Channeling macrophage polarization by rocaglates increases macrophage resistance to Mycobacterium tuberculosis

Macrophages contribute to host immunity and tissue homeostasis via alternative activation programs. M1-like macrophages control intracellular bacterial pathogens and tumor progression. In contrast, M2-like macrophages shape reparative microenvironments that can be conducive for pathogen survival or tumor growth. An imbalance of these macrophages phenotypes may perpetuate sites of chronic unresolved inflammation, such as infectious granulomas and solid tumors. We have found that plant-derived and synthetic rocaglates sensitize macrophages to low concentrations of the M1-inducing cytokine IFN-gamma and inhibit their responsiveness to IL-4, a prototypical activator of the M2-like phenotype. Treatment of primary macrophages with rocaglates enhanced phagosome-lysosome fusion and control of intracellular mycobacteria. Thus, rocaglates represent a novel class of immunomodulators that can direct macrophage polarization toward the M1-like phenotype in complex microenvironments associated with hypofunction of type 1 and/or hyperactivation of type 2 immunity, e.g., chronic bacterial infections, allergies, and, possibly, certain tumors.R35 GM118173 - NIGMS NIH HHS; R01 HL126066 - NHLBI NIH HHS; R01 GM120272 - NIGMS NIH HHS; R01 CA218500 - NCI NIH HHS; R01 HL133190 - NHLBI NIH HHS; R33 AI105944 - NIAID NIH HHSPublished versio

Atropisomeric Chromophores as Catalysts and Substrates for Asymmetric Light Induced Transformations

Photochemical transformations hold a unique place as they can provide access to molecules with unique stereochemical and structurally complex scaffolds, thus serving as a complementary approach to thermal transformations. However, asymmetric photoreactions have been under-explored due to the challenges in controlling the nature of the excited state(s). Various elegant strategies have been developed by chemists to address this bottleneck and achieved varying degrees of success. This dissertation describes a novel and unique strategy that employs atropisomeric thioureas as organo-photocatalysts to perform desired chemical transformations. The motivation of the thesis is to develop an alternative strategy that does not depend on energy/electron transfer processes to initiate the photoreactions. This dissertation describes another unique strategy that employs atropisomeric chromophores where axial chirality in the reactant is transferred to point chirality in the photoproduct(s). This research explains about rotamers control in the ground state that allows stereospecific phototransformations in the excited state(s) thus leading to enantioenriched product(s). The chapter 1 introduces the fundamental differences between asymmetric photochemical reactions and conventional thermal method. Further, an overview of various methodologies developed towards asymmetric photochemical transformations are detailed. In chapter 2 and chapter 3, various thiourea-based organo-photocatalysts were developed for enantioselective intramolecular [2+2] photocycloaddition of coumarin derivatives. The atropisomeric thioureas were found to be efficient in promoting the photocycloaddition leading to the corresponding products with high enantioselectivity (77-96% ee) at low catalyst loading (1-10 mol%). The photocatalytic cycle is proposed to proceed by the mechanism of ‘energy sharing’ via the formation of both static and dynamic complexes (exciplex formation), which is promoted by hydrogen bonding. Chapter 4 describes the intermolecular [2+2]-photocycloaddition of coumarin with tetramethylethylene promoted by thiourea catalysts. The photocatalytic cycle of coumarin mediated by thioureas is proposed to proceed via a combination of minimized aggregation, enhanced intersystem crossing and altered excited state lifetime(s), which is promoted by hydrogen bonding. 5 describes the enantiospecific hydrogen abstraction of atropisomeric enone carboxamides leading to spiro-β-lactam photoproduct(s). Divergent photoreactivity was observed based on restricted bond rotation(s) in atropisomeric substrates, when compared to their achiral analogue. The hydrogen abstraction also proceeded efficiently under visible light sensitized irradiation.National Science Foundation NSF Career (CHE-0748525)NSF (CHE-1213880), (CHE-1465075)Center for Sustainable Materials (II A-1355466)NDSU Graduate Dissertation Fellowshi

Photoreactions with a twist: atropisomerism-driven divergent reactivity of enones with UV and visible light

Light-induced transformation of atropisomeric and achiral enones displays divergent reactivity. Photocyclization leading to 3,4-dihydroquinolin-2-one was observed with achiral enone carboxamide, whereas the atropisomeric enone carboxamides underwent hydrogen abstraction leading to spiro-β-lactams. Detailed photochemical, photophysical and theoretical investigations have provided insight into this divergent reactivity and selectivity

Metal-Free Visible Light-Mediated Photocatalysis: Controlling Intramolecular [2 + 2] Photocycloaddition of Enones through Axial Chirality

Atropisomeric enone-imides and enone-amides featuring <i>N</i>-C_Aryl bond rotation were evaluated for intramolecular [2 + 2] photocycloaddition. Straight addition product was observed over cross-addition product with good control over reactivity. The atropselectivity was found to be dependent on the substituent on the aryl ring. Substitution-dependent atropselectivity was rationalized on the basis of a divergent mechanistic pathway