Characteristics of renin release from isolated superfused glomeruli in vitro

Abstract

1. A method is described for studying renin release from superfused rat glomeruli following their rapid isolation by a magnetic iron-oxide technique. 2. Microscopically selected glomeruli were free of tubular components. Some possessed vascular pole protrusions of up to 20 mum, unrelated to renin content. 3. Renin content of 102 batches, each of 400 glomeruli, was 1.34 plus or minus 0.08 times 10-4 Goldblatt hog units per 100 glomeruli (plus or minus S.E. of mean). Different osmolarities (305, 355 and 400 m-osmole/1.), sodium concentrations (110 and 135 mM) and buffer compositions of the preparation solution did not alter this value. Renin content per glomerulus in intact kidney was 100-fold higher. 4. At 30 degrees C the contained juxtaglomerular cells released renin at consistent but decreasing rates over 4-6 hr. Initial release rate in 110 mM sodium, 305 m-osmole/1. solutions were 0.86 plus or minus 0.068 times 10-6 units per 100 glomeruli per 30 min (plus or minus S.E. of mean, n = 42) or 0.546 plus or minus 0.046 percent of content per 30 min. In 135 mM sodium, 305 m-osmole/1. solutions, release was 2.4-fold higher (P less than 0.001) and remained elevated for at least 3 hr. When related to renin content per glomerulus resting release rate in vitro was higher by at most one order of magnitude than calculated in vivo values. 5. Release was augmented by gentle physical agitation of the glomeruli. 6. Release rate was inversely ralated to temperature. On reducing temperature from 30 degrees C, release increased 2.6-fold at 20 degrees C and 6.7-fold at 10 degrees C (P less than 0.001, n = 11). The response was reversible. 7. 3 mM sodium cyanide plus 3 mM sodium iodoacetate caused a variable release of renin associated with depletion of content within 4 hr. The response was progressive and reached a peak after 60 min. 8. Sensitivity of renin release to temperature and metabolic blockade indicates that energy is required for retention of renin by the cell. This, together with the release observed with increased sodium concentration at constant osmolarity, suggests a dependence of renin release upon the mechanism controlling the volume of the juxtaglomerular cell or its organelles.