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An orthogonal single-molecule experiment reveals multiple-attempt dynamics of type IA topoisomerases.

Kathryn H GunnJohn F MarkoAlfonso Mondragón
Published in: Nature structural & molecular biology (2017)
Topoisomerases are enzymes that are involved in maintaining the topological state of cellular DNA. Their dynamic characteristics remain poorly understood despite numerous structural, biophysical and biochemical studies. Recent single-molecule experiments revealed that an important feature of the type IA topoisomerase mechanism is the presence of pauses between relaxation events. However, these experiments could not determine whether the protein remains DNA bound during the pauses or what relationship may exist between protein domain movements and topological changes in the DNA. By combining two orthogonal single-molecule techniques, we found that E. coli topoisomerase I constantly changes conformation when attempting to modify the topology of DNA, but succeeds in only a fraction of the attempts. Thus, its mechanism can be described as a series of DNA strand-passage attempts that culminate in a successful relaxation event.
Keyphrases
  • single molecule
  • atomic force microscopy
  • living cells
  • escherichia coli
  • circulating tumor
  • machine learning
  • amino acid
  • protein protein
  • case control