Small subunit ribosomal RNA sequence links the myxospore stage of Henneguya mississippiensis n. sp. from channel catfish Ictalurus punctatus to an actinospore released by the benthic oligochaete Dero digitata.

There are more than 200 species of Henneguya described from fish. Of these, only three life cycles have been determined, identifying the actinospore and myxospore stages from their respective hosts. Two of these life cycles involve the channel catfish (Ictalurus punctatus) and the freshwater oligochaete Dero digitata. Herein, we molecularly confirm the life cycle of a previously undescribed Henneguya sp. by matching 18S ribosomal RNA (rRNA) gene sequence of the myxospore stage from channel catfish with the previously described actinospore stage (Aurantiactinomyxon mississippiensis) from D. digitata. Gill tissue from naturally infected channel catfish contained pseudocysts restricted to the apical end of the primary lamellae. Myxospores were morphologically consistent with Henneguya spp. from ictalurid fishes in North America. The spores measured 48.8 ± 4.8 µm (range = 40.7-61.6 µm) in total spore length. The lanceolate spore body was 17.1 ± 1.0 µm (14.4-19.3 µm) in length and 5.0 ± 0.3 µm (4.5-5.5 µm) in width. The two polar capsules were 6.2 ± 0.4 µm (5.8-7.0 µm) long and 5.0 ± 0.3 µm (4.5-5.5 µm) wide. The polar capsule contained eight to nine coils in the polar filament. The two caudal processes were of equal length, measuring 31.0 ± 4.1 µm (22.9-40.6 µm). The 1980-bp 18S rRNA gene sequence obtained from two excised cysts shared 99.4% similarity (100% coverage) to the published sequence of A. mississippiensis, an actinospore previously described from D. digitata. The sequence similarity between the myxospore from channel catfish and actinospore from D. digitata suggests that they are conspecific, representing alternate life stages of Henneguya mississippiensis n. sp.

Morfología y anatomía de ejes caulinares, licofilos y esporangios de Phlegmariurus phylicifolius: un aporte a la sistemática de las Lycopodiaceae neotropicales / Morphology and anatomy of caulinar axes, lycophylls and sporangia of Phlegmariurus phylicifolius: a contribution to the systematics of Neotropical Lycopodiaceae

Phlegmariurus is the only genus of Lycopodiaceae with the species grouped in 22 informal groups. Species level relationships within Phlegmariurus are poorly understood and their circumscriptions require a thorough molecular and morphological review. A detailed study of morphology and anatomy of caulinar axes, lycophylls and sporangia of Phlegmariurus phylicifolius was carried out in order to contribute to the elucidation of species circumscription in the informal group Phlegmariurus phlegmaria. Small pieces of caulinar axes bearing trophophylls, sporophylls and sporangia were fixed, dehydrated, Histowax (paraffin) embedded, sectioned in a rotatory microtome, and stained using the common Safranin O-Fast Green technique; handmade cross sections were also made and stained with the same technique. P. phylicifolius includes slender, pendulous plants up to 40cm long. Shoots heterophyllous, in the basal divisions ca. 10-20(-25)mm in diameter including the trophophylls, then abruptly constricted to (l-) 1.5-2(-2.5)mm in diameter including the imbricate, reduced sporophylls. Trophophylls are borne in alternating whorls of three, or decussate, subdecussate, or alternate, widely spaced in alternate leaved caulinar axes portions, perpendicular to the caulinar axes to falcately ascending, lanceolate to linear-lanceolate, with flat to slightly revolute margins. Each lycophyll is supplied by a single central vascular bundle, connected to a protoxylem pole in the stele. At the site of leaf-trace departure, no leaf (lycophyll) gap is present. Caulinar axes excluding leaves 0.7-1.2mm thick at the base, upward tapering to ca. 0.5mm. Caulinar axes present unistratified epidermis and endodermis, the cortex is characterized by the presence of a trabecular structure of lisigenous origin formed in the parenchimatous tissue next to the endodermis. The vascular tissue occupies the central part of the caulinar axes, forming a plectostele of subradiate organization, with five poles of protoxylem. The epidermal cells present sinuous anticlinal walls; invaginations in the inner side of external periclinal wall of the epidermal cells could be probably adaptive morphological feature of a water deficient environment. Leaves of constricted terminal divisions are decussate, or subdecussate, continuously or discontinuously sporangiate, appressed, abaxially rounded to carinate, widely lanceolate to widely ovate or subcordate, acute to mucronate or cuspidate, shorter than the sporangia. Each sporangium originates from a group of epidermal cells, axilar to the sporophylls. The cell walls of epidermal cell of the sporangia are Huperzioideae type. The morphological studies of trophophylls contribute to confirm the differences between P. phylicifolius and P. subulatus. Rev. Biol. Trop. 62 (3): 1217-1227. Epub 2014 September 01.

Phlegmariurus es el único género de Lycopodiaceae con las especies reunidas en 22 grupos informales. Las relaciones a nivel de especie dentro de Phlegmariurus están pobremente estudiadas y la circunscripción de las mismas requiere profundos exámenes moleculares y morfológicos. Se ha llevado a cabo un estudio detallado de la morfología y la anatomía de ejes caulinares, licofilos y esporangios de P. phylicifolius, con el fin de contribuir al esclarecimiento en la delimitación de las especies en el grupo Phlegmariurus phlegmaria. Segmentos de ejes caulinares con trofofilos, esporofilos y esporangios fueron fijados, deshidratados, incluidos en Histowax (parafina), cortados con un micrótomo rotatorio y coloreados usando la técnica tradicional Safranina O-Verde Rápido; además se hicieron cortes a mano alzada y se colorearon con la misma técnica. P. phylicifolius incluye plantas colgantes y péndulas de hasta 40cm de longitud. Los ejes son heterofilos, de aproximadamente 10-20(-25)mm de diámetro en las divisiones basales incluyendo los trofofilos, luego abruptamente reducidos a (l-) 1.5-2(-2.5)mm de diámetro incluyendo los esporofilos reducidos e imbricados. Los trofofilos están dispuestos en anillos alternantes de a tres, o decusados, subdecusados o alternos, dispuestos en forma espaciada en los ejes caulinares, perpendiculares al tallo hasta falcadamente ascendentes, lanceolados a lineal-lanceolados, con márgenes lisos o levemente revolutos. Cada licofilo está provisto de un haz vascular simple y central, conectado a un polo de protoxilema de la estela y sin laguna foliar. Los tallos poseen un ancho de 0.7-1.2mm en la base, excluyendo los licofilos, estrechándose hasta cerca de 0.5mm hacia el ápice. Los ejes caulinares presentan una epidermis uniestratificada y endodermis, la corteza se caracteriza por la presencia de una estructura trabecular de origen lisígeno formada en el tejido parenquimático próximo a la endodermis. El tejido vascular ocupa la parte central del eje caulinar, formando una plectostela de organización subradiada, con cinco polos de protoxilema. Las células epidérmicas presentan paredes anticlinales sinuosas; las invaginaciones en la cara interna de la pared periclinal externa podrían ser probablemente un característica morfológica adaptativa a un ambiente con períodos de sequía. Las hojas de las porciones apicales son decusadas o subdecusadas, con esporangio de disposición continua o discontinua, adpresas, abaxialmente redondeadas a carinadas, ampliamente lanceoladas a ovadas o subcordadas, ápice agudo a mucronado o cuspidado, más corto que el esporangio. Cada esporangio se origina de un grupo de células epidérmicas, en la axila de los esporofilos con el eje caulinar. Las paredes celulares de las células epidérmicas del esporangio son de tipo Huperzioideae. El estudio de la morfología de los trofofilos contribuye a confirmar las diferencias entre P. phylicifolius y P. subulatus.

Ontogenia de los esporangios, formación y citoquímica de esporas en licopodios (Lycopodiaceae) colombianos / Ontogeny of the sporangium, spore formation and cytochemistry in Colombian Lycopodials (Lycopodiaceae)

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.

Coniochaetidium zulianensis: a new record in the world

Basado en un estudio de hongos coprofílicos en el estado Zulia, Venezuela, una especie de la familia Coniochaetaceae, la cual presenta un ascocarpo tipo cleistotecio y ascósporas con poro germinativo, fue aislada de heces de paloma. Ésta fue identificada como una especie del género Coniochaetidium Malloch and Cain., la cual difiere de las otras cinco (5) especies descritas, en sus características morfológicas, presenta 8 esporas, ascas globosas y ascósporas elipsoidales. Además difiere de las otras porque las ascósporas desarrolladas en medios de cultivo son más largas, casi el doble de largo. La especie fue identificada como Coniochaetidium zulianensis Delgado, Urdaneta y Piñeiro, la cual representa un nuevo registro en el mundo.

On the basis of a study of coprophilous fungi from Zulia state, Venezuela, one specie of the family Coniochaetaceae, with cleistothecial ascocarp and ascospores with germ pore was isolated from dove dung. It was identified as species of Coniochaetidium Malloch and Cain. The species described in this paper differs from the other five (5) species in its morphological characteristic, globose asci, 8 spored and ellipsoidal ascospores, also this species differs from another by having larger ascopores, which are nearly double its length in culture. The species was identified as Coniochaetidium zulianensis Delgado, Urdaneta and Piñeiro, which represents a new record in the world.

What can spores do for us?

Many organisms have the ability to form spores, a remarkable phase in their life cycles. Compared with vegetative cells, spores have several advantages (e.g. resistance to toxic compounds, temperature, desiccation and radiation) making them well suited to various applications. The applications of spores that first spring to mind are bio-warfare and the related, but more positive, field of biological control. Although they are often considered metabolically inert, spores can also be used as biocatalysts. Other uses for spores are found in the fields of probiotics, tumour detection and treatment, biosensing and in the "war against drugs".

Gill infection of Leporinus macrocephalus Garavello & Britski, 1988 (Osteichthyes: Anostomidae) by Henneguya leporinicola n. sp. (Myxozoa: Myxobolidae). Description, histopathology and treatment.

Piauçus (Leporinus macrocephalus), were raised in 300 m2 ponds (density of 10 fish/m2) presenting asphyxia signals and daily mortality of 27 fishes. Specimens with 8-cm total body length, were collected for necropsy. Mucus of body surface and pieces of organs were collected and examined microscopically, in wet mounts, stained or in histological sections. The smears examination showed the presence of several spores in the secondary lamellae of the gill filaments, identified as Henneguya leporinicola n.sp (Myxozoa: Myxobolidae). Histopathological study showed epithelial hyperplasia and fulfilling of the spaces between the secondary lamellae, congestion and telangiectasia sinusoidal. It was also observed hyperplasia of the goblet cells and several cysts of parasite with 70.3 microns diameter. Such cysts were situated among the secondary lamellae, covered or not by the hyperplasic epithelium. With this diagnostic, three applications of formalin solution 10 ml/m3 were carried out. Fifteen days after that, fish were examined again to ascertain whether the treatment was efficient on disease caused by the protozoa. The tissue alterations present in the gills after the treatment were just a moderate sinusoidal congestion and a slight epithelial hyperplasia on the base of the secondary lamellae.