Differential Response of Oxidative and Glycolytic Skeletal Muscle Fibers to Mesterolone

doi:10.21203/rs.3.rs-459807/v1

Download PDF

Research Article

Differential Response of Oxidative and Glycolytic Skeletal Muscle Fibers to Mesterolone

https://doi.org/10.21203/rs.3.rs-459807/v1

This work is licensed under a CC BY 4.0 License

You are reading this latest preprint version

Background: Oxidative and glycolytic muscle fibers differ in their ultrastructure, metabolism, and responses to physiological stimuli and pathological insults. We examined whether these fibers respond differentially to exogenous anabolic androgenic steroids (AASs) by comparing morphological and histological changes between the oxidative anterior latissimus dorsi (ALD) and glycolytic pectoralis major (PM) fibers in adult avian muscles.

Methods: Adult female White Leghorn chickens (Gallus gallus) were randomly divided into five groups: a vehicle control and four mesterolone treatment groups (4, 8, 12, and 16 mg/kg). Mesterolone was administered orally every three days for 4 weeks. Immunocytochemical techniques and morphometric analyses were employed to measure the changes in muscle weight, fiber size, satellite cell (SC) composition, and number of myonuclei.

Results: Mesterolone increased both body and muscle weights and induced hypertrophy in glycolytic PM fibers but not in oxidative ALD fibers. Mesterolone induced SC proliferation in both muscles; however, the myonuclear accretion was noticeable only in the PM muscle. In both muscles, the collective changes maintained a constant myonuclear domain size and the changes were dose independent.

Conclusion: Mesterolone induced distinct dose-independent effects in avian oxidative and glycolytic skeletal muscle fibers; these findings might be clinically valuable in the treatment of age-related sarcopenia.

Nuclear Medicine & Medical Imaging

Biomedical Engineering

Skeletal muscle

fiber type

satellite cell

myonuclei

myonuclear domain

anabolic androgenic steroids

mesterolone

Avian skeletal muscles are composed of basal lamina-enclosed muscle fibers that can be divided into three major types according to their ultrastructure, metabolic characteristics, and contractile dynamics: i) type I red slow-twitch oxidative fibers, ii) type IIa intermediate fast-twitch oxidativeglycolytic fibers, and iii) type IIb white fasttwitch glycolytic fibers¹. Skeletal muscles are either heterogeneous (composed of multiple muscle fiber types) or homogeneous (composed predominantly of the same fiber type)². In chickens, the anterior latissimus dorsi (ALD) and pectoralis major (PM) are homogeneous muscles. The ALD muscle is a fatigue-resistant slow-contracting (tonic) muscle composed exclusively of oxidative type I fibers, whereas the PM muscle is an easily fatigable fast-contracting (phasic) muscle composed almost entirely of glycolytic type IIb fibers^3–5. The oxidative and glycolytic muscle fibers exhibit distinct responses under different physiological and pathological conditions. These distinct responses are usually accompanied by unique changes in the morphological and cellular characteristics of the fiber^6–8.

Satellite cells (SCs) are mononuclear adult myogenic stem cells located between the outer basal lamina and sarcolemma of muscle fibers^4,9. They are responsible for postnatal muscle growth, repair, and regeneration¹⁰. When there is no need for growth or repair, SCs remain in a quiescent state. However, they become active in response to various stimuli (such as neural activity, exercise loading, and hormones), begin proliferating, and finally differentiate into post-mitotic myonuclei (MN). In fact, SCs contribute to postnatal muscle growth, repair, and regeneration via two mechanisms: i) by fusing into preexisting mature muscle fibers (hypertrophy), a process known as myonuclear accretion, or less commonly ii) by fusing together and forming nascent muscle fibers (hyperplasia)⁹. SCs play an indispensable role during early postnatal muscle fiber growth; however, they are dispensable for adult skeletal muscle fiber growth¹¹.

Among the various stimuli promoting SC activity are anabolic androgenic steroids (AASs), which also augment muscle mass and size^4,5,12. Mesterolone (17-beta-hydroxy-1 alpha-methyl-5 alpha-androstan-3-one) is one of the most frequently used exogenous AASs for the treatment of hypogonadism^12,13. Mesterolone is distinguished from other AASs by its unique chemical structure that does not undergo ring aromatization into estrogen therefore it has no estrogenic side effects. Moreover, mesterolone has a very low hepatotoxicity, and confers oral activity that allows its oral route of administration¹⁴. These advantages of mesterolone encourage it to be considered as a potential alternative therapy for agerelated sarcopenia instead of injectable AASs. A pervious study reported that mesterolone significantly increases the weight and fiber size of the soleus muscle of transgenic mice¹⁵. We found that oral administration of mesterolone significantly increases the number of SCs in maturing avian pectoralis, a response accompanied by increased myonuclear density and DNA content¹². However, it is unclear if mesterolone has distinct effects on different types of normal adult muscle fibers.

In this study, we evaluated the dose-dependent and fiber type-specific effects of mesterolone on two distinct adult avian skeletal muscles, the predominantly oxidative ALD and the mainly glycolytic PM. We hypothesized that mesterolone differentially influences these two muscles by inducing distinct changes in their fiber morphometric and cellular characteristics.

Experimental model

Adult female White Leghorn chickens (Gallus gallus) were raised in the animal care unit at Jordan University of Science and Technology (JUST) in accordance with the institutional guidelines. The birds were housed in large cages (3 birds per cage) at a controlled room temperature of 21°C, fed ad libitum and under a 12–12 h light–dark cycle. All animal care procedures and treatments were conducted with the approval of the JUST committee on animal care, and in accordance with the guidelines of the U.S. National Institutes of Health on the use and care of laboratory animals and with the Animal Research: Reporting of In Vivo Experiments (ARRIVE) guidelines (https://arriveguidelines.org).

At the start of 26 weeks of age, the birds were randomly divided into 5 groups (n = 4 in each group): a control (C) group receiving distilled water (vehicle) only and four mesterolone dose groups receiving 4, 8, 12, and 16 mg/kg (termed groups M1 to M4, respectively). Mesterolone treatments were provided once every three days for four weeks based on a previous protocol¹². Each dose was dissolved in 1 mL distilled water before being administered by oral gavage using a feeding needle. Animals were weighed after group allocation (baseline), at the end of each week, and finally before sacrifice.

At the start of the 30^th week of age, the birds were sacrificed by cervical dislocation, and the left ALD and PM muscles were dissected out, trimmed free of fat, and weighed. The chicken ALD is a small superficial muscle located on the dorsal surface of the thorax originating from a number of cervical and thoracic vertebrae and inserting into the humerus, where it acts to maintain the folded wing against the body. Therefore, it is a fatigue-resistant muscle composed entirely of oxidative type I fibers^3,5. The PM is a relatively large muscle that extends from the sternum to the humerus, where it provides the abrupt force required for the wing down-stroke during flapping flight. It is an easily fatigable fast (phasic) contracting muscle that is composed almost entirely (>99%) of glycolytic type IIb (white) fibers^4,40.

Tissue preparation and sectioning

Muscle samples, approximately 0.5x0.5x1 cm, were cut from each muscle, embedded in optimal cutting temperature compound (O.C.T.; Bio-Optica, Milano, Italy), frozen in 2‑methylbutane, cooled using liquid nitrogen, and stored at -80°C. Serial cross‑sections of 10-µm thickness were cut at -20°C using a cryostat (SLEE-MNT, SLEE Medical GmbH, Mainz, Germany). Each pair of serial sections was picked up on positively charged microscopic slides (AM-1800, AmLabs West LLC, Boulder, CO, USA). Two sections were collected on each slide to increase the possibility of obtaining better fields for imaging. Serial slides bearing sections were numbered and stored at -40°C. Longitudinal sections were also obtained to measure the lengths of SC nuclei and MN.

Immunohistochemistry

Slides were recovered from -40°C storage, air-dried for 10 min, fixed with 4% formaldehyde in 1x phosphate‑buffered saline (PBS) solution for 4 min, washed twice in fresh PBS (5 min/wash), and incubated in ice-cold methanol for 15 min for permeabilization, followed by two 5 min washes with PBS. Blocking solution, consisting of 5 mM ethylenediaminetetraacetic acid (EDTA), 1% bovine serum albumin (BSA) diluted in PBS, and 5% goat serum, was applied over the sections for 20 min. Slides were then drained of the blocking solution and incubated with 150 mL fresh blocking solution containing a mouse monoclonal antibody against chicken Pax7 (1:100, Developmental Studies Hybridoma Bank, Iowa City, Iowa, USA) to label SC nuclei, and a rabbit monoclonal antibody against mouse laminin (1:200, L9393, Sigma Chemical Co., St. Louis, MO) to label the muscle fiber basal lamina. Slides were incubated overnight at 4°C in this primary antibody solution.

Following day, the slides were washed twice in 1x PBS at room temperature (5 min/wash), and incubated for 45 min in PBS containing Alexa Fluor 488-conjugated goat anti-mouse secondary antibody (1:400, A-11001, Invitrogen, Thermo Fisher Scientific, Carlsbad, CA, USA) to label anti-Pax7 and a tetramethylrhodamine (TRITC) goat anti-rabbit secondary antibody (1:400, T6778, Sigma-Aldrich, Merck, Germany) to label anti-laminin. Slides were then washed twice in 1x PBS for 5 min each, and mounted with UltraCruz Mounting medium containing DAPI (SC-24941, Santa Cruz Biotechnology Inc., Dallas, TX, USA) for nuclear counterstaining and sealed under cover slips.

Imaging

Four different fields of view from each slide were captured at 200× using an AxioScope.A1 microscope equipped with epifluorescence and an Axiocam ICc5 digital still camera (Carl-Zeiss, Jena, Germany). The captured fields were numbered in order of acquisition for each animal. Three epifluorescence images per field showing DAPI nuclear staining in blue, Alex Fluor-488 staining of SCs in green, and TRITC staining of the basal lamina in red were acquired for each field, and superimposed using Adobe Photoshop (Adobe System Inc., San Jose, CA, USA).

Image analyses

Fiber morphometric measurements were assessed using the ImageJ software (version 1.52a, available at: http://rsbweb.nih.gov/ij/). The actual cross-sectional area (CSA) and the ellipse minor axis, which is equal to the lesser fiber diameter, were measured for 300 contiguous fibers.

The numbers of SC nuclei and MN were counted for 300 contiguous fibers. SC nuclei were identified as all Pax7⁺/DAPI⁺ nuclei within the basal lamina, while MN were all Pax7^-/DAPI⁺ nuclei inside the basal lamina. The numbers of SC nuclei and MN per unit length (mm) of muscle fiber were calculated using the formula: N = A/(Ln + M), where A is the mean number of nuclei per fiber cross section, Ln is the mean length of the nucleus and M is the thickness of the tissue section on the slide^4,5,10. Longitudinal sections were used to measure the lengths of both SC nuclei and MN. Similar immunofluorescence techniques were employed to study these longitudinal sections. The mean lengths of 50 SC nuclei and 100 MN from each bird were measured using ImageJ.

The frequency of SCs (the percentage of SC nuclei to all nuclei located under the basal lamina) was calculated using the formula: SC nuclei/(SC nuclei + MN) ×100%. The concentration of SC (a measure of aggregation) is measured as the surface area of plasmalemma per SC. SCs become more concentrated and closer to each other as the surface area of plasmalemma per SC decreases. The surface area of plasmalemma per SC (S) can be calculated as S = πEU/N, where E is the lesser diameter (ellipse minor axis), U is the unit length of fiber (1 mm), and N is the number of SCs per unit length of muscle fiber (Allouh et al., 2008, 2017; Allouh and Rosser, 2010). Finally, the myonuclear domain (MND), which is the volume of cytoplasm per myonucleus, was calculated by dividing the volume of sarcoplasm per unit length of fiber by N, the number of myonuclei in this unit length⁵.

Statistical analysis

All numerical data were expressed as mean ± standard deviation (SD). Samples were divided into five groups (a control and four mesterolone-treated groups). Levene’s test was first applied to determine the homogeneity of variance among the groups. Data were then evaluated using one-way analysis of variance (ANOVA) at 5% level of significance. If a significant difference was found, Fisher’s least significant difference (LSD) post-hoc test was used to examine the exact statistical difference between the groups.

Body and muscle weights

All four mesterolone dose groups demonstrated significantly (P<0.01) greater mean body weight than the control group (control group: 1.32±0.09 kg; M1: 1.57±0.12 kg; M2: 1.58±0.13 kg; M3: 1.63±0.08 kg; M4: 1.69±0.09 kg), but there were no significant differences among the mesterolone dose groups, which implies that the effect was dose independent (Fig. 1). Additionally, both ALD (P<0.05) and PM (P<0.01) muscle weights increased significantly following mesterolone administration (Fig. 1).

Fiber size

There were no significant differences in the mean cross‑sectional area (CSA) and fiber diameter between the ALD muscle fibers of control and mesterolone‑treated groups or among the mesterolone‑treated groups (Table 1). However, the mean CSA and fiber diameter of PM fibers were significantly (P<0.05) greater in all mesterolone-treated groups than in the control group (Table 2). There were no significant differences in the CSA and diameter of PM fibers among the mesterolone‑treated groups (Table 2). The comparative changes between ALD and PM in fiber size are summarized in Table 3. In summary, mesterolone induced hypertrophy in glycolytic PM fibers, but not in the oxidative ALD fibers; these hypertrophic effects of mesterolone on PM muscle fibers were dose independent.

Cellular parameters (SCs and MN)

SC indices (SCs per 100 fibers, SCs per unit fiber length, SC frequency, and SC concentration) and myonuclear indices (MN per 100 fibers, and MN per unit fiber length) were measured to assess the effects of mesterolone on the cellular parameters of the fibers. In the basal state (control group), ALD muscle fibers contained more SCs and MN than PM muscle fibers (Tables 1 and 2). Mesterolone significantly (P<0.05) increased all SC indices in both ALD and PM muscles, when compared to those in the vehicle‑treated muscles (Tables 1 and 2). However, there were no significant (P>0.05) differences in SC indices among the mesterolone‑treated groups for each muscle. This indicated that mesterolone induced SC proliferation in both PM and ALD muscle fibers in a dose‑independent manner. Immunofluorescence sections labeled for SC nuclei from ALD and PM muscles are shown in Fig. 2 and Fig. 3, respectively. The SC indices increased to a relatively greater extent in PM fibers than ALD fibers (Table 3).

On the other hand, Mesterolone significantly (P<0.01) increased myonuclear indices in the PM muscle (Table 2) but did not induce any significant (P>0.05) changes in those of the ALD muscle (Table 1). There were no significant (P>0.05) differences in the myonuclear indices of the PM muscle among the mesterolone-treated groups. Collectively, these findings suggest that the increase in SC number within PM muscle fibers resulted in a higher rate of SC‑mediated myonuclear accretion, while the increase of SCs in the ALD muscle fibers failed to augment myonuclear accretion. Additionally, mesterolone induced myonuclear accretion in the PM muscle in a dose‑independent manner.

Myonuclear domain

The size of the myonuclear domain (MND) was calculated in both ALD and PM muscles. There were no significant (P>0.05) changes in the MND size in both ALD and PM muscles in response to mesterolone administration (Tables 1, 2, and 3). However, the MND size in these two muscle types was maintained by two different mechanisms. In PM, the increase in the fiber size (hypertrophy) was compensated by addition of new myonuclei (myonuclear accretion) to maintain the size of the MND. Alternatively, in ALD, the MND remained constant because there was no fiber hypertrophy and no myonuclear accretion.

This study demonstrates the differential effects of the AAS mesterolone on oxidative ALD muscle fibers and glycolytic PM muscle fibers in adult chicken. Mesterolone induced fiber hypertrophy in the PM muscle but not in the ALD muscle. Additionally, it triggered significant increases in SC numbers in both PM and ALD muscle. However, this resulted in an increased muscle fiber myonuclear content only in the PM. The increased myonuclear accretion, coupled with the hypertrophic changes, maintained a constant MND in the PM muscle following mesterolone treatment. However, the SC increase in the ALD muscle failed to induce myonuclear accretion; there was no significant change in muscle fiber size and, therefore, MND remained unaltered.

Adult oxidative and glycolytic muscles normally contain different proportions of SCs and myonuclei, both of which are more abundant and concentrated within oxidative fibers at rest than in the glycolytic fibers^16,17. We confirmed this in the current study by using robust immunocytochemical techniques and precise morphometric and cellular analyses.

The response of skeletal muscles to AASs varies according to fiber type, androgen receptor density, ASS type, ASS dosage, mode and duration of administration, sex, age, and muscle activity level^18–20. In this study, we examined only female chickens to avoid possible confounding effects of the relatively higher and dynamic levels of endogenous androgens in males²¹. In a previous study, we showed that mesterolone induced significant growth in maturing PM muscle and that this response was associated with increase in SC numbers¹². Here, we demonstrate comparable results in the adult PM. In a previous study, we also reported that the injectable AAS, sustanon, significantly boosted SC number and increased the overall size of the ALD muscle fibers in adult female chicken⁵. This was in line with the previous findings that injectable AASs are more potent than oral AASs, such as mesterolone²². However, it cannot be ignored that the injectable steroids are associated with significant side effects. For example, Sustanon has been associated with estrogenic, hepatic, and cardiovascular side effects, whereas mesterolone has not been related to any of these toxic effects¹⁴. Mesterolone has only been found to induce dyslipidemia when used at a very high dose (100 mg/d) for a long period of time (6 months)²³.

Skeletal muscles grow through either only hypertrophy or both hypertrophy and hyperplasia²⁴. In this study, we could not exclude the possibility of mesterolone-induced hyperplasia of the ALD muscle. However, the contribution of hyperplasia to muscle growth is minimal, when compared to that of hypertrophy, in vertebrate skeletal muscle^25,26. Splitting of preexisting muscle fibers and connective tissue invasion was proposed as an alternative mechanism for muscle growth. However, this is usually observed only in muscles under stretch overload or in actively regenerating muscles^27,28. We did not observe fiber splitting in any of the large number of images acquired for this study.

The myonuclear domain remains constant during fiber and muscle growth as MN expansion is offset by the increase in cytoplasmic volume, while the myonuclear domain is reduced by muscle atrophy²⁹. However, this ratio is maintained only under certain conditions and certain studies have found a loose association between cytoplasmic volume and myonuclear number^30,31. This discrepancy may arise from differences in the experimental model and the type of stimulus applied to induce muscle growth^32,33. We found that the MND remained unaltered with mesterolone treatment in both ALD and PM muscles, albeit through different mechanisms.

Age-related sarcopenia (ARS) is a common condition, where there is a loss of skeletal muscle bulk because of aging, resulting in progressive impairment of physical activity. ARS can appear in individuals as early as their 30s and worsen progressively, causing an average loss of 40% of body muscle mass by the age of 80³⁴. Glycolytic muscles are more susceptible to ARS³⁵. The current management approaches for ARS in the elderly are limited³⁶. Injectable testosterone replacement therapy is beneficial to restore muscle mass in individuals with ARS. However, the efficacy of injectable testosterone is limited by its serious side effects, such as increased risks of hepatotoxicity and cardiovascular diseases³⁷. In addition, we reported that the effect of injectable testosterone complex, Sustanon, on skeletal muscles is type non-specific (results in glycolytic and oxidative muscle fiber hypertrophy)^5,38. However, the beneficial effect of mesterolone on skeletal muscle is fiber type-specific (only glycolytic fibers). The effect is dose independent, implying that a minimum dose can be an effective therapy for ARS with minimal side effects when compared to injectable testosterone.

Comparative studies at the subcellular and molecular levels are needed to better understand the mechanisms underlying these differential responses of oxidative and glycolytic skeletal muscle fibers to mesterolone. Also, additional studies for investigating the possibility of hyperplasia in ALD following mesterolone treatment, such as immunostaining experiments with antibodies against proteins expressed specifically in newly formed fibers, are needed.

In conclusion, this study showed that mesterolone induced a dose-independent hypertrophy in the glycolytic fibers but not in the oxidative fibers. In addition, mesterolone induced dose-independent SC-mediated myonuclear accretion only in the glycolytic fibers. This study provides further evidence that oxidative and glycolytic muscle fibers exhibit distinct differential responses under AASs’ stimulation. Importantly, this study suggests that a minimum dose of mesterolone might be clinically effective in treating age-related sarcopenia (ARS), since ARS mostly affects glycolytic fibers³⁹.

Acknowledgements

This study was funded by grants to MZA from the Deanship of Research at JUST (Grants # 20150145 and 20150290). Publication fees was provided by a grant to MZA from the College of Medicine and Health Sciences at United Arab Emirates University, Al Ain, UAE (Grant # G00003289, Fund # 31M441).

Author contributions

Conception and design of the work: M.Z.A. Acquisition of data: H.A.A., E.I.S., and R.S.S. Analysis and interpretation: H.A.A., E.I.S., R.S.S., and M.Z.A. Drafting the manuscript: H.A.A., A.G.M. and B.S.E. Substantial revision of the manuscript: A.G.M. and B.S.E. Preparation of the final revised version and responsible for the submission process: M.Z.A. All authors have approved the submitted version of this manuscript to the journal.

Competing interests

The authors declare no competing interests.

Ethics declaration

This study was conducted with the approval of the Animal Care and Use Committee at Jordan University of Science and Technology, and in accordance with the guidelines of the U.S. National Institutes of Health on the use and care of laboratory animals and with the Animal Research: Reporting of In Vivo Experiments (ARRIVE) guidelines (https://arriveguidelines.org).

Additional information

Correspondence and requests for materials should be addressed to M.Z.A.

Data availability

The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.

Elsevier Sturkie’s Avian Physiology. (2015). doi:10.1016/C2012-0-02488-X.
Welch, K. C. & Altshuler, D. L. Fiber type homogeneity of the flight musculature in small birds. Comp Biochem Physiol B Biochem Mol Biol. 152, 324–331 (2009).
Kirkpatrick, L. J. et al. Pax7 shows higher satellite cell frequencies and concentrations within intrafusal fibers of muscle spindles. J Histochem Cytochem. 56, 831–840 (2008).
Allouh, M. Z. & Rosser, B. W. C. Nandrolone decanoate increases satellite cell numbers in the chicken pectoralis muscle. Histol Histopathol. 25, 133–140 (2010).
Allouh, M. Z., Jarrar, A. A., Asfour, H. A., Said, R. S. & Shaqoura, E. I. Sustanon induces dose-independent hypertrophy and satellite cell proliferation in slow oxidative fibers of avian skeletal muscle. Histol Histopathol. 32, 1151–1159 (2017).
de Theije, C. C. et al. Differential sensitivity of oxidative and glycolytic muscles to hypoxia-induced muscle atrophy. J Appl Physiol (1985). 118, 200–211 (2015).
Hyatt, H. W. et al. Comparative adaptations in oxidative and glycolytic muscle fibers in a low voluntary wheel running rat model performing three levels of physical activity.Physiol Rep3, (2015).
Talbot, J. & Maves, L. Skeletal muscle fiber type: using insights from muscle developmental biology to dissect targets for susceptibility and resistance to muscle disease. Wiley Interdiscip Rev Dev Biol. 5, 518–534 (2016).
Asfour, H. A., Allouh, M. Z. & Said, R. S. Myogenic regulatory factors: The orchestrators of myogenesis after 30 years of discovery. Exp Biol Med (Maywood). 243, 118–128 (2018).
Allouh, M. Z., Yablonka-Reuveni, Z. & Rosser, B. W. C. Pax7 reveals a greater frequency and concentration of satellite cells at the ends of growing skeletal muscle fibers. J Histochem Cytochem. 56, 77–87 (2008).
Murach, K. A. et al. Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice. Skelet Muscle. 7, 14 (2017).
Allouh, M. Z. & Aldirawi, M. H. Influence of mesterolone on satellite cell distribution and fiber morphology within maturing chicken pectoralis muscle. Anat Rec (Hoboken). 295, 792–799 (2012).
Klein, S. A. et al. Substitution of testosterone in a HIV-1 positive patient with hypogonadism and Wasting-syndrome led to a reduced rate of apoptosis. Eur J Med Res. 2, 30–32 (1997).
Llewellyn, W. Anabolics. (Molecular Nutrition LLC).
Fontana, K., White, K. E., Campos, G. E. R., da Cruz-Höfling, M. A. & Harris, J. B. Morphological changes in murine skeletal muscle in response to exercise and mesterolone. J Electron Microsc (Tokyo). 59, 153–164 (2010).
Tseng, B. S., Kasper, C. E. & Edgerton, V. R. Cytoplasm-to-myonucleus ratios and succinate dehydrogenase activities in adult rat slow and fast muscle fibers. Cell Tissue Res. 275, 39–49 (1994).
Yin, H., Price, F. & Rudnicki, M. A. Satellite cells and the muscle stem cell niche. Physiol Rev. 93, 23–67 (2013).
Gustafsson, J. A. et al. Studies on steroid receptors in human and rabbit skeletal muscle - clues to the understanding of the mechanism of action of anabolic steroids. Prog Clin Biol Res. 142, 261–290 (1984).
Kadi, F., Bonnerud, P., Eriksson, A. & Thornell, L. E. The expression of androgen receptors in human neck and limb muscles: effects of training and self-administration of androgenic-anabolic steroids. Histochem Cell Biol. 113, 25–29 (2000).
Hartgens, F. & Kuipers, H. Effects of androgenic-anabolic steroids in athletes. Sports Med. 34, 513–554 (2004).
Trost, L. W. & Mulhall, J. P. Challenges in Testosterone Measurement, Data Interpretation, and Methodological Appraisal of Interventional Trials. J Sex Med. 13, 1029–1046 (2016).
Dandoy, C. & Gereige, R. S. Performance-enhancing drugs. Pediatr Rev. 33, 265–271 quiz 271–272 (2012).
Jockenhövel, F. et al. Influence of various modes of androgen substitution on serum lipids and lipoproteins in hypogonadal men. Metabolism. 48, 590–596 (1999).
Vo, T. A. et al. Skeletal muscle growth dynamics and the influence of first-feeding diet in Atlantic cod larvae (Gadus morhua L.). Biol Open. 5, 1575–1584 (2016).
McCarthy, J. J. et al. Effective fiber hypertrophy in satellite cell-depleted skeletal muscle. Development. 138, 3657–3666 (2011).
Georgiou, S. et al. Transient up- and down-regulation of expression of myosin light chain 2 and myostatin mRNA mark the changes from stratified hyperplasia to muscle fiber hypertrophy in larvae of gilthead sea bream (Sparus aurata L.). Cell Tissue Res. 363, 541–554 (2016).
Antonio, J. & Gonyea, W. J. Muscle fiber splitting in stretch-enlarged avian muscle. Med Sci Sports Exerc. 26, 973–977 (1994).
Cooper, S. T. & Head, S. I. Membrane Injury and Repair in the Muscular Dystrophies. Neuroscientist. 21, 653–668 (2015).
Allen, D. L., Roy, R. R. & Edgerton, V. R. Myonuclear domains in muscle adaptation and disease. Muscle Nerve. 22, 1350–1360 (1999).
Gundersen, K. & Bruusgaard, J. C. Nuclear domains during muscle atrophy: nuclei lost or paradigm lost? J Physiol. 586, 2675–2681 (2008).
Qaisar, R. & Larsson, L. What determines myonuclear domain size? Indian J Physiol Pharmacol. 58, 1–12 (2014).
McCall, G. E. et al. Maintenance of myonuclear domain size in rat soleus after overload and growth hormone/IGF-I treatment. J Appl Physiol (1985). 84, 1407–1412 (1998).
Kadi, F. Adaptation of human skeletal muscle to training and anabolic steroids. Acta Physiol Scand Suppl. 646, 1–52 (2000).
McCormick, R. & Vasilaki, A. Age-related changes in skeletal muscle: changes to life-style as a therapy. Biogerontology. 19, 519–536 (2018).
Akasaki, Y. et al. Glycolytic fast-twitch muscle fiber restoration counters adverse age-related changes in body composition and metabolism. Aging Cell. 13, 80–91 (2014).
Naranjo, J. D., Dziki, J. L. & Badylak, S. F. Regenerative Medicine Approaches for Age-Related Muscle Loss and Sarcopenia: A Mini-Review. Gerontology. 63, 580–589 (2017).
Shin, M. J., Jeon, Y. K. & Kim, I. J. Testosterone and Sarcopenia. World J Mens Health. 36, 192–198 (2018).
Allouh, M. Z. & Aldirawi, M. H. Effects of sustanon on the distribution of satellite cells and the morphology of skeletal muscle fibers during maturation. Pak J Biol Sci. 15, 215–223 (2012).
Nilwik, R. et al. The decline in skeletal muscle mass with aging is mainly attributed to a reduction in type II muscle fiber size. Exp Gerontol. 48, 492–498 (2013).
Bandman, E. & Rosser, B. W. Evolutionary significance of myosin heavy chain heterogeneity in birds. Microsc Res Tech. 50, 473–491 (2000).

Table 1: Anterior latissimus dorsi fiber size and cellular parameters in control and mesterolone‑treated groups

Parameter	Control	M1	M2	M3	M4
Fiber CSA (µm²)	1817±319	2047±323	1836±156	2127±245	2038±526
Lesser Fiber diameter (µm)	37.32±4.11	39.82±3.16	37.94±1.83	40.17±2.32	39.26±5.44
SCs per 100 fibers	22.8±3.6	42.5±7.0**	35.3±6.5*	44.3±7.6**	35.5±4.9**
SCs per 1 mm	10.8±1.7	21.0±3.5**	17.9±3.3**	21.1±3.6**	17.7±2.5**
SC frequency (%)	5.9±0.5	9.4±2.4**	9.1±1.7*	8.6±1.6*	8.8±1.6*
Surface area of plasma- lemma per SC (µm²)	10938±632	6044±912**	6851±1331**	6054±745**	7031±1068**
MN per 100 fibers	363.3±65.0	418.8±78.9	353.8±20.8	477.0±75.0	369.5±42.0
MN per 1 mm	171.5±30.5	208.7±39.3	170±10	223.3±35.2	176.2±20
MND (µm³)	10634±1234	9926±1591	10830±1135	9619±1042	11454±1969

M1, M2, M3, M4: groups treated with 4, 8, 12, and 16 mg/kg mesterolone, respectively. CSA: cross-sectional area; SC: satellite cell; MN: myonuclei; MND: myonuclear domain. Values represent the means ± standard deviations. *P<0.05, **P<0.01 significantly different from the control group (ANOVA, LSD post‑hoc).

Table 2: Pectoralis major fiber size and cellular parameters in control and mesterolone‑treated groups

Parameter	Control	M1	M2	M3	M4
Fiber CSA (µm²)	2042±244	2616±267**	2718±186**	2390±22*	2631±133**
Lesser Fiber diameter (µm)	42.2±2.4	48.3±2.4**	48.4±2.1**	46.9±1.2*	46.8±1.1*
SCs per 100 fibers	8.0±1.0	20.3±4.8**	16.5±3.4*	20.7±4.6**	15.5±4.5*
SCs per 1 mm	3.9±0.4	10.0±2.4**	8.1±1.7*	10.2±2.3**	7.6±2.2*
SC frequency (%)	3.3±0.3	6.3±1.3**	5.0±0.7*	6.0±1.0**	4.8±1.3*
Surface area of plasmalemma per SC (µm²)	144936± 22869	67980± 18521**	81927± 14250**	63640± 11869**	86245± 19336**
MN per 100 fibers	235.8±14.3	300.5±25.4**	313±22.1**	321.3±22.9**	309.8±10.7**
MN per 1 mm	114.5±6.9	146.0±12.3**	152.1±10.8**	156.1±11.1**	150.6±5.2**
MND (µm³)	17930±2951	17998±2170	17904±1244	15382±1077	17488±1076

Table 3: Distinct mesterolone‑induced changes in fiber size and cellular parameters of anterior latissimus dorsi (ALD) and pectoralis major (PM) muscles

Parameter	ALD muscle (oxidative fibers)	PM muscle (glycolytic fibers)
Fiber CSA	unchanged	> 17%–33%
Fiber diameter	unchanged	> 11%–15%
SCs per 100 fibers	> 1.5–1.9 fold	> 1.9–2.6 fold
SCs per 1 mm	> 1.6–2.0 fold	> 1.9–2.6 fold
SC frequency	> 1.5–1.6 fold	> 1.5–1.9 fold
Surface area of plasmalemma per SC	<1.6–1.8 fold	< 1.7–2.3 fold
MN per 100 muscle fibers	unchanged	> 1.3–1.4 fold
MN per 1 mm	unchanged	> 1.3–1.4 fold
Myonuclear domain	unchanged	unchanged

CSA: cross-sectional area; SC: satellite cell; MN: myonuclei

No competing interests reported.

Download PDF

Editorial decision: Major revision
17 May, 2021
Reviews received at journal
15 May, 2021
Reviews received at journal
10 May, 2021
Reviewers agreed at journal
30 Apr, 2021
Reviewers agreed at journal
28 Apr, 2021
Reviewers invited by journal
28 Apr, 2021
Editor assigned by journal
28 Apr, 2021
Editor invited by journal
27 Apr, 2021
Submission checks completed at journal
27 Apr, 2021
First submitted to journal
24 Apr, 2021

You are reading this latest preprint version

Differential Response of Oxidative and Glycolytic Skeletal Muscle Fibers to Mesterolone

Status:

Version 1

Abstract

Figures

Introduction

Methods

Results

Discussion

Declarations

References

Tables

Additional Declarations

Status:

Version 1