Molecular characterization of vitellin from the ovaries of the white shrimp Penaeus (Litopenaeus) vannamei (original) (raw)
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Identification and characterization of vitellin in a hermophrodite shrimp, Pandalus kessleri
Comparative Biochemistry and Physiology Part B: Comparative Biochemistry, 1989
A female specific protein (FSP, vitellogenin) in hemolymph and its related ovarian protein (vitellin) of Pandalus kessleri were studied by means of electrophoretical and immunological procedures. 2. The vitellin was purified from vitellogenic ovaries using hydroxylapatite, DEAE cellulose and Sepharose 6B columns, consecutively. 3. The vitellin had a molecular weight of approximately 560 kD and was composed of two subunits, 81 and 110 kD, respectively. 4. The vitellogenin concentrations in the hemolymph increased as vitellogenesis in the ovarian oocytes advanced and dropped markedly after the release of mature eggs.
Characterization of vitellin from the ovaries of the banana shrimp Litopenaeus merguiensis
Comparative Biochemistry and …, 2006
Vitellin (Vt) was purified from ovary extracts of mature females of the banana shrimp Litopenaeus merguiensis using DEAE-Sephacel and Superdex 200 columns. Native Vt had an apparent molecular mass of 398 kDa as determined by native PAGE and by gel filtration chromatography. Under reducing and denaturing conditions (SDS-PAGE), Vt is composed of two major subunits of 87 and 78 kDa, although some faint bands were also detected. The N-terminal 10 amino acids sequence of the 78 kDa subunit is identical to that of Litopenaeus vannamei Vt and very similar to that of Litopenaeus japonicus vitellogenin (Vg) as well as Litopenaeus semisulcatus Vt, with an identity of 89%. Anti-Vt polyclonal antibody raised against purified Vt shows a high specificity with only ovarian Vt and hemolymph Vg of vitellogenic shrimps in double immunodiffusion and Western blot assays. Vg and Vt concentrations in hemolymph, hepatopancreas and ovaries were measured by ELISA. Vg concentrations increased in the hemolymph in the early stages of ovarian development and declined in the maturation stages. As there were undetectable concentrations of Vg in the hepatopancreas while an elevation of Vg levels occurred in the hemolymph, during the time that Vt was accumulating in the ovaries during oogenesis, this would suggest that the contribution of Vg synthesized by the hepatopancreas only might be not sufficient for adequate development of the oocytes in the banana shrimp L. merguiensis during vitellogenesis. D
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.
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.
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
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