The allosteric role of the Ca2+ switch in adhesion and elasticity of C-cadherin

Modular proteins such as titin, fibronectin, and cadherin are ubiquitous components of living cells. Often involved in signaling and mechanical processes, their architecture is characterized by domains containing a variable number of heterogeneous “repeats” arranged in series, with either flexible or rigid linker regions that determine their elasticity. Cadherin repeats arranged in series are unique in that linker regions also feature calcium-binding motifs. While it is well known that the extracellular repeats of cadherin proteins mediate cell-cell adhesion in a calcium-dependent manner, the molecular mechanisms behind the influence of calcium in adhesion dynamics and cadherin's mechanical response are not well understood. Here we show, using molecular dynamics simulations, how calcium ions control the structural integrity of cadherin's linker regions, thereby affecting cadherin's equilibrium dynamics, the availability of key residues involved in cell-cell adhesion, and cadherin's mechanical response. The all-atom, multi-nanosecond molecular dynamics simulations involved the entire C-cadherin extracellular domain solvated in water (a 345,000 atom system). Equilibrium simulations show that the extracellular domain maintains its crystal conformation (elongated and slightly curved) when calcium ions are present. In the absence of calcium ions, however, it assumes a disordered conformation. The conserved residue Trp², which is thought to insert itself into a hydrophobic pocket of another cadherin molecule (thereby providing the basis for cell-cell adhesion), switches conformation from exposed to intermittently buried upon removal of calcium ions. Furthermore, the overall mechanical response of C-cadherin's extracellular domain is characterized at low force by changes in shape (tertiary structure elasticity), and at high force by unraveling of secondary structure elements (secondary structure elasticity). This mechanical response is modulated by calcium ions at both low and high force, switching from a stiff, rod-like to a soft, spring-like behavior upon removal of ions. The simulations provide an unprecedented molecular view of calcium-mediated allostery in cadherins, also illustrating the general principles of linker-mediated elasticity of modular proteins relevant not only for cell-cell adhesion and sound transduction, but also muscle elasticity.     

VE-cadherin links tRNA synthetase cytokine to anti-angiogenic function

A natural fragment of an enzyme that catalyzes the first step of protein synthesis-human tryptophanyl-tRNA synthetase (T2-TrpRS) has potent anti-angiogenic activity. A cellular receptor through which T2-TrpRS exerts its anti-angiogenic activity has not previously been identified. Here T2-TrpRS was shown to bind at intercellular junctions of endothelial cells (ECs). Using genetic knock-outs, binding was established to depend on VE-cadherin, a calcium-dependent adhesion molecule, which is selectively expressed in ECs, concentrated at adherens junctions, and is essential for normal vascular development. In contrast, T2-TrpRS binding to EC junctions was not dependent on platelet endothelial cell adhesion molecule type-1, another adhesion molecule found at EC junctions. Pull-down assays confirmed direct complex formation between T2-TrpRS and VE-cadherin. Binding of T2-TrpRS inhibited VEGF-induced ERK activation and EC migration. Thus, a VE-cadherin-dependent pathway is proposed to link T2-TrpRS to inhibition of new blood vessel formation.     

Mechanism of dimerization and structural features of human LI-cadherin

Liver intestine (LI)-cadherin is a member of the cadherin superfamily, which encompasses a group of Ca²⁺-dependent cell-adhesion proteins. The expression of LI-cadherin is observed on various types of cells in the human body, such as normal small intestine and colon cells, and gastric cancer cells. Because its expression is not observed on normal gastric cells, LI-cadherin is a promising target for gastric cancer imaging. However, because the cell adhesion mechanism of LI-cadherin has remained unknown, rational design of therapeutic molecules targeting this cadherin has been hampered. Here, we have studied the homodimerization mechanism of LI-cadherin. We report the crystal structure of the LI-cadherin homodimer containing its first four extracellular cadherin repeats (EC1-4). The EC1-4 homodimer exhibited a unique architecture different from that of other cadherins reported so far, driven by the interactions between EC2 of one protein chain and EC4 of the second protein chain. The crystal structure also revealed that LI-cadherin possesses a noncanonical calcium ion–free linker between the EC2 and EC3 domains. Various biochemical techniques and molecular dynamics simulations were employed to elucidate the mechanism of homodimerization. We also showed that the formation of the homodimer observed in the crystal structure is necessary for LI-cadherin–dependent cell adhesion by performing cell aggregation assays. Taken together, our data provide structural insights necessary to advance the use of LI-cadherin as a target for imaging gastric cancer.     

Elastic versus brittle mechanical responses predicted for dimeric cadherin complexes

Cadherins are a superfamily of adhesion proteins involved in a variety of biological processes that include the formation of intercellular contacts, the maintenance of tissue integrity, and the development of neuronal circuits. These transmembrane proteins are characterized by ectodomains composed of a variable number of extracellular cadherin (EC) repeats that are similar but not identical in sequence and fold. E-cadherin, along with desmoglein and desmocollin proteins, are three classical-type cadherins that have slightly curved ectodomains and engage in homophilic and heterophilic interactions through an exchange of conserved tryptophan residues in their N-terminal EC1 repeat. In contrast, clustered protocadherins are straighter than classical cadherins and interact through an antiparallel homophilic binding interface that involves overlapped EC1 to EC4 repeats. Here we present molecular dynamics simulations that model the adhesive domains of these cadherins using available crystal structures, with systems encompassing up to 2.8 million atoms. Simulations of complete classical cadherin ectodomain dimers predict a two-phased elastic response to force in which these complexes first softly unbend and then stiffen to unbind without unfolding. Simulated α, β, and γ clustered protocadherin homodimers lack a two-phased elastic response, are brittle and stiffer than classical cadherins and exhibit complex unbinding pathways that in some cases involve transient intermediates. We propose that these distinct mechanical responses are important for function, with classical cadherin ectodomains acting as molecular shock absorbers and with stiffer clustered protocadherin ectodomains facilitating overlap that favors binding specificity over mechanical resilience. Overall, our simulations provide insights into the molecular mechanics of single cadherin dimers relevant in the formation of cellular junctions essential for tissue function.     

The extracellular architecture of adherens junctions revealed by crystal structures of type I cadherins

Adherens junctions, which play a central role in intercellular adhesion, comprise clusters of type I classical cadherins that bind via extracellular domains extended from opposing cell surfaces. We show that a molecular layer seen in crystal structures of E- and N-cadherin ectodomains reported here and in a previous C-cadherin structure corresponds to the extracellular architecture of adherens junctions. In all three ectodomain crystals, cadherins dimerize through a trans adhesive interface and are connected by a second, cis, interface. Assemblies formed by E-cadherin ectodomains coated on liposomes also appear to adopt this structure. Fluorescent imaging of junctions formed from wild-type and mutant E-cadherins in cultured cells confirm conclusions derived from structural evidence. Mutations that interfere with the trans interface ablate adhesion, whereas cis interface mutations disrupt stable junction formation. Our observations are consistent with a model for junction assembly involving strong trans and weak cis interactions localized in the ectodomain.     

Molecular characterization of the substance P*neurokinin-1 receptor complex: development of an experimentally based model

Molecular models for the interaction of substance P (SP) with its G protein-coupled receptor, the neurokinin-1 receptor (NK-1R), have been developed. The ligand.receptor complex is based on experimental data from a series of photoaffinity labeling experiments and spectroscopic structural studies of extracellular domains of the NK-1R. Using the ligand/receptor contact points derived from incorporation of photolabile probes (p-benzoylphenylalanine (Bpa)) into SP at positions 3, 4, and 8 and molecular dynamics simulations, the topological arrangement of SP within the NK-1R is explored. The model incorporates the structural features, determined by high resolution NMR studies, of the second extracellular loop (EC2), containing contact points Met(174) and Met(181), providing important experimentally based conformational preferences for the simulations. Extensive molecular dynamics simulations were carried out to probe the nature of the two contact points identified for the Bpa(3)SP analogue (Bremer, A. A., Leeman, S. E., and Boyd, N. D. (2001) J. Biol. Chem. 276, 22857-22861), examining modes of ligand binding in which the contact points are fulfilled sequentially or simultaneously. The resulting ligand.receptor complex has the N terminus of SP projecting toward transmembrane helix (TM) 1 and TM2, exposed to the solvent. The C terminus of SP is located in proximity to TM5 and TM6, deeper into the central core of the receptor. The central portion of the ligand, adopting a helical loop conformation, is found to align with the helices of the central regions EC2 and EC3, forming important interactions with both of these extracellular domains. The model developed here allows for atomic insight into the biochemical data currently available and guides targeting of future experiments to probe specific ligand/receptor interactions and thereby furthers our understanding of the functioning of this important neuropeptide system.     

Calcium site mutations in cadherin: impact on adhesion and evidence of cooperativity

This work describes quantitative force and bead aggregation measurements of the adhesion and binding mechanisms of canine E-cadherin mutants W2A, D134A, D103A, D216A, D325A, and D436A. The W2A mutation affects the formation of the N-terminal strand dimer, and the remaining mutations target calcium binding sites at the interdomain junctions. Surface force measurements show that the full ectodomain of canine E-cadherin forms two bound states that span two intermembrane gap distances. The outer bond coincides with adhesion between the N-terminal extracellular domains (EC1) and the inner bond corresponds to adhesion via extracellular domain 3 (EC3). The W2A, D103A, D134A, and D216A mutations all eliminated adhesion between the N-terminal domains, and they attenuated or nearly eliminated the inner bond. The W2A mutant, which does not destabilize the protein structure, attenuates binding via EC3, which is separated from the mutation by several hundred amino acids. This long-range effect suggests that the presence or absence of tryptophan-2 docking allosterically alters the adhesive function of distal sites on the protein. This finding appears to reconcile the multidomain binding mechanism with mutagenesis studies, which suggested that W2 is the sole binding interface. The effects of the calcium site mutations indicate that structural perturbations cooperatively impact large regions of the protein structure. However, the influence of the calcium sites on cadherin structure and function depends on their location in the protein.     

Computational model of E-cadherin clustering under force

E-cadherins play a critical role in the formation of cell-cell adhesions for several physiological functions, including tissue development, repair, and homeostasis. The formation of clusters of E-cadherins involves extracellular adhesive (trans-) and lateral (cis-) associations between E-cadherin ectodomains and stabilization through intracellular binding to the actomyosin cytoskeleton. This binding provides force to the adhesion and is required for mechanotransduction. However, the exact role of cytoskeletal force on the clustering of E-cadherins is not well understood. To gain insights into this mechanism, we developed a computational model based on Brownian dynamics. In the model, E-cadherins transit between structural and functional states; they are able to bind and unbind other E-cadherins on the same and/or opposite cell(s) through trans- and cis-interactions while also creating dynamic links with the actomyosin cytoskeleton. Our results show that actomyosin force governs the fraction of E-cadherins in clusters and the size and number of clusters. For low forces (below 10 pN), a large number of small E-cadherin clusters form with less than five E-cadherins each. At higher forces, the probability of forming fewer but larger clusters increases. These findings support the idea that force reinforces cell-cell adhesions, which is consistent with differences in cluster size previously observed between apical and lateral junctions of epithelial tissues.     

Homophilic adhesion of E-cadherin occurs by a co-operative two-step interaction of N-terminal domains.

Cluster formation of E-cadherin on the cell surface is believed to be of major importance for cell-cell adhesion. To mimic this process the extracellular part of mouse E-cadherin (ECAD) was recombinantly fused to the assembly domain of rat cartilage oligomeric matrix protein (COMP), resulting in the chimeric protein ECAD-COMP. The COMP domain formed a five-stranded alpha-helical coiled-coil. This enabled the formation of a pentameric ECAD with bundled C-termini and free N-termini. The pentameric protein construct ECAD-COMP and the monomeric ECAD were expressed in human embryonal kidney 293 cells. Electron microscopy, analytical ultracentrifugation, solid phase binding and cell attachment assays revealed that pentamers showed strong self-association and cell attachment, whereas monomers exhibited no activity. At the high internal concentration in the pentamer the N-terminal EC1 domains of two E-cadherin arms interact to form a ring-like structure. Then the paired domains interact with a corresponding pair from another pentamer. None of the four other extracellular domains of E-cadherin is involved in this interaction. Based on these results, an in vivo mechanism is proposed whereby two N-terminal domains of neighbouring E-cadherins at the cell surface first form a pair, which binds with high affinity to a similar complex on another cell. The strong dependence of homophilic interactions on C-terminal clustering points towards a regulation of E-cadherin mediated cell-cell adhesion via lateral association.     

IQGAP1 and calmodulin modulate E-cadherin function

Ca(2+)-dependent cell-cell adhesion is mediated by the cadherin family of transmembrane proteins. Adhesion is achieved by homophilic interaction of the extracellular domains of cadherins on adjacent cells, with the cytoplasmic regions serving to couple the complex to the cytoskeleton. IQGAP1, a novel RasGAP-related protein that interacts with the cytoskeleton, binds to actin, members of the Rho family, and E-cadherin. Calmodulin binds to IQGAP1 and regulates its association with Cdc42 and actin. Here we demonstrate competition between calmodulin and E-cadherin for binding to IQGAP1 both in vitro and in a normal cellular milieu. Immunocytochemical analysis in MCF-7 (E-cadherin positive) and MDA-MB-231 (E-cadherin negative) epithelial cells revealed that E-cadherin is required for accumulation of IQGAP1 at cell-cell junctions. The cell-permeable calmodulin antagonist CGS9343B significantly increased IQGAP1 at areas of MCF-7 cell-cell contact, with a concomitant decrease in the amount of E-cadherin at cell-cell junctions. Analysis of E-cadherin function revealed that CGS9343B significantly decreased homophilic E-cadherin adhesion. On the basis of these data, we propose that disruption of the binding of calmodulin to IQGAP1 enhances the association of IQGAP1 with components of the cadherin-catenin complex at cell-cell junctions, resulting in impaired E-cadherin function.     

Ectodomain shedding of nectin-1alpha by SF/HGF and TPA in MDCK cells

Nectin is a Ca(2+)-independent immunoglobulin-like cell-cell adhesion molecule implicated in the organization of the junctional complex comprised of E-cadherin-based adherens junctions and claudin-based tight junctions in epithelial cells. Scatter factor (SF)/hepatocyte growth factor (HGF) and 12-O-tetradecanoylphorbol-13-acetate (TPA), a tumor-promoting phorbol ester, induce cell spreading, followed by cell-cell dissociation and cell scattering, in Madin-Darby canine kidney (MDCK) cells. We found here that SF/HGF and TPA induced proteolytic cleavage of nectin-1alpha in the ectodomain, resulting in generation of the 80-kDa extracellular fragment and the 33-kDa fragment composed of the transmembrane and cytoplasmic domains, in MDCK cells. This shedding of nectin-1alpha was inhibited by metalloprotease inhibitors. These results indicate that SF/HGF and TPA induce the ectodomain shedding of nectin-1alpha presumably by a metalloprotease, and have raised the possibility that this shedding is involved in the SF/HGF- and TPA-induced cell-cell dissociation.     

A presenilin-1/gamma-secretase cleavage releases the E-cadherin intracellular domain and regulates disassembly of adherens junctions

E-cadherin controls a wide array of cellular behaviors including cell-cell adhesion, differentiation and tissue development. Here we show that presenilin-1 (PS1), a protein involved in Alzheimer's disease, controls a gamma-secretase-like cleavage of E-cadherin. This cleavage is stimulated by apoptosis or calcium influx and occurs between human E-cadherin residues Leu731 and Arg732 at the membrane-cytoplasm interface. The PS1/gamma-secretase system cleaves both the full-length E-cadherin and a transmembrane C-terminal fragment, derived from a metalloproteinase cleavage after the E-cadherin ectodomain residue Pro700. The PS1/gamma-secretase cleavage dissociates E-cadherins, beta-catenin and alpha-catenin from the cytoskeleton, thus promoting disassembly of the E-cadherin-catenin adhesion complex. Furthermore, this cleavage releases the cytoplasmic E-cadherin to the cytosol and increases the levels of soluble beta- and alpha-catenins. Thus, the PS1/gamma-secretase system stimulates disassembly of the E-cadherin- catenin complex and increases the cytosolic pool of beta-catenin, a key regulator of the Wnt signaling pathway.     

Stability studies of extracellular domain two of neural-cadherin

Neural- (NCAD) and epithelial- (ECAD) cadherin are calcium-dependent cell-adhesive molecules, and are localized at excitatory and inhibitory synapses respectively. They play an important role in synaptogenesis, synapse maintenance and plasticity. The extracellular region plays a critical role in cadherin-mediated cell adhesion, and has five tandemly repeated ectodomains (EC1-EC5). Calcium binding is required for dimer formation between first two N-terminal domains (EC1-EC2). Despite similarity in the primary structure, the extracellular domains of NCAD and ECAD have different intrinsic stability, dimerization affinity and kinetics of disassembly. To investigate the origin of these differences, we are characterizing the modular domains individually. Here, we report studies of NCAD2, EC2 of NCAD. This domain is important for calcium binding and is the physical linkage between the dimerization interface in EC1 and the membrane proximal modular domains. Thermal-denaturation studies show that NCAD2 is less stable than ECAD2 and less influenced by the adjoining 7-residue, N- and C-terminal linker segments. In addition the NCAD2 constructs are less influenced by added salt. This difference is likely due to variation in the overall number and distribution of charges on these anionic proteins. Our studies indicate that despite their sequence similarity and apparently passive role in adhesive dimer formation, EC2 of E- and N-cadherins are distinctly different and may contribute to the differences in energetics and kinetics of dimerization.     

Role of each immunoglobulin-like loop of nectin for its cell-cell adhesion activity

Nectins are Ca(2+)-independent immunoglobulin (Ig)-like cell-cell adhesion molecules that form cell-cell junctions, cooperatively with or independently of cadherins, in a variety of cells. Nectins comprise a family of four members, nectin-1, -2, -3, and -4. All nectins have one extracellular region with three Ig-like loops, one transmembrane segment, and one cytoplasmic tail. It has been shown mainly by use of cadherin-deficient L fibroblasts stably expressing each nectin that nectins first form homo-cis-dimers and then homo- or hetero-trans-dimers, causing cell-cell adhesion, and that the formation of the cis-dimers is necessary for the formation of the trans-dimers. However, kinetics of the formation of these dimers have not been examined biochemically by use of pure nectin proteins. We prepared here pure recombinant proteins of extracellular fragments of nectin-3 containing various combinations of Ig-like loops, all of which were fused to the Fc portion of IgG and formed homo-cis-dimers through the Fc portion, and of an extracellular fragment of nectin-1 containing three Ig-like loops which was fused to secreted alkaline phosphatase and formed homo-cis-dimers. We showed here by use of these proteins that the first Ig-like loop of nectin-3 was essential and sufficient for the formation of trans-dimers with nectin-1, but that the second Ig-like loop of nectin-3 was furthermore necessary for its cell-cell adhesion activity.     

Annexin A6 at the cardiac myocyte sarcolemma--evidence for self-association and binding to actin

The plasma membrane of the heart muscle cell and its underlying cytoskeleton are vitally important to the function of the heart. Annexin A6 is a major cellular calcium and phospholipid binding protein. Here we show that annexin A6 copurifies with sarcolemma isolated from pig heart. Two pools of annexin A6 are present in the sarcolemma fraction, one dependent on calcium and one that resists extraction by the calcium chelator EGTA. Potential annexin A6 binding proteins in the sarcolemma fraction were identified using Far Western blotting. Two major annexin A6 binding proteins were identified as actin and annexin A6 itself. Annexin A6 bound to itself both in the presence and in the absence of calcium ions. Sites for self association were mapped by performing Western blots on proteolytic fragments of recombinant annexin A6. Annexin A6 bound preferentially not only to the N terminal fragment (domains I-IV, residues 1-352) but also to C-terminal fragments corresponding to domains V+VI and domains VII+VIII. Actin binding to annexin A6 was calcium-dependent and exclusively to the N-terminal fragment of annexin A6. A calcium-dependent complex of annexin A6 and actin may stabilize the cardiomyocyte sarcolemma during cell stimulation.     

The remarkable mechanical strength of polycystin-1 supports a direct role in mechanotransduction

Polycystin-1 is a large membrane-associated protein that interacts with polycystin-2 in the primary cilia of renal epithelial cells to form a mechanosensitive ion channel. Bending of the cilia induces calcium flow into the cells, mediated by the polycystin complex. Antibodies to polycystin-1 and polycystin-2 abolish this activation. Based on this, it has been suggested that the extracellular region of polycystin-1, which has a number of putative binding domains, may act as a mechanosensor. A large proportion of the extracellular region of polycystin-1 consists of beta-sandwich PKD domains in tandem array. We use atomic force microscopy to investigate the mechanical properties of the PKD domains of polycystin-1. We show that these domains, despite having a low thermodynamic stability, exhibit a remarkable mechanical strength, similar to that of immunoglobulin domains in the giant muscle protein titin. In agreement with the experimental results molecular dynamics simulations performed at low constant force show that the first PKD domain of polycystin (PKDd1) has a similar unfolding time as titin I27, under the same conditions. The simulations suggest that the basis for this mechanical stability is the formation of a force-stabilised intermediate. Our results suggest that these domains will remain folded under external force supporting the hypothesis that polycystin-1 could act as a mechanosensor, detecting changes in fluid flow in the kidney tubule.     

Transmembrane and Extracellular Domains of Syndecan-1 Have Distinct Functions in Regulating Lung Epithelial Migration and Adhesion

Syndecan-1 is a cell surface proteoglycan that can organize co-receptors into a multimeric complex to transduce intracellular signals. The syndecan-1 core protein has multiple domains that confer distinct cell- and tissue-specific functions. Indeed, the extracellular, transmembrane, and cytoplasmic domains have all been found to regulate specific cellular processes. Our previous work demonstrated that syndecan-1 controls lung epithelial migration and adhesion. Here, we identified the necessary domains of the syndecan-1 core protein that modulate its function in lung epithelial repair. We found that the syndecan-1 transmembrane domain has a regulatory function in controlling focal adhesion disassembly, which in turn controls cell migration speed. In contrast, the extracellular domain facilitates cell adhesion through affinity modulation of α₂β₁ integrin. These findings highlight the fact that syndecan-1 is a multidimensional cell surface receptor that has several regulatory domains to control various biological processes. In particular, the lung epithelium requires the syndecan-1 transmembrane domain to govern cell migration and is independent from its ability to control cell adhesion via the extracellular domain.     

Separation force measurements reveal different types of modulation of E-cadherin-based adhesion by nectin-1 and -3

Nectins are Ca2+-independent cell adhesion molecules found at cadherin-based adherens junctions. We used a dual pipette assay that measures the forces required to separate cell doublets to determine how nectins affect the formation and strength of cell-cell adhesion. Less force was required to separate doublets of L cells expressing nectin-1 or nectin-3 than to separate doublets of E-cadherin-expressing cells. Heterodimers formed between cells expressing nectin-1 or nectin-3 adhered more strongly than homodimers. Nectin-3 that does not trans-interact with nectin-1 inhibited E-cadherin-mediated adhesion. However, the extracellular fragment of nectin-1 did not have an agonistic effect on E-cadherin-dependent cell adhesion when it trans-interacted with nectin-3, expressed at high levels in cells. In contrast, the extracellular fragment of nectin-3 had a significant agonistic effect on cadherin-based adhesion when it interacted with endogenous nectin-1, expressed at low levels in cells. Our results indicate that E-cadherin is the key molecule involved in cell adhesion and that the regulation of E-cadherin-based adhesion involving cellular nectin-1 trans-interacting with nectin-3 is qualitatively different from that involving cellular nectin-3 trans-interacting with nectin-1 and depends on the nectin levels expressed by cells.     

Fast dissociation kinetics between individual E-cadherin fragments revealed by flow chamber analysis

E-cadherin is the predominant adhesion molecule of epithelia. The interaction between extracellular segments of E-cadherin in the membrane of opposing cells is homophilic and calcium dependent. Whereas it is widely accepted that the specificity of the adhesive interaction is localized to the N-terminal domain, the kinetics of the recognition process are unknown. We report the first quantitative data describing the dissociation kinetics of individual E-cadherin interactions. Aggregation assays indicate that the two outermost domains of E-cadherin (E/EC1-2) retain biological activity when chemically immobilized on glass beads. Cadherin fragment trans-interaction was analysed using a flow chamber technique. Transient tethers had first-order kinetics, suggesting a unimolecular interaction. The unstressed lifetime of individual E-cadherin interactions was as brief as 2 s. A fast off rate and the low tensile strength of the E-cadherin bond may be necessary to support the high selectivity and plasticity of epithelial cell interactions.     

Interaction of paratropomyosin with beta-connectin and its 400-kilodalton fragment from chicken skeletal muscle as influenced by the calcium ion concentration.

The binding of paratropomyosin to beta-connectin, which has been suggested to interact at the A-I junction of a sarcomere, was confirmed by measuring the changes in turbidity of a mixture with changing NaCl concentration, pH and free calcium ions, and by morphological observation and a coprecipitation assay of the aggregates formed in the mixture. Paratropomyosin also bound to the 400-kDa fragment which is the N-terminal portion of beta-connectin and contains the A-I junction region. Moreover, the interaction of paratropomyosin with the 400-kDa fragment was enhanced by a calcium ion concentration from 10(-7) M to 10(-5) M and markedly suppressed above 10(-4) M calcium ions. We conclude that paratropomyosin probably binds to the 400-kDa fragment of beta-connectin in the A-I junction region in living and pre-rigor skeletal muscle. In postmortem skeletal muscle paratropomyosin may be released from the 400-kDa portion of the connectin filament by increased calcium ion concentration and translocated on to thin filaments to induce meat tenderization.