Equal contribution of hepatopancreas and ovary to the production of vitellogenin (PmVg1) transcripts in the tiger shrimp, Penaeus monodon (original) (raw)
Related papers
Biology of …, 2004
An additional vitellogenin gene (MeVg2) that is structurally different from MeVg1 was cloned and characterized from the shrimp Metapenaeus ensis. The MeVg2 gene consists of fewer exons-introns and is most likely evolved from the MeVg1 gene. The cDNA for MeVg2 is 8.0 kilobases (kb) in size, and the deduced MeVg2 precursor shared an overall 54% amino sequence identity to the MeVg1 gene of the same shrimp. As compared to the MeVg1 precursor, MeVg2 precursor consists of more potential subunit cleavage sites, suggesting that the precursor may be processed into many smaller subunits. The MeVg2 is expressed only in the hepatopancreas, and the expression level of MeVg2 in adult female increases from the early vitellogenic stage, reaching a maximum at the middle vitellogenic stage, and remains high toward the end of vitellogenic cycle. In addition to the 8-kb mRNA, smaller transcripts of 1.5-2.5 kb for MeVg2 were identified, and the 8-kb transcript only constitutes less than 10% of the overall MeVg2-derived transcripts. To confirm the presence of the small transcripts, we screened the shrimp hepatopancreas cDNA library and isolated two smaller MeVg2specific cDNA clones. These clones shared greater than 99% overall identity to the corresponding C-terminal region of the MeVg2 precursor, suggesting that an alternative expression/ splicing of the MeVg2 gene occurred. By immunohistochemical analysis, vitellin-immunopositive signals were localized in the lumen and extracellular fraction of the hepatopancreas. Amino acid sequence determination of the tissue protein and secreted protein from the hepatopancreas revealed that the 76-kDa vitellogenin subunit is most likely processed into smaller-sized subunits. Taken together, these results suggest that the hepatopancreas is an important organ for the synthesis of vitellogenin and may contribute to vitellogenesis by producing a large quantity of smaller MeVg2 subunit for ovarian uptake.
Molecular Reproduction and Development, 2007
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.
Zoological Science, 2000
In Crustacea, reproductive function and mechanisms regulating vitellogenesis have not been fully elucidated. This is due in great part to a lack of information concerning the biochemical nature of the vitellogenin molecule, the hemolymph precursor of yolk protein, vitellin, as well as the functional expression of the vitellogenin-encoding gene. We have therefore cloned a cDNA encoding vitellogenin in the kuruma prawn, Penaeus japonicus based on the N-terminal amino acid sequence of the 91 kDa subunit of vitellin. The open reading frame of this cDNA encoded 2,587 amino acid residues. This is the first investigation reporting a full-length cDNA and its corresponding amino acid sequence for vitellogenin in any crustacean species.
Gene, 2003
Vitellogenin is the major egg yolk protein synthesized in female shrimp during gonad maturation. Although there are several reports for the cloning of vitellogenin complementary DNA (cDNA) in different crustaceans, little is known of the gene organization of this protein. This study reports the first cloning and characterization of a full-length gene encoding the vitellogenin precursor from the shrimp Metapenaeus ensis. By genomic DNA library screening, six different lambda clones were isolated using shrimp partial gene sequence as probe. Initial DNA sequence determination revealed that these clones are derived from different genes with coding sequence similar to other crustacean vitellogenins. Two of these clones were used for further analysis. One of the lambda clones (l3.3) carries most of the coding sequence that correspond to the M. ensis vitellogenin gene (MeVg1) and the other clone (l8.3) carries a smaller portion of the coding sequence of a different vitellogenin gene (MeVg2). The l3.3 clone was chosen for further characterization. To clone the remaining 5 0 end upstream promoter region, 5 0 untranslated region and the remaining coding sequence of MeVg1, a polymerase chain reaction (PCR)-based gene walking approach was used. Subsequently, a PCR clone with overlapping sequence identical to the genomic clone was obtained and the organization of MeVg1 gene was constructed. The MeVg1 gene consists of 15 exons and 14 introns spanning approximately 10 kb. Several potential cleavage sites were identified from the deduced vitellogenin precursor. Cleaving of the precursor in these sites would result in the production of several vitellogenin subunits. To clone the cDNA for the vitellogenin, 5 0 and 3 0 rapid amplification of cDNA ends was performed using ovary cDNA of the shrimp. A 4.4 kb 5 0 cDNA clone and a 4 kb 3 0 end cDNA clone were isolated. The size of the reconstructed cDNA for M. ensis Vg is 7.97 kb and consists of the longest open reading frame of 7776 bp. Unlike the vitellogenin precursor of most insects and vertebrates, the deduced vitellogenin precursor lacks the polyserine domain important for receptor-mediated endocytosis. Phylogenetic analysis revealed a closer relationship of the MeVg1 with other crustacean vitellogenins but distantly related to other invertebrate and vertebrate vitellogenins. By reverse transcription-PCR, we have demonstrated that the shrimp MeVg1 gene is expressed only in the ovary and hepatopancreas while the MeVg2 gene is expressed exclusively in the hepatopancreas. In conclusion, the shrimp ovary also contribute significantly in the production of vitellogenin at transcription level and the gene organization of the shrimp protein may provide an insight in the evolution of this group of important proteins. q
Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology, 2001
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. ᮊ
Journal of Experimental Zoology, 2004
In order to determine the primary structure of vitellogenin in a protandric species, the coonstriped shrimp Pandalus hypsinotus, we previously purified four vitellin components (designated as VnA, VnB, VnC, and VnD, respectively), and chemically analyzed their partial amino acid sequences. In this study, we subsequently cloned a cDNA encoding vitellogenin in this species based on the N-terminal and internal amino acid sequences of VnA, as well as the N-terminal sequence of VnC. The open reading frame of this cDNA encoded a pro-vitellogenin in which vitellins were arranged as follows: NH 2 -VnA-VnB-VnC/D-COOH. The deduced amino acid sequence possessed a single consensus cleavage sequence, R-X-K/R-R, along the lines of vitellogenins reported in other crustaceans and insects, and the N-terminal sequence of VnB was immediately preceded by this sequence. The comparison of primary structures revealed the existence of a basic and characteristic structure for the vitellogenin molecule in decapod crustacean species, and phylogenetic analysis reflected the current taxonomic classifications of Crustacea. An approximately 8 kb-long transcript of the vitellogenin gene was detected in the hepatopancreas of female shrimps having a gonadosomatic index higher than 1.0 by Northern blot analysis, but was not observed in the hepatopancreas and gonads of male shrimps and the hepatopancreas of female shrimps having a gonadosomatic index lower than 1.0. These results indicate that the hepatopancreas is responsible for vitellogenin synthesis.
Journal of Crustacean Biology, 2013
A complete cDNA sequence of vitellogenin (Vg-H) was cloned from the hepatopancreas of Fenneropenaeus merguiensis (De Man, 1888). The full-length Vg-H gene consists of 7958 bp and contains an ORF of 7761 bp. It encodes a polypeptide of 2587 amino acids, comprising a predicted molecular mass of 283 kD and the theoretical pI is 6.5. The amino acid sequences of the mature vitellogenin (Vg) composed of a signal peptide, three possible O-glycosylation sites, three phosphorylation sites and putative possessing sites (R-X-K/R-R) recognized by subtilisin-like endoproteases. Cleavage at residues 725 to 728 will produce two Vg subunits (78 and 200 kD), which the N-terminal amino acid sequence of 78 kD subunit is identical to that of vitellin purified from the ovary. These properties suggest that Vg protein encoding by Vg-H undergoes processing at its synthetic sites prior to being transported to developing oöcytes. The deduced primary structure of Vg-H showed the highest identity (98.8%) to the Vg-O previously cloned from the ovary of the same species. It is more related to the penaeid Vg sequences than that of nonpenaeids. In situ hybridization revealed that mRNA encoding Vg was expressed both in follicle cells in the ovary and parenchyma cells in the hepatopancreas. In the developing ovary, highest levels were detected during the early vitellogenic stage 2, declining thereafter. In the hepatopancreas, Vg mRNA levels reached a maximum at stage 3 of ovarian development. Profiles of Vg mRNA expression in the ovary and hepatopancreas suggest that the contribution of these tissues to vitellogenesis is inversely related during gonad maturation. Thus, Vg gene sequences expressed in the ovary and hepatopancreas are most likely identical and both tissues are responded for yolk protein synthesis in F. merguiensis.
Molecular reproduction and …, 2006
In order to determine the primary structure of banana shrimp, Penaeus merguiensis, vitellogenin (Vg), we previously purified vitellin (Vt) from the ovaries of vitellogenic females, and chemically analyzed the N-terminal amino acid sequence of its 78 kDa subunit. In this study, a cDNA from this species encoding Vg was cloned based on the N-terminal amino acid sequence of the major 78 kDa subunit of Vt and conserved sequences of Vg/Vt from other crustacean species. The complete nucleotide sequence of Vg cDNA was achieved by RT-PCR and 5′ and 3′ rapid amplification of cDNA ends (RACE) approaches. The full-length Vg cDNA consisted of 7,961 nucleotides. The open reading frame of this cDNA encoding a precursor peptide was comprised of 2,586 amino acid residues, with a putative processing site, R-X-K/R-R, recognized by subtilisin-like endoproteases. The deduced amino acid sequence was obtained from the Vg cDNA and its amino acid composition showed a high similarity to that of purified Vt. The deduced primary structure, of P. merguiensis Vg was 91.4% identical to the Vg of Penaeus semisulcatus and was also related to the Vg sequences of six other crustacean species with identities that ranged from 86.9% to 36.6%. In addition, the amino acid sequences corresponding to the signal peptide, N-terminal region and C-terminal region of P. merguiensis Vg were almost identical to the same sequences of the seven other reported crustacean species. Results from RT-PCR analysis showed that Vg mRNA expression was present in both the ovary and hepatopancreas of vitellogenic females but was not detected in other tissues including muscle, heart, and intestine of females or in the hepatopancreas of mature males. These results indicate that the Vg gene may be expressed only by mature P. merguiensis females and that both the ovary and hepatopancreas are possible sites for Vg synthesis in this species of shrimp. Mol. Reprod. Dev. © 2006 Wiley-Liss, Inc.
Is There Extraovarian Synthesis of Vitellogenin in Penaeid Shrimp?
The Biological Bulletin, 1992
Extraovarian synthesis of vitellogenin (Vg), has been reported for several crustaceans, mainly in the subepidermal adipose tissue (SAT) or the hepatopancreas (HEP). The precise site(s) of Vg synthesis in penaeid shrimp is hitherto unknown and was investigated in a large local species Pcnaeus semisulcalus de Haan. Protein synthesis was determined in SAT and HEP tissue pieces incubated //; vitro. Incubations were at 25 C for eight hours in an oxygen enriched atmosphere, under sterile conditions in a physiological medium, containing 14 Cleucine. At the end of the incubation period, tissue homogenates and medium samples were analyzed for de novo protein synthesis. Total protein synthesis was determined by trichloroacetic acid precipitation. Specific vitellin (Vt) synthesis was determined by radioimmunoprecipitation with a polyclonal Vt-specific antiserum. Characterization of other de novo synthesized proteins was carried out by fluorography from polyacrylamide gels. Subepidermal adipose tissues removed from females at all stages of ovarian development did not synthesize Vtspecific proteins, in spite of the fact that total protein synthesis levels were high. The major protein synthesized de novo in the SAT of males and females is a protein with an identical electrophoretic mobility as hemocyanin in polyacrylamide gels. In vitro protein synthesis in HEP tissues was low compared to SAT or ovary systems. Vtspecific de novo synthesized protein was identified in HEP's from early vitellogenic females, but constituted less than 15% of total protein synthesis. We have previously shown that ovarian tissues from vitellogenic females incubated in vitro exhibited high levels of protein synthesis, an average of 38% of which is Vt-specific (Browdy et ai. 1990, J. Exp. Zoo/. 255: 205-2 1 5). The calculated Vt syn
Fisheries Science, 2005
In order to compare the dynamics of vitellogenin gene expression between naturally maturing prawns and prawns induced to mature artificially by eyestalk ablation, a cDNA encoding vitellogenin was cloned from a cDNA library prepared from the hepatopancreas of the kuruma prawn Penaeus ( Marsupenaeus ) japonicus , and a quantitative real-time reverse transcription -polymerase chain reaction (RT-PCR) system was developed. Sequence analysis revealed the likely possibility that vitellogenin cDNA from the hepatopancreas was identical to that from the ovary which had been isolated in a previous study. Based on this information, a quantitative real-time RT-PCR system was established and the dynamics of vitellogenin mRNA levels were examined. In naturally maturing prawns, vitellogenin mRNA levels were maintained at low levels during the previtellogenic stage, and thereafter, levels increased as vitellogenesis progressed but decreased during the latter stages of maturation in the hepatopancreas and ovary. In contrast, in eyestalk-ablated prawns, changes in mRNA levels differed in both tissues; an obvious increment of mRNA levels was revealed in the ovary, whereas mRNA levels were negligible in the hepatopancreas. This suggests that eyestalk ablation cannot be used to accurately simulate the natural process of vitellogenin gene expression during vitellogenesis, and that vitellogenin gene expression is regulated in a tissue-specific manner.