Ca<sup>2+</sup> Binding Protein S100A1 Competes with Calmodulin and PIP2 for Binding Site on the C-Terminus of the TPRV1 Receptor

Grycová, Lenka; Holendová, Blanka; Lánský, Zdeněk; Bumba, Ladislav; Jirku, Michaela; Boušová, Kristýna; Teisinger, Jan

doi:10.1021/cn500250r

Cited by 18 publications

(33 citation statements)

References 40 publications

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“…The dissociation constants of TRPM4np WT with CaM and S100A1 were in a comparable micromolar range for both complexes, which corresponds to the data of previous binding affinities measured for other TRP/CaM and TRP/S100A1 complexes [33,34,37]. Using steady-state fluorescence anisotropy measurements, we have determined the dissociation constants of the TRPM4np/CaM and TRPM4np/S100A1 complexes with clusters of hydrophobic L134, L138, V143 and basic R139, R140, R144 residues involved in the interactions.…”

Section: Discussionsupporting

confidence: 81%

“…Using steady-state fluorescence anisotropy measurements, we have determined the dissociation constants of the TRPM4np/CaM and TRPM4np/S100A1 complexes with clusters of hydrophobic L134, L138, V143 and basic R139, R140, R144 residues involved in the interactions. The Ca 2+ dependence of TRP/CaM or TRP/S100A1 interactions was validated in our previous experiments [33][34][35]37], which made it possible to use buffers with 2 mM of CaCl 2 in our binding assays. Using steadystate fluorescence anisotropy measurements, we determined the dissociation constants of the TRPM4np/ CaM and TRPM4np/S100A1 complexes.…”

Section: Discussionmentioning

confidence: 62%

“…CaM becomes more extended with each pair of EF-hands upon Ca 2+ binding, exposing a hydrophobic patch via CaM a-helix flexible linker that is available to interact with a target receptor domain [28]. This first step reveals the positive amino-acid residues eligible to form a specific interaction with the ligand [33][34][35][36][37][38][39][40]. Both monomer subunits are composed of four helices containing two EF-hand calcium-binding loops [29].…”

Section: Introductionmentioning

confidence: 99%

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Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

et al. 2017

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The transient receptor potential channel of melastatin 4 (TRPM4) belongs to a group of large ion receptors that are involved in countless cell signalling cascades. This unique member is ubiquitously expressed in many human tissues, especially in cardiomyocytes, where it plays an important role in cardiovascular processes. Transient receptor potential channels (TRPs) are usually constituted by intracellular N- and C- termini, which serve as mediators affecting allosteric modulation of channels, resulting in the regulation of the channel function. The TRPs tails contain a number of conserved epitopes that specifically bind the intracellular modulators. Here, we identify new binding sites for the calmodulin (CaM) and S100 calcium-binding protein A1 (S100A1), located in the very distal part of the TRPM4 N terminus. We have used chemically synthesized peptides of the TRPM4, mimicking the binding epitopes, along with fluorescence methods to determine and specify CaM- and S100A1-binding sites. We have found that the ligands binding epitopes at the TRPM4 N terminus overlap, but the interacting mechanism of both complexes is probably different. The molecular models supported by data from the fluorescence method confirmed that the complexes formations are mediated by the positively charged (R139, R140, R144) and hydrophobic (L134, L138, V143) residues present at the TRPM4 N terminus-binding epitopes. The data suggest that the molecular complexes of TRPM4/CaM and TRPM4/S100A1 would lead to the modulation of the channel functions.

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Section: Discussionsupporting

confidence: 81%

Section: Discussionmentioning

confidence: 62%

Section: Introductionmentioning

confidence: 99%

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Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

et al. 2017

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“…31 High frequency calcium fluxes at the membrane result from increased channel opening events alone. TRP channel opening frequency is reportedly controlled by PIP2 [59][60][61][62] and inhibited by calmodulin. 59,[63][64][65] Studying these proteins in context of growth factor-stimulated calcium influx and EMT may be of interest.…”

Section: Molecular Control Of Calcium Influxes Upon Induction Of Epitmentioning

confidence: 99%

“…TRP channel opening frequency is reportedly controlled by PIP2 [59][60][61][62] and inhibited by calmodulin. 59,[63][64][65] Studying these proteins in context of growth factor-stimulated calcium influx and EMT may be of interest. However, regulation by PIP2 or calmodulin does not explain why microtubule targeting agents inhibit high frequency calcium influxes following HGF stimulation.…”

Section: Molecular Control Of Calcium Influxes Upon Induction Of Epitmentioning

confidence: 99%

Control of cell mechanics by RhoA and calcium fluxes during epithelial scattering

2016

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Epithelial tissues use adherens junctions to maintain tight interactions and coordinate cellular activities. Adherens junctions are remodeled during epithelial morphogenesis, including instances of epithelialmesenchymal transition, or EMT, wherein individual cells detach from the tissue and migrate as individual cells. EMT has been recapitulated by growth factor induction of epithelial scattering in cell culture. In culture systems, cells undergo a highly reproducible series of cell morphology changes, most notably cell spreading followed by cellular compaction and cell migration. These morphology changes are accompanied by striking actin rearrangements. The current evidence suggests that global changes in actomyosin-based cellular contractility, first a loss of contractility during spreading and its activation during cell compaction, are the main drivers of epithelial scattering. In this review, we focus on how spreading and contractility might be controlled during epithelial scattering. While we propose a central role for RhoA, which is well known to control cellular contractility in multiple systems and whose role in epithelial scattering is well accepted, we suggest potential roles for additional cellular systems whose role in epithelial cell biology has been less well documented. In particular, we propose critical roles for vesicle recycling, calcium channels, and calcium-dependent kinases.

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S100A1 and S100B: Calcium Sensors at the Cross‐Roads of Multiple Chondrogenic Pathways

Diaz-Romero

Nešić

2017

Journal Cellular Physiology

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The S100 protein family comprises more than 20 members of small calcium binding proteins operating as Ca2 +-activated switches that interact and modulate the activity of a large number of targets. S100A1 and S100B, two members of this family, have been recently associated with the differentiation status of human articular chondrocytes. Both proteins are homogeneously expressed in all cartilage zones, their expression decreases during chondrocyte dedifferentiation, and can be induced under conditions promoting redifferentiation. Although S100 proteins have a broad range of extra- and intracellular roles, functional studies of S100 proteins expressed in chondrocytes have focused on their extracellular roles linked to catabolic processes. The intracellular roles of S100A1 and S100B in chondrocytes remain largely unexplored, yet the few studies addressing their intracellular activity point toward potentially important functions in chondrocyte biology. This review summarizes reported intracellular S100A1 and S100B regulatory functions described in other cell types that could be also involved in the regulation of chondrogenic processes in cartilage. Potential roles of S100A1 and S100B in the TGF-β-SMAD, the cAMP-PKA-CREB, and the PI3K-AKT pathways, Ca2+ homeostasis, cytoskeleton dynamics, the calcineurin-NFAT pathway, interactions with the p53 family, and the Hippo pathway are examined in the context of chondrocyte biology. Based on the plethora of interactions of S100A1 and S100B with different molecular partners playing essential roles in chondrocyte biology, and the staggering complexity and ubiquity of cross-talk among these partners, we hypothesize that these S100 proteins play fundamental roles in the spatial and temporal regulation of chondrogenesis. J. Cell. Physiol. 232: 1979-1987, 2017. © 2016 Wiley Periodicals, Inc.

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Ca²⁺ Binding Protein S100A1 Competes with Calmodulin and PIP2 for Binding Site on the C-Terminus of the TPRV1 Receptor

Cited by 18 publications

References 40 publications

Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

Control of cell mechanics by RhoA and calcium fluxes during epithelial scattering

S100A1 and S100B: Calcium Sensors at the Cross‐Roads of Multiple Chondrogenic Pathways

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Ca2+ Binding Protein S100A1 Competes with Calmodulin and PIP2 for Binding Site on the C-Terminus of the TPRV1 Receptor

Cited by 18 publications

References 40 publications

Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

Shared CaM‐ and S100A1‐binding epitopes in the distal TRPM4 N terminus

Control of cell mechanics by RhoA and calcium fluxes during epithelial scattering

S100A1 and S100B: Calcium Sensors at the Cross‐Roads of Multiple Chondrogenic Pathways

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Ca²⁺ Binding Protein S100A1 Competes with Calmodulin and PIP2 for Binding Site on the C-Terminus of the TPRV1 Receptor