Comparative study of recombinant rat nucleoside diphosphate kinases alpha and beta by intrinsic protein fluorescence.

Nucleoside diphosphate (NDP) kinases of mammals are hexamers of two sorts of randomly associated highly homologous subunits of 152 residues each and, therefore exist in cell as NDP kinase isoforms. The catalytic properties and three-dimensional structures of the isoforms are very similar. The physiological meaning of the existence of the isoforms in cells remained unclear, but studying recombinant rat NDP kinases alpha and beta, each containing only one sort of subunits, we discovered that, in contrast to the isoenzyme beta, NDP kinase alpha is able to interact with the complex between bleached rhodopsin and G-protein transducin in retinal rod membranes at lowered pH values (Orlov et al. FEBS Lett. 389, 186-190, 1996). In order to search for possible molecular basis of such differences between these isoenzymes, a detailed comparative study of their intrinsic fluorescence properties in a large range of solvent conditions was performed in this work. The isoenzymes alpha and beta both contain the same three tryptophan (Trp78, 133, Ind 149) and four tyrosine (Tyr 52, 67, 147, and 151) residues per subunit, but exhibit pronounced differences in their fluorescence properties (both in spectral positions and shape and quantum yield values) and behave differently under pH titration. Whereas NDP kinase alpha undergoes spectral changes in the pH range 5-7 with the mid-point at 6.2, no unequivocal indication of a structural change of NDP kinase beta under pH titration from 9 to 5 was obtained. Since the pH dependencies obtained for fluorescence of isoenzyme alpha resembles the dependence of its binding to the rhodopsin-transducin complex it was suggested that the differences between the NDP kinase isoenzymes alpha and beta in the pH-induced behavior, revealed by the fluorescence spectroscopy, and the differences in their ability to interact with rhodopsin-transducin complex may have the same physical nature, that would be a physico-chemical reason of possible functional dissimilarity of NDP kinase isoforms in cell. An additional analysis of three-dimensional structure of homologous NDP kinases revealed that the source of the differences in fluorescence properties and pH-titration behavior between the isoenzymes alpha and beta may be due to the difference in their global electrostatic charges, rather than to any structural differences between them at neutral pH. The unusually high positive electrostatic potential at he deeply buried active site Tyr52 makes possible that it exists in deprotonated tyrosinate form at neutral and moderately acidic solution. Such a possibility may account for rather unusual fluorescence properties of NDP kinase alpha: (i) rather long-wavelength emission of NDP kinase alpha at ca. 340 nm at pH ca. 8 at extremely low accessibility to external quenchers and, possibly, (ii) an unusually high quantum yield value (ca. 0.42).

Overexpression of nucleoside diphosphate kinases induces neurite outgrowth and their substitution to inactive forms leads to suppression of nerve growth factor- and dibutyryl cyclic AMP-induced effects in PC12D cells.

Whether nucleoside diphosphate kinase (NDPK) is involved in neuronal differentiation was investigated with special reference to its enzyme activity. Neurite outgrowth of PC12D cells induced by nerve growth factor or a cyclic AMP analog was suppressed to some extent when inactive NDPKs (the active site histidine 118 was replaced with alanine), not active forms, were transiently overexpressed. This suppression was more definite in their stably expressed clones. NDPKbeta-transfected clones and, to a lesser extent, NDPKalpha-transfected clones, but not inactive NDPK-transfected clones, extended neurites without differentiation inducers. These results imply that NDPKs may play a role by exerting their enzyme activity during differentiation of PC12 cells.

Interaction of nucleoside diphosphate kinase with membranes of bleached bovine retinal rod outer segments. Effects of pH, salts, and guanine nucleotides.

Soluble nucleoside diphosphate (NDP) kinase in purified bovine retinal rod outer segment (ROS) preparations exhibit equilibrium binding to bleached photoreceptor membranes. The binding is under the control of pH and concentration of salts (NaCl, KCl, CaCl2, or MgCl2). Acidic pH and low ionic strength favor the membrane-bound form. It was found that: 1) the membrane-bound NDP kinase is released by the presence of low concentrations of guanosine 5;-O-(3-thio)triphosphate (GTP[S]), GTP, and other related compounds, whereas adenosine 5;-(beta,gamma-imino)triphosphate (AdoPP(NH)P) is ineffective under similar conditions; 2) the binding of NDP kinase to bleached ROS membranes required the presence ROS G-protein transducin (Gt); and 3) Gt-depleted ROS membranes were still able to bind NDP kinase, whereas its apparent affinity was weak and unaffected by GTP[S]. These results imply that GTP[S]-dependent interaction of NDP kinase with the membranes in the presence of bleached visual pigment rhodopsin is mediated by Gt. The possible participation of NDP kinase in extremely rapid photoactivation of Gt in in vivo ROS is discussed.

Transducin-mediated, isoform-specific interaction of recombinant rat nucleoside diphosphate kinases with bleached bovine retinal rod outer segment membranes.

The properties of the binding of recombinant rat nucleoside diphosphate (NDP) kinase isoforms alpha and beta (NDP kinase alpha and beta, respectively) to bleached bovine retinal rod outer segment (ROS) membranes were investigated. It was found that: (1) both NDP kinase isoforms interacted with ROS membranes in a pH-, cation- and GTPgammaS-dependent manner; (2) the retinal G-protein transducin was an obligatory factor for the interaction; (3) the apparent affinity of NDP kinase alpha for ROS membranes was about 100-fold higher than that of NDP kinase beta; and (4) an alpha-isoform-specific peptide, corresponding to the sequence of the N-terminal third (variable region), had the ability to displace bovine NDP kinase from ROS membranes. The results suggest the possible involvement of NDP kinases in cellular regulation via interaction with G-proteins and provide a structural basis for the possible differential roles of mammalian NDP kinase isoforms in the cell.

Calcium-regulated interactions of human alpha-lactalbumin with bee venom melittin.

Affinity chromatography, fluorescence and circular dichroism spectroscopy methods have been used to study the interaction of melittin, a 26-residue peptide from bee venom, with Ca2(+)-binding alpha-lactalbumin from human milk. It has been revealed that melittin binds to the apo- and acidic states of alpha-lactalbumin while the presence of Ca2+ makes the interaction essentially weaker. The association constant for the complex of melittin with apo-alpha-lactalbumin determined from spectropolarimetric melittin-titration data is 2 X 10(7) M-1. The complexation of alpha-lactalbumin with melittin decreases its affinity to Ca2+ by three orders of magnitude. The interaction of apo-alpha-lactalbumin with melittin causes some changes in the environment of its aromatic amino acid residues and drastically alters the conformation of melittin, increasing its alpha-helical content but leaving its single tryptophan residue accessible to water. In the case of the acidic state of alpha-lactalbumin the interaction does not induce an increase in alpha-helical content of melittin.

Effects of cation binding on the thermal transitions in calmodulin.

The thermal transitions in different forms of bovine brain calmodulin (0, 1, 2, 3 and 4 bound Ca2+ ions per molecule) have been studied by means of microcalorimetry, intrinsic tyrosine fluorescence, circular dichroism and infrared spectroscopy. The heating of the apoprotein from 5 to 110 degrees C induces at least three unfolding transitions. The heating of Ca2+-loaded calmodulin causes at least two structural transitions, one of which occurs at relatively low temperatures, from approx. 30 to approx 50 degrees C. The binding of the biologically significant Ca2+, Mg2+, Na+ and K+ ions has been measured at 12, 20, 28, 37 and 50 degrees C by means of the fluorescence method. The values of the binding parameters for these cations do not depend on temperature within the range 12 to 50 degrees C. It has been proposed that the temperature independence of the metal-ion-binding properties of calmodulin is achieved due to the temperature-induced structural changes, which adjust the protein conformation in such a way that the protein-binding parameters remain constant.