We have been engaged in the research of the largest protein family since our group has been established. Numerous structure prediction methods have been developed based on protein sequence and structure analysis; such methods can be found on the CYSREDOX web server for the prediction of cystein residues participating in disulphide bonds. The concept of stabilization centers has been introduced for non-covalent crosslink playing a dominant role in protein structure stability. A new method has been developed for the prediction and identification of amino acids in these centers based on the amino acid sequence and on the protein structure, respectively (i.e. SCide, SCpred, SRide web servers). Among others, these results have been successfully applied for the analysis of the functionally regulated stability of MHC proteins and of the properties of TIM barrel structural elements, respectively, as well as for the demonstration of the divergent evolution of PD-(D/E)XK restriction endonucleases. The structural properties of several proteins have been determined by molecular mechanical and molecular dynamical tools. The role of the hydration sphere in protein – DNA recognition processes has been shown. Also, the role of metal ions in the functionality of endonucleases has been identified. Our most recent results are in the development of novel methodology for the modeling of biochemical reactions.

Our most recognized achievement of the past five years was the realization that disordered proteins have a higher mean energy than globular proteins. Based on this observation the partially or fully disordered proteins or protein segments can be distinguished using the protein sequence alone (see IUPred web server). It allowed to gain valuable insight concerning the intermolecular interactions of disordered proteins. This includes the uncovering of the role preformed structural elements and certain motifs play in protein-protein interactions. Furthermore, it enabled the verification of the abundance of disordered proteins among hubs in protein interaction networks and the significantly high occurrence of protein disorder in essential proteins. These fundamental results enabled the characterization of interacting regions in disordered proteins and the development of a prediction method called ANCHOR for the prediction of such disordered binding sites. We have also demonstrated the functional role of protein disorder in numerous cases, including the analysis of the dUTPase and transglutaminase substrate preference and the mediator complex involved in transcriptional regulation.