Post-binding events in insulin action

Different mechanisms of increased proteolysis in atrophy induced by denervation or unweighting of rat soleus muscle

Mechanisms of accelerated proteolysis were compared in denervated and unweighted (by tail-cast suspension) soleus muscles. In vitro and in vivo proteolysis were more rapid and lysosomal latency was lower in denervated than in unweighted muscle. In vitro, lysosomotropic agents (eg, chloroquine, methylamine) did not lessen the increase in proteolysis caused by unweighting, but abolished the difference in proteolysis between denervated and unweighted muscle. Leucine methylester, an indicator of lysosome fragility, lowered latency more in denervated than in unweighted muscle. 3-Methyladenine, which inhibits phagosome formation, increased latency similarly in all muscles tested. Mersalyl, a thiol protease inhibitor, and 8-(diethylamino)octyl-3,4,5-trimethoxybenzoate hydrochloride (TMB-8), which antagonizes sarcoplasmic reticulum release of Ca2+, reduced accelerated proteolysis caused by unweighting without diminishing the faster proteolysis due to denervation. Calcium ionophore (A23187) increased proteolysis more so in unweighted than control muscles whether or not Ca2+ was present. Different mechanisms of accelerated proteolysis were studied further by treating muscles in vivo for 24 hours with chloroquine or mersalyl. Chloroquine diminished atrophy of the denervated but not the unweighted muscle, whereas mersalyl prevented atrophy of the unweighted but not of the denervated muscle, both by inhibiting in vivo proteolysis. These results suggest that (1) atrophy of denervated, but not of unweighted, soleus muscle involves increased lysosomal proteolysis, possibly caused by greater permeability of the lysosome, and (2) cytosolic proteolysis is important in unweighting atrophy, involving some role of Ca2(+)-dependent proteolysis and/or thiol proteases.

Insulin resistance of uremia

Glucose intolerance is a nearly universal finding in patients with chronic renal failure and in animal models of uremia. The glucose intolerance results from impaired insulin-mediated glucose disposal by muscle, adipose, and liver tissue. Insulin binding by these tissues is not reduced. Rather, several defects exist in the postreceptor cascade of insulin action. Although impaired insulin-mediated glucose uptake and metabolism occur, the primary defect and causative agent are not established. The purpose of the present article is to review recent literature on the potential mechanisms underlying the insulin resistance of chronic renal failure.

Effects of lutropin (LH) receptor internalization and recycling on the apparent numbers of LH receptors in rat testis Leydig cells at different temperatures

The effect of different temperatures on the Scatchard analysis of binding studies with 125I-hCG and intact rat testis Leydig cells has been investigated. The results show that at temperatures greater than 4 degrees C an overestimation of the number of receptors/cell is likely to occur. A one-site analysis of the data gives values of 13,573, 61,924 and 3802 LH receptors/cell at 34 degrees C, 21 degrees C and 4 degrees C respectively. At 34 degrees C and 21 degrees C (but not at 4 degrees C) a two-site analysis of the data is possible, giving similar high affinity binding components at both temperatures (KD 1 X 10(-10) M) but with dissimilar low affinity binding components (34 degrees C, 2.17 X 10(-9) M and 21 degrees C, 6.3 X 10(-8) M). The calculated total number of LH receptors using a two-site analysis at 21 degrees C is equal to 114,766 receptors/cell, and at 34 degrees C it is 37,987 receptors/cell. It is proposed that the differences in the level of binding at different temperatures and the associated changes in the value of KD, reflect the temperature sensitivity of the endocytic pathway of the 125I-hCG/LH receptor complex within the rat testis Leydig cell. From previous studies it is known that at 34 degrees C and 21 degrees C, a large part of the cell-associated hormone is not receptor bound but rather it represents 'processed' hormone before it is released from the cell. At 4 degrees C the cell-associated 125I-hCG remains bound only to cell surface LH receptors and thus gives a more accurate measure of total receptor numbers/cell.