Competitive binding assays for high-affinity binders in the presence of endogenous ligands: application to biotin-binding proteins

Endogenous ligands complicate radioligand-binding assays of high-affinity binding proteins by obscuring binding sites or by diluting the labeled ligand. We have developed a mathematical model for such systems where radioligand and endogenous ligand are structurally identical. Data which relate radioligand binding at equilibrium as a function of sample volume can be plotted such that the concentrations of endogenous ligand and binder are graphically determined; however, a more precise determination may be done by nonlinear regression with the aid of a microcomputer. The method is demonstrated for the assay of biotin-binding proteins in the presence of a range of endogenous biotin concentrations below and above that required to saturate the binding sites.     

Target selectivity in EF-hand calcium binding proteins

EF-hand calcium binding proteins have remarkable sequence homology and structural similarity, yet their response to binding of calcium is diverse and they function in a wide range of biological processes. Knowledge of the fine-tuning of EF-hand protein sequences to optimize specific biochemical properties has been significantly advanced over the past 10 years by determination of atomic resolution structures. These data lay the foundation for addressing how functional selectivity is generated from a generic ionic signal. This review presents current ideas about the structural mechanisms that provide the selectivity of different EF-hand proteins for specific cellular targets, using S100 and calmodulin family proteins to demonstrate the critical concepts. Three factors contribute significantly to target selectivity: molecular architecture, response to binding of Ca(2+) ions, and the characteristics of target binding surfaces. Comparisons of calmodulin and S100 proteins provide insights into the role these factors play in facilitating the variety of binding configurations necessary for recognizing a diverse set of targets.     

Identification of bovine brain calcium binding proteins

Three peaks of calcium binding activity have been identified by the Chelex-100 calcium binding assay of the fractions from DEAE cellulose chromatography of 100,000 X g supernatant of bovine brain. These calcium binding activity peaks have been subjected to extensive purification and three novel calcium binding proteins (Mr 27,000, Mr 48,000 and Mr 63,000) and two previously characterized proteins (calcineurin and calmodulin) have been identified as components of calcium binding activity peaks. Analysis of the calcium binding properties of the novel proteins by equilibrium dialysis suggests these proteins may be intracellular calcium receptors.     

Identification of calcium binding proteins from brain

A procedure was worked out for purification and identification of calcium-binding proteins from bovine brain using Ca²⁺-dependent, reversible binding to a hydrophobic support, phenyl-Sepharose, as the method of isolation. These proteins could be visualized during and after their separation by running them on non-denaturing polyacrylamide gels, blotting to Zeta-probe paper, and autoradiographing with⁴⁵Ca²⁺. About 24 polypeptides could be seen in this fraction on SDS (Laemmli) gels and about 8–10 native, Ca²⁺-binding proteins could be seen on non-denaturing gels and on blots of their 45Ca²⁺ autoradiographs. Some of these proteins could be purified further by chromatography on DEAE-Sephacel and still retain their⁴⁵Ca²⁺-binding activity.     

Tuning the affinity for lanthanides of calcium binding proteins

The possibility of selectively substituting one or more lanthanides into the four canonical calcium binding sites of calcium-loaded vertebrate calmodulin (CaM) was investigated by monitoring changes in the (1)H-(15)N HSQC NMR spectra of the (15)N-enriched protein upon titration with Yb(3+). The affinity of lanthanides for both N-terminal sites I and II is only moderately higher than that of calcium, and comparable with that of calcium for the two C-terminal sites. This situation induces binding of lanthanides to other noncanonical sites located at the interdomain linker, the N- and C-terminal ends, and at the inter-EF-hand linkers. Therefore, mutants were designed to alter the metal binding properties of calcium sites I (D22N, D24E), II (D58N, N60D, D58N-N60D), III (N97D), II-III (N60D-N97D), and IV (D129N), as well as of the inter-EF-hand linker of the N-terminal domain (N42K, T44K). The most striking effects were obtained for the N60D mutant at site II, as selective lanthanide binding is achieved even in the presence of excess calcium, and little or no population of the noncanonical sites occurs. Similar although less pronounced effects were observed for the N97D mutant. These findings allow us to better define some of the determinants of the relative affinities of calcium and lanthanides in CaM and, by extension, in other calcium binding proteins. Finally, by using CaM samples containing only three of the four calcium ions, it was possible to prepare well-defined Ca(3)Ln-CaM derivatives (Ln = Tb, Dy, Tm, and Yb), with interesting properties as NMR probes.     

Increased covalent binding of acetaldehyde to calmodulin in the presence of calcium

The regulatory protein, calmodulin, undergoes major conformational changes in response to changes in intracellular calcium concentration. Furthermore, calmodulin has been reported to have lysine residues which markedly increase their reactivity toward electrophilic substances in the calcium-loaded state. We found that calmodulin formed two to three times more stable adducts with acetaldehyde in the calcium-loaded state as compared to the calcium-free state. Competition-binding studies showed that calmodulin could preferentially compete with albumin for acetaldehyde in the presence, but not in the absence, of calcium. When calmodulin was in the calcium-loaded state, trifluoperazine, an inhibitor of calmodulin activity, significantly decreased the stable binding of acetaldehyde to the protein, whereas in the calcium-free state, minimal effects on binding were observed. Since calmodulin is involved in regulation of multiple important processes in the cell, it is possible that acetaldehyde-calmodulin adducts could contribute to liver injury by perturbation of calcium-dependent homeostatic mechanisms within the hepatocyte.     

Modeling of quantal neurotransmitter release kinetics in the presence of fixed and mobile calcium buffers

The local calcium concentration in the active zone of secretion determines the number and kinetics of neurotransmitter quanta released after the arrival of a nerve action potential in chemical synapses. The small size of mammalian neuromuscular junctions does not allow direct measurement of the correlation between calcium influx, the state of endogenous calcium buffers determining the local concentration of calcium and the time course of quanta exocytosis. In this work, we used computer modeling of quanta release kinetics with various levels of calcium influx and in the presence of endogenous calcium buffers with varying mobilities. The results of this modeling revealed the desynchronization of quanta release under low calcium influx in the presence of an endogenous fixed calcium buffer, with a diffusion coefficient much smaller than that of free Ca²⁺, and synchronization occurred upon adding a mobile buffer. This corresponds to changes in secretion time course parameters found experimentally (Samigullin et al., Physiol Res 54:129–132, 2005; Bukharaeva et al., J Neurochem 100:939–949, 2007).     

NADPH-diaphorase and calcium binding proteins in the trigeminal nucleus oralis of rats

We have examined the distribution of nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d) and the calcium binding proteins (CBPs), calbindin D-28k (CB), calretinin (CR) and parvalbumin (PV), in the trigeminal nucleus oralis (Sp5O). NADPH-d was detected by histochemistry while CBP was detected by immunohistochemistry. NADPH-d-positive neurons were distributed in the medial rostro-dorsomedial part (RDMsp5O) and dorsomedial part (DMsp5O) of Sp5O, and the rostrolateral part of the nucleus of the solitary tract (NTS). CB- and CR-positive neurons were mainly distributed in the dorsal part of Sp5O. In contrast, PV-positive neurons were mainly distributed in the ventral part of Sp5O. NADPH-d colocalized with CB (40%) and CR (20%) but not with PV in neurons of DMsp5O/ NTS. The mean cell sizes of neurons in RDMsp5O were larger than those in DMsp5O/NTS. PV-positive neurons were larger than NADPH-d-positive neurons. NADPH-d-, CB- and CR-positive neurons were generally small in RDMsp5O and DMsp5O/NTS. Few neurons were retrogradely labeled in RDMsp5O and DMsp5O from the thalamus, when numerous labeled neurons were in the principal and interpolar nuclei. These data indicate that NADPH-d histochemistry and CB, CR and PV immunohistochemistry identify a discrete cell population in Sp5O. Those labeled neurons in RDMsp5O and DMsp5O/NTS were considered to be involved in sensorimotor reflexive function of the intra-oral structures.     

Poly(ADP-ribosylation) of proteins determines the pool of endogenous NAD and the radiosensitivity of thymus lymphocytes

A decrease in the endogenous NAD content that occurs immediately after gamma-irradiation of thymus lymphocytes is attributed to activation of poly (ADP-ribosylation) and not to changes in the activity of NAD-glycohydrolase and/or to the release of NAD from cells. The addition of benzamide 60 min before irradiation prevents the postirradiation drop of the NAD level and produces a radioprotective effect. At the same time, benzamide inhibits nuclear superhelix DNA repair and causes an average of 40 per cent decrease in the activity of DNA ligases I and II. The authors discuss the idea that the content of intracellular NAD in thymocytes is a critical factor responsible for the vitality of these cells.     

NADPH-diaphorase and calcium binding proteins in the trigeminal nucleus oralis of rats

We have examined the distribution of nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d) and the calcium binding proteins (CBPs), calbindin D-28k (CB), calretinin (CR) and parvalbumin (PV), in the trigeminal nucleus oralis (Sp5O). NADPH-d was detected by histochemistry while CBP was detected by immunohistochemistry. NADPH-d-positive neurons were distributed in the medial rostro-dorsomedial part (RDMsp5O) and dorsomedial part (DMsp5O) of Sp5O, and the rostrolateral part of the nucleus of the solitary tract (NTS). CB- and CR-positive neurons were mainly distributed in the dorsal part of Sp5O. In contrast, PV-positive neurons were mainly distributed in the ventral part of Sp5O. NADPH-d colocalized with CB (40%) and CR (20%) but not with PV in neurons of DMsp5O/NTS. The mean cell sizes of neurons in RDMsp5O were larger than those in DMsp5O/NTS. PV-positive neurons were larger than NADPH-d-positive neurons. NADPH-d-, CB- and CR-positive neurons were generally small in RDMsp5O and DMsp5O/NTS. Few neurons were retrogradely labeled in RDMsp5O and DMsp5O from the thalamus, when numerous labeled neurons were in the principal and interpolar nuclei. These data indicate that NADPH-d histochemistry and CB, CR and PV immunohistochemistry identify a discrete cell population in Sp5O. Those labeled neurons in RDMsp5O and DMsp5O/NTS were considered to be involved in sensorimotor reflexive function of the intra-oral structures.     

Phosphorylation of neurofilament proteins by endogenous calcium/calmodulin-dependent protein kinase

A protein fraction containing neurofilaments was prepared from rat brain cytosol by differential centrifugation and gel filtration chromatography. These preparations were enriched for a calcium/calmodulin-dependent kinase activity that phosphorylated endogenous neurofilament proteins. The enzyme incorporated approximately 1 mol PO4/mol of each neurofilament triplet polypeptide. These data suggest that a calmodulin-dependent kinase may mediate some of the effects of calcium on cytoskeletal function by phosphorylation of neurofilament proteins.     

The effect of endogenous proteases on the spectrin binding proteins of human erythrocytes

We have demonstrated that in human erythrocyte ghosts endogenous proteolytic activity is responsible for the digestion of the spectrin binding proteins (bands 2.1 to 2.6). The pH optimum, cofactor requirements and inhibitor sensitivity have been established. Our results indicate that proteolysis of bands 2.1 to 2.6 and the formation of 3′, a fragment containing an active spectrin binding site, can occur through two enzymatic pathways: a cascade of consecutive proteolytic cleavages of the spectrin binding proteins inhibited by phenylmethylsulfonyl fluoride or a Ca²⁺-stimulated, phenylmethylsulfonyl fluoride-insensitive, EDTA-inhibited cleavage of band 2.1 to band 2.3, followed by digestion to band 3′ by phenylmethylsulfonyl fluoride-inhibitable enzymes. These findings may provide the techniques necessary to prevent proteolysis of the spectrin binding proteins during purification and reconstitution experiments and provide insight into how they are formed in vivo.     

Free-energy linkage between folding and calcium binding in EF-hand proteins

Troponin is the singular Ca²⁺-sensitive protein in the contraction of vertebrate striated muscles. Troponin C (TnC), the Ca²⁺-binding subunit of the troponin complex, has two distinct domains, C and N, which have different properties despite their extensive structural homology. In this work, we analyzed the thermodynamic stability of the isolated N-domain of TnC using a fluorescent mutant with Phe 29 replaced by Trp (F29W/N-domain, residues 1-90). The complete unfolding of the N-domain of TnC in the absence or presence of Ca²⁺ was achieved by combining high hydrostatic pressure and urea, a maneuver that allowed us to calculate the thermodynamic parameters (ΔV and ΔG_atm). In this study, we propose that part of the affinity for Ca²⁺ is contributed by the free-energy change of folding of the N- and C-domains that takes place when Ca²⁺ binds. The importance of the free-energy change for the structural and regulatory functions of the TnC isolated domains was evaluated. Our results shed light on how the coupling between folding and ion binding contributes to the fine adjustment of the affinity for Ca²⁺ in EF-hand proteins, which is crucial to function.     

The GyrA-box determines the geometry of DNA bound to gyrase and couples DNA binding to the nucleotide cycle

DNA gyrase catalyses the adenosine triphosphate-dependent introduction of negativesupercoils into DNA. The enzyme binds a DNA-segment at the so-called DNA-gate and cleavesboth DNA strands. DNA extending from the DNA-gate is bound at the perimeter of thecylindrical C-terminal domains (CTDs) of the GyrA subunit. The CTDs are believed tocontribute to the wrapping of DNA around gyrase in a positive node as a prerequisite forstrand passage towards negative supercoiling. A conserved seven amino acid sequence motifin the CTD, the so-called GyrA-box, has been identified as a hallmark feature of gyrases.Mutations of the GyrA-box abolish supercoiling. We show here that the GyrA-box marginallystabilizes the CTDs. Although it does not contribute to DNA binding, it is required forDNA bending and wrapping, and it determines the geometry of the bound DNA. Mutations ofthe GyrA-box abrogate a DNA-induced conformational change of the gyrase N-gate anduncouple DNA binding and adenosine triphosphate hydrolysis. Our results implicate theGyrA-box in coordinating DNA binding and the nucleotide cycle.     

Calcium binding protein from porcine intestine binds to phosphatidylserine vesicles in the presence of calcium

Protein II, a 32K cytoskeleton-associated protein isolated from porcine intestinal epithelium, binds to vesicles composed of phosphatidylserine in the presence, but not the absence, of 10 microM Ca2+. Binding was saturable and was specifically inhibited by chelation of free Ca2+ with EGTA. Binding was also inhibited by trifluophenothiazine. Vesicles composed of dimyristoylphosphatidylcholine did not bind protein II, suggesting that interaction with phosphatidylserine was selective. These properties are consistent with a possible role for protein II in Ca-regulated cytoskeleton-cell membrane events.     

Restoration of the calcium binding activity of mutant calmodulins toward normal by the presence of a calmodulin binding structure

The altered calcium binding activity of calmodulins (CaM) with point mutations can be restored toward that of wild type CaMs by the formation of a complex between CaM and a CaM binding sequence. Three different site-specific mutations resulted in selective effects on the apparent stoichiometry and affinity of CaM for calcium, with maintenance of the ability to activate myosin light chain kinase. The effects on calcium binding, however, were suppressed when the mutant CaMs were complexed with RS20, a peptide analog of a myosin light chain kinase CaM binding site. The mutations included: 1) a Glu----Ala mutation at two phylogenetically conserved calcium ligands in the second (E67A-CaM) and fourth (E140A-CaM) sites; and 2) a Ser----Phe mutation at residue 101 (S101F-CaM) which affects ion channel regulation. The mutant CaMs bind 4 calciums in the absence of magnesium, but two sites have approximately 60- to 300-fold weaker binding than wild-type CaM (SYNCAM CaM). E67A-CaM and E140A-CaM bound only two calciums and S101F-CaM bound 4 calciums in the presence of magnesium. E67A-CaM and E140A-CaM recovered the ability to bind 4 calcium ions in the presence of the RS20 CaM binding peptide. These results are consistent with models in which the calcium binding activity of CaM within a supramolecular complex is different from purified CaM and raise the possibility that the selective functional effects of in vivo mutations in the calcium binding sites of CaM might be partially due to the ability of some CaM binding proteins to select and utilize CaM conformations with calcium ligation structures different from the so-called canonical EF-hand.     

Detection, in synaptic membranes of proteins, specific substrates for endogenous phosphorylation in the presence of GTP

Using the polyacrylamide gel electrophoresis (PAGE) of the synaptic membranes of proteins isolated from the rat brain cortex it is shown that on phosphorylation in the presence of [gamma-33P] GTP (5 and 10 microM) and 10-20-fold excess of unlabelled ATP the phosphorylation of protein with molecular weights of 41,000 and 49,000 Dalton greatly increased but the labelling of proteins with molecular weights of 54000 and 30,000 Dalton strongly decreased or was completely abolished. The addition of unlabelled ATP practically does not change the phosphorylation of the bands (proteins) with molecular weights of 86,000, 82,000, 46,000 Dalton and weakly decreased when labelling proteins with molecular weight of 59,000. The results obtained permit suggesting the existence of proteins--substrates of specific phosphorylation with GTP in synaptic membranes.