Relações entre o teor de fenóis totais e o ciclo das galhas de Cecidomyiida e em Aspidosperm a spruceanum Müll. Arg. (Apocynaceae) Relationships between phenolic contents and a Cecidomyiidae gall cycle in Aspidosperma spruceanum Müll. Arg. (Apocynaceae)

Alterações morfológicas detectadas em diversas espécies vegetais em função da indução de galhas são comumente acompanhadas de mudanças químicas importantes para o estabelecimento e manutenção do sistema galhador-planta hospedeira. O estudo da variação do teor de fenóis totais e sua relação com o desenvolvimento das galhas no sistema Aspidosperma spruceanum-Cecidomyiidae foi realizado ao longo de um ano, no qual foram detectados pelo menos dois ciclos de vida dos insetos indutores. O nível de infestação foliar foi alto, atingindo 87%, e os Cecidomyiidae tiveram a região internervural como sítio preferencial de oviposição. A variação sazonal no conteúdo de fenóis totais nas amostras de folhas sadias e galhadas foi primariamente relacionada às condições abióticas e muito embora este teor tenha atingido o máximo de 10 mg EAT g-1, indicando um ambiente químico celular não favorável à indução e a sua sobrevivência, o indutor de A. spruceanum supera esta barreira química, podendo ainda ser favorecido pela proteção contra inimigos naturais propiciada pelos fenólicos.<br>Morphological alterations detected in several plant species due to gall induction are commonly followed by chemical changes fundamental to the establishment and maintenance of the host plant-gall maker system. The study of phenolic contents variation and its relation to gall development in Aspidosperma spruceanum-Cecidomyiidae system through a year-time detected two insect life cycles. The level of infestation was high, getting up to 87%, and the Cecidomyiidae preferentially oviposited in internervural region. Seasonal variation in phenolic contents in healthy and galled leaves detected in A. spruceanum was primarily related to abiotic conditions. Even though the levels of phenolic contents might get a maximum of 10 mg EAT g-1, which indicated a non stimulating cell chemical environment to gall induction and herbivore survivorship, A. spruceanum gall maker surpassed this chemical barrier, and might also be favored by the chemical protection against its natural enemies, that phenolic contents might confer

Clonal integration beyond resource sharing: implications for defence signalling and disease transmission in clonal plant networks

Item does not contain fulltextResource sharing between ramets of clonal plants is a well-known phenomenon, which allows stoloniferous and rhizomatous species to internally translocate water, mineral nutrients and carbohydrates from sites of high supply to sites of high demand. The mechanisms and implications of resource integration in clonal plants have extensively been studied in the past. Vascular ramet connections are likely to provide an excellent means to share substances other than resources, such as systemic defence signals and pathogens. The aim of this paper is to propose the idea that physical ramet connections of clonal plants can be used (1) to transmit signals, which enable members of clonal plant networks to share information about their biotic and abiotic environments, and (2) to facilitate the internal distribution of systemic pathogens in clonal plant networks and populations. We will focus on possible mechanisms as well as on potential ecological and evolutionary implications of clonal integration beyond resource sharing. More specifically, we will explore the role of physiological integration in clonal plant networks for the systemic transmission of direct and indirect defence signals after localized herbivore attack. We propose that sharing defence induction signals among ramets may be the basis for an efficient early warning system, and it may allow for effective indirect defence signalling to herbivore enemies through a systemic release of volatiles from entire clonal fragments. In addition, we will examine the role of clonal integration for the internal spread of systemic pathogens and pathogen defence signals within clonal plants. Clonal plants may use developmental mechanisms such as increased flowering and clone fragmentation, but also specific biochemical defence strategies to fight pathogens. We propose that clonal plant networks can act as stores and vectors of diseases in plant populations and communities and that clonal life histories favour the evolution of pathogens with a low virulence