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Soluble factor mediated manipulation of mesenchymal stem cell mechanics for improved function of cell-based therapeuticsGhosh, Deepraj 21 September 2015 (has links)
Mesenchymal stem cells (MSCs) are bone marrow derived multipotent cells with the ability to self-renew and differentiate into multiple connective cell lineages. In vivo, MSCs travel from the bone-marrow to the inflammatory sites and actively participate in remodeling and regeneration process under the influence of soluble growth factors. Due to these inherent properties, MSCs have emerged as an ideal candidate for diverse regenerative therapeutic applications. The development of MSC-based therapies requires in vitro expansion of MSCs; however, MSC expansion results in phenotypical changes that have limited its efficacy upon reintroduction in vivo. In order to increase the efficacy of MSC-based therapeutics, it is critical for us to improve the current understanding of MSC interactions with its niche specific factors and explore new methods to enhance MSC function in vivo.
We used tumor conditioned media, which contains soluble factors secreted by tumor cells in culture (TCM), and inflammatory niche-specific soluble factors, such as platelet derived growth factor (PDGF) and transforming growth factor-β1 (TGF-β1), to characterize the mechanical response of MSCs. The intracellular mechanical properties of MSCs were dramatically altered in response to soluble factors and MSCs displayed cytosolic stiffening in response to TCM and TGF-β1. Although PDGF treated cells did not elicit any mechanical response, blocking PDGF signaling with a small molecule inhibitor reversed the stiffening response in TGF-β1 treated cells, indicating crosstalk between these two pathways is essential in TGF-β1 mediated cell stiffening. Furthermore, a genome-wide microarray analysis revealed TGF-β1 dependent regulation of cytoskeletal actin-binding protein (ABP) genes. Actin crosslinking and bundling protein genes, which regulate cytosolic rheology through changes in semiflexible actin polymer meshworks, were upregulated with TGF-β1 treatment.
Since TGF-β1 treatment profoundly altered the MSC phenotype after relatively short exposure times, we sought to understand if pretreated cells could sustain these enhanced characteristics leading to higher efficacy in vivo. We found that MSCs pretreated with TGF-β1 displayed enhanced adhesive properties while maintaining the expression profile of surface adhesion molecules even after removal of stimulus. Additionally, pretreated MSCs exposed to lineage specific induction media, demonstrated superior differentiation potential along multiple lineages. Based on the large number of sustained changes, TGF-β1 pretreated cells were used to treat full thickness skin wounds for in vivo wound healing model to determine their therapeutic efficacy. TGF-β1 pretreated MSCs increased wound closure rate and displayed enhanced migration of MSCs towards the center of the wound compared to the control cells.
In conclusion, soluble factor pretreated MSCs with altered mechanical properties displayed significantly improved cell functions leading to highly efficient tissue regeneration in vivo. Mechanical priming of MSCs with niche specific factors prior to transplantation can become a viable strategy to maximize their therapeutic potential.
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Identifying signaling differences between GPCR-induced growth factor receptor transactivation and direct ligand activationKouchmeshky, Azita 14 March 2014 (has links)
Growth factor receptors have significant effects on various normal function of body such as cell proliferation, differentiation and apoptosis. They are also involved in neuronal function and dysfunction, cardiovascular diseases, and malignancies. Recently, multiple G protein-coupled receptors (GPCRs) have been shown to transactivate receptor tyrosine kinases (RTKs). Since both classes of receptors have complicated downstream cascades individually, understanding the signaling differences between GPCR-induced growth factor receptor transactivation and direct ligand activation is an important challenge. To clarifying this phenomenon we investigated the phosphorylation profile and downstream effectors of ligand-activated vs. transactivated PDGF?? receptors. Dopamine receptors (one of the receptors of the GPCRs family) were used to compare the PDGF?? receptor phosphorylation and activity during direct activation and transactivation. Dose-response and time-course data between these two stimuli were evaluated. Furthermore, the phosphorylation site profiles and the intracellular signaling pathways of PDGF?? receptor after direct activation and transactivation were examined. In addition, possible synergic effects between transactivation and direct activation were explored. The results of this project showed that the phosphorylation profile and downstream effectors of ligand activated receptors versus transactivated receptors are different. Our data indicated that transactivation-induced pathways are more involved in survival and proliferation effects compared to ligand activation. This research answered basic questions about transactivation phenomena and proposes that these transactivation pathways could be exploited as a therapeutic approach for neurodegenerative diseases.
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