alpha-L-Fucosidase (alpha-fucosidase) is the most active of a number of glycosidases measured in rat epididymal sperm through use of artificial 4-methylumbelliferyl substrates. In addition, enzyme activity can be detected in purified populations of testicular germ cells; in comparison to round spermatids, caput epididymal sperm show at least a 1.8-fold increase in alpha-fucosidase activity per cell. Metabolic labeling of cultured testicular germ cells, followed by immunoprecipitation and SDS-PAGE, reveals synthesis of alpha-fucosidase as a polypeptide of 54 kDa in pachytene spermatocytes and round spermatids but no synthesis in condensing spermatids. This polypeptide is N-glycosylated but does not undergo further processing as determined by pulse/chase labeling and treatment with endoglycosidase H. In contrast, the alpha-fucosidase synthesized by cultured clone 9 cells (a rat liver-derived cell line) undergoes processing from a 54-kDa precursor to a slightly larger intermediate centered at 56 kDa on SDS-PAGE (via carbohydrate modification) and finally to a 52-kDa mature polypeptide. Immunoblotting confirms the presence of the 54-kDa form of alpha-fucosidase in testicular germ cells and shows the existence of a 52-kDa mature polypeptide in epididymal sperm. In addition, immunoreactive polypeptide is more prominent in caput epididymal sperm preparations; this is consistent with the increase in enzyme activity. In the absence of alpha-fucosidase synthesis beyond the round spermatid stage of development, it appears that alpha-fucosidase may be acquired from the luminal fluid by sperm during transit through the excurrent duct system. This hypothesis is supported by evidence that metabolically labeled cultured epididymal epithelial cells synthesize and secrete into culture medium an immunoprecipitable 58-kDa alpha-fucosidase polypeptide. Analysis of sperm isolated from the first part of the caput epididymis indicates that both acquisition and processing of sperm-associated alpha-fucosidase takes place prior to or concomitant with arrival of sperm in the epididymis.
A number of hsp70-like proteins are associated with developing male germ cells. One of these molecules, P70, is not sensitive to heat stress and is germ cell-specific, and its expression is developmentally regulated. We have characterized the association of the rat P70(rP70) with differentiating germ cells in the testis and with posttesticular sperm. An antibody originally raised against human sperm proacrosin (designated C3; Sigel et al., 1987: J Reprod Immunol 11:307-319) was found to immunostain rP70 by immunoblot analysis and was used in subsequent studies of the rP70 molecule. The C3 antibody reacted with P70 isoforms in rat, human, mouse, guinea pig, boar, and rooster testicular homogenates. In the developing rat testis, abundant rP70 protein levels were first detected on postnatal day 22, with upregulation to adult levels occurring after postnatal day 28. Purified populations of adult rat pachytene spermatocytes, round spermatids, and elongating spermatids, isolated by unit gravity velocity sedimentation, all expressed rP70. Posttesticular sperm exhibited a loss of the rP70 molecule; caput epididymal sperm were weakly immunoreactive for rP70, but no immunoreactivity was observed in either cauda epididymal sperm or epididymal fluid. In contrast to human ejaculated sperm, rat ejaculated sperm did not express rP70. The loss of P70 from rat posttesticular sperm may reflect species-specific differences in P70 functions, which are thought to include a role in the structural modifications that occur during germ cell differentiation.
Urate oxidase, an enzyme involved in purine catabolism, comprises the crystalline core of rat liver peroxisomes. An affinity-purified monospecific antibody was developed to study the expression of urate oxidase protein levels. Immunoreactive urate oxidase was not detectable in prenatal liver; however, it is present at low levels after birth until approximately day 15 (postnatal age); expression sharply increases just prior to day 20, after which the enzyme is maintained at adult levels. This pattern of expression was similar to that of another peroxisomal enzyme, catalase; these developmental increases reflect the increase in peroxisomal number. Administration of exogenous glucocorticoid hormone to 10-day-old rats resulted in a precocious rise (2.5-fold) in urate oxidase levels. Adrenalectomy at 10 days of age did not cause decreased levels in the fourth week of life. In adult animals, while exogenous glucocorticoid administration did not influence urate oxidase levels, adrenalectomy at 60 days of age decreased urate oxidase levels to 40 percent of control levels. Subsequent administration of exogenous glucocorticoid hormone restored urate oxidase to normal levels. Parallel studies of catalase levels indicate that this glucocorticoid-sensitive response is not generalized for all peroxisomal proteins. Our results suggest that peroxisomes proliferate during early postnatal development, but after this process is complete, the biogenesis of individual peroxisomal proteins may be independently regulated.
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