Hiroyuki Kamiya spends much of his time researching Biochemistry, Molecular biology, DNA, Nucleotide and Mutagenesis. The concepts of his Molecular biology study are interwoven with issues in Mutation, 3T3 cells, Gene, Transfection and Coding strand. His DNA research includes themes of Photochemistry, Endocytosis and Escherichia coli.
His study in Nucleotide is interdisciplinary in nature, drawing from both Deoxyguanosine and Enzyme. His study explores the link between Mutagenesis and topics such as Point mutation that cross with problems in Deoxyuridine and Base pair. The study incorporates disciplines such as DNA polymerase I and Primer in addition to DNA polymerase.
Hiroyuki Kamiya focuses on Molecular biology, DNA, Biochemistry, Gene and Plasmid. His Molecular biology research is multidisciplinary, incorporating perspectives in Mutation, Mutagenesis, Transgene, Transfection and DNA polymerase. His work in DNA covers topics such as Stereochemistry which are related to areas like Duplex.
His Biochemistry research focuses on Nucleotide, Escherichia coli, Enzyme, Hydrolysis and DNA damage. In general Gene, his work in Gene expression, Frameshift mutation and Expression vector is often linked to Phagemid linking many areas of study. His Plasmid research includes themes of HeLa and DNA sequencing.
His primary areas of study are Molecular biology, DNA, Plasmid, Gene and Duplex. He has included themes like Biochemistry, Mutant, Guanine, DNA polymerase and Transcription in his Molecular biology study. His research in Mutant intersects with topics in Mutation and Escherichia coli.
His studies in DNA polymerase integrate themes in fields like Base pair and DNA polymerase II. His work on DNA replication, DNA repair and Homologous recombination as part of general DNA research is frequently linked to Short tract gene conversion and Reduction, bridging the gap between disciplines. Hiroyuki Kamiya has researched Plasmid in several fields, including Transfection, Transgene and AP site.
His main research concerns Molecular biology, Plasmid, DNA, Transgene and Nuclease. His Molecular biology research includes elements of Nucleobase, AP site, Biochemistry, Transfection and Guanine. His Plasmid study deals with the bigger picture of Gene.
His study of DNA Repair Protein is a part of DNA. His Transgene study combines topics in areas such as Coactivator, Histone acetyltransferase, Histone, Reporter gene and DNA-binding domain. As part of the same scientific family, Hiroyuki Kamiya usually focuses on Nuclease, concentrating on Stereochemistry and intersecting with Cleavage.
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Transferrin-modified liposomes equipped with a pH-sensitive fusogenic peptide: an artificial viral-like delivery system.
Tomoyuki Kakudo;Shinji Chaki;Shiroh Futaki;Ikuhiko Nakase.
Mutagenic potentials of damaged nucleic acids produced by reactive oxygen/nitrogen species: approaches using synthetic oligonucleotides and nucleotides SURVEY AND SUMMARY
Nucleic Acids Research (2003)
MITO-Porter : a liposome-based carrier system for delivery of macromolecules into mitochondria via membrane fusion
Yuma Yamada;Hidetaka Akita;Hiroyuki Kamiya;Kentaro Kogure.
Biochimica et Biophysica Acta (2008)
The Oxidized Forms of dATP Are Substrates for the Human MutT Homologue, the hMTH1 Protein
Katsuyoshi Fujikawa;Hiroyuki Kamiya;Hiroyuki Yakushiji;Yoshimitsu Fujii.
Journal of Biological Chemistry (1999)
c-Ha-ras containing 8-hydroxyguanine at codon 12 induces point mutations at the modified and adjacent positions.
Hiroyuki Kamiya;Kazunobu Miura;Hiroyuki Ishikawa;Hideo Inoue.
Cancer Research (1992)
Formation of 2-Hydroxydeoxyadenosine Triphosphate, an Oxidatively Damaged Nucleotide, and Its Incorporation by DNA Polymerases STEADY-STATE KINETICS OF THE INCORPORATION
Hiroyuki Kamiya;Hiroshi Kasai.
Journal of Biological Chemistry (1995)
Design of RNA enzymes distinguishing a single base mutation in RNA
Makoto Koizumi;Yoji Hayase;Shigenori Iwai;Hiroyuki Kamiya.
Nucleic Acids Research (1989)
Mechanism of improved gene transfer by the N-terminal stearylation of octaarginine: enhanced cellular association by hydrophobic core formation.
I A Khalil;S Futaki;M Niwa;Y Baba;Y Baba.
Gene Therapy (2004)
8-Hydroxyadenine (7,8-dihydro-8-oxoadenine) induces misincorporation in in vitro DNA synthesis and mutations in NIH 3T3 cells.
Hiroyuki Kamiya;Hiroyuki Miura;Naoko Murata-Kamiya;Hiroyuki Ishikawa.
Nucleic Acids Research (1995)
8-Hydroxyguanine (7,8-dihydro-8-oxoguanine) in hot spots of the c-Ha-ras gene: effects of sequence contexts on mutation spectra
Hiroyuki Kamiya;Naoko Murata-Kamiya;Shiro Koizume;Hideo Inoue.
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