posted on 2022-02-11, 15:10authored byChengfei Ruan, Jiahua Zhou, Zhouxian Li, Kejia Li, Zheng Fang, Xiaolei Zhang, Mingliang Ye
Recently,
numerous efforts have been devoted to identifying drug
targets and binding sites in complex proteomes, which is of great
importance in modern drug discovery. In this study, we developed a
robust lysine reactivity profiling method to systematically study
drug-binding targets and binding sites at the proteome level. This
method is based on the principle that binding of a drug to a specific
region of target proteins will change the reactivity of lysine residues
that are located at this region, and these changes can be detected
with an enrichable and lysine reactive probe. Coupled with data-independent
acquisition (DIA), the known target proteins and corresponding binding
sites were successfully revealed from K562 cell lysates for three
model drugs: geldanamycin, staurosporine, and dasatinib. In addition,
the drug-induced conformational changes of certain targets were also
revealed by our method during the screening of staurosporine. The
screening sensitivity of our method revealed from the screening of
stuarosporine and dasatinib was comparable with that of thermal proteome
profiling (TPP) or machine learning-based limited proteolysis (LiP-Quant).
Overall, 21 and 4 kinase targets, including adenosine 5′-triphosphate
(ATP)-binding targets, were identified for staurosporine and dasatinib
in K562 cell lysates, respectively. We found that target proteins
identified by TPP, LiP-Quant, and our method were complementary, emphasizing
that the development of new methods that probe different properties
of proteins is of great importance in drug target deconvolution. We
also envision further applications of our method in proteome-wide
probing multiple events that involve lysine reactivity changes.