Abstract
Transmembrane proteins (TMP) play a crucial role in several physiological processes. Despite their importance and diversity, only a few TMP structures have been determined by high-resolution protein structure characterization methods so far. Due to the low number of determined TMP structures, the parallel development of various bioinformatics and experimental methods was necessary for their topological characterization. The combination of these methods is a powerful approach in the determination of TMP topology as in the Constrained Consensus TOPology prediction. To support the prediction, we previously developed a high-throughput topology characterization method based on primary amino group-labelling that is still limited in identifying all TMPs and their extracellular segments on the surface of a particular cell type. In order to generate more topology information, a new step, a partial proteolysis of the cell surface has been introduced to our method. This step results in new primary amino groups in the proteins that can be biotinylated with a membrane-impermeable agent while the cells still remain intact. Pre-digestion also promotes the emergence of modified peptides that are more suitable for MS/MS analysis. The modified sites can be utilized as extracellular constraints in topology predictions and may contribute to the refined topology of these proteins.
Highlights
Transmembrane proteins (TMP) play a crucial role in several physiological processes
About 55% of the drugs currently approved by the Food and Drug Administration (FDA) target TMPs proving the importance of this class of proteins[1]
The state-of-the-art algorithms take into account the consensus of other methods (CCTOP15, TOPCONS16) and the best ones consider already known structural information about TMPs generated by various experimental techniques[15]
Summary
Transmembrane proteins (TMP) play a crucial role in several physiological processes. Despite their importance and diversity, only a few TMP structures have been determined by high-resolution protein structure characterization methods so far. Due to the low number of determined TMP structures, the parallel development of various bioinformatics and experimental methods was necessary for their topological characterization. We previously developed a high-throughput topology characterization method based on primary amino group-labelling that is still limited in identifying all TMPs and their extracellular segments on the surface of a particular cell type. Methods of high-resolution structural determination are constantly evolving, bioinformatics[3,8,9] and other experimental methods[10,11] have a great importance in the characterization of topology of TMPs. Topology defines the number and location of transmembrane segments (TMSs) along the protein sequence, as well as the orientation of the connecting loops relative to the membrane. The main disadvantage of these methods is that the modifications sometimes affect the location or function of the target protein, making the results ambiguous and unreliable[25,27,29]
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