Uptake of environmental DNA in Bacillus subtilis occurs all over the cell surface through a dynamic pilus structure.

At the transition to stationary phase, a subpopulation of Bacillus subtilis cells can enter the developmental state of competence, where DNA is taken up through the cell envelope, and is processed to single stranded DNA, which is incorporated into the genome if sufficient homology between sequences exists. We show here that the initial step of transport across the cell wall occurs via a true pilus structure, with an average length of about 500 nm, which assembles at various places on the cell surface. Once assembled, the pilus remains at one position and can be retracted in a time frame of seconds.

Fortuitously compatible protein surfaces primed allosteric control in cyanobacterial photoprotection.

Highly specific interactions between proteins are a fundamental prerequisite for life, but how they evolve remains an unsolved problem. In particular, interactions between initially unrelated proteins require that they evolve matching surfaces. It is unclear whether such surface compatibilities can only be built by selection in small incremental steps, or whether they can also emerge fortuitously.

Single-Molecule Dynamics of DNA Receptor ComEA, Membrane Permease ComEC, and Taken-Up DNA in Competent Bacillus subtilis Cells.

In competent Gram-negative and Gram-positive bacteria, double-stranded DNA is taken up through the outer cell membrane and/or the cell wall and is bound by ComEA, which in Bacillus subtilis is a membrane protein. DNA is converted to single-stranded DNA and transported through the cell membrane via ComEC. We show that in Bacillus subtilis, the C terminus of ComEC, thought to act as a nuclease, is important not only for DNA uptake, as judged from a loss of transformability, but also for the localization of ComEC to the cell pole and its mobility within the cell membrane.