THE RELATIONSHIP BETWEEN THE STRUCTURE AND ACTIVITY OF RAT SKELETAL MUSCLE MITOCHONDRIA AFTER THYROIDECTOMY AND THYROID HORMONE TREATMENT

doi:10.1083/jcb.26.2.555

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THE RELATIONSHIP BETWEEN THE STRUCTURE AND ACTIVITY OF RAT SKELETAL MUSCLE MITOCHONDRIA AFTER THYROIDECTOMY AND THYROID HORMONE TREATMENT

R. Gustafsson ¹, J. R. Tata ¹, O. Lindberg ¹, and L. Ernster ¹

¹ From the Wenner-Gren Institute, Stockholm, Sweden.

Dr. Tata's present address is the National Institute for Medical Research, London, England

The fine structure of rat gastrocnemius muscle fibers has beenstudied after changes were induced in the basal metabolic rate(BMR) by thyroidectomy and L-thyroxine administration underanabolic conditions. Biochemical analysis of skeletal musclemitochondrial respiration and phosphorylation from the sametissue preparations has been summarized, details having beenpublished earlier (3). As estimated from electron micrographs,the total amount of mitochondria from thyroidectomized animalswas enlarged 1.5 times over that from normal controls. The totalamount of mitochondria from thyroidectomized or normal animalsmade hypermetabolic with thyroxine was increased 2.5 to 3.5times over that from their corresponding controls. In all cases,there was an increase in the mitochondrial population and theprofile ratio of cristae to matrix was also considerably increased,thus indicating both relative and absolute enlargements of theentire surface of the cristae per unit fiber. The major structuralchanges persisted for at least 3 weeks after the cessation ofthyroxine treatment, by which time the elevated mitochondrialrespiratory and phosphorylative activity had declined to normalvalues. The hypertrophy and increase in mitochondrial populationwas more prominent in the perinuclear and subsacrolemmic regionsnear blood vessels than in the interstices of the fibrils. Thevery long interfibrillar mitochondria found in both the hypo-and hypermetabolic tissues are more likely to be derived fromoutgrowths of the original mitochondria rather than from a fusionof smaller ones. These findings are compatible with the ideasexpressed elsewhere (see 1, 3, 10) that, under conditions closeto the physiological, thyroid hormones control mitochondrialmetabolic activity by a subtle alteration in mitochondrial compositionwith respect to their respiratory and phosphorylative constituents.The possible application of using thyroid hormones in the studyof biogenesis of mitochondria and the synthesis of mitochondrialconstituents are discussed.

Submitted on December 21, 1964

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