Sexual Plasticity in a Marine Goby (Lythrypnus dalli): Social, Endocrine, and Genetic Influences on Functional Sex

Rodgers, Edmund William

03 December 2007

Sex determination occurs early in development for most animals, at which time sex is fixed for life. Many teleost fishes, however, exhibit remarkable sexual plasticity throughout their life history, ranging from multiple morphs within a sex to functional adult sex reversal. To understand the development and evolution of adult sex reversal, I examined behavioral, endocrine, and genetic contributions to the regulation of functional sex in adult animals, using the bluebanded goby (Lythrypnus dalli) as an experimental model. This species was found to be equally capable of sexual transitions from female to male (protogyny) as from male to female (protandry). Throughout adult life, sexual phenotype is determined by social status, an emergent property of agonistic behavioral interactions that follows a relatively simple social convention: if dominant become or remain male, or if subordinate, become or remain female. The translation of social status into a change in sexual phenotype in the protogynous direction requires a rapid drop in circulating estrogens and an increase in the gonadal expression of a testis differentiating gene dmrt1. Steroid hormones do not play a significant role in modulating status, but the androgen 11-ketotestosterone does positively correlate with the expression of paternal behavior. Taken together, these findings suggest an evolutionary mechanism in sexually plastic species that has linked the conserved molecular cascades of sexual differentiation to a novel signal that varies over life history, social status, thereby allowing for lifelong phenotypic plasticity.

dmrt1

Social dominance

Protandry

Sexual plasticity

Protogyny

Biology, general

Perfil morfo-funcional da inversão de sexo em Synbranchidae (Teleostei: Synbranchiformes) / Morpho-functional characteristics of sex reversal in Synbranchidae (Teleostei: Synbranchiformes)

Antoneli, Fernanda Natalia

25 August 2006

Orientador : Irani Quagio-Grassiotto / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-07T07:43:09Z (GMT). No. of bitstreams: 1 Antoneli_FernandaNatalia_D.pdf: 38673941 bytes, checksum: b5d1b651382a852a4a58b296f16a2d96 (MD5) Previous issue date: 2006 / Resumo: Os peixes teleósteos exibem vários padrões sexuais durante sua ontogenia, nos quais as gõnadas se transformam em ovários ou testículos funcionais. Nas distintas Ordens podem ser encontradas espécies gonocóricas, assim como hermafroditas, tanto simultâneas quanto seqüenciais ou consecutivas. No hermafroditismo seqüencial (protândrico ou protogínico), a mudança de sexo nos indivíduos adultos envolve a degeneração do tecido gonadal do primeiro sexo e o crescimento e maturação do tecido do sexo oposto, passando por uma fase de intersexo. Nas espécies hermafroditas protogínicas, mais frequentemente observada nos teleósteos, os individuos desenvolvem-se como fêmeas e, posteriormente, na vida adulta, seus ovários funcionais são substituídos por testículos, transformando-as em machos reprodutivamente ativos. Fatores internos e externos (ambientais) parecem controlar a mudança de sexo nas espécies hermafroditas seqüenciais. Nos vertebrados, o funcionamento do sistema reprodutor envolve o sistema nervoso e complexas vias de feedback hormonais, ambos integrados no chamado eixo hipotalâmico-hipofisário-gonadal. Nos peixes teleósteos, os esteróides sexuais, assim como os hormônios hipotalâmicos e adenohipofisários são considerados os principais fatores que controlam o desenvolvimento sexual gonadal, e podem estar envolvidos na inversão de sexo em espécies hermafroditas. Synbranchus marmoratus é um peixe hermafrodita protogínico diândrico e, na busca das possíveis correlações entre as alterações morfológicas gonadais e variações plasmáticas dos esteróides sexuais, observou-se que, na dependência do grau de decréscimo da oogênese e aumento da atividade do tecido masculino, o processo de inversão de sexo foi dividido em três fases: inicial, intermediária e final. A gõnada transicional de S. marmoratusfoi caracterizada pela a) desorganização da estrutura típica ovariana; b) massiva degeneração de células germinativas femininas; c) surgimento das células germinativas masculinas iniciais nas bordas das lamelas ovigeras, em associação com prováveis células de Sertoli; d) intensa proliferação e migração de células mióides; e) intensa atividade macrofágica, com a presença de melanomacrófagos e centros melanomacrofágicos; e f) aparecimento de grupos de células de Leydig no compartimento intersticial. As células de Leydig constituíram estruturas masculinas pioneiras a surgirem no ovário, então considerada gônada transicional inicial. Assim, estas células foram consideradas marcadores mortológicos e funcionais do processo de inversão sexual nesta espécie. As células de Leydig apresentaram as típicas características ultraestruturais associadas à esteroidogênese, bem como alta atividade esteroidogênica (3j3-HSD),provavelmente, produzindo andrógenos necessários ao desenvolvimento do tecido masculino gonadal e à espermatogênese. Na fase intermediária, a arquitetura masculina gonadal começa a ser definida, com a proliferação de numerosos cistos com células germinativas em diferentes fases de desenvolvimento. Nas gônadas transicionais finais, apenas poucos oócitos em degeneração e centros melanomacrofágicos permanecem. A mortologia da gônada transicional nesta fase é caracterizada pela completa formação das "lamelas testiculares" e dos túbulos seminíferos, os quais podem ser classificados como do tipo lobular irrestrito. Em nível hormonal, o início da transição sexual está associado à diminuição dos níveis plasmáticos de 17'beta'-estradiol, e o aumento da testosterona circulante, sugerindo a implicação destas circunstâncias para dar início à inversão de sexo natural em S. marmoratus. Os níveis plasmáticos de 11-cetotestosterona apenas sofrem baixas variações durante o início e progresso do referido processo, indicando um papel secundário deste andrógeno na inversão de sexo em S. marmoratus. A identificação das células adenohípofisárias de S. marmoratus durante a inversão de sexo não mostra qualquer alteração no padrão de imunomarcação das células produtoras dos diferentes hormônios ao longo do processo, excetuando-se as células gonadotrópicas, cuja atividade de síntese foi bastante alta nos intersexos iniciais. Provavelmente, estas células ofereçam suporte hormonal para a inversão de sexo nessa espécie. Assim, a inversão de sexo em S. marmoratus parece ocorrer sob controle do eixo hipotalâmico-hipofisário-gonadal. Por sua vez, as alterações morto lógicas necessárias à efetivação do processo propriamente dito - desestruturação do tecido gonadal feminino e desenvolvimento do tecido do sexo oposto - são gradualmente promovidas, seja pela falta ou escassez de estrógenos, e/ou pelo aumento dos níveis de andrógenos. Por conseguinte, S. marmoratus constitui um excelente modelo para o estudo dos eventos morto-funcionais da inversão de sexo / Abstract: Teleost fishes exhibit several sexual patterns during their ontogeny, in which the gonads change into functional ovaries or testes. In distinct Orders, both gonochoristic and hermaphrodite species, simultaneous as well as sequential or consecutive, can be found. In sequential hermaphroditism (protandrous or protogynous), sex change in adult individuais involves the degeneration of the primary sex gonadal tissue and the growth and maturation of the opposite sex, passing through an intersex phase. In protogynous hermaphrodite species, most frequently observed in teleosts, individuais first develop into females and later, at adulthood, their functional ovaries are gradually replaced by testes, becoming them into active reproductively males. Internal and external (environmenta) factors seem to control the sex change in sequential hermaphrodite species. In vertebrates, the dynamic of reproductive system involves the nervous system and complex hormonal biosynthetic pathways, all of them integrated in the called brain-pituitary-gonad axis. In teleost fish, sex steroids, as well as brain and pituitary hormones, are considered to be the main factors controlling gonadal sex development, and may be involved in sex reversal in hermaphrodite species. Synbranchus marmoratus is a protogynous diandric fish. Depending on the degree of female gametogenesis decrease and male tissue activity increase, the sex reversal process was divided into three phases: early, intermediate, and final. S. marmoratus transitional gonad was characterized by the: a) disorganization of the typical ovarian structure; b) massive degeneration of the female germ cells; c) appearance of initial male germ cells . at the border of ovigerous lamellae in association with putative Sertoli cells; d) intense proliferation and migration of myoid cells; e) intense macrophage activity with the presence of melanomacrophages and melanomacrophage centers; and f) appearance of clusters of Leydig cells in the interstitial compartment. Leydig cells constitute the pioneer male structures to arise in the ovary, considered the early transitional gonad at this point. Thus, these cells were considered morphological and functional markers of the sex reversal process in this species. Leydig cells presented the typical fine structures associated to steroidogenesis, such as high steroidogenic activity (3'beta'-HSD), probably, producing androgens necessary to development of gonadal male tissue, and spermatogenesis. In the intermediate phase, the male gonadal architecture begins to be defined, with the proliferation of numerous spermatocysts containing germ cells at different developmental stages. In final transitional gonads, only few degenerating oocytes and melanomacrophage centers remain. The morphology of transitional gonad at this phase is characterized by the complete formation of the testicular lamellae and the seminiferous lobules, which can be classified as unrestricted lobular type. At hormonal level, the beginning of the sexual transition is associated with the decrease of plasma estradiol-17 'beta' levels and the increase of circulating testosterone, suggesting the implication of such circumstances to trigger the natural sex change in S. marmoratus. Plasma 11-ketotestosterone levels onlysuffered weak variations during the initiation and progress of such process, which may indicate the secondary role of this androgen in S. marmoratus sex reversal. The identification of the adenohypophyseal cells of Synbranchus marmoratus during sex reversal does not show any alteration in the immunomarcation pattern of secretory cells of different hormones during the process, except for gonadotropin-producing oolls, which synthesis activity was very high in the initial intersexes. Probably, these cells offer hormonal support for sex reversal in this species. Therefore, sex reversal in S. marmoratus seems to occur under hypothalamic-hypophyseal-gonadal axis control. Morphological alterations necessary to sex reversal process accomplishment - disorganization of female gonadal tissue and development of the tissue of opposite sex - are gradually promoted by the estrogens privation, and/or by the androgens levels increase. Therefore, S. marmoratus constitutes an excellent model for the studying of morpho-functional eventsof sex change / Doutorado / Biologia Celular / Doutor em Biologia Celular e Estrutural

Hermafroditismo

Protoginia

Transexualismo

Esteroides sexuais

Adenohipofise

Hermaphroditism

Protogyny

Transexualism

Sex steroids

Adenohypophysis

The reproductive and physiological condition of a deep-sea mussel (Bathymodiolus septemdierum Hashimoto & Okutani, 1994) living in extremely acidic conditions

Rossi, Giulia

02 December 2016

Oceanic uptake of anthropogenic CO2 emissions is causing wholesale shifts seawater carbonate chemistry towards a state of decreased carbonate ion concentration and reduced ocean pH. This change in water chemistry has potentially dire implications for marine organisms, especially those that build and maintain calcium carbonate structures. Our understanding of how ocean acidification may affect marine organisms is limited, as most studies have been short-term laboratory experiments. The CO2 flux from hydrothermal vent fluids on NW Eifuku submarine volcano (Mariana Volcanic Arc) provides a natural setting to investigate the effects of acidification. Here, the vent mussel, Bathymodiolus septemdierum, lives in water with pH as low as 5.22. This study was designed to examine the consequences of a low pH environment on reproduction, calcification and somatic growth in B. septemdierum, since the presumed elevated cost of acid-base regulation may diminish available energy for these processes. Histological analysis reveals both females and males display synchronous gametogenesis across collection sites with spawning occurring between late winter and early spring. Mussels are functionally dioecious, although evidence of protogynous hermaphroditism was found– a first record for the genus. In comparison with mussels at near normal pH, we find no evidence that the pattern of gametogenesis is affected by low pH conditions. However, calcification is compromised: at a given shell volume, shells from NW Eifuku weigh about half those from sites with near normal pH mussels. The condition index (CI = body ash free dry weight/ shell volume) was assessed in mussels collected from four low pH sites on Northwest Eifuku and two control sites from Lau Basin and Nifonea Ridge; we show that low pH conditions negatively affect CI, especially when energy availability is limited. Bathymodiolus septemdierum acquires energy from chemoautotrophic symbionts in the specialized gill epithelial cells. Using a gill condition index (GCI = gill ash free dry weight/ shell volume) and transmission electron microscopy to determine symbiont abundances in gill tissues, we show that NW Eifuku mussels with healthy gills and abundant symbionts have a higher CI than mussels from NW Eifuku with unhealthy gills. Optimal environmental sulphide concentrations appear to sustain higher symbiont abundances. While the survival of mussels on NW Eifuku is remarkable, it can come at a considerable cost to body and shell condition when during periods of energy limitation. Bathymodiolus septemdierum shows substantial resilience to low pH conditions when energy availability is sufficient due to energy budget adjustments that maximize fitness. / Graduate / 0329, 0472, 0416

Bathymodiolus septemdierum

Northwest Eifuku

High CO2

Gametogenesis,

Protogyny

Body condition

Endosymbionts