Initiation of Solution NMR Studies on the Bacterial Cell Division Regulator MinD

Abstract

Bacterial cell division relies on the cell division septum to form at the mid-cell position. In gram negative bacteria, this is mediated by three proteins, MinC, MinD and MinE. Together these proteins interact with each other and the membrane in a dynamic, oscillating process which prevents cell division septum formation at the cell poles. The early phase of this process involves MinD binding to the membrane, which is triggered upon binding of ATP. Subsequent interactions with MinE result in stimulation of the ATPase activity of MinD. After hydrolysis, MinD is released from the membrane and diffuses to a new binding site. Many in silico models have been constructed of the Min system in an attempt to describe its self-organizing behaviour. A limitation of these models is that, in order to prevent rapid re-binding of MinD to the membrane after hydrolysis of ATP, the exchange of bound ADP for ATP is assumed to be a slow process, on the order of 1/s . In order to provide experimental evidence of the rate of nucleotide binding, we performed a series of triple-resonance NMR experiments to complete a partial assignment of backbone atom resonances, which required the application of deuterium labelling and amino acid-specific selective unlabelling. After the introduction of ATP, it was discovered that no dimerization had been induced, in contrast with existing literature. It was proposed that MinD from N. gonorrhoeae only forms a dimer in the presence of a membrane, while literature with MinD from E. coli shows it does not have this requirement. Interestingly while dimerization had not been induced, there was a persistent population of dimeric species even in the absence of nucleotide. This was discovered to be the result of disulfide formation, likely an artifact of established purification protocols. Binding of both ADP and ATP to MinD were studied by titration using NMR, with the relative affinity of both nucleotides to MinD being indistinguishable. By analyzing peak coalescence in the half-bound condition, a maximum rate was determined for nucleotide binding, with the lifetime being on the order of 170ms. Results from this experiment support models requiring a slow nucleotide binding step, and help enhance understanding of how Min proteins sustain oscillations required for normal cell division.