Hepatopancreas and ovary are sites of vitellogenin synthesis as determined from partial cDNA encoding of vitellogenin in the marine shrimp,Penaeus vannamei

Summary

The site of yolk protein synthesis in crustaceans has long been a subject of controversy. A portion of the vitellogenin gene structure was reported recently in a freshwater giant prawn (Macrobrachium rosenbergii) and black tiger shrimp (Penaeus monodori), in which the hepatopancreas was confirmed to be the extraovarian site of vitellogenin synthesis. The ovary is also frequently reported to be the site of yolk protein synthesis in penaeid shrimp. The same PCR product was obtained using cDNA from the hepatopancreas or the ovary as a template. The deduced amino acid sequence of Vg in P. vannamei showed high identities of 57% and 78% with those from M. rosenbergii and P. monodon, respectively. The same location of the intron in the sequenced region of genomic DNA was also found between these three species. We therefore concluded that the hepatopancreas and ovary are sites of vitellogenin synthesis in P. vannamei. The partial structure of the vitellogenin gene is further presented.     

Vitellogenin gene expression and hemolymph vitellogenin during vitellogenesis, final maturation, and oviposition in female kuruma prawn, Marsupenaeus japonicus

In penaeid shrimps, vitellogenin (VTG), the precursor of vitellin, is synthesized in the ovary and hepatopancreas and accumulated in oocytes during ovarian development. In the present study, VTG gene expression levels and hemolymph VTG levels were determined throughout ovarian development in female kuruma prawn, Marsupenaeus japonicus. Hemolymph VTG levels and VTG mRNA levels in the ovary and hepatopancreas were high during vitellogenesis, remained high until final maturation, and then decreased after oviposition. This profile suggests that VTG synthesis activity increases during vitellogenesis and decreases after oviposition. Absence of a significant increase in ovary size in final maturation suggests cessation of yolk accumulation and low activity of VTG synthesis in spite of high VTG mRNA levels. VTG mRNA levels in ovary and hepatopancreas were both highly correlated during vitellogenesis. Thus, their contribution to yolk accumulation seems to be similar. In contrast, VTG mRNA levels in the hepatopancreas increased more slowly at the start of vitellogenesis and declined more sharply after oviposition than in the ovary. This suggests a difference in the regulation of VTG synthesis between the ovary and the hepatopancreas.     

Hepatopancreas is the extraovarian site of vitellogenin synthesis in black tiger shrimp, Penaeus monodon.

The site of yolk protein synthesis in crustaceans has long been a subject of controversy. The vitellogenin gene structure was partially reported only very recently in Macrobrachium rosenbergii, after which the hepatopancreas was confirmed as the extraovarian site of vitellogenin synthesis in that species. Ovaries are the most frequently reported as the site of yolk protein synthesis in penaeid shrimp. Using cDNA reversed-transcribed from mRNA isolated from the hepatopancreas of vitellogenic female shrimp, Penaeus monodon, we found that its deduced amino acid sequence had high identity of 48% with that from M. rosenbergii vitellogenin. A similar location of the intron in the sequenced region of genomic DNA was also found between these two species. We therefore concluded that the hepatopancreas the extraovarian site of vitellogenin synthesis in P. monodon in vivo. The partial structure of vitellogenin gene is presented in this study.     

Vitellogenin and its messenger RNA during ovarian development in the female blue crab, Callinectes sapidus: gene expression, synthesis, transport, and cleavage

Blue crab vitellogenin (VTG) cDNA encodes a precursor that, together with two other Brachyuran VTGs, forms a distinctive cluster within a phylogenetic tree of crustacean VTGs. Using quantitative RT-PCR, we found that VTG was primarily expressed in the hepatopancreas of a vitellogenic female, with minor expression in the ovary. VTG expression in the hepatopancreas correlated with ovarian growth, with a remarkable 8000-fold increase in expression from stage 3 to 4 of ovarian development. In contrast, the VTG levels in the hepatopancreas and hemolymph decreased in stage 4. Western blot analysis and N-terminal sequencing revealed that vitellin is composed of three subunits of approximately 78.5 kDa, 119.42 kDa, and 87.9 kDa. The processing pathway for VTG includes an initial hepatopancreatic cleavage of the primary precursor into approximately 78.5-kDa and 207.3-kDa subunits, both of which are found in the hemolymph. A second cleavage in the ovary splits the approximately 207.3-kDa subunit into approximately 119.4-kDa and approximately 87.9-kDa subunits. The hemolymph VTG profiles of mated and unmated females during ovarian development indicate that early vitellogenesis and ovarian development do not require mating, which may be essential for later stages, as VTG decreased to the basal level at stage 4 in the unmated group but remained high in the mated females. Our results encompass comprehensive overall temporal and spatial aspects of vitellogenesis, which may reflect the reproductive physiology of the female blue crab, e.g., single mating and anecdysis in adulthood.     

Dynamics of vitellogenin mRNA expression during vitellogenesis in the banana shrimp Penaeus (Fenneropenaeus) merguiensis using real-time PCR

An open reading frame (ORF) of vitellogenin (Vg) cDNA was amplified from the ovaries of the banana shrimp, Penaeus merguiensis. An examination of Vg-deduced amino acid sequence revealed the presence of cleavage sites at a consensus motif for subtilisin-like endoproteases prior to the N-terminal sequences of purified vitellin (Vt) subunits. A comparison of the primary structures of Vg molecules in decapod crustacean species revealed the existence of a common characteristic structure, and phylogenetic analysis reflected the current taxonomic classifications of crustaceans. A PCR product of 1.1 kb encoding the 3'-end of Vg cDNA was cloned from the hepatopancreas. Although its sequence was almost identical to that of the same region of the ovarian Vg, with only 18 nucleotide differences, analysis suggests that they have been subjected to natural selection, indicating that there may be two different, tissue-specific Vg genes in P. merguiensis. This is consistent with the different expression patterns of Vg mRNA, as determined by real-time PCR. Vg mRNA levels were maintained at low levels during the previtellogenic stage and they increased as vitellogenesis progressed to reach a peak at the early vitellogenic stage in the ovary or at the vitellogenic stage in the hepatopancreas, and thereafter, levels decreased. Expression of Vg mRNA was much higher in the ovary compared to the hepatopancreas at all stages of ovarian development, implying that the ovary is mainly responsible for Vt synthesis. These indicate that penaeids constitute a unique model for vitellogenesis, showing intraovarian gene expression and synthesis of yolk protein.     

Deduced primary structure of vitellogenin in the giant freshwater prawn, Macrobrachium rosenbergii, and yolk processing during ovarian maturation

A cDNA encoding vitellogenin (Vg) in the giant freshwater prawn, Macrobrachium rosenbergii, was cloned based on the cDNA sequence of vitellin (Vn) fragments A-N and B-42 determined previously, and its amino acid sequence deduced. The open reading frame (ORF) encoded 2,537 amino acid residues and its deduced amino acid sequence possessed three consensus cleavage sites, R-X-R-R, similar to those reported in Vgs of insects. The deduced primary structure of Vg in M. rosenbergii was seen to be similar to that of Penaeus japonicus, especially in the N-terminal region. It is therefore likely that Vgs in crustacean species including prawns and other related decapods exhibit a similar structural pattern. Based on the deduced primary structure of Vg and analysis of the various Vg and Vn subunits found in the hemolymph and ovary during ovarian maturation, we demonstrated the post-translational processing of Vg in M. rosenbergii. This is the first time that Vg processing has been clearly demonstrated in a crustacean species. Vg, after being synthesized in the hepatopancreas, is considered to be cleaved by a subtilisin-like endoprotease to form two subunits, A and proB, which are then released into the hemolymph. In the hemolymph, proB is possibly cleaved by a processing enzyme of unknown identity to give rise to subunits B and C/D. The three processed subunits A, B, and C/D are sequestered by the ovary to give rise to three yolk proteins, Macr-VnA, VnB, and VnC/D.     

Hepatopancreas is the extraovarian site of vitellogenin synthesis in black tiger shrimp, Penaeus monodon

The site of yolk protein synthesis in crustaceans has long been a subject of controversy. The vitellogenin gene structure was partially reported only very recently in Macrobrachium rosenbergii, after which the hepatopancreas was confirmed as the extraovarian site of vitellogenin synthesis in that species. Ovaries are the most frequently reported as the site of yolk protein synthesis in penaeid shrimp. Using cDNA reversed-transcribed from mRNA isolated from the hepatopancreas of vitellogenic female shrimp, Penaeus monodon, we found that its deduced amino acid sequence had high identity of 48% with that from M. rosenbergii vitellogenin. A similar location of the intron in the sequenced region of genomic DNA was also found between these two species. We therefore concluded that the hepatopancreas the extraovarian site of vitellogenin synthesis in P. monodon in vivo. The partial structure of vitellogenin gene is presented in this study.     

Identification of the yolk receptor protein in oocytes of Nereis virens (Annelida,Polychaeta) and comparison with the locust vitellogenin receptor

Summary In oviparous animals large amounts of yolk proteins of extraovarian origin are accumulated by developing oocytes during vitellogenesis. The yolk protein precursors, the vitellogenins (VTG), are transported into the oocytes by receptor-mediated endocytosis. In oocytes of the polychaetous annelid, Nereis virens, the receptor protein for VTG was visualized by ligand blotting studies as a protein with an apparent molecular mass of 190 kDa under non-reducing conditions. Anti-Locusta VTG receptor antibodies recognize the Nereis VTG receptor protein. The Nereis VTG receptor protein binds Locusta and Schistocerca VTG; the VTG receptor proteins of both locust species bind the Nereis vitellin. These results indicate the conservation of structural elements important for internalization of VTG.Abbreviations CHAPS 3-[(3-cholamidopropyl)dimethyl-ammonio]-1-propane-sulphonic acid - HBS HEPES-buffered saline - PAP peroxidase-anti-peroxidase - SDS-PAGE sodium dodecylsulphate polyacrylamide gel electrophoresis - TRIS, TBS TRIS-buffered saline - VT vitellin - VTG vitellogenin     

From hepatopancreas to ovary: molecular characterization of a shrimp vitellogenin receptor involved in the processing of vitellogenin

We report the first cloning and characterization of cDNA encoding a putative vitellogenin (Vg) receptor (VgR) from the shrimp, Penaeus monodon. The shrimp VgR cDNA is 6.8 kb; the deduced protein has 1943 amino acids with a molecular weight of 211 kDa. VgR is ovary specific and consists of conserved cysteine-rich domains, epidermal growth factor-like domains, and YWTD motifs similar to the low-density lipoprotein, very low-density lipoprotein, and VgR of insects and vertebrates. VgR expression level in the ovary is low during early vitellogenesis and increases to maximum levels in females with a gonadosomatic index of 3-4, presumably when needed for receptor-mediated endocytosis during the rapid phase of extraovarian Vg production by the hepatopancreas. A peptide from the C-terminal end of VgR was synthesized for antibody production. Anti-VgR antibody recognized an ovarian membrane protein, and the level of this protein was high when extraovarian production of Vg reached peak levels. By immunohistochemical analysis, VgR was detected strongly in the membranes of larger oocytes. VgR expression was knocked down after the shrimp were injected with VgR double-stranded RNA, leading to a decrease in VgR protein content in the ovary, but an increase in the hemolymph level of Vg. This study represents the first report of the functional analysis of a putative VgR in a crustacean.     

Effects of bilateral and unilateral eyestalk ablation on vitellogenin synthesis in immature female kuruma prawns, Marsupenaeus japonicus

In penaeid shrimp species, vitellogenin (VTG) synthesis in the ovary and hepatopancreas is under the inhibitory regulation of a neuroendocrine system, the X-organ/sinus gland complex in the paired eyestalks, and eyestalk ablation (removal of the X-organ/sinus gland complex) is widely used for inducing ovarian development. However, the difference in effects of bilateral and unilateral ablation on VTG gene expression has not been clarified so far. In the present study, VTG synthesis was monitored over a 16-day period after ablation and compared between replicates of immature female kuruma prawns, Marsupenaeus (Penaeus) japonicus, that had been bilaterally or unilaterally ablated and control specimens. After bilateral ablation, ovarian development was induced, and the ovarian weight, hemolymph VTG levels, and VTG mRNA levels in the ovary increased significantly. Significant VTG mRNA increase was detected 12 h after bilateral ablation. In contrast, after unilateral ablation, ovarian development was not induced, and the ovarian weight, hemolymph VTG levels, and VTG mRNA levels in the ovary did not change significantly from the control. These results indicate that in immature female prawns, unilateral ablation does not induce VTG gene expression, whereas bilateral ablation induces rapid VTG gene expression (<12 h). The ineffectiveness of unilateral ablation suggests that the remaining X-organ/sinus gland complex in the unilaterally ablated female prawns may secrete sufficient VIH to suppress VTG synthesis.     

Oogenesis and oocytes

The morphological features of polychaete ovarian morphology and oogenesis are reviewed. Some basic information on ovarian structure and/or oogenesis is known for slightly more than half of recognized polychaete families although comprehensive studies of oogenesis have been conducted on 0.1 of described species. Relative to other major metazoan groups, ovarian morphology is highly variable in the Polychaeta. While some species appear to lack a defined ovary, most have paired organs that are segmentally repeated to varying degrees depending on the family. Ovaries vary widely in their location but are most frequently associated with the coelomic peritoneum, parapodial connective tissue, or elements of the circulatory system. The structural complexity of the ovary is correlated with the type of oogenesis expressed by the species. In some polychaetes, extraovarian oogenesis occurs in which previtellogenic oocytes are released into the coelom from a simple ovary where differentiation occurs in a solitary fashion or in association with nurse cells or follicle cells. In other species, intraovarian oogenesis occurs in which oocytes undergo vitellogenesis within the ovary, often in association with follicle cells that may provide nutrition. Vitellogenesis probably includes both autosynthetic and heterosynthetic processes; autosynthesis involves the manufacture of yolk bodies via the proteosynthetic organelles of the oocyte whereas heterosynthesis involves the extraovarian production of female-specific yolk proteins that are incorporated into the oocyte through a receptor-mediated process of endocytosis. Variation in the speed of egg production varies widely and appears to be correlated with the vitellogenic mechanism employed. Mature ova display a wide range of egg envelope morphologies that often show some intrafamilial similarities.     

Localization of vitellogenin mRNA expression and vitellogenin uptake during ovarian maturation in the giant freshwater prawn Macrobrachium rosenbergii

In situ hybridization and immunohistochemical techniques were used to investigate the dynamics of vitellogenin (Vg) mRNA expression and Vg uptake during ovarian maturation in the hepatopancreas and ovary at differing stages of ovarian maturation in both intact and eyestalk ablated female Macrobrachium rosenbergii. In the hepatopancreas of intact animals, Vg mRNA expression was detected faintly two days after ecdysis, and signals showed a gradual increase as the molt cycle advanced to the premolt stages, but decreased at the late premolt stage. Vg mRNA was detected in the R-cells of the hepatopancreas, indicating that these cells are responsible for synthesizing Vg. No Vg mRNA expression was observed in the ovary. Immunohistochemistry results for the hepatopancreas showed a pattern of staining intensity similar to that of in situ hybridization. Increases in the accumulation of yolk protein in the oocytes occurred concomitantly with increasing Vg mRNA expression. In eyestalk ablated animals, Vg mRNA expression and Vg uptake showed similar but accelerated patterns to those of intact animals. This study has confirmed on the cellular level previous results that Vg synthesis is intrinsically correlated to ovarian maturation and the molt cycle in M. rosenbergii.     

Solubilization and characterization of the chicken oocyte vitellogenin receptor.

This paper describes the biochemical characterization of the chicken oocyte plasma-membrane receptor for one of the major lipid-carrying yolk proteins, vitellogenin (VTG). The receptor was extracted from oocyte membranes with the non-ionic detergent octyl-beta-D-glucoside and visualized by ligand blotting, with 125I-VTG as a protein with an apparent Mr of 96000, under non-reducing conditions. It exhibited high affinity for native chicken VTG (Kd 2 X 10(-7) M) but was unable to bind VTG with reductively methylated lysine residues or phosvitin (the phosphoserine-rich intracellular cleavage product of VTG). Polyclonal antibodies to the 96 kDa protein inhibited VTG binding to the receptor and were able to precipitate functional VTG-receptor activity from oocyte-membrane detergent extracts with a concomitant removal of the 96 kDa protein. Antibodies directed against the mammalian receptor for low-density lipoprotein showed cross-reactivity with the chicken oocyte VTG receptor, raising the possibility that lipoprotein receptors in birds are structurally related to those in mammalian species.     

Characterization and processing of superoxide dismutase-fused vitellogenin in the diapause embryo formation: a special developmental pathway in the brine shrimp, Artemia parthenogenetica

To withstand environmental stress, Artemia release diapause cysts via an oviparous pathway instead of producing swimming nauplius larvae by the ovoviviparous pathway. Encased in such a cyst, the embryos at diapause can survive for many years. Vitellogenin (Vtg), the precursor of vitellins, the main yolk proteins, is crucial for embryonic development. This study compares vitellogenesis between oviparity and ovoviviparity, the two reproductive modes occurring in A. parthenogenetica. A Vtg gene was cloned, based on N-terminal amino acid sequence analysis, PCR amplification, and cDNA library construction and screening, and was found to consist of 6778 bp with a 6657 bp open reading frame encoding 2219 amino acids. From the deduced primary structure, Artemia vitellogenin (ArVtg) was found to possess six copies of the consensus cleavage site, R-X-X-R, and to contain a superoxide dismutase (SOD)-like domain at the N-terminus. This is an unusual finding for crustacean Vtg proteins, having been reported only in one previous crustacean, Daphnia magna. Using Northern blot analysis and in situ hybridization, ArVtg gene expression was observed at early stages of vitellogenesis in the connective tissue located in the cephalothorax, with trace expression in the ovary. Western blot analysis and several N-terminal sequences revealed that ArVtg was cleaved at each consensus cleavage site and that more than 10 subunits were formed during posttranslational processing in ovarian maturation. Of these, only the SOD-containing subunits (～90 and 60 kDa) showed different profiles between the oviparous and ovoviviparous pathways. This suggests that these high concentration components have an important function for the encysted diapaused embryos during long-term cell-cycle arrest, which has remained unknown up until now.