[On the nervous system of a parasitic cnidarian Polypodium hydriforme].

Nerve cells in a parasitic cnidarian Polypodium hydriforme at the parasitic and free-living stages of the life cycle have been localized immunocytochemically using antibodies to FMRF-amide, and their ultrastructure has been described. Ganglion cells form a net under epidermis consisting of bi- and tripolar neurons which cross the mesoglea and usually contact muscle cells and cnidocytes. Fusiform sensory and neurosecretory cells, especially characteristic to sensory tentacles, are interspersed among epidermal cells. All three types of nerve cells have dense cored vesicles about 80-120 nm in diameter. The sensory cells demonstrate a sensory flagellum-like immobile structure. Neurosecretory and sensory cells form septate junctions with epidermal cells. Ganglion cells show gap junctions between them. A centriole encircled by a fragment of nuclear envelope which is a marker of ectodermal lineage cells in Polypodium has been described in the cytoplasm of a sensory cell, thus proving the ectodermal nature of the nervous system.

Muscular system of a peculiar parasitic cnidarian Polypodium hydriforme: a phalloidin fluorescence study.

Musculature of the free-living stages of Polypodium hydriforme has been studied using phalloidin fluorescence method and confocal microscopy. P. hydriforme is a unique cnidarian possessing only smooth muscle cells situated within the mesoglea, not epithelial muscle cells, like the rest of cnidarians. Phalloidin fluorescence on whole mount preparations demonstrates an extensively developed subepidermal muscle system mostly consisting of long parallel fibers running along the tentacles. For the first time along with contracted muscle fibers we could clearly demonstrate relaxed fibers looking as long spirals. System of thin parallel circular F-actin positive fibers has been discovered outside of longitudinal muscles. The body of the animal and the mouth cone contain weakly developed parallel muscles. No special attachment of the muscle fibers to the tips of the tentacles or to the rim of the mouth has been observed. The results are discussed in connection with the "triploblastic" organization of P. hydriforme and its phylogenetic position.

[Cytomorphological characteristics of Polypodium hydriforme and problems of myxozoan and cnidarian phylogeny].

The present review analyses cytomorphological characters of the parasitic cnidarian Polypodium hydriforme, discriminating between those of bilateral (triploblastic) animals, common characters shared with the Myxozoa, and the unique characters of this species. Phylogenetic position of the group of parasitic cnidarians and of the class Polypodiozoa is discussed. A conclusion is made that the cytomorphological characters as well as 18S rDNA analysis of P. hydriforme and Myxozoa justify establishment of a new taxonomic group (a clade) of parasitic cnidarians (Endocnidozoa) uniting Polypodiozoa and Myxozoa (Zrzavý, Hypsa, 2003). The unique characters of P. hydriforme suggest that the phylum Cnidaria is more diverse than commonly supposed, and that P. hydriforme is not an aberrant cnidarian species but a relic organism, which might originally belong to the cnidarian class Polypodiozoa, which underwent reduction in the course of adaptation to parasitism.

[Amoebocytes in mesoglea of Polypodium hydriforme]. / Amebotsity v mezoglee u Polypodium hydriforme.

Mesogleal amoebocytes of free-living Polypodium hydriforme have been studied with transmission electron microscope. The amoebocytes have numerous processes and contain cytoplasmic vacuoles with fibrous material of different density. The phenomenon of cell death (apoptosis) of mesogleal amoebocytes is described. Chromatin of dying cells becomes condensed forming picnotic "caps" in the nucleus. No mitotic cells were encountered among mesogleal amoebocytes. The origin and functions of mesogleal amoebocytes of P. hydriforme are discussed.

[Cytological aspects of similarity and difference of Myxozoa and Cnidaria]. / Tsitologicheskie aspekty skhodstva i razlichiia miksosporidii i knidarii.

A comparative cytomorphological analysis of Myxozoa and parasitic Cnidaria Polypodium hydriforme has been carried out in view of the Weill (1938) hypothesis, which regards Myxozoa as a reduced Cnidaria. The question on the relation of Myxozoa and Cnidaria was arising several times with the application of some new methods during the Myxozoa studies. At present the idea on their phylogenetic relationships has appeared again in connection with an absolutely new understanding of the myxozoan life cycle (Wolf, Markiw, 1984), as well as with the application of molecular-biological methods for their phylogenetic studies. The latter, however, provided some diverse results. So far no comparative cytomorphological analysis of Myxozoa and Polypodium has been carried out. The present paper is to fill the gap on the basis of accumulated facts. According to Weill (1938), the features of similarity of parasitic Cnidaria and Myxozoa are the following: 1) the presence in both of extrusomes (nematocysts and polar capsules) whose structure and development are surprizingly similar; 2) the nuclear dimorphism and somato-generative segregation; 3) the presence of a somatic nutritional cell, surrounding the multiplying generative cells; at present it is known that polyploidy of somatic nuclei and the absence of parasitophorous vacuole are characteristic of trophamnion of Polypodium and trophozoite of Myxozoa; 4) the presence of radial symmetry in both groups; 5) the construction of a diblastic organism made of a cluster of endodermal cells and a few ectodermal cells; 6) the similarity of their cell contacts (Grassé, 1970). At present it is possible to add to Weill's (1938) list of features common for parasitic Cnidaria and Myxozoa the number of important similarities between Polypodium and Myxozoa, some of which being not characteristic of Cnidaria: 1) the "cell in cell" organization of all Polypodium parasitic stages and all Myxozoa life cycle stages; 2) the presence of gametophore supplied with extrusomes; 3) both organisms have haplophase in their life cycles preceded by two-step meiosis; 4) there are mitochondria with tubular cristae in both organisms; 5) the absence of spermatozoa and eggs in both organisms; 6) the similarity of Polypodium cnidocile structure and the cone-like formation situated at the anterior end of polar capsule of actinospore (Lom. Dykova, 1997); 7) the participation of MTOC in the formation of extrusomes in both animals. In spite of the obvious similarity between Myxozoa and parasitic Cnidaria (including Polypodium) it is, however, necessary to take into account differences between them, the main being as follows: the absence in Myxozoa of flagellated stages, centrioles, tissues and organs, true blastophylla, planula-like larvae, gastrulation; the presence of low cell integrations in Myxozoa; Cnidaria and Myxozoa have different types of mitosis, their life cycles and the discharge mechanism of their stinging apparatus being also different. We consider as quite valid a suggestion by Siddall et al. (1995) that parasitic Cnidaria could present an early separated branch of the cnidarian evolution. Further studies of Myxozoa life cycle may show their more definite relation to parasitic Cnidaria. The problem has not yet been solved completely since the available molecular-biological data are rather contradictory and moreover there is no distinct idea as to the Eumetazoa ancestor so far. A further thorough investigation is badly needed in the feelds of developmental cycle, cytomorphology and molecular biology of the variety of narcomedusae and representatives of Myxozoa. This may help to find some transitional forms and stages of the animals and to understand whether we deal with a regressive evolution of parasitic Cnidaria or with a parallel evolution of taxa originated from the common ancestor.

Life cycle, cytology, and morphology of Polypodium hydriforme, a coelenterate parasite of the eggs of acipenseriform fishes.

Polypodium hydriforme is the only coelenterate adapted to intracellular parasitism in oocytes of acipenserid and polyodontid fishes. It occurs in both the Old and the New worlds, being parasitic in 12 species of Acipenseridae and in 1 species of Polyodontidae. Its earliest parasitic stages are binucleate cells that occur in previtellogenic oocytes. All embryonic and postembryonic development (which seems to be parthenogenetic) up to the budding stolon stage takes place inside fish oocytes and lasts several years. The planula and stolon have inverted germ layers. All parasitic stages are encircled with a highly polyploid unicellular trophamnion that is homologous to the second polar body. Before spawning, eversion of the stolon takes place inside the oocyte. At spawning, the everted stolons get into water and the free-living phase of the life cycle begins. The stolon fragments into individual specimens that can move and feed. They multiply by longitudinal fission (paratomy). In mid-summer they form 2 kinds of endodermal gonads. The so-called "female" gonads (2 ovaria, each with a gonoduct encircled with a common envelope) produce diploid cells that display no meiotic phenomena. The so-called "male" gonads have no gonoducts, but their sex cells undergo 2 meiotic divisions, giving rise to binucleate cells with unequal nuclei. The entire gonad becomes a gametophore with an ectodermal lid carrying nematocysts and containing many binucleate cells. Gametophores can be deposited onto the skin of prelarvae of fishes. How the parasite gets into young fish oocytes is not known.

Peculiarities of the embryonic development of Polypodium hydriforme Ussov (Coelenterata), a parasite of acipenserid oocytes.

"Unicellular" stages (107 specimens) and multicellular stages (64 specimens) of embryogenesis of Polypodium, found in 14 sterlet (Acipenser ruthenus L.) females, have been studied with light microscopy, cytophotometry, and autoradiography following incubation with 3H-uridine. All stages of the embryonic development occur inside host oocytes. The "unicellular" stage includes a binucleate cell with unequally sized nuclei; separation inside it of a small cell around the smaller nucleus, i.e. transformation of the single cell into a complex of 2 cells, the larger one enveloping the smaller; formation of a cavity inside the nucleus of the large (outer) cell, and migration of the small cell into it, and "cell-in-a-cell" stage, the small (generative) cell being inside the cavity formed by the nucleus of the large (trophic) cell. The latter gives rise to a hypertrophied but still unicellular envelope around the embryo, the trophamnion. The multicellular stages start with segmentation of the generative cell into blastomeres. These form a morula lying inside the cavity of the trophamnion. Gastrulation occurs by morular delamination. The inversion of the germ layers, typical of parasitic Polypodium stages, apparently arises during gastrulation. Both the generative cell ("egg") and the blastomeres are haploid, at least until the morula stage. The eggs of Polypodium are the smallest ones among coelenterates; they lack yolk and develop without fertilization. Diploidy seems to be restored during segmentation. The trophamnion cell grows, its nucleus becomes highly polypoid, and its cytoplasm accumulates mucoprotein inclusions. Both the blastomere nuclei and the trophamnion nucleus have large nucleoli and actively synthesize RNA. The stages of embryogenesis of Polypodium closely correspond to stages of the host oogenesis. The embryonic development of Polypodium lasts several years and is the slowest among coelenterates. However, it has some features typical of the class Hydrozoa.

[Cytological paradoxes in the developmental cycle of the coelenterate Polypodium hydriforme--an intracellular parasite from the oocytes of acipenserid fishes]. / Tsitologicheskie paradoksy v tsikle razvitiia kishechnopolostnogo Polypodium hydriforme--vnutrikletochnogo parazita iz ootsitov osetrovykh ryb.

Successive stages of the embryonic development of Polypodium hydriforme, occurring at the parasitic phase of its life cycle, are considered. The development of a new parasitic generation starts without fertilization, i. e. parthenogenetically. The embryo develops from aberrant binucleate gametes formed in the result of meiosis within entodermal gonads of free-living animals. This type of gametogenesis, earlier considered as spermatogenesis (Raikova, 1961), is now interpreted as oogenesis. A conclusion is drawn about a change of the sexual orientation of the male gonad which becomes a female one in the course of evolution of Polypodium. As to the gonads of free-living animals, which were formerly interpreted as female ones, they seem to be abortive rudimentary organs since they produce no mature sex cells. A long-lasting block of cytokinesis of the 2nd meiotic division, as well as utilization of the polar body of this division as a phorocyte and, later, as a trophamnion, are important adaptations of Polypodium to parasitism. It is the larger nucleus with a voluminous cytoplasm, rather than the smaller nucleus, that becomes here the 2nd polar body. Polypodium differs from other coelenterates by the presence of highly polyploid feeding cells at both the parasitic (the trophamnion, 500 c) and free-living phases of the life cycle (trophocytes in the rudimentary female gonad, 8c-32c).

Morphology, ultrastructure, and development of the parasitic larva and its surrounding trophamnion of Polypodium hydriforme Ussov (Coelenterata).

The larval stage of Polypodium hydriforme is planuliform and parasitic inside the growing oocytes of acipenserid fishes. The larva has inverted germ layers and a special envelope, the trophamnion, surrounding it within the host oocyte. The trophamnion is a giant unicellular provisory structure derived from the second polar body and performing both protective and digestive functions, clearly a result of adaptation to parasitism. The trophamnion displays microvilli on its inner surface, and irregular protrusions anchoring it to the yolk on its outer surface. Its cytoplasm contains long nuclear fragments, ribosomes, mitochondria, microtubules, microfilaments, prominent Golgi bodies, primary lysosomes, and secondary lysosomes with partially digested inclusions. The cells of the larva proper are poorly differentiated. No muscular, glandular, neural, interstitial, or nematocyst-forming cells have been found. The entodermal (outer layer) cells bear flagella and contain rough endoplasmic reticulum; the ectodermal (inner layer) cells lack cilia and contain an apical layer of acid mucopolysaccharid granules. The cells of both layers contain mitochondria, microtubules, and Golgi bodies; their nuclei display large nucleoli with nucleolonema-like structure, decondensed chromatin, and some perichromatin granules. At their apical rims, the ectodermal cells from septate junctions; laterally, the cells of both layers form simple contacts and occasional interdigitations. The lateral surfaces of entodermal cells are strengthened by microtubules.

The parasitic coelenterate, Polypodium hydriforme USSOV, from the eggs of the American acipenseriform Polyodon spathula.

No significant differences in macro- and micromorphology were found between the parasitic stolon and free-living polyps of Polypodium sp. obtained from infected eggs of the North American acipenseriform fish Polyodon spathula and corresponding developmental stages of Polypodium hydriforme Ussov, parasitic in the Volga sterlet (Acipenser ruthenus). Therefore, both the American and the European forms of Polypodium belong to the species P. hydriforme Ussov.

Amplified ribosomal DNA in meiotic prophase oocyte nuclei of acipenserid fishes.

In situ hybridization has been performed in sections through ovaries ofAcipenser ruthenus andAcipenser güldenstädti in order to detect the rDNA sequences. Hybridization resulted in specific labelling of the "caps" of extrachromosomal DNA present in pachytene oocyte nuclei and of the chromatin granules distributed beneath the nuclear envelope in early diplotene nuclei. In the same sections, the nuclei of all ovarian cells in both species (oogonia, leptotene, and zygotene stage oocytes, follicular cells, connective tissue cells) showed a very low, but similar labelling.Amplification of genes for rRNA thus occurs at the pachytene stage in early oogenesis ofAcipenseridae. No rDNA amplification could be detected in the previous stages.

Evolution of the nucleolar apparatus during oogenesis in Acipenseridae.

Evolution of the nucleoli has been followed during oogenesis in the Acipenserid fishes, Acipenser ruthenus (the sterlet) and A. guidenstadti (the sturgeon) using light and electron microscopes. In the ovaries of adults, the oogonial nuclei usually have a single nucleolus with an adjacent mass of paranucleolar fibrillar material. The cytoplasm of the oogonia contains two dense bodies peculiar only to gonocytes, one being electron dense and containing RNA and the otherbeing electron-lucent and lacking RNA...

[Incorporation of H3-thymidine into the oocytes of a sterlet in the early meiotic prophase]. / Vkliuchenie H3-timidina v ootsity rannei profazy meioza sterliadi

DNA synthesis in meiotic oocytes of the sterlet (A. ruthenus) has been studied during early prophase stages using H3-thymidine. The pattern of H3-thymidine incorporation is similar to that in oocytes of Amphibia and Osteichthyes. In the oogonia as well as in the leptotene and zygotene oocytes, the label is predominantly localized over chromosomes. An intensive incorporation of H3-thymidine into the material of the heterochromatic "cap" has been observed during pachytene. Thus, the main synthesis of extra DNA in the sterlet oocytes occurs during pachytene. No DNA in synthesized by the diplotene oocytes.