Porcine vinculin and metavinculin differ by a 68-residue insert located close to the carboxy-terminal part of the molecule.

Metavinculin is a higher mol. wt variant of vinculin expressed only in muscle tissue. Using amino acid sequencing methods on the intact molecules and their proteolytic subfragments, together with a polyclonal antibody specific only for metavinculin from porcine stomach, we have been able to identify and sequence the difference peptide in the porcine metavinculin molecule. By alignment with the complete sequence of chick fibroblast vinculin (communicated by G.J. Price, P. Jones, M.D. Davison, R. Bendori, S. Griffiths, B. Patel, B. Geiger and D.R. Critchley, prior to publication) the exact location of the insert could be determined. In porcine metavinculin, this insert lies between the 90-kd protease-resistant amino-terminal core and the carboxy terminus of the molecule. It contains 68 amino acids and is flanked by KWSSK sequences, one of which is present in vinculin. The identity of the mapped vinculin and metavinculin sequences outside this difference peptide is consistent with the two proteins arising via alternative splicing at the mRNA level. The lack of reactivity of the porcine metavinculin antibody with metavinculin from chicken as well as the finding of different proteolytic cleavage sites in avian metavinculin indicate a species-specific amino acid sequence in the difference piece of the metavinculin molecule.     

Functional studies of the domains of talin

The protein talin has two domains of approximately 200 and 47 kD, which can be cleaved apart by a variety of proteases. To examine the function of these two structural domains of talin, we have digested purified talin with a calcium-dependent protease and separated the resulting fragments chromatographically. Both fragments were radioiodinated and used to probe Western blots of whole fibroblasts and chicken gizzard extracts. The large talin fragment bound to vinculin and metavinculin. The small fragment did not demonstrate any binding in this assay. The fragments were labeled fluorescently and microinjected into fibroblasts in tissue culture. The large talin fragment incorporated quickly into focal adhesions where it remained stable for at least 14 h. The small fragment associated with focal adhesions of fibroblasts but was also distributed diffusely in the cytoplasm and the nucleus. These experiments suggest that talin has at least two sites that contribute to its localization in focal adhesions. Intact talin microinjected into Madin-Darby bovine kidney epithelial cells localized to the focal adhesions but was excluded from the zonulae adherentes, despite the localization of vinculin to both of these sites. In contrast, the large talin fragment, when microinjected into these epithelial cells, incorporated into both focal adhesions and zonulae adherentes. The difference in localization between the large talin fragment and intact talin seems to be due to the removal of the small domain. This difference in localization suggests that talin binding sites in zonulae adherentes have limited accessibility.     

Interaction of iodinated vinculin, metavinculin and α-actinin with cytoskeletal proteins

Iodinated vinculin, metavinculin and α-actinin were used to probe the interaction of these proteins with electrophoretically separated cytoskeletal proteins. Using the gel overlay technique, we detected strong binding of ¹²⁵I-vinculin and ¹²⁵I-metavinculin to α-actinin, 175 kDa polypeptide, talin, vinculin and metavinculin themselves, and moderate binding to actin.¹²⁵I-α-actinin was capable of interacting with vinculin and metavinculin. The specific binding of ¹²⁵-I-α-actinin to vinculin and metavinculin immobilized on a polysterene surface was also demonstrated. We suggest that the ability of vinculin and α-actinin to form a complex may be realized in microfilament-membrane linkages.     

Obstructive hypertrophic cardiomyopathy is associated with reduced expression of vinculin in the intercalated disc

Mutations in the cardiac-specific insert of vinculin, metavinculin, rarely cause hypertrophic cardiomyopathy (HCM) and dilated cardiomyopathy (DCM). Subsequently, a missense mutation in the ubiquitously expressed vinculin was discovered in a patient with obstructive HCM. Microscopic examination of both myectomy specimens from patients bearing genetic defects in metavinculin and vinculin showed a marked reduction of vinculin/metavinculin expression in the intercalated disc, but normal expression in the Z-disc. Given that distinct functional domains were altered by the metavinculin and vinculin mutations, we hypothesized that the intercalated disc-specific reduction of vinculin may stem from left ventricular tract obstruction in general rather than rarely observed perturbations in VCL-encoded vinculin. To test this hypothesis, we examined the localization of vinculin/metavinculin in hypertrophied human heart tissue from patients with cardiovascular conditions associated with obstruction and hemodynamic overload using an immunohistochemistry approach. Tissue specimens derived from patients with obstructive HCM and aortic stenosis (AS) showed a universal defect of vinculin/metavinculin expression in the intercalated disc but preserved expression in the cardiac Z-disc, whereas tissue specimens derived from patients with either DCM, hypertensive heart disease (HTN), or pulmonary hypertension (PHTN) exhibited normal expression of vinculin/metavinculin in both the Z- and the intercalated disc despite being associated with hypertrophy. Results of this study suggest that cardiac hypertrophy may be associated with different expression of the marker vinculin/metavinculin depending on the underlying pathophysiology; hemodynamic overload may not affect the localization whereas obstructive disease substantially reduces the expression of vinculin preferentially in the intercalated disc.     

Detection of metavinculin in human platelets using a modified talin overlay assay

Talin was purified from human platelets and proteolytically cleaved by the calcium-dependent protease (CDP II) to two stable fragments of 200 and 47 kDa. The 200 kDa fragment was radiolabeled and used in Western blot overlay assays of fractionated platelet proteins. This procedure revealed vinculin to be the major talin binding protein. However, in addition, a less abundant protein of approximately 150 kDa also interacted strongly with the talin fragment. Using conventional immunoblot analysis we have confirmed that this protein is metavinculin, a protein previously believed to be confined to cardiac and smooth muscle tissue.     

Comparative biochemical analysis suggests that vinculin and metavinculin cooperate in muscular adhesion sites

Metavinculin, the muscle-specific splice variant of the cell adhesion protein vinculin, is characterized by a 68-amino acid insert within the C-terminal tail domain. The findings that mutations within this region correlate with hereditary idiopathic dilated cardiomyopathy in man suggest a specific contribution of metavinculin to the molecular architecture of muscular actin-membrane attachment sites, the nature of which, however, is still unknown. In mice, metavinculin is expressed in smooth and skeletal muscle, where it co-localizes with vinculin in dense plaques and costameres, respectively, but is of conspicuously low abundance in the heart. Immunoprecipitates suggest that both isoforms are present in the same complex. On the molecular level, both vinculin isoforms are regulated via an intramolecular head-tail interaction, with the metavinculin tail domain having a lower affinity for the head as compared with the vinculin tail. In addition, metavinculin displays impaired binding to acidic phospholipids and reduced homodimerization. Only in the presence of phospholipid-activated vinculin tail, the metavinculin tail domain is readily incorporated into heterodimers. Mutational analysis revealed that the metavinculin insert significantly alters binding of the C-terminal hairpin loop to acidic phospholipids. In summary, our data lead to a model in which unfurling of the metavinculin tail domain is impaired by the negative charges of the 68-amino acid insert, thus requiring vinculin to fully activate the metavinculin molecule. As a consequence, microfilament anchorage may be modulated at muscular adhesion sites through heterodimer formation.     

Raver1, a dual compartment protein, is a ligand for PTB/hnRNPI and microfilament attachment proteins.

By screening a yeast two-hybrid library with COOH-terminal fragments of vinculin/metavinculin as the bait, we identified a new protein termed raver1. Raver1 is an 80-kD multidomain protein and widely expressed but to varying amounts in different cell lines. In situ and in vitro, raver1 forms complexes with the microfilament-associated proteins vinculin, metavinculin, and alpha-actinin and colocalizes with vinculin/metavinculin and alpha-actinin at microfilament attachment sites, such as cell-cell and cell matrix contacts of epithelial cells and fibroblasts, respectively, and in costameres of skeletal muscle. The NH2-terminal part of raver1 contains three RNA recognition motifs with homology to members of the heterogeneous nuclear RNP (hnRNP) family. Raver1 colocalizes with polypyrimidine tract binding protein (PTB)/hnRNPI, a protein involved in RNA splicing of microfilament proteins, in the perinucleolar compartment and forms complexes with PTB/hnRNPI. Hence, raver1 is a dual compartment protein, which is consistent with the presence of nuclear location signal and nuclear export sequence motifs in its sequence. During muscle differentiation, raver1 migrates from the nucleus to the costamere. We propose that raver1 may coordinate RNA processing and targeting as required for microfilament anchoring in specific adhesion sites.     

Purification and characterization of β-structural domains of β-lactoglobulin liberated by limited proteolysis

Incubation of β-lactoglobulin with immobilized trypsin at 5–10°C results in a time-dependent release of several fragments of the core domain in yields approaching 15%. Digests were fractionated by ion-exchange chromatography with a Mono Q HR5/5 column and analyzed after disulfide reduction by polyacrylamide gel electrophoresis in sodium dodecylsulfate. Three fragments with approximate molecular weights of 13.8, 9.6, and 6.7 kD were identified. The fraction from ion-exchange chromatography yielding the 6.7 kD fraction after disulfide reduction was further characterized because it was most homogeneous and gave the highest yield. The C-terminal cleavage site of the 6.7 kD core fragment appeared to be Lys₁₀₀ or Lys₁₀₁ as determined by C-terminal amino acid analysis. The exact masses, after reduction with dithiothreitol, are 6195 and 6926 as determined by laser desorption mass spectrometry, corresponding to residues 48–101 and 41–100. Prior to reduction, β-lactoglobulin C-terminal residues 149–162 are connected to these core domain fragments as shown by C-terminal analysis and mass spectrometry. Structural studies indicate that these 7.9 and 8.6 kD core domain fragments released by immobilized trypsin retain much of their native structure. CD spectra indicate the presence of antiparallel β-sheet structure similar to the native protein but the α-helix is lost. Spectra in the aromatic region indicate the existence of tertiary structure. Moreover, structural transitions in urea are completely reversible as measured by CD spectra, although the extrapolated ΔG _D ^H20 and the urea concentration at the transition midpoint are lower than for the native protein. The core domain fragments also display apH-dependent binding to immobilizedtrans-retinal as does intact protein. A single endotherm is obtained for both core domain fragments and native protein upon differential scanning calorimetry, but again, the domain is less stable as indicated by a transition peak maxima of 56.9°C as compared with 81.1°C for native protein.     

Cholinergic receptor-mediated differential cytoskeletal recruitment of actin- and integrin-binding proteins in intact airway smooth muscle

We tested the hypothesis that cholinergic receptor stimulation recruits actin- and integrin-binding proteins from the cytoplasm to the cytoskeleton-membrane complex in intact airway smooth muscle. We stimulated bovine tracheal smooth muscle with carbachol and fractionated the tissue homogenate into pellet (P) and supernatant (S) by ultracentrifugation. In unstimulated tissues, calponin exhibited the highest basal P-to-S ratio (P/S; 2.74 ± 0.47), whereas vinculin exhibited the lowest P/S (0.52 ± 0.09). Cholinergic receptor stimulation increased P/S of the following proteins in descending order of sensitivity: -actinin > talin metavinculin > -smooth muscle actin > vinculin calponin. Carbachol induced ERK1/2 phosphorylation by 300% of basal value. U0126 (10 µM) completely inhibited carbachol-induced ERK1/2 phosphorylation but did not significantly affect the correlation between -actinin P/S and carbachol concentration. This observation indicates that cytoskeletal/membrane recruitment of -actinin is independent of ERK1/2 mitogen-activated protein kinase activation. Metavinculin and vinculin are splice variants of a single gene, but metavinculin P/S was significantly higher than vinculin P/S. Furthermore, the P/S of metavinculin but not vinculin increased significantly in response to cholinergic receptor stimulation. Calponin and -actinin both belong to the family of calponin homology (CH) domain proteins. However, unlike -actinin, the calponin P/S did not change significantly in response to cholinergic receptor stimulation. These findings indicate differential cytoskeletal/membrane recruitment of actin- and integrin-binding proteins in response to cholinergic receptor stimulation in intact airway smooth muscle. -Actinin, talin, and metavinculin appear to be key cytoskeletal proteins involved in the recruitment process. actinin; mitogen-activated protein kinase; metavinculin; vinculin     

Purification and characterization of an 85 kDa talin-binding fragment of vinculin

Vinculin and talin are adhesion plaque proteins which have been shown to interact with each other in vitro. In order to begin to investigate where the talin-binding domain is in vinculin, vinculin was digested with Staphylococcus aureus V8 protease to generate two major fragments of 85 and 30 kDa, and these fragments were purified. Nitrocellulose overlays with 125I-talin and the 125I-85 kDa vinculin fragment and sucrose density gradient centrifugation demonstrated that the talin-binding domain was localized to the 85 kDa vinculin fragment. Quantification of 125I-talin binding in the overlays showed that four times more talin bound to the 85 kDa fragment as compared to intact vinculin. Competitive immunoprecipitation experiments demonstrated that unlabeled 85 kDa fragment was about three-fold more effective at competing for 125I-85 kDa binding to talin than was unlabeled vinculin. These results suggest that the 30 kDa fragment inhibits the vinculin-talin interaction even though the talin-binding domain is localized in the 85 kDa fragment.     

Pepsin fragmentation of botulinum type E neurotoxin: Isolation and characterization of 112, 48, 46, and 16 kD fragments

Controlled digestion of 150 kD single chain botulinum type E neurotoxin with pepsin atpH 6.0 produced 112, 48, 46, and 16 kD fragments. These were chromatographically purified; their locations in the 1300 amino acid residue long neurotoxin were determined by identifying the amino terminal 10 residues of 112 and 48 kD fragments, 50 residues of 46 kD fragment, and 59 residues of 16 kD fragment. The 48 and 112 kD fragments contain the N-terminal segment of the neurotoxin (i.e., residue no. 1 to 425 and 1 to 990, respectively), the 46 kD fragment corresponds to 407 residues of the C-terminal region, and the 16 kD fragment contains the 140 residues from a segment nearer to the C-terminus. The 48 kD fragment is similar to the 50 kD N-terminal light chain of the 150 kD dichain neurotoxin, which is generated by tryptic cleavage of the 150 kD single chain neurotoxin, and is separated from the 100 kD C-terminal heavy chain by dithiothreitol (DTT) reduction of an intrachain disulfide bond in the presence of 2 M urea (Sathyamoorthy and DasGupta,J. Biol. Chem. 260, 10461, 1985). The pepsin-generated 48 kD fragment, unlike the light chain, was isolated without exposure to DTT and urea. The single chain 112 kD fragment following trypsin digestion yielded 48 and 60 kD fragments that were separable after DTT reduction of the intrachain disulfide which links them. The N-terminal residues of the smaller fragment were identical to that of the single chain 150 kD neurotoxin; the single chain 112 kD fragment is therefore the neurotoxin minus the 50 kD C-terminal half of the heavy chain. The biological activities of the 48 and 112 kD fragments can be demonstrated in permeabilized PC12 cells (Lomnethet al., J. Neurochem. 57, 1413, 1991); they inhibit norepinephrine release.     

Metavinculin: New insights into functional properties of a muscle adhesion protein

Metavinculin is a muscle-specific splice variant of the ubiquitously expressed cytoskeletal adaptor protein vinculin. Both proteins are thought to be co-expressed in all muscle types where they co-localize to microfilament-associated adhesion sites. It has been shown that a metavinculin-specific insertion of 68 amino acids alters the biochemical properties of the five-helix bundle in the tail domain. Here, we demonstrate that the metavinculin-specific helix H1′ plays an important role for protein stability of the tail domain, since a point mutation in this helix, R975W, which is associated with the occurrence of dilated cardiomyopathy in man, further decreases thermal stability of the metavinculin tail domain. In striated muscle progenitor cells (myoblasts), both, metavinculin and the R975W mutant show significantly reduced, albeit distinctive residency and exchange rates in adhesion sites as compared to vinculin. In contrast to previous studies, we show that metavinculin is localized in a muscle fiber type-dependent fashion to the costameres of striated muscle, reflecting the individual metabolic and physiological status of a given muscle fiber. Metavinculin expression is highest in fast, glycolytic muscle fibers and virtually absent in M. diaphragmaticus, a skeletal muscle entirely lacking fast, glycolytic fibers. In summary, our data suggest that metavinculin enrichment in attachment sites of muscle cells leads to higher mechanical stability of adhesion complexes allowing for greater shear force resistance.     

Paxillin: a new vinculin-binding protein present in focal adhesions

The 68-kD protein (paxillin) is a cytoskeletal component that localizes to the focal adhesions at the ends of actin stress fibers in chicken embryo fibroblasts. It is also present in the focal adhesions of Madin-Darby bovine kidney (MDBK) epithelial cells but is absent, like talin, from the cell-cell adherens junctions of these cells. Paxillin purified from chicken gizzard smooth muscle migrates as a diffuse band on SDS-PAGE gels with a molecular mass of 65-70 kD. It is a protein of multiple isoforms with pIs ranging from 6.31 to 6.85. Using purified paxillin, we have demonstrated a specific interaction in vitro with another focal adhesion protein, vinculin. Cleavage of vinculin with Staphylococcus aureus V8 protease results in the generation of two fragments of approximately 85 and 27 kD. Unlike talin, which binds to the large vinculin fragment, paxillin was found to bind to the small vinculin fragment, which represents the rod domain of the molecule. Together with the previous observation that paxillin is a major substrate of pp60src in Rous sarcoma virus-transformed cells (Glenney, J. R., and L. Zokas. 1989. J. Cell Biol. 108:2401-2408), this interaction with vinculin suggests paxillin may be a key component in the control of focal adhesion organization.     

Cardiomyopathy Mutations in Metavinculin Disrupt Regulation of Vinculin-Induced F-Actin Assemblies

Debilitating heart conditions, notably dilated and hypertrophic cardiomyopathies (CMs), are associated with point mutations in metavinculin, a larger isoform of the essential cytoskeletal protein vinculin. Metavinculin is co-expressed with vinculin at sub-stoichiometric ratios in cardiac tissues. CM mutations in the metavinculin tail domain (MVt) occur within the extra 68-residue insert that differentiates it from the vinculin tail domain (Vt). Vt binds actin filaments (F-actin) and promotes vinculin dimerization to bundle F-actin into thick fibers. While MVt binds to F-actin in a similar manner to Vt, MVt is incapable of F-actin bundling and inhibits Vt-mediated F-actin bundling. We performed F-actin co-sedimentation and negative-stain EM experiments to dissect the coordinated roles of metavinculin and vinculin in actin fiber assembly and the effects of three known metavinculin CM mutations. These CM mutants were found to weakly induce the formation of disordered F-actin assemblies. Notably, they fail to inhibit Vt-mediated F-actin bundling and instead promote formation of large assemblies embedded with linear bundles. Computational models of MVt bound to F-actin suggest that MVt undergoes a conformational change licensing the formation of a protruding sub-domain incorporating the insert, which sterically prevents dimerization and bundling of F-actin by Vt. Sub-domain formation is destabilized by CM mutations, disrupting this inhibitory mechanism. These findings provide new mechanistic insights into the ability of metavinculin to tune actin organization by vinculin and suggest that dysregulation of this process by CM mutants could underlie their malfunction in disease.     

Regulation of HMG-CoA reductase: identification of the site phosphorylated by the AMP-activated protein kinase in vitro and in intact rat liver.

The intact, 100 kd microsomal enzyme and the 53 kd catalytic fragment of rat HMG-CoA reductase are both phosphorylated and inactivated by the AMP-activated protein kinase. Using the catalytic fragment, we have purified and sequenced peptides containing the single site of phosphorylation. Comparison with the amino acid sequence predicted from the cDNAs encoding other mammalian HMG-CoA reductases identifies this site as a serine residue close to the C-terminus (Ser872 in the human enzyme). Phosphopeptide mapping of native, 100 kd microsomal HMG-CoA reductase confirms that this C-terminal serine is the only major site phosphorylated in the intact enzyme by the AMP-activated protein kinase. The catalytic fragment of HMG-CoA reductase was also isolated from rat liver in the presence of protein phosphatase inhibitors under conditions where the enzyme is largely in the inactive form. HPLC, mass spectrometry and sequencing of the peptide containing Ser872 demonstrated that this site is highly phosphorylated in intact liver under these conditions. We have also identified by amino acid sequencing the N-terminus of the catalytic fragment, which corresponds to residue 423 of the human enzyme.     

Domain Structure and Conformation of a Cellobiohydrolase from Trichoderma pseudokiningii S-38

A cellobiohydrolase (CBH) with a molecular mass of 66 kD was purified from Trichoderma pseudokiningii S-38. Papain digestion produced a 59- to 60-kD core domain with 54% of intact activity on crystalline cellulose and with full activity against soluble substrates. Digestion products also included two small peptides with molecular mass of about 3–4 kD, which are heavily glycosylated and difficult to purify; the mixed peptides displayed the capacity to disorganize the cellulose fiber. The sequencing results indicated that the intact enzyme had a blocked N-terminal and there was a 10-amino-acid sequence in the N-terminal of the core protein of Ser-Gly-Thr-Ala-Val-Thr-Cys-Leu-Ala-Asp. Fluoresence and circular dichroism properties indicated that the core protein has an independent conformation and is conformationally similar to intact enzyme, suggesting that the spectroscopic properties of the intact enzyme come from the core protein.     

Sequence Analysis of a Proteolyzed Site in Drosophila Choline Acetyltransferase

The amino terminal sequence of the 13-kilodalton (kD) polypeptide present in purified Drosophila acetyl-CoA: choline-O-acetyltransferase (EC 2.3.1.6) was determined, and its position in the sequence of the intact enzyme was located. Enzyme polypeptides for sequencing were obtained from native enzyme protein by denaturation, followed by fractionation on reverse-phase HPLC. The 13-, 54-, and 67-kD polypeptides recovered from the separation were subjected to amino terminal sequencing. Only the 13-kD fragment yielded a sequence. The 67- and 54-kD polypeptides appeared completely blocked to gas-phase Edman sequencing. The location of the amino terminal sequence from the 13-kD polypeptide in the cDNA-deduced enzyme sequence indicated that this fragment represents the carboxyl portion of the 67-kD enzyme, with the 54-kD polypeptide providing the amino terminal portion. The proteolysis that gave rise to the 13-kD polypeptide occurred at the carboxyl side of a monobasic lysine residue. An earlier comparison of the enzyme from Drosophila and pigs indicated that the cleaved lysine may be a conserved residue in the porcine enzyme. The cleaved enzyme region characterized in this study does not coincide with the regions of high homology found in the two enzymes, but hydrophilicity profiles generated for this area showed similarities.     

Detection of an In Vivo 8 kD C-terminal Breakdown Product of D1-protein under Visible and UV-B Light

An 8 kD in vivo turnover product of D1 polypeptide was identified using a C-terminal specific anti-D1-antibody in thylakoids isolated from 5–10 days old seedlings of wheat (Triticum aestivum cv HD2329). Eight days old wheat seedlings grown under visible light were irradiated with UV-B (1 MW cm^?2) alone (0–5h) and Tricine SDS-PAGE was run of the isolated thylakoids. UV-B exposure of intact wheat leaves generates a fragment of 24 kD and concomitant increase in 8 kD fragment was also observed. From these results it is concluded that in wheat visible light induces the breakdown of D1 polypeptide into an 8 kD C-terminal thylakold bound fragment and UV-B stress results in an increase in 8 kD breakdown fragment, thus suggesting that visible light/UV-B has a common hot spot on D1 protein in wheat.     

Domain Structure and Conformation of a Cellobiohydrolase from Trichoderma pseudokiningii S-38

A cellobiohydrolase (CBH) with a molecular mass of 66 kD was purified from Trichoderma pseudokiningii S-38. Papain digestion produced a 59- to 60-kD core domain with 54% of intact activity on crystalline cellulose and with full activity against soluble substrates. Digestion products also included two small peptides with molecular mass of about 3–4 kD, which are heavily glycosylated and difficult to purify; the mixed peptides displayed the capacity to disorganize the cellulose fiber. The sequencing results indicated that the intact enzyme had a blocked N-terminal and there was a 10-amino-acid sequence in the N-terminal of the core protein of Ser-Gly-Thr-Ala-Val-Thr-Cys-Leu-Ala-Asp. Fluoresence and circular dichroism properties indicated that the core protein has an independent conformation and is conformationally similar to intact enzyme, suggesting that the spectroscopic properties of the intact enzyme come from the core protein.