Abstract
Background: At the cellular level, normal chromosome segregation is ensured by the intrinsic mechanics of mitosis and the proper functioning of the error-checking spindle assembly checkpoint (SAC). Protein Mad1 (the mitotic arrest-deficient), an important SAC component, plays a crucial role in avoiding cellular aneupoidy, a state leading to genetic diseases such as cancer or bipolar disorder.
Objective: To clarify the role of aneuploidy in genetic diseases, a number of wild type (wt) and mutant spindle checkpoint proteins have been studied, but till now the process is not well understood.
Method: Here, we report a number of 32 Mad1 mutants (8 already known to induce aneuploidy or Mad1 dimer destabilization and 24 de novo mutants designed by us) comprising mutation in the carboxi-terminal domain (CTD) represented by residues 598-718. Their molecular features (electronic, steric, and also the descriptors derived directly from amino acids sequence: counts of atom and bound types, dihedral angles) were calculated and compared by structure-activity relationships methods (SAR) in order to elucidate their possible contribution to aneuploidy.
Results: Our results suggest that some molecular descriptors of Mad1-CTD mutants and wt Mad1, like accessible solvent surface areas and its derivatives, could be important for predicting aneuploidy induced by Mad1 improper function.
Conclusion: It was found that molecular descriptors of Mad1 wt and mutants evaluated here are important resources for upcoming computational studies focused on aneuploidy, provided kinetic data about Mad1- kinetocore and/or Mad1-Bub1 interactions
Keywords: Aneuploidy, computational mutagenesis, genetic disorder, Mad1 mutants, SAR, molecular descriptors.
Graphical Abstract