Dominique Mornet

Molecular movements promoted by metal nucleotides in the heavy-chain regions of myosin heads from skeletal muscle.

Molecular movements generated in the heavy-chain regions (27-50-20(X 10(3)) Mr) of myosin S1 on interaction with nucleotides ATP, AMPPNP, ADP and PPi were investigated by limited proteolysis of several enzyme-metal nucleotide complexes in the absence and presence of reversibly bound and crosslinked F-actin. The rate and extent of the nucleotide-promoted conversion of the NH2-terminal 27 X 10(3) Mr and 50 X 10(3) Mr segments into products of 22 X 10(3) Mr and 45 X 10(3) Mr, respectively, were estimated to determine the amplitude of the molecular movements. The 22 X 10(3) Mr peptide was identified by amino acid sequence studies as being derived from cleavage of the peptide bond between Arg and Ile (at position 23 to 24). The 45 X 10(3) Mr peptide, previously shown to represent the NH2-terminal part of the 50 X 10(3) Mr region, would be connected to the adjacent C-terminal 20 X 10(3) Mr region by a pre-existing loop segment of about 5 X 10(3) Mr; the proteolytic sensitivity of the latter region is increased particularly by nucleotide binding. The tryptic reaction proved to be a sensitive indicator of the conformational state of the liganded heavy chain as the rate of peptide bond cleavage in the two regions is dependent on the nature of the bound ligand; it decreases in the order: ATP greater than AMPPNP greater than ADP greater than PPi. It depends also on the nature of the metal present, Mg2+ and Ca2+ being much more effective than K+. Binding of F-actin to the S1-MgAMPPNP complex affords significant protection against breakdown of 27 X 10(3) Mr and 50 X 10(3) Mr peptides, but with concomitant hydrolysis of the 50 X 10(3) Mr-20 X 10(3) Mr junction. Additionally, interaction of MgATP with HMM modulates the tryptic fission of the S1-S2 region. The overall data provide a molecular support for the two-state model of the myosin head and emphasize the involvement of the 50 X 10(3) Mr unit in the mechanism of coupling between the actin and nucleotide binding sites.

Dystrophin and utrophin complexed with different associated proteins in cardiac Purkinje fibres

Abnormal dystrophin expression is directly responsible for Duchenne and Becker muscular dystrophies. In skeletal muscle, dystrophin provides a link between the actin network and the extracellular matrix via the dystrophin-associated protein complex. In mature skeletal muscle, utrophin is a dystrophin-related protein localized mainly at the neuromuscular junction, with the same properties as dystrophin in terms of linking the protein complex. Utrophin could potentially overcome the absence of dystrophin in dystrophic skeletal muscles. In cardiac muscle, dystrophin and utrophin were both found to be present with a distinct subcellular distribution in Purkinje fibres, i.e. utrophin was limited to the cytoplasm, while dystrophin was located in the cytoplasmic membrane.In this study, we used this particular characteristic of cardiac Purkinje fibres and demonstrated that associated proteins of dystrophin and utrophin are different in this structure. We conclude, contrary to skeletal muscle, dystrophin-associated proteins do not form a complex in Purkinje fibres. In addition, we have indirect evidence of the presence of two different 400u2009kDa dystrophins in Purkinje fibres.

Dystrophin Dp71 in PC12 cell adhesion

Previously, we reported that PC12 cells with decreased Dp71 expression (antisense-Dp71 cells) display deficient nerve-growth-factor-induced neurite outgrowth. In this study, we show that disturbed neurite outgrowth of antisense-Dp71 cells is accompanied by decreased adhesion activity on laminin, collagen and fibronectin. In wild-type cells, the immunostaining of Dp71 and &bgr;1-integrin overlaps in the basal area contacting the substrate, but staining of both proteins decrease in the antisense-Dp71 cells. Morphology of antisense-Dp71 cells at the electron microscopic level is characterized by the lack of filopodia, cellular projections involved in adhesion. Our findings suggest that Dp71 is required for the efficient PC12 cell attachment to &bgr;1-integrin-dependent substrata and that decreased adhesion activity of the antisense-Dp71 cells could determine their deficiency to extend neurites.

α7B Integrin changes in mdx mouse muscles after l-arginine administration

Muscle fibers attach to laminin in the basal lamina using two mechanisms, i.e., dystrophin with its associated proteins and α7β1 integrin. In humans, gene‐mutation defects in one member of these complexes result in muscular dystrophies. This study revealed changes after l‐arginine treatment of utrophin‐associated proteins and the α7B integrin subunit in mdx mouse, a dystrophin‐deficient animal model. In the two studied muscles (cardiac muscle and diaphragm), the α7B integrin subunit was increased in 5‐week‐old treated mice. Interestingly, the diaphragm histopathological appearance was significantly improved by l‐arginine administration. These results highlight a possible way to compensate for dystrophin deficiency via α7β1 integrin.

Dystrophin Dp71 is critical for stability of the DAPs in the nucleus of PC12 cells.

We have adopted the PC12 cell line as in vitro cell model for studying Dp71 function in neuronal cells. These cells express a cytoplasmic (Dp71f) and a nuclear (Dp71d) isoform of Dp71 as well as various dystrophin-associated proteins (DAPs). In this study, we revealed by confocal microscopy analysis and Western blotting evaluation of cell fractions the presence of different DAPs (β-dystroglycan, β-dystrobrevin, ε-sarcoglycan and γ1-syntrophin) in the nucleus of PC12 cells. Furthermore, we established by immunoprecipitation assays that Dp71d and the DAPs form a dystrophin-associated protein complex (DAPC) in the nucleus. Interestingly, depletion of Dp71 by antisense treatment (antisense-Dp71 cells) provoked a drastic reduction of nuclear DAPs, which indicates that Dp71d is critical for DAPs stability within the nucleus. Although Up71, the utrophin gene product homologous to Dp71, exhibited increased expression in the antisense-Dp71 cells, its scarce nuclear levels makes unlikely that could compensate for Dp71 nuclear deficiency.

Interaction of the heavy chain of gizzard myosin heads with skeletal F-actin

To probe the molecular properties of the actin recognition site on the smooth muscle myosin heavy chain, the rigor complexes between skeletal F-actin and chicken gizzard myosin subfragments 1 (S1) were investigated by limited proteolysis and by chemical cross-linking with 1-ethyl-3-[3-(dimethyl-amino)propyl]carbodiimide. Earlier, these approaches were used to analyze the actin site on the skeletal muscle myosin heads [Mornet, D., Bertrand, R., Pantel, P., Audemard, E., & Kassab, R. (1981) Biochemistry 20, 2110-2120; Labbé, J.P., Mornet, D., Roseau, G., & Kassab, R. (1982) Biochemistry 21, 6897-6902]. In contrast to the case of the skeletal S1, the cleavage with trypsin or papain of the sensitive COOH-terminal 50K-26K junction of the head heavy chain had no effect on the actin-stimulated Mg2+-ATPase activity of the smooth S1. Moreover, actin binding had no significant influence on the proteolysis at this site whereas it abolished the scission of the skeletal S1 heavy chain. The COOH-terminal 26K segment of the smooth papain S1 heavy chain was converted by trypsin into a 25K peptide derivative, but it remained intact in the actin-S1 complex. A single actin monomer was cross-linked with the carbodiimide reagent to the intact 97K heavy chain of the smooth papain S1. Experiments performed on the complexes between F-actin and the fragmented S1 indicated that the site of cross-linking resides within the COOH-terminal 25K fragment of the S1 heavy chain. Thus, for both the striated and smooth muscle myosins, this region appears to be in contact with F-actin.(ABSTRACT TRUNCATED AT 250 WORDS)

Caldesmon structure and function: Sequence analysis of a 35 kilodalton actin- and calmodulin-binding fragment from the C-terminus of the turkey gizzard protein

We have determined the amino acid sequence of a 35 kDa proteolytic fragment (CaD35) derived from the C-terminus of turkey gizzard caldesmon. This 239-residue peptide contains binding sites for actin and calmodulin. Residues 1-96 of CaD35 comprise CaD15, an actin-binding subfragment which we previously showed to resemble the tropomyosin-binding segment of troponin T. The remainder of the CaD35 sequence shows no significant similarity to other proteins. Residues 111-128 may form a basic, amphipathic helix which interacts with calmodulin.

Proximity of alkali light chains to 27K domain of the heavy chain in myosin subfragment 1.

When myosin chymotryptic subfragment-1 was treated with dimethyl-suberimidate or dithiobis (succinimidylpropionate) under nearly physiological ionic conditions, the alkali light chains A1 and A2 were selectively and intramolecularly cross-linked to the 95K heavy chain. Experimental conditions were developed with both reagents for optimal production of A1 and A2-containing dimers. After conversion of reversibly cross-linked S-1 (A1+A2) into (27K-50K-20K)-S-1 derivative by restricted tryptic proteolysis, the light chains were found to be attached to the NH2-terminal 27K segment of the heavy chain.

Structural aspects of actomyosin interaction

Actin binding to myosin-S1 modulates the limited tryptic cleavage of the COOH-terminal region of the 95K heavy chain at the joint connecting the 75K and 20K peptide units; concomitantly actin affords total protection against the resulting loss of acto-S1 Mg2+-ATPase activity. The specificity of the actin effect is illustrated by the fact that it exerts itself not only on free S1 but also on the intact myosin molecule. Mg2+-ATP and Mg2+-ADP impair the protective action of actin to an extent closely related to their respective affinity for the acto-S1 complex. Tryptic fragmentation of S1 heavy chain under highly controlled conditions, using trypsin to S1 weight ratios in the range 1:1000 - 1:1500 led us to establish that peptide bond cleavage at the 75K-20K junction is a sequential process giving rise first to a 22K peptide intermediate which is subsequently converted to the stable 20K fragment. Most importantly, it is also demonstrated that the loss of S1 activation by actin is not due to the initial scission of the 75K-22K linkage but is intimately associated with the breakdown of the 22K precursor into its 20K moiety. Three trypsin-modified S1 derivatives, the heavy chain of which is a complex of two or three fragments, were purified. A detailed analysis of the C-termini of these fragments, as compared to the C-terminal structure of the intact heavy chain, indicated that the 20K fragment is formed mainly through the degradation of a NH2-terminal 2K segment in the 22K precursor and that this proteolytic event is the only one accounting for the acto-S1 ATPase loss. Cross-linking experiments exploiting the reaction of a carbodiimide reagent with rigor complexes containing either fluorescent actin or fluorescent fragmented S1 revealed unequivocally the attachment of the actin monomer to recognition sites on the 20K and 50K units of S1 heavy chain. Specific interactions between the C-terminal 20K domain and light chain LC2 are proposed as being part of the molecular mechanism of the myosin-linked regulation of actomyosin interaction.

The effect of respiratory muscle training with CO2 breathing on cellular adaptation of mdx mouse diaphragm.

The aim of our study was to investigate the cellular mechanisms induced by hypercapnic stimulation of ventilation, during 6 weeks/30 min per day, in 10 mdx and 8 C57BL10 mice (10+/-0.2 months old). Ten mdx and eight C57BL10 mice served as control group. This respiratory training increases in vitro maximal tetanic tension of the diaphragm only in mdx mice. Western blot analysis of diaphragm showed: (1) an over-expression of alpha-dystrobrevin in mdx and C57BL10 training group compared to control group (8100+/-710 versus 6100+/-520 and 2800+/-400 versus 2200+/-250 arbitrary units); (2) a decrease in utrophin expression only in mdx training group compared to control group (2100+/-320 versus 3100+/-125 arbitrary units). Daily respiratory muscle training in mdx mice, induces a beneficial effect on diaphragm strength, with an over-expression of alpha-dystrobrevin. Further studies are needed to determine if, in absence of dystrophin, the over-expression of alpha-dystrobrevin could be interpreted as a possible pathway to improve function of dystrophic muscle.