Defective adult muscle satellite cells in Zmpste24 deficient mice

Scharner, Juergen.

January 2008

Thesis (M. Phil.)--University of Hong Kong, 2009. / Includes bibliographical references (leaves 117-131) Also available in print.

Defective adult muscle satellite cells in Zmpste24 deficient mice /

Scharner, Juergen.

January 2008

Thesis (M. Phil.)--University of Hong Kong, 2009. / Includes bibliographical references (leaves 117-131) Also available online.

Crosstalk Between the Planar Cell Polarity and Hedgehog Signaling Pathways Influences Satellite Cell Fate

Freeman, Emily

16 January 2019

Our laboratory has identified two secreted proteins, Wnt7a and Sonic hedgehog (Shh), that regulate satellite cell (SC) fate, during muscle differentiation. While Wnt7a stimulates symmetric SC division through the planar cell polarity (PCP) pathway, Shh activates Myf5 expression in the committed SC following asymmetric division through cilia-mediated Hedgehog (Hh) signaling. Crosstalk between these pathways has been well characterized during development, and is likely to be conserved in muscle regeneration. Indeed, accumulating evidence suggests the PCP pathway influences primary cilia formation, an organelle required for proper Hh signal transduction. Here we show that Wnt7a treatment in primary myoblasts increases the presence of primary cilia. Additionally, using myofiber culture, we demonstrate that Wnt7a increases myogenin (MyoG) expression. Removal of primary cilia through a small interfering RNA (siRNA) targeted towards IFT88 impedes Wnt7a mediated MyoG expression, suggesting crosstalk between the PCP and Hh pathways facilitates muscle differentiation. Furthermore, through siRNA knockdown we have identified the downstream PCP effectors, Inturned and Fuzzy as the main candidates responsible for this crosstalk. Knockdown of either Inturned or Fuzzy impedes Wnt7a-mediated MyoG expression. Taken together our data demonstrates crosstalk between the PCP pathway and Hh signaling regulates the differentiation of SCs.

Duchenne Muscular Dystrophy

Hedgehog Signaling

Planar Cell Polarity

Satellite Cells

Regulation of Satellite Cells During Skeletal Muscle Repair and Regeneration

January 2012

abstract: Postnatal skeletal muscle repair is dependent on the tight regulation of an adult stem cell population known as satellite cells. In response to injury, these quiescent cells are activated, proliferate and express skeletal muscle-specific genes. The majority of satellite cells will fuse to damaged fibers or form new muscle fibers, while a subset will return to a quiescent state, where they are available for future rounds of repair. Robust muscle repair is dependent on the signals that regulate the mutually exclusive decisions of differentiation and self-renewal. A likely candidate for regulating this process is NUMB, an inhibitor of Notch signaling pathway that has been shown to asymmetrically localize in daughter cells undergoing cell fate decisions. In order to study the role of this protein in muscle repair, an inducible knockout of Numb was made in mice. Numb deficient muscle had a defective repair response to acute induced damage as characterized by smaller myofibers, increased collagen deposition and infiltration of fibrotic cells. Satellite cells isolated from Numb-deficient mice show decreased proliferation rates. Subsequent analyses of gene expression demonstrated that these cells had an aberrantly up-regulated Myostatin (Mstn), an inhibitor of myoblast proliferation. Further, this defect could be rescued with Mstn specific siRNAs. These data indicate that NUMB is necessary for postnatal muscle repair and early proliferative expansion of satellite cells. We used an evolutionary compatible to examine processes controlling satellite cell fate decisions, primary satellite cell lines were generated from Anolis carolinensis. This green anole lizard is evolutionarily the closet animal to mammals that forms de novo muscle tissue while undergoing tail regeneration. The mechanism of regeneration in anoles and the sources of stem cells for skeletal muscle, cartilage and nerves are poorly understood. Thus, satellite cells were isolated from A. carolinensis and analyzed for their plasticity. Anole satellite cells show increased plasticity as compared to mouse as determined by expression of key markers specific for bone and cartilage without administration of exogenous morphogens. These novel data suggest that satellite cells might contribute to more than muscle in tail regeneration of A. carolinensis. / Dissertation/Thesis / Ph.D. Molecular and Cellular Biology 2012

Molecular biology

Anolis carolinensis

Notch signaling

Satellite cells

Genome-Wide Studies on the Molecular Functions of Pax7 in Adult Muscle Satellite Cells

Punch, Vincent

January 2011

Pax3 and Pax7 belong to a family of conserved transcription factors that play important and diverse roles in development. In the embryo, they carry out similar roles in neural and somite development, but Pax7 fails to compensate for critical functions of Pax3 in the development of limb musculature. Conversely, in the adult, Pax7 is necessary for the maintenance and survival of muscle satellite cells, whereas Pax3 cannot effectively fulfill these roles in the absence of Pax7. To identify the unique roles of Pax7 in adult muscle cells, we have analyzed global binding of Pax3 and Pax7 by ChIP-Seq. Here, we show that despite highly homologous DNA-binding domains, the majority of binding sites are uniquely recognized by Pax7 and are enriched for homeobox motifs. Genes proximal to conserved, unique Pax7 binding sites cluster into specific functional groups which may reflect the unique biological roles of Pax7. Combining Pax7 binding sites with gene expression data, we describe the regulatory networks directed by Pax7 and show that Pax7 binding is associated with positive gene regulation. Moreover, we show Myf5 is a direct target of Pax7 and identify a novel binding site in the satellite cell control region upstream of Myf5.

Pax7

Skeletal muscle

Transcriptional networks

Satellite cells

Stem cells

Regeneration

C/EBPbeta is a Negative Regulator of Skeletal Muscle Differentiation

Li, Grace T.Y.

January 2011

C/EBPβ is a bZIP transcription factor known to be involved in various physiological processes, including adipogenesis, osteogenesis and liver development. Previous studies in this laboratory revealed an inhibition of myogenesis and reduced myogenic protein expression in 5-azacytidine treated mesenchymal stem cells retrovirally transduced to overexpress C/EBPβ. The goal of this thesis was to evaluate the role of C/EBPβ in myogenic differentiation by overexpression in C2C12 myoblasts and primary myoblasts. We demonstrate reduced MyoD protein expression and subsequent downregulation of myogenic proteins during differentiation following C/EBPβ overexpression. We localized C/EBPβ to the quiescent Pax7+ satellite cells associated with the muscle fiber. Upon satellite cell activation, we observed the downregulation of C/EBPβ protein expression prior to MyoD protein expression. Furthermore, the re-expression of C/EBPβ correlated with the loss of MyoD expression later in differentiation. Histological analysis of C/EBPβ-/- mice revealed smaller fibers and a reduced Pax7+ satellite cell population as compared to control animals. In this thesis, we propose that C/EBPβ is a negative regulator of skeletal muscle differentiation by inhibiting the expression of MyoD, thus impairing proper progression through the myogenic program. In addition, we propose a role for C/EBPβ in the maintenance of undifferentiatied satellite cells.

C/EBPbeta

satellite cells

skeletal muscle differentiation

MyoD

Six1 Is Important for Myoblast Proliferation Through Direct Regulation of Ccnd1

Horner, Ellias

January 2016

The transcription factor Six1 of the sine oculis homeobox family has been tied to skeletal muscle formation. Work completed thus far has allowed our research team to identify the precise mechanism by which Six1 regulates the expression of MyoD, a key myogenic gene, in muscle stem cells. Furthermore, loss-of-function of this protein, mediated by RNA interference, has implicated Six1 as essential towards normal myogenic differentiation. However, beyond Six1 and its involvement towards myogenesis, our data also suggests the transcription factor as a potential regulator of the cell cycle. Data from our lab shows that loss of Six1 expression significantly impairs primary myoblast proliferation and appears to impair satellite cell activation in response to muscle injury in vivo. Furthermore, loss of Six1 decreases the expression of key cell cycle genes. Combining functional genomics approaches such as ChIP-Seq and Gene Expression Profiling together with Gene Ontology Term Enrichment shows a significant representation for biological processes regarding the cell cycle and its regulation; these biological clusters contain a large subset of genes that are bound and modulated by Six1. In particular, Ccnd1 was found to display a similar expression pattern as Six1 in growing myoblasts and its expression was found to be directly controlled by Six1. Furthermore, Ccnd1 over-expression was sufficient to rescue the Six1-knockdown associated cell cycle phenotype. Together, these data suggest that in response to injury Six1 enhances the expression of the cell cycle gene Ccnd1 thus modulating myoblast proliferation for muscle regeneration.

Myoblasts

Satellite Cells

Six1

Proliferation

Myogenesis

Cell Cycle

Ccnd1

Extraocular Muscles in Amyotrophic Lateral Sclerosis

Tjust, Anton

January 2017

Amyotrophic lateral sclerosis (ALS) is an incurable neurodegenerative disease of motor neurons characterized by muscle paralysis and death within 3-5 years of onset. However, due to unknown mechanisms, the extraocular muscles (EOMs) remain remarkably unaffected. The EOMs are highly specialized muscles that differ from other muscles in many respects, including innervation and satellite cells (SCs). Understanding whether these factors play a role in the relative sparing of EOMs in ALS could provide useful clues on how to slow down the progression of ALS in other muscles. The EOMs and limb muscles from terminal ALS patients and age-matched controls as well as the commonly used SOD1G93A ALS mouse model were studied with immunofluorescence. Antibodies against neurofilament and synaptophysin were used to identify nerves and neuromuscular junctions (NMJs); against Pax7, NCAM, MyoD, myogenin, Ki-67, dystrophin and laminin, to identify SCs and their progeny in EOMs and limb muscles. The proportion and fiber size of myofibers containing myosin heavy chain (MyHC) slow tonic and MyHC slow twitch were also determined in human EOMs. The abundance of SCs differed extensively along the length of control human EOMs, being twice as abundant in the anterior portion. Pax7-positive cells were also detected in non-traditional SC positions. EOMs from terminal ALS patients showed similar numbers of resting and activated SCs as the controls. In limb muscles of ALS patients, the number of resting and activated SCs ranged from low (similar to normal aged, sedentary individuals) to high numbers, especially in muscles with long duration of disease and varied between the upper and lower limbs. The EOMs maintained a high degree of innervation compared to hindlimb muscles of symptomatic SOD1G93A mice. MyHC slow tonic fibers were less abundant in ALS patients than in controls. The change seemed more pronounced in bulbar onset patients, and in this group of subjects only, there was a strong association between decline in MyHC slow tonic fibers and age of death. Notably, the decline in MyHC slow tonic fibers was unrelated to disease duration. Our data suggested that SCs play a minor role in the progression of ALS in general and in the sparing of the EOMs in particular. The generally preserved innervation in the EOMs of G93A mice may reflect distinct intrinsic properties relevant for sparing of the oculomotor system.  Even though the EOMs are relatively spared in ALS, MyHC slow tonic myofibers were selectively affected and this may reflect differences in innervation, as these fibers are multiply innervated. / Amyotrofisk lateralskleros (ALS) är en obotlig neurodegenerativ sjukdom som främst påverkar kroppens viljestyrda motoriska nervceller. ALS leder till förlamning, muskelförtvining och slutligen döden genom andningssvikt, vanligen inom tre till fem år efter sjukdomsdebuten. Av okända anledningar så bibehålls ögonmusklernas funktion mycket bättre vid ALS i jämförelse med andra muskler och är hos merparten av patienter i stort sett opåverkade. Ögonmusklerna är mycket specialiserade muskler som skiljer sig från andra muskler i kroppen på flera sätt, bland annat genom deras unika nervförsörjning och genom de satellitceller – muskelspecifika stamceller, som finns i dem. En ökad förståelse för hur dessa faktorer inverkar på ögonmusklernas motståndskraft vid ALS skulle kunna ge värdefulla ledtrådar till hur man skulle kunna sakta ned sjukdomens fortskridande i andra muskler vid ALS. Ögonmuskler och extremitetsmuskler från avlidna ALS-patienter och åldersmatchade friska kontroller, tillsammans med transgena möss med den sjukdomsalstrande mutationen SOD1G93A, studerades genom immunfluorescens och efterföljande mikroskopering. Antikroppar mot molekylerna Pax7, NCAM, MyoD, myogenin, Ki-67, laminin och dystrofin användes för att identifiera satellitceller och deras dotterceller i ögonmuskler och extremitetsmuskler. Antikroppar mot neurofilament och synaptofysin användes för att identifiera nerver och neuromuskulära synapser hos transgena SOD1-möss. Antikroppar mot toniska (tonic) och ryckande (twitch) muskelmyosinkedjor användes för att bestämma proportionen av och storleken på dessa typer av muskelfibrer i ögonmuskler från avlidna ALS-patienter och friska kontroller. Mängden satellitceller varierade mellan de främre och de mer bakre delarna i friska, humana ögonmuskler och var dubbelt så många i den främre delen av muskeln jämfört med den mellersta och bakre delen av muskeln. Celler som uttryckte satellitcellsmarkören Pax7 hittades även i icke-traditionella satellitcellspositioner i ögonmusklerna. Mängden satellitceller i ögonmusklerna från ALS-patienter var samma som hos friska kontroller. I extremitetsmusklerna hos ALS-patienter varierade mängden satellitceller mellan låga nivåer (liknande de hos friska åldrade, inaktiva individer) till höga nivåer, särskilt i muskler där sjukdomen fortskridit under lång tid. Dessutom varierade mängden satellitceller mellan övre och nedre extremiteter. Hos symptomatiska SOD1G93A-möss hade ögonmusklerna en mycket välbevarad innervation jämfört med bakbensmusklerna, där många neuromuskulära synapser saknade kontakt mellan nerven och motorändplattan. Proportionen muskelfibrer med toniska muskelmyosinkedjor var lägre hos ALS-patienter jämfört med friska kontroller. Denna minskning var tydligare hos patienter där sjukdomssymtomen hade debuterat i tugg- och ansiktsmuskulaturen – så kallad bulbär ALS. Dessutom fanns det i den här gruppen, men ingen annan studerad grupp, en stark korrelation mellan nedgången i toniska fibrer och patientens ålder. Värt att notera är att minskningen av toniska muskelfibrer saknade korrelation med hur länge patienten hade varit sjuk i ALS. Den generellt välbevarade innervationen i ögonmusklerna hos SOD1G93A-möss kan spegla distinkta inneboende egenskaper hos ögonmusklerna som är av vikt för bevarandet av ögonrörligheten vid ALS. Gällande satellitceller så antyder våra data att satellitceller och deras regenerativa kapacitet spelar en försumbar roll vid ALS i allmänhet och vid ögonmusklernas bevarande i synnerhet. Slutligen, även om ögonmuskler generellt är välbevarade vid ALS så är toniska muskelfibrer märkbart påverkade och detta kan spegla skillnader mellan olika nervcellsgruppers känslighet vid ALS.

ALS

EOM

Satellite cells

innervation

neuromuscular disease

neurodegenerative disease

The Role of Growth Arrest Specific 6 and Axl Signaling in Skeletal Muscle Regeneration

Matsumura, Marc Shigeru

05 December 2019

Skeletal muscle regeneration is a critical process that replaces damaged muscle fibers with new fibers. The regenerative process can be segmented into four main phases: necrosis, inflammation, regeneration, and maturation. While many of the key signaling molecules are known and characterized, there are still gaps in our understanding of how this process is regulated. While it is reported that growth arrest specific 6 (Gas6) and its receptor Axl are expressed in mature muscle tissue, nothing is known about the effect that Gas6 and Axl have on regulating skeletal muscle regeneration. In this study we investigated the regenerative process in a Gas6/Axl double knockout (dKO) mouse model. The tibialis anterior (TA) muscle was chemically injured with BaCl2 and allowed to recover for 3, 7, or 14 days. We investigated satellite cell (SC) activation and muscle growth. We found that the dKO injured muscle has fewer SCs at 3-days post-injury, but the percentage of mitotically active SCs were no different between WT and dKO injured muscle. Interestingly, basal and injured dKO muscle has an increased cross-sectional area compared to wild type in male mice. Together this may suggest that in the absence of Gas6/Axl signaling may lead to impaired regeneration and compensatory fiber hypertrophy. The mechanism behind the hypertrophy remains unknown, but ultimately our findings suggest that Gas6/Axl signaling has an effect on skeletal muscle regeneration.

Gas6

Axl

regeneration

satellite cells

hypertrophy

Life Sciences

Cell Transplantation for Myocardial Repair: An Experimental Approach

Marelli, Daniel, Desrosiers, Carolyne, El-Alfy, Mohamed, Kao, Race L., Chiu, Ray C.J.

01 January 1992

Myocardium lacks the ability to regenerate following injury. This is in contrast to skeletal muscle (SKM), in which capacity for tissue repair is attributed to the presence of satellite cells. It was hypothesized that SKM satellite cells multiplied in vitro could be used to repair injured heart muscle. Fourteen dogs underwent explantation of the anterior tibialis muscle. Satellite cells were multiplied in vitro and their nuclei were labelled with tritiated thymidine 24 h prior to implantation. The same dogs were then subjected successfully to a myocardial injury by the application of a cryoprobe. The cells were suspended in serum-free growth medium and autotransplanted within the damaged muscle. Medium without cells was injected into an adjacent site to serve as a control. Endpoints comprised histology using standard stains as well as Masson trichrome (specific for connective tissue), and radioautography. In five dogs, satellite cell isolation, culture, and implantation were technically satisfactory. In three implanted dogs, specimens were taken within 6-8 wk. There were persistence of the implantation channels in the experimental sites when compared to the controls. Macroscopically, muscle tissue completely surrounded by scar tissue could be seen. Masson trichrome staining showed homogeneous scar in the control site, but not in the test site where a patch of muscle fibres containing intercalated discs (characteristic of myocardial tissue) was observed. In two other dogs, specimens were taken at 14 wk postimplantation. Muscle tissue could not be found. These preliminary results could be consistent with the hypothesis that SKM satellite cells can form neo-myocardium within an appropriate environment. Our specimens failed to demonstrate the presence of myocyte nuclei. It is therefore further hypothesized that in the late postoperative period, the muscle regenerate failed to survive.

myocardial regeneration

neo-myocardium

satellite cells

skeletal muscle