S100A1 and S100B interactions with annexins.

Members of the annexin protein family interact with members of the S100 protein family thereby forming heterotetramers in which an S100 homodimer crossbridges two copies of the pertinent annexin. Previous work has shown that S100A1 and S100B bind annexin VI in a Ca(2+)-dependent manner and that annexin VI, but not annexin V, blocks the inhibitory effect of S100A1 and S100B on intermediate filament assembly. We show here that both halves of annexin VI (i.e., the N-terminal half or annexin VI-a and the C-terminal half or annexin VI-b) bind individual S100s on unique sites and that annexin VI-b, but not annexin VI-a, blocks the ability of S100A1 and S100B to inhibit intermediate filament assembly. We also show that the C-terminal extension of S100A1 (and, by analogy, S100B), that was previously demonstrated to be critical for S100A1 and S100B binding to several target proteins including intermediate filament subunits, is not part of the S100 surface implicated in the recognition of annexin VI, annexin VI-a, or annexin VI-b. Evaluation of functional properties with a liposome stability and a calcium influx assay reveals the ability of both S100 proteins to permeabilize the membrane bilayer in a similar fashion like annexins. When tested in combinations with different annexin proteins both S100 proteins mostly lead to a decrease in the calcium influx activity although not all annexin/S100 combinations behave in the same manner. Latter observation supports the hypothesis that the S100-annexin interactions differ mechanistically depending on the particular protein partners.

The calcium-modulated proteins, S100A1 and S100B, as potential regulators of the dynamics of type III intermediate filaments.

The Ca2+-modulated, dimeric proteins of the EF-hand (helix-loop-helix) type, S100A1 and S100B, that have been shown to inhibit microtubule (MT) protein assembly and to promote MT disassembly, interact with the type III intermediate filament (IF) subunits, desmin and glial fibrillary acidic protein (GFAP), with a stoichiometry of 2 mol of IF subunit/mol of S100A1 or S100B dimer and an affinity of 0.5-1.0 microM in the presence of a few micromolar concentrations of Ca2+. Binding of S100A1 and S100B results in inhibition of desmin and GFAP assemblies into IFs and stimulation of the disassembly of preformed desmin and GFAP IFs. S100A1 and S100B interact with a stretch of residues in the N-terminal (head) domain of desmin and GFAP, thereby blocking the head-to-tail process of IF elongation. The C-terminal extension of S100A1 (and, likely, S100B) represents a critical part of the site that recognizes desmin and GFAP. S100B is localized to IFs within cells, suggesting that it might have a role in remodeling IFs upon elevation of cytosolic Ca2+ concentration by avoiding excess IF assembly and/or promoting IF disassembly in vivo. S100A1, that is not localized to IFs, might also play a role in the regulation of IF dynamics by binding to and sequestering unassembled IF subunits. Together, these observations suggest that S100A1 and S100B may be regarded as Ca2+-dependent regulators of the state of assembly of two important elements of the cytoskeleton, IFs and MTs, and, potentially, of MT- and IF-based activities.

Role of the C-terminal extension in the interaction of S100A1 with GFAP, tubulin, the S100A1- and S100B-inhibitory peptide, TRTK-12, and a peptide derived from p53, and the S100A1 inhibitory effect on GFAP polymerization.

Whereas native and recombinant S100A1 inhibited GFAP assembly, a truncated S100A1 lacking the last six C-terminal residues (Phe88-Ser93) (S100A1Delta88-93) proved unable to do so. The inhibitory effects of native and recombinant S100A1 on GFAP assembly were blocked by both TRTK-12, a synthetic peptide derived from the alpha-subunit of the actin capping protein, CapZ, and a synthetic peptide derived from the tumor-suppressor protein, p53, in a dose-dependent manner. By fluorescent spectroscopy, TRTK-12 and the p53 peptide, like GFAP and tubulin, caused a dose- and Ca2+-dependent blue-shift of the fluorescence maximum of acrylodan-S100A1. In contrast, GFAP, tubulin, TRTK-12, or the p53 peptide caused no significant changes in the fluorescence spectrum of acrylodan-S100A1Delta88-93. By chemical crosslinking, both TRTK-12 and the p53 peptide strongly reduced or blocked the formation of GFAP-S100A1 or tubulin-S100A1 complexes, respectively, and S100A1Delta88-93 was unable to complex with tubulin, whereas a remarkably reduced complexation of GFAP with the truncated protein was observed. All the above observations show that the C-terminal extension of S100A1 is an essential part of the S100A1 site implicated in the recognition of GFAP, tubulin, p53, and the alpha-subunit of CapZ.

Annexin VI binds S100A1 and S100B and blocks the ability of S100A1 and S100B to inhibit desmin and GFAP assemblies into intermediate filaments.

Annexin VI, a member of a family of Ca(2+)-dependent phospholipid- and membrane-binding proteins, interacts with the Ca(2+)-regulated EF-hand proteins, S100A1 and S100B, and blocks the ability of these two proteins to inhibit the assembly of desmin and glial fibrillary acidic protein (GFAP) into intermediate filaments in a Ca(2+)- and dose-dependent manner. S100A1 and S100B each possess one annexin VI binding site, characterized by an affinity for annexin VI in the submicromolar range. Binding of annexin VI to either S100 protein occurs at a site that appears to differ in some parts from that recognizing desmin and GFAP. As S100A1 and S100B exist in solution as homodimers in which the two monomers are related by a 2-fold symmetry axis, each of the above S100 homodimers likely crosslinks two annexin VI molecules, a situation that appears typical of all the annexin-S100 protein complexes described thus far. However, whereas in the cases of other annexin-S100 complexes the C-terminal extension of the S100 molecule appears indispensable for annexin binding, the annexin VI binding site cannot be restricted to the S100A1 and S100B C-terminal extension. We speculate that the annexin VI site on S100A1/B may only partially overlap to the desmin/GFAP site. In contrast, no effects of annexin V on the ability of S100A1 or S100B to affect the desmin and GFAP assemblies could be documented, although binding of annexin V to S100A1 and S100B could be detected at relatively high Ca2+ concentrations. The present data suggest that annexin VI might regulate S100A1 and S100B activities and vice versa.

S-100 (alpha and beta) binding peptide (TRTK-12) blocks S-100/GFAP interaction: identification of a putative S-100 target epitope within the head domain of GFAP.

Alignment of previously characterized S-100 (alpha and beta)-binding peptides (J. Biol. Chem. 270, 14651-14658) has enabled the identification of a putative S-100 target epitope within the head domain of glial fibrillary acidic protein (GFAP). The capacity of a known peptide inhibitor of S-100 protein (TRTK-12), homologous to this region, to perturb the interaction of S-100 (alpha and beta) and GFAP (J. Biol. Chem 268, 12669-12674) was investigated. Fluorescence spectrophotometry and chemical cross-linking analyses determined TRTK-12 to disrupt S-100:GFAP interaction in a dose- and Ca(2+_dependent manner. TRTK-12 also inhibited S-100's ability to block GFAP assembly and to mediate disassembly of preformed glial filaments. Each of these events was strictly dependent upon the presence of calcium and inhibitory peptide, maximal inhibition occurring at a concentration of TRTK-12 equivalent to the molar amount of S-100 monomer present. Together with our recent report demonstrating TRTK-12 also blocks the interaction of S-100 protein with the actin capping protein, CapZ, these results suggest TRTK-12 functions as a pleiotropic inhibitor of S-100 function. Availability of a functional inhibitor of S-100 will assist the further characterization of S-100 protein function in vitro and in vivo. Moreover, this report provides additional evidence supportive of a role for S-100 as a multi-faceted regulator of cytoskeletal integrity.

Characterization of type III intermediate filament regulatory protein target epitopes: S-100 (beta and/or alpha) binds the N-terminal head domain; annexin II2-p11(2) binds the rod domain.

We have investigated the interaction of S-100 proteins (beta and/or alpha) and annexin II2-p11(2) with glial fibrillary acidic protein (GFAP) and desmin to have further information on the mechanisms whereby S-100 proteins and annexin II2-p11(2) affect assembly/disassembly of GFAP and desmin intermediate filaments (IFs). Analyses were conducted on either native IF subunits, GFAP or desmin rod domain, or headless GFAP or desmin. Our data indicate that: (i) S-100 proteins bind to GFAP and desmin N-terminal head domain; (ii) annexin II2-p11(2) binds to GFAP rod domain; (iii) annexin II2-p11(2) does not interact with desmin nor affects desmin assembly. The present data suggest that the ability of S-100 proteins to inhibit GFAP and desmin assemblies and to promote the disassembly of preformed GFAP and desmin IFs depends on occupation of a site on the N-terminal head domain of these IF subunit. It is known that the N-terminal head domain is critical for the progression from the stage of GFAP and desmin dimers/tetramers to that of large oligomers. On the other hand, the ability of annexin II2-p11(2) to stimulate GFAP assembly under conditions where this latter is normally hampered (e.g., at alkaline pH values) might depend on annexin II2-p11(2)-induced changes in the structure of GFAP rod domain, possibly as a consequence of charge modifications. By contrast, the inability of annexin II2-p11(2) to bind to desmin would depend on desmin resistance to charge modifications.

Effects of calcium-binding proteins (S-100a(o), S-100a, S-100b) on desmin assembly in vitro.

S-100a(o), the alpha alpha isoform of a subfamily of Ca(2+)-binding proteins of the EF-hand type expressed in cardiac and skeletal muscle cells, is reported to inhibit the assembly of the intermediate filament subunit desmin and to stimulate the disassembly of desmin intermediate filaments in the presence of micromolar levels of free Ca(2+). These effects are dose-dependent with respect to the S-100a(o) concentration and maximal at a desmin/S-100a(o) (dimer) molar ratio of approximately 2. Other members of the S-100 subfamily [S-100a (alpha beta) and S-100b (beta beta) and the unfractionated mixture of S-100a plus S-100b produce qualitatively similar effects on desmin assembly, with a potency that depends on the fraction of S-100alpha subunit (the most potent) or S-100beta subunit (the least potent) present in the S-100 isoforms tested. A binding stoichiometry of 2 mol of desmin/mol of S-100a(o) (dimer) and an affinity in the submicromolar range are calculated. The S-100beta subunit also interacts with desmin, but with a lower affinity compared with S-100alpha. By contrast, the S-100-like proteins calcyclin and p11 neither interact with desmin nor affect desmin assembly. The present data suggest that S-100a(o) might play a role in the regulation of the state of assembly of desmin intermediate filaments.

Annexin II2-p11(2) (calpactin I) stimulates the assembly of GFAP in a calcium- and pH-dependent manner.

Annexin II2-p11(2) (calpactin I) was tested as a potential regulator of GFAP assembly into glial filaments (GF), following the observation that it interacts with GFAP and cosediments with GF in a sedimentation assay. Under conditions where GFAP assembly is reduced, e.g., at pH values > 6.8, annexin II2-p11(2) stimulates GF formation in a Ca(2+)- and dose-dependent manner. Concomitantly, an ever larger fraction of annexin II2-p11(2) can be recovered in GF pellets as the pH is raised from 6.8 to 7.35. Monomeric annexin II also stimulates GFAP assembly, although with a smaller efficacy as compared to annexin II2-p11(2), but does not cosediment with GF to a large extent, whereas p11 neither cosediments with GF nor affects GFAP assembly. On the other hand, the in vitro reconstituted annexin II2-p11(2) heterotetramer mimics native annexin II2-p11(2), and perturbation of the integrity of annexin II2-p11(2) by a mild treatment with alpha-chymotrypsin results in the nearly complete abolition of the stimulatory effect of annexin II2-p11(2) on GFAP assembly. These data suggest that annexin II2-p11(2) might be involved in the regulation of the state of assembly of GF, possibly in concert with other proteins.

S-100 protein and annexin II2-p11(2) (calpactin I) act in concert to regulate the state of assembly of GFAP intermediate filaments.

S-100 protein and annexin II2-p11(2) were reported to inhibit and to stimulate the assembly of glial fibrillary acidic protein (GFAP), respectively, in a Ca(2+)-dependent manner. Here we show by a number of experimental approaches that S-100 protein contrasts all the effects of annexin II2-p11(2) on GFAP assembly and, conversely, that annexin II2-p11(2) contrasts the inhibitory effects of S-100 protein on GFAP assembly, in a dose-dependent manner in both cases. Altogether, these data suggest that two specific Ca2+ effectors, i.e., annexin II2-p11(2) and S-100 protein, might regulate the state of assembly of glial filaments in a concerted manner.

Mechanism of S100 protein-dependent inhibition of glial fibrillary acidic protein (GFAP) polymerization.

S100 protein, a subfamily of Ca(2+)-binding proteins of the EF-hand type, was recently shown to bind to and to inhibit the polymerization of the glial fibrillary acidic protein (GFAP), the intermediate filament component of astroglial cells, in the presence of micromolar levels of Ca2+ (J. Biol. Chem. 268, 12669-12674). By a sedimentation assay and viscometry we show here that S100 protein interferes with the very early steps of GFAP polymerization (nucleation) and with the GFAP polymer growth, thereby retarding the onset of GFAP assembly, reducing the rate and the extent of GFAP assembly, and increasing the critical concentration of GFAP assembly. Moreover, S100 protein disassembles preformed glial filaments. All the above effects can be explained by sequestration of soluble GFAP by S100 protein, as also indicated by the stoichiometry of S100 protein binding to GFAP and of S100 protein effects on GFAP assembly. Our data suggest that S100 protein might serve the function of avoiding excess GFAP polymerization and might participate in remodeling of glial filaments following elevation of the intracellular free Ca2+ concentration. Also, our data lend support to the notion that intermediate filaments are dynamic cytoskeleton structures that assemble and disassemble, and to the existence of cytoplasmic factors implicated in the regulation of the state of assembly of intermediate filaments.

Calpactin I binds to the glial fibrillary acidic protein (GFAP) and cosediments with glial filaments in a Ca(2+)-dependent manner: implications for concerted regulatory effects of calpactin I and S100 protein on glial filaments.

Calpactin I, a heterotetrameric, cytoskeletal protein complex composed of two copies of annexin II cross-linked by two copies of p11, an S100-like protein, binds to the glial fibrillary acidic protein (GFAP) and cosediments with glial filaments (GF) in a Ca(2+)-dependent manner, apparently without affecting GFAP polymerization under the present experimental conditions. Cosedimentation of calpactin I with GF, which occurs at micromolar free Ca2+ concentrations, is proportional to the concentrations of both calpactin I and GFAP and does not occur under conditions where GFAP assembly is maximally inhibited by, e.g., S100 protein. Annexin II also cosediments with GF and binds to GFAP, although to much smaller extents. Other annexins, such as annexins I, V, and VI, or p11 do not bind to either GF or GFAP. Calpactin I and S100 protein bind to different sites on GFAP, as investigated by fluorescence spectroscopy using acrylodan-labeled GFAP. Calpactin I and S100 protein might act, in the presence of Ca2+, in a concerted manner to determine the number and topography of GF in differentiating and/or mature glial cells.