AUTORADIOGRAPHIC STUDIES OF SYNTHESIS AND INTRACELLULAR MIGRATION OF GLYCOPROTEINS IN THE RAT ANTERIOR PITUITARY GLAND

The incorporation of [³H]fucose in the somatotrophic and gonadotrophic cells of the rat adenohypophysis has been studied by electron microscope autoradiography to determine the site of synthesis of glycoproteins and to follow the migration of newly synthesized glycoproteins. The pituitaries were fixed 5 min, 20 min, 1 h, and 4 h after the in vivo injection of [³H]fucose and autoradiographs analyzed quantitatively. At 5 min after [³H]fucose administration, 80–90% of the silver grains were localized over the Golgi apparatus in both somatotrophs and gonadotrophs. By 20 min, the Golgi apparatus was still labeled and some radioactivity appeared over granules. At 1 h and 4 h, silver grains were found predominantly over secretory granules. The kinetic analysis showed that in both protein-secreting cells (somatotrophs) and glycoprotein-secreting cells (gonadotrophs), the glycoproteins have their synthesis completed in the Golgi apparatus and migrate subsequently to the secretory granules. It is concluded from these in vivo studies that glycoproteins which are not hormones are utilized for the formation of the matrix and/or of the membrane of the secretory granules. The incorporation of [³H]fucose in gonadectomy cells (hyperstimulated gonadotrophs) was also studied in vitro after pulse labeling of pituitary fragments in medium containing [³H]fucose. The incorporation of [³H]fucose was localized in both the rough endoplasmic reticulum (ER) and the Golgi apparatus. Later, the radioactivity over granules increased while that over the Golgi apparatus decreased. The concentration of silver grains over the dilated cisternae of the rough ER was not found to be modified at the longest time intervals studied.     

Quantitative determination of the intracellular fate of internalized plasma membrane in dissociated pituitary prolactin cells utilizing a radioiodinated cationic ferritin probe (CFI*) and electron microscopic autoradiography

Dissociated anterior pituitary cells derived from estrogen-treated female rats were incubated with radioiodinated cationic ferritin (CFI) for 2 min and subsequently in the absence of CFI for varying periods of time up to 3 hr in order to quantitate, using electron microscopic autoradiography, the distribution of retrieved plasma membrane in these cells. Following a 2-min incubation with CFI, autoradiographic grains were found to be associated almost exclusively with the plasma membrane. With increasing periods of incubation in the absence of CFI, grain-density analysis revealed increasing levels of CFI in multiple intracellular organelles. The levels of CFI were greatest for the lysosomes, intermediate for the mature secretory granules, and least for the Golgi cisternae and immature secretory granules. These findings are consistent with the idea that a portion of the retrieved plasma membrane is degraded in lysosomes and that the remainder is recycled to organelles comprising the secretory pathway to be reutilized in successive waves of the secretory cycle.     

Intracellular transport and storage of secretory proteins in relation to cytodifferentiation in neoplastic pancreatic acinar cells

The pancreatic acinar carcinoma established in rat by Reddy and Rao (1977, Science 198:78-80) demonstrates heterogeneity of cytodifferentiation ranging from cells containing abundant well- developed secretory granules to those with virtually none. We examined the synthesis intracellular transport and storage of secretory proteins in secretory granule-enriched (GEF) and secretory granule-deficient (GDF) subpopulations of neoplastic acinar cells separable by Percoll gradient centrifugation, to determine the secretory process in cells with distinctly different cytodifferentiation. The cells pulse-labeled with [3H]leucine for 3 min and chase incubated for up to 4 h were analyzed by quantitative electron microscope autoradiography. In GEF neoplastic cells, the results of grain counts and relative grain density estimates establish that the label moves successively from rough endoplasmic reticulum (RER) leads to the Golgi apparatus leads to post-Golgi vesicles (vacuoles or immature granules) leads to mature secretory granules, in a manner reminiscent of the secretory process in normal pancreatic acinar cells. The presence of approximately 40% of the label in association with secretory granules at 4 h postpulse indicates that GEF neoplastic cells retain (acquire) the essential regulatory controls of the secretory process. In GDF neoplastic acinar cells the drainage of label from RER is slower, but the peak label of approximately 20% in the Golgi apparatus is reached relatively rapidly (10 min postpulse). The movement of label from the Golgi to the post- Golgi vesicles is evident; further delineation of the secretory process in GDF neoplastic cells, however, was not possible due to lack of secretory granule differentiation. The movement of label from RER leads to the Golgi apparatus leads to the post-Golgi vesicles suggests that GDF neoplastic cells also synthesize secretory proteins, but to a lesser extent than the GEF cells. The reason(s) for the inability of GDF cells to concentrate and store exportable proteins remain to be elucidated.     

High resolution analysis of the secretory pathway in mammotrophs of the rat anterior pituitary

The secretory process in pituitary mammotrophs was analyzed by quantitative electron microscope autoradiography. Dispersed pituitary cells from estrogen-treated female rats were subjected to pulse- labeling with [3H]leucine (5 min) followed by a chase incubation of up to 4 h. Autoradiograms were prepared using fine-grained emulsion (Kodak 129-01), and analyzed using a three-step "mask analysis' procedure: (a) the distribution of autoradiographic grains is determined as in a simple grain density analysis; (b) masks (transparent overlays) are used to generate expected grains from assumed sources; and (c) a computer program compares these two distributions and varies the expected distribution to match the observed distribution, thereby identifying the radioactive sources in the tissue. The overall route of intracellular transport of prolactin from rough endoplasmic reticulum (ER) leads to Golgi complex leads to immature secretory granules leads to mature secretory granules was as established in previous studies. However, by use of the high resolution emulsion and method of analysis, the precision with which label could be localized within individual source compartments was much greater and the time resolution was much sharper than achieved previously using Ilford L4 emulsion and simple grain density analysis. The main new findings were as follows: (a) the ER was essentially drained of radioactivity by 30 min, the Golgi complex by 1 h, and the immature secretory granules by 2h postpulse. This indicates that the secretory product (prolactin) is rapidly and efficiently transported out of these compartments. (b) approximately 30% of the total radioactivity remains located in the ground cytoplasm over the entire postpulse period examined (up to 4 h), and by 30 min postpulse the grain density in the ground cytoplasm exceeded that of the ER. This indicates the ability to resolve ER-associated label (presumably associated mainly with secretory products) from the cytoplasmic label (presumably associated with nonsecretory proteins). (c) the specific activity of immature secretory granules was much greater than previously appreciated; at 1 h postpulse it was greater than 200 times that of the adjacent Golgi complex cisternae. This large dynamic range in observed grain density demonstrates the ability to effectively correct for radiation spread and thus to detect with great accuracy high concentration of label even from very small structures (20-100 nm) which constitute a small percentage (less than 1%) of the total cell area.     

Glycosylation process in gonadotrophs: a quantitative electron microscope autoradiographic study with labeled glucosamine

Incorporation of [3H]glucosamine into dispersed anterior pituitary cells was studied by electron microscope autoradiography. Gonadotrophs were examined to determine the intracellular route and kinetic patterns of glycosylation. Studies were performed with cells from; (a) normal adult male rats; (b) rats orchidectomized 3 wk earlier; and (c) orchidectomized rats treated with tunicamycin. Our results show that incorporation of [3H]glucosamine first occurs in the rough endoplasmic reticulum (RER), then proceeds in the Golgi elements (where peripheral carbohydrates are attached). Treatment with tunicamycin results in a decrease in labeling of these 2 organelles. Comparison of the kinetic patterns in normal and castrated male rats shows that the accumulation of labeled glycosylated proteins in granules reaches a plateau within 2 hr post-pulse in normal rats, and rises during a 6-hr chase in castrated rats. However, because of the necessity for a rather long 15 min pulse, we cannot exclude the possibility that incorporation of glucosamine during the pulse may occur concomitantly in the RER and the Golgi saccules, to be followed by rapid transfer to the secretory granules.     

Appearance of acid phosphatase activity in the developing anterior pituitary of the rat

The ultrastructure of the anterior pituitary gland in developing rats was investigated according to Gomori's method for acid phosphatase. During the earlier period of development (day 14 to 16 of gestation), enzyme activity could not be found, although nonspecific deposits of lead were observed within the nuclear envelope, ER, and Golgi cisternae. This facilitated observation of the topographical relationship of the intracellular membrane system and suggestive evidence was obtained that the nuclear envelope in the pituitary anlage is involved in formation of the Golgi apparatus.During days 17 and 18 of gestation, when granule formation begins, little acid phosphatase activity was detectable in the Golgi apparatus and in the secretory granules. A polarized distribution of acid phosphatase was first detected in the Golgi apparatus on day 20 of gestation, with a concomitant increase of lysosomes.From these findings it seems that acid phosphatase begins to contribute to the secretory process a few days after granule formation has started.     

Cholesterol-rich intracellular membranes: a precursor to the plasma membrane

The disposition of newly synthesized sterols in cultured human fibroblasts has been examined in this study. We began by demonstrating that cholesterol mass and exogenously added [3H]cholesterol both are markers for the plasma membrane, perhaps better than 5'-nucleotidase. Cells were incubated with radioactive acetate to label their endogenous sterols biosynthetically, treated with cholesterol oxidase to convert plasma membrane cholesterol to cholestenone, and then homogenized and spun to equilibrium on sucrose gradients. The density gradient profiles of the various organelles were monitored using these markers: plasma membrane, radioactive cholestenone; smooth endoplasmic reticulum, 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase); and Golgi apparatus, galactosyltransferase. The buoyant density profiles of radioactive intracellular cholesterol and lanosterol both had a peak at 1.12 g/cm3, similar to 5'-nucleotidase and galactosyltransferase but not to HMG-CoA reductase. This result suggests that cholesterol biosynthesis is not taken to completion in the endoplasmic reticulum. Digitonin treatment shifted the profiles of both plasma membrane and intracellular cholesterol to higher densities. Pretreatment of intact cells with cholesterol oxidase abolished the digitonin shift of plasma membranes but not the intracellular cholesterol, indicating that these two membrane pools are not entirely physically associated. Because intracellular cholesterol was shifted more than any of the organelle markers, it must reside in a separate membrane. Since digitonin selectively shifts the density of membranes rich in cholesterol, we infer that newly synthesized cholesterol accumulates in such membranes prior to its delivery to the plasma membrane. Taken together, these results suggest that cholesterol may be concentrated for delivery to the plasma membrane by being synthesized from a sterol precursor such as lanosterol in a discrete but undefined intracellular membrane.     

In vitro incorporation of (3H)threonine and (3H)glucose by the mucous and serous cells of the human bronchial submucosal gland. A quantitative electron microscope study

Incorporation of [3H]threonine and [3H]glucose by the mucous and serous cells of the human bronchial submucosal gland has been studied over 8 h using, for the first time in vitro pulse labeling and electron microscope autoradiography. In assessing the autoradiographs, two methods were compared, the circle analysis and the recently described hypothetical grain analysis. Preliminary studies showed formaldehyde to be the most suitable fixative. Chemical analysis of tissue revealed that [3H]threonine was incorporated into the polypeptide moiety of the bronchial gland product and that metabolites of [3H]-glucose were incorporated into the carbohydrate. Tritiated threonine was first localized in the endoplasmic reticulum of both mucous and serous cells and later migrated to the Golgi apparatus, while metabolites of [3H]glucose localized first mainly in the Golgi apparatus. From here, both radioactive precursors were next identified in vacuoles and, finally, in secretory granules. The mucous cell incorporated strikingly more of both radioactive precursors than the serous cell. Thus, it seems that oligosaccharides of mucous and serous cell glycoproteins are synthesized mainly in the Golgi apparatus and added there to the polypeptide core which is synthesized in the endoplasmic reticulum. The relationship of the mucous cell to the serous cell is discussed. It seems that under "normal" conditions each cell represents a different line but that injury may transform a serous cell into a mucous cell.     

Association of newly synthesized pro-opiomelanocortin with secretory granule membranes in pituitary pars intermedia cells

The prohormone, pro-opiomelanocortin (POMC) is synthesized on ribosomes, subsequently routed to the Golgi apparatus and finally packaged into secretory granules where it is processed to various biologically active hormones (alpha-melanotropin, adrenocorticotropin, beta-endorphin and beta-lipotropin). We report here that in frog and mouse pars intermedia cells, newly synthesized [3H]Arg-labeled POMC is associated with the secretory granule membrane prior to processing. This association with the secretory granule membrane may be related to the intracellular transport and packaging of POMC and/or the facilitation of processing of the prohormone within the organelle.     

Calcium and the secretory cycle of prolactin cells: a cytochemical and ultrastructural study of dopamine inhibition and monobutyryl cyclic AMP-stimulation of prolactin secretion

To identify intracellular calcium pools that may be involved in the secretory process in prolactin (PRL) cells, hemi pituitaries were incubated in medium containing 10(-6) M dopamine, 5 mM cyclic cAMP (experimentals), or in medium alone (controls) and then processed for electron microscopy using potassium pyroantimonate to localize intracellular calcium. PRL in the medium was measured by radioimmunoassay. The concentration of antimonate associated with mitochondria, Golgi saccules, and secretory granules was estimated. Dopamine inhibition of PRL secretion (> 80% at 1, 2, 3 h) resulted in accumulation of secretory granules in all stages of maturation and dilation of Golgi saccules at 2 and 3 h, accompanied by increased mitochondria antimonate and increased Golgi-associated antimonate. Cyclic AMP stimulation of secretion (635% at 5 min., declining to 34% at 1 h) resulted in marked exocytosis at 5 and 15 min., declining after 30 min. Mitochondrial antimonate decreased after 30 min. Stimulated cells exhibited numerous coated membrane structures at or near exocytotic pits and an amassing of microvesicles at the margin of the Golgi apparatus. Although some secretory granules consistently exhibited reactivity to antimonate (unchanged by inhibition or stimulation), plasma membrane, and granule membrane translocated to the plasma membrane during exocytosis, were not reactive.     

Changes in cell polarity during mitosis in rat parotid acinar cells.

We studied the ultrastructure and cytochemistry of mitotic parotid acinar cells in vivo after induction of mitosis by isoproterenol injection. With entrance of the cells into the division cycle, the Golgi apparatus lost its characteristic stacked structure and internal polarity among the cisternae, appearing as fragments distributed throughout the cytoplasm. These fragments consisted of electron-lucent vesiculotubular structures and electron-dense 70-nm vesicles; neither component showed thiamine pyrophosphatase activity, a marker for trans cisternae of the Golgi apparatus, but the 70-nm vesicles showed a positive reaction for osmium impregnation, indicating retention of the cis nature. The rough endoplasmic reticulum was dilated and fragmented. Recovery of the structure of Golgi apparatus and rearrangement of rough endoplasmic reticulum occurred in daughter cells during telophase. These changes were the same as those observed after drug-induced inhibition of protein transport. The secretory granules were not dispersed but were divided into two groups with which centrioles were closely associated. Both groups migrated with the centrioles as far as the next interphase. The distribution of 5'-nucleotidase on the luminal plasma membrane showed no change during the process of division, thus demonstrating that surface polarity was maintained during mitosis. These changes in organelle structure and distribution may be due to the conversion of cell function from a secretory to a mitotic action.     

Lectin-labeled membrane is transferred to the Golgi complex in mouse pituitary cells in vivo

Labeling of the Golgi complex with the lectin conjugate wheat germ agglutinin-horseradish peroxidase (WGA-HRP), which binds to cell surface membrane and enters cells by adsorptive endocytosis, was analyzed in secretory cells of the anterior, intermediate, and posterior lobes of mouse pituitary gland in vivo. WGA-HRP was administered intravenously or by ventriculo-cisternal perfusion to control and salt-stressed mice; post-injection survival times were 30 min-24 hr. Peroxidase reaction product was identified within the extracellular clefts of anterior and posterior pituitary lobes through 24 hr but was absent in intermediate lobe. Endocytic vesicles, spherical endosomes, tubules, dense and multivesicular bodies, the trans-most saccule of the Golgi complex, and dense-core secretory granules attached or unattached to the trans Golgi saccule were peroxidase-positive in the different types of anterior pituitary cells and in perikarya of supraoptico-neurohypophyseal neurons; endoplasmic reticulum and the cis and intermediate Golgi saccules in the same cell types were consistently devoid of peroxidase reaction product. Dense-core secretory granules derived from cis and intermediate Golgi saccules in salt-stressed supraoptic perikarya likewise failed to exhibit peroxidase reaction product. The results suggest that in secretory cells of anterior and posterior pituitary lobes, WGA-HRP, initially internalized with cell surface membrane, is eventually conveyed to the trans-most Golgi saccule, in which the lectin conjugate and associated membrane are packaged in dense-core secretory granules for export and potential exocytosis of the tracer. Endoplasmic reticulum and the cis and intermediate Golgi saccules appear not to be involved in the endocytic/exocytic pathways of pituitary cells exposed to WGA-HRP.     

Posttranslational Processing of Carboxypeptidase E, a Neuropeptide-Processing Enzyme, in AtT-20 Cells and Bovine Pituitary Secretory Granules

Abstract: Carboxypeptidase E (CPE) functions in the posttranslational processing of peptide hormones and neurotransmitters. Like other peptide processing enzymes, CPE is present in secretory granules in soluble and membrane-associated forms that arise from posttranslational processing of a single precursor, “proCPE.” To identify the intracellular site of proCPE processing, the biosynthesis and posttranslational processing were investigated in the mouse anterior pituitary-derived cell line, AtT-20. Following a 15-min pulse with [³⁵S]Met, both soluble and membrane-bound forms of CPE were identified, indicating that the posttranslational processing event that generates these forms of CPE occurs in the endoplasmic reticulum or early Golgi apparatus. The relative proportion of soluble and membrane-bound forms of CPE changed when cells were chased for 2 h at 37°C but was unaffected when cells were chased at either 20 or 15°C, suggesting that further processing of membrane forms to the soluble form occurs in a post-Golgi compartment. Treatment of the cells with chloroquine did not alter the relative distribution of soluble and membrane forms, suggesting that an acidic compartment is not required for this processing event. Overexpression of CPE did not influence the distribution of soluble and membrane forms of CPE, indicating that the CPE-processing enzymes are not rate-limiting. To examine directly CPE-processing enzymes, bovine anterior pituitary secretory vesicles were isolated. An enzyme activity that releases the membrane-bound form of CPE was detected in the purified secretory vesicle membranes. This enzyme, which removes the C-terminal region of CPE, is partially inhibited by EDTA and phenylmethylsulfonyl fluoride and is activated by CaCI₂. Together, the data indicate that posttranslational processing of CPE occurs in secretory granules and that this activity may be mediated by a prohormone convertase-like enzyme.     

Membrane modification during secretory granule formation in rat somatotrophs

Somatotrophs from male rat anterior pituitary were used to investigate the formation of secretory granules. When enzymatically dispersed cells were incubated with cationized ferritin (CF) for 15 min, CF labeled immature secretory granules, but not mature granules of somatotrophs. Most immature granules labeled by CF transformed to the mature types within 120 min. This indicates that the fusion of endocytic vesicles with the immature granules occurs during the maturation process of secretory granules. The internalized CF was distributed not only in the immature secretory granules, but also in the peripheral region of trans Golgi cisternae or GERL. Enzyme cytochemistry revealed that acid phosphatase-positive cisternae (GERL) were the main site for secretory granule formation, and was devoid of thiamine pyrophosphatase (TPPase) activity. A small number of secretory granules were also present in the peripheral regions of TPPase-positive Golgi cisternae. The granule-forming sites, however, lacked TPPase activity, while the remaining region of the same cisterna showed the positive enzyme activity. This indicates that the granule-forming region at the periphery of Golgi cisterna is different from the remaining part of the same cisterna in terms of cytochemical properties. This probably results from the insertion of endocytic vesicle membrane, since the same granule-forming sites preferentially fused with CF-labeled small vesicles which lacked cytochemical TPPase activity. Taken together. Our results suggest that the membrane of secretory granules is modified during the granule formation, at least partly by the fusion of endocytic small vesicles with Golgi cisternae (or GERL), and with immature secretory granules.     

FURTHER STUDIES ON THE THETA CELL OF THE MOUSE ANTERIOR PITUITARY AS REVEALED BY ELECTRON MICROSCOPY, WITH SPECIAL REFERENCE TO THE MODE OF SECRETION

Theta cells reported previously as a new cell type in the anterior pituitary of the mouse were examined with the electron microscope. This type of cell is distinguished by the presence of pleomorphic secretory granules, a characteristic arrangement of the rough surfaced variety of endoplasmic reticulum, a well developed Golgi complex, and an eccentrically located nucleus. The secretory granules are seen at first as small granules of low density within the Golgi vesicles. While they are within the Golgi vesicles they become larger and denser. Simultaneously they move from the proximal to the distal part of the Golgi region and finally emerge from the Golgi area as mature granules in the cytoplasm. Thus, secretory granules are always enveloped by a limiting membrane which originates from the wall of the Golgi vesicle. At the stage of granule-extrusion, the cell membrane fuses with the limiting membrane of the granules and openings in the cell membrane appear at the place of extrusion. The granules then appear to lie within inpocketings of the cell membrane. They lose their density within these inpocketings or within the cytoplasm and occasionally show fragmentation. After complete loss of density, the granules are extruded as amorphous materials to the territory outside of the cell.     

A clathrin-coated, Golgi-related compartment of the insulin secreting cell accumulates proinsulin in the presence of monensin

When the intracellular transit of 3H-labeled (pro)-insulin polypeptides is perturbed by monensin in the pancreatic B-cell, proinsulin conversion is impaired and the radioactive peptides accumulate in a clathrin-coated membrane compartment related to the Golgi apparatus. Clathrin was demonstrated by immunocytochemistry using the postembedding protein A-gold technique. The coated compartment, which is dilated by monensin, comprises Golgi cisternae with condensing secretory material and newly formed secretory granules; under monensin block, the noncoated (storage) secretory granules do not become significantly labeled. These data suggest that an unperturbed passage through a Golgi-related, clathrin-coated membrane compartment which subsequently matures into noncoated secretory granules is needed for the normal processing of (pro)insulin polypeptides.     

Evidence that biosynthesis of platelet-activating factor (paf-acether) by human neutrophils occurs in an intracellular membrane

Human polymorphonuclear leukocytes (PMN) were incubated in the absence or presence of the calcium ionophore A23187 (6 microM) for 10 min at 37 degrees C. They were then lysed by nitrogen cavitation and fractionated using Percoll gradients. Three major fractions of increasing density corresponding to plasma membrane, intracellular membranes and secretory granules were detected using [3H]concanavalin A, NADH-dehydrogenase and beta-D-glucuronidase as respective markers. In both cases, the acetyltransferase activity responsible for biosynthesis of paf-acether (platelet-activating factor of 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) was detected in the intermediary fraction, the enzyme activity being increased 3-4-fold in stimulated cells. From the comparison with the distribution of various markers, it is concluded that in human PMN the final step of paf-acether assembly occurs in an intracellular membrane, possibly the endoplasmic reticulum.     

Multigranular exocytosis induced by phospholipase A2-activators,melittin and mastoparan,in rat anterior pituitary cells

Summary Effects of phospholipase A₂-activators, melittin and mastoparan, on rat anterior pituitary cells were studied by use of the electron microscope. Rat anterior pituitaries were incubated in HEPES buffer containing 20 g/ml of melittin or the same dose of mastoparan for 5 min, 10 min and 20 min. Features indicating discharge of granule contents by exocytosis were increased with time, and the simultaneous extrusion of a number of secretory granules, named multigranular exocytosis, was often recognized in addition to single-granule exocytosis at 10 min and 20 min. Most membrane pits, where the multigranular exocytosis as well as the single-granule exocytosis occurred, were coated. Moreover, a large number of vesicles coated or noncoated were distributed near the trans side of the Golgi apparatus of melittin-treated or mastoparan-treated cells after 20 min. These vesicles might be related to membrane internalized from the excess surface membrane derived from the limiting membrane of exocytosed granules. These observations indicate that phospholipase A₂-activators induce hormone release involving membrane fusion between limiting membranes of secretory granules, and between granulelimiting membrane and plasma membrane in rat anterior pituitary cells.This study was supported by grants from the Japan Ministry of Education     

Presence of angiotensin II in the adult male rat anterior pituitary gland: immunocytochemical study after cryoultramicrotomy

Angiotensin II (AII)-like immunoreactivity and binding sites have recently been demonstrated at the pituitary level. This peptide also exerts a stimulatory effect on anterior pituitary hormone release. Immunocytochemistry on ultrathin sections obtained by cryoultramicrotomy was used with the aim of localizing endogenous AII-like material at the cellular and subcellular levels of the anterior pituitary gland. AII-like immunostaining was observed only in gonadotrophs, lactotrophs, and corticotrophs. In gonadotrophs, AII-like immunoreactivity was restricted only to secretion granules. In the two other immunoreactive cells, lactotrophs and corticotrophs, immunostaining was observed in the cytoplasm and in the nucleus. In the cytoplasm, AII-like material was visualized in the cytoplasmic matrix and in the secretory granules. In the nucleus, immunostaining was distributed in the euchromatin in the vicinity of the heterochromatin. AII-like immunoreactivity was also seen at the plasma membrane, but only scarcely. No reaction product was found when anti-AII serum preincubated with AII was used. These immunocytochemical results (1) provide evidence that gonadotrophs are only a site of synthesis and/or storage of AII-like material, (2) indicate that lactotrophs and corticotrophs are cells for AII and (3) provide cytological evidence for a direct participation of AII in the regulation of the lactotropic and corticotropic function.     

The site of incorporation of sialic acid residues into glycoproteins and the subsequent fates of these molecules in various rat and mouse cell types as shown by radioautography after injection of [3H]N- acetylmannosamine. II. Observations in tissues other than liver

Biochemical evidence from the preceding paper indicated that [3H]N- acetylmannosamine may be used as a fairly specific precursor for the sialic acid residues of glycoproteins (and perhaps glycolipids) in radioautographs of rat liver and duodenum. In order to study the site of incorporation of this label in cell types of various tissues, we gave 40-g rats and 15-g Swiss albino mice a single intravenous injection of 8 mCi of [3H]N-acetylmannosamine and sacrificed them after 2 and 10 min. To trace the subsequent migration of the labeled glycoproteins, we injected 40-g rats with 4 mCi of [3H]N- acetylmannosamine and sacrificed them after 20 and 30 min, 1, 4, and 24 h, and 3 and 9 d. Light microscope radioautographic analysis revealed that in a great variety of cell types the label was initially localized to the Golgi region. Electron microscope radioautographic analysis of duodenal villous columnar and goblet cells, pancreatic acinar cells and Paneth cells, from rats and mice sacrificed 10 min after injection, showed that the silver grains were localized over Golgi saccules (and adjacent secretion granules). In kidney proximal and distal tubule cells reaction was initially localized to the Golgi apparatus in some areas of the kidney cortex whereas in other areas it was more diffuse. In all cells, the proportion of silver grains over the Golgi apparatus decreased with time after injection while an increasing number of grains appeared over secretion products in secretory cells or over the plasma membrane in other cell types. Lysosomes also became increasingly labeled at later time intervals. The above results suggest that in most cell types sialic acid residues are incorporated into glycoproteins (and perhaps glycolipids), primarily in the Golgi apparatus. With time, these newly synthesized molecules migrate to secretion products, to the plasma membrane, or to the lysosomes.