Sonia Trigueros1, Joaquim Roca. 1. Institut de Biologia Molecular de Barcelona, CSIC, Jordi Girona 18-26, 08034 Barcelona, Spain.
Abstract
BACKGROUND: Type II topoisomerases are a highly conserved class of enzymes which transport one double-stranded DNA segment through a transient break in another. Whereas the eukaryotic enzymes are homodimers of a single polypeptide, their bacterial homologues are homodimers of two independently coded protein subunits. Unlike eukaryotic topoisomerase II and bacterial topoisomerase IV, DNA gyrase is a bacterial type II topoisomerase which specializes in intramolecular DNA transport. RESULTS: We have fused the Escherichia coli coding sequences for the proteins GyrB and GyrA, which comprise DNA gyrase. This fusion was expressed in yeast cells and yielded the expected full-length protein product. When it was expressed in Deltatop1- top2-4 yeast cells, the fusion protein compensated their slow growth and reverted their elevated chromosomal excision of ribosomal genes. Furthermore, it removed DNA positive supercoils. The fusion protein, however, was unable to complement the temperature-dependent lethality of top2-4 cells. CONCLUSION: Fusion of the E. coli GyrB and GyrA proteins leads to a catalytically active topoisomerase which compensates several phenotypic traits attributed to unconstrained DNA supercoiling in topoisomerase-deficient cells. However, since the fusion protein cannot substitute for topoisomerase II, it may be efficient in intramolecular but not intermolecular DNA passage, resembling the catalytic properties of DNA gyrase.
BACKGROUND: Type II topoisomerases are a highly conserved class of enzymes which transport one double-stranded DNA segment through a transient break in another. Whereas the eukaryotic enzymes are homodimers of a single polypeptide, their bacterial homologues are homodimers of two independently coded protein subunits. Unlike eukaryotic topoisomerase II and bacterial topoisomerase IV, DNA gyrase is a bacterial type II topoisomerase which specializes in intramolecular DNA transport. RESULTS: We have fused the Escherichia coli coding sequences for the proteins GyrB and GyrA, which comprise DNA gyrase. This fusion was expressed in yeast cells and yielded the expected full-length protein product. When it was expressed in Deltatop1- top2-4 yeast cells, the fusion protein compensated their slow growth and reverted their elevated chromosomal excision of ribosomal genes. Furthermore, it removed DNA positive supercoils. The fusion protein, however, was unable to complement the temperature-dependent lethality of top2-4 cells. CONCLUSION: Fusion of the E. coli GyrB and GyrA proteins leads to a catalytically active topoisomerase which compensates several phenotypic traits attributed to unconstrained DNA supercoiling in topoisomerase-deficient cells. However, since the fusion protein cannot substitute for topoisomerase II, it may be efficient in intramolecular but not intermolecular DNA passage, resembling the catalytic properties of DNA gyrase.
Authors: Benjamin D Bax; Pan F Chan; Drake S Eggleston; Andrew Fosberry; Daniel R Gentry; Fabrice Gorrec; Ilaria Giordano; Michael M Hann; Alan Hennessy; Martin Hibbs; Jianzhong Huang; Emma Jones; Jo Jones; Kristin Koretke Brown; Ceri J Lewis; Earl W May; Martin R Saunders; Onkar Singh; Claus E Spitzfaden; Carol Shen; Anthony Shillings; Andrew J Theobald; Alexandre Wohlkonig; Neil D Pearson; Michael N Gwynn Journal: Nature Date: 2010-08-04 Impact factor: 49.962