Chicken oviduct-specific expression of transgene by a hybrid ovalbumin enhancer and the Tet expression system(GENETICS, MOLECULAR BIOLOGY, AND GENE ENGINEERING)

スポンサーリンク

概要

• 論文の詳細を見る

• We generated genetically manipulated chickens and quail by infecting them with a retroviral vector expressing the human growth hormone under the control of chicken ovalbumin promoter/enhancer up to -3861 bp from the transcriptional start site. The growth hormone was expressed in an oviduct-specific manner and was found in egg white, although its level was low. The DNA sequence of the integrated form of the viral vector in the packaging cells was shown to be truncated and contained only the sequence spanning -3861 to -1569 bp. This represented only the DNase I hypersensitive site (DHS) III of the 4 DHSs and lacked the proximal promoter of the ovalbumin control region. We found several TATA-like and other promoter motifs of approximately -1800 bp and considered that these promoter motifs and DHS III may cause weak but oviduct-specific expression of the growth hormone. To prove this hypothesis and apply this system to oviduct-specific expression of the transgene, the truncated regulatory sequence was fused to an artificial transactivator-promoter system. In this system, initial weak but oviduct-specific expression of the Tet activator from the promoter element in the ovalbumin control sequence triggered a self-amplifying cycle of expression. DsRed was specifically expressed in oviduct cells of genetically manipulated chickens using this system. Furthermore, deletion of a short region possibly containing the promoter elements (-2112 to -1569 bp) completely abrogated oviduct-specific expression. Taken together, these results suggest that weak expression of this putative promoter causes oviduct-specific expression of the transgene.

著者

• Kamihira Masamichi

  Graduate School of Systems Life Sciences, Kyushu University

• 三宅 克英

  名大院・工・生物機能

• Kamihira M

  Department Of Biotechnology School Of Engineering Nagoya University

• Kamihira Masamichi

  Nagoya University:(present Office)kyushu University

• Kamihira Masamichi

  名古屋大学 工学研究科生物機能工学

• Kamihira Masamichi

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Kawabe Yoshinori

  Department Of Chemical Engineering Faculty Of Engineering Kyushu University

• Kawabe Yoshinori

  九州大学 工学研究院化学工学

• Kawabe Yoshinori

  名古屋大学 工学研究科生物機能工学

• Kamihira Masamichi

  Department Of Chemical Engineering Faculty Of Engineering Nagoya University

• Iijima S

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Iijima Shinji

  Department Of Biotechnology School Of Engineering Naogya University

• Iijima Shinji

  Department Of Biotechnology Faculty Of Engineering Nagoya University

• Iijima S

  Department Of Biotechnology Faculty Of Engineering Nagoya University

• Iijima Shinji

  Department Of Chemical Engineering Nagoya University

• Ono Ken-ichiro

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Kodama Daisuke

  Nagoya University

• Kyogoku Kenji

  Kaneka Corporation

• Yamashita Takashi

  Kaneka Corporation

• INAYOSHI Yujin

  Department of Biotechnology, Graduate School of Engineering, Nagoya University

• Kodama Daisuke

  Department Of Materials Chemistry And Engineering College Of Engineering Nihon University

• Morshed Mahboob

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• 三宅 克英

  名古屋大学大学院工学研究科

• Kuga Yuko

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Motono Makoto

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Murai K

  Osaka Univ. Osaka Jpn

• Yoshida Kazuhiro

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Kojima Yasuhiro

  Department Of Neurosurgery Nishiarai Hospital

• Nishijima Ken-ichi

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Miyake K

  Nagoya University

• Miyake Katsuhide

  Department Of Biotechnology School Of Engineering Nagoya University

• Nishijima Ken-ichi

  Department Of Applied Biological Chemistry The University Of Tokyo:(present Address)department Of Bl

• Miyake Katsuhide

  Ecotopia Science Institute Nagoya University

• Nishimiya Daisuke

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• 三宅 克英

  名大院・工・化学生物工

• Okino Yuuki

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Motono Makoto

  Department Of Biotechnology Graduate School Of Engineering Nagoya University:(present Office)departm

• Inayoshi Yujin

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• 三宅 克英

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Kodama Daisuke

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Miyake Katsuhide

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Kawabe Yoshinori

  Department Of Biotechnology Graduate School Of Engineering Nagoya University

• Iijima Shinji

  Department of Biotechnology, Graduate School of Engineering, Nagoya University

• Nishijima Kenichi

  Department of Biotechnology, Graduate School of Engineering, Nagoya University

• KOJIMA Yasuhiro

  Department of Applied Chemistry, Faculty of Science and Engineering, Chuo University

• IIJIMA Shinji

  Department of Agricultural Chemistry, The University of Tokyo

関連論文

• 2Cp04 ニワトリ由来ガラクトース転移酵素、及びシアル酸転移酵素の解析(遺伝子工学,一般講演)
• Preparation of artificial skeletal muscle tissues by a magnetic force-based tissue engineering technique(CELL AND TISSUE ENGINEERING)
• 211 新規エンド型シアリダーゼの構造と機能
• 605 新規エンドシアリダーゼの精製およびクローニング
• 1Bp15 口腔連鎖球菌Sfreptococcus anginosusの英膜多糖生合成系遺伝子群の単離と解析(遺伝子工学,一般講演)
• 病原性細菌莢膜多糖の生合成系遺伝子群とその応用(分子機能を拓く)
• 3I11-2 口腔連鎖球菌Streptococcus anginosusの夾膜多糖合成系遺伝子群の解析(ペプチド工学・プロテオーム,糖鎖工学,一般講演)
• BM-P10 Construction of skeletal muscular tissue-like structures by a magnetic force-based tissue engineering technique(Section III Biomedical Engineering)
• E-cadherin gene-engineered feeder systems for supporting undifferentiated growth of mouse embryonic stem cells(CELL AND TISSUE ENGINEERING)
• 1Dp20 レトロウイルスのゲノムインテグレーションメカニズムの解析(生体情報工学,遺伝子工学,核酸工学,一般講演)
• 3I11-3 ニワトリ由来シアル酸転移酵素の昆虫細胞を用いた生産法の確立(ペプチド工学・プロテオーム,糖鎖工学,一般講演)
• 3C11-5 バキュロウイルスを用いた連鎖球菌由来β-1,4-ガラクトース転移酵素の活性発現(酵素学・酵素工学・タンパク質工学,糖鎖工学,一般講演)
• 3C12-2 バクテリオファージ由来エキソ型ポリシアル酸分解酵素(酵素学・酵素工学・タンパク質工学,糖鎖工学,一般講演)
• 3P-2093 ニワトリ卵白タンパク質におけるガラクトース附加能欠損と改善(8b セル&ティッシュエンジニアリング,一般演題,動物バイオテクノロジー,伝統の技と先端科学技術の融合)
• 2P-2084 レトロウイルスのゲノムインテグレーションメカニズムの解析(8b セル&ティッシュエンジニアリング,一般演題,動物バイオテクノロジー,伝統の技と先端科学技術の融合)
• Growth Induction of Rat Primary Hepatocytes Using Antisense Oligonucleotides
• Growth and Differentiation of Cultured Fetal Hepatocytes Isolated from Various Developmental Stages
• Differentiation and Proliferation of Primary Rat Hepatocytes Cultured as Spheroids
• Efficient Induction of Hepatocyte Spheroids in a Suspension Culture Using a Water-Soluble Synthetic Polymer as an Artificial Matrix
• Specific Separation of Animal Cells Using Aqueous Two-Phase Systems
• Construction of Heterotypic Cell Sheets by Magnetic Force-Based 3-D Coculture of HepG2 and NIH3T3 Cells(CELL AND TISSUE ENGINEERING)
• Magnetic Force-Based Cell Patterning Using Arg-Gly-Asp (RGD) Peptide-Conjugated Magnetite Cationic Liposomes(CELL AND TISSUE ENGINEERING)
• BM-P11 Genetically modified angiogenic cell sheets fabricated by magnetic force-based tissue engineering techniques(Section III Biomedical Engineering)
• AN-P30 Accumulative gene integration technique using recombinase mediate cassette exchange(Section I Animal and Plant Cell Cultures)
• AN-P27 Site-specific genetic modification of target cells using an integrase-defective retroviral vector and cre-mediated cassette exchange(Section I Animal and Plant Cell Cultures)
• AN-P25 Artificial promoter system for chicken oviduct-specific expression of target gene(Section I Animal and Plant Cell Cultures)
• Human beta defensin-3 engineered keratinocyte sheets constructed by a magnetic force-based tissue engineering technique(CELL AND TISSUE ENGINEERING)
• 1Kp18 Cre recombinase mediated site-specific genetic modification of target cells using integrase-defective retroviral vectors
• 2Cp15 Generation of Genetically Manipulated Chickens Producing Epo/Fc Fusion Protein
• Enhancement of Cell Function through Heterotypic Cell-Cell Interactions Using E-Cadherin-Expressing NIH3T3 Cells(CELL AND TISSUE ENGINEERING)
• Functional Role of RhoA in Growth Regulation of Primary Hepatocytes
• 2Jp14 レトロウイルスのゲノムインテグレーションメ力ニズムの解析(生体医用工学・人工臓器,一般講演)
• 3F11-4 B 群溶血性連鎖球菌におけるシアリルラクトサミンポリマー生合成系糖転移酵素群の機能解析
• Enhanced Cell Aggregation and Liver Functions Using Polymers Modified with a Cell-Specific Ligand in Primary Hepatocyte Cultures
• 552 連鎖球菌が生産するシアリルルイス糖鎖類似多糖合成系遺伝子群における糖転移酵素遺伝子の解析
• 441 B群溶血性連鎖球菌のシアリルルイス糖鎖類似多糖合成遺伝子群の発現制御
• 1062 微生物が生産するシアリルルイス糖鎖類似多糖合成系遺伝子群の解析
• BP-P3 Retroviral gene transfer to chickens for the production of pharmaceutical proteins into eggs(Section II Biopharmaceuticals Production)
• Retroviral Gene Transduction into Chicken Embryo Gonads through Blood Circulation(CELL AND TISSUE ENGINEERING)
• Production of Recombinant Tumor Necrosis Factor Receptor/Fc Fusion Protein by Genetically Manipulated Chickens(GENETICS, MOLECULAR BIOLOGY, AND GENE ENGINEERING)
• Transport of Human Immunoglobulin G and Fc-Fusion Proteins to Chicken Egg Yolk(BIOCHEMICAL ENGINEERING)
• Production of scFv-Fc Fusion Protein Using Genetically Manipulated Quails(CELL AND TISSUE ENGINEERING)
• Characterization of Transient Expression System for Retroviral Vector Production(MEDICAL BIOTECHNOLOGY)
• Production of Anti-CD2 Chimeric Antibody by Recombinant Animal Cells(CELL AND TISSUE ENGINEERING)
• Transcriptional Coactivators CBP and p300 Cooperatively Enhance HNF-1α-Mediated Expression of the Albumin Gene in Hepatocytes
• 2F09-3 Analysis of chicken ovalbumin promoter region.
• Simple Assay Method for Endocrine Disrupters by in Vitro Quail Embryo Culture : Nonylphenol Acts as a Weak Estrogen in Quail Embryos(BIOCHEMICAL ENGINEERING)
• Production of Anti-Prion scFv-Fc Fusion Proteins by Recombinant Animal Cells
• protamine-Modified DDAB Lipid Vesicles Promote Gene Transfer in the Presence of Serum^1
• Integrase-Mediated Nonviral Gene Transfection with Enhanced Integration Efficiency
• Improved hatching for in vitro quail embryo culture using surrogate eggshell and artificial vessel
• Exogenous Gene Transfection into Quail Embryo Using Cationic Lipid Vesicles
• Enhancement of Transfection Efficiency Using Ligand-Modified Lipid Vesicles
• Host Range Specificity of a Novel Runaway-Type Vector for Mammalian Cells
• Inducible Production of Erythropoietin Using New Runaway-Type Vector by Mammalian Cell Culture in Spinner Flask
• Continuous Production of Human Erythropoietin by Immobilized Recombinant L-929 Cells
• Kinetic Study of Hybridoma Metabolism and Antibody Production in Continuous Culture Using Serum-Free Medium
• Immobilization of Animal Cells Using Photo-Crosslinkable Resin
• Effect of Dissolved Oxygen Concentration on Monoclonal Antibody Production in Hybridoma Cell Cultures
• High Cell Density Cultivation of Anchorage-Dependent Cells Using a Novel Macroporous Cellulosic Support
• Formation of Inclusion Complexes between Cyclodextrins and Aromatic Compounds under pressurized Carbon Dioxide
• Effects of Oxygen Aeration on Production of Monoclonal Antibody in Immobilized Hybridoma-Cell Bioreactor
• Purification of Recombinant α-Amylase with Immuno-Affinity Chromatography Using Monoclonal Antibody
• Effective Utilization of Horseradish and Wasabi by Treatment with Supercritical Carbon Dioxide
• Synthesis of Aspartame Precursors by Enzymatic Reaction in Supercritical Carbon Dioxide(Food & Nutrition)
• Brewing of Sake from Rice and Rice-Koji Defatted by Supercritical Carbon Dioxide Treatment
• Removal of Organic Solvent from Antibiotics with Supercritical Carbon Dioxide
• 1pB17-1 B群溶血性連鎖球菌におけるシアリルラクトサミン生合成系の制御メカニズムの解析(遺伝子工学・核酸工学,一般講演)
• 3F11-5 B 群溶血性連鎖球菌におけるシアリルラクトサミン生合成系の制御メカニズムの解析
• 454 連鎖球菌におけるシアリルラクトサミン生合成系の制御機構
• 1141 初代肝細胞培養でのRNAiによる遺伝子発現抑制(動物細胞工学,生体医用工学,一般講演)
• Identification of Sialyltransferases of Streptococcus agalactiae
• Molecular Characterization of a Novel β1, 3-Galactosyltransferase for Capsular Polysaccharide Synthesis by Streptococcus agalactiae Type Ib^1
• Putative Regulatory Gene for Polysaccharide Synthesis of Streptococcus agalactiae Type Ia
• Molecular Cloning and Characterization of a Novel Bacteriophage-Associated Sialidase
• Mammalian Chromatin Remodeling Complex SWI/SNF Is Essential for Enhanced Expression of the Albumin Gene during Liver Development
• Repression of GR-Mediated Expression of the Tryptophan Oxygenase Gene by the SWI/SNF Complex during Liver Development
• Expression of Chromatin Remodeling Factors during Neural Differentiation
• Characterization of a Multidomain Cellulase from an Extremely Thermophilic Anaerobe Strain NA10
• 901 Streptococcus agalactiae type Ibの夾膜多糖合成系遺伝子群の構造解析
• BP-O5 Transgenic chickens expressing galactosyltransferase produce galactosylated pharmaceutical proteins into egg white(Section II Biopharmaceuticals Production)
• Functional Expression of Streptococcal Galactosyltransferase in Baculovirus/Insect Cell Expression System(ENZYMOLOGY, PROTEIN ENGINEERING, AND ENZYME TECHNOLOGY)
• Coliphage Derived Sialidase Preferentially Recognizes Nonreducing End of Polysialic Acid(ENZYMOLOGY, PROTEIN ENGINEERING, AND ENZYME TECHNOLOGY)
• 1045 Paracoccus denitrificansの脱窒系遺伝子群の発現解析
• 405 好熱嫌気性菌NA10株由来の多機能型セルラーゼの構造と機能
• 607 好熱嫌気性菌NA10株由来のβ-グルカナーゼ遺伝子の構造解析
• 228 Paracoccus denitrificansの脱窒系遺伝子群の構造解析
• Transcriptional Regulation of nir and nor Operons of Paracoccus denitrificans
• Cloning and Nucleotide Sequence of the Nitric Oxide Reductase Locus in Paracoccus denitrificans IFO 12442
• Magnetic separation of cells from developing embryoid bodies using magnetite cationic liposomes(CELL AND TISSUE ENGINEERING)
• Enhanced contractile force generation by artificial skeletal muscle tissues using IGF-I gene-engineered myoblast cells(CELL AND TISSUE ENGINEERING)
• 1Gp10 レトロウイルスインテグラーゼのSUMO化とその役割(セル&ティッシュエンジニアリング,一般講演)
• 1Fp16 口腔連鎖球菌Streptococcus属莢膜多糖生合成系遺伝子群の解析(遺伝子工学,一般講演)
• 1Fp15 ニワトリ卵白タンパク質におけるN結合型糖鎖附加能の解析(遺伝子工学,一般講演)
• Chicken oviduct-specific expression of transgene by a hybrid ovalbumin enhancer and the Tet expression system(GENETICS, MOLECULAR BIOLOGY, AND GENE ENGINEERING)
• Accumulative gene integration into a pre-determined site using Cre/loxP(CELL AND TISSUE ENGINEERING)
• Organization of the capsule biosynthesis gene locus of the oral streptococcus Streptococcus anginosus(GENETICS, MOLECULAR BIOLOGY, AND GENE ENGINEERING)
• Constitutive expression of the brg1 gene requires GC-boxes near to the transcriptional start site
• Hollow Fiber Bioreactor Perfusion Culture System for Magnetic Force-Based Skeletal Muscle Tissue Engineering
• Hollow Fiber Bioreactor Perfusion Culture System for Magnetic Force-Based Skeletal Muscle Tissue Engineering

もっと見る 閉じる

スポンサーリンク