The metabolic properties of brown adipose tissue (BAT), liver, and skeletal muscles were compared in lean and obese diabetic SHR/N-cp rats (a new model of type II diabetes) to test whether the severe insulin resistance of obese animals is specifically associated with a thermogenic defect in BAT. The respiratory response of brown adipocytes to norepinephrine and to agents bypassing the adenylate cyclase complex (dibutyryl cyclic AMP and palmitate) was decreased by two-thirds in obese rats, thereby indicating the presence of a major postreceptor defect. Significantly, total BAT cytochrome oxidase activity, uncoupling protein content, and mitochondrial guanosine 5'-diphosphate binding (3 indexes of BAT thermogenic capacity) were also decreased by two-thirds. The specific activities of these parameters expressed per total BAT mitochondrial protein were not altered either. This indicates that the total number of mitochondria per cell is decreased in BAT of obese rats. In contrast, total tissue cytochrome oxidase activity, protein content, and DNA content all increased by two to three times in the liver of obese SHR/N-cp rats, but these parameters remained unchanged in skeletal muscles (vastus lateralis and soleus). Such a remarkable liver hypertrophy may have occurred as a consequence of the persistent hyperphagia-hyperinsulinemia of obese rats that induced a hyperplasia and/or a hepatocyte polyploidization. This observation together with the fact that daily energy expenditure associated with food intake was markedly increased in obese rats (representing as much as 25% of the total energy expenditure) strongly suggests that the liver plays a major role in energy balance in these animals. It is concluded that there is a specific regression of mitochondria in BAT, but not in other important oxidative tissues (liver and skeletal muscles), of obese SHR/N-cp rats. With the consideration that insulin deficiency in streptozotocin-induced diabetic rats (a model of type I diabetes) similarly decreases total BAT cytochrome oxidase activity and uncoupling protein content, it is suggested by analogy that severe insulin resistance (associated with diabetes) in obese spontaneously hypertensive rats represents a major factor leading to mitochondrial regression in BAT.
