Abstract
Melanosomes and lysosomes share several structural and biosynthetic properties. Therefore, a large number of mouse pigment mutants were tested to determine whether genes affecting melanosome structure or function might also affect the lysosome. Among 31 mouse pigment mutants, six had 1.5- to 2.5- fold increased concentrations of kidney β-glucuronidase. Three mutants, pale ear, pearl and pallid, had a generalized effect on lysosomal enzymes since there were coordinate increases in kidney β-galactosidase and α-mannosidase. The effects of these three mutations are lysosome specific since rates of kidney protein synthesis and activities of three nonlysosomal kidney enzymes were normal. Also, the mutants are relatively tissue specific in that all had normal liver lysomal enzyme concentrations.—A common dysfunction in all three mutants was a lowered rate of lysosomal enzyme secretion from kidney into urine. While normal C57BL/6J mice daily secreted 27 to 30% of total kidney β-glucuronidase and β-galactosidase, secretion of these two enzymes was coordinately depressed to 1 to 2%, 8 to 9% and 4 to 5% of total kidney enzyme in the pale-ear, pearl and pallid mutants, respectively. Although depressed lysosomal enzyme secretion is the major pigment mutant alteration, the higher lysomal enzyme concentrations in pearl and pallid may be partly due to an increase in lysosomal enzyme synthesis. In these mutants kidney glucuronidase synthetic rate was increased 1.4- to 1.5-fold.—These results suggest that there are several critical genes in mammals that control the biogenesis, processing and/or function of related classes of subcellular organelles. The mechanism of action of these genes is amenable to further analysis since they have been incorporated into congenic inbred strains of mice.
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Selected References
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