Naoshi Hiramatsu

Vitellogenin-Derived Yolk Proteins of White Perch, Morone americana: Purification, Characterization, and Vitellogenin-Receptor Binding1

Abstract The objectives of this study were to 1) purify and characterize vitellogenin-derived yolk proteins of white perch (Morone americana), 2) develop a nonisotopic receptor binding assay for vitellogenin, and 3) identify the yolk protein domains of vitellogenin recognized by the ovarian vitellogenin receptor. Four yolk proteins derived from vitellogenin (YP1, YP2 monomer [YP2m] and dimer [YP2d], and YP3) were isolated from ovaries of vitellogenic perch by selective precipitation, ion exchange chromatography, and gel filtration. The apparent molecular masses of purified YP1, YP2m, and YP2d after gel filtration were 310 kDa, 17 kDa, and 27 kDa, respectively. YP3 appeared in SDS-PAGE as a ∼20-kDa band plus some diffuse smaller bands that could be visualized by staining for phosphoprotein with Coomassie Brilliant Blue complexed with aluminum nitrate. Immunological and biochemical characteristics of YP1, YP2s, and YP3 identified them as white perch lipovitellin, β′-components, and phosvitin, respectively. A novel receptor-binding assay for vitellogenin was developed based on digoxigenin (DIG)-labeled vitellogenin tracer binding to ovarian membrane proteins immobilized in 96-well plates. Lipovitellin from white perch and vitellogenin from perch and other teleosts effectively displaced specifically bound DIG-vitellogenin in the assay, but phosvitin and the β′-component could not, demonstrating for the first time that the lipovitellin domain of teleost vitellogenin mediates its binding to the oocyte receptor. Lipovitellin was less effective than vitellogenin in this regard, suggesting that the remaining yolk protein domains of vitellogenin may interact with its lipovitellin domain to facilitate binding of vitellogenin to its receptor.

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.

Gender-specific expression of multiple estrogen receptors, growth hormone receptors, insulin-like growth factors and vitellogenins, and effects of 17β-estradiol in the male tilapia (Oreochromis mossambicus)

Gender-specific expression of estrogen receptors (ER alpha and ER beta), growth hormone receptors (GHR1 and GHR2), insulin-like growth factors (IGF-I and IGF-II) and three vitellogenins (Vgs A-C) was examined in the liver, gonad, pituitary, and brain of sexually mature male, female, and 17 beta-estradiol (E2)-treated male tilapia (Oreochromis mossambicus). Reflecting greater growth rate in male tilapia, hepatic expression of GHR1, GHR2, IGF-I and IGF-II as well as plasma IGF-I levels were higher in males than in females, whereas the expression of Vgs A-C and ER alpha was higher in females. On the other hand, expression of all genes measured was higher in the ovary than in testis. Forty eight hours after E2 injection (5 microg/g) into male fish, hepatic expression of most transcripts measured were altered to levels that were similar to those seen in females. The changes included decreased expression of GHR1, GHR2, IGF-I, and IGF-II, and increased expression of ER alpha and Vgs A-C. E2 treatment also increased Vg and decreased IGF-I in the plasma. Brain expression of ER alpha, ER beta, GHR1, and IGF-I was higher in females than in males, whereas pituitary expression of GHR2 and IGF-I was lower in females; only brain expression of GHR1 was increased by E2 treatment. These findings suggest that E2 stimulates Vg production primarily through activation of ER alpha and down-regulation of the GH/IGF-I axis, thus shifting energy from somatic growth towards vitellogenesis at the level of the liver.

Induction of Three Vitellogenins by 17beta-Estradiol with Concurrent Inhibition of the Growth Hormone-Insulin-Like Growth Factor 1 Axis in a Euryhaline Teleost, the Tilapia (Oreochromis mossambicus)

Abstract The objective of the present study was to utilize the male Mozambique tilapia (Oreochromis mossambicus) as a model for examining the molecular mechanisms that mediate the physiological transition between somatic and gonadal growth in female teleost fish, and in vertebrates in general. Partial cDNAs that encode multiple forms of vitellogenin (Vtg), which is the major precursor of yolk proteins, were cloned from estrogen-treated males and utilized to develop real-time quantitative RT-PCR assays, which were supplemented by an assay for Vtg immunoreactivity in the plasma. Alignment analyses of the amino acid sequences deduced from the vtg cDNAs revealed three distinct tilapia Vtgs, which were categorized as Aa-, Ab-, and C-type Vtgs. A single injection of male tilapias with 17beta-estradiol (E2) at 5 μg/g body weight significantly increased the plasma E2 and hepatic levels of all three vtg transcripts within 1 day. Plasma E2 levels declined after 3 days, whereas the plasma Vtg immunoreactivity and hepatic levels of the three vtg transcripts continued to increase. Hepatic expression of the estrogen receptor (esr) 1 gene, but not the esr2 gene, also increased markedly 1 day after E2 injection and remained elevated for 5 days. While plasma growth hormone (Gh) levels were unaffected, hepatic expression of transcripts that encoded the Gh receptor and insulin-like growth factor 1 (Igf1) was suppressed by E2, as were the plasma Igf1 levels. These results clearly suggest a distinct negative interplay between the growth and reproductive axes at the molecular level of key hepatic regulatory pathways involved in the control of energy utilization by gonadal and somatic growth processes.

Molecular Characterization and Expression of Vitellogenin Receptor from White Perch (Morone americana)

Abstract A full-length (4021 base pair [bp]) cDNA encoding a polypeptide (844 amino acids) with a predicted mass of 93 kDa and other characteristic structural features of a vertebrate vitellogenin receptor (VgR) was isolated from a white perch (Morone americana) ovarian cDNA library. Northern blotting performed using a specific digoxygenin-labeled VgR cDNA probe revealed a distinct ∼4.1 kilobase (kb) hybridization signal in an mRNA preparation obtained from previtellogenic perch ovaries. The deduced amino acid sequence of the perch VgR was 89% and 82% identical, respectively, to that of the tilapia and rainbow trout. Because it possessed an eight-repeat ligand-binding domain (LR8) but lacked an O-linked sugar domain (−), the perch VgR was identified as a non-O-linked form of VgR (LR8−). Unlike the case in other vertebrates investigated, including tilapia and trout, no species of mRNA encoding an O-linked form of VgR (LR8+) could be detected when perch ovarian or liver mRNA reverse transcripts or cDNA libraries were screened by PCR using primer sets flanking the putative O-linked sugar domain. These novel findings call into question the assumptions that an LR8+ splice variant of the VgR always is dominantly present in somatic tissues and exists at lower levels in ovarian tissues to sequester lipoproteins distinct from Vg. A SYBR-green-based real-time reverse transcription-polymerase chain reaction assay was developed and used to quantitatively measure VgR expression in gonadal and somatic tissues, for the first time in any vertebrate. The main site of perch VgR mRNA expression was the ovary and the highest level of VgR mRNA expression was in ovaries whose largest follicles contained previtellogenic oocytes. Expression of VgR mRNA decreased with oocyte growth during vitellogenesis and was very limited in ovulated eggs. These quantitative results verify the concept that growing oocytes must extensively recycle LR8− forms of the VgR.

Conserved and Variant Molecular and Functional Features of Multiple Egg Yolk Precursor Proteins (Vitellogenins) in White Perch (Morone americana) and other Teleosts

Three complete cDNAs encoding different forms of vitellogenin (Vtg) were isolated from a white perch (Morone americana) liver cDNA library and characterized with respect to immunobiochemical and functional features of the three Vtgs and their product yolk proteins (YPs) in this species and in the congeneric striped bass (Morone saxatilis). The two longest cDNAs encoded Vtgs with a complete suite of yolk protein domains that, based on comparisons with vtg sequences from other species, were categorized as VtgAa and VtgAb using the current nomenclature for multiple teleost Vtgs. The shorter cDNA encoded a Vtg that lacked a phosvitin domain, had a shortened C-terminus, and was categorized as VtgC. Mapping of peptide sequences from the purified Vtgs and their derived YPs to Vtg sequences deduced from the cDNAs definitively identified the white perch VtgAa, VtgAb, and VtgC proteins. Detailed comparisons of the primary structures of each Vtg with partial or complete sequences of Morone yolk proteins or of Vtgs from other fishes revealed conserved and variant structural elements of teleost Vtgs with functional significance, including, as examples, signal peptide cleavage sites, dimerization sites, cathepsin D protease recognition sites, and receptor-binding domains. These comparisons also yielded an interim revision of the classification scheme for multiple teleost Vtgs.

Vitellogenin-derived yolk proteins in a hybrid sturgeon, bester (Huso huso x Acipencer ruthenus): Identification, characterization and course of proteolysis during embryogenesis

Vitellogenin (Vg) and its corresponding yolk protein (YP) products, YP1, YP2 and YP3, were isolated from serum of estrogen-treated hybrid sturgeon (bester; Huso huso X Acipencer ruthenus) and eggs from untreated fish, respectively. Vitellogenin had an apparent molecular mass of 580 kDa and appeared as two major bands corresponding to 180 kDa and 120 kDa after SDS-PAGE. Apparent molecular weights of YP1, YP2 and YP3 were 370 kDa, 88 kDa and 19 kDa, respectively. After SDS-PAGE, YP1 appeared as a main band of 110 kDa, while YP2 was resolved as a single band of 94 kDa and 29 kDa band under non-reducing and reducing conditions, respectively. Yolk protein 3 appeared as a diffuse band corresponding to 16 kDa and two faint bands below 14.4 kDa after SDS-PAGE. However, the 16 kDa band alone was observed after dephosphorylation with alkaline phosphatase. The course of cleavage of yolk proteins in bester embryos and alevins was observed by SDS-PAGE and Western blotting from fertilization onward. After hatching, the main 110 kDa band of YP1 was degraded into smaller peptides during development, while YP2 hardly showed any such structural changes. The amino acid compositions of purified yolk proteins indicated that YP1, YP2 and YP3 were bester lipovitellin, beta-component, and phosvitin, respectively.

Carp (Cyprinus carpio) vitellogenin: purification and development of a simultaneous chemiluminescent immunoassay

Vitellogenin (Vg) was purified from the serum of vitellogenic female carp (Cyprinus carpio) by hydroxylapatite column chromatography and gel filtration. Vg had an apparent molecular mass of 490 kDa and appeared as two bands corresponding to 190 and 156 kDa after SDS-PAGE under reducing conditions. These bands were immunoreacted in Western blotting using antiserum against carp lipovitellin (anti-Lv) which is an egg yolk protein derived from Vg. The amino acid composition of carp Vg was similar to previous reports of cyprinids. The chemiluminescent immunoassay (CLIA) for carp Vg was developed to quantify serum Vg using purified carp Vg and anti-Lv. Its measurable range was from 1.95 to 1000 ng/ml. The dilution curve in the CLIA of vitellogenic female serum was parallel to the standard curve of purified Vg. The coefficient variations of intra- and inter-assay were less than 5%, respectively. Furthermore, the assay had cross-reactivity with the sera of other female cyprinids (crucian carp and Japanese dace). In fish diets-experiments, Vg was detected in all fish in the fish meal containing soybean (20%) group, but was not detected in almost all of the fish in the fish meal-group. This suggests that a soybean based-diet may induce Vg production in the serum of cultivated carp.

Multiple vitellogenin‐derived yolk proteins in gray mullet (Mugil cephalus): Disparate proteolytic patterns associated with ovarian follicle maturation

Disparate proteolytic patterns of yolk proteins, derived from three types of vitellogenin (VgA, VgB, and VgC), were observed in gray mullet. Immuno‐biochemical analyses of extracts obtained from vitellogenic ovaries (VO) and ovulated eggs (OE) confirmed that a large proportion of VgA‐derived lipovitellin (LvA) was degraded into free amino acids (FAAs) during ovarian follicle maturation. The maturation‐associated alteration of VgB‐derived Lv (LvB) involved only limited proteolysis; the heavy and light LvB chains were dissociated into at least three and one polypeptide fragments, respectively. The native mass of VgC‐derived Lv (LvC) exhibited little difference between VO and OE, although it was apparent that the LvC was ‘nicked’ during maturation, resulting in the appearance of several bands in OE. Similar analyses confirmed that VgA‐derived β′‐component (β′‐cA) and VgB‐derived β′‐c (β′‐cB) decreased during maturation in both quantity and native mass, while phosvitin derived from either VgA (PvA) or VgB (PvB) appeared to be degraded into FAAs. The pattern of maturation‐associated proteolysis of mullet yolk proteins is similar to that reported for other marine teleosts spawning pelagic eggs. However, the depository ratio of the three distinct types of Lv in the mullet VO appeared to be different from that estimated for another marine pelagophil, the barfin flounder. These results support a recent paradigm regarding the significance of Vg multiplicity upon successive physiological events in this group of fishes including the hydration of maturing oocytes, the acquisition of proper egg buoyancy, and the generation of requisite nutrient stocks for each stage of embryogenesis and larval development. Mol. Reprod. Dev. 75: 1307–1317, 2008.

Disparate Binding of Three Types of Vitellogenin to Multiple Forms of Vitellogenin Receptor in White Perch

Three types of white perch (Morone americana) vitellogenin (VtgAa, VtgAb, and VtgC) were purified, labeled with digoxigenin (DIG), and subjected to Vtg receptor (Vtgr) binding assays in 96-well plates coated with perch ovarian membrane proteins or to ligand blotting procedures. Binding specificity was evaluated by incubating membrane protein preparations with constant amounts of DIG-Vtg tracer (VtgAa, VtgAb, VtgC, or a mixture of VtgAa and VtgAb [VtgAa/b]) alone or in the presence of unlabeled Vtg ligands. At 250-fold excess molar concentration relative to the tracer, VtgAa and VtgAb were each able to displace only approximately 50% of bound DIG-VtgAa/b, but VtgAa/b could fully displace DIG-VtgAa and DIG-VtgAb under the same conditions. Over a broad range of excess molar ratios, unlabeled VtgAa and VtgAb each displaced their respective DIG-Vtg tracer much more effectively than each did the heterologous tracer (DIG-VtgAb and DIG-VtgAa, respectively). Ligand blotting revealed three forms of Vtgr, a large receptor (>212 kDa) that bound only to VtgAa and two smaller receptors (∼116 and ∼110.5 kDa) that bound preferentially to VtgAb. The VtgC did not specifically bind to ovarian membrane proteins in either assay. Collectively, these results indicate the presence of a system of multiple ovarian Vtgrs with disparate binding to the three types of Vtg present in higher-order teleosts (Acanthomorpha). To our knowledge, this is the first report on binding of multiple types of Vtg to multiple forms of Vtgr in any vertebrate.