To evaluate proliferation as a factor in maintenance of parenchymal cell populations in adult male mouse submandibular glands, a variety of surveys were conducted following a pulse with 3H-thymidine. Striated granular duct (SGD) cells had the highest labeling index, followed by intercalated duct (ID) cells, then acinar (AC) cells, and granular duct (GD) cells had the lowest. These cell types showed from 30% to 60% completion of mitosis by 24 hr, with SGD, AC, and GD showing a likely second wave of mitosis sometime between 2 and 7 days after the pulse. About 40% of the pulse-labeled cells still remained as single cells at 42 days after the pulse. Repeat divisions in daughter cells of the primary labeled cells were very rare. A shift in the pattern of labeled cells at the ID-GD junction indicates that ID and SGD cells in this compartment are differentiating to GD cells. Further comparison of the magnitude of this conversion with the amount of noncompartmental GD cell proliferation provided a basis for calculating that approximately 70% of GD cell population maintenance occurs by self-proliferation, and the remaining 30% is contributed by differentiation from ID and SGD cells. A similar survey at the ID-acinus junction showed no evidence of conversion of ID cells to AC cells indicating that most, if not all, proliferative activity leading to AC cell population maintenance occurs by self-proliferation. Finally, based in part on structural changes at the ID-GD junction during the survey period, a pattern of cell conversion described as "in situ differentiation" is proposed. When this pattern is carried to fruition, this explains several structural features of the secretory complex typical to the male pattern submandibular gland. The proposed mechanism is supported by a three-dimensionally reconstructed sequence of likely intermediate structures.
Sexual dimorphism has been observed in salivary glands of many species. In this study, evidence for sexual differences in adult mouse submandibular gland is extended beyond parenchymal cell composition, size, and volumes to include patterns of DNA synthesis and complexity of ductal branching. Computer-assisted three-dimensional reconstructions also revealed differences in overall organization of secretory complexes. Consistent with observations by others, granular intercalated duct cells were absent, while striated granular duct cells were low in proportion in the male glands relative to female glands. When the mean of average cell volumes were compared, acinar (AC) cells were smaller than granular duct (GD) cells in the male, but in the female the reverse was true. Furthermore, in addition to differences in average volumes of GD cells, the average volume of AC cells was significantly greater in females than males. The most dramatic evidence for sexual dimorphism was observed following a 90-min labeling with 3H-thymidine. Though all cell types showed DNA replication activity, the intercalated duct (ID) cells were substantially more active than AC and GD cells in the female, while in the male the GD cells, ID cells, and AC cells all showed approximately equal activity. Three-dimensional reconstructions indicated that the female possessed a more highly branched intercalated duct system and that the GD usually terminated within a secretory complex, whereas in males the GD typically passes through a secretory complex and forms a prominent cap-like structure on the opposite side.
The predominant mucins in human whole saliva, MG1 and MG2, serve to protect and to lubricate the oral cavity. In this study, both unstimulated and stimulated whole salivas were collected from two groups of subjects: young (18-35 years of age) and aged (65-83 years of age). The subjects were in apparent good health. Saliva samples from each subject were analyzed by SDS-PAGE. The gels were stained with Stains-all, and both MG1 and MG2 were quantitated by video-image densitometry. The protocol gave reproducible values for each mucin. The stimulated and unstimulated salivas from aged subjects showed significant reductions in concentrations of both MG1 and MG2, as quantitated in mucin dye-binding units. Possible associations of these reductions with the aging process are discussed.
A system based in part on three-dimensional structural relationships is described for precisely characterizing the location of cells within secretory complexes of the adult female mouse submandibular gland. The pattern of DNA synthesis during a 90-minute pulse with 3H-thymidine was characterized based upon the above system. Seventy-eight percent of all radiolabeled nuclei were found in the intercalated duct system. One-half of these were in second-order intercalated ducts. DNA synthesis was also observed in acinar cells, granular intercalated duct cells, striated granular duct cells, and granular duct cells. Some secretory complexes contained multiple radiolabeled nuclei, with some of these nuclei in a side-by-side configuration. Approximately one-half of all secretory complexes contained radiolabeled nuclei. A second survey of the frequency of complexes containing radiolabeled nuclei was conducted following four pulses at eight-hour intervals over a 26-hour period. Only about 30% of all complexes contained radiolabeled nuclei. This reduction in the frequency of radiolabeled nuclei when compared with the single pulse suggests the possibility of individual variation. However, a more prolonged period of daily injections for nine days with 3H-thymidine resulted in all but one of the secretory complexes containing radiolabeled nuclei. This latter observation suggests that cell addition in adult submandibular glands is widespread.
This article summarizes a series of recent studies that broaden the criteria for sexual dimorphism in adult mouse submandibular gland. From these observations, a hypothesis is presented, suggesting that the gross histological differences that are characteristic of adult sexual dimorphism in the gland secondarily result from differences in the activities of three fundamental cellular processes, that is, rates of cell proliferation, cell sizes, and ongoing patterns of differentiation.
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