RESUMO
BACKGROUND: The LEAFY (LFY) transcription factors are present in algae and across land plants. The available expression and functional data of these genes in embryophytes suggest that LFY genes control a plethora of processes including the first zygotic cell division in bryophytes, shoot cell divisions of the gametophyte and sporophyte in ferns, cone differentiation in gymnosperms and floral meristem identity in flowering plants. However, their putative plesiomorphic role in plant reproductive transition in vascular plants remains untested. RESULTS: We perform Maximum Likelihood (ML) phylogenetic analyses for the LFY gene lineage in embryophytes with expanded sampling in lycophytes and ferns. We recover the previously identified seed plant duplication that results in LEAFY and NEEDLY paralogs. In addition, we recover multiple species-specific duplications in ferns and lycophytes and large-scale duplications possibly correlated with the occurrence of whole genome duplication (WGD) events in Equisetales and Salviniales. To test putative roles in diverse ferns and lycophytes we perform LFY expression analyses in Adiantum raddianum, Equisetum giganteum and Selaginella moellendorffii. Our results show that LFY genes are active in vegetative and reproductive tissues, with higher expression in early fertile developmental stages and during sporangia differentiation. CONCLUSIONS: Our data point to previously unrecognized roles of LFY genes in sporangia differentiation in lycophytes and ferns and suggests that functions linked to reproductive structure development are not exclusive to seed plant LFY homologs.
RESUMO
Myxozoans are widespread and common endoparasites of fish with complex life cycles, infecting vertebrate and invertebrate hosts. There are two classes: Myxosporea and Malacosporea. To date about 2500 myxosporean species have been described. By comparison, there are only five described malacosporean species. Malacosporean development in the invertebrate hosts (freshwater bryozoans) has been relatively well studied but is poorly known in fish hosts. Our aim was to investigate the presence and development of malacosporeans infecting a diversity of fish from Brazil, Europe and the USA. We examined kidney from 256 fish belonging variously to the Salmonidae, Cyprinidae, Nemacheilidae, Esocidae, Percidae, Polyodontidae, Serrasalmidae, Cichlidae and Pimelodidae. Malacosporean infections were detected and identified by polymerase chain reaction and small subunit ribosomal DNA sequencing, and the presence of sporogonic stages was evaluated by ultrastructural examination. We found five malacosporean infections in populations of seven European fish species (brown trout, rainbow trout, white fish, dace, roach, gudgeon and stone loach). Ultrastructural analyses revealed sporogonic stages in kidney tubules of three fish species (brown trout, roach and stone loach), providing evidence that fish belonging to at least three families are true hosts. These results expand the range of fish hosts exploited by malacosporeans to complete their life cycle.
Assuntos
Doenças dos Peixes/parasitologia , Peixes/parasitologia , Especificidade de Hospedeiro , Myxozoa/crescimento & desenvolvimento , Animais , Brasil , DNA Ribossômico/genética , Europa (Continente) , Rim/parasitologia , Estágios do Ciclo de Vida , Myxozoa/classificação , Myxozoa/genética , Doenças Parasitárias em Animais/parasitologia , Estados UnidosRESUMO
Pera is a neotropical genus that currently belongs to the family Peraceae. This circumscription resulted from an inclusion of the Rafflesiaceae between the old tribe Pereae and all other Euphorbiaceae, and wherein Pereae was elevated to family rank making Euphorbiaceae monophyletic again. These changes are necessary although Rafflesiaceae are holoparasitic with extremely reduced vegetative bodies and large flowers while Peraceae and Euphorbiaceae have well developed vegetative parts and reduced flowers. As the embryology of Peraceae was poorly known, and embryological processes are conservative, we studied the embryology of Pera glabrata, searching for similarities between Peraceae, Rafflesiaceae, and Euphorbiaceae that could support this grouping. Usual methods of light microscopy and scanning electron microscopy were utilised. The results show endothecium with reversed-T-shaped cells, prismatic crystals in the tapetum, and disintegrated aerenchymatous septum in the mature fruit as unique features for Peraceae and possibly apomorphies for the family. In addition to the unisexual flowers, porogamous fertilization is present and one ovule per carpel which may support the Peraceae-Rafflesiaceae-Euphorbiaceae clade. The comparative approach also suggests possible (syn-)apomorphies for linoids and phyllanthoids, only linoids, Rafflesiaceae, Euphorbiaceae, and Ixonanthaceae. The presence of a placental obturator found previously unknown in Peraceae emerged as a possible synapomorphy for the euphorbioids (including Ixonanthaceae, Linaceae, Phyllanthaceae, Picrodendraceae, Peraceae, Rafflesiaceae, and Euphorbiaceae), which appeared in a common ancestor of the group and has been lost in Rafflesiaceae.
Assuntos
Magnoliopsida/classificação , Evolução Biológica , Classificação , Euphorbiaceae/classificação , Euphorbiaceae/citologia , Euphorbiaceae/embriologia , Euphorbiaceae/genética , Flores/classificação , Flores/citologia , Flores/embriologia , Flores/genética , Magnoliopsida/citologia , Magnoliopsida/embriologia , Magnoliopsida/genética , Sementes/classificação , Sementes/citologia , Sementes/embriologia , Sementes/genéticaRESUMO
Studies on reproductive aspects, spore morphology and ultrastructure of Lycopodiaceae are not very common in the scientific literature, and constitute essential information to support taxonomic and systematic relationships among the group. In order to complete existing information, adding new and broader contributions on these topics, a comparative analysis of the sporogenesis ultrastructure, with emphasis on cytological aspects of the sporocyte coat development, tapetum, monoplastidic and polyplastidic meiosis, sporoderm ontogeny and ornamentation of the mature spores, was carried out in 43 taxa of eight genera of the Lycopodiaceae: Austrolycopodium, Diphasium, Diphasiastrum, Huperzia (including Phlegmariurus), Lycopodium, Lycopodiella, Palhinhaea and Pseudolycopodiella growing in the Andes of Colombia and the Neotropics. For this study, the transmission electron microscopy (TEM) samples were collected in Cauca and Valle del Cauca Departments, while most of the spores for scanning electron microscopy (SEM) analysis were obtained from herbarium samples. We followed standard preparation procedures for spore observation by TEM and SEM. Results showed that the sporocyte coat is largely composed by primary wall components; the sporocyte develop much of their metabolic activity in the production of their coat, which is retained until the spores release; protective functions for the diploid cells undergoing meiosis is postulated here for this layer. The abundance of dictyosomes in the sporocyte cytoplasm was related to the formation and development of the sporocyte coat. Besides microtubule activity, the membrane of sporocyte folds, associated with electrodense material, and would early determine the final patterns of spore ornamentation. Monoplastidic condition is common in Lycopodium s.l., whereas polyplastidic condition was observed in species of Huperzia and Lycopodiella s. l.. In monoplastidic species, the tapetum presents abundant multivesicular bodies, while in polyplastidic species, the secretory activity of the tapetum is less intense. Sporoderm development is centripetal, exospore is the first formed layer, then the endospore and, if present, perispore is the final deposited layer. Adult spores of the Lycopodiaceae showed two patterns of ornamentation: negative or caviform (foveolate spores) and positive or muriform ornamentation, the latter with two subtypes (rugate and reticulate spores). The spores of Huperzia are characteristically foveolate, the rugate spores were found in a few species of Huperzia and in all of the Lycopodiella s. l. taxa studied, while Lycopodium s.l. spores bear reticulate ornamentation. Numerous ornamentation traits are diagnostic at the specific level. The types of ornamentation found do not support the recent extreme fragmentation of the family in several genera, but could match, a priori, with the idea of three subfamilies. The findings of sporogenesis, extremely similar in all taxa studied, point more to consider fewer genera, more comprehensive, than the recent, markedsplitting of the family. Rev. Biol. Trop. 62 (3): 1161-1195. Epub 2014 September 01.
Estudios sobre aspectos reproductivos, morfología y ultraestructura de las esporas de Lycopodiaceae no son abundantes en la literatura científica y constituyen información esencial para apoyar las relaciones taxonómicas y sistemáticas en el grupo. Con el fin de completar la información existente, añadiendo contribuciones nuevas y más amplias sobre estos temas, se realizó un análisis comparado de la ultraestructura de la esporogénesis, con énfasis en aspectos citológicos que tienen que ver con la formación de la cubierta de los esporocitos, el tapete, las meiosis monoplastidial y poliplastidial, la ontogenia del esporodermo y la ornamentación de las esporas maduras en 43 táxones de ocho géneros de Lycopodiaceae: Austrolycopodium, Diphasium, Diphasiastrum, Huperzia (incluyendo Phlegmariurus), Lycopodium, Lycopodiella, Palhinhaea y Pseudolycopodiella que crecen en los Andes de Colombia y el Neotrópico. Para estudios con microscopía electrónica de trasmisión (MET) las muestras se recolectaron en los departamentos de Cauca y Valle del Cauca, mientras que la mayoría de las muestras para microscopía electrónica de barrido (MEB) provienen de material herborizado de colecciones. Para la observación de las muestras con MET y MEB se utilizaron protocolos estándar para el procesamiento de esporas. La cubierta de los esporocitos está formada por pared primaria; los esporocitos invierten gran parte de su actividad metabólica en la producción de esa cubierta, que es mantenida hasta la liberación de las esporas y tiene funciones de protección de las células que harán meiosis. La abundancia de dictiosomas en los esporocitos se relacionó con la formación y desarrollo de la cubierta. Además de la actividad de los microtúbulos, la presencia de sinuosidades y plegamientos asociados con material electro denso en la membrana de los esporocitos determinarían tempranamente los patrones de ornamentación de las esporas. La condición monoplastidial es común en Lycopodium s.l.y la poliplastidial se observó en Huperzia y Lycopodiella s. l. En especies monoplastidiales el tapete presenta abundantes cuerpos plurivesiculares, en las poliplastidiales la actividad secretora del tapete es menos intensa. El desarrollo del esporodermo es centrípeto, el exosporio se forma primero, seguido del endosporio y el perisporio, si está presente, se deposita de último. En las esporas adultas de Lycopodiaceae se encontraron dos patrones de ornamentación: negativo o caviforme (esporas foveoladas) y positivo o muriforme (esporas rugadas y reticuladas). Las esporas foveoladas son características de Huperzia; las rugadas de unas pocas especies de Huperzia y las especies de Lycopodiella s. l., mientras que las reticulada son típicas de Lycopodium s. l.. Numerosos caracteres de la ornamentación resultan diagnósticos en el nivel específico. Los tipos principales no apoyan la extrema fragmentación reciente de la familia en varios géneros, aunque podría coincidir, a priori, con la idea de tres subfamilias. Los hallazgos de la esporogénesis, extremadamente similar en todos los táxones estudiados, apuntan más a la unificación de los géneros en la familia que a su segregación.
Assuntos
Lycopodiaceae/ultraestrutura , Meiose , Esporângios/embriologia , Esporos/crescimento & desenvolvimento , Colômbia , Lycopodiaceae/classificação , Lycopodiaceae/embriologia , Microscopia Eletrônica de Varredura , Esporângios/ultraestrutura , Esporos/ultraestruturaRESUMO
Studies on reproductive aspects of Lycopodiaceae are not very abundant in the scientific literature, and constitute essential information to support taxonomic and systematic relationships among the group. Here we present a detailed study of the ontogeny of sporangia and sporogenesis, and the chemical determination of several compounds generated during spore formation. The analyses were performed in 14 taxa of six genera of the family, Diphasiastrum, Diphasium, Huperzia (a genus which is treated here including Phlegmariurus), Lycopodiella, Lycopodium and Palhinhaea. Specimens were collected in three departments from the Colombian Andes between 1 454-3 677m altitude. Ontogeny was studied in small, 1cm long pieces of strobili and axis, which were fixed in glutaraldehyde or FAA, dehydrated in alcohol, embedded in LR White, sectioned in 0.2-0.5μm and stained with toluidine blue (TBO), a metachromatic dye that allows to detect both sporopollenin and lignin or its precursors, during these processes. For other studies, paraplast plus-embedded sections (3-5μm) were stained with safranin-fast green and alcian blue-hematoxylin. Chemical tests were also conducted in sections of fresh sporangia at different stages of maturity using alcian blue (mucopolysaccharides), Lugol solution (starch), Sudan III (lipids), phloroglucinol (lignin) and orcein (chromosomes). Sections were observed with photonic microscope equipped with differential interference contrast (DIC) and fluorescence microscopy (for spore and sporangium walls unstained). Strobili and sporangia were dehydrated with 2.2 dimethoxypropane, critical point dried and coated with gold for scanning electron microscopy (SEM). Our results indicated that the ontogeny of sporangia and sporogenesis were very similar to the previously observed in Huperzia brevifolia. Cutinisation occurs in early stages of development of sporangium cell walls, but in their final stages walls become lignified. As for the sporoderm development, the exospore is the first layer formed, composed by sporopollenin. The endospore deposits as a thin inner layer composed of cellulose, pectin and carboxylated polysaccharides. The perispore, if present, deposits at last. Mucopolysaccharides were found on the sporocyte coat and its abundance in sporangial cavity persists up to the immature tetrads stage, and then disappears. The lipids were abundant in the sporocytes, tetrads and spores, representing the main source of energy of the latter. In contrast, starch is not detected in the spores, but is abundant in premeiotic sporocytes and immature tetrads, developmental stages of high cellular metabolic activity. Intrinsic fluorescence corroborates the presence of lignin and cutin in the sporangium wall, while the sporopollenin is restricted to the exospore. The transfusion cells and the perispore are not always present. However, the processes of ontogeny and sporogenesis are extremely similar throughout the taxa studied, suggesting that they represent conservative family traits, nonspecific or generic.
Los estudios sobre aspectos reproductivos no son muy abundantes en la literatura científica sobre los taxones de Lycopodiaceae y constituyen información esencial para apoyar la taxonomía y relaciones sistemáticas en el grupo. Por lo tanto, se presenta aquí un análisis detallado de la ontogenia de los esporangios y esporogénesis, así como determinaciones químicas de varios compuestos generados durante la formación de las esporas. Los análisis se llevaron a cabo en 14 taxones de seis géneros de la familia: Diphasiastrum, Diphasium, Huperzia (un género que se trata aquí, incluyendo Phlegmariurus), Lycopodiella, Lycopodium y Palhinhaea. Las muestras fueron recolectadas en tres departamentos de los Andes de Colombia entre 1 454-3 677m de altitud. La ontogenia se estudió en trozos de estróbilos y ejes, de 1cm de largo, que se fijaron en glutaraldehido o FAA, se deshidrataron en alcohol, se incluyeron en LR White, se seccionaron en cortes de 0.2-0.5μm y se colorearon con azul de toluidina (TBO), un colorante metacromático que permite detectar tanto esporopolenina como lignina o sus precursores. Para estudios adicionales, secciones de 3-5μm de material incluido en paraplast plus se colorearon con safranina-verde rápido y azul alciánhematoxilina. Las pruebas químicas se llevaron a cabo en secciones de esporangios sin fijar en diferentes etapas de madurez utilizando azul alcián (mucopolisacáridos), solución de Lugol (almidón), Sudán III (lípidos), fluoroglucinol (lignina) y orceína (cromosomas). Las observaciones se efectuaron con microscopio fotónico equipado con contraste diferencial de interferencia (DIC) y microscopía de fluorescencia (para esporas y pared de los esporangios sin colorear). Para observaciones con microscopía electrónica de barrido (MEB), los estróbilos y esporangios se deshidrataron con 2,2 dimetoxipropano, se desecaron a punto crítico y se metalizaron con oro. Los resultados indican que la ontogenia de los esporangios y esporogénesis es muy similar a la observada previamente en Huperzia brevifolia. En las primeras etapas de desarrollo, las paredes celulares de la epidermis del esporangio se cutinizan y en las finales se lignifican. En el desarrollo del esporodermo, la primera capa que se forma es el exosporio, compuesto por esporopolenina. El endosporio es una capa interna delgada compuesta de celulosa, pectina y polisacáridos carboxilados. El perisporio, si está presente, es la última capa que se deposita. Los mucopolisacáridos se encontraron en la cubierta del esporocito, son abundantes en la cavidad esporangial hasta la etapa de tétradas inmaduras y luego desaparecen. Los lípidos son abundantes en esporocitos, tétradas y esporas, y representan la principal fuente de energía de estas. En contraste, el almidón no se detecta en las esporas pero es abundante en esporocitos premeióticos y tétradas inmaduras, ambos con gran actividad metabólica. La fluorescencia intrínseca corrobora la presencia de lignina y cutina en la pared del esporangio, mientras que la esporopolenina se limita al exosporio. Las células de transfusión y el perisporio no siempre están presentes. Sin embargo, los procesos de la ontogenia y esporogénesis son extremadamente similares en todos los taxones estudiados, lo que sugiere que representan rasgos típicos de familia, no específicos ni genéricos.
Assuntos
Lycopodiaceae/crescimento & desenvolvimento , Esporângios/crescimento & desenvolvimento , Esporos/crescimento & desenvolvimento , Histocitoquímica , Lycopodiaceae/química , Lycopodiaceae/classificação , Lycopodiaceae/citologia , Meiose , Microscopia de Fluorescência , Esporângios/química , Esporângios/classificação , Esporângios/citologia , Esporos/química , Esporos/classificação , Esporos/citologiaRESUMO
Studies on some reproductive traits in Equisetum species are scarce and valuable to understand species distribution. Therefore, a detailed study of the sporogenesis process and spore development in E. bogotense is presented, with an analysis of the main events during meiosis, maturation of spores, spore wall ultrastructure, orbicules and elaters. Specimens were collected from 500 to 4 500m in Cauca, Colombia. Strobili at different maturation stages were fixed, dehydrated, embedded in resin, and ultra-microtome obtained sections were stained with Toluidine blue. Observations were made with optical microscopy with differential interference contrast illumination technique (DIC), transmission and scanning electron microscopy (TEM and SEM). Ultrathin sections (70-80μm) for TEM observations were stained with uranyl acetate and lead citrate; while samples for SEM observations, were fixed, dehydrated in 2.2-dimethoxypropane and dried at critical point as in standard methods. Strobili have numerous mature sporangiophores, each one with a peltate structure, the scutellum, bearing five-six sessile sporangia attached to the axis of strobilus by the manubrium. Immature sporocytes (spore mother cells) are tightly packed within the young sporangia. The sporocytes quickly undergo meiosis, by passing the stage of archesporium and give origin to tetrads of spores. The tapetum loses histological integrity during early stages of sporogenesis, intrudes as a plasmodial mass into the cavity of the sporangium, partially surrounding premeiotic sporocytes, and then, tetrads and adult spores. The tapetum disintegrates towards the end of the sporogenesis, leaving spores free within the sporangial cavity. Spores present several cytological changes that allow them to achieve greater size and increase the number of plastids, before reaching the adult stage. Sporoderm includes three layers external to the cytoplasmic membrane of the spore cell, and they are pseudoendospore, exospore and perispore. Viewed with SEM, the exospore is smooth to rugulate, with micro perforations, while the perispore is muriform, rugate, with narrow, delicate, discontinuous, randomly distributed folds delimiting incomplete, irregular areolae, externally covered by of different size, densely distributed orbicules. These orbicules are also found all over the external face and margins of the elaters, while the internal face is smooth and lack orbicules. Viewed with TEM, the exospore is a thick layer of fine granular material, while perispore is a thinner layer of dense, separate orbicules. The elaters are composed by two layers of fibrillar material: an inner layer with longitudinally oriented fibrils and an outer, thicker and less dense layer with fibrils transversely fibrils and abundant, external orbicules. It is suggested that the processes of ontogeny and characters of the sporoderm are relatively constant in Equisetum; however, sporogenesis in E. bogotense is synchronous and this condition has been observed so far only in E. giganteum, a tropical genus also found in Colombia.
Los estudios sobre aspectos reproductivos son escasos en Equisetum. Por eso, hemos realizado un análisis detallado del proceso de esporogénesis, desarrollo de las esporas, ultraestructura de procesos que tienen lugar durante la meiosis, formación de la pared esporal, orbículas y eláteres de E. bogotense, en especímenes procedentes del Cauca, Colombia. Los estudios se efectuaron mediante microscopía fotónica, electrónica de transmisión (TEM) y de barrido (SEM). Los estróbilos llevan numerosos esporangióforos maduros, cada uno con un escutelo peltado, unido al eje del estróbilo por el manubrio y portador de 5-6 esporangios sésiles. Los esporocitos experimentan meiosis dando origen a tétradas de esporas. El tapete pierde la integridad histológica en las primeras etapas de esporogénesis y rodea los esporocitos premeióticos, posteriormente a las tétradas y finalmente las esporas inmaduras, que experimentan cambios citológicos y de tamaño antes de alcanzar la etapa adulta. El esporodermo de las esporas adultas de E. bogotense consiste de seudoendosporio, exosporio y perisporio. Vistos con MEB, el exosporio de las esporas adultas es liso a rugulado con microperforaciones y el perisporio es muriforme, rugado, con pliegues delicados, estrechos, discontinuos, que se distribuyen al azar y delimitan aréolas incompletas. Externamente el perisporio está cubierto por orbículas, que se forman también en la cara externa y los márgenes de los eláteres. Vistos con TEM, el exosporio es una capa de material granular fino y el perisporio, una capa mucho más delgada con orbículas discretas. Los eláteres están formados por dos capas de naturaleza fibrilar, orientadas longitudinalmente y transversalmente. La esporogénesis en E. bogotense es sincrónica, similar a la de E. giganteum, otra especie de distribución tropical que también crece en Colombia.
Assuntos
Equisetum/ultraestrutura , Esporângios/ultraestrutura , Esporos/ultraestrutura , Colômbia , Equisetum/classificação , Equisetum/embriologia , Esporângios/embriologia , Esporos/crescimento & desenvolvimentoRESUMO
The sporogenesis and development of gametophytes in Tetracentron sinense Oliv. were studied with light microscopy. The anther has four microsporangia; its primary anther wall consists of an epidermis, an endothecium, one or two middle layers and one glandular tapetum. Simultaneous cytokinesis follows meiosis, forming a tetrahedral tetrad. Mature pollen grains are two-celled at the time of anther dehiscence. Its ovule is anatropous, bitegmic and crassinucellate; the development of the female gametophyte is of the monosporic 8-nucleate Polygonum type. Significantly, some striking features were first found in T. sinense: (1) anther dehiscence occurs soon after the endothecium fibrously thickens and the intersporangial septum degenerates; (2) tapetum degeneration is retarded, persisting up to the stage of two-celled pollen grain; (3) a few cellular events such as the vacuolization and the contraction and deformation of the pollen mother cell (PMC) and microspore are not normal at the PMC, dyad and tetrad stages. The abnormalities during male reproduction might be one of important factors resulting in the poor natural regeneration of T. sinense.
Assuntos
Magnoliopsida/embriologia , Gametogênese Vegetal/fisiologia , Células Germinativas Vegetais/crescimento & desenvolvimento , Pólen/embriologia , Magnoliopsida/citologia , Células Germinativas Vegetais/citologia , Reprodução/fisiologiaRESUMO
Ontogeny of strobili, sporangia development and sporogenesis in Equisetum giganteum (Equisetaceae) from the Colombian Andes. Studies on the ontogeny of the strobilus, sporangium and reproductive biology of this group of ferns are scarce. Here we describe the ontogeny of the strobilus and sporangia, and the process of sporogenesis using specimens of E. giganteum from Colombia collected along the Rio Frio, Distrito de Sevilla, Piedecuesta, Santander, at 2 200m altitude. The strobili in different stages of development were fixed, dehydrated, embedded in paraffin, sectioned using a rotatory microtome and stained with the safranin O and fast green technique. Observations were made using differential interference contrast microscopy (DIC) or Nomarski microscopy, an optical microscopy illumination technique that enhances the contrast in unstained, transparent. Strobili arise and begin to develop in the apical meristems of the main axis and lateral branches, with no significant differences in the ontogeny of strobili of one or other axis. Successive processes of cell division and differentiation lead to the growth of the strobilus and the formation of sporangiophores. These are formed by the scutellum, the manubrium or pedicel-like, basal part of the sporangiophore, and initial cells of sporangium, which differentiate to form the sporangium wall, the sporocytes and the tapetum. There is not formation of a characteristic arquesporium, as sporocytes quickly undergo meiosis originating tetrads of spores. The tapetum retains its histological integrity, but subsequently the cell walls break down and form a plasmodium that invades the sporangial cavity, partially surrounding the tetrads, and then the spores. Towards the end of the sporogenesis the tapetum disintegrates leaving spores with elaters free within the sporangial cavity. Two layers finally form the sporangium wall: the sporangium wall itself, with thickened, lignified cell walls and an underlying pyknotic layer. The mature spores are chlorofilous, morphologically similar and have exospore, a thin perispore and two elaters. This study of the ontogeny of the spore-producing structures and spores is the first contribution of this type for a tropical species of the genus. Fluorescence microscopy indicates that elaters and the wall of the sporangium are autofluorescent, while other structures induced fluorescence emitted by the fluorescent dye safranin O. The results were also discussed in relation to what is known so far for other species of Equisetum, suggesting that ontogenetic processes and structure of characters sporoderm are relatively constant in Equisetum, which implies important diagnostic value in the taxonomy of the group. Rev. Biol. Trop. 59 (4): 1845-1858. Epub 2011 December 01.
Estudios sobre la ontogenia del estróbilo, los esporangios y la biología reproductiva de Equisetum son escasos, por lo tanto, para la especie E. giganteum, se estudiaron estos aspectos en especímenes recolectados a orillas del Río Frío, Santander, Colombia (2 200m). Los estróbilos en diferentes etapas de maduración fueron fijados, deshidratados, embebidos en parafina, seccionados en micrótomo rotatorio y teñidos con safranina O-fast green. Las observaciones se efectuaron mediante un microscopio óptico de alta resolución con contraste diferencial de interferencia (DIC) y microscopio de fluorescencia. Los estróbilos se inician a partir del meristemo apical, tanto en el eje principal como en los laterales, sin diferencias en el proceso de ontogenia y esporogénesis entre estróbilos de diferentes ejes. Sucesivas mitosis y diferenciación celular conducen al crecimiento del estróbilo, y a la formación de los esporangióforos peltados, formados por el manubrio, o porción basal con aspecto de pedicelo, el escutelo, o porción apical aplanada y las iniciales del esporangio, los cuales se diferenciarán para formar la pared del esporangio, los esporocitos y el tapete. No se forma arquesporio y los esporocitos experimentan meiosis para formar tétradas de esporas. El tapete mantiene la integridad histológica hasta la formación de las tétradas y en esa etapa forma un plasmodio que invade la cavidad esporangial la cual rodea parcialmente las tétradas y luego las esporas, y aparecen las cámaras plasmodiales, un término propuesto aquí para las formaciones designadas en inglés "tapetal gaps". La pared del esporangio queda reducida a dos capas celulares: una externa con engrosamientos lignificados en todas las paredes celulares y una interna picnótica. Al finalizar la esporogénesis, el tapete degenera, y las esporas, con exosporio, perisporio delgado, casi membranáceo y eláteres quedan libres en la cavidad esporangial. El esporodermo, los núcleos y nucléolos presentan fluorescencia roja, inducida por coloración con safranina O, mientras que los eláteres y las células de la pared del esporangio presentan autofluorescencia amarillo-naranja.
Assuntos
Equisetum/citologia , Esporângios/citologia , Esporos/crescimento & desenvolvimento , Colômbia , Equisetum/crescimento & desenvolvimento , Meiose , Esporângios/crescimento & desenvolvimentoRESUMO
Sporangia ontogeny and sporogenesis of the lycopodium Huperzia brevifolia (Lycopodiaceae) from the high mountains of Colombia. Huperzia brevifolia is one of the dominant species of the genus Huperzia living in paramos and superparamos from the Colombian Andes. A detailed study of the sporangiums ontogeny and sporogenesis was carried out using specimens collected at 4200m above sea level, in Parque Natural Nacional El Cocuy, Colombia. Small pieces of caulinar axis bearing sporangia were fixed, dehydrated, paraffin embedded, sectioned in a rotatory microtome, and stained using the common Safranin O-Fast Green technique; handmade cross sections were also made, stained with aqueous Toluidine Blue (TBO). The sporangia develops basipetally, a condition that allows observation of all the developmental stages taking place throughout the caulinar axis of adult plants. Each sporangium originates from a group of epidermal cells, axilar to the microphylls. These cells undergo active mitosis, and produce new external and internal cellular groups. The sporangium wall and the tapetum originate from the external group of cells, while the internal cellular group leads to the sporogenous tissue. Meiosis occur in the sporocytes and produce simultaneous types tetrads, each one giving rise four trilete spores, with foveolate ornamentation. During the sporangium ripening, the outermost layer of the wall develops anticlinally, and inner periclinal thickenings and the innermost one perform as a secretory tapetum, which persists until the spores are completely mature. All other cellular layers colapse. Rev. Biol. Trop. 57 (4): 1141-1152. Epub 2009 December 01.
Se describe la ontogenia y la esporogénesis en H. brevifolia, en material recolectado en el Parque Nacional Natural El Cocuy (Boyacá-Colombia) a 4200m de altitud. Los esporangios se desarrollan de forma basípeta sobre el eje caulinar: los iniciales y juveniles se localizan en el ápice y los adultos a maduros, en la base. El desarrollo se inicia a partir de un grupo de células epidérmicas localizadas en las axilas que forman los microfilos con el eje caulinar. Estas células se dividen activamente por mitosis formando una masa celular externa y otra interna. La primera da origen a la pared del esporangio, de varios estratos celulares; de éstos, el estrato externo desarrolla engrosamientos en las paredes anticlinales y en la periclinal interna. El estrato celular interno se diferencia para formar el tapete secretor. Los demás estratos celulares de la pared se degradan durante la maduración del esporangio. La masa celular interna da origen al tejido esporógeno que forma los esporocitos, que experimentan la meiosis I hasta la etapa de díada. La meiosis II concluye con la formación de tétradas, constituidas por esporas en disposición tetraédrica. Las esporas son foveoladas con abertura trilete y son liberadas del esporangio a través de la dehiscencia.