Tag Archives: binding sites

Plasminogen fragments K 1-3 and K 5 bind to different sites in fibrin fragment DD

T. V. Grinenko, L. G. Kapustianenko, T. A. Yatsenko, O. I. Yusova, V. N. Rybachuk

Palladin Institute of Biochemistry, National Academy of Sciences of Ukraine, Kyiv;
e-mail: grinenko@biochem.kiev.ua

Specific plasminogen-binding sites of fibrin molecule are located in Аα148-160 regions of C-terminal domains. Plasminogen interaction with these sites initiates the activation process of proenzyme and subsequent fibrin lysis. In this study we investigated the binding of plasminogen fragments K 1-3 and K 5 with fibrin fragment DD and their effect on Glu-plasminogen interaction with DD. It was shown that the level of Glu-plasminogen binding to fibrin fragment DD is decreased by 50-60% in the presence of K 1-3 and K 5. Fragments K 1-3 and K 5 have high affinity to fibrin fragment DD (Kd is 0.02 for K 1-3 and 0.054 μМ for K 5). K 5 interaction is independent and K 1-3 is partly dependent on C-terminal lysine residues. K 1-3 interacts with complex of fragment DD-immobilized K 5 as well as K 5 with complex of fragment DD-immobilized K 1-3. The plasminogen fragments do not displace each other from binding sites located in fibrin fragment DD, but can compete for the interaction. The results indicate that fibrin fragment DD contains different binding sites for plasminogen kringle fragments K 1-3 and K 5, which can be located close to each other. The role of amino acid residues of fibrin molecule Аα148-160 region in interaction with fragments K 1-3 and K 5 is discussed.

Analysis of conformational flexibility of loop 110-120 of protein tyrosine phosphatase 1B

V. Yu. Tanchuk, V. O. Tanin, A. I. Vovk

Institute of Bioorganic Chemistry and Petrochemistry,
National Academy of Sciences of Ukraine, Kyiv;
e-mail: v_tanchuk@yahoo.com; vovk@bpci.kiev.ua

Conformations of the catalytic center of protein tyrosine phosphatase 1B (PTP1B) and surrounding loops are known to be important in catalysis and inhibition of the enzyme. There were 98 conformations from 88 PDB files representing PTP1B with different ligands which were analyzed to investigate the details of loop 110-120 movement and mobility of separate residues. The differences were identified by a special software tool which performs multiple comparisons of selected parts of PDB files. The conformations were divided into 6 clusters. It was found that the loop formed by residues 110-120 can be characterized by four main conformations. Predominantly, the loop 110-120 adopts the main conformation and keeps it during WPD loop movement. Three other conformations appear to be stabilized in case of closed WPD loop and seem to be favorable for PTP1B with subunit structure.