Gonadotropic control of ovarian follicle maturation: the two-stage concept and its mechanisms

Most research on the control of oocyte maturation by luteinizing hormone (LH) in teleosts and amphibians has focused on the production and action of maturation-inducing hormone (MIH), the follicular hormone that directly triggers the resumption of oocyte meiosis. However, current information indicates that LH regulates maturation in two stages, and that 'oocyte maturation' can be appropriately described within the broader context of 'ovarian follicle maturation'. During the first stage of maturation the follicle (somatic) cells acquire the ability to produce MIH and the oocyte to respond to MIH (i.e. oocyte maturational competence, OMC), whereas in the second stage the follicle cells produce MIH and, consequently, the oocyte is released from meiotic arrest. A number of factors such as insulin-like growth factor-I, serotonin, and others may mediate or modulate the OMC-inducing action of LH. Like the acquisition of MIH-producing ability, the acquisition of OMC requires activation of the protein kinase A pathway. Two major cellular events associated with OMC acquisition are increases in homologous and heterologous gap junction contacts and in oocyte MIH receptor activity. The increased oocyte MIH receptor activity is presumably associated with OMC acquisition, but the significance of changes in gap junction contacts is at present uncertain. To eliminate inconsistency and ambiguity associated with current terminology we propose that the term, ovarian follicle (or oocyte) maturation be used for teleosts without qualifiers such as 'final' to define the first and second stages of follicular maturation.

Cloning and characterization of a vasa-like gene in rainbow trout and its expression in the germ cell lineage

The origin of germ cells and the molecular mechanisms of primordial germ cell (PGC) determination in teleosts are unclear. Vasa is a member of the DEAD protein family and plays an indispensable role in germ cell determination in Drosophila and Xenopus species. In this study, we isolated and characterized a rainbow trout vasa cDNA as a first step towards understanding the molecular mechanisms of PGC determination and development and to develop a molecular marker to identify the PGCs in rainbow trout. Cloning of vasa cDNA was performed by degenerate- and RACE-PCR. The predicted amino acid sequence of rainbow trout Vasa contained eight consensus sequences for the DEAD protein family and five arginine-glycine-glycine repeats, a common character of known Vasa homologues. Overall amino acid similarity to the Vasa of Drosophila was 79.2%. Whole-mount in situ hybridization of eyed stage embryos (eighty somite stage) revealed that signals were localized to the putative PGCs. In adult rainbow trout tissues, both ovaries and testes contained large amounts of vasa gene transcripts. A reverse transcription-polymerase chain reaction analysis of unfertilized eggs proved that trout vasa is a maternal factor. Although we have not determined whether rainbow trout vasa functions as a germ cell determinant, its limited expression in the germ cell lineage proved that rainbow trout vasa can be used as a marker molecule for PGCs. This marker will make it possible to identify the PGCs or presumptive PGCs in early trout embryos whose germ cells can not be distinguished by morphological characteristics.

Germ cell transplantation as a potential biotechnological approach to fish reproduction

Although the use of germ cell transplantation has been relatively well established in mammals, the technique has only been adapted for use in fish after entering the 2000s. During the last decade, several different approaches have been developed for germ cell transplantation in fish using recipients of various ages and life stages, such as blastula-stage embryos, newly hatched larvae and sexually mature specimens. As germ cells can develop into live organisms through maturation and fertilization processes, germ cell transplantation in fish has opened up new avenues of research in reproductive biotechnology and aquaculture. For instance, the use of xenotransplantation in fish has lead to advances in the conservation of endangered species and the production of commercially valuable fish using surrogated recipients. Further, this could also facilitate the engineering of transgenic fish. However, as is the case with mammals, knowledge regarding the basic biology and physiology of germline stem cells in fish remains incomplete, imposing a considerable limitation on the application of germ cell transplantation in fish. Furthering our understanding of germline stem cells would contribute significantly to advances regarding germ cell transplantation in fish.

Connexin messenger ribonucleic acids in the ovary of Atlantic croaker: molecular cloning and characterization, hormonal control, and correlation with appearance of oocyte maturational competence

Intercellular gap junction channels are composed of connexin (Cx) protein. In the Atlantic croaker ovary, gonadotropin (GtH)-induced oocyte maturational competence is accompanied by an obligatory synthesis of RNA and protein and by the formation of granulosa cell-oocyte gap junctions. However, the GtH control of Cx gene expression in relation to follicular differentiation (including maturational competence) has not been examined in Atlantic croaker or in any other vertebrate species. Moreover, Cx genes and their products have not been characterized in fishes. Therefore, the objectives of this study were to characterize ovarian Cx mRNAs in Atlantic croaker and to determine their regulation by GtH during the acquisition of maturational competence. Polymerase chain reaction was used to amplify Cx cDNA prepared from maturationally incompetent or competent ovaries. Mixed primers for this reaction were based on the high sequence homology of selected regions of known connexins. One major fragment (Cx1) was amplified from incompetent ovary cDNA, and two major fragments (Cx1' and Cx2) from competent ovary cDNA. Sequence analysis showed that Cx1 and Cx1' are identical and that Cx1 and Cx2 have high sequence homology to other Cx cDNAs. A cDNA library made from competent ovaries was screened with Cx1 or Cx2 used as probes. Two cDNAs were isolated: one (Cx1) encoded 282 amino acids (32,693 daltons; Cx32.7), and the other (Cx2) encoded 285 amino acids (32,169 daltons; Cx32.2). Both amino acid sequences showed all key features of Cx. Northern blot analysis showed a negligible level of Cx32.2 mRNA in incompetent ovaries, but a substantial rise in its levels accompanied the GtH induction of maturational competence. However, Cx32.7 mRNA levels in incompetent and competent ovaries were similar. In conclusion, selective activation of the ovarian Cx32.2 gene by GtH seems to occur during the acquisition of oocyte maturational competence.

Developmental and protein kinase-dependent regulation of ovarian connexin mRNA and oocyte maturational competence in Atlantic croaker

The acquisition of oocyte maturational competence (OMC) in ovarian follicles of Atlantic croaker is associated with increased gap junction (GJ) contacts and increased levels of ovarian connexin (Cx) 32.2 mRNA. However, the developmental control of ovarian Cx gene expression and the mechanisms of OMC acquisition are unknown. Ovarian Cx32.2 and Cx32.7 mRNA levels were determined in fish with gonadosomatic indices (GSI; gonad weight-to-body weight ratio) ranging from 0.1 to 13%. The mRNA level for both Cx increased from a low level in previtellogenic ovaries (GSI, <1%) to a peak level during the midstage of ovarian growth (GSI, 6-7%). Levels of Cx32.2 mRNA, but not Cx32.7 mRNA, declined markedly during late ovarian vitellogenic growth (GSI, 7-13%), and increased again upon stimulation of OMC by human chorionic gonadotropin (hCG). These changes in ovarian Cx32.2 mRNA seem to parallel previously reported changes in the incidence of oocyte-granulosa cell GJ during follicular growth and early maturation. In vitro treatment with hCG and protein kinase A (PKA) activators (dbcAMP and forskolin) induced ovarian Cx32.2 mRNA levels and OMC. The effects of hCG were blocked by PKA inhibitors (H89, H7). Protein kinase C (PKC) inhibitors (GF 109207X) had little effect on hCG-induced Cx32.2 mRNA or OMC, whereas PKC activators (PMA) blocked both events. There was no association between changes in Cx32.7 mRNA levels and OMC status in these experiments. In conclusion, changes in Cx32.2 gene expression seem to be involved in the regulation of oocyte-granulosa cell GJ during growth and differentiation of the croaker ovarian follicle. Also, the stimulation of OMC and Cx32.2 mRNA levels by hCG is mediated by PKA-dependent pathways and antagonized by PKC-dependent mechanisms.

Production of germ-line chimeras in rainbow trout by blastomere transplantation

We describe a technique for producing germ-line chimeric rainbow trout, Oncorhynchus mykiss, by microinjection of the isolated blastomeres. FITC-labeled donor cells and non-labeled recipient embryos at various developmental stages between the early blastula and early gastrula stages were used for cell transplantation. The chimera formation rate and the degree of donor cell distribution in recipient embryos were evaluated at both the late gastrula stage (5 days post fertilization (dpf)) and the 40-somite stage (10 dpf). Among the six combinations of developmental stages of donor and recipient embryos, the combination of midblastula (2.5 dpf) donor cells and early blastula (1.5 dpf) recipient embryos gave the highest chimera formation rate and the best distribution pattern of donor cells. Using this combination, chimeric rainbow trout were produced with donor blastomeres from dominant orange-colored mutant embryos and wild-type recipient embryos. Of the 238 chimeric embryos produced, 28 (12%) hatched normally and 14 of the 28 fry (50%) had donor-derived orange body color. To test for germ-line transmission of donor cells, gametes obtained from the matured chimeras were fertilized with gametes from wild-type fish. Of the 19 matured chimeras, 6 (32%) yielded donor-derived orange-colored progeny, in addition to wild-type siblings. The contribution rates of donor cells in the germ-line ranged from 0.3 to 14%. This technique for producing germ-line chimeras should be a powerful tool for cell-mediated gene transfer in rainbow trout. Especially, if body color mutants are used for either donor cells or the host embryos, it will be possible to easily concentrate F1 transgenic embryos derived from transplanted donor cells by body color screening. Mol. Reprod. Dev. 59: 380-389, 2001.

Identification of novel genes associated with molecular sex differentiation in the embryonic gonads of rainbow trout (Oncorhynchus mykiss)

The molecular pathways in embryonic vertebrates leading to gonad formation in each sex are incompletely understood. The purpose of this study was to identify novel genes that could be associated with sex-specific gonadal differentiation in a fish, the rainbow trout (Oncorhynchus mykiss). This study was facilitated by a custom microarray based on 7,671 genes derived from embryonic rainbow trout gonad cDNA libraries and public databases. Gonad samples for total RNA isolation were obtained from pvasa-green fluorescent protein (pvasa-GFP) transgenic rainbow between 300 and 700 degree-days of development post-fertilization. The transgenic fish permitted the collection of gonads from embryonic rainbow trout during the period of molecular sex differentiation in advance of any morphologically distinguishable characteristics of sex. A bioinformatic method was used with the microarray data that looked for strong associations in gene expression patterns between known sex differentiation genes (the target genes) and novel genes (the target-associated genes) previously not allied with sex differentiation in fishes. The expression patterns of representative target genes from both sexes and their target-associated genes were independently confirmed by real-time reverse transcription polymerase chain reaction to support the validity of the bioinformatic method employed. Numerous novel genes were identified in the gonads of embryonic female and male rainbow trout that could be involved in sex-specific differentiation pathways in this fish.

Hormonal Regulation of Vasa-Like Messenger RNA Expression in the Ovary of the Marine Teleost Sparus aurata

The vasa gene is an important maternal regulator of primordial germ cell (PGC) development in both vertebrate and invertebrate models. It is also expressed in the mature gonads, but its role in these tissues is still unclear. In oviparous species, oogenesis is a complex process under hormonal control: estrogens, gonadotropins, and other hormones operate at different stages of oogenesis, regulating meiosis, vitellogenesis, follicle maturation, and egg release. The aim of this work is the determination of a regulative role of hormones controlling oocyte maturation on vasa mRNA expression in the sea bream ovary through a molecular biology approach. By in situ hybridization and reverse transcription-polymerase chain reaction (RT-PCR), reaction (the vasa mRNA in the sea bream ovary was found to be expressed at higher levels in the advanced stages of oocyte maturation. After in vivo hormonal treatment, the effect on ovarian vasa mRNA expression was studied through semiquantitative RT-PCR. The quantification of vasa-like mRNA expression in sea bream ovary demonstrates that estradiol (E2), growth hormone (GH), and the combination of gonadotropin-releasing hormone (GnRH) with GH are able to induce an increase in vasa mRNA expression. In contrast, the treatments with GnRH alone or E2 plus GH significantly decreased vasa mRNA expression. These data suggest a regulative interplay between the vasa gene expression and the endocrine system that controls the oogenesis in the ovary of the sea bream.

Intercellular channels in teleosts: functional characterization of two connexins from Atlantic croaker

Gap junction channels, composed of protein subunits termed connexins, are believed to play a critical role in the process of oocyte differentiation and maturation. We have used the paired Xenopus oocyte assay to characterize functionally two connexin genes, connexin-32.2 and connexin-32.7, recently cloned from the ovary of the Atlantic croaker (Micropogonia undulatus), a species that has emerged as a useful model to study the process of maturation of the ovarian follicle. We have found that, while both connexin proteins were expressed at comparable levels in Xenopus oocytes, only one, connexin-32.2, was functionally competent to induce the formation of intercellular channels. Connexin-32.2 channels exhibited voltage-dependent closure that was similar to, but distinct from that of previously characterized mammalian connexins. In addition, the silent connexin-32.7 was unable to functionally interact with connexin-32.2, either in heterotypic channels or as dominant negative inhibitor. Because connexin-32.2 expression is strikingly regulated during oocyte maturation, these data provide further evidence for a role of intercellular channels in the control of oocyte-follicular cell interactions.

Expression of connexin 43 mRNA and protein in developing follicles of prepubertal porcine ovaries

A major form of cell-cell communication is mediated by gap junctions, aggregations of intercellular channels composed of connexins (Cxs), which are responsible for exchange of low molecular weight (<1200 Da) cytosolic materials. These channels are a growing family of related proteins. This study was designed to determine the ontogeny of connexin 43 (Cx43) during early stages of follicular development in prepubertal porcine ovaries. A partial-length (412 base) cDNA clone was obtained from mature porcine ovaries and determined to have 98% identity with published porcine Cx43. Northern blot analysis demonstrated a 4.3-kb mRNA in total RNA isolated from prepubertal and adult porcine ovaries. In-situ hybridization revealed that Cx43 mRNA was detectable in granulosa cells of primary follicles but undetectable in dormant primordial follicles. The intensity of the signal increased with follicular growth and was greatest in the large antral follicles. Immunohistochemical evaluation indicated that Cx43 protein expression correlated with the presence of Cx43 mRNA. These results indicate that substantial amounts of Cx43 are first expressed in granulosa cells following activation of follicular development and that this expression increases throughout follicular growth and maturation. These findings suggest an association between the enhancement of intercellular gap-junctional communication and onset of follicular growth.

Genetic mapping of the dominant albino locus in rainbow trout (Oncorhynchus mykiss)

Albinism in animals is generally a recessive trait, but in Japan a dominant oculocutaneous albino (OCA) mutant strain has been isolated in rainbow trout (Oncorhyncus mykiss). After confirming that this trait is not due to a tyrosinase gene mutation that causes OCA1 (tyrosinase-negative OCA), we combined the amplified fragment length polymorphism (AFLP) technique with bulked segregant analysis (BSA) to map the gene involved in dominant oculocutaneous albinism. Four AFLP markers tightly linked to the dominant albino locus were identified. One of these markers was codominant and we have it converted into a GGAGT-repeat microsatellite marker, OmyD-AlbnTUF. Using this pentanucleotide-repeat DNA marker, the dominant albino locus has been mapped on linkage group G of a reference linkage map of rainbow trout. The markers identified here will facilitate cloning of the dominant albino gene in rainbow trout and contribute to a better understanding of tyrosinase-negative OCA in animals.

Molecular cloning, tissue distribution, and hormonal control in the ovary of Cx41 mRNA, a novel Xenopus connexin gene transcript

Gap junctions (GJ) are aggregates of intercellular channels, composed of connexin (Cx) protein, between adjacent cells. The vertebrate ovarian follicle contains homocellular (granulosa cell-granulosa cell) and heterocellular (granulosa cell-oocyte) GJ. However, the function of GJ during final oocyte differentiation (maturation) is controversial. The objectives of this study are to reexamine the number and identity of Cx genes that are expressed in the Xenopus ovary, and to examine the potential role of GJ in oocyte maturation by determining the temporal association between changes in ovarian Cx mRNA content and the process of maturation. We used reverse transcriptase-polymerase chain reaction to amplify ovarian cDNA fragments using degenerate Cx primers. We amplified three Cx-like fragments: one was novel and two corresponded to known Cx of Xenopus ovaries (Cx38 and 43). The novel fragment was used to screen an ovarian cDNA library. One positive clone was identified and its nucleotide sequence determined. Its deduced amino acid sequence showed that it corresponded to a novel Cx, Cx41, belonging to the Group II class of Cx. Xenopus Cx41 showed the highest homology to rat Cx37 (65% identity, 80% similarity). Also, the last 10 C-terminal amino acids of Cx41 were identical to those of rat, mouse, and human Cx37. Cx41 transcripts were detected by riboprobe mapping in ovarian somatic cells, heart, leg muscle, liver and eye, but not in brain or in oocytes of any developmental stage. Full-grown follicles incubated in vitro with human chorionic gonadotropin became committed to mature within 1-4 hr, and physical signs of maturation (germinal vesicle breakdown) were seen at 4-5 hr. Significant reductions in the levels of Cx41 and 43, but not 38 transcripts were seen at 4 hr, after oocytes had committed to mature. Thus, if availability of Cx mRNA determines availability of Cx protein and GJ, our results would suggest that irreversible commitment to maturation occurred prior to major declines in follicular GJ during the periovulatory period. The present study is the first to report the presence of at least two hormone-responsive Cx gene transcripts (Cx41 and 43 in Xenopus) in ovaries of a single animal species.

Primordial germ cell migration in the yellowtail kingfish (Seriola lalandi) and identification of stromal cell-derived factor 1

Primordial germ cells (PGCs) are progenitors of the germ cell lineage, giving rise to either spermatogonia or oogonia after the completion of gonadal differentiation. Currently, there is little information on the mechanism of PGCs migration leading to the formation of the primordial gonad in perciform fish. Yellowtail kingfish (Seriola lalandi) (YTK) (order Perciforms) inhabit tropical and temperate waters in the southern hemisphere. Fundamental details into the molecular basis of larval development in this species can be easily studied in Australia, as they are commercially cultured and readily available. In this study, histological analysis of YTK larvae revealed critical time points for the migration of PGCs to the genital ridge, resulting in the subsequent development of the primordial gonad. In YTK larvae at 3, 5, 7 and 10 days post hatch (DPH), PGCs were not yet enclosed by somatic cells, indicating the primordial gonad had not yet started to form. While at 15, 18 and 20 DPH PGCs had already settled at the genital ridge and started to become enclosed by somatic cells indicating the primordial gonad had started to develop. A higher number of PGCs were observed in the larvae at 15 and 18 DPH indicating PGCs proliferation, which corresponds with them becoming enclosed by the somatic cells. Directional migration of PGCs toward the genital ridge is a critical event in the subsequent development of a gonad. In zebrafish, mouse and chicken, stromal-cell derived factor (SDF1) signalling is one of the key molecules for PGC migration. We subsequently isolated from YTK the SDF1 (Slal-SDF1) gene, which encodes for a 98-residue precursor protein with a signal peptide at the N-terminus. There is spatial conservation between fish species of four cysteine residues at positions C9, C11, C34 and C49, expected to form disulphide bonds and stabilize the SDF structure. In YTK, Slal-SDF1 gene expression analyses shows that this gene is expressed in larvae from 1 to 22 DPH and demonstrates distinct spatial localisation in the larvae at 7 DPH. These results provide a platform for further studies into the molecular machinery of PGC migration in yellowtail kingfish, as well as other perciform fish species.

Green Fluorescent Protein As a Cell-Labeling Tool and a Reporter of Gene Expression in Transgenic Rainbow Trout

: Green fluorescent protein (GFP) has been used as an indicator of transgene expression in living cells and organisms. For testing the utility of GFP in rainbow trout, we microinjected fertilized eggs with four types of supercoiled constructs containing two variants of GFP complementary DNA (S65T and EGFP), driven by two ubiquitous regulatory elements, human cytomegalovirus immediate early enhancer-promoter (CMV) and Xenopus laevis elongation factor 1alpha enhancer-promoter (EF1). Green fluorescence was first observed at 3 days postfertilization, when the embryo was in the mid-blastula stage. Fluorescence could be detected mosaically in various types of embryonic cells and tissues of swim-up fry. Both the percentage of fluorescent cells and the fluorescence intensity of GFP-expressing cells on blastoderms, measured with a microscopic photometry system, were highest in CMV-EGFP-microinjected embryos. We conclude that GFP is capable of producing detectable fluorescence in rainbow trout, and can be a powerful tool as a cell marker and reporter gene for cold-water fish, and that analysis of GFP expression in living cells is useful for characterizing the activity of cis-elements in vivo.

Effects of maturation-inducing hormone on heterologous gap junctional coupling in ovarian follicles of Atlantic croaker

A previous ultrastructural study of heterologous (granulosa cell-oocyte) gap junction (GJ) contacts in ovarian follicles of Atlantic croaker suggested that these contacts disappear late during the process of resumption of oocyte meiosis. This observation suggested that, unlike scenarios proposed for a number of other species, uncoupling of GJ is not necessary for the onset of meiotic resumption in croaker follicles. However, the functionality of heterologous GJ contacts and the temporal association between maturation-inducing hormone (MIH)-induced changes in heterologous coupling and resumption of oocyte meiosis have not been examined in Atlantic croaker. These questions were addressed with a cell-cell coupling assay that is based on the transfer of a GJ marker, Lucifer Yellow, from oocytes to granulosa cells. Follicle-enclosed oocytes injected with Lucifer Yellow allowed transfer of the dye into the follicle cell layer, thus confirming that there is functional heterologous coupling between the oocyte and the granulosa cells. Dye transfer was observed in vitellogenic, full-grown/maturation-incompetent, and full-grown/maturation-competent follicles. Treatment of maturation-competent follicles with MIH caused a time-dependent decline in the number of follicles transferring dye. However, although GJ uncoupling in some of the follicles was observed before germinal vesicle breakdown (GVBD, index of meiotic resumption), about 50% of the follicles maintained the ability to transfer dye even after GVBD had occurred. Further, a known GJ inhibitor (phorbol 12-myristate 13-acetate) blocked heterologous GJ within a time frame similar to that seen with MIH but without inducing any of the morphological changes (including GVBD) associated with follicular maturation. In conclusion, uncoupling of heterologous GJ seems insufficient and unnecessary for the onset of meiotic resumption in ovarian follicles of Atlantic croaker.

Hormonal regulation and cellular distribution of connexin 32.2 and connexin 32.7 RNAs in the ovary of Atlantic croaker

The in vitro effects of human chorionic gonadotropin (hCG) on ovarian connexin (Cx) 32.2 and 32.7 RNA levels and ovarian follicle maturation were assessed, and the cellular distribution of Cx transcripts in the ovary was determined. hCG caused a concentration-dependent induction of Cx32.2 RNA, which peaked coincidentally with the appearance of morphological indices of oocyte maturational competence (OMC). Cx32.2 RNA levels declined thereafter in all treatment groups, although this decline was not accompanied by the onset of germinal vesicle breakdown (GVBD) at the lowest hCG concentration used. The levels of Cx32.7 RNA initially declined and subsequently increased to preincubation values after hCG treatment, but these changes were not dependent on hCG concentration. In a separate experiment, the decline in Cx32.7 RNA occurred in the presence or absence of hCG and was prevented by low (physiological) concentrations of estradiol-17beta (E2) or by protein kinase C (PKC) inhibitor, but was enhanced in the presence of high E2 concentrations or of PKC activator. These changes in Cx32. 7 RNA abundance were not associated with any indices of oocyte maturation. In situ hybridization of tissue sections showed the presence of Cx32.2 and Cx32.7 RNA in somatic cells of the ovarian follicle but not in oocytes. Cx32.2 RNA seemed to be present in granulosa and thecal cells, but the assay resolution was insufficient to reliably determine the distribution of Cx32.7 transcript by somatic cell type. In view of earlier findings that Cx32.2-based (but not Cx32.7-based) connexons can form functional homotypic channels, these results indicate that Cx32.2 gene expression in granulosa cells is sufficient for the formation of homologous gap junctions (GJ). Northern blot of RNA extracts from ovulated eggs, which are free of follicle cells, showed the presence of relatively low levels of both Cx RNAs. Thus, it is possible that Cx32.2 is present in oocytes and that it participates in heterologous (homotypic) GJ formation between the oocyte and the granulosa cells. In conclusion, Cx32.2 RNA levels in somatic cells of the ovarian follicle correlated positively with morphological indices of OMC acquisition, but subsequently declined during GVBD. These changes in Cx32.2 RNA may function in the regulation of GJ contacts during follicular maturation.

Cloning and characterization of pejerrey mitochondrial DNA and its application for RFLP analysis

Probes were cloned, characterized, and developed for all regions of the mitochondrial DNA (mtDNA) of pejerrey Odontesthes bonariensis to provide the basis for the study of genetic diversity of South American atherinopsinii and to enable species identification from small amounts of tissue. The mtDNA was extracted from liver and cleaved with Eco RI, producing four fragments (7&middot;4, 3&middot;4, 3&middot;1 and 2&middot;9 kb) which were cloned using pUC118 plasmid vectors. Sequence analysis from both ends of the fragments showed that they encode tRNA (Asp, Phe, and Ser-TGA), 12 S rRNA, cytochrome oxidase (CO) II, NADH 4, 5, and 6, and the d-loop, and that the relative positions of these genes are identical to those in the mtDNA of other teleosts. A comparison of homology with carp mtDNA nucleotide sequences revealed that tRNA (Phe and Ser-TGA) and CO II were relatively conserved, whereas the d-loop region was highly divergent. The cloned mtDNA probes detected mtDNA fragments from about 800 ng of total DNA extracted from liver, muscle, and single embryos of O. bonariensis, and were effective for restriction length fragment polymorphism (RFLP) analysis of Patagonina hatcheri, the most distant atherinopsine relative of pejerrey. The cloned mtDNA probes may be useful for the analysis of genetic diversity and non-destructive species identification, including the examin-ation of eggs, larvae and juveniles. The mtDNA sequences reported here provide the basis for the design of primers for PCR-based RFLP analysis. 1997 The Fisheries Society of the British Isles

Characterization of proopiomelanocortin in the snakeskin gourami (Trichopodus pectoralis) and its expression in relation to food intake

Proopiomelanocortin (POMC) is the precursor of several hormones involved in physiological systems including feed intake. The snakeskin gourami (Trichopodus pectoralis) POMC complementary DNA (TpPOMC) was cloned and characterized. Phylogenetic analysis showed that TpPOMC was clustered in a major POMC lineage in fish. Analysis of the Ka to Ks ratios for the entire POMC sequence and for each hormonal segment suggested that different POMC-derived peptide segments were subject to different evolutionary pressures. High expression level of TpPOMC was observed in all brain regions, with the highest levels in the diencephalon and pituitary gland. In situ hybridization also revealed that TpPOMC-expressing cells were distributed in discrete brain regions. The transcription level of TpPOMC was also found at moderate levels in several peripheral tissues, including gills, liver, head kidney, trunk kidney, stomach, intestine, spleen, ovary and testis, and at a low level in muscle. The expression level of TpPOMC was evaluated in each brain region (telencephalon, mesencephalon, metencephalon, and diencephalon together with the pituitary gland) at 1 h before the first and the last meals of the day and compared with expression levels at a time interval between the first and the last meals of the day. Low expression levels of TpPOMC were found at 1 h before the last meal of the day (P < 0.05). These finding suggest that decreased POMC expression level may lead to reduced melanocyte-stimulating hormones, which may in part be responsible for stimulating food intake. The effect of short-term fasting (24 h) on TpPOMC expression level in each brain region was also investigated. In telencephalon and diencephalon together with the pituitary gland, TpPOMC messenger RNA reached a nadir at 12 h of fasting, whereas TpPOMC transcript showed a nadir at 6 h of fasting in metencephalon and mesencephalon. A peak of TpPOMC level was observed at 18 h of fasting in metencephalon and diencephalon together with the pituitary gland. These findings suggest that TpPOMC expression is affected by nutritional status.

Structural Organization of the Atlantic Croaker Connexin 32.2 Gene and Its 5' Flanking Region

Gonadotropic hormone stimulates the accumulation of connexin (Cx) 32.2 messenger RNA in ovaries of the marine teleost Atlantic croaker. This effect can be mimicked by protein kinase A (PKA) activators and blocked by PKA inhibitors as well as protein kinase C (PKC) stimulators. However, the mechanisms of Cx32.2 gene regulation are unknown. In this study, we determined the structure of the Cx32.2 gene as a first step toward characterizing the regulatory mechanisms of Cx32.2 gene expression. A cosmid library of croaker genomic DNA was screened with a Cx32.2 complementary DNA probe. One positive clone was subcloned and sequenced. The Cx32.2 gene contained two exons and one intron. The first exon contained a portion of the 5' untranslated region (UTR), and the second exon contained the remaining 5' UTR, the amino acid coding region, and the 3' UTR. The distal 5' flanking region also contained a sequence homologous to a different croaker Cx gene, Cx32.7, but it is unclear if this sequence constitutes a pseudogene or an exon of the Cx32.7 gene. The 5' flanking region of the Cx32.2 gene contained two core cyclic AMP response elements (CRE, CGTCA) and one full-consensus activating protein- (AP)-1 binding site (AGTCAG). The distal core CRE was associated with a sequence that enhances CRE activity (GAGC). A third core CRE site was present in the intron. These findings are consistent with the following hypotheses: the induction of ovarian Cx32.2 mRNA levels by gonadotropic hormone is at least partly mediated by CRE-dependent activation of the Cx32.2 gene, and the inhibition of basal and gonadotropic-hormone-stimulated ovarian Cx32.2 mRNA by PKC is due to negative effects on transcription via the AP-1 transcription factor complex. This study is the first to characterize the structure and putative response elements of the 5' flanking region of fish Cx genes.

Cloning and sequencing of cDNAs of the β-globin gene family in carp

A total blood cell cDNA library was constructed using a 3-year-old carp Cyprinus carpio. A β-globin cDNA (CβG1) was identified from the library by the polymerase chain reaction using a β-globin-specific primer deduced from the carp β-globin-A amino acid sequence. Also, five additional types of β-globin cDNAs (CβG2∼6) were isolated by colony hybridization using CβG1 as a probe. Sequence analysis revealed that these CβGs encoded 147 amino acids, and the deduced amino acid sequences showed high identity (89·1-95·2%) to previously reported carp β-globin amino acid sequences. The nucleotide sequences of the CβGs were very similar (identity 96·0-99·6%) and the expression levels of CβG1∼6 were 28·6, 28·6, 21·4, 14·3, 3·6 and 3·6% of the total number of cloned CβGs, respectively. Although the complete amino acid sequence identities between the CβGs and the β-globin of higher vertebrates were low, functionally important regions such as the α-βcontact region and haem contact region were well conserved. These data showed that, as in higher vertebrates, the adult carp has a multiple β-globin gene family (at least six members). However, transcripts encoding four types of peptides (CβG1 type, CβG2 and 3 type, CβG5 type, and CβG4 and 6 type) were expressed at relatively high levels, this being a unique character of the carp haemoglobin system.

Germ cell-specific expression of green fluorescent protein in transgenic rainbow trout under control of the rainbow trout vasa-like gene promoter

A technique to identify and isolate live fish primordial germ cells (PGCs) has not been established, in spite of the importance of purified germ cells for molecular and cellular studies. In rainbow trout, the distribution of vasa transcripts is restricted to the germ cell lineage, making this transcript a useful indicator of PGCs. Therefore, in this study, we cloned and characterized the rainbow trout vasa-like gene (RtVLG) regulatory regions and produced transgenic trout carrying the green fluorescent protein (GFP) gene driven by the RtVLG regulatory regions (p vasa-GFP) in order to identify live PGCs in vivo. In transgenic trout carrying the p vasa-GFP construct, cells showing green fluorescence were first observed at the mid-blastula stage; however, no cell-type-specific expression was observed at this stage. At the eyed stage, about 30% of the transgenic embryos showed specific GFP expression in PGCs, and at the hatching stage, about 70% of the transgenic embryos did so. An immunohistochemical study of hatching stage embryos revealed that the GFP-expressing cells are located in genital ridges. This transgenic trout, having visualizable PGCs, will make it possible to isolate live PGCs for in vitro studies and to study the ontogeny of PGCs including sex differentiation in live embryos.