Step toward Probing the Nonannular Belt of Membrane Proteins

Integral membrane proteins are embedded in the biological membrane, where they carry out numerous biological processes. Although lipids present in the membrane are crucial for membrane protein function, it remains difficult to characterize many lipid binding events to membrane proteins, such as those that form the annular belt. Here, we use native mass spectrometry along with the charge-reducing properties of trimethylamine N-oxide (TMAO) to characterize a large number of lipid binding events to the bacterial ammonia channel (AmtB). In the absence of TMAO, significant peak overlap between neighboring charge states is observed, resulting in erroneous abundances for different molecular species. With the addition of TMAO, the weighted average charge state (Zavg) was decreased. In addition, the increased spacing between nearby charge states enabled a higher number of lipid binding species to be observed while minimizing mass spectral peak overlap. These conditions helped us to determine the equilibrium binding constants (Kd) for up to 16 lipid binding events. The binding constants for the first few lipid binding events display the highest affinity, whereas the binding constants for higher lipid binding events converge to a similar value. These findings suggest a transition from nonannular to annular lipid binding to AmtB.

Automated summary

This study used native mass spectrometry and trimethylamine N-oxide (TMAO) as a charge-reducing agent to characterize lipid binding events to the bacterial ammonia channel (AmtB). The results showed that the addition of TMAO decreased the average charge state and increased the spacing between nearby charge states, allowing for the observation of more lipid binding events and determination of binding constants. The binding constants for higher lipid binding events converged to a similar value, suggesting a transition from nonannular to annular lipid binding to AmtB.