Squamous cell carcinomas of the head and neck cultured in floating collagen gels: 1. The maintenance of stromal and epithelial elements in vitro without fibroblast overgrowth.

The study of the molecular biology of head and neck squamous cell carcinomas has been heavily reliant on the analysis of cell lines. This is largely because the maintenance of primary cell cultures is difficult. However, being monoclonal, cell lines are not representative of the primary tumor because of the loss of tumor cell heterogeneity. We report a technique for primary culture of squamous cell carcinomas with maintenance of epithelial and stromal cell components without overgrowth of the fibroblast cells. Phenotypic markers for fibroblasts and squamous cells were present up to 45 days after initiation of culture, and expression of epidermal growth factor receptor and involucrin in cultures paralleled that in the primary tumor. In vivo, tumor stromal elements are thought to play an important role in the support of epithelial cell growth. In the collagen gel system the preservation of the stromal cell component likely improves culture viability and growth. More importantly, this culture system allows the in vitro tumor to more accurately reflect the tumor from which it was derived, and it permits the study of primary squamous cell carcinomas under in vitro conditions.

Myoepithelial cells actively proliferate during atrophy of rat parotid gland.

Despite limited supporting evidence, salivary gland myoepithelial cells are said to be differentiated cells with little or no capacity to replicate; they presumably develop from stem cells. This study investigated the proliferative potential of myoepithelial cells with an antibody to proliferating cell nuclear antigen and a rat model. This model involved clamping of the parotid duct causing atrophy of the gland and then releasing the duct followed by gland regeneration. Rats were sacrificed at time points during atrophy and regeneration phases and the number and location of cycling myoepithelial cells assessed. Cycling myoepithelial cells were identified with double immunohistochemical staining, cycling cells with proliferating cell nuclear antigen-positive nuclei within muscle-specific actin-positive cytoplasm (the latter identified with antibody HHF35). The results show that baseline proliferative rates of myoepithelial cells in both the resting and fully regenerated gland ranged from 0.3% to 2%, similar to rates for other major cell types in the normal rat gland. A peak myoepithelial cell proliferative rate of 23% occurred at day 5 during the atrophy phase. Rates during the regenerative phase were not significantly different than the baseline levels. Similarities of rat and human parotid gland and the definite proliferative capacity of myoepithelial cells indicates that these specialized cells must be considered one of the potential progenitor cells for human salivary gland tumors.

Differentiating myoepithelial and acinar cells in rat neonatal parotid gland and histogenetic concepts for salivary gland tumors.

Histogenetic concepts for salivary gland tumors are predicated on the presence of reserve or undifferentiated cells in normal glands, presumably the source for cell renewal and induction of tumors. Developing rat parotid gland, which remains fetal-like at birth, provides the opportunity to study differentiation and observe whether cytologically undifferentiated cells do or do not have functional indicators of specific differentiation pathways. Immunohistochemistry and immuno-electron microscopy, when applied to parotid gland at birth, at 12 days of age and in the adult gland, indicate that commitment to myoepithelial cell differentiation occurs prior to development of structural changes characteristic of these cells. Conversely, secretory granules are evident in differentiating acinar cells prior to synthesis of amylase. The results suggest that an appearance of undifferentiation does not confer reserve cell status either in the normal salivary gland or their tumors.

Postirradiated submandibular gland: a potential model to study salivary gland radioprotection and tumourigenesis.

Theoretical reserve cells located in the intercalated and excretory ducts are postulated to be responsible for salivary gland tumourigenesis, with acinar cells playing no role in this process. Animal models, one using low-dose radiation to rat submandibular glands, indicate that this hypothesis is incorrect. Few human models have been devised to demonstrate and verify this theory. Submandibular glands in the field of ionizing radiation, as external-beam radiotherapy for head and neck tumours, were examined using an immunocytochemical technique and an antibody to proliferating cell nuclear antigen (PCNA), a specific marker for cycling cells. In the nonirradiated gland, nuclei positive for PCNA were seen in acinar as well as ductal cells of all types. Six months post irradiation, human submandibular glands show increased proliferative rates in both ductal and acinar cells that are significantly greater than control glands (p = .012). Based on this regenerative capacity, postirradiated human submandibular glands might serve as a model to investigate various treatment modalities for the prevention of radiation damage to acinar cells and the consequent patient morbidity that develops due to xerostomia. As well, these results suggest that even in humans, acinar cells are potential targets for carcinogenic agents and that current histogenic concepts for salivary gland tumourigenesis are incorrect.

Detection of proliferating cell nuclear antigen in paraffin-embedded specimens is dependent on preembedding tissue handling and fixation.

Immunohistochemical detection of proliferating cell nuclear antigen (PCNA), a cell cycle-related protein used to estimate tumor growth fraction, is variable in formalin-fixed compared with methanol-fixed tissue specimens. This is assumed to result from conformational changes in the antigenic epitope induced by formaldehyde; therefore, to be susceptible to retrieval in archival specimens. In this study, formalin fixation reduced the intensity of staining and the number of positive cells to approximately 25% of those in methanol-fixed material. The washing of tissue specimens prior to methacarn fixation also reduced PCNA staining. Loss of staining was not restored after use of a commercial retrieval kit recommended for PCNA immunohistochemistry. Immunoblotting of formalin fixatives and saline washings after removal of tissue specimens consistently demonstrated the presence of PCNA-like activity in solution. We conclude that the exceptional solubility of PCNA is responsible for reduced immunostaining in formalin-fixed material, that the loss is irreversible, and that methanol or methacarn is the fixative of choice for PCNA immunohistochemistry.

Collagen gel cultures of normal salivary gland: conditions for continued proliferation and maintenance of major cell phenotypes in vitro.

The presence of three functionally and phenotypically distinct epithelial cell populations--acinar, duct, and myoepithelial cells--in major salivary glands creates problems when developing physiologically appropriate culture systems for the study of these tissues in vitro. Previous attempts to establish cultures of rat submandibular gland resulted in continued proliferation and maintenance of glandular architecture, but loss of distinct features of differentiation of the three epithelial cell types. The present study describes an ultrathin free-floating collagen gel culture technique (mantle gels). Using this method, immunohistochemical and ultrastructural studies indicate that rat submandibular gland continues to cycle, and secretory activity and phenotypic markers for acinar, duct, and myoepithelial cells are all demonstrable after 4 weeks in culture, suggesting that this constitutes the ideal system for in vitro investigation of the pathobiology of the salivary gland.

Pathology of the salivary glands: the contribution of electron microscopy.

Electron microscopy has a limited role in the diagnosis of primary salivary gland tumors, although it can be helpful in metastatic lesions of possible salivary gland origin. The diversity of subtypes in salivary gland tumors, as well as the range of histomorphology within any one subtype, is unparalleled in any other human tumor. This and their relative infrequency causes diagnostic problems for pathologists. Ultrastructural techniques have been of major importance in determining the inter-relationship of these tumors for classification purposes, revealing the subtle variations in common cellular differentiation pathways, determining the organization of tumor cells, and displaying the importance of extracellular matrix materials in establishing diagnostic criteria for each of the many subtypes. Electron microscopy has also been valuable in non-neoplastic salivary gland disease and has an increasing role in experimental studies involving tissue from human and animal salivary parenchyma.

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.

Immunohistochemical analysis of the proliferative capacity of duct and acinar cells during ligation-induced atrophy and subsequent regeneration of rat parotid gland.

To study the proliferative capacity of salivary gland, an animal model of regeneration was developed. A clamp, which induced atrophy in parotid gland by obstructing the main excretory duct but allowed restoration of duct patency following removal, was implanted in a series of rats. When it was removed (Day 7), the weight of the glands was reduced by 50% and acinar cells had decreased from 93.8% to 8.2% of total cell population. Regeneration occurred rapidly following removal of the clamp. The number and location of cycling intercalated, striated, and excretory duct cells and acinar cells were monitored using an antibody to proliferating cell nuclear antigen (PCNA). All cell types were induced to cycle but the predominant cell to cycle was the acinar cell. During regeneration the number of PCNA+ acinar cells increased 38.7-fold from steady-state values. Results demonstrate that acinar cells have a significant potential for cycling, contrary to current histogenetic theories of salivary gland tumourigenesis which exclude acinar cells as potential progenitor cells on the grounds of their putative limited cycling capacity.

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.