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.     

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.     

Tunic phagocytes are involved in allorejection reaction in the colonial tunicate Aplidium yamazii (Polyclinidae, Ascidiacea)

The colonial ascidian Aplidium yamazii exhibited an allorejection reaction when two allogeneic colonies were brought into contact at their growing edges or at artificial cut surfaces. This species has no vascular network in the tunic, unlike the botryllid ascidians, which have a vascular network throughout the colony's common tunic. In the allorejection reaction induced by contact at the growing edges, some small, hard-packed tunic masses were formed at the contact points. Histological and electron microscopic investigation of these tunic masses revealed that they contained aggregates of tunic cells, with tunic phagocytes being the major cell type present. Some of the tunic phagocytes in these tunic masses appeared to be disintegrating. When allogeneic colonies were placed in contact at their artificial cut surfaces, the colonies partially fused, then separated. In this allorejection reaction, some loosely packed tunic masses remained in the gap between the two withdrawn colonies. These results strongly suggest that the tunic phagocytes are likely to be the major effector cells in the allorejection reaction. We also propose that the tunic phagocytes are not only the effector cells in the allorejection reaction but also bear the sites of allorecognition.     

Colonial allorecognition,hemolytic rejection,and viviparity in botryllid ascidians

Allorecognition is a fundamental system that animals use to maintain individuality. Although embryos are usually semiallogeneic with their mother, viviparous animals are required to allow these embryos to develop inside the maternal body, but must also eliminate an "invasion" by nonself. In colonial ascidians of the family Botryllidae, when two colonies are brought into contact at their growing edges, a hemolytic rejection reaction occurs between allogeneic colonies. Morula cells, a type of hemocyte, are the major effector cells in the hemolytic rejection. Morula cells infiltrate and aggregate where the two colonies make contact, and then discharge their vacuolar contents, which contain phenoloxidase and quinones. In viviparous botryllids, colonial contact at artificially cut surfaces always results in colonial fusion and establishment of a common vascular network even between allogeneic colonies in which the growing-edge contact results in rejection. This colonial fusion between incompatible colonies (surgical fusion) suggests that the allorecognition sites are not distributed in the vascular system in which the embryos are brooded. It is supposed that a common ancestor of the viviparous species lost the capacity for allorecognition in their vascular system to protect its embryos from alloreactivity, when it changed from ovoviviparous to viviparous in the course of evolution. The limited distribution of allorecognition sites would be a solution to the embryo-parent histoincompatibility in viviparity.     

Oxidative stress induces cytotoxicity during rejection reaction in the compound ascidian Botryllus schlosseri

When genetically incompatible colonies of the compound ascidian Botryllus schlosseri contact each other, a rejection reaction occurs, characterised by the appearance of cytotoxic foci along the touching borders. In the course of this reaction, morula cells, a common haemocyte-type in ascidians, release their vacuolar content, mainly phenoloxidase and its polyphenol substrata, upon the recognition of soluble factors diffusing from the alien colony through the partially fused tunic. In a previous paper, we demonstrated the relationship between phenoloxidase and cytotoxicity. Here, we investigated the effects of superoxide dismutase, catalase and sorbitol (scavengers of superoxide anions, peroxides and hydroxyl radicals, respectively) on the cytotoxicity observed in haemocyte cultures incubated with heterologous blood plasma. Although the above compounds have no effects on morula cell degranulation and phenoloxidase activity, they suppress cell death, suggesting that oxidative stress plays a key role in in vitro cytotoxicity. In addition, sorbitol reduces the extent of the cytotoxicity occurring in the rejection reaction between incompatible colonies, which stresses the important role of hydroxyl radicals in this process. The observation of a decrease in total and non-protein thiols in haemocytes previously incubated with heterologous blood plasma fits the hypothesis of oxidative stress as the main cause of phenoloxidase-related cytotoxicity.     

Allogeneic inhibition in a compound ascidian, Batryllus primigenus Oka. I. Processes and features of "Nonfusion" reaction

The processes and features of the “Nonfusion” reaction (NFR), a measure positive allogeneic inhibition, in a compound ascidian, Botryllus primigenus, has been studied.The process and the features of NFR have been observed when two incompatible colonies were placed as to make a contact with (1) ampullae to ampullae, (2) ampullae to margin without ampullae, and (3) cut surface to cut surface of the colonies. NFR appeared immediately after fusion of the test matrices of two incompatible colonies. The ampullae have the ability to loosen or dissolve the outer membrane of the test matrix and to penetrate into the other colony. The first response in NFR was the destruction of test cells around the contact area leading to an appearance of filaments around disintegrated test cells. The second reaction was contraction of the ampullae. Distal parts of the ampullae were thus cut off by constriction and necrosis. The contact area between two incompatible colonies was then separated from the healthy parts of both colonies, and NFR was completed.     

A complex allorecognition system in a reef-building coral: delayed responses,reversals and nontransitive hierarchies

A highly polymorphic and complex allorecognition system in the coral Stylophora pistillata was revealed in the field by assaying branch pair combinations among 11 colonies (181 assays) for 24 months. Replicates of between-colony combinations exhibited consistent outcomes, in both time scale and type of response. Different allogeneic combinations exhibited one of two main outcomes, either unilateral rejection, or an array of other incompatible reactions following a state of non-fusion. These responses were partially linked with color morphs (purple dominated yellow). An additional 22 isogeneic grafts resulted in complete fusion. Unilateral rejection occurred 1–7 months following initial contact. Nonfusion usually developed into skeletal suture barriers after 3–9 months, and then into unilateral colony-specific overgrowths at 6–23 months with some reversals in direction at 18–22 months. During this process, small lesions usually developed on the tissue of the subordinate partner, which were either overgrown by the dominant partner or healed. After two years, a network of overgrowths among colonies was established with essentially hierarchial properties, but some nontransitive interactions also occurred. The colonies segregated into three distinct histocompatibility groups; within each group, colonies engaged in nonfusion. Between groups, colonies exhibited nonfusion or rejected each other in a group-specific manner. Based on the results, we discuss the terminology used for fusion versus rejection phenomena in scleractinian corals, the possible genetic background for self-nonself recognition in Stylophora, and the methodological artifacts associated with the use of short-term allorecognition assays. Correspondence to: B. Rinkevich     

Colony specificity and chemotaxis in the compound ascidian Botryllus schlosseri

We re-investigated the behavior of hemocytes during the non-fusion (rejection) reaction between genetically incompatible colonies of the ascidian Botryllus schlosseri. In the course of the reaction, hemocytes - mainly morula cells - crowd inside the blind ends of marginal vascular vessels (known as ampullae) of the colonial leading edge (LE) facing the foreign colony which suggests the occurrence of chemotactic attraction of circulating hemocytes towards the ampullar lumen. Then, cells migrate, through the ampullar tips, into the partially fused tunics and contribute to the formation of the necrotic spots along the contact borders which characterize the reaction. Studies on histological sections clearly indicate that, although morula cell concentration is always higher in ampullae of the LE than in those of the lateral (L) part of the colony, their frequency significantly increases in LE ampullae of rejecting colonies with respect to LE ampullae of both fusing and isolated colonies. In addition, in vitro chemotaxis experiments demonstrated that blood plasma from incompatible colonies can stimulate morula cell migration through polycarbonate filters and this passage is inhibited by antibodies raised against mammalian pro-inflammatory cytokines. The possible nature and role of molecules recognized by anti-cytokine antibodies in hemocyte migration are discussed.     

Mating type of isolates derived from the spermogonial state ofPuccinia coronata var.coronata

Hyphal confrontation between two haploid cultures originating from single basidiospores was used to determine the mating type ofPuccinia coronata var.coronata. Pairs of 15 single-basidiospore cultures were placed approximately 1 mm apart on the medium in all possible combinations. Hyphae of the pairs of colonies came into contact with each other in all combinations approximately two weeks after confrontations. When the nuclear number of hyphal cells in a contact zone was investigated one month after confrontation, monokaryotic hyphae were observed in selfing combination. On the other hand, dikaryotic hyphae were observed in 90.5% of crossing combinations between different cultures. Two isolates are considered compatible if dikaryotic hyphae are present in the contact zone but incompatible if they are absent. The mating type of the fungus was found to be characterized by multiple-allelomorphic tetrapolar incompatibility controlled by the “A” and “B” incompatible factors. Contribution No. 116, Laboratories of Plant Pathology and Mycology, Institute of Agriculture and Forestry, University of Tsukuba     

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 morphology of allograft rejection in Styela plicata (Urochordata: Ascidiacea)

Summary This study identifies three discrete processes responsible for the rejection of tunic tissue transplanted between individuals of the solitary ascidian Styela plicata. The first stage of rejection is characterized by the destruction of blood vascular components within incompatible allografts. In the second phase, dense boundaries of extracellular material are deposited between grafts and the surrounding host tunic, effectively amputating the transplanted tissues. Finally, detached transplants undergo a gradual necrosis which results in the total degeneration of extracellular graft matrices. Of these three phases, the initial cellular depletion of allografts is responsible for the immunological specificity that is characteristic of histocompatibility in S. plicata. The subsequent amputation and necrosis of extracellular graft matrices are taken to be non-specific consequences of the initial cellular reactivity.     

Allogeneic inhibition in a compound ascidian, Botryllus primigenus Oka. II. cellular and humoral responses in "nonfusion"reaction

Involvement of cellular and humoral responses in the “nonfusion” reaction (NFR) in a compound ascidian, Botryllus primigenus, was studied.NFR was irreversible and progressed at the same rate to completion even if one of the incompatible colonies was experimentally removed after NFR had been initiated between them. When two incompatible colonies were placed in a row with another compatible but genetically nonidentical colony between them, a rejection reaction was observed in blood vessels on the central colonies; or between the central colony and either one of the side colonies, which had fused with the central colony later than the other side colonies.It was tentatively supposed that NFR was mediated by an involvement of two types of factors. It was assumed that one was colony-specific, and the other was not necessarily colony-specific. The former was found contained in the test matrix and blood, which upon being introduced into a genetically different and incompatible colony, affected its test cells or granular amoebocytes which were then disintegrated. The latter was released from test cells upon their disintegration causing constriction of the ampullae or of the blood vessels forming an area of necrosis between reciprocally rejecting colonies.     

Allogeneic interactions in Hydractinia: is the transitory chimera beneficial?

The colonial marine hydroid, Hydractinia, exhibits four possible outcomes to allogeneic contacts: passive rejection, aggressive rejection, stable fusion and transitory fusion. In the special case of transitory fusion, Hydractinia colonies undergo tissue fusion, followed by tissue death at the original contact area, and colony separation. This type of rejection is different in several aspects from the rejection process that accompanies incompatible encounters. It has been suggested that in transitory fusion, the colonies gain immediate benefits from fusion, mainly due to size increase, without succumbing to costs associated with fusion (germ line parasitism). We report a long-term observation of repeated fusion and separation cycles in clones featuring transitory fusion that revealed a slow-down of specific growth rates following fusion, and recovery in growth rates following separation. Very rapid transfer of stained material between partners in transitory chimeras provides suggestive evidence that protection against germ line parasitism is far from being guaranteed by separation. Our data cast doubt as to whether the benefits considered for transitory fusion are sustainable and support the already made suggestion that fusion with self, rather than fusion with kin, has been the major selective force governing the evolution of allorecognition in colonial invertebrates.     

Pigmentation and tunic cells in Cystodytes dellechiajei (Urochordata, Ascidiacea)

The tunic of Cystodytes dellechiajei (Poly- citoridae), a colony-forming species of the Ascidiacea that contains biologically active alkaloids, was investigated using light microscopy, laser-scanning microscopy and nuclear magnetic resonance techniques. The colonies contain numerous individual zooids, which are embedded in a common tunic. Each zooid is protected by a firm capsule of overlapping calcareous spicules. The colonies lack blood vessels in the tunic, but six morphologically different types of tunic cells were found: pigment cells, bladder cells, vacuolated filopodial cells, granular filopodial cells, morula cells and granular cells. Rod-like bacteria were found in the tunic matrix. Bladder cells and pigment cells could be identified as storage units for acid and pyridoacridine alkaloids, making the tunic inedible and repelling predators. Filopodial cells have long filopodia, which probably are connected to each other. They may be involved in transportation processes within the tunic tissue. The functions of the morula cells and the granular cells are unknown as yet. With its several specialised cells, the tunic of C. dellechiajei represents a dynamic living tissue containing biologically active compounds. Accepted: 20 September 2000     

Alloimmune memory is absent in the Red Sea hydrocoral Millepora dichotoma

When two allogeneic colonies of the Red Sea hydrocoral Millepora dichotoma (Cnidaria, Hydrozoa) come into tissue contact, one of the genotypes is usually overgrown by the other. The directionality and pace of this alloresponse are thought to be genetically determined. We established tissue contacts between allogeneic colonies in situ in order to elucidate a possible memory component in this response. First-set interactions were established from all possible pairwise combinations between three colonies in eight replicates per combination. Interactions were followed up for 8 weeks. Thereafter, interacting pairs were detached and either regrafted near the original contact area to form second-set assays or challenged by third party grafts. Additional delayed first-set assays was also established. Overgrowth of delayed first-set, second-set, and third-party grafts was followed again for 8 weeks. The mean overgrowths recorded in the second set of the interactions were indistinguishable from the first sets in all three colony combinations. A specific alloimmune memory has not been found in this cnidarian system as opposed to other cases within the phylum.     

An Attempt to Predict Response of Sunflowers to Races of Plasmopara halstedii Using Cultured Sunflower Cells

Cultured sunflower cells reacted alike to inoculation in compatible and incompatible combinations with three races of Plasmopara halstedii, cause of downy mildew. Infection structures formed on the surfaces of cells derived from both resistant and susceptible sunflowers, but no intracellular fungal structures or other signs of penetration were evident in either case. There was no indication of a hypersensitive reaction (rapid death) in cells within 20 h of inoculation in incompatible combinations. The reaction of cells in culture was not like that of intact plants in either compatible or incompatible combinations.     

Effects of allogeneic contact on life-history traits of the colonial ascidian Botryllus schlosseri in Monterey Bay

The formation of chimeric colonies following allogeneic contact between benthic invertebrates may strongly affect colony fitness. Here we show that, in a field population of the colonial ascidian Botryllus schlosseri in Monterey Bay, California, more than 20% of all colonies occur in allogeneic contact with conspecifics. We experimentally assessed the effects of allogeneic contact on the following life-history traits under natural field conditions: growth, age and size at first reproduction, and egg production (fecundity). When compared with isolated colonies, and in some cohorts also with colonies that rejected allogeneic neighbors, colonies that fused with neighbors incurred reduced fitness in terms of most life-history traits measured. We propose that one of the benefits of precise allorecognition is that, in fused colonies, it limits the unit of selection to chimeric individuals composed of closely related kin.     

Tunic abnormalities of the urochordate Halocynthia pyriformis

This paper reports lesions of the tunicate Halocynthia pyriformis, which either grossly resembled supernumerary siphons or appeared as elongate protrusions on the surface of the tunic. The lesions were present on freshly collected animals; they did not develop during maintenance in the laboratory. The siphon-like structures were doughnut-shaped thickenings of noncellular tunic material around a vertical core of necrotic debris; the elongate protrusions were also tubular thickenings of tunic material surrounding a necrotic core. Both types of lesions were extensively infiltrated with blood cells and possibly exfoliated epidermal cells proximal to the necrotic cores, suggestive of an inflammatory response. Bacteria were seen within the debris of the elongate protrusions. These lesions were interpreted as injury and repair responses of the tunic rather than developmental anomalies or neoplasia. Their etiology could not be precisely determined. The bacteria associated with the intracystic debris of the elongate lesions could have been causative or only secondary invaders. Possibly the postulated injury resulted from a chance abrasion, puncture, contact with toxic material, or from a parasite. An intimate association of numerous hydrozoids around the base of the animal and a few on the upper portion of the tunic suggested a plausible explanation of at least some of these lesions. Occasionally, one observed the hydrorhiza of a hydrozoan embedded in the tunic itself; living hydranths were seen extending from these structures. The tunic was thickened in the region of the hydrorhiza, and histological examination of these thickenings showed details quite similar to those reported above. There was a core of necrotic debris and considerable cellular infiltration of the tunic. Probably these lesions represent the result of a primitive cellular immune response of the tunicate against the hydrozoans, or against secondary bacterial infections associated with the presence of the hydrozoans in the tunic.     

The ontogeny of allorecognition in a colonial hydroid and the fate of early established chimeras

Colonies of the marine hydroid, Hydractinia, are able to discriminate between their own tissues and those belonging to unrelated conspecifics. We have studied the ontogeny of this allorecognition system by a series of allogeneic transplantations along a developmental gradient, including two-cell-stage embryos, 8 h morulae, planula larvae and metamorphosed polyps. Allograft acceptance of incompatible tissue was observed in all embryonic and larval stages, whereas metamorphosed polyps rejected incompatible transplanted allografts. Most of the chimeras established at the two-cell-stage, although composed of two allogeneic, incompatible entities with mismatching allorecognition loci, developed normally and remained stable through metamorphosis. The results of post metamorphic transplantation assays among the chimeras and the naive ramets, suggested that both incompatible genotypes were still represented in the chimera despite the onset of alloimmune maturation. The naive colonies always rejected each other. Chimeras established from later embryonic and larval stages did not develop into adult chimeric entities, but rather separated immediately post metamorphosis. We thus show that (1) allorecognition in this species matures during metamorphosis and (2) genetically incompatible entities may coexist in one immunologically mature, chimeric soma, provided that they were grafted early enough in ontogeny.