Abstract. CE9 is a posterior-tail domain-specific integral plasma membrane glycoprotein of the rat testicular spermatozoon. During epididymal maturation, CE9 undergoes endoproteolytic processing and then redistributes into the anterior-tail plasma membrane domain of the spermatozoon (Petruszak, J. A. M., C. L. Nehme, and J. R. Bartles. 1991. J. Cell. Biol. 114:917-927). We have determined the sequence of CE9 and found it to be a Type Ia transmembrane protein identical to the MRC OX-47 T-cell activation antigen, a member of the immunoglobulin superfamily predicted to have two immunoglobulin-related loops and three asparagine-linked glycans disposed extracellularly. Although encoded by a single gene and mRNA in the rat, the majority of spermatozoal CE9 is of smaller apparent molecular mass than its hepatocytic counterpart due to the under-utilization of sites for asparagine-linked glycosylation. By fluorescence recovery after photobleaching, CE9 was determined to be mobile within the posterior-tail plasma membrane domain of the living rat testicular spermatozoon, thus implying the existence of a regional barrier to lateral diffusion that is presumed to operate at the level of the annulus. Through the development of an in vitro system, the modification of this diffusion barrier to allow for the subsequent redistribution of CE9 into the anterior-tail domain was found to be a time-, temperature-, and energy-dependent process.C ELLS with asymmetrical shapes compartmentalize their integral plasma membrane proteins to morphologically distinguishable surface domains. The mammalian spermatozoon has at least four compositionally distinct plasma membrane domains, corresponding to those covering the anterior and posterior segments of its head and tail (for example see Koehler, 1978;Friend, 1982;Primakoff and Myles, 1983;Holt, 1984). This highly asymmetrical cell compartmentalizes its plasma membrane proteins not only during spermiogenesis, but also through a series of processing and redistribution events that accompany posttesticular maturation in the epididymis, capacitation, and the acrosome reaction Jones et al., 1990;Phelps et al., 1990;Cowan et al., 1991).We recently identified a domain-specific plasma membrane protein of the rat spermatozoon called CE9 (Petruszak et al., 1991). Compartmentalized initially to the posteriortall plasma membrane domain of the testicular spermatozoon, CE9 redistributes into the anterior-tall plasma membrane domain during maturation in the epididymis. This change in localization is preceded by the endoproteolytic Cheryl L. Nehme and Mario M. Cesario contributed equally to this work.Please address reprint requests to Dr. J. R. Bartles, Department of CMS Biology, Northwestern University Medical School, Ward Building, 303 East Chicago Avenue, Chicago, IL 60611.removal of a portion of the amino terminus of the protein.In an effort to learn more about CE9 and its compartmentalization, we have determined the structure of rat CE9, measured its lateral diffusion within the posterior-tall plasma mem...
We used immunoperoxidase histochemistry and confocal immunofluorescence microscopy to examine the events involved in the compartmentalization of CE9 to the posterior-tail plasma membrane domain during spermatogenesis in the rat. We identified two major episodes of spermatogenesis during which CE9 appeared to accumulate in relatively large amounts intracellularly within elements of the secretory pathway. The first episode encompassed cells from preleptotene through early pachytene primary spermatocytes and was evident as intense intracellular labeling of the endoplasmic reticulum and the Golgi complex. The second episode encompassed spermatids in steps 8-12 of spermiogenesis and was evident as intense intracellular labeling of the Golgi complex and smaller vesicular structures observed within the cytoplasm of the spermatid. Between these two episodes, CE9 was detected in considerably reduced amounts. Although present within the Golgi complex and the acrosomic system throughout much of the first half of spermiogenesis, CE9 was not detected on the tail of the spermatid until steps 8-9 of spermiogenesis. Although detected initially in relatively small amounts along the entire length of the tail beginning at steps 8-9, there was no evidence for the presence of relatively large amounts of CE9 on the tail or anywhere else on the surface of the spermatid until after step 11 of spermiogenesis. Between step 11 and steps 13-14 of spermiogenesis, CE9 was observed to accumulate in relatively large amounts on the whole tail coincident with its apparent loss from the Golgi complex. CE9 was observed to then undergo further compartmentalization to the posterior-tail domain sometime between steps 13-14 of spermiogenesis and spermiation. Our results suggest that CE9 is synthesized and enters the secretory pathway throughout much of spermatogenesis, but that the site of accumulation of CE9 varies considerably as a function of development. With respect to the biogenesis of the posterior-tail plasma membrane domain, our results suggest that CE9 is targeted from the Golgi complex to the plasma membrane of the whole tail during mid to late spermiogenesis and then redistributes laterally into the posterior-tail domain coincident with the caudal migration of the annulus late in spermiogenesis. This proposed pathway has a number of important implications for the logistical capabilities of the mammalian spermatid.
Western blotting, immunofluorescence and immunogold electron microscopy were used to examine the compartmentalization, processing and redistribution of the integral plasma membrane protein CE9 on the spermatozoa of rats, mice and hamsters. In each species examined, spermatozoal CE9 was found to undergo endoproteolytic processing followed by a net redistribution from the posterior-tail domain into the anterior-tail domain of the plasma membrane during epididymal maturation. Compared to spermatozoa of the rat and mouse, those of the hamster were found to express a greater proportion of their CE9 within the anterior-tail plasma membrane domain at all stages of maturation. As a consequence, CE9 was judged to be a suitable marker for two different spermatozoal plasma membrane domains: the posterior-tail plasma membrane domain (spermatozoa from the testis and caput epididymidis of the rat and mouse) and the anterior-tail domain (spermatozoa from the cauda epididymidis of the hamster). Immunogold electron microscopy was used to pinpoint the positions of the boundaries of these CE9-containing plasma membrane domains at a high level of resolution. In each case, the position of the CE9 domain boundary was found to be strongly correlated with that of the subplasmalemmal electron-dense ring known as the annulus. The precise spatial relationship between the CE9 domain boundary and the annulus was, however, found to differ significantly among species and/or as a function of maturation.
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