Ultrastructure of the body cavities in juveniles and adults of the appendicularian Oikopleura gracilis (Tunicata,Chordata) suggests how the heart may have evolved in tunicates

The organization of the body cavities is an important morphological trait that can be used for establishing the phylogenetic relationships between different groups of animals. In the present study, the hemocoel and coelomic systems of 10‐hr‐old juveniles and adults of the hermaphroditic oikopleurid Oikopleura gracilis were examined using light and transmission electron microscopy. The trunk hemocoel in 10‐hr‐old juveniles was represented by small clefts containing layers of extracellular matrix of adjacent tissues or interstices with migrating primordial germ syncytium. The wide hemocoel in the tail contained extracellular strands, subdividing the hemocoel into hemal sinuses. In adults, a large hemocoel appeared in the trunk and tail, and also contained extracellular strands. The hermaphroditic gonad was surrounded by its own lining, separating it from the hemocoel. The gamete‐filled cavity in the ovary and testis appeared only at late‐stage gonadogenesis, when the pre‐spawning reduction of syncytium occurred in the gonads. The true coelom in 10‐hr‐old juveniles and adults was represented by the pericardium. The lining of the pericardium consisted of myoepithelial and peritoneal cells. In the myoepithelial cells of 10‐hr‐old juveniles, myofibrils had been formed. The myoepithelial cells of adults had several parallel rows of completely differentiated myofibrils. The substantial reduction of the coelomic and circulatory systems in O. gracilis evidently results from the extreme shortening of ontogeny in appendicularians. Development in O. gracilis from early juvenile to adult involves the following steps, which also suggest how the tunicate heart may have evolved: a single‐layered coelomic sac gives rise to a grooved pericardium with an open hemal sinus (simple heart). In ascidians, this simple heart in turn gives rise to a closed tubular, double‐layered heart–pericardial complex, with a separate pericardial cavity and a closed heart, whose wall is formed by specialized myocardium.     

The effect of inhibitors upon intracellular cyclic AMP levels and chick myoblast differentiation.

The small free-living nematode Caenorhabditis elegans is usually found as a hermaphrodite, but occasionally true males appear in the population. This study provides an account of gonadogenesis in the normal male and in a mutant that is a temperature-sensitive sex transformer.Male and hermaphrodite gonads develop from morphologically identical primordia. The small primordial gonad lies on the ventral side of the worm in the coelomic cavity. The gonadial primordium contains four nuclei at parturition. As this primordium develops in a hermaphrodite, it produces a double-armed, mirror symmetrical gonad that produces first sperm and then eggs. In the male, however, this primordium develops into an asymmetrical structure composed of a ventrally located testis, a loop region, a seminal vesicle, and a vas deferens. The male gonad presents a linear sequence of nuclei in successive stages of spermatogenesis beginning with a mitotic region in the testis, followed by clearly distinguishable stages of meiosis throughout the loop region to the seminal vesicle.A temperature-sensitive sex transformer mutant, tsB202, has been isolated. tsB202 carries an autosomal recessive mutation in linkage group II that at restrictive temperature transforms an XX hermaphrodite into a phenotypic male, complete with a normal male gonad and vestigial external genitalia. These transformed males are classified as pseudomales because they do not exhibit mating behavior. Temperature shift experiments have determined the specific temporal sequences of gonadogenesis, oogenesis, and spermatogenesis. Proper manipulation of the temperature regimen causes the production of intersexes. In one intersex, a male gonad complete with sperm, seminal vesicle, and vas deferens also contains oocytes. In another intersex produced by the complementary temperature shift, a hermaphrodite-shaped gonad develops that produces only sperm and no oocytes.     

Formation and ultrastructural organization of gonads in Oikopleura gracilis Lohmann, 1896 (Urochordata: Appendicularia)

This study deals with the formation and ultrastructural organization of the gonads in a common species of appendicularian, Oikopleura gracilis, from Peter the Great Bay. Light microscopy observations show that the gonads develop from a transparent primordium that is located in the basolateral part of the gonad cavity; the primordium increases in size in the process of development and differentiates into the testis and ovary. The testis is covered by a single layer of ultrastructurally uniform follicular epithelium and contains a population of proliferating male gonocytes. The ovary contains two types of germ line nuclei, which are large polyploid nuclei that belong to the auxiliary cells and small meiotic nuclei of the oocytes. The two nuclei types, together with a common cytoplasm, form a syncytium of the ovary, or the coenocyst. As in the dioecious Oikopleura dioica, the coenocyst of O. gracilis produces naked oocytes that are devoid of a type III follicular membrane. The coenocyst is covered by a single-layered follicular epithelium, in which two cell types can be distinguished ultrastructurally. Thus, the synchronous maturation of sex products in O. gracilis is achieved by the formation of the germ-line syncytium in the testis and the coenocyst in the ovary, which generates a large number of simultaneously ripening oocytes that are competent for fertilization.     

Development and early differentiation of gonad in the european eel (Anguilla anguilla [L.], Anguilliformes,Teleostei): A cytological and ultrastructural study

The structure of the gonad of the European eel (Anguilla anguilla [L.]), an “undifferentiated” gonochoristic teleost, was investigated by transmission electron microscopy from 6–8 cm elvers to 22 cm yellow eels with juvenile hermaphroditic gonads. The pear-shaped gonads of 6–8 cm elvers assume, in 12–15 cm eels, a lamellar shape and enlarge by migration of germ cells, which we refer to as primary primordial germ cells. In the gonads of ∼ 16 cm eels, the primary primordial germ cells multiply, giving rise to clusters of germ cells that have ultrastructural characteristics of the primary primordial germ cells but show giant mitochondria, enlarged Golgi complexes, and round bodies not limited by membranes. We refer to these as secondary primordial germ cells. In 16–18 cm eels, syncytial clones of oogonia interconnected by cytoplasmic bridges are also observed. In 18–22-cm-long eels, the gonads contain primordial germ cells, oogonial clones, early oocyte cysts, single oocytes in early growth stages, and primary spermatogonia. Such germ cells are present in the same cross section where they are either intermingled or are in areas of predominantly female germ cells close to areas with predominantly male germ cells. These gonads are juvenile hermaphroditic and should be considered ambisexual because in larger eels they differentiate either into an ovary or into a testis. Somatic cells always envelop the germ cells following their migration into the gonad. These somatic cells first show similar ultrastructural features and then differentiate either into early Sertoli cells investing spermatogonia, or into early follicular (granulosa) cells investing the early previtellogenic oocytes. In eels ∼ 14 cm long, primitive steroid-producing cells also migrate into the gonad. In the ambisexual gonad they differentiate either into immature Leydig cells in the male areas, or into early special cells of the theca in the female areas. Nerve fibers are joined to the steroid-producing cells. Gonad development and differentiation are also associated with structural changes of the connective tissue characterized by the progressive appearance and deposition of collagen fibrils first in the mesogonadium, then in the gonad vascular region, and then in the germinal region. The collagen-rich areas are massive in the male areas and reduced in the female ones. J. Morphol. 231:195–216, 1997. © 1997 Wiley-Liss, Inc.     

革胡子鲇原始生殖细胞的起源、迁移及性腺分化

革胡子鲇又称埃及胡子鲇,是一种多次产卵类型的硬骨鱼。作者用组织学、组织化学、电子显微镜等方法对革胡子鲇的原始生殖细胞(Primordial germ cells,PGCs)的起源、特征、迁移方式和性腺分化进行了研究。实验结果:PGCs来源于内胚层;PGCs的细胞质中存在着一种与生殖细胞有关的电子致密物--生殖质(Germ plasm);PGCs在迁移过程中有主动迁移的能力;PGCs到达生殖嵴的部位后,与生殖上皮细胞(Epithelisl cells)一起共同形成原始性腺;原始性腺分别逐步向精巢和卵巢分化;生殖质与性腺的分化有密切关系;卵巢的分化比精巢早。       

Genetic control of cell interactions in chimeras

The manufacture of mammalian chimeras by aggregating embryos of different genetic constitutions makes possible the study of the genetic control of cellular interactions during embryonic development. Several different chimeric combinations have been made to study the role of the sex-reversed mutation in gonadogenesis and in gametogenesis. Sex reversed directs the gonad to become a testis and thus renders a SxrXX mouse sterile since gonocytes with two X chromosomes cannot complete gametogenesis in a testis. However, SxrXX gonocytes in the ovary of a female chimera become normal oocytes. The competitive interactions of genetically different melanoblasts in populating hair follicles and of primordial germ cells in populating the gonad have been revealed in chimeras. Chimeras have also been used to rescue inviable teraploid embryos and to permit teteraploid cells to display their differentiative capacities in normal tissue environments. We conclude that the genotype affects the capacity of cells to elaborate and to respond to inductive stimuli at each step in differentiation. The fine tuning of cellular interactions becomes apparent in chimeras made from embryos of different genotype.     

Primordial germ cells originate from the endodermal strand cells in the ascidian Ciona intestinalis

The origin of germ cells in the ascidian is still unknown. Previously, we cloned a vasa homologue (CiVH) of Ciona intestinalis from the cDNA library of ovarian tissue by polymerase chain reaction and showed that its expression was specific to germ cells in adult and juvenile gonads. In the present study, we prepared a monoclonal antibody against CiVH protein and traced the staining for this antibody from the middle tailbud stage to young adulthood. Results showed that positive cells are present in the endodermal strand in middle tailbud embryos and larvae. When the larval tail was absorbed into the trunk during metamorphosis, the CiVH-positive cells migrated from the debris of the tail into the developing gonad rudiment, and appeared to give rise to a primordial germ cell (PGC) in the young juvenile. The testis rudiment separated from the gonad rudiment, the remainder of which differentiated into the ovary. PGCs of the testis rudiment and the ovary rudiment differentiated into spermatogenic and oogenic cells, respectively. When the larval tail containing the antibody-positive cells was removed, the juveniles did not contain any CiVH-positive cells after metamorphosis, indicating that the PGCs in the juvenile originated from part of the larval tail. However, even in such juveniles, positive cells newly appeared in the gonad rudiment at a later stage. This observation suggests that a compensatory mechanism regulates germline formation in C. intestinalis.     

Differentiation of the gonad rudiment into ovary and testis in the solitary ascidian, Ciona intestinalis

In the early juveniles of Ciona intestinalis, primordial germ cells arise on the degenerated mass of the resorbed tadpole tail, and assemble to form a discrete gonad rudiment. The present study elucidated the morphological sequences during differentiation of the gonad rudiment into the testis and ovary. In 11- to 12-day juveniles, the gonad rudiment, an elongate sac, divided into the testicular and ovarian rudiments. The testicular rudiment separated as a round vesicle from the thickened wall of the elongate sac. The original sac, after separation of the round vesicle, developed into the ovary. In the testicular rudiment, germ cells formed a continuous central mass without association of somatic cells, while in the ovarian rudiment, each germ cell was associated with somatic cells within the epithelium composing the wall of the rudiment. In 13- to 15-day juveniles the testicular rudiment changed into branched tubes ending in club-shaped follicles. Cells characterized by many flattened cisternae of rough endoplasmic reticulum (distal cells) constituted the distal wall of each follicle. Spermatogenic cells were freely present in the follicular lumen, but the largest spermatogonia were in contact with the distal cells. Both in the testicular and ovarian rudiments, germ cells entered meiosis in 18-day juveniles. A novel body (periesophageal body) was found just beneath the ventral margin of the esophageal opening. It comprised irregular follicles made up of one cell type whose cytoplasm, filled with round vesicles and Golgi complexes, was suggestive of an endocrine function. Fragments derived from the periesophageal body were present around the developing ovary.     

Sex Differentiation in Meloidogyne incognita and Anatomical Evidence of Sex Reversal

Sex differentiation was studied by examining the cellular structure of gonad primordia extracted from second-stage juveniles developing under different environmental conditions. In female jnveniles, divisions of the two somatic cells of the primordium occurred in mid-sccond stage and resulted in 12 cells. Two of them were differentiated as cap cells, two occupied the anterior central and eight the posterior central part of the V-shaped primordium. The two germinal cells divided at the 6-8 somatic-cell stage of the primordium; i.e., earlier than in any other plant-parasitic nematode. In male juveniles of similar developmental stage, divisions of somatic cells resulted in 10 cells: one cap cell at the posterior tip and nine cells at the anterior part of the rod-shaped primordium. Germinal cells divided at the 6-8 sontatic-cell stage. On the basis of gonad anatomy it was concluded that some female juveniles undergo sex reversal and proceed with further development as males. The degree of expression of intersexual features depends on the period at which sex reversal occurs. Sex reversal at an early period gives rise to males with one testis, almost indistinguishable front true males. Sex reversal at mid-second stage involves degeneration of the nucleus of one of the cap cells resulting in males with an atrophied testis and a well-developed testis. More delayed sex reversal results in males with two testes of approximately equal size. To explain these patterns of development, it is assumed that sex differentiation is hormonally controlled and that the environment influences hormonal balance by affecting gene expression.     

Primordial germ cell-somatic cell partnership: a balancing cell signaling act

Recent studies demonstrate that the normal progression of the germ cell lineage during gonadogenesis involves a delicate balance of primordial germ cell survival and death factors generated by surrounding somatic cells. This balance operates in a different fashion in females and males. The fine tuning primordial germ cell specification in the wall of the yolk sac, migration through the hindgut and dorsal mesentery, and colonization in the urogenital ridges involves the temporal and spatial activation of the following signaling pathways: Primordial germ cell specification involves bone morphogenetic proteins 2, 4 and 8b, and their migration is facilitated by the c-kit receptor-ligand duet. When colonization occurs: (1) neuregulin-beta ligand is expressed and binds to an ErbB2-ErbB3 receptor tyrosine kinase heterodimer on primordial germ cells; (2) Vasa, an ortholog of the Drosophila gene vasa, member of an ATP-dependent RNA helicase of the DEAD (Asp-Glu-Ala-Asp)-box family protein is also expressed by primordial germ cells; (3) Bcl-x (cell survival factor) and Bax (cell death factor) join forces to modulate the first burst of primordial germ cell apoptosis; (4) Cadherins, integrins, and disintegrins bring together primordial germ cells and somatic cells to organize testis and ovary. Information on other inducers of primordial cell survival, such as TER (teratoma) factor, is beginning to emerge.     

Histological study of the development and sex differentiation of the gonad in the European eel

The histological structure of the gonads was studied in yellow eels sampled from a coastal lagoon and from stocks reared in an aquaculture plant showing different sex ratios. Gonad development related to body size rather than to age and underwent an intermediate stage characterized by a structure of an early testis but containing oogonia and oocytes. This gonad was called the Syrski organ and the stage juvenile ambisexual. Ovaries were found in eels from 22–30 cm in length, possibly derived from undifferentiated gonads or from Syrski organs. Fully differentiated testes were found in eels >35 cm, derived from Syrski organs. These observations support the results of previous research. From elvers and in eels up to 15–16 cm in length, growth of the gonadal primordium is due to primordial germ cell migration. In eels > 15 cm multiplication of primordial cells begins. Oogonial clones were found in eels > 18 cm in length, whilespermatogonium B clones were observed in eels >30 cm in length. The dynamics of sex differentiation was different among stocks with different ultimate sex ratios: ovaries were found in shorter eels in stocks with a prevalence of females, in longer eels in stocks with a prevalence of males. This result supports the hypothesis of a metagametic (environmental) sex determination. The somatic cells in contact with germ cells and those in the interstitium appeared early during gonad development and preceded germ cell differentiation. This suggests that somatic cells are the targets of the environmental factors influencing sex differentiation.     

Histological and ultrastructural investigation of early gonad development and sex differentiation in Adriatic sturgeon (Acipenser naccarii,Acipenseriformes, Chondrostei)

Gonad development and sex differentiation from embryos to 594‐day‐old individuals were investigated in farmed Acipenser naccarii using light and transmission electron microscopy. The migrating primordial germ cells first appear along the dorsal wall of the body cavity in embryos 1.5 days before hatching. The gonadal ridge, containing a few primary primordial germ cells (PGC‐1) surrounded by enveloping cells, appears in 16‐day‐old larvae. At 60 days, the undifferentiated gonad is lamellar and PGC‐1 multiply, producing PGC‐2. In 105‐day‐old juveniles, a distinct germinal area with advanced PGC‐2 appears on the lateral side near the mesogonium and the first blood vessels are visible. At 180 days, putative ovaries with a notched gonadal epithelium and putative testes with a smooth one appear, together with adipose tissue on the distal side. In 210‐day‐old juveniles, active proliferation of germ cells begins in the putative ovaries, whereas putative testes still contain only a few germ cells. The onset of meiosis and reorganization of stromal tissue occurs in ovaries of 292‐day‐old individuals. Ovaries with developed lamellae enclosing early oocyte clusters and follicles with perinucleolar oocytes occur at 594 days. Meiotic stages are never found, even in anastomozing tubular testes of 594‐day‐old individuals. Steroid producing cells are detected in the undifferentiated gonad and in the differentiated ones of both sexes. Anatomical differentiation of the gonad precedes cytological differentiation and female differentiation largely precedes that of the male. Gonad development and differentiation are also associated with structural changes of connective tissue, viz. collagen‐rich areas are massive in developing testes and reduced in ovaries. J. Morphol., 2008. © 2008 Wiley‐Liss, Inc.     

Meiotic germ cells antagonize mesonephric cell migration and testis cord formation in mouse gonads

The developmental fate of primordial germ cells in the mammalian gonad depends on their environment. In the XY gonad, Sry induces a cascade of molecular and cellular events leading to the organization of testis cords. Germ cells are sequestered inside testis cords by 12.5 dpc where they arrest in mitosis. If the testis pathway is not initiated, germ cells spontaneously enter meiosis by 13.5 dpc, and the gonad follows the ovarian fate. We have previously shown that some testis-specific events, such as mesonephric cell migration, can be experimentally induced into XX gonads prior to 12.5 dpc. However, after that time, XX gonads are resistant to the induction of cell migration. In current experiments, we provide evidence that this effect is dependent on XX germ cells rather than on XX somatic cells. We show that, although mesonephric cell migration cannot be induced into normal XX gonads at 14.5 dpc, it can be induced into XX gonads depleted of germ cells. We also show that when 14.5 dpc XX somatic cells are recombined with XY somatic cells, testis cord structures form normally; however, when XX germ cells are recombined with XY somatic cells, cord structures are disrupted. Sandwich culture experiments suggest that the inhibitory effect of XX germ cells is mediated through short-range interactions rather than through a long-range diffusible factor. The developmental stage at which XX germ cells show a disruptive effect on the male pathway is the stage at which meiosis is normally initiated, based on the immunodetection of meiotic markers. We suggest that at the stage when germ cells commit to meiosis, they reinforce ovarian fate by antagonizing the testis pathway.     

Genital primordium of the free-living marine nematode Halichoanolaimus sonorus (Chromadoria,Chromadorida)

Summary

The genital primordium of the first stage juvenile (J1) of the free-living marine nematode Halichoanolaimus sonorus (Chromadorida: Selachinematidae) was studied using transmission electron microscopy. The primordium consists of four undifferentiated cells: two primordial germ cells (PGC) 5–6 μm in diameter and two somatic cells. The PGC have a large nucleus with nucleolus. The centriole was detected in close vicinity of the PGC nucleus. Most of the cell mitochondria are in close contact with the nuclear envelope. The mitochondria are interspersed by 0.2–0.3 μm particles of an electron-dense diffuse substance devoid of surrounding membrane. Both PGC are closely attached to each other and to the neighboring somatic cells of the genital primordium. The elongated somatic cells contain nuclei devoid of nucleoli; the cytoplasm is filled with free ribosomes and contains occasional cisternae of rough endoplasmatic reticulum (RER), Golgi bodies, mitochondria, and transparent vesicles. The genital primordium is separated by a narrow space from of the intestine (dorsally) and the somatic muscles (ventrally). The PGC of H. sonorous are devoid of typical P granules known for previously studied nematodes as distinct markers of germ line cell lineage. Perinuclear particles of dense diffuse substance found in PGC of H. sonorous could be considered as germ determinants analogous to P granules.     

Development of the reproductive system of Caenorhabditis elegans

A morphological study of the growth and the development of the reproductive system of the nematode Caenorhabditis elegans has been carried out. When the first stage larva hatches from the egg it contains four primordial gonadial cells. These cells proliferate and form the entire adult reproductive system, consisting of approximately 2500 nuclei, in 45 hr at 25°C. Several distinctive morphological featues of gonadogenesis and early embryogenesis that are recognizable in the compound microscope can be used to chart the development of the nematode. The mature gonad presents a linear developmental axis both temporally and morphologically of the formation of oocytes, fertilization, and the early stages of embryogenesis. The structure of the adult ovary indicates that the cytoplasm of each newly formed oocyte is derived from a common core of cytoplasm within the multinuclear ovary.     

Description of Choleoeimeria duszynskii n. sp. (Apicomplexa: Eimeriidae) from the gallbladder of the Middle Eastern short-fingered gecko Stenodactylus doriae (Blanford) (Sauria: Gekkonidae) in Saudi Arabia

Choleoeimeria duszynskii n. sp. is described from the gallbladder of the Middle Eastern short-fingered gecko Stenodactylus doriae (Blanford) from Salasel, Central region, Saudi Arabia. Oöcysts are ellipsoidal (rarely ovoidal), 23–25 × 16–18 (24 × 17) μm, with mean length/width ratio 1.4. Oöcyst wall is smooth, bi-layered, c.1.0 μm thick. Micropyle, oöcyst residuum and polar granule are absent. Sporocysts are ellipsoidal, 8–10 × 4–6 (9 × 5) μm, with a smooth, colourless sporocyst wall and mean length/width ratio 1.7. Sporozoites are sausage-shaped, with one end slightly pointed, arranged head to tail around sporocyst residuum. Refractile bodies and nuclei are not discernible. The endogenous development is restricted to the epithelium of the gallbladder and bile duct. Meronts are rounded, 12 μm in diameter, containing up to c.15 merozoites. Microgamonts are irregular in shape, 22 × 17 μm, containing a large number of microgametes. Macrogamonts are spherical, 17 μm in diameter, with centrally located nucleus and wall-forming bodies at the periphery.