The C-Terminal Random Coil Region Tunes the Ca2+-Binding Affinity of S100A4 through Conformational Activation

S100A4 interacts with many binding partners upon Ca²⁺ activation and is strongly associated with increased metastasis formation. In order to understand the role of the C-terminal random coil for the protein function we examined how small angle X-ray scattering of the wild-type S100A4 and its C-terminal deletion mutant (residues 1–88, Δ13) changes upon Ca²⁺ binding. We found that the scattering intensity of wild-type S100A4 changes substantially in the 0.15–0.25 Å⁻¹ q-range whereas a similar change is not visible in the C-terminus deleted mutant. Ensemble optimization SAXS modeling indicates that the entire C-terminus is extended when Ca²⁺ is bound. Pulsed field gradient NMR measurements provide further support as the hydrodynamic radius in the wild-type protein increases upon Ca²⁺ binding while the radius of Δ13 mutant does not change. Molecular dynamics simulations provide a rational explanation of the structural transition: the positively charged C-terminal residues associate with the negatively charged residues of the Ca²⁺-free EF-hands and these interactions loosen up considerably upon Ca²⁺-binding. As a consequence the Δ13 mutant has increased Ca²⁺ affinity and is constantly loaded at Ca²⁺ concentration ranges typically present in cells. The activation of the entire C-terminal random coil may play a role in mediating interaction with selected partner proteins of S100A4.     

Mitochondrial retrograde regulation of HSP101 expression in Arabidopsis thaliana under heat stress and amiodarone action

Heat stress in plants elevates the potential across the inner mitochondrial membrane (mtΔψ) and activates the expression of heat shock proteins (HSPs). The treatment of Saccharomyces cerevisiae cells with amiodarone (AMD) elevated the cytosolic Ca²⁺ level ([Ca²⁺]_cyt) in parallel with (mtΔψ) increase and led to the induction of Hsp104 synthesis. The hyperpolarization was presumably due to the increase in [Ca²⁺]_cyt. In the present study the effects of AMD (0–100 μM) on cell viability, HSP expression, mtΔψ, and [Ca²⁺]_cyt were investigated using the cell culture of Arabidopsis thaliana (L.) Heynh. The treatment of cultured cells with AMD led to the elevation of [Ca²⁺]_cyt, which was accompanied by the increase in mtΔψ and by activation of HSP101 expression. The increase in [Ca²⁺]_cyt and expression of HSP101 were also observed upon the treatment with the protonophore CCCP (carbonyl cyanide m-chlorophenylhydrazone, 4 μM) known to diminish mtΔψ. The results suggest that plant cell mitochondria modulate the cytosolic Ca²⁺ level by changing the potential at the inner mitochondrial membrane and, thereby, participate in the retrograde regulation of HSP101 expression.     

The Effects of CapZ Peptide (TRTK-12) Binding to S100B-Ca as Examined by NMR and X-ray Crystallography

Structure-based drug design is underway to inhibit the S100B-p53 interaction as a strategy for treating malignant melanoma. X-ray crystallography was used here to characterize an interaction between Ca²⁺-S100B and TRTK-12, a target that binds to the p53-binding site on S100B. The structures of Ca²⁺-S100B (1.5-Å resolution) and S100B-Ca²⁺-TRTK-12 (2.0-Å resolution) determined here indicate that the S100B-Ca²⁺-TRTK-12 complex is dominated by an interaction between Trp7 of TRTK-12 and a hydrophobic binding pocket exposed on Ca²⁺-S100B involving residues in helices 2 and 3 and loop 2. As with an S100B-Ca²⁺-p53 peptide complex, TRTK-12 binding to Ca²⁺-S100B was found to increase the protein's Ca²⁺-binding affinity. One explanation for this effect was that peptide binding introduced a structural change that increased the number of Ca²⁺ ligands and/or improved the Ca²⁺ coordination geometry of S100B. This possibility was ruled out when the structures of S100B-Ca²⁺-TRTK-12 and S100B-Ca²⁺ were compared and calcium ion coordination by the protein was found to be nearly identical in both EF-hand calcium-binding domains (RMSD = 0.19). On the other hand, B-factors for residues in EF2 of Ca²⁺-S100B were found to be significantly lowered with TRTK-12 bound. This result is consistent with NMR ¹⁵N relaxation studies that showed that TRTK-12 binding eliminated dynamic properties observed in Ca²⁺-S100B. Such a loss of protein motion may also provide an explanation for how calcium-ion-binding affinity is increased upon binding a target. Lastly, it follows that any small-molecule inhibitor bound to Ca²⁺-S100B would also have to cause an increase in calcium-ion-binding affinity to be effective therapeutically inside a cell, so these data need to be considered in future drug design studies involving S100B.     

Subcellular distribution of S100 proteins in tumor cells and their relocation in response to calcium activation

 S100 proteins, a subgroup of the EF-hand Ca²⁺-binding protein family, regulate a variety of cellular processes via interaction with different target proteins. Several pathological disorders, including cancer, are linked to altered Ca²⁺ homeostasis and might involve the multifunctional S100 proteins, which are expressed in a cell- and tissue-specific manner. The present work demonstrates a distinct intracellular localization of S100A6, S100A4, and S100A2 in two tumor cell lines derived from metastatic epithelial breast adenocarcinoma (MDA-MB231) and cervical carcinoma (HeLa). Treatment of the cells by thapsigargin, the ionophore A23187, or cyclic ADP-ribose, to increase [Ca²⁺]_i via different pathways, led to relocation of S100A6 and S100A4 but only partially of the nuclear S100A2, as demonstrated by confocal laser scanning microscopy. These findings support the hypothesis that S100 proteins could play a crucial role in the regulation of Ca²⁺ homeostasis in cancer cells. Accepted: 3 March 1999     

S100A6 - New facts and features

S100A6 (calcyclin) is a 10.5 kDa Ca²⁺-binding protein that belongs to the S100 protein family. S100A6 contains two EF-hand motifs responsible for binding of Ca²⁺. It also binds Zn²⁺ through not yet identified structures. Binding of Ca²⁺ induces a conformational change in the S100A6 molecule which in consequence increases its overall hydrophobicity and allows for interaction with target proteins. S100A6 was found in different mammalian and avian (chicken) tissues. A high level of S100A6 is observed in epithelial cells, fibroblasts and in different kinds of cancer cells. The function of S100A6 is not clear at present, but it has been suggested that it may be involved in cell proliferation, cytoskeletal dynamics and tumorigenesis. Additionally, S100A6 might have some extracellular activities. This review presents new facts and features concerning the S100A6 protein.     

The role of S100A4 protein in anticancer cytotoxicity: its presence is required on the surface of CD4+CD25+PGRPs+S100A4+ lymphocyte and undesirable on the surface of target cells

S100A4 is a Ca²⁺-binding protein that performs an important role in metastasis. It is also known for its antitumor functions. S100A4 is expressed by a specialized subset of CD⁴⁺CD²⁵⁺ lymphocytes and is present on those cell's membranes along with peptidoglycan recognition proteins (PGRPs). There, by interacting with major heat shock protein Hsp70, S100A4 plays an important cytotoxic role. The resulting stably formed complex of PGRPs, S100A4 and Hsp70 is required for the identification and binding between a lymphocyte and a target cell. Here, we investigated the S100A4 functions in CD⁴⁺CD²⁵⁺PGRPs⁺S100A4⁺ lymphocyte cytotoxicity against target cells. We demonstrated that those lymphocytes do not form a stable complex with the tumor target cells that themselves have S1004A on their surface. That observation can be explained by our finding that S100A4 precludes the formation of a stable complex between PGRPs, S100A4 (on the lymphocytes’ surface), and Hsp70 (on the target cells’ surface). The decrease in S100A4 level in CD⁴⁺CD²⁵⁺PGRPs⁺S100A4⁺ lymphocytes inhibits their cytotoxic activity, while the addition of S100A4 in the medium restores it. Thus, the resistance of target cells to CD⁴⁺CD²⁵⁺PGRPs⁺ S100A4⁺ lymphocyte cytotoxicity depends on their S100A4 expression level and can be countered by S100A4 antibodies.     

Mechanism of the Ca-Dependent Interaction between S100A4 and Tail Fragments of Nonmuscle Myosin Heavy Chain IIA

The interaction between the calcium-binding protein S100A4 and the C-terminal fragments of nonmuscle myosin heavy chain IIA has been studied by equilibrium and kinetic methods. Using site-directed mutants, we conclude that Ca²⁺ binds to the EF2 domain of S100A4 with micromolar affinity and that the K_d value for Ca²⁺ is reduced by several orders of magnitude in the presence of myosin target fragments. The reduction in K_d results from a reduced dissociation rate constant (from 16 s^− 1 to 0.3 s^− 1 in the presence of coiled-coil fragments) and an increased association rate constant. Using peptide competition assays and NMR spectroscopy, we conclude that the minimal binding site on myosin heavy chain IIA corresponds to A1907-G1938; therefore, the site extends beyond the end of the coiled-coil region of myosin. Electron microscopy and turbidity assays were used to assess myosin fragment filament disassembly by S100A4. The latter assay demonstrated that S100A4 binds to the filaments and actively promotes disassembly rather than just binding to the myosin monomer and displacing the equilibrium. Quantitative modelling of these in vitro data suggests that S100A4 concentrations in the micromolar region could disassemble myosin filaments even at resting levels of cytoplasmic [Ca²⁺]. However, for Ca²⁺ transients to be effective in further promoting dissociation, the elevated Ca²⁺ signal must persist for tens of seconds. Fluorescence recovery after photobleaching of A431/SIP1 cells expressing green fluorescent protein-myosin IIA, immobilised on fibronectin micropatterns to control stress fibre location, yielded a recovery time constant of around 20 s, consistent with in vitro data.     

Divalent metal ion complexes of S100B in the absence and presence of pentamidine

As part of an effort to inhibit S100B, structures of pentamidine (Pnt) bound to Ca²⁺-loaded and Zn²⁺,Ca²⁺-loaded S100B were determined by X-ray crystallography at 2.15 Å (R_free = 0.266) and 1.85 Å (R_free = 0.243) resolution, respectively. These data were compared to X-ray structures solved in the absence of Pnt, including Ca²⁺-loaded S100B and Zn²⁺,Ca²⁺-loaded S100B determined here (1.88 Å; R_free = 0.267). In the presence and absence of Zn²⁺, electron density corresponding to two Pnt molecules per S100B subunit was mapped for both drug-bound structures. One Pnt binding site (site 1) was adjacent to a p53 peptide binding site on S100B (± Zn²⁺), and the second Pnt molecule was mapped to the dimer interface (site 2; ± Zn²⁺) and in a pocket near residues that define the Zn²⁺ binding site on S100B. In addition, a conformational change in S100B was observed upon the addition of Zn²⁺ to Ca²⁺-S100B, which changed the conformation and orientation of Pnt bound to sites 1 and 2 of Pnt-Zn²⁺,Ca²⁺-S100B when compared to Pnt-Ca²⁺-S100B. That Pnt can adapt to this Zn²⁺-dependent conformational change was unexpected and provides a new mode for S100B inhibition by this drug. These data will be useful for developing novel inhibitors of both Ca²⁺- and Ca²⁺,Zn²⁺-bound S100B.     

Control of Ca Release by Action Potential Configuration in Normal and Failing Murine Cardiomyocytes

Cardiomyocytes from failing hearts exhibit spatially nonuniform or dyssynchronous sarcoplasmic reticulum (SR) Ca²⁺ release. We investigated the contribution of action potential (AP) prolongation in mice with congestive heart failure (CHF) after myocardial infarction. AP recordings from CHF and control myocytes were included in a computational model of the dyad, which predicted more dyssynchronous ryanodine receptor opening during stimulation with the CHF AP. This prediction was confirmed in cardiomyocyte experiments, when cells were alternately stimulated by control and CHF AP voltage-clamp waveforms. However, when a train of like APs was used as the voltage stimulus, the control and CHF AP produced a similar Ca²⁺ release pattern. In this steady-state condition, greater integrated Ca²⁺ entry during the CHF AP lead to increased SR Ca²⁺ content. A resulting increase in ryanodine receptor sensitivity synchronized SR Ca²⁺ release in the mathematical model, thus offsetting the desynchronizing effects of reduced driving force for Ca²⁺ entry. A modest nondyssynchronous prolongation of Ca²⁺ release was nevertheless observed during the steady-state CHF AP, which contributed to increased time-to-peak measurements for Ca²⁺ transients in failing cells. Thus, dyssynchronous Ca²⁺ release in failing mouse myocytes does not result from electrical remodeling, but rather other alterations such as T-tubule reorganization.     

Store-operated Ca2+ entry and Ca2+ responses to hypothalamic releasing hormones in anterior pituitary cells from Orai1−/− and heptaTRPC knockout mice

Store operated Ca²⁺ entry (SOCE) is the most important Ca²⁺ entry pathway in non-excitable cells. However, SOCE can also play a pivotal role in excitable cells such as anterior pituitary (AP) cells. The AP gland contains five different cell types that release six major AP hormones controlling most of the entire endocrine system. AP hormone release is modulated by Ca²⁺ signals induced by different hypothalamic releasing hormones (HRHs) acting on specific receptors in AP cells. TRH and LHRH both induce Ca²⁺ release and Ca²⁺ entry in responsive cells while GHRH and CRH only induce Ca²⁺ entry. SOCE has been shown to contribute to Ca²⁺ responses induced by TRH and LHRH but no molecular evidence has been provided. Accordingly, we used AP cells isolated from mice devoid of Orai1 channels (noted as Orai1−/− or Orai1 KO mice) and mice lacking expression of all seven canonical TRP channels (TRPC) from TRPC1 to TRPC7 (noted as heptaTRPC KO mice) to investigate contribution of these putative channel proteins to SOCE and intracellular Ca²⁺ responses induced by HRHs. We found that thapsigargin-evoked SOCE is lost in AP cells from Orai1−/− mice but unaffected in cells from heptaTRPC KO mice. Conversely, while spontaneous intracellular Ca²⁺-oscillations related to electrical activity were not affected in the Orai1−/− mice, these responses were significantly reduced in heptaTRPC KO mice. We also found that Ca²⁺ entry induced by TRH and LHRH is decreased in AP cells isolated from Orai1−/−. In addition, Ca²⁺ responses to several HRHs, particularly TRH and GHRH, are decreased in the heptaTRPC KO mice. These results indicate that expression of Orai1, and not TRPC channel proteins, is necessary for thapsigargin-evoked SOCE and is required to support Ca²⁺ entry induced by TRH and LHRH in mouse AP cells. In contrast, TRPC channel proteins appear to contribute to spontaneous Ca²⁺-oscillations and Ca²⁺ responses induced by TRH and GHRH. We conclude that expression of Orai1 and TRPC channels proteins may play differential and significant roles in AP physiology and endocrine control.     

Solution Structure of S100A1 Bound to the CapZ Peptide (TRTK12)

As is typical for S100-target protein interactions, a Ca²⁺-dependent conformational change in S100A1 is required to bind to a 12-residue peptide (TRTK12) derived from the actin-capping protein CapZ. In addition, the Ca²⁺-binding affinity of S100A1 is found to be tightened (greater than threefold) when TRTK12 is bound. To examine the biophysical basis for these observations, we determined the solution NMR structure of TRTK12 in a complex with Ca²⁺-loaded S100A1. When bound to S100A1, TRTK12 forms an amphipathic helix (residues N6 to S12) with several favorable hydrophobic interactions observed between W7, I10, and L11 of the peptide and a well-defined hydrophobic binding pocket in S100A1 that is only present in the Ca²⁺-bound state. Next, the structure of S100A1-TRTK12 was compared to that of another S100A1-target complex (i.e., S100A1-RyRP12), which illustrated how the binding pocket in Ca²⁺-S100A1 can accommodate peptide targets with varying amino acid sequences. Similarities and differences were observed when the structures of S100A1-TRTK12 and S100B-TRTK12 were compared, providing insights regarding how more than one S100 protein can interact with the same peptide target. Such comparisons, including those with other S100-target and S100-drug complexes, provide the basis for designing novel small-molecule inhibitors that could be specific for blocking one or more S100-target protein interactions.     

Spectral studies of the Ca2+-dependent interaction of trifluoperazine with S100b

S100b is a calcium-binding protein that will bind to many calmodulin target molecules in a Ca²⁺-dependent manner. In order to study the Ca²⁺-dependent binding properties of S100b, its interaction with a calmodulin antagonist, trifluoperazine (TFP), was investigated using [¹⁹F]- and [¹H]-NMR and UV-difference spectroscopy. It was estimated from [¹⁹F]-NMR that in the absence of Ca²⁺, thek _1/2 value of TFP was 130 µM, while itsk _1/2 value decreased to 28 µM in the presence of Ca²⁺. The addition of KCl was not antagonistic to the Ca²⁺-dependent interaction of TFP to S100b. The chemical exchange rate of TFP with Ca²⁺-bound S100b was estimated to be 9×10² sec^?1. By comparison with TFP-calmodulin exchange rates, it is suggested that the TFP-binding site on S100b is structurally different from its binding sites on calmodulin. Proton NMR resonance broadening in the range 6.8–7.2 ppm, corresponding to phenylalanine nuclei of S100b, indicates that these residues may be involved in TFP binding. Addition of Ca²⁺ to a 1:1 mixture of S100b and TFP resulted in a red-shifted UV-difference spectrum, while no significant difference spectrum was detected when Mg²⁺ was added to a S100b-TFP solution. Thus, we suggest that Ca²⁺ induces the exposure of a hydrophobic domain on S100b containing one or more phenylalanine residues that will bind TFP but that this domain is different from the hydrophobic domain on calmodulin.     

S100 and annexin proteins identify cell membrane damage as the Achilles heel of metastatic cancer cells

Mechanical activity of cells and the stress imposed on them by extracellular environment is a constant source of injury to the plasma membrane (PM). In invasive tumor cells, increased motility together with the harsh environment of the tumor stroma further increases the risk of PM injury. The impact of these stresses on tumor cell plasma membrane and mechanism by which tumor cells repair the PM damage are poorly understood. Ca²⁺ entry through the injured PM initiates repair of the PM. Depending on the cell type, different organelles and proteins respond to this Ca²⁺ entry and facilitate repair of the damaged plasma membrane. We recently identified that proteins expressed in various metastatic cancers including Ca²⁺-binding EF hand protein S100A11 and its binding partner annexin A2 are used by tumor cells for plasma membrane repair (PMR). Here we will discuss the involvement of S100, annexin proteins and their regulation of actin cytoskeleton, leading to PMR. Additionally, we will show that another S100 member – S100A4 accumulates at the injured PM. These findings reveal a new role for the S100 and annexin protein up regulation in metastatic cancers and identify these proteins and PMR as targets for treating metastatic cancers.     

Refined crystal structures of human Ca(2+)/Zn(2+)-binding S100A3 protein characterized by two disulfide bridges

S100A3, a member of the EF-hand-type Ca²⁺-binding S100 protein family, is unique in its exceptionally high cysteine content and Zn²⁺ affinity. We produced human S100A3 protein and its mutants in insect cells using a baculovirus expression system. The purified wild-type S100A3 and the pseudo-citrullinated form (R51A) were crystallized with ammonium sulfate in N,N-bis(2-hydroxyethyl)glycine buffer and, specifically for postrefolding treatment, with Ca²⁺/Zn²⁺ supplementation. We identified two previously undocumented disulfide bridges in the crystal structure of properly folded S100A3: one disulfide bridge is between Cys30 in the N-terminal pseudo-EF-hand and Cys68 in the C-terminal EF-hand (SS1), and another disulfide bridge attaches Cys99 in the C-terminal coil structure to Cys81 in helix IV (SS2). Mutational disruption of SS1 (C30A + C68A) abolished the Ca²⁺ binding property of S100A3 and retarded the citrullination of Arg51 by peptidylarginine deiminase type III (PAD3), while SS2 disruption inversely increased both Ca²⁺ affinity and PAD3 reactivity in vitro. Similar backbone structures of wild type, R51A, and C30A + C68A indicated that neither Arg51 conversion by PAD3 nor SS1 alters the overall dimer conformation. Comparative inspection of atomic coordinates refined to 2.15−1.40 Å resolution shows that SS1 renders the C-terminal classical Ca²⁺-binding loop flexible, which are essential for its Ca²⁺ binding properties, whereas SS2 structurally shelters Arg51 in the metal-free form. We propose a model of the tetrahedral coordination of a Zn²⁺ by (Cys)₃His residues that is compatible with SS2 formation in S100A3.     

Spectral studies of the Ca2+-dependent interaction of trifluoperazine with S100b

S100b is a calcium-binding protein that will bind to many calmodulin target molecules in a Ca²⁺-dependent manner. In order to study the Ca²⁺-dependent binding properties of S100b, its interaction with a calmodulin antagonist, trifluoperazine (TFP), was investigated using [¹⁹F]- and [¹H]-NMR and UV-difference spectroscopy. It was estimated from [¹⁹F]-NMR that in the absence of Ca²⁺, thek _1/2 value of TFP was 130 µM, while itsk _1/2 value decreased to 28 µM in the presence of Ca²⁺. The addition of KCl was not antagonistic to the Ca²⁺-dependent interaction of TFP to S100b. The chemical exchange rate of TFP with Ca²⁺-bound S100b was estimated to be 9×10² sec^–1. By comparison with TFP-calmodulin exchange rates, it is suggested that the TFP-binding site on S100b is structurally different from its binding sites on calmodulin. Proton NMR resonance broadening in the range 6.8–7.2 ppm, corresponding to phenylalanine nuclei of S100b, indicates that these residues may be involved in TFP binding. Addition of Ca²⁺ to a 1:1 mixture of S100b and TFP resulted in a red-shifted UV-difference spectrum, while no significant difference spectrum was detected when Mg²⁺ was added to a S100b-TFP solution. Thus, we suggest that Ca²⁺ induces the exposure of a hydrophobic domain on S100b containing one or more phenylalanine residues that will bind TFP but that this domain is different from the hydrophobic domain on calmodulin.     

Binding and Functional Folding (BFF): A Physiological Framework for Studying Biomolecular Interactions and Allostery

EF-hand Ca²⁺-binding proteins (CBPs), such as S100 proteins (S100s) and calmodulin (CaM), are signaling proteins that undergo conformational changes upon increasing intracellular Ca²⁺. Upon binding Ca²⁺, S100 proteins and CaM interact with protein targets and induce important biological responses. The Ca²⁺-binding affinity of CaM and most S100s in the absence of target is weak (^CaK_D > 1 μM). However, upon effector protein binding, the Ca²⁺ affinity of these proteins increases via heterotropic allostery (^CaK_D < 1 μM). Because of the high number and micromolar concentrations of EF-hand CBPs in a cell, at any given time, allostery is required physiologically, allowing for (i) proper Ca²⁺ homeostasis and (ii) strict maintenance of Ca²⁺-signaling within a narrow dynamic range of free Ca²⁺ ion concentrations, [Ca²⁺]^free. In this review, mechanisms of allostery are coalesced into an empirical “binding and functional folding (BFF)” physiological framework. At the molecular level, folding (F), binding and folding (BF), and BFF events include all atoms in the biomolecular complex under study. The BFF framework is introduced with two straightforward BFF types for proteins (type 1, concerted; type 2, stepwise) and considers how homologous and nonhomologous amino acid residues of CBPs and their effector protein(s) evolved to provide allosteric tightening of Ca²⁺ and simultaneously determine how specific and relatively promiscuous CBP-target complexes form as both are needed for proper cellular function.     

Ca2+‐dependent activation of guard cell anion channels,triggered by hyperpolarization,is promoted by prolonged depolarization

Rapid stomatal closure is driven by the activation of S‐type anion channels in the plasma membrane of guard cells. This response has been linked to Ca²⁺ signalling, but the impact of transient Ca²⁺ signals on S‐type anion channel activity remains unknown. In this study, transient elevation of the cytosolic Ca²⁺ level was provoked by voltage steps in guard cells of intact Nicotiana tabacum plants. Changes in the activity of S‐type anion channels were monitored using intracellular triple‐barrelled micro‐electrodes. In cells kept at a holding potential of ?100 mV, voltage steps to ?180 mV triggered elevation of the cytosolic free Ca²⁺ concentration. The increase in the cytosolic Ca²⁺ level was accompanied by activation of S‐type anion channels. Guard cell anion channels were activated by Ca²⁺ with a half maximum concentration of 515 nm (SE = 235) and a mean saturation value of ?349 pA (SE = 107) at ?100 mV. Ca²⁺ signals could also be evoked by prolonged (100 sec) depolarization of the plasma membrane to 0 mV. Upon returning to ?100 mV, a transient increase in the cytosolic Ca²⁺ level was observed, activating S‐type channels without measurable delay. These data show that cytosolic Ca²⁺ elevation can activate S‐type anion channels in intact guard cells through a fast signalling pathway. Furthermore, prolonged depolarization to 0 mV alters the activity of Ca²⁺ transport proteins, resulting in an overshoot of the cytosolic Ca²⁺ level after returning the membrane potential to ?100 mV.     

Molecular Basis of S100A1 Activation at Saturating and Subsaturating Calcium Concentrations

The S100A1 protein mediates a wide variety of physiological processes through its binding of calcium (Ca²⁺) and endogenous target proteins. S100A1 presents two Ca²⁺-binding domains: a high-affinity “canonical” EF (cEF) hand and a low-affinity “pseudo” EF (pEF) hand. Accumulating evidence suggests that both Ca²⁺-binding sites must be saturated to stabilize an open state conducive to peptide recognition, yet the pEF hand’s low affinity limits Ca²⁺ binding at normal physiological concentrations. To understand the molecular basis of Ca²⁺ binding and open-state stabilization, we performed 100 ns molecular dynamics simulations of S100A1 in the apo/holo (Ca²⁺-free/bound) states and a half-saturated state, for which only the cEF sites are Ca²⁺-bound. Our simulations indicate that the pattern of oxygen coordination about Ca²⁺ in the cEF relative to the pEF site contributes to the former’s higher affinity, whereas Ca²⁺ binding strongly reshapes the protein’s conformational dynamics by disrupting β-sheet coupling between EF hands. Moreover, modeling of the half-saturated configuration suggests that the open state is unstable and reverts toward a closed state in the absence of the pEF Ca²⁺ ion. These findings indicate that Ca²⁺ binding at the cEF site alone is insufficient to stabilize opening; thus, posttranslational modification of the protein may be required for target peptide binding at subsaturating intracellular Ca²⁺ levels.     

Collagen remodeling by phagocytosis is determined by collagen substrate topology and calcium-dependent interactions of gelsolin with nonmuscle myosin IIA in cell adhesions

We examine how collagen substrate topography, free intracellular calcium ion concentration ([Ca²⁺]_i, and the association of gelsolin with nonmuscle myosin IIA (NMMIIA) at collagen adhesions are regulated to enable collagen phagocytosis. Fibroblasts plated on planar, collagen-coated substrates show minimal increase of [Ca²⁺]_i, minimal colocalization of gelsolin and NMMIIA in focal adhesions, and minimal intracellular collagen degradation. In fibroblasts plated on collagen-coated latex beads there are large increases of [Ca²⁺]_i, time- and Ca²⁺-dependent enrichment of NMMIIA and gelsolin at collagen adhesions, and abundant intracellular collagen degradation. NMMIIA knockdown retards gelsolin recruitment to adhesions and blocks collagen phagocytosis. Gelsolin exhibits tight, Ca²⁺-dependent binding to full-length NMMIIA. Gelsolin domains G4–G6 selectively require Ca²⁺ to interact with NMMIIA, which is restricted to residues 1339–1899 of NMMIIA. We conclude that cell adhesion to collagen presented on beads activates Ca²⁺ entry and promotes the formation of phagosomes enriched with NMMIIA and gelsolin. The Ca²⁺ -dependent interaction of gelsolin and NMMIIA in turn enables actin remodeling and enhances collagen degradation by phagocytosis.