L Heslop’s research while affiliated with Ealing, Hammersmith & West London College and other places

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Publications (13)


Figure 1 . Loss and proliferation of MPCs following myoblast transplantation into irradiated host muscle. (A) Irradiated left TA muscles of female nude mdx mice were transplanted with 5 ϫ 10 5 radiolabeled male H-2K b clone 18 MPCs. At the times indi- 
Figure 2. Biphasic loss of donor MPCs from irradiated host muscles during the initial 24 h after transplantation. [ 14 C]Thymidinelabeled H-2K b clone 18 MPCs were injected into irradiated left TA muscles of nude mdx mice. Each muscle received 5 10 5 cells and at the times indicated, amount of 14 C present in host muscles was measured. Less than 10% of the injected radiolabel remained 24 h after MT. 60% was lost during the first 60 min and a second event, initiated 8 h after MT, resulted in the subsequent disappearance of most of the remaining label. Results are presented as percentages of 14 C present in 5 10 5 labeled MPCs, and each time point is the mean value from four muscles 1 SD. Muscles taken at 0 h were removed as quickly as possible after MT (i.e., 5 min) and contained 85% of the injected label.
Figure 3 . Dystrophin expression in sections of irradiated mdx muscles, 3 wk after transplantation of unlabeled or radiolabeled normal MPCs. Cryosections of irradiated, nude mdx TA muscles were immunostained for the presence of dystrophin 3 wk after transplantation of 5 ϫ 10 5 H-2K b clone 18 MPCs. No differences 
Figure 4. Differential effects of labeling with [ 14 C]thymidine and [ 3 H]thymidine on MPCs in vitro. H-2K b clone 18 MPCs were cultured for 16 h in the presence of 0.25 Ci/ml of either [ 14 C]thymidine or [ 3 H]thymidine, and then replated at 500 cells/cm 2. The numbers of cells in cultures of [ 14 C]thymidine-labeled (filled circles), [ 3 H]thymidine-labeled (filled squares), and control unlabeled (open circles) cells were counted over 4 d. Each point is the mean of three cultures 1 SD. The growth of MPCs precultured in presence of equivalent concentrations of unlabeled thymidine (4.6 M for [ 14 C]thymidine and 50 pM for [ 3 H]thymidine) was indistinguishable from the control, unlabeled cells at thymidine concentrations of standard medium (data not shown).
Figure 5. Comparative behavior of primary MPCs in irradiated and nonirradiated host muscles. TA muscles of female nude mdx mice were injected with 5 10 5 [ 3 H]thymidine-labeled male primary MPCs. The right legs of host mice had been irradiated 3 d before transplantation. Amounts of Y chromosome (filled columns) and 3 H (open columns) were measured in muscles of host mice killed at times indicated after MT. In both irradiated and contralateral, nonirradiated muscles, there was similar progressive loss of radiolabel over 4 d. However, after an initial fall at 4 h equal to that of radiolabel, amounts of Y chromosome increased in both series, although increase in irradiated muscles was considerably greater than in nonirradiated, contralateral muscles. Each column is the mean of two muscles, presented as percentages of marker injected, determined by analysis of cell pellets prepared as for transplantation.
Dynamics of Myoblast Transplantation Reveal a Discrete Minority of Precursors with Stem Cell–like Properties as the Myogenic Source
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May 2013

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97 Reads

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22 Citations

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L Heslop

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D S Yu

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P S Zammit
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Beauchamp et al 2000

May 2013

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324 Reads



Stem Cell Function, Self-Renewal, and Behavioral Heterogeneity of Cells from the Adult Muscle Satellite Cell Niche

July 2005

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200 Reads

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1,310 Citations

Cell

Satellite cells are situated beneath the basal lamina that surrounds each myofiber and function as myogenic precursors for muscle growth and repair. The source of satellite cell renewal is controversial and has been suggested to be a separate circulating or interstitial stem cell population. Here, we transplant single intact myofibers into radiation-ablated muscles and demonstrate that satellite cells are self-sufficient as a source of regeneration. As few as seven satellite cells associated with one transplanted myofiber can generate over 100 new myofibers containing thousands of myonuclei. Moreover, the transplanted satellite cells vigorously self-renew, expanding in number and repopulating the host muscle with new satellite cells. Following experimental injury, these cells proliferate extensively and regenerate large compact clusters of myofibers. Thus, within a normally stable tissue, the satellite cell exhibits archetypal stem cell properties and is competent to form the basal origin of adult muscle regeneration.



Kinetics of Myoblast Proliferation Show That Resident Satellite Cells Are Competent to Fully Regenerate Skeletal Muscle Fibers

December 2002

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119 Reads

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297 Citations

Experimental Cell Research

The satellite cell compartment provides skeletal muscle with a remarkable capacity for regeneration. Here, we have used isolated myofibers to investigate the activation and proliferative potential of satellite cells. We have previously shown that satellite cells are heterogeneous: the majority express Myf5 and M-cadherin protein, presumably reflecting commitment to myogenesis, while a minority is negative for both. Although MyoD is rarely detected in quiescent satellite cells, over 98% of satellite cells contain MyoD within 24 h of stimulation. Significantly, MyoD is only observed in cells that are already expressing Myf5. In contrast, a minority population does not activate by the criteria of Myf5 or MyoD expression. Following the synchronous activation of the myogenic regulatory factor+ve satellite cells, their daughter myoblasts proliferate with a doubling time of approximately 17 h, irrespective of the fiber type (type I, IIa, or IIb) from which they originate. Although fast myofibers have fewer associated satellite cells than slow, and accordingly produce fewer myoblasts, each myofiber phenotype is associated with a complement of satellite cells that has sufficient proliferative potential to fully regenerate the parent myofiber within 4 days. This time course is similar to that observed in vivo following acute injury and indicates that cells other than satellite cells are not required for complete myofiber regeneration.


Single fibers of skeletal muscle as a novel graft for cell transplantation to the heart

June 2002

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49 Reads

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41 Citations

Journal of Thoracic and Cardiovascular Surgery

Skeletal myoblast transplantation is a promising alternative to treat heart failure. A single fiber, the minimal functional unit of skeletal muscle, retains skeletal myoblasts beneath the basal lamina. When surrounding muscle is injured, myoblasts migrate from the fiber into the damaged area to regenerate muscle. We hypothesized that such isolated fibers could be used as an efficient vehicle to deliver myoblasts into damaged myocardium, resulting in improved cardiac function. Living single fibers of rat skeletal muscle were isolated, and their behavior was characterized in vitro. Single fibers were injected into the myocardium (at 4 sites, each receiving a single fiber) of rats in 2 models of heart failure induced either by means of doxorubicin administration or left coronary artery occlusion. Skeletal myoblasts dissociated from an isolated single fiber, proliferated, and differentiated into multinucleated myotubes in vitro. Within 3 days after grafting in vivo, original fibers provided putative myoblasts and disappeared. At 4 weeks, discrete loci consisting of several multinucleated myotubes were observed. Furthermore, single-fiber transplantation significantly improved cardiac function compared with the control treatment in either doxorubicin-treated hearts (maximum dP/dt, 4013.9 +/- 96.1 vs 3603.1 +/- 102.3 mm Hg/s; minimum dP/dt, -2313.7 +/- 75.1 vs. -2057.1 +/- 52.4 mm Hg/s) or ischemic hearts (maximum dP/dt, 3905.6 +/- 103.0 vs 3572.6 +/- 109.7 mm Hg/s; minimum dP/dt, -2336.1 +/- 69.7 vs -2106.4 +/- 74.2 mm Hg/s). Single-fiber transplantation acts as a vehicle for delivering putative skeletal myoblasts that appear to differentiate into myotubes within the myocardium. This was associated with improved function of failing hearts, suggesting its efficacy as a novel graft for cellular cardiomyoplasty.


Fig. 2. LELI enhances the number of satellite cells emanating from single fibers. Single myofibers prepared from EDL muscle of 21-day-old mice were non-irradiated (left panels) or irradiated with He-Ne laser (right panels) and kept in serum-free medium for the entire experiment. Data are expressed as the cumulative rank of data from single fibers of four independent experiments (n=200). Results are ranked according to the number of cells that accumulated around each single fiber on the indicated days. Individual ranks are expressed as percentage of total rank to normalize the data for sample size, plotted on the vertical axis. Superimposed on each curve as an H symbol is the mean value±1 s.e.m. for each treatment. Median value is indicated by dotted lines. In most cases, the mean and median values are close, therefore most samples are not distant from a Gaussian distribution. The population distribution of LELI cells is significantly different from control cells on all days (KruskalWallis ANOVA median test; Rao R (4,99)=9.65; P<0.001).
Fig. 3. Analysis of the number of satellite cells emanating from single fibers in the presence of serum. (A) Data are expressed as the cumulative rank of the data from single fibers grown in DMEM containing 0.1% HS and either non-irradiated (left panel) or LELI (right panel) (n=200). Curves were plotted as described in Fig. 2. The population distribution of LELI cells is significantly different from control cells on all days (Kruskal-Wallis ANOVA median test; Rao R (4,99)=9.65; P<0.001). (B) A synergistic effect of LELI and serum on cell accumulation around the fibers. Data are presented as the percentage change of the total cell number that was pooled from all experiments in each treatment relative to day 1. White bars, nonirradiated fibers were grown in 0.1% HS-DMEM. Black bars, fibers were irradiated and kept in serum-free DMEM. Hatched bars, fibers were subjected to LELI and kept in DMEM-0.1% HS.
Fig. 4. Effect of LELI on anti-and pro-apoptotic proteins. Two fibers were plated on each Petri dish: one was irradiated and the other served as a control. One day post irradiation, fibers were fixed and stained for BAX (A, C) or Bcl-2 (B, D) and counter-stained with DAPI. Bar, 30 µM. (E) Western blot analysis of Bcl-2, BAX, p53 and p21 in control and irradiated i28 myogenic cells on various days post-irradiation. Equal quantities of proteins were loaded as evidenced by staining for-tubulin. (F) Densitometric analysis of protein expression levels normalized to that of-tubulin. Results are averages of two independent repeats.
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Shefer G, Partridge TA, Heslop L, Gross JG, Oron U, Halevy OLow-energy laser irradiation promotes the survival and cell cycle entry of skeletal muscle satellite cells. J Cell Sci 115:1461-1469

May 2002

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193 Reads

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162 Citations

Journal of Cell Science

Low energy laser irradiation (LELI) has been shown to promote skeletal muscle cell activation and proliferation in primary cultures of satellite cells as well as in myogenic cell lines. Here, we have extended these studies to isolated myofibers. These constitute the minimum viable functional unit of the skeletal muscle, thus providing a close model of in vivo regeneration of muscle tissue. We show that LELI stimulates cell cycle entry and the accumulation of satellite cells around isolated single fibers grown under serum-free conditions and that these effects act synergistically with the addition of serum. Moreover, for the first time we show that LELI promotes the survival of fibers and their adjacent cells, as well as cultured myogenic cells, under serum-free conditions that normally lead to apoptosis. In both systems, expression of the anti-apoptotic protein Bcl-2 was markedly increased, whereas expression of the pro-apoptotic protein BAX was reduced. In culture, these changes were accompanied by a reduction in the expression of p53 and the cyclin-dependent kinase inhibitor p21, reflecting the small decrease in viable cells 24 hours after irradiation. These findings implicate regulation of these factors as part of the protective role of LELI against apoptosis. Taken together, our findings are of critical importance in attempts to improve muscle regeneration following injury.


Low-energy laser irradiation promotes the survival and cell cycle entry of skeletal muscle satellite cells

April 2002

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16 Reads

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179 Citations

Journal of Cell Science

Low energy laser irradiation (LELI) has been shown to promote skeletal muscle cell activation and proliferation in primary cultures of satellite cells as well as in myogenic cell lines. Here, we have extended these studies to isolated myofibers. These constitute the minimum viable functional unit of the skeletal muscle, thus providing a close model of in vivo regeneration of muscle tissue. We show that LELI stimulates cell cycle entry and the accumulation of satellite cells around isolated single fibers grown under serum-free conditions and that these effects act synergistically with the addition of serum. Moreover, for the first time we show that LELI promotes the survival of fibers and their adjacent cells, as well as cultured myogenic cells, under serum-free conditions that normally lead to apoptosis. In both systems, expression of the anti-apoptotic protein Bcl-2 was markedly increased, whereas expression of the pro-apoptotic protein BAX was reduced. In culture, these changes were accompanied by a reduction in the expression of p53 and the cyclin-dependent kinase inhibitor p21, reflecting the small decrease in viable cells 24 hours after irradiation. These findings implicate regulation of these factors as part of the protective role of LELI against apoptosis. Taken together, our findings are of critical importance in attempts to improve muscle regeneration following injury.


Figure 1: Satellite and myogenic cells from Myf5nlacZ/+ mice contain -galactosidase. Freshly isolated soleus myofibres demonstrated -galactosidase (red) in satellite cells (arrowed) as identified by expression of CD34 (green) (a), a satellite cell marker.13 The majority of nuclei expressed neither, as shown by DAPI nuclear counter staining (b). By 48 h in culture, soleus myofibres isolated from Myf5nlacZ/+ mice had produced many cells, the vast majority of which expressed desmin (red) with -galactosidase (green) (c). These cells also co-expressed -galactosidase (e) with MyoD (f), although the relative levels of these protein varied between individual cells (arrows in d-f). DAPI nuclear counter staining revealed all cells present (d). Bar equals 30 m.
Transplanted primary neonatal myoblasts can give rise to functional satellite cells as identified using the Myf5(nlacZ/+) mouse

June 2001

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103 Reads

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102 Citations

Gene Therapy

Myoblast transplantation is a potential therapeutic approach for the genetic modification of host skeletal muscle tissue. To be considered an effective, long-lived method of delivery, however, it is essential that at least a proportion of the transplanted cells also retain their proliferative potential. We sought to investigate whether transplanted neonatal myoblasts can contribute to the satellite cell compartment of adult skeletal muscle by using the Myf5nlacZ/+ mouse. The Myf5nlacZ/+ mouse has nlacZ targeted to the Myf5 locus resulting in beta-galactosidase activity in quiescent satellite cells. Following transplantation, beta-galactosidase-labelled nuclei were detected in host muscles, showing that donor cells had been incorporated. Significantly, beta-galactosidase-positive, and therefore donor-derived, satellite cells were detected. When placed in culture, beta-galactosidase marked myogenic cells emanated from the parent fibre. These observations demonstrate that cell transplantation not only results in the incorporation of donor nuclei into the host muscle syncytia, but also that the donor cells can become functional satellite cells. The Myf5nlacZ/+ mouse therefore provides a novel and specific marker for determining the contribution of transplanted cells to the satellite cell pool.


Citations (10)


... EMG findings in the laser group also confirmed muscle contractility and presence by recording the action potentials of motor units. The role of LLL therapy in muscle regeneration is underscored by its stimulation of satellite cell proliferation and differentiation, 34 as well as increases in myofibrils, 35 antiapoptotic properties, 34 anti-inflammatory properties 21 and angiogenesis. 19 Our results further confirm LLL's efficacy in muscle repair by showing increased muscle mass in the laser group compared to the control group. ...

Reference:

The effect of low-level laser therapy on external anal sphincter repair and treatment of fecal incontinence: A double-blind randomized controlled clinical trial
Low-energy laser irradiation promotes the survival and cell cycle entry of skeletal muscle satellite cells
  • Citing Article
  • April 2002

Journal of Cell Science

... An additional unexpected problem involving a very rapid adverse host immune response has been identified from experimental studies in mice. Intramuscular injection of cultured (congenic) donor myoblasts in classical MTT results in massive and rapid death of donor myoblasts, with over 80% dead within the first hour after injection (reviewed in Beauchamp et al., 1999; Skuk and Tremblay, 2000; Smythe et al., 2000, 2001). This rapid myoblast death appears to be due to exposure to tissue culture conditions (Smythe and Grounds, 2000) that alter the myoblasts so that, when transferred in vivo, they provoke an acute adverse host immune response. ...

Dynamics of Myoblast Transplantation Reveal a Discrete Minority of Precursors with Stem Cell–like Properties as the Myogenic Source

... Satellite cells reside between the plasma membrane and the basal lamina of muscle fibers. They have demonstrated effectiveness and autonomy in muscle regeneration, capable of proliferating and differentiating into various types of muscle fibers in response to mechanical damage in the extracellular environment (78,79). A decrease in satellite cells, or a decline in their function, can compromise (17), sarcopenic obesity (20), heart failure (15), alzheimers disease (13), metabolic syndrome (12), disease (13), frailty (10), dysfunction (21), obesity (10), Health (17), stress (14), damage (31) Experimental Study (10) Expression (65), activation (44), double blind (13), association (21), risk (19), mechanisms (29), in vivo (22), mouse model (10), cells (18), mice (19) Nutrition and ...

Stem Cell Function, Self-Renewal, and Behavioral Heterogeneity of Cells from the Adult Muscle Satellite Cell Niche
  • Citing Article
  • July 2005

Cell

... Imbalanced degeneration-regeneration, possibly exacerbated by high levels of inflammation, is the primary driver of muscle loss. [42] The muscle fibers of this group (III) were splitted and wavy, which was probably due to the incomplete fusion of the regenerating fibers within the same basal lamina [43,44] . There were also eosinophilic material infiltrate between the fibers which denoted the presence of immature collagen. ...

Patterns of repair of dystrophic mouse muscle: Studies on isolated fibers
  • Citing Article
  • November 1999

Developmental Dynamics

... Duchenne Muscular Dystrophy (DMD) is caused by mutations in the dystrophin gene, leading to increased muscle fiber fragility, loss of satellite cell polarity, and functional impairment, which compromise muscle regeneration [125]. In the early stages of DMD, satellite cell-mediated regeneration can temporarily counteract muscle fiber degeneration; however, as the disease progresses, muscle tissue increasingly undergoes fibrosis and fat infiltration [125,126]. ...

Evidence of a myogenic stem cell that is exhausted in dystrophic muscle

Journal of Cell Science

... Under homeostatic conditions, MuSCs exist in a quiescent state [3]. Quiescence is a state of reversible cell cycle arrest, and in MuSCs, it is marked by the expression of the transcription factor Pax7, along with a number of cell surface markers, such as CD34 [4][5][6][7]. As stem cells, MuSCs are defined by their ability to commit to differentiation or to self-renew and replenish the MuSC pool [8,9]. ...

Expression of Cd34 and Myf5 Defines the Majority of Quiescent Adult Skeletal Muscle Satellite Cells

... Ralston and Hall then provided evidence for the widespread diffusion of cytoplasmically soluble beta-galactosidase (β-gal), and translocation of nuclear localizing β-gal in myotubes (55). Yang et al. and others demonstrated β-gal translocation over distances up to 150 µm in vivo (56)(57)(58). However, it remained unclear whether such translocation involved protein or RNA diffusion. ...

Transplanted primary neonatal myoblasts can give rise to functional satellite cells as identified using the Myf5(nlacZ/+) mouse

Gene Therapy

... A possible significance has been suggested based on increasing knowledge of low-intensity light therapy (LILT) or photobiomodulation (PBM) therapy, that uses low intensities of light with wavelengths in the visible (VIS), red, and near-IR (NIR) (Tafur et al., 2010;Kim et al., 2017). These modalities have been shown to influence a wide variety of cellular functions, including gene expression, growth and proliferation, survival, and differentiation (Shefer et al., 2002;Zhang et al., 2003). These functions are primarily mediated by raising the levels of adenosine triphosphate (ATP), a process in which cytochrome c oxidase appears to be the primary photo acceptor and transducer of photo signals in these regions of the light spectrum (Karu, 2010;Poyton and Ball, 2011). ...

Shefer G, Partridge TA, Heslop L, Gross JG, Oron U, Halevy OLow-energy laser irradiation promotes the survival and cell cycle entry of skeletal muscle satellite cells. J Cell Sci 115:1461-1469

Journal of Cell Science

... Collins et al. transplanted single intact myofibers into radiation-ablated muscles and demonstrated that as few as seven satellite cells associated with a single myofiber could generate >100 new myofibers containing thousands of myonuclei [28]. Other groups have shown beneficial effects of single fiber transplantation in preclinical models of aging [29] and heart failure [30]. However, the isolation of single myofibers is challenging and requires a high degree of technical skill and expertise as well as the need for regulatory approval. ...

Single fibers of skeletal muscle as a novel graft for cell transplantation to the heart
  • Citing Article
  • June 2002

Journal of Thoracic and Cardiovascular Surgery

... Second, of those cells that do stop cycling, a large proportion enter a quiescent, non-differentiating state referred to as 'reserve cells' (in line with previous literature 19 ) that we were able to characterise transcriptomically for the first time. This phenomenon seems to occur at much higher rates in vitro than in the physiological setting 41 , but the precise extent to which these reserve cells are analogous to quiescent SCs in vivo remains difficult to understand. Indeed, the increased proportion of reserve cells observed in vitro likely reflects a lack of signalling from neighbouring cells or ECM that finely tune the number of SCs returning to quiescence in vivo 42 . ...

Kinetics of Myoblast Proliferation Show That Resident Satellite Cells Are Competent to Fully Regenerate Skeletal Muscle Fibers
  • Citing Article
  • December 2002

Experimental Cell Research