IL-1ß- and IL-4-polarized macrophages have opposite effects on adipogenesis of intramuscular fibro-adipogenic progenitors in humans.

Intramuscular fat deposition represents a negative prognostic factor for several myopathies, metabolic diseases and aging. Fibro-adipogenic progenitors (FAPs) are considered as the main source of intramuscular adipocytes, but the mechanisms controlling their adipogenic potential are still not elucidated in humans. The aim of this study was to explore the regulation of human FAP adipogenesis by macrophages. We found that CD140a-expressing FAPs were located close to CD68 positive macrophages in muscles from patients with Duchenne muscular dystrophy (DMD). This strongly suggests a potential interaction between FAPs and macrophages in vivo. Isolated human primary FAPs were then differentiated in the presence of conditioned media obtained from primary blood monocyte-polarized macrophages. Molecules released by IL-1ß-polarized macrophages (M(IL-1ß)) drastically reduced FAP adipogenic potential as assessed by decreased cellular lipid accumulation and reduced gene expression of adipogenic markers. This was associated with an increased gene expression of pro-inflammatory cytokines in FAPs. Conversely, factors secreted by IL-4-polarized macrophages (M(IL-4)) enhanced FAP adipogenesis. Finally, the inhibition of FAP adipocyte differentiation by M(IL-1ß) macrophages requires the stimulation of Smad2 phosphorylation of FAPs. Our findings identify a novel potential crosstalk between FAPs and M(IL-1ß) and M(IL-4) macrophages in the development of adipocyte accumulation in human skeletal muscles.

The primary cilium is necessary for the differentiation and the maintenance of human adipose progenitors into myofibroblasts.

The primary cilium is an organelle, present at the cell surface, with various biological functions. We, and others, have shown that it plays a role in the differentiation of adipose progenitors (APs) into adipocytes. APs can also differentiate into myofibroblasts when treated with TGF-ß1. Several components of the TGF-ß1 pathway are located within the cilium suggesting a function for this organelle in AP myofibrogenesis. We studied differentiation of APs into myofibroblasts in two human models: APs of the adipose tissue (aAPs) and APs resident in the skeletal muscles (mAPs). We showed that, in vivo, myofibroblasts within muscles of patients with Duchenne Muscular Dystrophy were ciliated. In vitro, myofibroblasts derived from APs maintained a functional primary cilium. Using HPI4, a small molecule that inhibits ciliogenesis, and siRNA against Kif-3A, we provide evidence that the primary cilium is necessary both for the differentiation of APs into myofibroblasts and the maintenance of the phenotype. Disruption of the primary cilium inhibited TGF-ß1-signalisation providing a molecular mechanism by which the cilium controls myofibroblast differentiation. These data suggest that myofibroblasts from various origins are controlled differently by their primary cilium.

Characterization of adipocytes derived from fibro/adipogenic progenitors resident in human skeletal muscle.

A population of fibro/adipogenic but non-myogenic progenitors located between skeletal muscle fibers was recently discovered. The aim of this study was to determine the extent to which these progenitors differentiate into fully functional adipocytes. The characterization of muscle progenitor-derived adipocytes is a central issue in understanding muscle homeostasis. They are considered as being the cellular origin of intermuscular adipose tissue that develops in several pathophysiological situations. Here fibro/adipogenic progenitors were isolated from a panel of 15 human muscle biopsies on the basis of the specific cell-surface immunophenotype CD15+/PDGFRα+CD56-. This allowed investigations of their differentiation into adipocytes and the cellular functions of terminally differentiated adipocytes. Adipogenic differentiation was found to be regulated by the same effectors as those regulating differentiation of progenitors derived from white subcutaneous adipose tissue. Similarly, basic adipocyte functions, such as triglyceride synthesis and lipolysis occurred at levels similar to those observed with subcutaneous adipose tissue progenitor-derived adipocytes. However, muscle progenitor-derived adipocytes were found to be insensitive to insulin-induced glucose uptake, in association with the impairment of phosphorylation of key insulin-signaling effectors. Our findings indicate that muscle adipogenic progenitors give rise to bona fide white adipocytes that have the unexpected feature of being insulin-resistant.

Extracellular DNA oxidation stimulates activation of NRF2 and reduces the production of ROS in human mesenchymal stem cells.

INTRODUCTION: Human blood normally contains circulating cell-free DNA (cirDNA). Cell-free DNA (cfDNA) present in cell culture medium is termed extracellular DNA (ecDNA). Its concentration, GC content and oxidation level depend on physiological state of the organism. cirDNA could probably be one of the aggressive factors encountered by therapeutic stem cells. The authors hypothesize that oxidized cirDNA could influence their survival rate. They aimed to uncover the effects of oxidized ecDNAs, including ecDNA of cultivated primary tumor cells and cirDNA from blood plasma of cancer patients on mesenchymal stem cells (MSCs). AREAS COVERED: Increased concentrations of cfDNA stimulate a rapid increase in reactive oxygen species (ROS) synthesis and up-regulate antioxidant response genes (NRF2, KEAP1, SOD1, BRCA1, BCL2) in MSCs. This response is more prominent when cfDNA contains higher proportions of 8-oxo-dG. Within an hour, oxidized DNA induces a decrease in ROS production while NRF2 mRNA levels continue to augment and the NRF2 protein translocates into the nucleus. Additionally, oxidized DNA up-regulates PPRAG2 with no apparent induction of adipogenesis. This kind of response is specific for MSCs. EXPERT OPINION: Oxidized cfDNA up-regulates NRF2 and PPARG2 and reduces ROS production in MSCs. These effects should be taken into account when considering therapeutic applications of stem cells.

The topoisomerase 1-interacting protein BTBD1 is essential for muscle cell differentiation.

DNA topoisomerase I (Topo1) contributes to vital biological functions, but its regulation is not clearly understood. The BTBD1 protein was recently cloned on the basis of its interaction with the core domain of Topo1 and is expressed particularly in skeletal muscle. To determine BTBD1 functions in this tissue, the in vitro model used was the C2C12 mouse muscle cell line, which expresses BTBD1 mainly after myotube differentiation. We studied the effects of a stably overexpressed BTBD1 protein truncated of the 108 N-terminal amino-acid residues and harbouring a C-terminal FLAG tag (Delta-BTBD1). The proliferation speed of Delta-BTBD1 C2C12 cells was significantly decreased and no myogenic differentiation was observed, although these cells maintained their capacity to enter adipocyte differentiation. These alterations could be related to Topo1 deregulation. This hypothesis is further supported by the decrease in nuclear Topo1 content in Delta-BTBTD1 proliferative C2C12 cells and the switch from the main peripheral nuclear localization of Topo1 to a mainly nuclear diffuse localization in Delta-BTBTD1 C2C12 cells. Finally, this study demonstrated that BTBD1 is essential for myogenic differentiation.

Analysis of altered gene expression in rat soleus muscle atrophied by disuse.

The present study involved a global analysis of genes whose expression was modified in rat soleus muscle atrophied after hindlimb suspension (HS). HS muscle unloading is a common model for muscle disuse that especially affects antigravity slow-twitch muscles such as the soleus muscle. A cDNA cloning strategy, based on suppression subtractive hybridization technology, led to the construction of two normalized soleus muscle cDNA libraries that were subtracted in opposite directions, i.e., atrophied soleus muscle cDNAs subtracted by control cDNAs and vice versa. Differential screening of the two libraries revealed 34 genes with altered expression in HS soleus muscle, including 11 novel cDNAs, in addition to the 2X and 2B myosin heavy chain genes expressed only in soleus muscles after HS. Gene up- and down-regulations were quantified by reverse Northern blot and classical Northern blot analysis. The 25 genes with known functions fell into seven important functional categories. The homogeneity of gene alterations within each category gave several clues for unraveling the interplay of cellular events implied in the muscle atrophy phenotype. In particular, our results indicate that modulations in slow- and fast-twitch-muscle component balance, the protein synthesis/secretion pathway, and the extracellular matrix/cytoskeleton axis are likely to be key molecular mechanisms of muscle atrophy. In addition, the cloning of novel cDNAs underlined the efficiency of the chosen technical approach and gave novel possibilities to further decipher the molecular mechanisms of muscle atrophy.

Identification of altered gene expression in skeletal muscles from Duchenne muscular dystrophy patients.

Mutations in the dystrophin gene lead to dystrophin deficiency, which is the cause of Duchenne muscular dystrophy (DMD). This important discovery more than 10 years ago opened a new field for very productive investigations. However, the exact functions of dystrophin are still not fully understood and the complex process leading to subsequent muscle fiber necrosis has not been clearly described; hence there has not yet been any marked improvement in patient treatment. To decipher the molecular mechanisms induced by a lack of dystrophin, we started identifying genes whose expression is altered in DMD skeletal muscles. The approach was based on differential screening of a human muscle cDNA array. Nine genes were found to be up- or downregulated. Our results indicate expression alterations in mitochondrial genes, titin, a muscle transcription factor and three novel genes. First characterizations of these novel genes indicated that two of them have striated muscle tissue specificity.

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.

Exclusion of muscle specific actinin-associated LIM protein (ALP) gene from 4q35 facioscapulohumeral muscular dystrophy (FSHD) candidate genes.

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominant disorder for which no candidate gene has yet been identified. The gene corresponding to one of the novel human cDNAs that we cloned on the basis of a muscle restricted expression pattern [Piétu G, Alibert O, Guichard B, et al. Genome Res 1996;6:492-503] was mapped in the region of the FSHD1A genetic locus, i.e. one of the loci involved in this muscular dystrophy. The corresponding encoded protein contains a PDZ and a LIM domain, two protein-protein interaction domains, and was very recently shown to bind alpha-actinin-2 and was named ALP (actinin-associated LIM protein) [Xia H, Winokur S, Kuo W, Altherr M, Bredt D. J Cell Biol 1997;139:507-515]. We raised a specific polyclonal anti-ALP serum against an ALP recombinant polypeptide to evaluate the size, level of expression and subcellular localization of ALP in three patients, clearly diagnosed with FSHD disease. Quantitative or qualitative alterations of ALP expression have not been detected in any of them, thus prompting us to exclude ALP as a FSHD gene candidate.

Upregulation of M-creatine kinase and glyceraldehyde3-phosphate dehydrogenase: two markers of muscle disuse.

Muscle disuse induces substantial alterations in the highly plastic skeletal muscle tissues, which occur especially in antigravity slow muscles. We differentially screened a muscle cDNA array to identify modifications in gene profile expression induced in slow rat soleus muscle mechanically unloaded by hindlimb suspension as a model for muscle disuse. This study focused on muscle creatine kinase mRNA and protein and glyceraldehyde-3-phosphate dehydrogenase mRNA, which were found to be upregulated in unweighted muscles. These upregulations were analyzed over a 4-wk time course of hindlimb suspension and compared with variations in myosin heavy chain (MHC) isoforms while specifically focusing on type IIx MHC mRNA and protein. The two metabolic marker upregulations clearly preceded IIx MHC contractile protein upregulation. Muscle creatine kinase upregulation was shown to be an excellent, and the earliest, marker of muscle disuse at mRNA and protein levels.

Molecular cloning and functional expression of a novel human gene encoding two 41-43 kDa skeletal muscle internal membrane proteins.

Systematic analysis of gene transcript repertoires prepared from libraries made with various specific human tissues permitted isolation of many partially sequenced cDNA clones. A few of these represented novel genes with limited or no similarity to known genes from humans or other species. The present study set out to isolate and sequence the full-length cDNA corresponding to one of these novel human transcripts, and identify the corresponding protein product at the subcellular level. Current sequence analyses have revealed that the protein contains a hydrophobic N-terminal segment and an internal leucine-zipper motif. Numerous sites of putative post-translational modifications, such as N-linked glycosylation, myristoylation and phosphorylation sites, were also identified. Using one monoclonal antibody raised against a recombinant fragment, two different 41-43 kDa proteins were detected in human skeletal muscle, heart and placenta homogenates at various ratios. Both immunodetected protein products of the novel human gene were distributed in the transverse tubules and/or near the junctional sarcoplasmic reticulum within skeletal muscle cells. Both proteins had physical properties believed to be attributable to integral membrane components. Finally, the GENX-3414 gene was chromosomally localized at position 4q24-q25.

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.

E-box- and MEF-2-independent muscle-specific expression, positive autoregulation, and cross-activation of the chicken MyoD (CMD1) promoter reveal an indirect regulatory pathway.

Members of the MyoD family of gene-regulatory proteins (MyoD, myogenin, myf5, and MRF4) have all been shown not only to regulate the transcription of numerous muscle-specific genes but also to positively autoregulate and cross activate each other's transcription. In the case of muscle-specific genes, this transcriptional regulation can often be correlated with the presence of a DNA consensus in the regulatory region CANNTG, known as an E box. Little is known about the regulatory interactions of the myogenic factors themselves; however, these interactions are thought to be important for the activation and maintenance of the muscle phenotype. We have identified the minimal region in the chicken MyoD (CMD1) promoter necessary for muscle-specific transcription in primary cultures of embryonic chicken skeletal muscle. The CMD1 promoter is silent in primary chick fibroblast cultures and in muscle cell cultures treated with the thymidine analog bromodeoxyuridine. However, CMD1 and chicken myogenin, as well as, to a lesser degree, chicken Myf5 and MRF4, expressed in trans can activate transcription from the minimal CMD1 promoter in these primary fibroblast cultures. Here we show that the CMD1 promoter contains numerous E-box binding sites for CMD1 and the other myogenic factors, as well as a MEF-2 binding site. Surprisingly, neither muscle-specific and the other myogenic factors, as well as a MEF-2 binding site. Surprisingly, neither muscle-specific expression, autoregulation, or cross activation depends upon the presence of of these E-box or MEF-2 binding sites in the CMD1 promoter. These results demonstrate that the autoregulation and cross activation of the chicken MyoD promoter through the putative direct binding of the myogenic basic helix-loop-helix regulatory factors is mediated through an indirect pathway that involves unidentified regulatory elements and/or ancillary factors.

An avian muscle factor related to MyoD1 activates muscle-specific promoters in nonmuscle cells of different germ-layer origin and in BrdU-treated myoblasts.

We isolated the cDNA encoding a myogenic factor expressed in embryonic chick breast muscle by virtue of its weak hybridization to the mouse MyoD1 clone. Nucleotide sequence analysis and amino acid comparison define this clone, CMD1, as encoding a protein similar to mouse MyoD1. CMD1 encodes a polypeptide smaller than MyoD1, 298 versus 318 amino acids, respectively, and is 80% concordant by amino acid sequence overall. The basic and myc domains required for myogenic conversion of mouse 10T1/2 'fibroblasts' to myoblasts with MyoD1 are completely conserved in CMD1. CMD1 is just as efficient as the mouse homolog in myogenic conversion of 10T1/2 cells and coactivates the endogenous mouse MyoD1 gene in the process. The efficiency of myoblast conversion depends on the levels of CMD1 expression and suggests that the cellular concentration of CMD1 plays a role in the onset of myogenesis. Transient expression of CMD1 in a variety of nonmuscle cells from different germ-layer origins activates both cotransfected muscle-specific promoters and, in some cases, endogenous muscle-specific genes. 5-Bromodeoxyuridine (BrdU) treatment of chicken and mouse myoblasts reduces the expression of CMD1 and MyoD1, respectively, and may explain how this thymidine analog inhibits myogenesis and the activity of transfected muscle-specific promoters in BrdU-treated myoblasts. Transient expression of CMD1 in BrdU-treated myoblasts reactivates cotransfected muscle-specific promoters. CMD1 activates muscle-specific promoters in cotransfections regardless of cell type, whereas 'housekeeping' or constitutive promoters can be activated moderately, unaffected, or repressed, depending on the promoter and cell background. The rate and degree of myogenic conversion may be more restricted by cell phenotype than by germ-layer origin.

Immunocytochemical analysis of the regeneration of myofibrils in long-term cultures of adult cardiomyocytes of the rat.

Dissociated adult rat ventricular cardiomyocytes obtained from hearts by retrograde perfusion with collagenase were investigated in long-term cultures. Myofibril regeneration, isoprotein transition of alpha- and beta-myosin heavy chain (MHC), and M-band localization of M-creatine kinase in the reconstituting heart cells were studied. Myofibril formation was demonstrated by the use of antibodies against either cardiac C-protein or myomesin as early differentiation markers. Four days after plating, small myofibrils could be identified in attached cells in a perinuclear fashion; later in culture the cells displayed various shapes and myofibril distribution. Frequently a patchy distribution of myofibrils within the extending peripheral processes could be observed. Colocalization of sarcomeres and phalloidin-stained F-actin filament bundles was demonstrated by double fluorescence staining and by the use of high intensifying video microscopy and computerized image processing. The immunofluorescence distribution of alpha- and beta-MHC isoproteins in newly isolated and cultured cardiomyocytes changed from 100% alpha-MHC and 70% beta-MHC in rod-shaped cells to about 100% beta-MHC and 70% alpha-MHC in spread out cultured cells. This shift was corroborated by a relative gradual decline in alpha-MHC at the expense of increasing amounts of beta-MHC with time in culture as assessed by sodium dodecyl sulfate gel electrophoresis of total cell homogenates. In addition, whereas rod-shaped newly isolated cardiomyocytes showed a clear M-band association of M-creatine kinase as found in adult heart tissue, adult cultivated spread out cells did not show a cross-striated pattern after incubation with antibody. Taken together, these observations suggest that adult cardiomyocytes not only undergo extensive morphological transitions in long-term cultures, but also generate new myofibrillar structures lacking M-creatine kinase and containing the beta-MHC, thus fitting the characteristics of fetal myofibrils. These results indicate a change from the adult terminally differentiated to a less differentiated state of the cardiac cells in culture.

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).

Distribution of alpha- and beta-myosin heavy chains in the ventricular fibers of the postnatal developing rat.

Four monoclonal antibodies, two raised against alpha-myosin heavy chain (MHC) and two against beta-MHC, have been used to investigate in situ the fiber distribution of alpha- and beta-MHC in rat cardiac ventricles during postnatal development. Eighteen ventricles from 2-day-old to 1-year-old rats were analyzed. Three fiber populations were determined according to their immunofluorescent labeling: one with only alpha-MHC, one only beta-MHC, and one with mixed alpha- and beta-MHC. Large variations in the proportions of these three fiber populations according to age indicate that: (1) alpha-MHC are expressed in all fibers until the second month; they then disappear in a small endocardial fiber population and in a few apparently conductive fibers around the vessels. (2) beta-MHC are also first expressed in all fibers and then disappear gradually from epicardium to endocardium between the second and fourth weeks, except in the conductive fibers; they reappear during the second month sequentially from endocardium to epicardium; and they are then expressed in almost all fibers, except in a small epicardial fiber population, proportionally larger in the right ventricle than in the left. Immunological characterization of MHC isolated from a 22-day-old-rat ventricle, using anti-beta immunoaffinity chromatography, suggests that MHC of conductive fibers are probably at least partially in an alpha beta heterodimeric form.

Local diversity of myosin expression in mammalian atrial muscles. Variations depending on age and thyroid state in the rat and the rabbit.

Rat, rabbit, pig, and bovine atrial myocardia were investigated with anti-alpha and anti-beta myosin heavy chain monoclonal antibodies. Analysis of atrial fibers by indirect immunofluorescence and assay of myosin heavy chains in tissue micro samples by immunoaffinity chromatography revealed both heterogeneity and plasticity in the atrial myosin heavy chains, undetected by electrophoresis of native atrial myosins under nondenaturing conditions. We found both alpha- and beta-like myosin heavy chains to be expressed in rat and rabbit, as they are in pig and bovine, atrial myocardia. They were regionally distributed within atrial muscles. The beta-like myosin heavy chains were present at much lower levels in rat and rabbit atria than in pig and bovine atria. Young rat atrial myosin was composed of only alpha-like heavy chains. In the rat and the rabbit, hyperthyroidism induced a beta- to alpha-like myosin heavy chain transition, which was considerable in the right atria and complete in the left atria. In the rat, thyroidectomy induced a moderate alpha- to beta-like myosin heavy chain transition, visible in the left atria. The significance of this atrial myosin heavy chain polymorphism is discussed in relation to the existence of anatomical localizations of the two myosin variants.

Local changes in myosin types in diseased human atrial myocardium: a quantitative immunofluorescence study.

Two monoclonal antibody groups were prepared from adult human atrial and ventricular myosin heavy chains. Using these two groups, we were able to identify two myosin variants in human atria and to classify human atrial fibers into alpha-, mixed, or beta-fibers according to the reactivity of the two monoclonal antibody groups to alpha- and beta-myosin heavy chains of normal young and hypothyroid rat ventricles, respectively. The alpha-fiber percentage of the left atria in two normal human hearts was 15% higher than in the right atria. The auricles contained two to three times more alpha-fibers than beta-fibers, whereas the proportion was reversed in the crista terminalis. The mean fiber diameter of the alpha- and beta-fibers was 13.6 +/- 3 micron. A complete alpha- to beta-fiber transition was observed in all atrial regions of two hearts with severe ventricular myocardial infarction; a moderate alpha- to beta-fiber transition was observed only in the left atria of two hearts with primary congestive cardiomyopathy. The mean diameters of the two fiber types were significantly increased in all diseased hearts (19 +/- 3.8 micron). We hypothesize that pressure overload and increased wall tension successively induce an enlargement of the fiber diameter and an alpha- to beta-myosin transition.