Rotational modes of Ca2+-liganded calmodulin, as determined by time-domain fluorescence

The interaction of auramine O with calmodulin: location of the binding site on the connecting strand

The cationic dye auramine O forms a fluorescent complex with Ca(2+)-liganded calmodulin. One moderately strong binding site is present, as well as one or more weaker sites. The binding site for auramine O is different from those for toluidinyl-naphthalene sulfonate. The dependence of binding upon electrolyte concentration suggests a substantial electrostatic component of the free energy of binding. The splitting of the bond between residues 77 and 78 by trypsin digestion abolishes auramine O binding; the N- and C-terminal half-molecules have virtually no binding capacity. This suggests that the primary binding site is located near the midpoint of the connecting strand and includes elements of both half-molecules. Thrombin digestion, which splits calmodulin between residues 106 and 107, also substantially reduces auramine O binding; this may be interpreted in terms of the stabilization of the structure of the connecting strand by interaction with residues within binding domain IV. The binding affinity at pH 5.0, where the helical organization of the connecting strand may be intact, is greater than at neutral pH.

The interaction of cyclosporin and calmodulin

The interaction of cyclosporin A and dansyl cyclosporin A with bovine and wheat germ calmodulin has been monitored by measurements of induced changes in dansyl and bound toluidinyl naphthalene sulfonate fluorescence. The interaction is Ca2(+)-dependent and 1:1. Measurements of the efficiency of radiationless energy transfer from bound dansyl cyclosporin A to an acceptor group located on Cys-27 of wheat germ calmodulin suggest that the primary binding site is not located on the N-terminal lobe (residues 1-65). However, studies with proteolytic fragments of calmodulin indicate that elements of the N-terminal half-molecule (residues 1-77) may be involved in the stabilization of the binding site. The binding of cyclosporin alters the physical properties of calmodulin and, in particular, reduces the localized rotational mobility of a fluorescent probe.

The interaction of calmodulin with the C-terminal M5 peptide of myosin light chain kinase

The interaction with calmodulin of the 17-residue C-terminal fragment M5 of myosin light chain kinase has been studied by several physical techniques. Circular dichroism measurements suggest that M5 exists within the complex primarily as an alpha-helix. Fluorescence intensity measurements of the single tryptophan of M5 (Trp-4) indicate that it is in a relatively nonpolar environment and is shielded from solvent. Dynamic measurements of fluorescence anisotropy decay indicate that Trp-4 changes from a freely rotating fluorophore to one which is largely immobilized upon complex formation. Static fluorescence measurements show that 2,6-TNS is displaced from its binding site on calmodulin by M5. The binding of M5 also partially inhibits the proteolytic scission by trypsin of the bond between residues 77 and 78.

The conformation of calmodulin: a substantial environmentally sensitive helical transition in Ca4-calmodulin with potential mechanistic function

The conformation of Ca4-calmodulin in solution, as assessed by far-UV peptide circular dichroism, contains significantly less alpha-helix than the proposed X-ray crystal structure. We now show that Ca4-calmodulin adopts significant additional helical structure in solution in the presence of a helicogenic solvent (50%, v/v, aqueous 2,2,2-trifluoroethanol or 50%, v/v, methylpentane-5,5-diol). We suggest that the long continuous helix (residues 66-92 of the crystal structure) is not necessarily a normal feature of the calmodulin structure in solution, and may be due in part to the conditions of crystallisation. This result is supported by time-resolved tyrosine fluorescence anisotropy studies indicating that Ca4-calmodulin in solution is an essentially compact globular structure which undergoes isotropic rotational motion. We conclude that, under appropriate ionic and apolar environmental conditions, Ca4-calmodulin undergoes a substantial helical transition, which may involve residues in the central region of the molecule. Such a transition could have an important function in determining specificity and affinity in interactions of calmodulin with different target sequences of Ca2+-dependent regulatory enzymes.

The interaction of delta-hemolysin with calmodulin

Delta-Hemolysin forms a 1:1 complex with Ca2+ -liganded calmodulin. Probably because of the pronounced tendency of delta-hemolysin to self-associate, the apparent binding affinity is much less than that for melittin. Complex formation is reflected by an increase in quantum yield of Trp-15 of delta-hemolysin and by increased shielding from acrylamide quenching. There is, however, no indication of a change in peptide molecular ellipticity. The binding of 2-toluidinyl-naphthalene-6-sulfonate is reduced by complex formation, suggesting the involvement of a hydrophobic region. Complex formation also blocks the proteolysis by trypsin of the bond between residues 77 and 78. The time decays of fluorescence intensity and anisotropy for tryptophan are multiexponential for both free and complexed delta-hemolysin; the average decay time for intensity is substantially increased for the complex. The localized mobility of tryptophan is greatly reduced in the complex. Complex formation appears to involve both the C-terminal lobe and the connecting strand of calmodulin.

Ligand-triggered conformational perturbations elicit changes at the single cysteinyl residue of spinach calmodulin

Following application of stoichiometric amounts of Ca2+ or specific partner peptides to spinach calmodulin, dynamic changes in the nanosecond range could be monitored at a strategically anchored fluorescence or spin probe. For these studies the single cysteinyl residue 26 of spinach calmodulin was labelled with a thiol-specific proxyl (i.e. 2,2,5,5-tetramethyl-1-pyrrolidinyl-oxyl) spin probe or with a bimane fluorescence probe. With Ca2+ and a specific ligand (mastoparan) present, fluorescence studies (anisotropy, lifetime) indicated that the rotational motion of the protein complex becomes slower relative to the motion of calmodulin in the absence of the specific ligand. The probe's attachment site 26 appears to reside in a fairly polar microenvironment as reported by a series of proxyl spin probes varying in label length. The rotational correlation time of the shortest spin probe markedly changed upon binding of a specific peptide to a calmodulin region distant from that of the monitoring spin probe. We interpret these observations as indicating that ligand-triggered conformational perturbations are eliciting specific responses at the cysteinyl residue 26 of spinach calmodulin.