The ability to distinguish self and nonself components seems to be widespread throughout the animal kingdom (Hildemann and Reddy, 1973; Cooper, 1976). The vertebrates, from the cyclostomes onward, are capable of mounting specific humoral as well as cell-mediated immune responses in defence against invading nonself components. In invertebrates, however, it is only in advanced organisms that recognition of foreignness is followed by selective destruction or elimination of such material, and even then this is accomplished only by means of cell-mediated mechanisms. It is as yet unclear whether invertebrates possess an ability for Fuke, Masako T. 1980. ""CONTACT REACTIONS" BETWEEN XENOGENEIC OR ALLOGENEIC COELOMIC CELLS OF SOLITARY ASCIDIANS." The Biological bulletin 158, 304-315.
The self-sterility ofHalocynthia roretzi from Mutsu Bay, Japan, was examined. This sterility is strict and not a single egg can be fertilized in self-sterile animals. Less than 2% of the animals were self-fertile (with 100% cross-fertility). All heterologous sperm can fertilize all eggs, although there are pairs of individuals in which the coelomocytes recognize each other as self. Eggs deprived of follicle cells cannot be fertilized by either autologous or heterologous spermatozoa. Detached autologous or heterologous follicle cells can reattach to the chorion in calcium-enriched sea water and the reconstituted eggs recover their ability to be fertilized. A "mosaic egg" can therefore be obtained, which consists of oocyte, test cells and chorion originating from one individual and follicle cells from another. The "mosaic egg" was used to determine the site of recognition of self and non-self. The results indicate that the recognition resides in the chorion and/or test cells, probably the chorion. The relationship between somatic alloreactivity, previously found in coelomocytes ofH. roretzi, and gamete reactivity is discussed.
When unfertilized eggs (UFE) of the solitary ascidian, Halocynthia roretzi, are released naturally they are strictly self-sterile, whereas almost all ovarian eggs isolated after spawning are self-fertile. Self-sterile eggs are prepared within a relatively short period of several hours before the spawning. The morphological changes in ovarian eggs during late oogenesis were studied with special reference to the establishment of self-sterility. Four types of eggs at serial developmental stages were classified according to the morphology of their external envelopes. Self-sterility was established in the last stage, from the ovarian egg type 3 (OVE3) to UFE stages. Ovarian eggs which had become committed to UFE were denoted as full-grown ovarian eggs (FOE). FOE were able to differentiate into self-sterile UFE in vitro, whereas OVE3 could not. Several morphological differences between OVE3 and UFE were found. OVE3 had a germinal vesicle (GV), a type of vitelline coat (VC-OVE3) and no expanded perivitelline space, whereas UFE had completed germinal vesicle break down (GVBD), had another type of coat (VC-UFE) and showed an expanded perivitelline space. There were also some differences in the mode of fertilization between OVE3 and UFE. In UFE, sperm became bound firmly to the vitelline coat and passed through the coat with the help of follicle cells, whereas in OVE3, sperm did not bind so strongly and entered the perivitelline space without the aid of follicle cells. The relationships between the establishment of self-sterility and these morphological and functional changes in ovarian eggs are discussed.
The blood cells of a solitary ascidian, Halocynthia roretzi, were examined by electron microscopy (EM) with reference to their appearance by light microscopy (LM). In addition, their movement and stainability by vital dyes was observed by phase‐contrast microscopy, and their stainability by Giemsa was also examined. Nine cell types were recognized: vacuolated cells, hyaline amoebocytes, small amoebocytes, granular amoebocytes, macrogranular cells, globular cells, lymphocyte‐like cells, large basophilic cells and large granular cells. Vacuolated cells were found to possess various numbers of vacuoles containing strongly electron‐dense materials and could be divided into at least three subgroups. Granular amoebocytes contained microfilaments and many granules of uniform size. Hyaline amoebocytes and small amoebocytes seemed to be specialized as phagocytes. Macrogranular cells and globular cells were not well characterized. In the blood of adult individuals, hemoblasts were rarely found, although lymphocyte‐like cells were present. Each of two large cells, large basophilic cells and large granular cells, possessed novel granules or vacuoles, whose functions remain to be elucidated. The possible functions and relationships of these cells among various ascidian species are discussed.
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