Salivary gland acinar cells regenerate functional glandular structures in modified hydrogels

Xerostomia, a condition resulting from irradiation of the head and neck, affects over 40,000 cancer patients each year in the United States. Direct radiation damage of the acinar cells that secrete fluid and protein results in salivary gland hypofunction. Present medical management for xerostomia for patients treated for upper respiratory cancer is largely ineffective. Patients who have survived their terminal diagnosis are often left with a diminished quality of life and are unable to enjoy the simple pleasures of eating and drinking. This project aims to ultimately reduce human suffering by developing a functional implantable artificial salivary gland. The goal was to create an extracellular matrix (ECM) modified hyaluronic acid (HA) based hydrogel culture system that allows for the growth and differentiation of salivary acinar cells into functional acini-like structures capable of secreting large amounts of protein and fluid unidirectionally and to ultimately engineer a functional artificial salivary gland that can be implanted into an animal model.;A tissue collection protocol was established and salivary gland tissue was obtained from patients undergoing head and neck surgery. The tissue specimen was assessed by histology and immunohistochemistry to establish the phenotype of normal salivary gland cells including the native basement membranes. Hematoxylin and eosin staining confirmed normal glandular tissue structures including intercalated ducts, striated ducts and acini. alpha-Amylase and periodic acid schiff stain, used for structures with a high proportion of carbohydrate macromolecules, preferentially stained acinar cells in the tissue. Intercalated and striated duct structures were identified using cytokeratins 19 and 7 staining. Myoepithelial cells positive for cytokeratin 14 were found wrapped around the serous and mucous acini. Tight junction components including ZO-1 and E-cadherin were present between both ductal and acinar cells. Ductal and acinar cells were identified in cultured cells from dispersed tissue. Biomarker studies with the salivary enzyme, alpha-amylase, and tight junction proteins, such as zonula occludens-1 and E-cadherin, confirmed the phenotype of these cells. Strong staining for laminin and perlecan/HSPG2 were noted in basement membranes and perlecan also was secreted and organized by cultured acinar populations, which formed lobular structures that mimicked intact glands when cultured on Matrigel(TM) or a bioactive peptide derived from domain IV of perlecan (PlnDIV). On either matrix, large acini-like lobular structures grew and formed connections between the lobes. alpha-Amylase secretion was confirmed by staining and activity assay. Biomarkers including tight junction protein E-cadherin and water channel protein, aquaporin 5 (AQP5) found in tissue, were expressed in cultured acinar cells. Cells cultured on Matrigel(TM) or PlnDIV peptide organized stress fibers and activated focal adhesion kinase (FAK).;HA, a natural polysaccharide and a major component of the ECM, can be used to generate soft and pliable hydrogels. A culture system consisting of HA hydrogel and PlnDIV peptide was used to generate a 2.5D culture system. Acinar cells cultured on these hydrogels self-assembled into lobular structures and expressed tight junction components such as ZO-1. Acini-like structures were stained for the presence of alpha-amylase. Live/dead staining revealed the presence of apoptotic cells in the center of the acini-like structures, indicative of lumen formation. The functionality of these acini-like structures was studied by stimulating them with neurotransmitters to enhance their fluid and protein production. Acini-like structures treated with norepinephrine and isoproterenol showed increased granule formation as observed by phase contrast microscopy and alpha-amylase staining in the structures. Lobular structures on hydrogels were treated with acetylcholine to increase fluid production. The increase in intracellular calcium due to the activation of the M3 muscarinic receptor via binding to acetylcholine was measured. Although cells in 2D did not show any differences, cells on the 2.5D hydrogels showed an increase in intracellular calcium.;The culture system consisting of PlnDIV peptide reported here will aid the development of an artificial salivary gland which will foster formation of functional salivary units capable of secreting salivary fluid and which can be implanted into patients to relieve xerostomia. Future experiments will involve implantation of these hydrogels in animal models to test their functionality in vivo.