Characterization of L-plastin interaction with beta integrin and its regulation by micro-calpain.

Recent evidences suggest that plastin/fimbrin is more than a simple actin cross-linking molecule. In this context and based on the fact that other members of the same family interact with transmembrane proteins, such as integrins, we have investigated a possible interaction between L-plastin and integrins. By combining coimmunoprecipitation of endogenous proteins and in vitro techniques based on solid phase and solution assays, we demonstrate that L-plastin is an additional binding partner for the beta-chain of integrin and confirmed that both proteins display some colocalization. We then show that L-plastin binds to the cytoplasmic domain of beta1 integrin and to beta1 and beta2 peptides. Using recombinant L-plastin domains, we demonstrate that the integrin-binding sites are not located in NH(2) terminal part of L-plastin but rather in the two actin-binding domains. Using pull-down, cross-linking experiments, and enzyme-linked immunosorbent assay, we show that the L-plastin/integrin complex is regulated by mu-calpain cleavage and is not directly dissociated by calcium. Indeed, despite the ability of calpain to cleave both proteins, only the cleavage of beta integrin hindered the formation of the L-plastin/integrin complex. We discuss these results in the light of the three-dimensional structure of the actin-binding domains of L-plastin.

Characterization of two transgene insertional mutations at pirouette, a mouse deafness locus.

The mouse mutant 'pirouette' (pi) exhibits profound hearing loss and vestibular defects due to inheritance of a recessive mutation on chromosome 5. Dysfunction has been correlated with defects during maturation of sensory cells in the inner ear. As an initial step in characterizing pirouette at the genetic level, we have localized the candidate interval to a small region on central chromosome 5 by analysis of a congenic strain of pirouette mice. This region exhibits conserved synteny with human chromosome 4 and suggests that pirouette may be a genetic model of the human nonsyndromic deafness disorder DFNB25, which has been localized to 4p15.3-q12. In addition to the original spontaneous pirouette strain, we have identified and characterized 2 additional mouse strains with allelic mutations at the same locus. Analysis of the morphology in each of the 3 pirouette alleles indicated very similar early postnatal alterations in maturation of stereocilia and suggests that the gene affected in pirouette normally plays a role in building or maintaining these structures that are critical for sensory mechanotransduction.

Biochemical characterization of the L-plastin-actin interaction shows a resemblance with that of alpha-actinin and allows a distinction to be made between the two actin-binding domains of the molecule.

Actin interaction with L-plastin, a plastin/fimbrins isoform of the alpha-actinin family of molecules, is poorly characterized, from the biochemical point of view. Besides, molecular modeling of the T-isoform has recently provided a complete model of interaction with filamentous actin [Volkmann, N., DeRosier, D., Matsudaira, P., and Hanein, D. (2001) J. Cell Biol. 153, 947-956]. In this study, we report that recombinant L-plastin binds actin in a manner that strongly resembles that of the alpha-actinin-actin interface. The similitudes concern the absence of specificity toward the actin isoform and the inhibition of the binding by phosphoinositides. Furthermore, the participation of actin peptides 112-125 and 360-372 in the interface together with an inhibition of the rate of pyrenyl F-actin depolymerization is in favor of a lateral binding of the plastin isoform along the filament axis and strenghtens the similitudes in the way L-plastin and alpha-actinin bind to actin. We have also investigated the functional aspect and the putative equivalence of the two actin-binding domains of L-plastin toward actin binding. We demonstrate for the first time that the two recombinant fragments, expressed as single domains, have different affinities for actin. We further analyzed the difference using chemical cross-linking and F-actin depolymerization experiments assayed by fluorescence and high-speed centrifugation. The results clearly demonstrate that the two actin-binding domains of plastin display different modes of interaction with the actin filament. We discuss these results in light of the model of actin interaction proposed for T-plastin.

Postmortem degradation of white fish skeletal muscle (sea bass, Dicentrarchus labrax): fat diet effects on in situ dystrophin proteolysis during the prerigor stage.

All during fish postmortem evolution, structural muscle proteins are targets for various proteases. During the prerigor period (24 hours at 4 degrees C for sea bass), cytoskeletal proteins are affected by the first proteolytic events. These cleavages disrupt connections between myofibrils and the extracellular matrix, induce segmentation of myofibril cores, and modify the rheological properties of tissue. Dystrophin, a cytoskeletal actin-binding protein, is a relevant in situ marker for muscular proteolysis in the prerigor period. The immunodetection of dystrophin allowed the monitoring of early proteolysis during fish storage. Using antidystrophin antibodies directed toward the carboxy-terminal region, a highly sensitive domain exposed to calpain activity, we showed that proteolysis kinetics are strongly influenced by the muscular lipid content. In particular, comparison between low-fat diets (11.3% lipid) and high-fat diets (30% lipid), used during sea bass farming (90 days), revealed a faster proteolysis rate during the first 8 hours of storage at 0 degrees C with the high-fat diet. The origin of this faster proteolysis is discussed on the basis of a possible activation or translocation of calpains related to lipid accumulation in muscle fibers and cytoskeleton alterations.

Interaction of actin with the capping protein, CapZ from sea bass (Dicentrarchus labrax) white skeletal muscle.

We have compared the functional properties of CapZ from fish white skeletal muscle with those of CapZ from chicken muscle. CapZ is a heterodimer, which enhances actin nucleation and inhibits the depolymerization process by binding to the barbed ends of microfilaments. Here, we report the interaction of CapZ not only with F-actin, but also with monomeric actin. The affinity of sea bass CapZ for G-actin estimated by enzyme-linked immunosorbent assay (ELISA) was in the microM range. This association was PIP2 dependent. Binding contacts with the barbed end of actin were delimited by both ELISA and fluorescence approaches. One site (actin sequence 338-348) was located in a helical region of the subdomain 1, region already implicated in the interaction with other actin binding proteins such as gelsolin. Another site implicates the C-terminal region (sequence 360-372) of actin. Finally, the partial competition of antibodies directed against CapZ alpha or beta-subunits towards CapZ interaction with actin filaments suggests both subunits participate in the complex with actin.

Use of a chaotropic anion iodide in the purification of Z-line proteins: isolation of CapZ from fish white muscle.

In the present study, we have described an improved method allowing the isolation of proteins which form tightly associated complexes in organized structures such as Z line in skeletal muscle. This procedure is based on both extraction and chromatography in the presence of a chaotropic agent. KI at medium concentration (0.6 M) was selected, taking into account its dissociating activity and mild effect on the native state of proteins. This procedure was applied to purify and to characterize for the first time a CapZ from fish white muscle, a protein involved in the stabilization of the filaments in Z line. The alpha and beta CapZ subunits were identified using anti-synthetic peptide antibodies directed against conserved sequences derived from chicken CapZ. The protocol can be also used for the isolation of other muscular proteins such as alpha-actinin and actin. Finally this technique may be utilized to obtain a good amount of capping protein which could be employed in experiments of microfilament dynamics.

Alpha actinin-CapZ, an anchoring complex for thin filaments in Z-line.

CapZ is a widely distributed and highly conserved, heterodimeric protein, that nucleates actin polymerization and binds to the barbed ends of actin filaments, preventing the addition or loss of actin monomers. CapZ interaction with actin filaments was shown to be of high affinity and decreased in the presence of PIP2. CapZ was located in nascent Z-lines during skeletal muscle myofibrillogenesis before the striated appearance of thin filaments in sarcomers. In this study, the stabilization and the anchorage of thin filaments were explored through identification of CapZ partners in the Z-line. Fish (sea bass) striated white muscle and its related Z-line proteins were selected since they correspond to the simplest Z-line organization. We report here the interaction between purified CapZ and alpha-actinin, a major component of Z filaments and polar links in Z-discs. Affinity of CapZ for alpha-actinin, estimated by fluorescence and immunochemical assays, is in the microM range. This association was found to be independent of actin and shown to be weakened in the presence of phosphoinositides. Binding contacts on the alpha-actinin molecule lie in the 55 kDa repetitive domain. A model including CapZ/alpha-actinin/titin/actin interactions is proposed considering Luther's 3D Z-line reconstruction.

Binding of a native titin fragment to actin is regulated by PIP2.

Titin is a giant protein which extends from Z-line to M-line in striated muscles. We report here the purification of a 150-kDa titin fragment, obtained after V8 protease treatment of myofibrils. This polypeptide was located at the N1-line level, in a titin part known to exhibit stiff properties correlated to an association with actin. By solid or liquid phase binding assays and cosedimentation, we have clearly demonstrated a direct, saturable and relative high affinity binding of the native titin fragment to F-actin. The 150-kDa titin fragment was also shown to accelerate actin polymerization. Furthermore, the actin-titin interaction was found to be inhibited by phosphoinositides.

Analysis of long-range structural effects induced by DNase-I interaction with actin monomeric form or complexed to CapZ.

Two fundamental properties of monomeric actin were examined in this study, ie its interaction with DNase-I, and the inhibition of endonuclease activity consecutive to the association of the two molecules. In particular, the topological independence between catalytic site of DNase-I and interface with actin, structural changes in actin monomer and the absence of conformational changes in DNase-I were described. We demonstrated a loss of flexibility of antigenic structures in actin subdomain I (ie epitopes 18-28 and 95-105) as well as modification in the exposure of Cys10 and Cys374 after DNase-I binding. Furthermore, the conformational changes induced by DNase-I into the actin molecule weakened the interaction of CapZ to its binding site located in the C-terminal region of actin monomer. These structural changes were time-dependent. When actin was cleaved in the DNase-I binding loop (sequence 38-52) at position 42 by E coli A2 strain protease, a tight DNase-I binding to split actin and the conformational changes were still observed, whereas the DNase-I inhibition activity was completely abolished. Finally, when we substitute Ca2+ by Mg2+ (ATP-Mg2+ monomeric actin) which induces a tighter conformation of actin and partially restores the inhibitory ability of split actin, long-range conformational effects of DNase-I are prevented and the ternary complex DNase-I-actin-CapZ is obtained.

Isolation and properties of white skeletal muscle alpha-actinin from sea-trout (Salmo trutta) and bass (Dicentrarchus labrax).

Fish alpha-actinin purified from sea-trout and bass white muscle by means of two different extraction procedures was used to investigate the eventual presence of different muscle isoforms in Z-disks. These fish alpha-actinins have the same apparent molecular weight (100 kDa) and the same isoelectric point (pI = 5.6), and also have a total antigenic identity towards anti-bass and anti-chicken alpha-actinin antibodies, suggesting a single molecular species. The role of fish alpha-actinin as an anchorage site for thin actin filaments and elastic titin filaments in Z-bands was studied. Despite conservation of the actin-binding site, fish alpha-actinin has a better actin-binding ability (kD = 0.3 microM) than chicken smooth muscle alpha-actinin (kD = 1.6 microM). Several other structural and functional characteristics of fish alpha-actinin were also studied: conservation of sequence and domain structure, the role of divalent ions (Ca2+, Mg2+) and the dielectric constant of the medium in alpha-actinin-actin interaction. Although the reason for fish white muscle alpha-actinin's close affinity to actin was not clearly established, our results suggested that the physicochemical environment of the Z-filaments in Z-disks might be crucial.

Actin interaction with purified dystrophin from electric organ of Torpedo marmorata: possible resemblance with filamin-actin interface.

We have purified dystrophin from Torpedo marmorata electric tissue by means of alkaline extraction in conjunction with an affinity chromatography column using anti-peptide antibodies. Using solution (cosedimentation) and solid phase experiments (sedimentation with Sepharose filamentous actin and ELISA), we have demonstrated that purified dystrophin is able to bind filamentous and monomeric actin. Using ELISA coupled with biotin labelled peptides and taking advantage of strong affinity binding of streptavidin-biotin complex, we have identified two exposed sequences of the actin molecule implicated in dystrophin binding: fragment 40-113, further restricted to peptide 75-106 and peptide 360-372. In a previous study, we have shown that fragment 40-113 displays binding site(s) for filamin but probably not for alpha-actinin. Moreover, we have recently reported that alpha-actinin and filamin display divergent behaviours towards conformational changes of actin. In this study, we have demonstrated that, similarly to filamin, dystrophin binding is insensitive to the locking of actin in a monomeric conformation. Taken together, these results lead us to favour the idea that dystrophin could share properties in common with filamin in its binding of actin.

Inhibition of actin-dystrophin interaction by inositide phosphate.

Dystrophin, the protein absent from Duchenne dystrophy, is a member of the alpha-actinin protein family and located in the membrane cytoskeleton. It bridges a transmembrane glycoprotein complex with actin filaments. This work investigates the binding of dystrophin issued from Torpedo marmorata electric organ with actin in the presence of the phosphoinositide PIP2 that regulates alpha-actinin and filamin binding with actin. The interaction was inhibited (80%) by PIP2 and reached its minimum above 20 microM PIP2, but the effect was abolished when PIP2 was previously cleaved by phospholipase C. Using antibodies directed against the 27 kDa actin binding domain of alpha-actinin, a reliable carrier for actin binding sites ABS-1, ABS-2 and ABS-3 also involved in dystrophin and filamin, it was shown that PIP2 affects the ABS-3 environment.

Testosterone-induced masculinization of the rat levator ani muscle during puberty.

Previous study of the development of the levator ani muscle (LA) revealed that the sex difference in muscle fiber number is under the control of testosterone during the perinatal period. In this study, the development of the LA muscle was examined in both sexes to test the hypothesis that testosterone action determines a further sex difference at the onset of puberty. This period is of key importance because plasma testosterone concentration rises sharply between Postnatal Days 40 and 60 in the male, while in the female testosterone level stays very low. In the male, a transient increase in the satellite cell number occurs between Days 42 and 47, followed by a persistent myonuclei increase. Hence, when the pubertal process has been completed, the myonuclei number is increased by about 50%. Moreover, sexual dimorphism related to the muscle fiber width becomes more marked: before puberty (Day 30), the mean cross-sectional area of muscle fibers is 2-fold higher in males than in females, while between Days 30 and 78, a further hypertrophy is observed which leads to a mean cross-sectional area about 10-fold higher in the male. In the female, during the same period, there is neither satellite cell increase nor myonuclei increase and the fiber cross-sectional area remains constant. Treatment with testosterone before the onset of puberty induces a marked but transient satellite cell increase not only in male but also in female LA muscle as early as 3 days after the time of injection. This cell proliferation is followed by a subsequent increase in the myonuclei number. Results indicate that (1) the levator ani muscle in the male exhibits high sensitivity to testosterone during the pubertal process; during this period, sexual dimorphism related to fiber width and myonuclei number is emphasized; (2) the myonuclei increase is subsequent to the testosterone-induced satellite cell proliferation; and (3) the female LA muscle presents the same sensitivity to testosterone as the male. Hence, the female muscle does not acquire specific male characteristics, owing to the very low concentration of circulating androgens.

Characterization of the actin binding site on smooth muscle filamin.

We have isolated an NH2-terminal fragment of filamin (M(r) = 70,000) after digestion with Staphylococus aureus V8 protease. This fragment was shown to interact with filamentous actin in cosedimentation assays. Using cross-reactive anti-peptides antibodies directed against the strongly conserved 27-mer sequence of alpha-actinin, already implicated as an actin binding site (Kuhlman, P. A., Hemmings, L., and Critchley, D. R. (1992) FEBS Lett. 304, 201-206), we obtained evidence suggesting that the homologous sequence of filamin (121-147 sequence) is the major element in the interaction with actin. In particular, we used enzyme-linked immunosorbent assay experiments, in conjunction with a synthetic peptide approach, and found that the hydrophobic part of the 27-mer peptide (141-147 sequence) is largely involved in actin binding. Thus, the filamin sequence 121-147 (or the alpha-actinin sequence 108-134) and the actin counterpart composed of residues 112-125 and 360-372 (we have already implicated) could constitute the main interface between actin and these cytoskeletal proteins. However, the divergent behavior of filamin and alpha-actinin toward conformational changes of actin argues in favor of distinctive interfaces. Finally, the ionic strength dependence of the filamin-actin interaction, in contrast to that with alpha-actinin, strongly suggests that, besides hydrophobic interactions conferred by the 27-mer sequence, more hydrophilic region(s) of filamin participate(s) in the binding.

Further characterization of the alpha-actinin-actin interface and comparison with filamin-binding sites on actin.

The interaction between alpha-actinin and actin was further characterized using natural and synthetic peptides of actin together with anti-actin antibodies of known specificity. We demonstrated that two alpha-actinin binding sequences on actin are located within residues 112-125 and 360-372. Each peptide was shown to directly bind alpha-actinin and was able to dissociate the alpha-actinin-actin complex using solid phase binding assays and cosedimentation experiments. Taking into account the three-dimensional structure of actin (Kabsch, W., Mannherz, H. G., Suck, D., Pai, E. F., and Holmes, K. C. (1990) Nature 347, 37-44), we postulate that these two segments, proximal in the actin structure, are part of the same site. In addition, we compared these two segments with those recently found for filamin (Méjean, C., Lebart, M. C., Boyer, M., Roustan, C., and Benyamin, Y. (1992) Eur. J. Biochem. 209, 555-562), Egan, S., Stewart, M., Stossel, T. P., Kwiatkowski, D. J., and Hartwig, J. H. (1990) J. Cell Biol. 111, 1089-1105), and concluded that the two actin-binding proteins interact with closely spaced or overlapping but not identical sequences of actin subdomain 1.

Localization and identification of actin structures involved in the filamin-actin interaction.

The interface between gizzard filamin and skeletal muscle actin was located on the actin monomer. Conserved sequences 105-120 and 360-372, in the actin subdomain 1 near the myosin binding sites, were involved in this interaction. The corresponding peptides for these sequences were each found to bind filamin and compete in the actin-filamin interaction. When these two peptides were used together in the presence of filamin and filamentous actin, they dissociated sedimentable complexes formed by these two proteins.

Localization of a new alpha-actinin binding site in the COOH-terminal part of actin sequence.

The interaction of filamentous actin with alpha-actinin, an actin cross-linking protein, is well established. On the other hand, monomeric actin-alpha-actinin interaction has been a subject of controversy. In this report, we have characterized the interaction of monomeric actin, coated on plastic plates under conditions of non-polymerization, with alpha-actinin in presence of magnesium. Using specific polyclonal anti-actin antibodies, with the whole molecule or purified peptides, we have localized two sites of interaction on action molecule: one near Thr-103 and a new one in the twenty last amino acids.