Rosetta Rossi

The effect of ageing and immobilization on structure and function of human skeletal muscle fibres

Biopsy samples were taken from vastus lateralis muscle of seven young (YO, age 30.2 ± 2.2 years), and seven elderly (EL, age 72.7 ± 2.3 years) subjects and two elderly subjects whose right leg had been immobilized for 3.5 months (EL‐IMM, ages 70 and 75). The following main parameters were studied: (1) myosin heavy chain (MHC) isoform distribution of the samples, determined by SDS‐PAGE; (2) cross‐sectional area (CSA), specific force (Po/CSA) and maximum shortening velocity (Vo) of a large population (n= 593) of single skinned muscle fibres, classified on the basis of MHC isoform composition determined by SDS‐PAGE; (3) actin sliding velocity (Vf) on pure myosin isoforms determined by in vitro motility assays; (4) myosin concentration in single fibres determined by quantitative SDS‐PAGE. MHC isoform distribution was shifted towards fast isoforms in EL and to a larger extent in EL‐IMM. In EL and, more consistently, in EL‐IMM we observed a higher percentage of hybrid fibres than in YO, and noted the presence of MHC‐neonatal and of unusual hybrid fibres containing more than two MHC isoforms. Po/CSA significantly decreased in type 1 and 2A fibres in the order YO → EL → EL‐IMM. Vo of type 1 and 2A fibres was significantly lower in EL and higher in EL‐IMM than in YO, i.e. immobilization more than counteracted the age‐dependent decrease in Vo. The latter phenomenon was not observed for Vf. Vf on myosin 1 was lower in both EL and EL‐IMM than in YO. Vf on myosin 2X was lower in EL than in YO, and a similar trend was observed for myosin 2A. Myosin concentration decreased in type 1 and 2A fibres in the order YO → EL → EL‐IMM and was linearly related to the Po/CSA values of corresponding fibre types from the same subjects. The experiments suggest that (1) myosin concentration is a major determinant of the lower Po/CSA of single fibres in ageing and especially following immobilization and (2) ageing is associated with lower Vo of single fibres due to changes in the properties of myosin itself, whereas immobilization is associated with higher Vo in the absence of a change in myosin function.

Orthologous myosin isoforms and scaling of shortening velocity with body size in mouse, rat, rabbit and human muscles

Maximum shortening velocity (V0) was determined in single fibres dissected from hind limb skeletal muscles of rabbit and mouse and classified according to their myosin heavy chain (MHC) isoform composition. The values for rabbit and mouse V0 were compared with the values previously obtained in man and rat under identical experimental conditions. Significant differences in V0 were found between fibres containing corresponding myosin isoforms in different species: as a general rule for each isoform V0 decreased with body mass. Myosin isoform distributions of soleus and tibialis anterior were analysed in mouse, rat, rabbit and man: the proportion of slow myosin generally increased with increasing body size. The diversity between V0 of corresponding myosin isoforms and the different myosin isoform composition of corresponding muscles determine the scaling of shortening velocity of whole muscles with body size, which is essential for optimisation of locomotion. The speed of actin translocation (Vf) in in vitro motility assay was determined with myosins extracted from single muscle fibres of all four species: significant differences were found between myosin isoforms in each species and between corresponding myosin isoforms in different species. The values of V0 and Vf determined for each myosin isoform were significantly correlated, strongly supporting the view that the myosin isoform expressed is the major determinant of maximum shortening velocity in muscle fibres.

Specific contributions of various muscle fibre types to human muscle performance: an in vitro study

Human skeletal muscle fibres can be divided in five groups: 1, 1-2A, 2A, 2A-2B and 2B, by using myosin heavy chain (MHC) isoforms as molecular markers. This study aimed to define the contribution of each fibre type to the contractile performance of human muscles. Single fibre segments were dissected from bioptic samples of vastus lateralis and chemically skinned. Force-velocity properties, including isometric tension (P0), maximal shortening velocity (Vmax), maximum power output (Wmax) and the velocity at which Wmax is reached (Vopt), were determined at maximum calcium activation. Among these parameters Wmax showed the largest range of variation: about nine times between 2B and slow fibres. Vopt also showed large (about four times) and significant variations between fibre types. Force development at submaximum calcium activation was studied and force-pCa curves were obtained for each fibre type. Calcium sensitivity was greater in 2B than in 2A and in slow fibres. The slope of the force-pCa curve was greater in fast than in slow fibres. At the end of the experiment the MHC isoform composition of each fibre segment was determined by gel electrophoresis. The functional properties of each fibre type are discussed in the light of the motor unit recruitment mechanism to understand their possible physiological role.

Skeletal muscle hypertrophy and structure and function of skeletal muscle fibres in male body builders

Needle biopsy samples were taken from vastus lateralis muscle (VL) of five male body builders (BB, age 27.4 ± 0.93 years; mean ±s.e.m.), who had being performing hypertrophic heavy resistance exercise (HHRE) for at least 2 years, and from five male active, but untrained control subjects (CTRL, age 29.9 ± 2.01 years). The following determinations were performed: anatomical cross‐sectional area and volume of the quadriceps and VL muscles in vivo by magnetic resonance imaging (MRI); myosin heavy chain isoform (MHC) distribution of the whole biopsy samples by SDS‐PAGE; cross‐sectional area (CSA), force (Po), specific force (Po/CSA) and maximum shortening velocity (Vo) of a large population (n= 524) of single skinned muscle fibres classified on the basis of MHC isoform composition by SDS‐PAGE; actin sliding velocity (Vf) on pure myosin isoforms by in vitro motility assays. In BB a preferential hypertrophy of fast and especially type 2X fibres was observed. The very large hypertrophy of VL in vivo could not be fully accounted for by single muscle fibre hypertrophy. CSA of VL in vivo was, in fact, 54% larger in BB than in CTRL, whereas mean fibre area was only 14% larger in BB than in CTRL. MHC isoform distribution was shifted towards 2X fibres in BB. Po/CSA was significantly lower in type 1 fibres from BB than in type 1 fibres from CTRL whereas both type 2A and type 2X fibres were significantly stronger in BB than in CTRL. Vo of type 1 fibres and Vf of myosin 1 were significantly lower in BB than in CTRL, whereas no difference was observed among fast fibres and myosin 2A. The findings indicate that skeletal muscle of BB was markedly adapted to HHRE through extreme hypertrophy, a shift towards the stronger and more powerful fibre types and an increase in specific force of muscle fibres. Such adaptations could not be fully accounted for by well known mechanisms of muscle plasticity, i.e. by the hypertrophy of single muscle fibre (quantitative mechanism) and by a regulation of contractile properties of muscle fibres based on MHC isoform content (qualitative mechanism). Two BB subjects took anabolic steroids and three BB subjects did not. The former BB differed from the latter BB mostly for the size of their muscles and muscle fibres.

Fast fibres in a large animal: fibre types, contractile properties and myosin expression in pig skeletal muscles

SUMMARY Little is known about the influence of Myosin Heavy Chain (MHC) isoforms on the contractile properties of single muscle fibres in large animals. We have studied MHC isoform composition and contractile properties of single muscle fibres from the pig. Masseter, diaphragm, longissimus, semitendinosus, rectractor bulbi and rectus lateralis were sampled in female pigs (aged 6 months, mass 160 kg). RT-PCR, histochemistry, immunohistochemistry and gel electrophoresis were combined to identify and separate four MHC isoforms: MHC-slow and three fast MHC (2A, 2X, 2B). Maximum shortening velocity (Vo) and isometric tension (Po) were measured in single muscle fibres with known MHC isoform composition. Six groups of fibres (pure: slow, 2A, 2X and 2B, and hybrid: 2A-2X and 2X-2B) with large differences in Vo and Po were identified. Slow fibres had mean Vo=0.17±0.01 length s-1 and Po=25.1±3.3 mN mm-2. For fast fibres 2A, 2X and 2B, mean Vo values were 1.86±0.18, 2.55±0.19 and 4.06±0.33 length s-1 and mean Po values 74.93±8.36, 66.85±7.58 and 32.96±7.47 mN mm-2, respectively. An in vitro motility assay confirmed that Vo strictly reflected the functional properties of the myosin isoforms. We conclude that pig muscles express high proportions of fast MHC isoforms, including MHC-2B, and that Vo values are higher than expected on the basis of the scaling relationship between contractile parameters and body size.

Speeds of Actin Translocation in Vitro by Myosins Extracted from Single Rat Muscle Fibres of Different Types

As skeletal muscle fibres mostly express a single myosin isoform, they are a potential source of pure myosin isoforms. A technique is described that allows extraction and identification of pure myosin isoforms from single fibres, and testing of such myosins in an in vitro motility assay (IVMA). The results show that the extraction procedure does not alter myosin function and support the view that single fibres are reliable sources of purified myosin isoforms for IVMA.

Functional diversity between orthologous myosins with minimal sequence diversity

To define the structural differences that are responsible for the functional diversity between orthologous sarcomeric myosins, we compared the rat and human β/slow myosins. Functional comparison showed that rat β/slow myosin has higher ATPase activity and moves actin filaments at higher speed in in vitro motility assay than human β/slow myosin. Sequence analysis shows that the loop regions at the junctions of the 25 and 50 kDa domains (loop 1) and the 50 and 20 kDa domains (loop 2), which have been implicated in determining functional diversity of myosin heavy chains, are essentially identical in the two orthologs. There are only 14 non-conservative substitutions in the two myosin heavy chains, three of which are located in the secondary actin-binding loop and flanking regions and others correspond to residues so far not assigned a functional role, including two residues in the proximal S2 domain. Interestingly, in some of these positions the rat β/slow myosin heavy chain has the same residues found in human cardiac α myosin, a fast-type myosin, and fast skeletal myosins. These observations indicate that functional and structural analysis of myosin orthologs with limited sequence diversity can provide useful clues to identify amino acid residues involved in modulating myosin function.

Actin sliding velocity on pure myosin isoforms from dystrophic mouse muscles

Duchenne muscular dystrophy (DMD) is a genetic disease characterized by skeletal muscle wasting and atrophy. Recent evidence suggests that the impaired skeletal muscle performance in DMD is not solely dependent on a loss of contractile muscle mass. In this study the myosin motor function of mdx and control (wildtype, WT) mice was compared using pure myosin isoforms in an “in vitro motility assay” (IVMA). Actin sliding velocity (Vf) on myosin 2B extracted from single muscle fibers of gastrocnemius muscles was significantly lower in mdx mice (3.48 ± 0.13 μm/s, n = 18) than in WT mice (4.02 ± 0.19 μm/s, n = 10). No difference in Vf was found between myosin 1 extracted from soleus muscles of mdx (0.84 ± 0.04 μm/s, n = 13) and of WT (0.89 ± 0.04 μm/s, n = 10). The results suggest that the dystrophic process alters myosin molecular function, and this contributes to the functional impairment in dystrophic muscles. Muscle Nerve 40: 249–256, 2009