Loren M. LaPointe, Keenan C. Taylor, Sabareesh Subramaniam, Ambalika Khadria, Ivan Rayment, Alessandro Senes

"Structural organization of FtsB, a transmembrane protein of the bacterial divisome"

Biochemistry 2013 52 2574-85

Abstract We report the first structural analysis of an integral membrane protein of the bacterial divisome. FtsB is a single-pass membrane protein with a periplasmic coiled coil. Its heterologous association with its partner FtsL represents an essential event for the recruitment of the late components to the division site. Using a combination of mutagenesis, computational modeling and X-ray crystallography, we determined that FtsB self-associates and we investigated its structural organization. We found that the transmembrane domain of FtsB homo-oligomerizes through an evolutionarily conserved interaction interface where a polar residue (Gln 16) plays a critical role through the formation of an inter-helical hydrogen bond. The crystal structure of the periplasmic domain, solved as a fusion with Gp7, shows that 30 juxta-membrane amino acids of FtsB form a canonical coiled coil. The presence of conserved Gly residue in the linker region suggests that flexibility between the transmembrane and coiled coil domains is functionally important. We hypothesize that the transmembrane helices of FtsB form a stable dimeric core for its association with FtsL into a higher-order oligomer, and that FtsL is required to stabilize the periplasmic domain of FtsB, leading to the formation of a complex that is competent for binding to FtsQ, and to their consequent recruitment to the divisome. The study provides an experimentally validated structural model and identifies point mutations that disrupt association, thereby establishing important groundwork for the functional characterization of FtsB in vivo.

Structural files:

  • Crystal structure of Gp7-FtsB-28-63: 4IFF.pdb
  • Computational model of the FtsB transmembrane dimer (Model 1): Model1.pdb
  • Computational model of the FtsB transmembrane dimer (alternative model, Model 2): Model2.pdb
Alessandro Senes
Associate Professor
Department of Biochemistry - UW-Madison
433 Backcock Dr., Room 419
Madison, WI 53706
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