Abstract
Host redox dependent physiological responses play crucial roles in the determination of mycobacterial infection process. Mtb explores oxygen rich lung microenvironments to initiate infection process, however, later on the bacilli adapt to oxygen depleted conditions and become non-replicative and unresponsive toward anti-TB drugs to enter in the latency stage. Mtb is equipped with various sensory mechanisms and a battery of pro- and anti-oxidant enzymes to protect themselves from the host oxidative stress mechanisms. After host cell invasion, mycobacteria induces the expression of NADPH oxidase 2 (NOX2) to generate superoxide radicals (), which are then converted to more toxic hydrogen peroxide (H2O2) by superoxide dismutase (SOD) and subsequently reduced to water by catalase. However, the metabolic cascades and their key regulators associated with cellular redox homeostasis are poorly understood. Phagocytosed mycobacteria en route through different subcellular organelles, where the local environment generated during infection determines the outcome of disease. For a long time, mitochondria were considered as the key player in the redox regulation, however, accumulating evidences report vital role for peroxisomes in the maintenance of cellular redox equilibrium in eukaryotic cells. Deletion of peroxisome-associated peroxin genes impaired detoxification of reactive oxygen species and peroxisome turnover post-infection, thereby leading to altered synthesis of transcription factors, various cell-signaling cascades in favor of the bacilli. This review focuses on how mycobacteria would utilize host peroxisomes to alter redox balance and metabolic regulatory mechanisms to support infection process. Here, we discuss implications of peroxisome biogenesis in the modulation of host responses against mycobacterial infection.
Highlights
According to the World Health Organization (WHO) report approximately 10.4 million global populations are infected with tuberculosis (TB) (WHO Global Tuberculosis Report 2017)
mannose receptors (MRs) mediated Mycobacterium tuberculosis (Mtb) entry was found to alter the expression of PPARG followed by trans-repression of different pro-inflammatory cytokines and transcription factors (NFκB, AP-1, STAT), TNFA, IL6, CXCL8, and COX2 enzyme production which are important in the generation of inflammatory responses through production of prostaglandins in macrophages (Rajaram et al, 2010)
Peroxisomes play an important role in the induction of innate immune responses during viral and bacterial infections (Lazarow, 2011; Odendall and Kagan, 2013; Boncompain et al, 2014). These studies have shown that innate immune receptors such as RIG-I-like Receptor (RLR) proteins determines the fate of infection in human cells by inducing the expression of different forms of interferons (IFNs) that were majorly found in peroxisomes (Dixit et al, 2010; Odendall and Kagan, 2013; Pandey et al, 2014)
Summary
According to the World Health Organization (WHO) report approximately 10.4 million global populations are infected with tuberculosis (TB) (WHO Global Tuberculosis Report 2017). Our group has shown that Mtb ESAT-6 family proteins esxA dampen macrophage immune responses, by inducing oxidative stress mediated genomic instability to promote mycobacterial persistence inside the host cells (Mohanty et al, 2016). The most extensively studied PPARG isoform, which is a ligand-dependent transcription factor expressed in alveolar macrophages, lymphocytes, and dendritic cells (Tyagi et al, 2011), plays an important role in immunoregulation, energy and glucose metabolism, disease progression and pathology of bacterial infection (Reddy et al, 2016; Arnett et al, 2018).
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