Yasunori Koya

Multiple Vitellogenins (Vgs) in Mosquitofish (Gambusia affinis): Identification and Characterization of Three Functional Vg Genes and Their Circulating and Yolk Protein Products

Abstract The objectives of this study were to characterize multiple forms of vitellogenin (Vg) in mosquitofish (Gambusia affinis) and to discover the fate of each Vg during its processing into product yolk proteins. Two Vg preparations, with apparent masses of 600 kDa (600 Vg) and 400 kDa (400 Vg), were isolated from the plasma of fish treated with estradiol-17β (E2) by various chromatographic procedures. Immunological analyses verified the presence of two different Vg proteins (600 VgA and 600 VgB) in the 600 Vg preparation and of a single protein in the 400 Vg preparation. Three major yolk proteins (Yps) with apparent masses of 560, 400, and 28 kDa were observed in extracts of ovarian follicles from vitellogenic females. Immunological analyses demonstrated that the 400 Vg underwent no change in native mass after being incorporated into oocytes. The 600 Vgs gave rise to a 28 kDa β′-component and a native 560 kDa Yp, which was heterodimeric in structure, consisting of two types of complexes between phosvitin (Pv) and lipovitellin (Lv) heavy- and light-chains. Full-length cDNAs encoding the 600 VgA, 600 VgB, and 400 Vg were isolated from a liver cDNA library of E2 treated fish. Similar to the zebrafish vg3 gene, the 400 Vg cDNA lacked a Pv domain and was classified as an incomplete or phosvitinless (C-type) Vg. The deduced primary structures of 600 VgA and 600 VgB were complete, and these were categorized as type A and type B Vgs, respectively, according to our recent classification scheme. This is the first report on the characterization of three functional Vg genes and their circulating and yolk protein products in any vertebrate species.

Course of proteolytic cleavage in three classes of yolk proteins during oocyte maturation in barfin flounder Verasper moseri, a marine teleost spawning pelagic eggs

Proteolytic degradation of three classes of vitellogenin-derived yolk proteins (lipovitellin, phosvitin, and β′-component) was quantitatively examined during oocyte maturation in barfin flounder, Verasper moseri, a marine teleost which spawns pelagic eggs. Oocyte maturation takes place over 7 days at a water temperature of 6°C. Morphological changes in maturing oocytes, characterized by increasing size and transparency, occurred markedly during the latter half of oocyte maturation. Lipovitellin, which has a native molecular weight of 410,000 in post-vitellogenic oocytes, was cleaved into 170,000 fragments after the fourth day of oocyte maturation. A quantitative immunological assay showed a decline of total intact lipovitellin content in maturing oocytes of about 74%, corresponding to maturation-associated alterations of its molecular structure. An additional class of yolk protein, β′-component, also decreased in abundance during the same period. Indirect quantification of phosvitin in egg yolk, done by measuring serine content in gel chromatography fractions, demonstrated rapid degradation of this protein from the fourth to fifth day of oocyte maturation. Quantitative analysis of free amino acids in maturing oocytes showed a reverse correlation between the amount of intact forms of these three classes of yolk proteins and the water content of oocytes. All three classes of yolk proteins clearly undergo proteolytic cleavage during the latter half of oocyte maturation, possibly to provide osmotic effectors for oocyte hydration, which increases egg buoyancy, and to ensure an available stock of nutrients usable for early development. J. Exp. Zool. 278:189–200, 1997.© 1997 Wiley-Liss, Inc.

Internal Gametic Association and External Fertilization in the Elkhorn Sculpin, Alcichthys alcicornis

Morphological studies have demonstrated that fertilization in the copulating cottid species, the elkhorn sculpin (Alcichthys alcicornis), in which fertilization previously has been assumed to occur within the females genital tract, occurs externally. In the ovarian cavity of impregnated female fish, a number of spermatozoa were found to have entered the micropyle and a fertilizing spermatozoon had reached the lower end of the micropylar canal, but penetration of the spermatozoon into the ooplasm did not occur until after exposure to seawater. Based on these results and past studies, it is concluded that other cottids now regarded as internally-fertilizing species may also exhibit external fertilization with internal insemination.

Environmental regulation of annual reproductive cycle in the mosquitofish, Gambusia affinis.

To clarify the environmental factors regulating the annual reproductive cycle of the female mosquitofish, Gambusia affinis, a viviparous teleost, histological changes of the ovary in natural population, and laboratory experiments were examined. The results, extending over two years, suggested that ovarian recrudescence is initiated by the rise in temperature during spring and that ovarian regression is caused by the shorter daylength during late summer. The first rearing experiments using four photoperiod-temperature groups to investigate the factors triggering the onset of reproduction revealed that females with regressing ovaries began reproduction with the rise of temperature regardless of the photoperiod during spring. The results of the second experiment using three different temperature groups indicated that vitellogenesis occurred at over 14 degrees C and pregnancy at over 18 degrees C. The third experiment with four photoperiod-temperature groups was arranged to investigate the factors in the cessation of reproduction. Sexually active females ceased vitellogenesis of the next clutch of oocytes due to the shorter daylength regardless of temperatures during late summer; however, temperature seemed to influence the rate of embryo development. The critical photoperiod is estimated at about 12.5 hr. In nature, it is supposed that vitellogenesis starts when the temperature rises to about 14 degrees C, and final maturation of oocytes occurs when the temperature reaches about 18 degrees C during spring. Then, vitellogenesis of the next clutch of oocytes ceases when the daylength becomes shorter than 12.5 hr during late summer; the last gestation proceeds at a rate dependent on the temperature, and finally reproduction ends by the last parturition. J. Exp. Zool. 286:204-211, 2000.

Annual reproductive cycle based on histological changes in the ovary of the female mosquitofish,Gambusia affinis, in central Japan

To clarify the annual reproductive cycle of wild female mosquitofish,Gambusia affinis, in Mie Prefecture, central Japan, changes in ovarian histology were investigated. Female mosquitofish kept in aquaria under constant temperature (25°C) and photoperiod (16L: 8D) conditions produced successive broods at intervals of 22.1±0.46 days (n=7). Between days 0–3 following parturition, females began active vitellogenesis. Between days 3–5, fully grown oocytes matured and were fertilized, and embryonic development began in the follicles. By day 10, as fertilized eggs continued embryonic development, some oocytes at the oil-droplet stage had begun to accumulate yolk globules for the next gestation. Thus, vitellogenesis of the succeeding batch of oocytes overlaps with gestation during reproduction in the mosquitofish. A rearing experiment showed the annual reproductive cycle of mosquitofish breeding in Nagashima to be as follows. Although oocytes had not at that point developed to the yolk globule stage, copulation occurred in February. Females began vitellogenesis in early May, the first pregnancy of the year commencing in mid-May. From mid-May to August, females repeated the gestation cycle (vitellogenesis, maturation, fertilization, pregnancy and parturition) at around one month intervals. In September, oocyte recruitment from the oil-droplet to the yolk globule stage ceased. After the final parturition, the ovaries contained only non-vitellogenic oocytes. Spermatozoa in the ovarian cavity were scare from November to January.

Comparative study on ovarian structures in scorpaenids: possible evolutional process of reproductive mode

The reproductive modes of the Scorpaenidae are extremely varied: oviparity, viviparity, and even spawning of internally fertilized eggs or embryos (zygoparity or embryoparity), as in Helicolenus, are known. The ovarian structure of this family is divided into two types by the arrangement of the stroma and the ovarian cavity. One type is the ovary in which the lamella-like stroma develops from the ovarian hilus located on the dorsal side and where the ovarian cavity is located on the ventral side of ovary, classified as “cystovarian type II-1” by Takano (1989). In the other type, the stroma in the ovary develops radially around the blood circulatory system that traverses the center of the ovary, and then the ovarian cavity surrounds all the ovary, classified as “cystovarian type II-3” by Takano (1989). In the present analysis, previous reports about ovarian structure and the relationship to the reproductive mode of scorpaenids were described, and the ovarian structure of eight genera of Scorpaenidae was examined. The ovary of cystovarian type II-1 is seen only in viviparous genera and is not seen in oviparous genera. However, the cystovarian type II-1 is a general structure in other families of Scorpaeniformes, and this structure could be considered a primitive type of ovary rather than that acquired by the process of evolution from oviparity to viviparity. The ovary of cystovarian type II-3 is seen in all six oviparous genera and the one zygoparous genus examined. The ovary of this type is not found in any other family of teleosts, so it could be a structure originally divided in Scorpaenidae. In the genera having the cystovarian type II-3 ovary, there is a common feature of spawning: a floating egg mass encompassed by the gelatinous material. We postulate that the evolution of reproductive mode in the scorpaenid fishes is as follows: Sebastes and Sebastiscus have a primitive ovary in which viviparity has developed, whereas the genera that spawn a floating egg mass evolved the ovarian structure from primitive type to cystovarian type II-3, and further zygoparity, such as in Helicolenus, evolved from them.

Sex Differentiation and Pubertal Development of Gonads in the Viviparous Mosquitofish, Gambusia affinis

Abstract The ontogenetic development of gonads from embryo to adult was observed histologically in the viviparous teleost, Gambusia affinis. Primordial germ cells (PGCs) appeared in the subendodermal space of the embryo 14 days before birth, and then transferred to the dorsal mesentery to form paired genital ridges 12 days before birth. The PGCs proliferated in the genital ridge, forming gonadal primordia 10 days before birth. All gonadal primordia differentiated to the ovary containing oocytes 2 days before birth, but then redifferentiated to the ovary and testis just after birth. This indicates that the mosquitofish is a juvenile hermaphroditic species. The characteristics of gonadal sex differentiation just after birth were enlargement of the oocytes in females, and invasion of somatic cells from the hilar region to an inner portion of the gonad in males. The paired ovary fused at the basal area 5 days after birth, then on the ventral and dorsal portions, developing into a single ovary 10 days after birth. During this time a single ovarian cavity was formed on the dorsal portion of the ovary. The paired testes fused only at the basal area and became a single testis having two main lobes 10 days after birth. The oocytes gradually developed and began vitellogenesis 100 days after birth, but did not reach maturation until 110 days after birth. Spermatogenic cells formed cysts at 20 days, began meiosis at 70 days, and matured to form sperm balls 90 days after birth. The male fish sexually matured earlier than the female.

Annual changes in serum vitellogenin concentrations in viviparous eelpout, Zoarces elongatus

Vitellogenin of matrotrophic viviparous eelpout (Zoarces elongatus) was purified from estradiol-17 beta (E2) treated immature male sera by gel chromatography and anion exchange chromatography. Isolated vitellogenin has a molecular weight of 540 kDa estimated by gel chromatography. Serum levels of vitellogenin in females were measured during oocyte development and gestation by single radial immunodiffusion. Serum vitellogenin level was low (less than 0.2 mg/ml) during the early vitellogenic period, increased in the late vitellogenic period to a peak level (6.4 +/- 2.1 mg/ml) at the beginning of gestation. After that it rapidly decreased to a low level (0.1 +/- 0.1 mg/ml) during the early gestation period. Levels of vitellogenin remained low throughout the gestation period. Serum E2 levels in females showed increased from 1.3 to 3.0 ng/ml during the late vitellogenic period, and declined to 0.4 ng/ml during the early gestation period. Serum levels of E2 showed good correlation with serum vitellogenin levels, suggesting that the vitellogenin synthesis is controlled by E2 in this species. These results combined with the matrotrophic growth of embryo during gestation suggest that there is a shift in the synthesis of maternal nutritional products for embryos from the yolk to other nutrients.

SPERM STORAGE AND DEGRADATION IN THE OVARY OF A MARINE COPULATING SCULPIN,ALCICHTHYS ALCICORNIS (TELEOSTEI: SCORPAENIFORMES) : ROLE OF INTERCELLULAR JUNCTIONS BETWEEN INNER OVARIAN EPITHELIAL CELLS

The morphology of female sperm storage during the spawning period and the morphology of sperm degradation after the spawning period were investigated by electron microscopy in a copulating teleost, Alcichthys alcicornis. The spermatozoa were maintained in the ovarian cavity, floating in the ovarian fluid during the spawning period. The spermatozoa then degenerated and were phagocytized by macrophages invading the ovarian cavity after the spawning period. In the ovary during the spawning period, horseradish peroxidase used as a tracer revealed tight junctional complexes connecting adjacent cells of the inner ovarian epithelia (ovarian wall epithelium and ovigerous lamella epithelium). This indicates that a compartmentalization of the ovarian cavity occurs during the spawning period. The junctional complexes were breached after the spawning period, as shown by the fact that horseradish peroxidase penetrated the ovarian cavity via the intercellular space between the adjoining ovigerous lamella epithelia. These results suggest that the spermatozoa in the ovarian cavity are isolated from the maternal immune system by the tight junctional complexes between the adjoining inner ovarian epithelia during the spawning period, and then are eliminated by immune cells following the breakdown of the junctional complexes after the spawning period. J. Morphol. 233:153–163, 1997.

Annual reproductive cycle and rate of the spermatogenic process in male mosquitofish Gambusia affinis

The present study investigates the relationship between the annual cycle of testicular development and external environment and the rate of spermatogenesis in the mosquitofish Gambusia affinis based on histological observations of testes. The annual reproductive cycle of the mosquitofish was divided into two periods, i.e., the spermatogenic period (May–October) and resting period (October–April). In the spermatogenic period, the transition from spermatogonia to spermatocytes begins and meiosis actively progresses. In the resting period, the transition from spermatogonia to spermatocytes ceases, meiosis of spermatocytes that already shifted by this period gradually progresses, and a considerable number of sperm balls are produced. Onset of spermatogenesis seems to be related to both a rise in water temperature and a prolonged photoperiod. 5-bromo-2″-deoxyuridine (BrdU) was a useful in vivo marker of DNA synthesizing spermatogenic cells. The results of immunohistochemical detection of injected BrdU indicated that 5 days are needed for the conversion of spermatocytes to spermatids, 5 days for spermatids to spermatozoa, and 10 days for spermatozoa to sperm balls.