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1. Microfluidic coaxial 3D bioprinting of cell-laden microfibers and microtubes for salivary gland tissue engineering

   https://doi.org/10.1016/j.bioadv.2023.213588  

   Yin, Yu; Vázquez-Rosado, Ephraim J.; Wu, Danielle; Viswananthan, Vignesh; Farach, Andrew; Farach-Carson, Mary C.; Harrington, Daniel A. (November 2023, Biomaterials Advances)

   Replacement therapy for the salivary gland (SG) remains an unmet clinical need. Xerostomia (“dry mouth”) due to hyposalivation can result from injury or disease to the SG, such as salivary acinar death caused by radiation therapy (RT) for head and neck squamous cell carcinoma (HNSCC). Currently, only palliative treatments exist for xerostomia, and many patients endure deteriorated oral health and poor quality of life. Tissue engineering could offer a permanent solution for SG replacement by isolating healthy SG tissues prior to RT, expanding its cells in vitro, and recreating a functional salivary neogland for implantation post-RT. 3D bioprinting methods potentiate spatial cell deposition into defined hydrogel-based architectures, mimicking the thin epithelia developed during the complex branching morphogenesis of SG. By leveraging a microfluidics-based bioprinter with coaxial polymer and crosslinker streams, we fabricated thin, biocompatible, and reproducible hydrogel features that recapitulate the thin epithelia characteristics of SG. This flexible platform enabled two modes of printing: we produced solid hydrogel fibers, with diameters <100 μm, that could be rastered to create larger mm-scale structures. By a second method, we generated hollow tubes with wall thicknesses ranging 45-80 μm, total tube diameters spanning 0.6 – 2.2 mm, and confirmed tube patency. In both cases, SG cells could be printed within the thin hydrogel features, with preserved phenotype and high viability, even at high density (5.0 × 10^6 cells/mL). Our work demonstrates hydrogel feature control across multiple length scales, and a new paradigm for addressing SG restoration by creating microscale tissue engineered components. 

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2. Matrix Degradability Contributes to the Development of Salivary Gland Progenitor Cells with Secretory Functions

   https://doi.org/10.1021/acsami.3c03064  

   Metkari, Apoorva S.; Fowler, Eric W.; Witt, Robert L.; Jia, Xinqiao (July 2023, ACS Applied Materials & Interfaces)

   Synthetic matrices that are cytocompatible, cell adhesive and cell responsive are needed for the engineering of implantable, secretory salivary gland constructs to treat radiation induced xerostomia or dry mouth. Here, taking advantage of the bioorthogonality of the Michael-type addition reaction, hydrogels with comparable stiffness but varying degrees of degradability (100% degradable: 100DEG; 50% degradable: 50DEG; and non-degradable: 0DEG) by cell-secreted matrix metalloproteases (MMPs) were synthesized using thiolated HA (HA-SH), maleimide (MI)-conjugated integrin-binding peptide (RGD-MI) and MI-functionalized peptide crosslinkers that are protease degradable (GIW-bisMI) or non-degradable (GIQ-bisMI). Organized multicellular structures developed readily in all hydrogels from dispersed primary human salivary gland stem/progenitor cells (hS/PCs). As the matrix became progressively degradable, cells proliferated more readily and the multicellular structures became larger, less spherical, and more lobular. Immunocytochemical analysis showed positive staining for stem/progenitor cell markers CD44 and keratin 5 (K5) in all three types of cultures, and positive staining for the acinar marker α-amylase under 50DEG and 100DEG conditions. Quantitatively at the mRNA level, the expression levels of key stem/progenitor markers KIT, KRT5, and ETV4/5 were significantly increased in the degradable gels as compared to the non-degradable counterparts. Western blot analyses revealed that imparting matrix degradation led to >3.8-fold increase in KIT expression by day 15. The MMP-degradable hydrogels also promoted the development of a secretary phenotype, as evidenced by the upregulation of acinar markers α-amylase (AMY), aquaporin-5 (AQP5), and sodium-potassium-chloride cotransporter 1 (SLC12A2). Collectively, we show that cell-mediated matrix remodeling is necessary for the development of regenerative pro-acinar progenitor cells from hS/PCs. 

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3. Promoting Polarization and Differentiation of Primary Human Salivary Gland Stem/Progenitor Cells in Protease-Degradable Hydrogels via ROCK Inhibition

   https://doi.org/10.1021/acsami.4c22507  

   Metkari, Apoorva S; Witt, Robert L; Cognetti, David M; Dhong, Charles; Jia, Xinqiao (March 2025, ACS Applied Materials & Interfaces)
4. Viral and cellular determinants of polarized trafficking of viral envelope proteins from insect-specific and insect-vectored viruses in insect midgut and salivary gland cells

   https://doi.org/10.1128/jvi.00540-24  

   Hodgson, Jeffrey J; Chen, Robin Y; Blissard, Gary W; Buchon, Nicolas (September 2024, Journal of Virology)

   van_Oers, Monique M (Ed.)

   ABSTRACT Systemic viral infection of insects typically begins with the primary infection of midgut epithelial cells (enterocytes) and subsequent transit of the progeny virus in an apical-to-basal orientation into the hemocoel. For insect-vectored viruses, an oppositely oriented process (basal-to-apical transit) occurs upon secondary infection of salivary glands and is necessary for virus transmission to non-insect hosts. To examine this inversely oriented virus transit in these polarized tissues, we assessed the intracellular trafficking of two model viral envelope proteins (baculovirus GP64 and vesicular stomatitis virus G) in the midgut and salivary gland cells of the model insect,Drosophila melanogaster. Using fly lines that inducibly express either GP64 or VSV G, we found that each protein, expressed alone, was trafficked basally in midgut enterocytes. In salivary gland cells, VSV G was trafficked apically in most but not all cells, whereas GP64 was consistently trafficked basally. We demonstrated that a YxxØ motif present in both proteins was critical for basal trafficking in midgut enterocytes but dispensable for trafficking in salivary gland cells. Using RNAi, we found that clathrin adaptor protein complexes AP-1 and AP-3, as well as seven Rab GTPases, were involved in polarized VSV G trafficking in midgut enterocytes. Our results indicate that these viral envelope proteins encode the requisite information and require no other viral factors for appropriately polarized trafficking. In addition, they exploit tissue-specific differences in protein trafficking pathways to facilitate virus egress in the appropriate orientation for establishing systemic infections and vectoring infection to other hosts. IMPORTANCEViruses that use insects as hosts must navigate specific routes through different insect tissues to complete their life cycles. The routes may differ substantially depending on the life cycle of the virus. Both insect pathogenic viruses and insect-vectored viruses must navigate through the polarized cells of the midgut epithelium to establish a systemic infection. In addition, insect-vectored viruses must also navigate through the polarized salivary gland epithelium for transmission. Thus, insect-vectored viruses appear to traffic in opposite directions in these two tissues. In this study, we asked whether two viral envelope proteins (VSV G and baculovirus GP64) alone encode the signals necessary for the polarized trafficking associated with their respective life cycles. UsingDrosophilaas a model to examine tissue-specific polarized trafficking of these viral envelope proteins, we identified one of the virus-encoded signals and several host proteins associated with regulating the polarized trafficking in the midgut epithelium. 

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5. Basement Membrane Mimetic Hydrogel Cooperates with Rho‐Associated Protein Kinase Inhibitor to Promote the Development of Acini‐Like Salivary Gland Spheroids

   https://doi.org/10.1002/anbr.202300088  

   Fowler, Eric W.; Witt, Robert L.; Jia, Xinqiao (November 2023, Advanced NanoBiomed Research)

   Successful engineering of functional salivary glands necessitates the creation of cell‐instructive environments for ex vivo expansion and lineage specification of primary human salivary gland stem cells (hS/PCs). Herein, basement membrane mimetic hydrogels are prepared using hyaluronic acid, cell adhesive peptides, and hyperbranched polyglycerol (HPG), with or without sulfate groups, to produce “hyperGel+” or “hyperGel”, respectively. Differential scanning fluorescence experiments confirm the ability of the sulfated HPG precursor to stabilize fibroblast growth factor 10. The hydrogels are nanoporous, cytocompatible, and cell‐permissive, enabling the development of multicellular hS/PC spheroids in 14 days. The incorporation of sulfated HPG species in the hydrogel enhances cell proliferation. Culture of hS/PCs in hyperGel+ in the presence of a Rho kinase inhibitor Y‐27632 (Y‐27) leads to the development of spheroids with a central lumen, increases the expression of acinar marker aquaporin‐3 at the transcript level (AQP3), and decreases the expression of ductal marker keratin 7 at both the transcript (KRT7) and the protein levels (K7). Reduced expression of transforming growth factor beta (TGF‐β) targets SMAD2/3 is also observed in Y27‐treated cultures, suggesting attenuation of TGF‐β signaling. Thus, hyperGel+ cooperates with the Rho‐associated protein kinase inhibitor to promote the development of lumened spheroids with enhanced expression of acinar markers. 

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