Cytoplasm-to-myonucleus ratios in plantaris and soleus muscle fibres following hindlimb suspension

In multinucleated skeletal muscle fibres the size of the cytoplasmic volume-to-myonucleus ratio is related to the myosin heavy chain phenotype, with the ratio being larger in those fibres expressing the fast myosin heavy chain phenotype. It is unknown however, whether this ratio is modulated during muscle fibre adaptation, such as that which occurs following muscle unloading. In this study the relationship between cross sectional area, myonuclear number and myosin type, in single fibres from the plantaris and soleus muscles of adult rats following 28 days of hindlimb suspension was examined. Each fibre was cut transversely into two segments; one segment was used for immunohistochemical identification of myosin type, the other for determination of cross sectional area and myonuclei number. Single fibre analysis revealed significant atrophy of both plantaris fast and soleus slow fibres; the mean cross sectional area (mu m(2)) of these fibres, 3104 +/- 183 and 2082 +/- 107 (mean +/- SE), being 70 and 45%, respectively, of control means. The decreases in cross sectional area were not accompanied by corresponding decreases in the number of myonuclei (myonuclei/mm); in plantaris fast fibres the mean myonuclei counts were within the control range (88 +/- 8 (hindlimb suspension), 76 +/- 7 (control)), in soleus slow fibres the counts were significantly increased (185 +/- 12 (hindlimb suspension), 154 +/- 11 (control)). The changes resulted in a significant decrease in the cytoplasmic volume-to-myonucleus ratio (mu m(3) x 10(3)) for both fibre types; the mean ratios of 39 +/- 3 and 12 +/- 1, were 60% and 36% of control means for the plantaris fast and soleus slow fibres, respectively. These results indicate that following hindlimb suspension atrophy of muscle fibres the myonuclei numbers remain constant or increase and, hence, the effective cytoplasmic-to-myonucleus ratio is decreased. Further, the described changes are significantly greater in soleus slow than plantaris fast fibres.