Stretch-induced growth in chicken wing muscles: role of soluble growth-promoting factors

Physiology of Stretch-Mediated Hypertrophy and Strength Increases: A Narrative Review

Increasing muscle strength and cross-sectional area is of crucial importance to improve or maintain physical function in musculoskeletal rehabilitation and sports performance. Decreases in muscular performance are experienced in phases of reduced physical activity or immobilization. These decrements highlight the need for alternative, easily accessible training regimens for a sedentary population to improve rehabilitation and injury prevention routines. Commonly, muscle hypertrophy and strength increases are associated with resistance training, typically performed in a training facility. Mechanical tension, which is usually induced with resistance machines and devices, is known to be an important factor that stimulates the underlying signaling pathways to enhance protein synthesis. Findings from animal studies suggest an alternative means to induce mechanical tension to enhance protein synthesis, and therefore muscle hypertrophy by inducing high-volume stretching. Thus, this narrative review discusses mechanical tension-induced physiological adaptations and their impact on muscle hypertrophy and strength gains. Furthermore, research addressing stretch-induced hypertrophy is critically analyzed. Derived from animal research, the stretching literature exploring the impact of static stretching on morphological and functional adaptations was reviewed and critically discussed. No studies have investigated the underlying physiological mechanisms in humans yet, and thus the underlying mechanisms remain speculative and must be discussed in the light of animal research. However, studies that reported functional and morphological increases in humans commonly used stretching durations of > 30 min per session of the plantar flexors, indicating the importance of high stretching volume, if the aim is to increase muscle mass and maximum strength. Therefore, the practical applicability seems limited to settings without access to resistance training (e.g., in an immobilized state at the start of rehabilitation), as resistance training seems to be more time efficient. Nevertheless, further research is needed to generate evidence in different human populations (athletes, sedentary individuals, and rehabilitation patients) and to quantify stretching intensity.

Muscle function in men and women during maximal eccentric exercise

This study assessed muscle fatigue patterns of the elbow flexors in untrained men and women to determine if sex differences exist during acute maximal eccentric exercise. High-intensity eccentric exercise is often used by athletes to elicit gains in muscle strength and size gains. Development of fatigue during this type of exercise can increase risk of injury; therefore, it is important to understand fatigue patterns during eccentric exercise to minimize injury risk exposure while still promoting training effects. While many isometric exercise studies have demonstrated that women show less fatigue, the patterns of fatigue during purely eccentric exercise have not been assessed in men and women. Based on the lack of sex differences in overall strength loss immediately post-eccentric exercise, it was hypothesized that women and men would have similar relative fatigue pattern responses (i.e., change from baseline) during a single bout of maximal eccentric exercise. Forty-six subjects (24 women and 22 men) completed 5 sets of 10 maximal eccentric contractions on an isokinetic dynamometer. Maximal voluntary isometric contraction strength was assessed at baseline and immediately following each exercise set. Maximal eccentric torque and contractile properties (i.e., contraction time, work, half relaxation time, and maximal rate of torque development) were calculated for each contraction. Men and women demonstrated similar relative isometric (32% for men and 39% for women) and eccentric (32% for men and 39% for women) fatigue as well as similar deficits in work done and rates of torque development and relaxation during exercise (p > 0.05). Untrained men and women displayed similar relative responses in all measures of muscle function during a single bout of maximal eccentric exercise of the elbow flexors. Thus, there is no reason to suspect that women may be more vulnerable to fatigue-related injury.

Aging sustains the hypertrophy-associated elevation of apoptotic suppressor X-linked inhibitor of apoptosis protein (XIAP) in skeletal muscle during unloading

This study tested the hypotheses that apoptotic suppressors: (a) increase during muscle overload, (b) decrease in response to unloading following hypertrophy, and (c) respond to unloading in an aging-dependent fashion. Following 14 days of stretch-induced overloading, the X-linked inhibitor of apoptosis protein (XIAP) was elevated by 140% and 116% in patagialis (PAT) muscles of young and old quail, respectively, when compared to the contralateral control side. XIAP messenger RNA (mRNA) or protein was not different in experimental and control muscles of young birds after 7 or 14 days of unloading. In old birds, PAT XIAP mRNA and protein were 47% and 67% greater in experimental than in control muscles, respectively, after 7 days of unloading. Furthermore, XIAP mRNA had returned to control level by 14 days of unloading, but XIAP protein content was 57% greater than control muscles after 14 days of unloading. Higher levels of XIAP during unloading in old than in young muscles may be an attempt to counterbalance apoptosis-induced muscle atrophy.

Id2 and p53 participate in apoptosis during unloading-induced muscle atrophy

Apoptotic signaling was examined in the patagialis (PAT) muscles of young adult and old quail. One wing was loaded for 14 days to induce hypertrophy and then unloaded for 7 or 14 days to induce muscle atrophy. Although the nuclear Id2 protein content was not different between unloaded and control muscles in either age group, cytoplasmic Id2 protein content of unloaded muscles was higher than that in contralateral control muscles after 7 days of unloading in young quails. Nuclear and cytoplasmic p53 contents and the p53 nuclear index of the unloaded muscles were higher than those in control muscles after 7 days of unloading in young quails, whereas in aged quails, the p53 and Id2 contents and p53 nuclear index of the unloaded muscles were not altered by unloading. Immunofluorescent staining indicated that myonuclei and activated satellite cell nuclei contributed to the increased number of p53-positive nuclei. Conversely, unloading in either young adult or aged PAT muscles did not alter c-Myc protein content. Although Cu-Zn-SOD content was not different in unloaded and control muscles, Mn-SOD content increased in PAT muscles after 7 days of unloading in young quails, suggesting that unloading induced an oxidative disturbance in these muscles. Moderate correlational relationships existed among Id2, p53, c-Myc, SOD, apoptosis-regulatory factors, and TdT-mediated dUTP nick end labeling index. These data indicate that Id2 and p53 are involved in the apoptotic responses during unloading-induced muscle atrophy after hypertrophy in young adult birds. Furthermore, our data suggest that there is an aging-dependent regulation of Id2 and p53 during unloading of previously hypertrophied muscles.

Aging influences cellular and molecular responses of apoptosis to skeletal muscle unloading

The influence of aging on skeletal myocyte apoptosis is not well understood. In this study we examined apoptosis and apoptotic regulatory factor responses to muscle atrophy induced via limb unloading following loading-induced hypertrophy. Muscle hypertrophy was induced by attaching a weight to one wing of young and aged Japanese quails for 14 days. Removing the weight for 7 or 14 days after the initial 14 days of loading induced muscle atrophy. The contralateral wing served as the intra-animal control. A time-released bromodeoxyuridine (BrdU) pellet was implanted subcutaneously with wing weighting to identify activated satellite cells/muscle precursor cells throughout the experimental period. Bcl-2 mRNA and protein levels decreased after 7 days of unloading, but they were unchanged after 14 days of unloading in young muscles. Bcl-2 protein level but not mRNA level decreased after 7 days of unloading in muscles of aged birds. Seven days of unloading increased the mRNA level of Bax in muscles from both young and aged birds. Fourteen days of unloading increased mRNA and protein levels of Bcl-2, decreased protein levels of Bax, and decreased nuclear apoptosis-inducing factor (AIF) protein level in muscles of aged birds. BrdU-positive nuclei were found in all unloaded muscles from both age groups, but the number of BrdU-positive nuclei relative to the total nuclei decreased after 14 days of unloading compared with 7 days of unloading. The TdT-mediated dUTP nick end labeling (TUNEL) index was higher after 7 days of unloading in both young and aged muscles and after 14 days of unloading in aged muscles. Immunofluorescent staining revealed that almost all of the TUNEL-positive nuclei were also BrdU immunopositive, suggesting that activated satellite cell nuclei (both fused and nonfused) underwent nuclear apoptosis during unloading. There were significant correlations among levels of Bcl-2, Bax, and AIF and TUNEL index. Our data are consistent with the hypothesis that apoptosis regulates, at least in part, unloading-induced muscle atrophy and loss of activated satellite cell nuclei in previously loaded muscles. Moreover, these data suggest that aging influences the apoptotic responses to prolonged unloading following hypertrophy in skeletal myocytes.

Id2 expression during apoptosis and satellite cell activation in unloaded and loaded quail skeletal muscles

Inhibitor of differentiation-2 (Id2) is a basic helix-loop-helix protein that acts as a negative regulator of the myogenic regulatory transcription factor family, but Id2 has also been implicated in apoptosis in several cell lines. In this study, we tested the hypothesis that Id2 has a role in both apoptosis-associated muscle atrophy and muscle hypertrophy. A weight corresponding to 12% of the body weight was attached to one wing of Japanese quail to induce hypertrophy in the patagialis (PAT) muscle. Birds in group 1 were killed after 5 (n = 8), 7 (n = 10), or 14 days (n = 10) of loading. The left wing was loaded for 14 days in group 2 birds, and then the weight was removed and the PAT was examined after 7 (n = 10), 14 (n = 10), or 21 (n = 5) days of unloading. A time-released bromodeoxyuridine (BrdU) pellet was implanted subcutaneously with wing weighting to identify activated satellite cells during loading. The left wing was loaded for 14 days, unloaded for 14 days, and then the weight was reattached for a subsequent 7 (n = 10) or 14 days (n = 10) in group 3 birds. BrdU was implanted on the second loading phase in this group. Id2 mRNA as measured by kinetic PCR increased by 3.9-, 2.7-, and 1.6-fold, relative to control levels after 7, 14, and 21 days of unloading (group 2). Id2 protein as estimated by Western blots increased by 1.5-, 1.4-, and 0.75-fold after 7, 14, and 21 days of unloading (group 2). Muscle unloading induced apoptosis, because poly(ADP-ribose) polymerase-(PARP)-positive nuclei increased and caspase 8 levels increased by 2.6- and 1.7-fold after 7 or 14 days of unloading, respectively (group 2). Although BrdU-positive nuclei increased during loading (groups 1 and 3), 50% failed to survive during unloading (group 2). Id2 mRNA increased by 2.2- and 1.8-fold after 5 and 7 days of loading, respectively, but decreased to control levels by 14 days of loading in group 1. Id2 protein levels increased 2.1-fold after 5 days of loading (group 1). In contrast, Id2 did not increase in reloaded muscles of group 3 birds. These data suggest that Id2 may have a role in apoptosis-associated atrophy of skeletal muscles, but its role in muscle hypertrophy is less clear.

Attenuation of Ca(2+)-activated ATPase and shortening velocity in hypertrophied fast twitch skeletal muscle from aged Japanese quail

The effect of aging on the in vitro contractile properties of the patagialis (PAT) muscle of 35 young adult (YA; 8 weeks of age) and 35 aged adult (AA, 110 weeks of age) Coturnix quails was examined after 0-30 days of stretch-overload. Overload was achieved by placing a weight equivalent to 12% of the birds' body weight on one wing. The contralateral wing served as the intra-animal control. Overload increased the weight of the PAT by 45.1+/-2.1% in YA, and 24.1+/-2.6% in AA. Twitch contraction time increased with loading from 43.2+/-1.2 to 67.3+/-2.2 ms in YA birds and 57.2+/-1.7 to 77.4+/-1.9 ms in AA birds. Unloaded shortening velocity (Vo) decreased by 40.1+/-2.2 and 38.8+/-3.2% in YA and aged birds, respectively. The decrease in fast myosin expression was greater in overloaded muscles of YA (20%) as compared to AA birds (12%). However, this was accompanied by a greater decrease in total muscle ATPase activity in aged birds (61%) compared to YA birds (40%). Myosin isozyme Ca(2+)-ATPase activity was 26% lower in FM1 but not other fast myosins in YA birds, but it was approximately 30% lower in all fast myosins in PAT muscles of aged birds. These data show that the reduction of Vo and the increase in twitch duration with aging may be due in part to reductions in ATPase activity in all myosin isoforms, as compared to myosin isoforms isolated from YA birds.

Cyclic mechanical deformation stimulates human lung fibroblast proliferation and autocrine growth factor activity

Cellular hypertrophy and hyperplasia and increased extracellular matrix deposition are features of tissue hypertrophy resulting from increased work load. It is known, for example, that mechanical forces play a critical role in lung development, cardiovascular remodeling following pressure overload, and skeletal muscle growth. The mechanisms involved in these processes, however, remain unclear. Here we examined the effect of mechanical deformation on fibroblast function in vitro. IMR-90 human fetal lung fibroblasts grown on collagen-coated silastic membranes were subjected to cyclical mechanical deformation (10% increase in culture surface area; 1 Hz) for up to 5 days. Cell number was increased by 39% after 2 days of deformation (1.43 +/- .01 x 10(5) cells/membrane compared with control, 1.03 +/- 0.02 x 10(5) cells; mean +/- SEM; P < 0.02) increasing to 163% above control by 4 days (2.16 +/- 0.16 x 10(5) cells compared with 0.82 +/- 0.03 x 10(5) cells; P < 0.001). The medium from mechanically deformed cells was mitogenic for IMR-90 cells, with maximal activity in the medium from cells mechanically deformed for 2 days (stimulating cell replication by 35% compared with media control; P < 0.002). These data suggest that mechanical deformation stimulates human lung fibroblast replication and that this effect is mediated by the release of autocrine growth factors.

Stretch-induced growth-promoting activities stimulate fetal rat lung epithelial cell proliferation

There is increasing evidence to suggest that fetal lung growth requires normal fetal breathing movements. To study this process in vitro, the effect of mechanical stretch on proliferation of fetal rat lung cells maintained in organotypic cultures was examined. In previous studies it has been demonstrated that DNA synthesis and cell division are stimulated by stretch. To determine whether stretched cells release soluble growth factors into their culture medium, conditioned media (CMs) were collected after static culture or culture while stretched. At a 10% dilution (v/v), CM from stretched cells (S-CM) increased [3H]thymidine incorporation into DNA of mixed fetal rat lung cells by 60%, compared to CM from nonstretched cells (C-CM) (p < .01). S-CM increased [3H]thymidine incorporation of fetal lung epithelial cells by 3 to 4-fold (p < .01) and increased cell number by 11.9% (p < .05), but had no effect on fetal lung fibroblast growth. Addition of either PDGF-BB (20 ng/mL), IGF-I (25 ng/mL), or EGF (50 ng/mL) to C-CM, did not mimic the effect of S-CM on epithelial cell DNA synthesis. The stimulatory activity of S-CM on epithelial cell proliferation was heat-, acid- and trypsin-sensitive. It is concluded that organotypic fetal lung cell cultures respond to stretch by elaborating growth-promoting factors which stimulate fetal rat lung epithelial cell, but not fibroblast, proliferation.

Partial characterization of skeletal myoblast mitogens in mouse crushed muscle extract

We have utilized a model system to investigate myotrophic factors released by normal adult mouse muscles following a crush injury. We found that saline extracts from gently crushed mouse muscles (CME) contain potent mitogenic activities which act on primary newborn mouse myoblast cultures, as well as on mouse C2 cells, a mouse myoblast cell line. We compared the activity of CME on mouse myoblasts with that of basic fibroblast growth factor (bFGF) and insulin-like growth factor I (IGF-I), two growth factors known to be mitogenic for primary myoblasts (Allen, Dodson, and Lutein: Exp. Cell. Res., 152:154-160, 1984; DiMario and Strohman: Differentiation, 39:42-49, 1988; Allen and Boxhorn: J. Cell. Physiol., 138:311-315, 1989; Dodson, Allen, and Hossner: Endocrinology, 117:2357-2363, 1985; Florini and Magri: Am. J. Physiol., 256:C701-C711, 1989). We found that CME could act in an additive fashion to saturating doses of bFGF to increase proliferation in myoblast cultures. Additionally, CME acted additively to the combination of saturating amounts of bFGF and IGF-I on both C2 and primary myoblast cultures. We also examined additivity of CME with the combination of saturating doses of bFGF, IGF-I, transferrin (Tf), platelet-derived growth factor (PDGF), epidermal growth factor (EGF), adrenocorticotrophin (ACTH), and macrophage colony-stimulating factor (M-CSF). Our data indicate that CME contains Tf, as well as one or more uncharacterized mitogens for myoblasts which are distinct from Tf, the IGFs, bFGF, EGF, PDGF, M-CSF, and ACTH. These uncharacterized mitogens may act independently of known growth factors to stimulate myoblast proliferation, or may act through modulation of known growth factor activities.

Regional injury and the terminal differentiation of satellite cells in stretched avian slow tonic muscle

In the avian stretch model, the application of a weight overload to the humerus induces enlargement of the anterior latissimus dorsi (ALD) muscle and an increase in muscle fiber number which is accompanied by satellite cell activation. Myofiber injury may be an important stimulus to muscle fiber hyperplasia; therefore, light and electron microscopic evaluation was undertaken to determine if myofiber injury occurs in the stretch-enlarged ALD muscle of the adult quail. Autoradiographic studies were used to determine the terminal differentiation of labeled myogenic cells. A weight equal to 10% of body mass was attached to one wing of 27 adult quail and 3 birds were euthanized at 9 intervals of stretch, from 1 to 30 days. Birds were injected with tritiated thymidine at intervals ranging from 1 hr to 3 days prior to euthanization. Labeled nuclei were detected by light microscopic examination and identified by electron microscopy of a serial section. Three regions of the muscle were examined for disorganization of contractile elements, presence of cytoplasmic vacuoles, and/or phagocytic cell infiltration. The percentage of fibers exhibiting one or more of these criterion was significantly greater in the stretched ALD by Days 5 and 7 and declined at Day 10, reaching near control values by Day 14. Myofiber necrosis and phagocytic cell infiltration were only observed in the middle and distal regions of the stretched ALD muscle. Traditional signs of regeneration and repair were observed, including clusters of labeled myoblast-like cells and myotube formation within an existing basal lamina. New myotube formation with labeled central nuclei was also noted in the interstitial space, outside of basal lamina of persisting fibers. Labeled myonuclei were observed in the stretched fibers. These results demonstrate that chronic stretch produces regional injury and fiber degeneration and resultant regeneration in the ALD muscle of the adult quail. This may be an important stimulus for new fiber formation in this model.

Mechanisms of nascent fiber formation during avian skeletal muscle hypertrophy

This study examined two putative mechanisms of new fiber formation in postnatal skeletal muscle, namely longitudinal fragmentation of existing fibers and de novo formation. The relative contributions of these two mechanisms to fiber formation in hypertrophying anterior latissimus dorsi (ALD) muscle were assessed by quantitative analysis of their nuclear populations. Muscle hypertrophy was induced by wing-weighting for 1 week. All nuclei formed during the weighting period were labeled by continuous infusion of 5-bromo-2'-deoxyuridine (BrdU), a thymidine analog, and embryonic-like fibers were identified using an antibody to ventricular-like embryonic (V-EMB) myosin. The number of BrdU-labeled and unlabeled nuclei in V-EMB-positive fibers were counted. Wing-weighting resulted in significant muscle enlargement and the appearance of many V-EMB+ fibers. The majority of V-EMB+ fibers were completely independent of mature fibers and had a nuclear density characteristics of developing fibers. Furthermore, nearly 100% of the nuclei in independent V-EMB+ fibers were labeled. These findings strongly suggest that most V-EMB+ fibers were nascent fibers formed de novo during the weighting period by satellite cell activation and fusion. Nascent fibers were found primarily in the space between fascicles where they formed a complex anastomosing network of fibers running at angles to one another. Although wing-weighting induced an increase in the number of branched fibers, there was no evidence that V-EMB+ fibers were formed by longitudinal fragmentation. The location of newly formed fibers in wing-weighted and regenerating ALD muscle was compared to determine whether satellite cells in the ALD muscle were unusual in that, if stimulated to divide, they would form fibers in the inter- and intrafascicular space. In contrast to wing-weighted muscle, nascent fibers were always found closely associated with necrotic fibers. These results suggest that wing-weighting is not simply another model of regeneration, but rather produces a unique environment which induces satellite cell migration and subsequent fiber formation in the interfascicular space. De novo fiber formation is apparently the principal mechanism for the hyperplasia reported to occur in the ALD muscle undergoing hypertrophy induced by wing-weighting.

Mechanogenetic regulation of transcription

In many biological systems mechanical forces regulate gene expression: in bacteria changes in turgor pressure cause a deformation of the membrane and induce the expression of osmoregulatory genes; in plants gravity regulates cell growth ('geotropism'); in mammals stretching a muscle induces hypertrophy which is accompanied by qualitative changes in protein synthesis. Consequently, the term 'mechanogenetic control' seems to be a suitable common name for all these processes. The mechanism by which mechanical factors modulate transcriptional activity is still unknown. The purpose of this review is to bring together data from different fields in order to obtain a better understanding of the mechanogenetic control of cell growth.

Varying amounts of stretch stimulus regulate stretch-induced muscle hypertrophy in the chicken

1. The effects of different amounts of passive stretch per day and number of days of stretch on muscle hypertrophy in the chicken patagialis (PAT) muscle were determined. 2. Stretch for 24 hr per day (h/d) resulted in a more rapid hypertrophy both on a wet and dry tissue basis (P less than 0.001) than stretch for 4 h/d. 3. Stretch increased PAT weight 43% and 25% in 24 h/d and 4 h/d treatments, respectively, after 10 days of stretch, but by day 25 of stretch there was no difference between treatments. 4. In a second experiment, the PAT muscle was hypertrophied and then the effects of intermittent stretch (4 h/d) on regression of hypertrophy (muscle atrophy) were investigated. 5. Intermittent stretch (4 h/d) for 5 and 10 d significantly (P less than 0.001) inhibited regression of hypertrophied muscle. 6. The results of the present study indicate that stretch-induced hypertrophy can be modulated by varying the amount of stretch applied per day. 7. Intermittent stretch can be used to inhibit the regression which occurs when a continuous stretch stimulus is removed. 8. Intermittent stretch is a useful model for investigating mechanisms of muscle hypertrophy and inhibition of muscle atrophy.

Longitudinal growth of skeletal myotubes in vitro in a new horizontal mechanical cell stimulator

A new computerized mechanical cell stimulator device for tissue cultured cells is described which maintains the cells in a horizontal position during mechanical stretching of up to 400% in substratum length. Mechanical stimulation of myogenic cells in this device initiates several aspects of in vivo skeletal muscle organogenesis not seen in normal static tissue culture environments. Embryonic skeletal muscle cells from avian m. pectoralis are grown in the device attached to the collagen-coated elastic substratum. Dynamic stretching of the substratum in one direction for 3 d at a rate (0.35 mm/h) that stimulates in vivo bone elongation during development causes the myoblasts to fuse into parallel arrays of myotubes which are 2 to 4 times longer than myotubes grown under static culture conditions. This longitudinal myotube growth is accompanied by increased rates of cell proliferation and myoblast fusion. Prestretching the collagen-coated substratum before cell plating also results in increased cell proliferation, myotube orientation, and longitudinal myotube growth. The effects of substratum stretching on myogenesis in this model system thus occur by alterations in the cell's extracellular matrix and not by acting directly on the cells.

Further purification of a fibroblast growth factor-like factor from chick embryo extract by heparin-affinity chromatography

A mitogenic factor which promotes quail myoblast proliferation has been purified some 10(5)-fold from chick embryo extract by a combination of cation-exchange chromatography and heparin-affinity chromatography. The factor is eluted from heparin-Sepharose with 2 M NaCl and is a single-chain polypeptide with an apparent molecular weight of 15,000 to 17,000. It is active at subnanogram level in triggering the proliferation and thereby delaying temporarily fusion of myoblasts. It also stimulates the proliferation of quail fibroblasts in a similar effective concentration range. For both myoblasts and fibroblasts the dose-response to the factor is quantitatively and qualitatively comparable with that of bovine pituitary fibroblast growth factor. These observations strongly suggest that the factor very probably corresponds to chicken fibroblast growth factor or to a closely related molecule(s) and that it is possibly involved in the regulation of myogenesis.

Skeletal muscle growth is stimulated by intermittent stretch-relaxation in tissue culture

Avian pectoralis muscle cells differentiated in vitro are mechanically stimulated by repetitive stretch-relaxation of the cell's substratum using a computerized mechanical cell stimulator device. Initiation of mechanical stimulation increases the efflux of creatine kinase from the cells during the first 8-10 h of activity, but the efflux rate returns to control levels after this time period. Decreased total cell protein content accompanies the temporary elevation of creatine kinase efflux. With continued mechanical stimulation for 48-72 h, total cell protein loss recovers and significantly increases in medium supplemented with serum and embryo extract. Myotube diameters increase and cell hyperplasia occurs in the stimulated cultures. In basal medium without supplements, mechanical activity prevents myotube atrophy but does not lead to cell growth. Mechanically induced growth is accompanied by significant increases in protein synthesis rates. The increases in protein synthesis and accumulation induced by mechanical stimulation are not inhibited by tetrodotoxin but are significantly reduced in basal medium without supplements. Mechanically stimulated cell growth is thus dependent on medium growth factors but independent of electrical activity.

Nascent muscle fiber appearance in overloaded chicken slow-tonic muscle

The application of a weight overload to the humerus of chickens induces a hypertrophy of anterior latissimus dorsi (ALD) muscle fibers. This growth is accompanied by a rapid and almost complete replacement of one slow-tonic myosin isoform, SM-1, by another slow-tonic isoform, SM-2. In addition, a population of small fibers appears mainly in extrafascicular spaces and, concurrently, three additional myosin bands are detected by gel electrophoresis. Five antibodies against myosin heavy chain (MHC) isoforms were selected as immunocytochemical probes to determine the cellular location and nature of these myosins. The antibodies react with ventricular, fast skeletal muscle and either SM-1 or SM-2, or both the slow-tonic MHCs. The antifast and antiventricular antibodies react with myosin present in the 10-day embryonic ALD muscle but do not react with myosin in posthatch ALD muscle. The small fibers in overloaded muscle contain a myosin isoform characteristically expressed during the embryonic stage of ALD muscle development and therefore are named nascent myofibers. Some of the nascent myofibers do not react with the antibody to both slow-tonic MHCs, indicating the lack of the normal adult slow-tonic myosins which are expressed in 10-day embryos. In order to explore the origin of the nascent fibers, an electron microscopic study was performed. Stereological analysis of the existing fibers shows a stimulation of numbers and sizes of satellite cells. In addition, the volume occupied by nonmuscle and undifferentiated cells increases dramatically. Myotube formation with incipient myofibrils is seen in extrafascicular spaces. These data suggest that new muscle fiber formation accompanies hypertrophy in overloaded chicken ALD muscle and the process may involve satellite cell migration.

Purification and identification of transferrin as a major pituitary-derived mitogen for MTW9/PL2 rat mammary tumor cells

Transferrin was identified as a major tissue-derived growth factor for MTW9/PL2 rat mammary tumor cells. Mitogenic activity was assayed by the ability to stimulate the increase in number of MTW9/PL2 cells over 4 d in Dulbecco's modified Eagle's medium containing only 15 mM HEPES, 2 mM glutamine, and 50 micrograms/ml gentamicin. This growth-promoting activity was purified from ammonium sulfate precipitates of phosphate buffered saline extracts of porcine pituitaries using DEAE-Sepharose, chromatofocusing, molecular sieve chromatography and reverse phase high performance liquid chromatography. Pig pituitary mitogen (PPM) migrated as a single band at molecular weight 78,000 on sodium dodecyl sulfate polyacrylamide gel electrophoresis, eluted from chromatofocusing at multiple pH values near 6.3, exhibited an absorption maximum at 465 nm which was diminished by removal of iron, showed a characteristic salmon-pink color in aqueous solution, and was similar in amino acid composition to previously reported values for porcine transferrin. Purified PPM stimulated the growth of MTW9/PL2 cells with mitogenic potency (ED50 = 190 to 280 ng/ml) similar to commercially available human transferrin (ED50 = 160 to 350 ng/ml). We have concluded that using serum-free assay conditions with MTW9/PL2 cells, transferrin was a major source of the mitogenic activity present in extracts of porcine pituitary.

Effects of passive stretch on growth and regression of muscle from chickens of various ages

A non-invasive procedure was used to determine the effect of animal age on the growth response of muscle to passive stretch. Stretch increased patagialis muscle weight 61% in 6-week-old chicks and 34% in 10-month-old chicks, 28-month-old animals had an 18% loss of muscle mass during passive stretch. Removal of the stretch stimulus was followed by a rapid return of patagialis weight to control values in 6-week and 10-month animals, while muscle size of 28-month-old animals had not returned to control levels by 22 days, following removal of the stretch. The stretch-induced changes in muscle wet weight could, in part, be attributed to changes in muscle protein. Total muscle DNA content increased during rapid growth in 6-week- and 10-month-old chickens, and returned to control levels during muscle regression. Muscle hydroxyproline content increased in parallel with increases in muscle mass but did not return to control levels during muscle regression in 6-week-old animals. Results of the present study indicate that there was an effect of animal age on stretch-induced hypertrophy and regression of the patagialis muscle.