PMID: 4901474Aug 1, 1969Paper

Bacteriophage T4 DNA-dependent in vitro synthesis of lysozyme

Proceedings of the National Academy of Sciences of the United States of America
M Schweiger, L M Gold

Abstract

A cell-free system derived from uninfected Escherichia coli previously was shown to synthesize beta-glucosyl transferase in response to T4 DNA. This same in vitro system, when incubated at slightly higher magnesium concentrations, also synthesized enzymatically active lysozyme. The lysozyme activity that appeared was judged to be T4-specific since antibodies prepared against authentic T4-lysozyme inactivated the in vitro synthesized enzyme. DNA from a T4 mutant carrying a deletion in the lysozyme gene stimulated amino acid incorporation to the same extent as wild-type T4 DNA but was inactive in directing the synthesis of lysozyme. Various inhibitors of RNA and protein synthesis inhibited the in vitro synthesis of lysozyme.

References

Mar 1, 1969·Proceedings of the National Academy of Sciences of the United States of America·L M Gold, M Schweiger
Jun 28, 1968·Journal of Molecular Biology·T KasaiW Szybalski
Apr 1, 1966·Proceedings of the National Academy of Sciences of the United States of America·J J Protass, D Korn
Aug 1, 1966·Journal of Molecular Biology·E P GeiduschekM Sarnat
Feb 14, 1968·Journal of Molecular Biology·G StreisingerM Inouye
May 14, 1969·Journal of Molecular Biology·T Kasai, E K Bautz
Aug 5, 1967·Nature·W SalserA Bolle
Jul 1, 1964·Journal of Molecular Biology·B D HALLM H GREEN

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Citations

Jan 1, 1971·Molecular & General Genetics : MGG·P HerrlichW Sauerbier
Feb 1, 1971·Proceedings of the National Academy of Sciences of the United States of America·M E Morris, H Gould
Jul 25, 1986·Nucleic Acids Research·D S McPheetersL Gold
Sep 1, 1973·Virology·F Hagen, E T Young
Mar 1, 1978·Analytical Biochemistry·L S Johnston, F C Neuhaus
Aug 15, 1980·Cellular Immunology·S Bordin, E T Young
Sep 14, 1971·Journal of Molecular Biology·E N BrodyL W Black
Dec 1, 1972·Archives of Biochemistry and Biophysics·R Callahan, P Leder
Dec 1, 1972·Archives of Biochemistry and Biophysics·P LederR Callahan
Jun 14, 1971·Journal of Molecular Biology·D Hirsh, L Gold
Jun 14, 1971·Journal of Molecular Biology·F C DohanA Torriani
Nov 25, 1970·Biochemical and Biophysical Research Communications·J Y Chou
Jan 1, 1971·Virology·J M Wilhelm, R Haselkorn
Mar 10, 1972·Biochemical and Biophysical Research Communications·J M WilhelmE P Geiduschek
May 25, 1977·Journal of Molecular Biology·S I Feinstein, S Altman
Dec 5, 1975·Journal of Molecular Biology·M M ComerW H McClain
Aug 5, 1974·Biochemical and Biophysical Research Communications·H B Jensen, I F Pryme
Oct 15, 1971·Biochemical and Biophysical Research Communications·W C Summers, K Jakes
Sep 1, 1971·Angewandte Chemie·G Schreiber
Dec 1, 1976·European Journal of Biochemistry·A Crimaldi, G Ihler
Mar 1, 1981·Microbiological Reviews·D H Krüger, C Schroeder
Dec 1, 1970·Journal of Virology·P Herrlich, M Schweiger
May 1, 1979·Journal of Virology·L Mindich, J Lehman

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