Three-dimensional localization of DNA synthesis in secretory elements of adult female mouse submandibular gland

PLAG1 enhances the stemness profiles of acinar cells in normal human salivary glands in a cell type-specific manner

OBJECTIVES

Details of the histogenesis of salivary gland tumors are largely unknown. The oncogenic role of PLAG1 in the salivary gland has been demonstrated in vivo. Herein, we demonstrate PLAG1 roles in the acinar and ductal cells of normal human salivary glands to clarify the early events that occur during the histogenesis of salivary gland tumors.

METHODS

Normal salivary gland cells with acinar and ductal phenotypes were transfected with PLAG1 plasmid DNA. Subsequently, PLAG1 overexpressed and mock cells were examined by cell proliferation, transwell migration, and salisphere formation assays. Differentiation and salivary and pluripotent stem cell marker expression levels were evaluated by quantitative reverse transcription-polymerase chain reaction and immunofluorescence. Alterations in transcriptional expressions were investigated via cap analysis of gene expression with gene-enrichment and functional annotation analysis.

RESULTS

PLAG1 promoted cell proliferation and transwell migration in the acinar and ductal cells, and markedly enhanced the stemness profiles and luminal cell-like profiles in acinar cells; the stemness profiles were partially increased in the ductal cells.

CONCLUSION

PLAG1 enhanced the stemness profiles in the acinar cells of normal human salivary glands in a cell type-specific manner. Thus, it may be involved in salivary gland tumorigenesis by increasing the stemness character of the normal salivary gland cells.

Contributions of intercalated duct cells to the normal parenchyma of submandibular glands of adult rats

The parenchyma of the submandibular gland in the adult male rat is self-renewing, with most newly formed acinar and granular duct cells believed to differentiate from the rapidly proliferating intercalated duct (ID) compartment. Since the ID cells are phenotypically diverse, based on their different expression of perinatal secretory proteins, we systemically injected tritiated thymidine for 24 hours, and followed the pattern of thymidine distribution in cells by autoradiography and immunocytochemistry of defined cellular phenotypes over a 1-month chase period. Proliferating cells were found within all parenchymal cell compartments; they were most numerous in ID, and primarily in those cells lacking immunoreactivity for the perinatal proteins SMG-B1, -C, and -D. The labeling index (LI) of the ID cells reached a peak at 7 days postinjection, and then decreased over the next 3 weeks. Concurrently, the LI increased significantly in those cells at the junctions of ID with both acini and granular ducts, and also within these larger parenchymal elements. We conclude that the ID cells not reactive for perinatal proteins proliferate to expand the ID compartment, and that ID cells at the ends of the ducts differentiate into both acinar and granular duct cells. Our data provide no evidence for the differentiation of ID cells into cells of striated ducts (SD); however, the small number of excretory duct (ED) profiles seen in our preparations showed extremely high LI (>25%), suggesting that more extensive data might reveal a precursor role for the ED in replacement of SD cells. In addition to the stepwise passage of cells from ID to other parenchymal elements at their junctions, the reported occurrence of occasional clusters of B1-positive acini (BAC) among the typical B1-negative acini had suggested an alternate pathway, in which entire segments of newly expanded ID might develop directly into a recapitulated perinatal stage of B1-reactive cell, pursuant to becoming mature acinar cells. Consistent with this suggestion, the BAC had a fourfold greater LI than typical adult acini; moreover, when analyzed by electron microscopic immunocytochemistry, they appeared similar to the novel perinatal Type III cells both ultrastructurally and in their pattern of B1-immunogold labeling. In contrast, the less common acini showing a sublingual gland phenotype had no significant difference in LI from typical acinar cells. Overall, our results emphasize the importance of the nonimmunoreactive ID cells in normal cellular replacement, and the possibility that ID can undergo en bloc differentiation into replacement acini as well as incremental addition of single cells at the boundaries of ID with acini and with granular ducts.

Salivary glands: a paradigm for diversity of gland development

The major salivary glands of mammals are represented by three pairs of organs that cooperate functionally to produce saliva for the oral cavity. While each type of gland produces a signature secretion that complements the secretions from the other glands, there is also redundancy as evidenced by secretion of functionally similar and, in some cases, identical products in the three glands. This, along with their common late initiation of development, in fetal terms, their similarities in developmental pattern, and their proximate sites of origin, suggests that a common regulatory cascade may have been shared until shortly before the onset of overt gland development. Furthermore, occasional ectopic differentiation of individual mature secretory cells in the "wrong" gland suggests that control mechanisms responsible for the distinctive cellular composition of each gland also share many common steps, with only minor differences providing the impetus for diversification. To begin to address this area, we examine here the origins of the salivary glands by reviewing the expression patterns of several genes with known morphogenetic potential that may be involved based on developmental timing and location. The possibility that factors leading to determination of the sites of mammalian salivary gland development might be homologous to the regulatory cascade leading to salivary gland formation in Drosophila is also evaluated. In a subsequent section, cellular phenotypes of neonatal and adult glands are compared and evaluated for insights into the mechanisms and lineages leading to cellular diversification. Finally, the phenomena of proliferation, repair, and regeneration in adult salivary glands are reviewed, with emphasis on the extent to which the cellular diversity is reversible and which cell type other than stem cells has the ability to redifferentiate into other cell types.

Quantitative immunocytochemical study of secretory protein expression in parotid glands of rats chronically treated with isoproterenol

Chronic treatment of mice and rats with isoproterenol (IPR) causes marked hypertrophy and hyperplasia of the salivary glands, and alters the expression of several secretory proteins. We used quantitative postembedding immunogold labeling to study the cellular responses in the rat parotid gland during daily (up to 10 days) injections of IPR and during recovery (up to 14 days) after cessation of IPR treatment. Labeling densities of acinar cell secretory granules with antibodies to amylase and protein SMG-B1 (cross-reactive with the rat homologue of Parotid Secretory Protein, PSP) fell to 10% of control levels after 8-10 IPR injections, then increased during recovery, paralleling previous biochemical determinations of changes in protein and mRNA levels. With antibodies to proline-rich proteins (PRP), labeling densities initially fell, then subsequently showed considerable variability, but never exceeded control levels. These results contrast with biochemical determinations showing a marked induction of PRP synthesis, and may have both immunological and structural explanations. Occasional intercalated duct cells located close to the acini underwent differentiation toward an acinar-like phenotype as a result of IPR treatment. After 1-2 IPR injections, the secretory granules of these cells labeled with antibodies to amylase and PRP. Subsequently, the granules appeared electron-lucent and were increased in size and number. These observations support earlier work, suggesting that intercalated duct cells may differentiate into other gland cell types.

Emergence of salivary gland cell lineage diversity suggests a role for androgen-independent epidermal growth factor receptor signaling

Diversity of cell lineages within glandular organs is generated postnatally by differentiation of committed progenitor cells. Fundamental regulatory aspects of this process are not understood. The mouse submandibular salivary gland (SSG) served as model to assess the role of epidermal growth factor (EGF) receptor signaling during emergence of cell lineage diversity. Temporal fluctuations in EGF receptor mRNA levels coincident with crucial differentiative cell lineage transitions were revealed by RNase protection analyses. Between days 2 and 5, when proacinar cells are maturing and striated duct cells emerge, EGF receptor mRNA levels were highest and all differentiating cells exhibited EGF receptor immunoreactivity. EGF receptor mRNA levels then declined sharply and immunoreactivity became confined to ductal cells. At day 11 in male mice, and days 11 and 16 in females, a second increase in EGF receptor mRNA was detected coincident with emergence of granular convoluted tubule (GCT) cells. With completion of androgen-dependent GCT cell differentiation at the onset of puberty, EGF receptor mRNA levels and intensity of immunoreactivity decreased. Androgen effects on EGF receptor mRNA or immunoreactivity could not be detected. These temporally distinct patterns of EGF receptor expression suggest that this signaling pathway is a mechanism of potential importance in emergence of cell lineage diversity in a glandular organ.

The pathobiology of salivary gland. III. PCNA-localization of cycling cells induced in rat submandibular gland by low-dose x-radiation

Application of ionizing radiation to adult rat major salivary glands tested tenets of the bicellular reserve cell hypothesis for the induction of salivary gland tumors, namely, that stem cells preferentially located to luminal cells of the intercalated duct and basal cells of the excretory duct in normal salivary glands. The effect of a single, low dose (3000 cGy) of x-radiation administered to the parotid and submandibular glands was followed with the use of immunocytochemistry and an antibody to the cell cycle-related protein proliferating cell nuclear antigen to detect the kinetics and localization of cycling cells up to 15 days postirradiation. Maximal responses occurred in acinar cells (12.6-fold increase) of submandibular glands on day 7 postirradiation. Similar but less dramatic concurrent increases in proliferating cells were evident in intercalated (3.4-fold) and striated (2.2-fold) duct cells, but little response was seen in basal or luminal cells of submandibular gland excretory ducts. A limited but maximal proliferative response again occurred on day 7 in the parotid gland. Neither in the steady state nor irradiated submandibular gland was there evidence of specific stem ("reserve") cells associated with the intercalated or excretory ducts. It appears unnecessary to invoke stem cells in a model of cellular proliferation in salivary glands. Therefore current concepts of salivary gland tumorigenesis require modification because all cell types, including acinar cells, are at risk in the carcinogenic process.

Current status of histogenetic and morphogenetic concepts of salivary gland tumorigenesis

Because of their complexity and relative infrequency, salivary gland tumors commonly result in diagnostic problems. Histogenetic and morphogenetic concepts of tumorigenesis in these glands are reviewed and their relevance to routine diagnosis and classification of salivary gland tumors evaluated. Evidence is presented from animal and human studies that under steady-state and pathophysiological conditions, all cell types present in the normal gland, including acinar cells, are capable of rapidly entering the cell cycle and are, therefore, possible targets for neoplastic transformation.

Pathobiology of salivary glands. IV. Histogenetic concepts and cycling cells in human parotid and submandibular glands cultured in floating collagen gels

Localization of cells with proliferative capacity in human major salivary glands lacks extensive study. Minced fragments of human parotid (n = 3) and submandibular (n = 3) glands embedded in a floating collagen gel matrix and cultured for up to 28 days allowed maintenance of the three-dimensional relationship of the various cell types in these glands. Immunocytochemistry and electron microscopy of a time-dependent series of cultured gland fragments showed gradual cytologic modification of acinar cells so that acini became duct-like but also established that even after 28 days of culture certain cellular features allowed continued identification of acinar cells. Serial section immunostaining for amylase, cytokeratins, and proliferating cell nuclear antigen (a specific marker for cycling cells) revealed that acinar, intercalated duct, and excretory duct (both basal and luminal) cells are all capable of entering the cell cycle. At day 5 of culture, the number of cycling cells increased 16-fold in the parotid gland and 9-fold in the submandibular gland over that in the respective in situ gland. In this in vitro system, which perhaps simulates regenerative processes in human salivary glands, none of the samples showed cycling cells localized only to segments of intercalated duct or the basal cells of excretory duct as suggested by current histogenetic concepts.

DNA synthesis and development strategies with possible consequences on sexual dimorphism in adult mouse submandibular glands

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.

Parenchymal cell proliferation and mechanisms for maintenance of granular duct and acinar cell populations in adult male mouse submandibular gland

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.

Proliferative and structural differences between male and female mouse submandibular glands

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.