We present a method for isolating and cultivating primary human salivary gland-derived epithelial cells. These cells exhibit gene expression patterns consistent with them being of salivary epithelial origin and can be grown as salispheres on basement membrane matrices derived from Engelbreth-Holm-Swarm tumor cells or as monolayers on treated culture dishes.
The salivary glands are a site of significant interest for researchers interested in multiple aspects of human disease. One goal of researchers is to restore function of glands damaged by radiation therapies or due to pathologies associated with Sjögren’s syndrome. A second goal of researchers is to define the mechanisms by which viruses replicate within glandular tissue where they can then gain access to salivary fluids important for horizontal transmission. These goals highlight the need for a robust and accessible in vitro salivary gland model that can be utilized by researchers interested in the above mentioned as well as related research areas. Here we discuss a simple protocol to isolate epithelial cells from human salivary glands and propagate them in vitro. Our protocol can be further optimized to meet the needs of individual studies. Briefly, salivary tissue is mechanically and enzymatically separated to isolate single cells or small clusters of cells. Selection for epithelial cells occurs by plating onto a basement membrane matrix in the presence of media optimized to promote epithelial cell growth. These resulting cultures can be maintained as three-dimensional clusters, termed “salispheres”, or grown as a monolayer on treated plastic tissue culture dishes. This protocol results in the outgrowth of a heterogenous population of mainly epithelial cells that can be propagated for 5-8 passages (15-20 population doublings) before undergoing cellular senescence.
In mammals the salivary glands are organized into 3 pairs of major salivary glands: the parotid, submandibular, and sublingual glands. There also exists a series of minor glands located on the tongue and scattered throughout the oral cavity1. The major glands are responsible for the bulk volume of saliva produced2. In addition to providing antimicrobial protection through secreted factors, the saliva is important in the process of chewing and lubricating food as it passes through the esophagus2. As such, salivary gland dysfunction represents a medical issue where sufferers who are unable to produce enough saliva are more prone to developing maladies such as dental cavities or oral candidiasis3. Additionally, reduced saliva results in greater difficulty eating and digesting food having a significant impact on quality of life.
Salivary gland dysfunction is primarily found in patients suffering from Sjögren's syndrome, an autoimmune disorder, or in patients with head and neck cancer who have undergone irradiation therapy3,4,5,6. Damaged secretory acini within the glands as a result of autoimmunity or radiation therapy do not undergo self-renewal, which results in a patient living with irreversible damage6. The study of salivary glands has also garnered the attention or researchers interested in mechanisms of viral pathogenesis. Some pathogens, such as human cytomegalovirus (HCMV), persistently replicate within the salivary glands, which then allows for transmission of nascent virus to a new host via saliva7,8. Thus, there is an unmet need to develop robust and reproducible in vitro models of salivary gland tissue to tackle and understand a diverse array of medical problems.
Several models of the murine salivary gland system have been used as a starting point to understand and characterize the different epithelial cells that form the salivary glands9,10. There exist obvious and major differences between human and murine salivary glands11. Most notably the human parotid gland is larger in relation to the submandibular gland whereas the mouse submandibular and parotid are much similar in size1,2,11. While immortalized human submandibular cell lines exists, there are major concerns that the immortalized cells do not accurately maintain the phenotype of the primary tissue and secondary concerns that the immortalized cells are not actually derived from salivary epithelium itself12. For these reasons there is an interest and a need to study primary salivary tissue from humans.
Here we describe a protocol to isolate primary epithelial cells from human salivary glands for tissue culture. Our protocol is based on the works of Pringle et al. and Tran et al. with modifications made to generally simplify their procedures13,14. First, while Tran et al.'s protocol calls for a long five-hour incubation for enzymatically digesting the salivary tissue, our modified protocol has been successful with as little as one-hour incubation, similar to that in Pringle et al. Second, we use different enzymes for tissue digestion, most notably we don't use trypsin as is used in the original Tran et al. protocol, but instead use a mixture of dispase and collagenase. We prefer to avoid trypsin in the initial digestion steps as a recent study suggested that initial digestion of the salivary tissue by trypsin results in reduced cell viability, possibly by the loss of a rare stem cell population15. Lastly, we culture the salispheres on the surface of basement membrane matrix (BMM) using a commercially available media originally formulated for the propagation of bronchial epithelial cells. Our protocol can be used to isolate salivary cells from parotid, submandibular, and sublingual glands. These cells express salivary amylase and other salivary specific genes indicating that they maintain a phenotype similar to that of salivary acinar epithelial cells7. We have successfully generated salivary cultures from >50 primary human tissue samples using this methodology. Moreover, the primary salivary cells can easily be cryopreserved for use at a later date.
These protocols and studies have been reviewed and approved by the Institutional Review Board at the University of Cincinnati (Federal-wide Assurance #00003152, IRB protocol 2016-4183). Salivary tissue is commonly resected in many head and neck surgical procedures and is usually uninvolved by the malignant process. Typically, freshly resected salivary gland tissue is used within 2-4 h after removal from the patient (Figure 1A).
1. Reagent Preparation
2. Tissue Digestion
3. Coating wells with basement membrane matrix
NOTE: Basement membrane matrix (BMM) should be thawed overnight at 4 °C the day before it will be used. Once thawed, BMM should be constantly maintained on ice or at 4 °C as it will rapidly solidify (i.e., form a gel) at warmer temperatures. Additionally, care should be taken if samples have been chilled on ice prior to plating on BMM as cold samples will "melt" the BMM and expose cells to the plastic dish.
4. Filtering of undigested tissue, RBC lysis, and cell plating
5. Subculturing the salispheres and maintenance on BMM
6. Subculturing the salispheres on treated plastic tissue culture dishes
NOTE: If maintaining cells as a monolayer on plastic, start at this step. The following protocol applies to cells growing in a 100 mm dish.
7. Cryopreservation of cells
NOTE: Cryopreservation of cells can be accomplished from a single cell suspension originating from either salisphere or monolayer grown cells.
Two-three days after plating cells from digested tissue onto BMM, cells will readily form small clusters that will continue to expand in size up to 15-20 cells per cluster (Figure 2A). Cellular debris and detached dead cells are typically seen and should be removed by aspirating and replenishing with fresh media. Cells will continue to proliferate as salispheres for about 3-10 days, or as long as the BMM layer remains intact. Occasionally, due to partial breakdown of the BMM, cells will become attached to the underlying plastic and begin to proliferate as a monolayer. Salispheres grown on BMM will exhibit variability in size and structural complexity. Salispheres can be maintained by passing them onto freshly prepared BMM as described in the protocol. Within 2-3 days after passing onto fresh BMM, the cells will reform into spheres. Salisphere cells can also be plated onto cell culture-treated plastic and grown as a monolayer where they exhibit morphology consistent with cells of epithelial origin as shown in Figure 2B. While the salisphere cells grown on BMM as salispheres are likely to maintain a phenotype more characteristic of salivary tissue, the cells grown as a monolayer can be advantageous for some experimental protocols. More extensive characterization will need to be performed to determine to what extent the cells maintain a salivary phenotype when grown on a monolayer as compared to cells grown as salispheres.
Figure 1: Initial processing of human submandibular glands for salisphere preparation. Excised salivary gland tissue approximately 1 cm in diameter (A) is mechanically minced into smaller pieces using sharp scissors (B) until the gland is separated into digestible pieces of approximately 1-2 mm in size (C). The glandular pieces are then incubated in the dispase/collagenase solution for 30-90 min with periodic passage through serological pipettes until the sample is digested to mostly single cells or small clumps of cells (D). Please click here to view a larger version of this figure.
Figure 2: Primary human salisphere cells can be cultured as spheres on the basement membrane matrix or as a monolayer on treated cell culture dishes. Following initial digestion of salivary tissue, the digested glands are plated directly onto BMM and cultured for 3-10 days. Cells are fed every 2-3 days to provide fresh nutrients. Once the primary salispheres develop, the matrices can be digested in dispase/collagenase solution, trypsinized to generate single cells, and re-plated onto fresh BMM where they reform into spheres (A) or plated onto cell culture dishes where they readily form a cobblestone morphology typical of an epithelial monolayer (B). Please click here to view a larger version of this figure.
Salivary dysfunction represents a concern for the quality of life for those suffering from Sjögren's syndrome as well as those undergoing radiation therapy for cancers adjacent to the salivary glands3,4,5,16. One proposed therapy to treat these patients is to grow functional salivary stem cells or organoids in vitro, which can then be inserted into damaged salivary gland to replace affected tissue9. Additionally, salivary glands are often a site for persistence and transmission of human pathogens. For example, human herpesviruses such as human cytomegalovirus (HCMV) are known to infect and use the salivary glands and saliva to transmit virus to new hosts7,8,17. The molecular mechanisms underlying viral persistence in the salivary gland and movement to saliva remain unknown. The development of in vitro salivary cell systems will provide an essential model system to explore this mechanistic information.
We report here a robust protocol for generating primary salivary "salispheres" that can be grown in vitro either as clusters on BMM or as monolayers on plastic. The ability to culture and propagate primary human salivary gland epithelial cells represents an important platform on which researchers can (1) potentially develop replacement therapies for patients with salivary gland deficiencies for whom no other options exist; (2) better understand the basic physiology underlying salivary gland development, proliferation, secretion, etc.; and (3) define mechanisms used by pathogens to replicate and spread to new hosts.
Using these salivary cell cultures, we have reported that HCMV requires the pentameric glycoprotein complex for primary infection and also that the virus persists for an extended period, reminiscent of what occurs with HCMV in vivo7. Moreover, our functional studies revealed that the salivary cultures do not contain contaminating fibroblasts as fibroblast tropic, lab adapted viruses fail to infect and replicate in the primary salivary derived cells7. While we have used this protocol to generate cells for the evaluation of HCMV replication and spread in a primary salivary system, this protocol could readily be adapted to generate salivary cells useful for the wide range of research topics mentioned above. Additionally, this protocol could be adapted to suit the needs and budget of each individual researcher. While we have not validated other conditions ourselves, others have reported success growing salivary epithelial cells under different media conditions. For example, Dulbecco's modified Eagle's medium (DMEM):F12 mixture supplemented with epidermal growth factor and fibroblast growth factor-2 has been reported to promote robust growth of salivary cells18. Alternatively, Nam et al. use minimal essential media supplemented with fetal bovine serum before transferring the cells to a serum-free version of a keratinocyte growth media and have reported robust growth of salivary cells on plastic15. Thus, it does not appear that the salivary epithelial cells exhibit an absolute requirement for one particular media type, but rather appear to grow and proliferate on a number of commercially available media types.
In addition to media formulation, different basement membrane formulations could be evaluated for their abilities to support robust salivary epithelial cell growth. Growth of cells on commercially available basement membrane-containing matrixes readily yield salispheres and provides a simple, albeit expensive culturing system7,19. Similar to that discussed above concerning choice of media for cell growth, researchers have reported growth and development of salispheres on a number of different matrices and hydrogel systems. Hydrogels made from hyaluronic acid have the added benefit in creating an extracellular matrix crosslinked with desired chemical constituents to study their interactions and effects on cells. Using primary human tissue derived salivary cells, Srinivasan et al. reported success in growth and maintenance of a salivary progenitor cell population in hyaluronic acid hydrogels; increased progenitor cell growth was further observed when the hydrogels were incorporated with peptides derived from the basement membrane proteins such as perlecan and laminin20. Another system recently developed by Foraida et al. report using "electrospinning" to develop a nanofiber scaffold made of poly(lactic-co-glycolic acid) (PLGA). The PLGA hydrogels with added elastin were found to readily promote the development of a polarized submandibular cell system, which may be useful in ascertaining how cell polarization influences salivary biology and biochemistry21.
In this protocol, we have presented a simple method for the isolation and growth of primary salivary gland-derived epithelial cells. This protocol results in the rapid outgrowth of an epithelial cell population that can be maintained on average for 5-8 passages. It is critical to monitor the tissue during treatment with dispase/collagenase to ensure appropriate digestion as mentioned in the protocol. Incomplete digestion will severely diminish the number of salispheres that survive. It is also important to monitor the cultures for the outgrowth of fibroblasts that have an elongated shape and are very distinct from the polygonal epithelial cells that typically grow in discrete patches or clumps. We have used this protocol for the isolation of epithelial cells from humans and mice, but it seems likely that it could be adapted for use with other mammalian systems. Moreover, this protocol could be further modified by using additional purification steps based on cell surface marker expression and flow cytometry that could lead to the generation of more homogenous initial cell populations. Similarly, this protocol could be used to determine how different media or matrix/hydrogels formulation lead to the outgrowth of specific cell types when first generating the salispheres. In conclusion, this protocol should serve as a robust starting platform for the isolation and growth of primary salivary cells which can readily be adapted for a wide variety of experimental protocols and research areas.
The authors have nothing to disclose.
We would like to thank James P. Bridges for providing significant guidance on the methodologies involved for culturing primary cells. Matthew J. Beucler was supported by National Institutes of Health Training Grant T32-ES007250. This work was also supported by National Institutes of Health grants R01-AI121028 and R21-DE026267 awarded to William E. Miller.
100 mm culture dishes | Thermo Scientific | 172931 | |
15 mL conical tubes | Thermo Scientific | 339651 | |
50 mL conical tubes | Thermo Scientific | 339653 | |
Bronchial Epithelial Cell Growth Media | Lonza | CC-3171 | Add bullet kit as per manufacturer's instructions. Supplement with 20 mL of charcoal stripped serum. |
Cell strainer 70 µm nylon mesh | Fisher | 22-363-548 | |
Charcoal stripped fetal bovine serum | Gibco | 12676-029 | |
Collagenase type III | Worthington | LS004182 | Store at 4 °C. |
Cryogenic Tube | Fisher | 5000-0020 | |
Dispase | Cell Applications | 07923 | Dissolve collagenase to make a 0.15% (w/v) stock. Filter sterilize then store at -20 °C. |
Dissecting scissors | Fisher | 08-940 | |
Dulbecco phosphate buffered saline | Corning | 55-031-PC | |
General Chemicals | Sigma | ||
PathClear Basement membrane extract | Cultrex | 3432-005-01 | Thaw at 4 °C at least 24 hr prior to use. Always handle on ice. |
Six-well culture dishes | Falcon | 353046 | |
Surgical forceps | Fisher | 22-079-742 | |
Trypsin-EDTA solution | Corning | 25-052-CI |