsoBodyText, div.MsoBodyText { margin: 0in 0in 6pt; text-indent: 0.5in; line-height: 200%; font-size: 11pt; font-family: "Times New Roman"; }span.BodyTextChar { font-family: Calibri; }div.Section1 { page: Section1; } A 60 kDa monomeric protein isolated from the defensive purple ink secretion of the sea hare Aplysia californica has broad antimicrobial activity in tryptone peptone rich medium. This protein, which we call ‘escapin’, belongs to an L-amino acid oxidase family. The goals of my project were 1) to determine the products of escapin’s oxidation of its main substrate L-lysine, 2) to characterize the antimicrobial effects of escapin’s products, and 3) determine bactericidal mechanisms of action of these products. Escapin is a powerful bactericidal agent against several bacteria species including Escherichia coli, Pseudomonas aeruginosa, Staphylococcus aureus, and Vibrio harveyi. Escapin operates through a two-step process: 1) deamination of L-amino acids (especially L-lysine) by enzymatic activity to produce escapin intermediate products of L-lysine (EIP-K), hydrogen peroxide, and ammonia; and 2) EIP-K simultaneously reacts with hydrogen peroxide to generate escapin end products (EEP-K). EIP exists as an equilibrium mixture of the linear a-keto analogue of lysine and its cyclic forms, and the relative amount of the linear form increases with pH decreases. The powerful bactericidal effect of escapin requires the simultaneous presence of hydrogen peroxide and EIP-K in weak acidic conditions, which suggests that linear form of EIP-K with hydrogen peroxide is responsible for the bactericidal effect of escapin. Using E. coli MC4100 as a model, the mechanism of action of escapin was examined. Brief treatment with EIP-K + H2O2, but not EIP-K or H2O2 alone, causes irreversible DNA condensation with a time course similar to the bactericidal effect. A mutant strain resistant to EIP-K + H2O2 was isolated, and a single point mutation was found in the oxidative stress regulator gene (oxyR). Through a complementary assay, it was shown that wild type E. coli is conferred resistance to EIP-K + H2O2 by carrying mutated oxyR plasmid. Furthermore, in this bactericidal effect, heat or cold shock does not substitute for hydrogen peroxide induced oxidative stress. Thus, escapin’s powerful bactericidal effect may be through irreversible DNA condensation mediated through hydrogen peroxide generating an oxidative stress response, but the pathway mediating EIP-K’s synergistic effect is still unclear.

Toxin

Chemical defense

Flavin

Gastropod

Inking

Opisthobranchia

L-Amino acid oxidase (LAAO)

Amino acids

Enols

Imino compounds

Oxidation

DNA condensation

Biology, general

Biology of odoriferous defensive stink glands of the red flour beetle Tribolium castaneum

Lehmann, Sabrina

21 August 2015

No description available.

570

Tribolium castaneum

stink gland

chemical defense

defensive secretion

secretion volatiles

para-benzoquinone

quinone biosynthesis

RNAi knockdown screen

phenoloxidase

Laccase 2

Biologie (PPN619462639)

Fundamental Efforts to Develop Novel Biotechnological Approaches in Pest Management Applications against Coleoptera: Transcriptomic Exploration of the Chemical Defense Mechanism in the Red Flour Beetle, Tribolium castaneum

Li, Jianwei

24 January 2013

No description available.

572

odoriferous glands

stink glands

chemical defense

defensive secretion

defense mechanism

quinone secretion

alkene secretion

P450

decarboxylase

desaturase

coleopteran

insect

Tribolium