posted on 2015-08-18, 00:00authored byShenheng Guan, Michael J. Trnka, David A. Bushnell, Philip J. J. Robinson, Jason E. Gestwicki, Alma L. Burlingame
In native mass spectrometry, it has
been difficult to discriminate
between specific bindings of a ligand to a multiprotein complex target
from the nonspecific interactions. Here, we present a deconvolution
model that consists of two levels of data reduction. At the first
level, the apparent association binding constants are extracted from
the measured intensities of the target/ligand complexes by varying
ligand concentration. At the second level, two functional forms representing
the specific and nonspecific binding events are fit to the apparent
binding constants obtained from the first level of modeling. Using
this approach, we found that a power-law distribution described nonspecific
binding of α-amanitin to yeast RNA polymerase II. Moreover,
treating the concentration of the multiprotein complex as a fitting
parameter reduced the impact of inaccuracies in this experimental
measurement on the apparent association constants. This model improves
upon current methods for separating specific and nonspecific binding
to large, multiprotein complexes in native mass spectrometry, by modeling
nonspecific binding with a power-law function.