Dual energy landscape: The functional state of the β-barrel outer membrane protein G molds its unfolding energy landscape

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • Mehdi Damaghi - , TUD Dresden University of Technology (Author)
  • K. Tanuj Sapra - , TUD Dresden University of Technology (Author)
  • Stefan Köster - (Author)
  • Özkan Yildiz - (Author)
  • Werner Kühlbrandt - (Author)
  • Daniel J. Muller - , Chair of Cellular Machines (Author)

Abstract

We applied dynamic single-molecule force spectroscopy to quantify the parameters (free energy of activation and distance of the transition state from the folded state) characterizing the energy barriers in the unfolding energy landscape of the outer membrane protein G (OmpG) from Escherichia coli. The pH-dependent functional switching of OmpG directs the protein along different regions on the unfolding energy landscape. The two functional states of OmpG take the same unfolding pathway during the sequential unfolding of β-hairpins I-IV. After the initial unfolding events, the unfolding pathways diverge. In the open state, the unfolding of β-hairpin V in one step precedes the unfolding of β-hairpin VI. In the closed state, β-hairpin V and β-strand S11 with a part of extracellular loop L6 unfold cooperatively, and subsequently β-strand S12 unfolds with the remaining loop L6. These two unfolding pathways in the open and closed states join again in the last unfolding step of β-hairpin VII. Also, the conformational change from the open to the closed state witnesses a rigidified extracellular gating loop L6. Thus, a change in the conformational state of OmpG not only bifurcates its unfolding pathways but also tunes its mechanical properties for optimum function.

Details

Original languageEnglish
Pages (from-to)4151-4162
Number of pages12
JournalProteomics
Volume10
Issue number23
Publication statusPublished - Dec 2010
Peer-reviewedYes

External IDs

PubMed 21058339

Keywords

ASJC Scopus subject areas

Keywords

  • Atomic force microscopy, Interactions, Mechanical properties, Nanoproteomics, PH gating, Single-molecule force spectroscopy