Studies on the formation of germ cells in a compound ascidian Botryllus,primigenus oka

Gametogenesis of a compound ascidian Botryllus primigenus was studied histologically. On either side of the zooid (stage 9), in the gonadal space between the epidermis and the atrial epithelium, either a single testis or a complex of an egg follicle and a testis can be formed. The egg follicle consists of a single ovum (occasionally two ova) and its accessory cells and is connected with the atrial epithelium by the follicle stalk. The egg follicle is always accompanied by the brood pouch, a diverticulum of the atrial cavity. The testis is equipped with a vestigial spermiduct and is attached to the atrial epithelium. Buds of stage 8 comprise, besides the developing testes and, egg follicles, loose aggregations of hemoblasts and oocytes of early developmental stages, which are already accompanied by primary follicular cells. Both the oocytes and the primary follicular cells seem to arise from the hemoblasts. The young oocytes are isolated in the gonadal space of the buds nnd are transferred to buds of the succeeding generations until they finally mature. In the bud of stage 3, a compact mass of cells appears, attaching to tbe inner vesicle on either side of the body. It is derived from the hemoblasts lodged there in the preceding generation and presumably also from the circulating hemoblasts. When the cell mass receives a large oocyte derived from the preceding generation, part of the cell mass differentiates into egg envelopes, forming an egg follicle, and a follicle stalk and the remainder into a testis. When the cell mass receives no oocyte, it differentiate as a whole into a testis. In the egg follicle thus formed the outer and inner follicular cells increase in number by mitotic division. Subsequently, initial test cells are derived from the inner follicle by migration across the developing chorion; then they increas2 in number by mitosis. In the testis, meiosis and spermiogenesis take place.     

Viviparous development in Botrylloides (Compound Ascidians)

The mode of sexual reproduction and embryogenesis was compared in 3 species of Botrylloides: B. simodensis, B. lenis, and B. violaceus. In all species, a testis and an egg (occasionally 2 eggs), the former being anterior to the latter, mature in the mantle on either side of a zooid. The egg is surrounded by 2 follicular layers and is attached by a vesicular follicle stalk (oviduct) to the atrial brood pouch. The egg is ovulated into the brood pouch, where it is fertilized and undergoes embryogenesis. The egg of B. simodensis is heavily yolked and measures about 180 μm in diameter. The course of embryogenesis in this species is that typical of ascidians. A mature tadpole larva is produced and shed in about 5 days; then, the mother zooid degenerates. The larva is smallest of the three species and has 8 ampullae. The metamorphosed oozooid bears a single bud on the right side only. Extraembryonic nutrition seems to be very limited. Both Botrylloides lenis and B. violaceus are species which display extreme examples of viviparity. Their eggs are devoid of yolk granules, measuring about 90 μm in diameter in the former species and 60 μm in the latter. The course of embryogenesis is similar in these 2 species. The neurula stage is characterized by a spherical vesicular shape owing to precocious differentiation of the embryonic pharynx, whose ectoderm becomes vacuolated. At the posterior end of the neurula, the mesodermal cells are located in a mass, from which the tail is extended later. In B. lenis, embryogenesis takes about 20 days. At the neurula stage of the embryo, the mother zooid becomes a mantle sac as a result of visceral disintegration. During further embryogenesis, the growth of buds of successive generations in the colony is characteristically arrested. A swimming larva of this species is somewhat larger than that of B. simodensis. It has 14–24 ampullae, and the oozooid carries a single bud on its right side. In B. violaceus, the gestation period lasts for more than a month. At the early gastrula stage of the embryo, the body of the mother zooid fully disintegrates. Only the brood pouch bearing the embryo survives and remains connected with the colonial vascular system. In this species, sexual reproduction does not affect the growth of buds in the colony. The swimming larva is gigantic, being furnished with 24–34 ampullae, and the oozooid always bears 3 buds, 2 on the right side and one on the left side.     

Studies on Japanese botryllid ascidians. II. A new species of the genus Botryllus from the vicinity of Shimoda

Morphology and life history of a new species of the genus Botryllus belonging to the family Botryllidae were described in detail. This ascidian was collected from the stony shore in the vicinity of Shimoda (Shizuoka prefecture, Japan). The arrangement of ovary and testis in this ascidian was the same as that in other species of the genus Botryllus, while the embryo developed in a brood pouch formed from the invagination of peribranchial epithelium, as in the other genus Botrylloides. The processes and features of the allorecognition reaction of this ascidian were observed. The reaction showed the same processes as that in the species of the genus Botrylloides. Therefore, this ascidian has both features of the two genera of the family Botryllidae, which strongly suggests the necessity of reconsidering on the classificatory criteria of botryllid ascidians.     

Xenogeneic rejection among three botryllids (compound Ascidians)

Xenogeneic rejection was observed among colonies of three botryllids, Botryllus scalaris, Botryllus primigenus, and Botrylloides simodensis. Allogeneic recognition occurs in each of these species, but the manner of allogeneic rejection differs among them. We studied xenogeneic rejection reactions among these species under the following conditions: colony contact at natural growing edges, colony contact at artificially cut surfaces, and injection of xenogeneic blood plasma into a vascular vessel. In the first two cases, xenogeneic rejection occurred only in Botryllus primigenus and Botrylloides simodensis. The features of that xenogeneic rejection were similar to those of allogeneic rejection in each of these two botryllids. Injection of xenogeneic blood plasma induced responses similar to those of allogeneic rejection in all three botryllids. It is interesting to note that colonies of Botryllus scalaris never showed any response against injected blood plasma from allogeneic incompatible colonies, unlike the responses seen in colonies of the other two botryllids under the same conditions. On the basis of these results, the relationship between allogeneic and xenogeneic rejection in botryllids is discussed.     

Variation in multiple paternity in natural populations of a free-spawning marine invertebrate

For free-spawning marine invertebrates, fertilization processes control the genetic diversity of offspring. Each egg can potentially be fertilized by a sperm from a different male, and hence genetic diversity within a brood varies with levels of multiple paternity. Yet, few studies have characterized the frequency of multiple paternity in natural spawns. We analysed patterns of multiple paternity in two populations of the colonial ascidian Botryllus schlosseri using microsatellites. Because previous studies have shown that at moderate to high population densities, competition among male-phase B. schlosseri colonies results in the nearest male dominating the paternity of a brood, we specifically tested the effect of population density on patterns of paternity. Paternity was estimated using three multilocus indices: minimum number of fathers, counts of sperm haplotypes, and effective paternity (K(E)). Multiple paternity was evident in more than 92% of the broods analysed, but highly variable, with a few broods displaying unequal contributions of different males. We found no effect of population density on multiple paternity, suggesting that other factors may control paternity levels. Indirect benefits from increasing the genetic diversity of broods are a possible explanation for the high level of multiple paternity in this species.     

Comparative studies on the circulatory system of the compound ascidians,Botryllus, Botrylloides and Symplegma

The circulatory systems of four polystyelids, Botryllus schlosseri, B. primigenus, Botrylloides violaceus and Symplegma reptans, were compared. The palleal buds are connected to the parent zooid by a peduncle and to the colonial vascular system by connecting vessels. The peduncle of S. reptans disappears at an earlier stage of bud development than in B. primigenus; it survives the dissolution of the parent zooid in B. schlosseri and B. violaceus. The connecting vessel is formed by anastomosis between an epidermal outgrowth from the bud and a neighboring colonial vessel, and is characterized by the presence of a sphincter. The number of connecting vessels formed in a palleal bud is three in S. reptans, two in B. primigenus and one each in B. schlosseri and B. violaceus. In each species, the larva has eight rudiments of ampullae. In B. primigenus, the original ampullae degenerate soon after metamorphosis and new ampullae extend from the ventral epidermis of the oozooid. In the other species, the colonial vascular system is derived from the original ampullae. The whole colonial vascular system contracts and expands periodically, with regionally different phases. During each expansion cycle, the sphincter contracts once in B. primigenus and twice in S. reptans. The correlation may be due to blood pressure and the propagation of excitation through the colonial vascular system.     

Remarkable longevity of dilute sperm in a free-spawning colonial ascidian

Many benthic marine invertebrates reproduce by releasing sperm into the sea (free-spawning), but the amount of time that sperm are viable after spawning may have different consequences for fertilization, depending on the type of free-spawner. In egg-broadcasting marine organisms, gamete age is usually assumed to be irrelevant because of the low probability of contact between dilute sperm and egg. However, direct dilution effects might be reduced in egg-brooding free-spawners that filter dilute sperm out of the water column, and sperm longevity may play a role in facilitating fertilization in these taxa. We investigated the effects of time, temperature, and mixing on the viability of naturally released sperm of the colonial ascidian Botryllus schlosseri. Our data indicate that B. schlosseri sperm have a functional life span that is considerably longer than those of the sperm of many other marine invertebrate taxa (half-life of approximately 16 to 26 h), are able to fertilize eggs at extremely low external sperm concentrations (ca. 10(1) sperm ml(-1)), and have a longevity that varies with temperature. It is possible that such prolonged sperm longevity may be achieved by reductions in motility, reactivation of quiescent sperm by chemical cues, or intermittent swimming.     

Development of monoclonal antibodies specific to urochordate intracellular epitopes

Sixteen monoclonal antibodies (MAbs) specific to 2 urochordate genera (Botryllus schlosseri and Botrylloides) intracellular epitopes were generated in mice immunized with a mixture of fresh and paraformaldehyde-fixed cells obtained from animal's blood and cells from dissociated organs. Hybridoma clones were selected by ELISA tests and immunohistochemistry assays on paraffin-embedded animal tissues. Five MAbs were tested for reactions with different zooidal organs and cell compartments; 7 MAbs were tested, separately, on 5 different botryllid colonies (3 Botryllus and 2 Botrylloides). The results revealed high polymorphism. Whereas some of the MAbs recognized, specifically, only part of the botryllid genotypes tested, others recognized only part of the cellular compartments. These MAbs will be used as an important tool in the study of botryllid ascidian immunology and developmental biology, revealing the first wide panel of MAbs specific to urochordate intracellular antigens.     

Egg Envelope Cytodifferentiation in the Colonial Ascidian Botryllus schlosseri (Tunicata)

Abstract The formation and cytodifferentiation of egg envelopes were studied at the ultrastructural level in blastozooids of Botryllus schlosseri. The process was divided into five recognized stages of oogenesis. First, the small young oocytes (stage 1) are contacted by scattered cells (primary follicle cells—PFC) which adhere to the oolemma at several junctional spots. PFC extend all around the growing oocyte, acquire polarity, and form a layer covered externally by a thin basal membrane (stage 2). At stage 3 isolated cells are recognizable between the PFC layer and oocyte. They never form junctions with the oocyte and represent prospective inner follicle cells (IFC) and test cells (TC), the latter being progressively received in superficial depressions in the oocyte. The layer of PFC, which maintains junctions with the oolemma, represents prospective outer follicle cells (OFC). PFC are considered to be the source of the three cellular envelopes because a contribution from mesenchymatous elements was not observed. At the beginning of vitellogenesis (stage 4), the vitelline coat (VC) becomes recognizable as a loose net covering the oocyte and TC. It is crossed by the oocyte microvilli and OFC projections which meet and form numerous small junctional plaques, some of them resembling gap junctions. IFC, VC and TC show marked signs of differentiation with approaching ovulation. OFC differentiate completely before ovulation (stage 5) and are engaged in intense synthesis of proteins which may be transferred and taken by endocytosis into the oocyte for yolk formation. Experiments with injected horseradish peroxidase also revealed that proteins present in the blood may reach the oocyte via the intercellular pathway, overcoming OFC and IFC. The possible roles of all the egg envelopes are discussed.     

Fusion between incompatible colonies of a viviparous ascidian, Botrylloides lentus

Abstract. The mode of allo-recognition among colonies was investigated in a viviparous ascidian, Botrylloides lentus . Each embryo is enveloped by a pouch of epithelial cells (brood pouch), and is brooded in the vascular lumen of the parental colony. That is, the parental colony tolerates the presence of semi-allogeneic conspecifics (embryos) in the vascular system. A rejection reaction occurs when incompatible colonies are brought into contact at their growing edges. The inflammatory rejection reaction is limited to a small area where the tunic of two colonies has partially fused. On the contrary, incompatible colonies fuse and their blood vessels become interconnected with one another, when they are brought into contact at artificially cut surfaces. This mode is the same as those of other viviparous species of Botrylloides, B. fuscus and B. violaceus . A relationship between viviparity and the loss of allo-recognition in the vascular system is suggested.     

Ascidian follicle cells: Multifunctional adjuncts to maturation and development

Ascidians are primitive chordates, subphylum Tunicata, that are sessile filter‐feeding hermaphrodites as adults. Released oocytes are enclosed within a monolayer of follicle cells, a non‐cellular vitelline coat and a monolayer of test cells that cover the egg membrane. Follicle cell structure is distinctive in different groups. They originate from circulating hemoblasts with functional nuclei. They are necessary for germinal vesicle breakdown in several species and may secrete a meiosis‐inducing substance to the oocyte. In some families the follicle cells are necessary for fertilization. Although all ascidians are hermaphrodites, many are not capable of self fertilization. The follicle cells seem to be involved in self, non‐self discrimination. Attachment of sperm to egg involves a sperm surface glycosidase binding to an egg surface glycoside. The primary block to polyspermy involves a glycosidase released by the follicle cells. In one species with direct development, the follicle cells secrete a sticky substance that anchors the embryos in a wave‐swept rocky area; a brooding solitary ascidian with a tadpole larva uses a sticky substance secreted by follicle cells to attach the brood to the atrial chamber. Several species have floating eggs due to buoyancy of their follicle cells, a result of ammonia sequestration in at least one species. Many other marine invertebrates release eggs with attached follicle cells, and all vertebrates ovulate oocytes covered with follicle cells. Comparisons are discussed between these groups and ascidians.     

Morphological organization of the male brood pouch epithelium of Syngnathus abaster Risso (Teleostea, Syngnathidae) before, during, and after egg incubation

The morphological organization of the male brood pouch epithelium of Syngnathus abaster, before, during, and after the breeding period, was observed by light and electron microscopy. Before gestation, the epithelium of the pouch wall was compact and consisted of three kinds of cells: typical epithelial cells (pavement cells), mitochondria-rich cells (MR cells), and, presumably, differentiating MR cells. In this stage, very few capillaries were observed beneath the epithelium. During egg incubation, the capillaries increased in number and size, large intercellular spaces formed among epithelial cells at their basal sides, MR cells were abundant, and differentiating MR cells were only occasionally observed. After incubation, MR cells degenerated by necrosis and apoptosis. The intercellular spaces between the epithelial cells disappeared and the number and size of the capillaries beneath the epithelium decreased. The presence of MR cells during gestation and their degeneration after incubation suggest that these cells play a pivotal role in the physiological functions of the brood pouch. The similar cytological characteristics of syngnathid pouch MR cells and chloride cells of the teleostean gills suggests that the Syngnathidae brood pouch is involved in osmoregulation of the fluid surrounding the developing embryos.     

Role of Vasa, Piwi, and Myc-expressing coelomic cells in gonad regeneration of the colonial tunicate, Botryllus primigenus

In the colonial tunicate, Botryllus primigenus Oka, gonads consist of indifferent germline precursor cells, the primordial testis and ovary, and mature gonads, of which the immature gonad components can be reconstructed de novo in vascular buds that arise from the common vascular system, although the mechanism is uncertain. In this study, we investigated how and what kinds of cells regenerated the gonad components. We found that few Vasa-positive cells in the hemocoel entered the growing vascular bud, where their number increased, and finally developed exclusively into female germ cells. Simultaneously, small cell aggregates consisting of Vasa(-) and Vasa(±) cells appeared de novo in the lateral body cavity of developing vascular buds. Double fluorescent in situ hybridization showed that these cell aggregates were both Piwi- and Myc-positive. They could form germline precursor cells and a primordial testis and ovary that strongly expressed Vasa. Myc knockdown by RNA interference conspicuously lowered Piwi expression and resulted in the loss of germline precursor cells without affecting Vasa(+) oocyte formation. Myc may contribute to gonad tissue formation via Piwi maintenance. When human recombinant BMP 4 was injected in the test vessel, coelomic Piwi(+) cells were induced to express Vasa in the blood. We conclude, therefore, that in vascular buds of B. primigenus, female germ cells can develop from homing Vasa(+) cells in the blood, and that other gonad components can arise from coelomic Vasa(-)/Piwi(+)/Myc(+) cells.     

Permanent Genetic Resources added to Molecular Ecology Resources Database 1 August 2009-30 September 2009

This article documents the addition of 238 microsatellite marker loci and 72 pairs of Single Nucleotide Polymorphism (SNP) sequencing primers to the Molecular Ecology Resources Database. Loci were developed for the following species: Adelges tsugae, Artemisia tridentata, Astroides calycularis, Azorella selago, Botryllus schlosseri, Botrylloides violaceus, Cardiocrinum cordatum var. glehnii, Campylopterus curvipennis, Colocasia esculenta, Cynomys ludovicianus, Cynomys leucurus, Cynomys gunnisoni, Epinephelus coioides, Eunicella singularis, Gammarus pulex, Homoeosoma nebulella, Hyla squirella, Lateolabrax japonicus, Mastomys erythroleucus, Pararge aegeria, Pardosa sierra, Phoenicopterus ruber ruber and Silene latifolia. These loci were cross-tested on the following species: Adelges abietis, Adelges cooleyi, Adelges piceae, Pineus pini, Pineus strobi, Tubastrea micrantha, three other Tubastrea species, Botrylloides fuscus, Botrylloides simodensis, Campylopterus hemileucurus, Campylopterus rufus, Campylopterus largipennis, Campylopterus villaviscensio, Phaethornis longuemareus, Florisuga mellivora, Lampornis amethystinus, Amazilia cyanocephala, Archilochus colubris, Epinephelus lanceolatus, Epinephelus fuscoguttatus, Symbiodinium temperate-A clade, Gammarus fossarum, Gammarus roeselii, Dikerogammarus villosus and Limnomysis benedeni. This article also documents the addition of 72 sequencing primer pairs and 52 allele specific primers for Neophocaena phocaenoides.     

The Ultrastructure of Brood Pouch Formation in Tokophrya infusionum

SYNOPSIS Asexual reproduction in Tokophrya infusionum is by internal budding, whereby a ciliated, motile embryo is formed inside the sessile, non-ciliated parent in a specialized structure, the brood pouch. The process of embryogenesis and brood pouch formation was studied with the electron microscope using synchronized cultures. Reproduction begins with invagination of the pellicle and plasma membrane in the apical region of the adult. Early invagination is characterized by the presence of numerous microtubules beneath the plasma membrane or epiplasmic layer of the invaginating membranes. These microtubules apparently are important in formation of the brood pouch for colchicine blocks embryogenesis during the early stages. When the embryo is completed, it is ejected from the brood pouch thru the birth pore, an opening which is the site of the initial invagination and is present thruout embryogenesis. Theories of brood pouch formation are reviewed and discussed in light of the present investigation.     

Cyclic changes in fine structure of the epithelium lining the ovary of the viviparous teleost,Cymatogaster aggregata (Perciformes: Embiotocidae)

The most striking morphological feature of the ovarian epithelium of Cymatogaster is the presence of intercellular dilations during much of the year. These dilations increase markedly in volume during the several months prior to ovulation and fertilization, and decrease in volume during the months of embryogenesis and gestation. The epithelium then returns to its initial, relatively undifferentiated state. The extracellular material within the dilations likely is synthesized in the cells adjacent to or within the dilations. Apparently most of this material is released into the ovarian lumen when the apicolateral margins of adjacent epithelial cells pull apart; possibly it serves as nutrient for developing embryos. In addition to supporting embryogenesis, the ovarian epithelium also apparently is involved in sperm storage. Sperm are maintained within pockets in the ovarian epithelium for the several months between insemination and fertilization. The cells lining the sperm pocket do not develop the intercellular dilations characteristic of most of the ovarian epithelium, and sperm remain associated only with the sperm pocket cells.     

Eyes absent,a key repressor of polar cell fate during Drosophila oogenesis

Throughout Drosophila oogenesis, specialized somatic follicle cells perform crucial functions in egg chamber formation and in signaling between somatic and germline cells. In the ovary, at least three types of somatic follicle cells, polar cells, stalk cells and main body epithelial follicle cells, can be distinguished when egg chambers bud from the germarium. Although specification of these three somatic cell types is important for normal oogenesis and subsequent embryogenesis, the molecular basis for establishment of their cell fates is not completely understood. Our studies reveal the gene eyes absent (eya) to be a key repressor of polar cell fate. EYA is a nuclear protein that is normally excluded from polar and stalk cells, and the absence of EYA is sufficient to cause epithelial follicle cells to develop as polar cells. Furthermore, ectopic expression of EYA is capable of suppressing normal polar cell fate and compromising the normal functions of polar cells, such as promotion of border cell migration. Finally, we show that ectopic Hedgehog signaling, which is known to cause ectopic polar cell formation, does so by repressing eya expression in epithelial follicle cells.     

In vitro culture of mesenchymal lineage cells established from the colonial tunicate Botryllus primigenus

Body trunks were isolated from juvenile zooids of the Japanese colonial tunicate Botryllus primigenus and cultured in vitro to establish tissue-specific cell lines. Epidermal cells from some explants spread and formed a flat sheet consisting of vacuolated cells. They then dissociated into single cells, and their growth stopped within two weeks. Continuously proliferating cells were established from four explants. After the 20th implantation, nuclear and mitochondrial DNAs were extracted from these cells. The nucleotide sequences of proliferating cell nuclear antigen (PCNA) and mitochondrial large ribosomal RNA (mtlrRNA) completely matched the PCNA and mtlrRNA taken from living colonies of B. primigenus; this shows that the four independently proliferating cells were indeed of the Botryllus origin. One cell line (Bp0306E10) comprised round-shaped cells with a diameter of 8-10 microm. These cells have been cultured in vitro with a doubling time of approximately 24 hours since June, 2003. The BrdU labeling index was approximately 2%. Monoclonal antibodies raised against the cultured cells recognized a 28 kDa polypeptide and stained free mesenchymal cells in vivo. G418-resistant subclonal cells could be established by introducing a tunicate retrotransposon loaded with the neomycin resistance gene into the cells by electroporation. This study is the first to succeed in producing a sustainable cell culture of Botryllus.