Large-scale mRNA analysis of female skeletal muscles during 60 days of bed rest with and without exercise or dietary protein supplementation as countermeasures.

Microgravity has a dramatic impact on human physiology, illustrated in particular, with skeletal muscle impairment. A thorough understanding of the mechanisms leading to loss of muscle mass and structural disorders is necessary for defining efficient clinical and spaceflight countermeasures. We investigated the effects of long-term bed rest on the transcriptome of soleus (SOL) and vastus lateralis (VL) muscles in healthy women (BRC group, n = 8), and the potential beneficial impact of protein supplementation (BRN group, n = 8) and of a combined resistance and aerobic training (BRE group, n = 8). Gene expression profiles were obtained using a customized microarray containing 6,681 muscles-relevant genes. A two-class statistical analysis was applied on 2,103 genes with consolidated expression in BRC, BRN, and BRE groups. We identified 472 and 207 mRNAs whose expression was modified in SOL and VL from BRC group, respectively. Further clustering analysis, identifying relevant biological mechanisms and pathways, reported five main subclusters. Three are composed of upregulated mRNAs involved mainly in nucleic acid and protein metabolism, and two made up of downregulated transcripts encoding components involved in energy metabolism. Exercise countermeasure demonstrated drastic compensatory effects, decreasing the number of differentially expressed mRNAs by 89 and 96% in SOL and VL, respectively. In contrast, nutrition countermeasure had moderate effects and decreased the number of differentially-expressed transcripts by 40 and 25% in SOL and VL. Together, these data present a systematic, global and comprehensive view of the adaptive response of female muscle to long-term atrophy.

Direct visualization of the dystrophin network on skeletal muscle fiber membrane.

Dystrophin, the protein product of the Duchenne muscular dystrophy (DMD) gene locus, is expressed on the muscle fiber surface. One key to further understanding of the cellular function of dystrophin would be extended knowledge about its subcellular organization. We have shown that dystrophin molecules are not uniformly distributed over the humen, rat, and mouse skeletal muscle fiber surface using three independent methods. Incubation of single-teased muscle fibers with antibodies to dystrophin revealed a network of denser transversal rings (costameres) and finer longitudinal interconnections. Double staining of longitudinal semithin cryosections for dystrophin and alpha-actinin showed spatial juxtaposition of the costameres to the Z bands. Where peripheral myonuclei precluded direct contact of dystrophin to the Z bands the organization of dystrophin was altered into lacunae harboring the myonucleus. These lacunae were surrounded by a dystrophin ring and covered by a more uniform dystrophin veil. Mechanical skinning of single-teased fibers revealed tighter mechanical connection of dystrophin to the plasma membrane than to the underlying internal domain of the muscle fiber. The entire dystrophin network remained preserved in its structure on isolated muscle sarcolemma and identical in appearance to the pattern observed on teased fibers. Therefore, connection of defined areas of plasma membrane or its constituents such as ion channels to single sarcomeres might be a potential function exerted by dystrophin alone or in conjunction with other submembrane cytoskeletal proteins.

Visualization of cardiac ventricular myosin heavy chain homodimers and heterodimers by monoclonal antibody epitope mapping.

Two mAbs, one specific for cardiac alpha-myosin heavy chains (MHC) and the other specific for cardiac beta-MHC, were used to investigate the heavy-chain dimeric organization of rat cardiac ventricular myosin. Epitopes of the two mAbs were mapped on the myosin molecule by electron microscopy of rotary shadowed mAb-myosin complexes. mAbs were clearly identifiable by the different locations of their binding sites on the myosin rod. Thus, myosin molecules could be directly discriminated according to their alpha-or beta-MHC content. alpha alpha-MHC and beta beta-MHC homodimers were visualized in complexes consisting of two molecules of the same mAb bound to one myosin molecule. By simultaneously using the alpha-MHC-specific mAb and the beta-MHC-specific mAb, alpha beta-MHC heterodimers were visualized in complexes formed by one molecule of each of the two mAbs bound to one myosin molecule. Proportions of alpha alpha-and beta beta-MHC homodimers and alpha beta-MHC heterodimers were estimated from quantifications of mAb-myosin complexes and compared with the proportions given by electrophoreses under nondenaturing conditions. This visualization of cardiac myosin molecules clearly demonstrates the arrangement of alpha- and beta-MHC in alpha alpha-MHC homodimers, beta beta-MHC homodimers, and alpha beta-MHC heterodimers, as initially proposed by Hoh, J. F. Y., G. P. S. Yeoh, M. A. W. Thomas, and L. Higginbottom (1979).

Cardiac beta myosin heavy chain diversity in normal and chronically hypertensive baboons.

We have identified two distinct beta-myosin heavy chains (MHCs) present in baboon myocardium by electrophoresis in gradient pore gels and by Western blots with anti-MHC MAb. The two beta-MHCs have molecular masses of 210 and 200 kD and share several antigenic determinants including an epitope recognized by a beta-MHC-specific MAb. A fivefold increase in the level of the 200-kD beta-MHC was observed in the hypertrophied left ventricles of baboons with chronic (5.3 +/- 0.7 yr) renal hypertension. A 60% increase (P less than 0.01) in BP and a 100% increase (P less than 0.001) in left ventricular mass to body weight ratio occurred in hypertensive baboons compared with normotensive animals. The Ca2+-activated myosin ATPase activity in hypertrophied left ventricles was decreased by 35% (P less than 0.05) compared with controls. Normal levels of the 200-kD MHC were detected in the right ventricles and intraventricular septa of the hypertensive animals. These data suggest that cardiac MHCs of primates may exist in alternative molecular forms that are indistinguishable by nondenaturing gel electrophoresis and that increased concentration of a second beta-MHC is associated with ventricular hypertrophy (r = 0.55). The functional significance and mechanisms that control the concentration of beta-MHC subspecies remain to be determined.

The separation of the myosin light chains on agarose beads.

The myosin light chains from rabbit skeletal muscle and bovine and human hearts are separated according to their molecular weights by filtration on agarose beads. The purity of the isolated components and the yield of such columns are compared to the results obtained by other techniques of separation.

Human cardiac myosin ATPase and light subunits. A comparative study.

Myosin was extracted from normal human hearts (autopsy material) and compared to that of pig heart and rabbit white skeletal muscle. Myosin light subunits were isolated by a preparative urea gel electrophoresis. These subunits were shown by urea and sodium dodecylsulfate gel electrophoresis to be only slightly affected by the time lapse between death and the beginning of myosin extraction. This was also true for myosin ATPases. The Ca-2+-activated ATPases of pig and human heart myosins have the same apparent Km and V, whereas white skeletal muscle myosin ATPase has the same Km with a higher V. Human myosin light subunits, when compared to those of pig heart possess: (i) different molecular weights: 27 999 and 18 000 datlons for pig heart, and 25 000 and 19 000 daltons for human heart. (ii) for both the light chains, different ultraviolet spectra and a higher helical content for the subunit molecular weight 25 000. (iii) a different composition for several amino acids (Tyr, Pro, Lys). A third light subunit (molecular weight 15 000) was occasionally seen in human as well as pig heart myosin. It concentration varied inversely with that of the subunit molecular weight 27 000-25 000, and so was probably a degradation product of the heaviest subunit.

Large-scale analysis of differential gene expression in the hindlimb muscles and diaphragm of mdx mouse.

The mdx mouse is an animal model for Duchenne muscular dystrophy (DMD), which is caused by the absence of dystrophin. Mdx limb muscles substantially compensate for the lack of dystrophin while the diaphragm is affected like DMD skeletal muscles. To understand better the complex cascade of molecular events leading to muscle degeneration and compensatory processes in mdx muscles, we analyzed alterations of gene expression in mdx hindlimb and diaphragm muscles as compared to their normal counterparts. The strategy was based on suppression subtractive hybridization followed by reverse Northern quantitative hybridization. Four subtracted/normalized libraries, containing cDNA clones up- or downregulated in mdx hindlimb muscles or diaphragm, were constructed and a total of 1536 cDNA clones were analyzed. Ninety-three cDNAs were found to be differentially expressed in mdx hindlimb muscles and/or diaphragm. They corresponded to 54 known genes and 39 novel cDNAs. The potential role of the known genes is discussed in the context of the mdx phenotype.

Proteolytic susceptibility of the central domain in chicken gizzard and skeletal muscle dystrophins.

We investigated proteolytic susceptibility of the central domain in dystrophin molecules from chicken smooth and skeletal muscles. Dystrophin-enriched preparations from both muscles were made as described in Pons et al. (Proc. Natl. Acad. Sci. USA (1990) 87, 7851-7855). These preparations contained other protein components in addition to dystrophin. Three enzymes (Staphylococcus aureus proteinase, chymotrypsin and trypsin) having different proteolytic specificities were used. Time-courses of proteinase degradation were examined by the Western immunoblot technique using a specific polyclonal serum directed against a fragment (residues 1173-1728) of the dystrophin central domain. We observed accumulation of some major proteinase-resistant fragments, in the 110-160 kDa range originating from that central region of the molecule. Cleavage patterns of the smooth and skeletal muscle preparations were quite similar, but molecular weights of the breakdown products differed slightly. Interpretation of the results was based on two predictive structural models of the dystrophin central domain (Koenig and Kunkel (1990) J. Biol. Chem. 265, 4560-4566 and Cross et al. (1990) FEBS Lett. 262, 87-90). Skip residues at the end of repeat 13 (around the 1740th residue of the dystrophin amino acid sequence), as hypothesized in the Cross model, constitute probably the most sensitive site within the dystrophin central domain for any exogenous (or even endogenous) proteinase. Variations observed between dystrophins from skeletal and smooth muscles also suggest that the structures of both dystrophins differ slightly even within the dystrophin central domain. This precise identification of proteinase-resistant dystrophin fragments of variable lengths is a first step towards further physicochemical studies on the very large and rare dystrophin molecule.

Mdx transgenic mouse: restoration of recombinant dystrophin to the dystrophic muscle.

We report the restoration of the 430-kD dystrophin in mdx, the mouse model of Duchenne muscular dystrophy, by expression of a single-copy recombinant dystrophin transgene. Muscle-specific expression was achieved using a creatine kinase promoter influenced by two enhancers. Immunostaining with anti-Xp21-coded dystrophin monoclonal antibodies showed that the recombinant dystrophin was localized to the muscle fiber membrane. However, there was variability in the level of dystrophin expression in various animals with aging, between fast and slow muscles, and within different regions of the same muscle. Curiously, recombinant dystrophin was relatively absent in the diaphragm muscle of these mdx transgenic animals. Our studies indicate that there is a direct correlation between the level of muscle fibers expressing recombinant dystrophin and the level of muscle fibers with peripheral nuclei, indicating an improvement in muscle pathology. These studies indicate that the regional expression of recombinant dystrophin in dystrophic muscle leads to regional restoration of normal muscle morphology.

Transcriptomal analysis of failing and nonfailing human hearts.

Heart failure is a multifactorial disease that may result from different initiating events. To contribute to an improved comprehension of normal cardiac function and the molecular events leading to heart failure, we performed large-scale gene expression analysis of failing and nonfailing human ventricle. Our aim was to define and compare expression profiles of 4 specific pathophysiological cardiac situations: 1) left ventricle (LV) from nonfailing heart; 2) LV from failing hearts affected by dilated cardiomyopathy (DCM); 3) LV from failing hearts affected by ischemic CM (ICM); 4) right ventricle (RV) from failing hearts affected by DCM or ICM. We used oligonucleotide arrays representing approximately 12,000 human genes. After stringent numerical analyses using several statistical tests, we identified 1,306 genes with a similar expression profile in all 4 cardiac situations, therefore representative of part of the human cardiac expression profile. A total of 95 genes displayed differential expression between failing and nonfailing heart samples, reflecting a reversal to developmental gene expression, dedifferentiation of failing cardiomyocytes, and involvement of apoptosis. Twenty genes were differentially expressed between failing LV and failing RV, identifying possible candidates for different functioning of both ventricles. Finally, no genes were found to be significantly differentially expressed between failing DCM and failing ICM LV, emphasizing that transcriptomal analysis of explanted hearts results mainly in identification of expression profiles of end-stage heart failure and less in determination of expression profiles of the underlying etiology. Taken together, our data resulted in identification of putative transcriptomal landmarks for normal and disturbed cardiac function.

Expression of various NCAM isoforms in human embryonic muscles: correlation with myosin heavy chain phenotypes.

Neural cell adhesion molecules (NCAM) are known to play a pivotal role in regulating cell-cell interactions in various tissues. The diversity of NCAM is made by alternative splicing of a single gene and by post-translational modifications. The spatio-temporal expression of the various isoforms is developmentally regulated and may modulate cell interactions. We investigated the expression of NCAM isoforms, in particular polysialylated and phosphatidylinositol-anchored isoforms, in developing psoas and quadriceps human muscle from 15 weeks of gestation to term. In parallel, we examined the expression of the myosin heavy chain phenotype (another developmentally regulated system) to determine whether polysialylated-NCAM molecules (the so-called embryonic NCAM) and developmental myosin heavy chains are coexpressed. Our results showed an expression of polysialylated-NCAM and phosphatidylinositol-anchored isoforms during the early stages of myotube maturation. The expression of polysialylated-NCAM on developing myotube was always associated with the expression of developmental myosin heavy chains. However, the loss of polysialylated-NCAM from maturing myotubes was not correlated with the disappearance of the developmental myosin heavy chains, but rather with the appearance of an adult myosin heavy chain phenotype. The relationship between polysialylated-NCAM and myosin heavy chain phenotype was similar in psoas and in quadriceps muscles. We observed that maturation of quadriceps muscle takes place earlier than psoas. Biochemical analysis showed that phosphatidylinositol-anchored molecules were never polysialylated; this indicates different roles of these isoforms in muscle development.

Human mineralocorticoid receptor interacts with actin under mineralocorticoid ligand modulation.

The human mineralocorticoid receptor of the steroid receptor family contains a modular structure with domain E which is considered to be a hormone binding domain. Recombinant protein approaches enabled us to clearly determine that this domain is also able to interact with F-actin (Kd about 2 microM) and G-actin. Moreover, it was revealed that this mineralocorticoid receptor domain/actin interaction was modulated by specific mineralocorticoid ligands. Agonist (aldosterone) steroid binding almost totally (91%) abolished the interaction with F-actin, while antagonist (progesterone) binding allowed more than 30% of this binding. Steroid modulation of the interaction between domain E and actin indicated that this actin binding is specific and could be essential for cellular mineralocorticoid receptor activity.

Monoclonal antibodies targeted against the C-terminal domain of dystrophin or utrophin.

The structure-function relationships of dystrophin, a protein which is absent or defective in patients with Duchenne or Becker muscular dystrophies, and utrophin can only be compared if specific antibodies are produced. We expressed C-terminal parts of dystrophin and utrophin in expression vectors. Mice were immunized with recombinant proteins and 26 monoclonal antibodies were produced and analyzed. Their respective epitopes were determined using other overlapping recombinant products. We observed antibody specificity towards 400 kDa dystrophin and/or utrophin protein bands, either by Western blot analysis or immunodetection in human skeletal (quadriceps) and smooth (uterus) muscles. These antibodies have been used to compare the relative abundance of both dystrophin and utrophin relative to the structures analyzed.

Down-regulation of mitochondrial mRNAs in the mdx mouse model for Duchenne muscular dystrophy.

In our search for genes up- or down-regulated genes in the mdx mouse model for Duchenne muscular dystrophy, we isolated a down-regulated mitochondrial DNA clone. In addition to this clone, all protein-coding mitochondrial genes tested had tissue-specific and age independent down-regulated expression. This implied mechanisms at the RNA level since no change in the mitochondrial DNA contents were detected. Cytochrome c oxidase activity showed the same range of down-regulated expression. These data provide a molecular basis for energetic metabolism modifications in mdx mice.

A homologue of dystrophin is expressed at the neuromuscular junctions of normal individuals and DMD patients, and of normal and mdx mice. Immunological evidence.

Polyclonal and monoclonal antibodies, which recognize different regions and epitopes of the dystrophin molecule, bind to a protein of Mr 400,000 which is present in extracts of mdx muscle from regions which contain neuromuscular junctions (NMJ) and is absent from those which do not. This NMJ-associated homologue of dystrophin has at least 2 epitopes which are different to usual Xp21 form of dystrophin expressed along the sarcolemma of muscle fibres in normal muscles. This protein is also expressed at the NMJ of a DMD patient who lacks the first 52 exons of the Xp21 dystrophin gene and it must therefore be translated from a different gene transcript.

Absence of phosphates from the myosin heavy chains of striated muscles.

This work aimed to determine whether the heavy chains of myosin from different striated muscle were phosphorylated. Myosin and its heavy chains were prepared from cardiac and skeletal muscles of rats injected in vivo with radioactive phosphates. The results for radioactive phosphate localization indicate the absence of phosphate from pure heavy chains and from any of their purified fragments, whatever the striated muscle used. In addition, phosphates are present in the myosin phosphorylated light chain and in a contaminating protein closely associated to the myosin heavy chain.

Structural differences between atrial and ventricular myosins from normal human hearts.

Comparisons were made between myosins isolated from the right and left ventricles and the atria of normal human hearts. Parameters examined included electrophoretic mobilities of native molecules, K+ and Ca2+ dependent enzymatic activities, light chain composition, peptide patterns from partial proteolytic digests of entire heavy chains or rods, and maps of complete digests of specific 21 and 25 kilodalton heavy chain fragments. Human ventricular and atrial myosins differ in all parameters except in the charge of molecules. Structural differences between cardiac myosins derived from the two sources were apparent in both the head and tail portions of the heavy chains. With respect to the above parameters no differences were found between myosins from left and right human ventricles.

Heart contractile proteins.

That several proteins of the sarcomere differ from one muscle to the next is well documented, and it is becoming evident that homogeneous muscles, like the heart, are also species specific. 1) Clear-cut evidence is available concerning myosin, and, to date, several types of molecules have been described. a) The myosins of white skeletal, heart, and smooth muscle differ in the activity of their Ca2+ and K+ATPases, as also in the structure of their light subunits. b) The Ca2+ATPases of the various cardiac myosins have been shown to exhibit species differences and correlate with the speed of shortening of the muscle. 2) The structures of tropomyosin, some troponin components, and alpha actinin (but not actin) appear to be unlike in the different types of muscle. 3) These phylogenic modifications may be related to the changes characteristic of the particular muscles under pathological conditions, which are accompanied by substantial increase in protein synthesis.

Dystrophin and dystrophin-related protein (utrophin) distribution in normal and dystrophin-deficient skeletal muscles.

The respective localizations of dystrophin and dystrophin-related protein (DRP or utrophin) along the sarcolemmal membrane and at the neuromuscular junctions (NMJs) in normal and dystrophin-deficient skeletal muscles, were determined using confocal laser microscopy. The analysis was prompted by the recent availability of a new anti-utrophin mAb [Bewick et al. NeuroReport 1992; 3:857-860] and different mAbs that react with dystrphin or both dystrophin and utrophin. In dystrophin-deficient muscles, utrophin was expressed and detectable over large subcellular areas normally occupied by dystrophin along the sarcolemmal membranes and at the NMJs. Utrophin was expressed in a non-uniform, discontinuous way on the sarcolemmal membrane in dystrophin-deficient skeletal muscles, similar to dystrophin in normal muscle fibres. The respective distributions of both related muscle proteins and their positions relative to the alpha-bungarotoxin acetylcholine (ACh) receptor marker were determined. Double-staining experiments and superimposition of the confocal images showed that utrophin was more closely associated with ACh receptors than dystrophin at the NMJs in normal muscles. Utrophin distribution consequently differed from that of dystrophin.

Sarcolemmal expression of dystrophin C-terminus but reduced expression of 6q-dystrophin-related protein in two DMD patients with large deletions of the dystrophin gene.

Partial deletions of the dystrophin gene are the predominant genetic lesions in Duchenne (DMD) and Becker (BMD) muscular dystrophies. According to the reading frame hypothesis [1], any deletion disrupting the translational reading frame of the mRNA cannot result in expression of the dystrophin molecule and should lead to severe phenotypes of DMD. In contrast, deletions which maintain the reading frame across the deleted exons may give rise to truncated, semifunctional proteins and milder courses of the disease (i.e. BMD). Among the notable exceptions of this hypothesis are very large "in-frame" deletions by which functionally indispensable domains of the dystrophin molecule have been removed. Here, we report on two DMD patients with large intragenic in-frame deletions. Grossly truncated, but stable dystrophin molecules with preserved C-terminal domains were detected at the sarcolemma on cryosections in both patients. However, dystrophin organization on single-teased muscle fibers revealed disarrangement of the costameric pattern, if compared to normal skeletal muscle fibers. Compared to dystrophin-deficient DMD muscle, expression of chromosome-6-encoded dystrophin-related protein (DRP) was greatly diminished in skeletal muscle of both patients. We show, that loss of more than 50% of dystrophin seems to be deleterious for the protein's function and therefore, the extent of the deletions may have an impact on construction of dystrophin mini genes. Moreover, these findings shed new light on the functional significance of the C-terminal domain of dystrophin. They also suggest a negative correlation between sarcolemmal expression of the dystrophin C-terminus and DRP expression at the sarcolemma.