Redescrição e ciclo de vida de Clytia gracilis e Clytia linearis (Cnidaria, Hydrozoa, Campanulariidae)

Lindner, Alberto.

January 2000

Thesis (masters)--Universidade de São Paulo, 2000. / Title from PDF t.p. (viewed on May 21, 2006). Includes errata file ([2] p.). Includes bibliographical references.

Clytia Clytia

Redescrição e ciclo de vida de Clytia gracilis e Clytia linearis (Cnidaria, Hydrozoa, Campanulariidae). / Redescription and life cycle of Clytia gracilis and Clytia linearis (Cnidaria, Hydrozoa, Campanulariidae).

Lindner, Alberto

19 December 2000

Os ciclos de vida de Clytia linearis (Thornely, 1899) e de duas espécies apresentando caracteres considerados diagnósticos de Clytia gracilis (M. Sars, 1850) – aqui denominadas Clytia cf. gracilis sp. 1 e Clytia cf. gracilis sp. 2 – foram estudados com base em espécimes coletados no infralitoral raso da costa de São Sebastião e Ilhabela, sudeste do Brasil, entre fevereiro de 1999 e abril de 2000. Medusas foram cultivadas em laboratório, a temperatura de 22-24oC. Colônias de C. linearis são monossifônicas, simpodiais, com até 21,5mm de altura e portando até 26 hidrantes e 10 gonângios. Medusas adultas, alcançando 2,5-3,6mm de diâmetro e até 29 tentáculos e 28 estatocistos, podem ser distinguidas de outras espécies de Clytia pela presença de nematocistos microbásicos mastigóforos do tipo C. Medusas adultas de Clytia cf. gracilis spp. 1 e 2 podem ser distinguidas das demais espécies do gênero estudadas até o momento pela presença de uma fileira de nematocistos microbásicos mastigóforos do tipo A na umbrela, no nível do canal circular. Medusas adultas de C. cf. gracilis sp. 1 e C. cf. gracilis sp. 2 apresentam até 16 tentáculos e podem ser distinguidas entre si pelo diâmetro da umbrela: 6,6-10,1mm e 3,6-5,5mm, respectivamente. Quanto ao estágio de pólipo, C. cf. gracilis sp. 1 apresenta usualmente colônias dicotômicas eretas, hidrotecas alongadas, e gonotecas na hidrorriza e pedículos. Estes caracteres concordam com a descrição de C. gracilis, mas as espécies diferem entre si pela morfometria das gonotecas e dos nematocistos microbásicos mastigóforos do tipo B: aproximadamente 15mm de comprimento para C. gracilis e 9-10mm para C. cf. gracilis sp. 1. Por outro lado, nematocistos do tipo B de C. cf. gracilis sp. 2, com aproximadamente 14,5mm de comprimento, em média, são morfometricamente semelhantes aos de C. gracilis. No entanto, C. cf. gracilis sp. 2 difere de C. gracilis pela forma da hidroteca, por apresentar gonotecas apenas na hidrorriza, e pelo hábito polissifônico do colônias bem desenvolvidas. Uma terceira espécie, C. cf. gracilis sp. 3, é descrita com base em uma colônia sem gonângios. Aspectos da sistemática de Clytia são discutidos. / he life-cycles of Clytia linearis (Thornely, 1899) and two species with characters considered diagnostic of Clytia gracilis (M. Sars, 1850) – Clytia cf. gracilis sp. 1 and Clytia cf. gracilis sp. 2 – have been studied based on specimens collected in the shallow subtidal coast of São Sebastião and Ilhabela, southeast Brazil, between February 1999 and April 2000. Medusae were cultured in the laboratory (22-24oC). Colonies of C. linearis are monosiphonic, sympodial, up to 21.5mm high and bearing up to 26 hydranths and 10 gonangia. Adult medusae reached 2.5-3.6mm in diameter, and up to 29 tentacles and 28 statocysts. The presence of microbasic mastigophore type C nematocysts distinguishes adult medusae of C. linearis from other species of Clytia. A band of microbasic mastigophore type A nematocysts in the umbrella, at the level of the circular canal, distinguishes adult medusae of Clytia cf. gracilis spp. 1 and 2 from other species of the genus. Adult medusae of C. cf. gracilis sp. 1 and C. cf. gracilis sp. 2 have up to 16 tentacles, and can be distinguished by the diameter of the umbrella: 6.6-10.1mm and 3.6-5.5mm, respectively. Colonies of C. cf. gracilis sp. 1 are usually erect and dichotomous, the hydrothecae are elongated and the gonothecae present in the hydrorhiza and pedicels. These features closely match with the description of C. gracilis, but both species differ in the morphometry of the gonothecae and microbasic mastigophore type B nematocysts: about 15mm (length) for C. gracilis and 9-10mm for C. cf. gracilis sp. 1. Type B nematocysts of C. cf. gracilis sp. 2 (about 14.5mm in length) are more similar in size to those of C. gracilis. However, the former species differs from the latter in the shape of the hydrothecae, by having gonothecae only at the hydrorhiza and polysiphonic well-developed colonies. A third species, C. cf. gracilis sp. 3, is described based on an unfertile colony. Aspects of the systematics of Clytia are discussed.

Brasil

Brazil

Campanulariidae

ciclo de vida

Clytia gracilis

Clytia linearis

Cnidaria

hidróides

hydroids

Hydrozoa

Ilhabela

life-cycle

medusae

medusas

nematocistos

nematocysts

São Sebastião

sistemática

systematics

taxonomia

taxonomy

Redescrição e ciclo de vida de Clytia gracilis e Clytia linearis (Cnidaria, Hydrozoa, Campanulariidae). / Redescription and life cycle of Clytia gracilis and Clytia linearis (Cnidaria, Hydrozoa, Campanulariidae).

Alberto Lindner

19 December 2000

Os ciclos de vida de Clytia linearis (Thornely, 1899) e de duas espécies apresentando caracteres considerados diagnósticos de Clytia gracilis (M. Sars, 1850) – aqui denominadas Clytia cf. gracilis sp. 1 e Clytia cf. gracilis sp. 2 – foram estudados com base em espécimes coletados no infralitoral raso da costa de São Sebastião e Ilhabela, sudeste do Brasil, entre fevereiro de 1999 e abril de 2000. Medusas foram cultivadas em laboratório, a temperatura de 22-24oC. Colônias de C. linearis são monossifônicas, simpodiais, com até 21,5mm de altura e portando até 26 hidrantes e 10 gonângios. Medusas adultas, alcançando 2,5-3,6mm de diâmetro e até 29 tentáculos e 28 estatocistos, podem ser distinguidas de outras espécies de Clytia pela presença de nematocistos microbásicos mastigóforos do tipo C. Medusas adultas de Clytia cf. gracilis spp. 1 e 2 podem ser distinguidas das demais espécies do gênero estudadas até o momento pela presença de uma fileira de nematocistos microbásicos mastigóforos do tipo A na umbrela, no nível do canal circular. Medusas adultas de C. cf. gracilis sp. 1 e C. cf. gracilis sp. 2 apresentam até 16 tentáculos e podem ser distinguidas entre si pelo diâmetro da umbrela: 6,6-10,1mm e 3,6-5,5mm, respectivamente. Quanto ao estágio de pólipo, C. cf. gracilis sp. 1 apresenta usualmente colônias dicotômicas eretas, hidrotecas alongadas, e gonotecas na hidrorriza e pedículos. Estes caracteres concordam com a descrição de C. gracilis, mas as espécies diferem entre si pela morfometria das gonotecas e dos nematocistos microbásicos mastigóforos do tipo B: aproximadamente 15mm de comprimento para C. gracilis e 9-10mm para C. cf. gracilis sp. 1. Por outro lado, nematocistos do tipo B de C. cf. gracilis sp. 2, com aproximadamente 14,5mm de comprimento, em média, são morfometricamente semelhantes aos de C. gracilis. No entanto, C. cf. gracilis sp. 2 difere de C. gracilis pela forma da hidroteca, por apresentar gonotecas apenas na hidrorriza, e pelo hábito polissifônico do colônias bem desenvolvidas. Uma terceira espécie, C. cf. gracilis sp. 3, é descrita com base em uma colônia sem gonângios. Aspectos da sistemática de Clytia são discutidos. / he life-cycles of Clytia linearis (Thornely, 1899) and two species with characters considered diagnostic of Clytia gracilis (M. Sars, 1850) – Clytia cf. gracilis sp. 1 and Clytia cf. gracilis sp. 2 – have been studied based on specimens collected in the shallow subtidal coast of São Sebastião and Ilhabela, southeast Brazil, between February 1999 and April 2000. Medusae were cultured in the laboratory (22-24oC). Colonies of C. linearis are monosiphonic, sympodial, up to 21.5mm high and bearing up to 26 hydranths and 10 gonangia. Adult medusae reached 2.5-3.6mm in diameter, and up to 29 tentacles and 28 statocysts. The presence of microbasic mastigophore type C nematocysts distinguishes adult medusae of C. linearis from other species of Clytia. A band of microbasic mastigophore type A nematocysts in the umbrella, at the level of the circular canal, distinguishes adult medusae of Clytia cf. gracilis spp. 1 and 2 from other species of the genus. Adult medusae of C. cf. gracilis sp. 1 and C. cf. gracilis sp. 2 have up to 16 tentacles, and can be distinguished by the diameter of the umbrella: 6.6-10.1mm and 3.6-5.5mm, respectively. Colonies of C. cf. gracilis sp. 1 are usually erect and dichotomous, the hydrothecae are elongated and the gonothecae present in the hydrorhiza and pedicels. These features closely match with the description of C. gracilis, but both species differ in the morphometry of the gonothecae and microbasic mastigophore type B nematocysts: about 15mm (length) for C. gracilis and 9-10mm for C. cf. gracilis sp. 1. Type B nematocysts of C. cf. gracilis sp. 2 (about 14.5mm in length) are more similar in size to those of C. gracilis. However, the former species differs from the latter in the shape of the hydrothecae, by having gonothecae only at the hydrorhiza and polysiphonic well-developed colonies. A third species, C. cf. gracilis sp. 3, is described based on an unfertile colony. Aspects of the systematics of Clytia are discussed.

Brasil

Campanulariidae

ciclo de vida

Clytia gracilis

Clytia linearis

Cnidaria

hidróides

Hydrozoa

Ilhabela

medusas

nematocistos

São Sebastião

sistemática

taxonomia

Brazil

hydroids

life-cycle

medusae

nematocysts

systematics

taxonomy

Light-induced oocyte maturation in the hydrozoan clytia hemisphaerica / Régulation de la maturation ovocytaire par la lumière chez l'hydrozoaire clytia hemisphaerica

Quiroga Artigas, Gonzalo

23 May 2017

Un contrôle précis de la maturation ovocytaire et de la ponte sont essentiels au succès de la reproduction sexuée au sein le règne animal. Ces processus sont coordonnés précisément par des signaux endocriniens et/ou environnementaux, selon les espèces, mais beaucoup reste à apprendre sur leurs régulations. Chez les cnidaires, de nombreuses méduses du groupe des hydrozoaires sont connues pour produire des gamètes en réponse à la transition nuit/jour. Pour caractériser les machineries cellulaires et moléculaires liant la réception de la lumière à l'initiation de la maturation ovocytaire, j'ai étudié la méduse hydrozoaire Clytia hemisphaerica. Mon travail de thèse s’est découpé en trois parties, chacune impliquant l'identification d'un composant moléculaire clé de ce processus.Mon étude initiale faisait partie d'une collaboration avec N. Takeda (Asamushi) et R. Deguchi (Sendai), chercheurs qui avaient, avant le début de ma thèse, identifié chez Clytia les Hormones d'Incitation de Maturation ovocytaire endogènes (MIH) comme étant des tétrapeptides de type WPRPamide, produit par clivage de deux précurseurs à neuropeptides. J'ai montré par hybridation in situ et immunofluorescence que les deux gènes précurseurs du MIH sont exprimés par un type de cellules neurosécrétrices localisées au niveau de l’ectoderme de la gonade, et que les peptides MIH sont sécrétés par ces mêmes cellules suite à une stimulation lumineuse. Cette étude a posé les bases permettant l'identification des régulateurs agissant en amont et en aval du MIH, et plus spécifiquement ceux impliqués dans la photoréception de l’ectoderme de la gonade et la réception du MIH par les ovocytes.Pour identifier le récepteur du MIH de Clytia (CheMIHR) dans les ovocytes, j'ai compilé à partir de données transcriptomiques issues de tissus de gonades, une liste de 16 protéines candidates de la famille des Récepteurs Couplés aux Protéines G (GPCR). J'ai cloné les 16 cDNAs et, utilisant une méthode de « deorphelinisation » de GPCR basée sur de la culture cellulaire (collaboration avec P. Bauknecht et G. Jékély; MPI, Tübingen), j’ai pu identifier un GPCR activée par des peptides MIH synthétiques. Sa fonction in vivo comme récepteur essentiel du MIH a été confirmée par la méthode d'édition génétique CRISPR/CAS9. La délétion ainsi produite, entraînant un déplacement du cadre de lecture au sein du gène CheMIHR, a détérioré la croissance des colonies de polypes et le comportement de ponte des méduses matures. Confirmant la fonction de CheMIHR, la maturation ovocytaire chez des mutants CheMIHR ne pouvait pas être déclenchée par la lumière ou par addition de MIH synthétiques, mais pouvait être rétablie en utilisant des analogues au cAMP, molécule connue pour agir en aval de la réception du MIH dans les ovocytes d’hydrozoaires. Des analyses phylogénétiques ont montré que Clytia MIHR est affilié à un sous-ensemble de familles de neuropeptides de bilaterians impliqués dans divers processus physiologiques, notamment la régulation de la reproduction. Des hybridations in situ sur les méduses Clytia, ont en outre montré l'expression des précurseurs de CheMIH et de CheMIHR dans des cellules neurales hors de la gonade, suggérant un rôle plus large du couple CheMIH-MIHR que la seule initiation de la maturation ovocytaire.Pour mieux comprendre la photoréception des gonades chez Clyita, j'ai montré que la ponte est sélectivement incitée par la lumière bleu-cyan, et mis en évidence, grâce à l’analyse de données de transcriptome de gonade, qu’un photopigment de la famille des Opsin (Opsin9) est hautement exprimé dans l'ectoderme. De façon saisissante, les hybridations in situ ont montré que le gène Opsin9 est exprimé dans les mêmes cellules sécrétant le MIH. L'introduction d'une mutation de changement de cadre de lecture dans le gène Opsin9 via la technologie CRISPR/Cas9 a empêché la maturation ovocytaire et la ponte des méduses mutantes en réponse à la lumière... / Tight control of oocyte maturation and of gamete release is essential for successful sexual reproduction in the animal kingdom. These processes are precisely coordinated by endocrine and/or environmental cues, depending on the species, but much remains to be learned about their regulation. Within the Cnidaria, many hydrozoan jellyfish are known to spawn mature gametes following dark/light transitions. To characterise the cellular and molecular machinery linking light reception and oocyte maturation initiation, I have studied the hydrozoan jellyfish Clytia hemisphaerica. My thesis work had three parts, each involving the identification of a key molecular component of this process.My initial study was part of a collaboration with N. Takeda (Asamushi) and R. Deguchi (Sendai), who identified the endogenous oocyte Maturation-Inducing Hormones (MIH) in Clytia as WPRPamide-related tetrapeptides, generated by cleavage of two neuropeptide precursors. I showed by in situ hybridization and immunofluorescence that Clytia MIH is produced by neurosecretory cells of the gonad ectoderm that co-express the two precursor genes, and that it is secreted upon light stimulation. This study paved the way for identification of regulators acting upstream and downstream of MIH release in the gonads, specifically the ones involved in photoreception in the gonad ectoderm, and in MIH reception by the oocytes. To identify the Clytia MIH receptor (CheMIHR) in the oocytes, I compiled a shortlist of 16 candidate G protein-coupled receptors (GPCRs) from gonad transcriptome data. I cloned all 16 cDNAs and, using a cell culture-based "GPCR deorphanization" assay (collaboration with P. Bauknecht and G. Jékély; MPI, Tübingen), identified one GPCR that was activated by synthetic MIH peptides. Its in vivo function as the essential MIH receptor was confirmed by CRISPR/Cas9 gene editing. Introduction of a frame-shift mutation in the CheMIHR gene impaired growth of Clytia polyp colonies and also the spawning behaviour of mature medusae. Confirming the function of CheMIHR, oocyte maturation in CheMIHR mutants could not be triggered by light or by synthetic MIH, but could be restored using cell-permeable analogues of cAMP, known to act downstream of MIH reception in hydrozoan oocytes. Phylogenetic analyses showed that Clytia MIHR is related to a subset of bilaterian neuropeptide hormone receptor families involved in diverse physiological processes, including regulation of reproduction. Accordingly, in situ hybridization showed the expression of Clytia MIH precursors and MIHR in non-gonadal neural cells, suggesting a wider role of Clytia MIH-MIHR besides oocyte maturation initiation.To address gonad photoreception, I showed that Clytia spawning is selectively induced by blue-cyan light, and then identified using gonad transcriptome data an opsin photopigment (Opsin9) highly expressed in the ectoderm. Strikingly, in situ hybridization showed that Opsin9 is expressed in the MIH-secreting cells. Introduction of a frame-shift mutation into the Opsin9 gene via CRISPR/Cas9 prevented oocyte maturation and spawning of mutant jellyfish in response to light. Anti-MIH immunofluorescence and rescue experiments with synthetic MIH showed that the essential function of Opsin9 is upstream of MIH release. Spawning in Clytia thus appears to be regulated by a dual function photosensory-neurosecretory cell type, perhaps retained from a distant metazoan ancestor...

Clytia

Lumière

Maturation ovocytaire

Gpcr

Opsin

Neuropeptide

Opsin

Neuropeptide

Oocyte maturation

571.8