Targeting the Dectin-1 Receptor via Beta-Glucan Microparticles to Modulate Alternatively Activated Macrophage Activity and Inhibit Alternative Activation / INFLUENCING PROFIBROTIC MACROPHAGE POLARIZATION AND ACTIVITY USING YEAST-DERIVED MICROPARTICLES

Imran Hayat, Aaron

January 2021

Idiopathic Pulmonary Fibrosis (IPF) is a debilitating respiratory disorder that is characterized by a progressive decline in lung function. Originating through unknown etiology, it is essentially an unchecked wound healing response that causes the build-up of excessive scar tissue in the lung interstitial tissue with a heavy toll on the patient’s respiratory capacity. Pro-fibrotic alternatively activated macrophages (M2) have been linked as an important contributor to the fibrotic remodeling of the lung. Previous Ask research indicates that targeting M2 macrophages is possible through the use of the Dectin-1 receptor, a transmembrane cell surface receptor found in high abundance on M2 macrophages. Activating the Dectin-1 receptor through the use of beta-glucan, a ligand the receptor has a high affinity for, initiates a pro-inflammatory response within the naturally immunosuppressive macrophage and can alter its activity to be less fibrogenic. Our data suggest that M2 polarization of naïve macrophages can be inhibited in vitro by beta-glucan microparticles. Additionally, we have found that polarized M2 macrophages adopt M1-like characteristics when treated with beta-glucan microparticles, in a process that is largely Dectin-1 dependent. M2 cell surface marker CD206, increased levels of which are associated with rapidly progressing IPF, shows significantly decreased frequency of expression in M2 macrophages treated with beta-glucan microparticles. Our assessment for cell-specific uptake of beta-glucan microparticles suggests an important role of the Dectin-1 receptor for significantly increased uptake in murine wild-type M2 macrophages relative to their Dectin-1 knockout counterpart. The use of beta-glucan microparticles as a potential anti-fibrotic therapeutic was assessed in the bleomycin model of fibrotic lung disease. Mice given bleomycin and treated with beta-glucan displayed decreased soluble collagen content and TGFB expression within lung homogenate relative to fibrotic bleomycin control mice. Overall, these results provide insight into the use of beta-glucan as a potential activity modulator of macrophage function in IPF and the possibility of its use as a therapeutic. / Thesis / Master of Science (MSc)

PROFIBROTIC MACROPHAGE POLARIZATION AND REPROGRAMMING IN PRECISION CUT LUNG SLICES

Kumaran, Vaishnavi

January 2024

Idiopathic pulmonary fibrosis (IPF) is a progressive lung disease with worsening respiratory symptoms and physiological impairment. Pulmonary fibrosis is a chronic lung disease characterized by forming scar tissue (fibrosis) in the lungs. Alternatively activated macrophages (M2) known as pro-fibrotic are known to contribute to the fibrotic remodeling of the lung. In addition to the polarization of slices from naïve to pro-fibrotic, the addition of anti-fibrotic therapeutics reprogram slices back to a naïve condition. To polarize the slices, naïve slices are incubated with a previously investigated method in the lab known as the polarization cocktail. The polarization cocktail can be achieved by adding of IL-4, IL-6 and IL-13 to naïve(M0) slices in the Precision Cut lung slice (PCLS) model. For the therapeutic model, slices are incubated with the polarization cocktail and subsequently with the therapeutic. Our results have shown that the precision cut lung slice model can mimic previously investigated in-vivo experiments with the polarization cocktail. Secondly, the addition of therapeutics result in the slices exhibiting lower amounts of M2 markers and arginase activity concluding the model is suitable for the polarization and reprogramming of macrophages. / Thesis / Master of Science in Medical Sciences (MSMS)

Idiopathic pulmonary fibrosis

IPF

PCLS

Alternatively activated macrophage

M2

M1

Classically activated macrophage

Interstitial lung disease

Fibrotic lung disease

IHC

TGF-B

Beta-glucan

Microparticle

Yeast-Derived Beta Glucan

Ex vivo Models