Design and synthesis of the pseudo-EF hand in calbindin D9K: effect of amino acid substitutions in the alpha-helical regions

The formation of viroplasm-like structures by the rotavirus NSP5 protein is calcium regulated and directed by a C-terminal helical domain

The rotavirus NSP5 protein directs the formation of viroplasm-like structures (VLS) and is required for viroplasm formation within infected cells. In this report, we have defined signals within the C-terminal 21 amino acids of NSP5 that are required for VLS formation and that direct the insolubility and hyperphosphorylation of NSP5. Deleting C-terminal residues of NSP5 dramatically increased the solubility of N-terminally tagged NSP5 and prevented NSP5 hyperphosphorylation. Computer modeling and analysis of the NSP5 C terminus revealed the presence of an amphipathic alpha-helix spanning 21 C-terminal residues that is conserved among rotaviruses. Proline-scanning mutagenesis of the predicted helix revealed that single-amino-acid substitutions abolish NSP5 insolubility and hyperphosphorylation. Helix-disrupting NSP5 mutations also abolished localization of green fluorescent protein (GFP)-NSP5 fusions into VLS and directly correlate VLS formation with NSP5 insolubility. All mutations introduced into the hydrophobic face of the predicted NSP5 alpha-helix disrupted VLS formation, NSP5 insolubility, and the accumulation of hyperphosphorylated NSP5 isoforms. Some NSP5 mutants were highly soluble but still were hyperphosphorylated, indicating that NSP5 insolubility was not required for hyperphosphorylation. Expression of GFP containing the last 68 residues of NSP5 at its C terminus resulted in the formation of punctate VLS within cells. Interestingly, GFP-NSP5-C68 was diffusely dispersed in the cytoplasm when calcium was depleted from the medium, and after calcium resupplementation GFP-NSP5-C68 rapidly accumulated into punctate VLS. A potential calcium switch, formed by two tandem pseudo-EF-hand motifs (DxDxD), is present just upstream of the predicted alpha-helix. Mutagenesis of either DxDxD motif abolished the regulatory effect of calcium on VLS formation and resulted in the constitutive assembly of GFP-NSP5-C68 into punctate VLS. These results reveal specific residues within the NSP5 C-terminal domain that direct NSP5 hyperphosphorylation, insolubility, and VLS formation in addition to defining residues that constitute a calcium-dependent trigger of VLS formation. These studies identify functional determinants within the C terminus of NSP5 that regulate VLS formation and provide a target for inhibiting NSP5-directed VLS functions during rotavirus replication.

Coupling of ligand binding and dimerization of helix-loop-helix peptides: spectroscopic and sedimentation analyses of calbindin D9k EF-hands

Isolated Ca2+-binding EF-hand peptides have a tendency to dimerize. This study is an attempt to account for the coupled equilibria of Ca2+-binding and peptide association for two EF-hands with strikingly different loop sequence and net charge. We have studied each of the two separate EF-hand fragments from calbindin D9k. A series of Ca2+-titrations at different peptide concentrations were monitored by CD and fluorescence spectroscopy. All data were fitted simultaneously to both a complete model of all possible equilibrium intermediates and a reduced model not including dimerization in the absence of Ca2+. Analytical ultracentrifugation shows that the peptides may occur as monomers or dimers depending on the solution conditions. Our results show strikingly different behavior for the two EF-hands. The fragment containing the N-terminal EF-hand shows a strong tendency to dimerize in the Ca2+-bound state. The average Ca2+-affinity is 3.5 orders of magnitude lower than for the intact protein. We observe a large apparent cooperativity of Ca2+ binding for the overall process from Ca2+-free monomer to fully loaded dimer, showing that a Ca2+-free EF-hand folds upon dimerization to a Ca2+-bound EF-hand, thereby presenting a preformed binding site to the second Ca2+-ion. The C-terminal EF-hand shows a much smaller tendency to dimerize, which may be related to its larger net negative charge. In spite of the differences in dimerization behavior, the Ca2+ affinities of both EF-hand fragments are similar and in the range lgK = 4.6-5.3.

Role of the N-terminal helix I for dimerization and stability of the calcium-binding protein S100B

Human S100B(beta beta) is a small intracellular EF-hand calcium-binding protein that consists of two noncovalently associated 91-residue beta monomers. The three-dimensional structures of S100B reveal the dimer interface consists of four alpha-helices (I, I' and IV, IV') packed in an X-type bundle. In this study, guanidine hydrochloride denaturation and dynamic light scattering were used to assess the impact of single (L3A, L3S, M7A, I11A, F14A) and double (L3A/I11A and L3A/F14A) substitution mutations in helix I on the stability and dimerization propensity of S100B. The free energy of unfolding (Delta G(u)) of wild-type apo-S100B was determined to be 72.4 +/- 4.0 kJ mol(-1), consistent with it being the most stable calcium-binding protein to date. The order of stability of the mutants in their apo form is S100B > L3A > L3S > I11A > M7A approximately L3A/I11A > F14A > L3A/F14A. Further, there is a strong correlation between the stability and the cooperativity of unfolding. Each mutation proved to be more stable in its calcium form compared to its apo form. The calcium-bound L3S substitution proved to be significantly more stable than calcium-saturated S100B, whereas the L3A, I11A, and L3A/I11A mutants are only slightly more stable than the wild-type protein. The F14A and L3A/F14A mutants are significantly reduced in stability, even in the presence of calcium.

Investigating site-specific effects of the -X glutamate in a parvalbumin CD site model peptide

The -X glutamate in a 33-residue model peptide comprising the CD site of carp parvalbumin 4.25 (ParvCD) was replaced with aspartate (ParvCD-XD) and the effect on calcium-dependent dimerization and calcium affinity assessed. The peptide ParvCD demonstrates a 10(5)-fold lower calcium affinity than the same site in the native protein. Both the ParvCD and ParvCD-XD model peptides fail to bind magnesium. The low calcium affinity and failure of the model ParvCD site to bind magnesium may be due to higher enthalpic costs of chelation by the -X glutamate. Replacement of the -X glutamate with an aspartate resulted in a twofold increase in the calcium affinity of both the monomer and dimer forms and a twofold increase in the calcium dependent dimerization of the peptide. A -X glutamate to aspartate replacement in 33-residue model peptides corresponding to bovine brain calmodulin site 3 (R. M. Procyshyn and R. E. Reid, Arch. Biochem. Biophys. 311, 425-429, 1994) and in Escherichia coli d-galactose-binding protein (S. K. Drake, K. L. Lee, and J. J. Falke, Biochemistry 35, 6697-6705, 1996) agree with results in the ParvCD site. However, in rat oncomodulin a -X glutamate to aspartate replacement increases calcium affinity (R. C. Hapak, P. J. Lammers, W. A. Palmisano, E. R. Birnbaum, and M. T. Henzl, J. Biol. Chem. 264, 18751-18760, 1989). The different effect of a -X glutamate to aspartate substitution in the different sites suggests site-specific factors dictating the thermodynamic contribution of the -X glutamate to calcium affinity.

Characterization of a helix-loop-helix (EF hand) motif of silver hake parvalbumin isoform B

Parvalbumins are a class of calcium-binding proteins characterized by the presence of several helix-loop-helix (EF-hand) motifs. It is suspected that these proteins evolved via intragene duplication from a single EF-hand. Silver hake parvalbumin (SHPV) consists of three EF-type helix-loop-helix regions, two of which have the ability to bind calcium. The three helix-loop-helix motifs are designated AB, CD, and EF, respectively. In this study, native silver hake parvalbumin isoform B (SHPV-B) has been sequenced by mass spectrometry. The sequence indicates that this parvalbumin is a beta-lineage parvalbumin. SHPV-B was cleaved into two major fragments, consisting of the ABCD and EF regions of the native protein. The 33-amino acid EF fragment (residues 76-108), containing one of the calcium ion binding sites in native SHPV-B, has been isolated and studied for its structural characteristics, ability to bind divalent and trivalent cations, and for its propensity to undergo metal ion-induced self-association. The presence of Ca2+ does not induce significant secondary structure in the EF fragment. However, NMR and CD results indicate significant secondary structure promotion in the EF fragment in the presence of the higher charge-density trivalent cations. Sedimentation equilibrium analysis results show that the EF fragment exists in a monomer-dimer equilibrium when complexed with La3+.

Human S100b protein: formation of a tetramer from synthetic calcium-binding site peptides

Human brain S100b protein is a unique calcium-binding protein comprised of two identical 91-amino acid polypeptide chains that each contain two proposed helix-loop-helix (EF-hand) calcium-binding sites. In order to probe the assembly of the four calcium-binding sites in S100b, a peptide comprised of the N-terminal 46 residues of S100b protein was synthesized and studied by CD and 1H NMR spectroscopies as a function of concentration and temperature. At relatively high peptide concentrations and in the absence of calcium, the peptide exhibited a significant proportion of alpha-helix (45%). Decreasing the peptide concentration led to a loss of alpha-helix as monitored by CD spectroscopy and coincident changes in the 1H NMR spectrum. These changes were also observed by 1H NMR spectroscopy as a function of temperature where it was observed that the Tm of the peptide was lowered approximately 14 degrees C with a 17-fold decrease in peptide concentration. Sedimentation equilibrium studies were used to determine that the peptide formed a tetramer in solution in the absence of calcium. It is proposed that this tetrameric fold also occurs in S100b and is a result of the interaction of portions of all four calcium-binding sites.

Helix formation by the phospholipase A2 38-59 fragment: influence of chain shortening and dimerization monitored by nmr chemical shifts

The solution structure of a peptide fragment corresponding to the 38-59 region of porcine phospholipase A2 has been investigated using CD, nmr chemical shifts, and nuclear overhauser effects (NOEs). This isolated fragment of phospholipase forms an alpha-helix spanning residues 38-55, very similar to the one found in the native protein, except for residues 56-58, which were helical in the crystal but found random in solution. Addition of triflouroethanol (TFE) merely increased helix population but it did not redefine helix limits. To investigate how the folding information, in particular that concerning eventual helix start and stop signals, was coded in this particular amino acid sequence, the helices formed by synthetic peptides reproducing sections of this phospholipase 38-59 fragment, namely 40-59, 42-59, 38-50, and 45-57, were characterized using NOEs and helix populations quantitatively evaluated on different peptide chain segments using nmr chemical shifts in two solvents (H2O and 30% TFE/H2O). A set of nmr spectra was also recorded and assigned under denaturing conditions (6M urea) to obtain reliable values for the chemical shifts of each peptide in the random state. Based on chemical shift data, it was concluded that the helix formed by the phospholipase 38-59 fragment was not abruptly, but progressively, destabilized all along its length by successive elimination of residues at the N end, while the removal of residues at the C end affected helix stability more locally and to a lesser extent. These results are consistent with the idea that there are not single residues responsible for helix initiation or helix stability, and they also evidence an asymmetry for contributions to helix stability by residues located at the two chain ends. The restriction of molecular mobility caused by linking with a disulphide bridge at Cys 51 two identical 38-59 peptide chains did not increase helix stability. The helix formed by the covalently formed homodimer was very similar in length and population to that formed by the monomer.

Disulfide bonds in homo- and heterodimers of EF-hand subdomains of calbindin D9k: stability, calcium binding, and NMR studies

The effect of decreased protein flexibility on the stability and calcium binding properties of calbindin D9k has been addressed in studies of a disulfide bridged calbindin D9k mutant, denoted (L39C + P43M + I73C), with substitutions Leu 39-->Cys, Ile 73-->Cys, and Pro 43-->Met. Backbone 1H NMR assignments show that the disulfide bond, which forms spontaneously under air oxidation, is well accommodated. The disulfide is inserted on the opposite end of the protein molecule with respect to the calcium sites, to avoid direct interference with these sites, as confirmed by 113Cd NMR. The effect of the disulfide bond on calcium binding was assessed by titrations in the presence of a chromophoric chelator. A small but significant effect on the cooperativity was found, as well as a very modest reduction in calcium affinity. The disulfide bond increases Tm, the transition midpoint of thermal denaturation, of calcium free calbindin D9k from 85 to 95 degrees C and Cm, the urea concentration of half denaturation, from 5.3 to 8.0 M. Calbindins with one covalent bond linking the two EF-hand subdomains are equally stable regardless if the covalent link is the 43-44 peptide bond or the disulfide bond. Kinetic remixing experiments show that separated CNBr fragments of (L39C + P43M + I73C), each comprising one EF-hand, form disulfide linked homodimers. Each homodimer binds two calcium ions with positive co-operativity, and an average affinity of 10(6) M-1. Disulfide linkage dramatically increases the stability of each homodimer. For the homodimer of the C-terminal fragment Tm increases from 59 +/- 2 without covalent linkage to 91 +/- 2 degrees C with disulfide, and Cm from approximately 1.5 to 7.5 M. The overall topology of this homodimer is derived from 1H NMR assignments and a few key NOEs.

Role of interchain alpha-helical hydrophobic interactions in Ca2+ affinity, formation, and stability of a two-site domain in troponin C

We have previously shown that a 34-residue synthetic peptide representing the calcium-binding site III of troponin C formed a symmetric two-site dimer consisting of two helix-loop-helix motifs arranged in a head-to-tail fashion (Shaw, G.S., Hodges, R.S., & Sykes, B.D., 1990, Science 249, 280-283). In this study the hydrophobicities of the alpha-helices were altered by replacing L-98 and F-102 in the N-terminal region and/or I-121 and L-122 in the C-terminal region with alanine residues. Our results showed that substitution of hydrophobic residues either in the N- or C-terminal region have little effect on alpha-helix formation but resulted in a 100- and 300-fold decrease in Ca2+ affinity, respectively. Simultaneous substitution of both hydrophobes in the N- and C-terminal region resulted in a 1,000-fold decrease in Ca2+ affinity. Data from guanidine hydrochloride denaturation studies suggested that intermolecular interactions occur and that the less hydrophobic analogs had a lower overall conformational stability. These data support the contention that the hydrophobic residues are important in the formation of the two-site domain in troponin C, and this hydrophobic association stabilizes Ca2+ affinity.

Ellipticity changes of the sarcoplasmic reticulum Ca(2+)-ATPase induced by cation binding and phosphorylation

The sarcoplasmic reticulum (SR) Ca(2+)-ATPase is a member of the 'P-type' class of cation transport ATPases which form a covalent phosphorylated intermediate. It has been proposed that during ion transport, these proteins cyclically adopt two major enzymatic states E1 and E2, that are related to two essential conformations of the protein. By the use of especially sensitive circular dichroism (CD) instrumentation it is shown here that Ca2+ addition induces 5% or 2.5% increases in Ca(2+)-ATPase ellipticity at 225 nm in the absence or in the presence of Mg2+, respectively. Furthermore, a 2% change in the same direction was observed when the enzyme was phosphorylated with Pi in the absence of Ca2+. These results suggest that the E1----E2 transition and the E2-P formation are associated with structural changes of the polypeptide backbone structure of the calcium pump protein.