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Modulation Of Bacterial Pathogenesis By CurcuminMarathe, Sandhya 02 1900 (has links) (PDF)
Foodborne diseases are one among the diseases with high morbidity and mortality rate. The concern is raised with the emergence of pathogenic strains that are resistant to the available set of antibiotics. Conventional regimens fail to treat the infections caused by these pathogens prolonging the sickness leading to increased morbidity and mortality. The situation can get further complicated with the dietary intake of the host. Of late it has been understood that the dietary flavonoids play an important role in regulating the immune system. Curcumin, a pigment from turmeric, is one among such bioflavonoid with an immunomodulatory potential.
Curcumin has been a front-line topic of mainstream scientific research for a variety of diseases from cancer to Alzheimer’s to infectious diseases. Curcumin being considered as a spicy panacea is not a remedy for all diseases. Its ability to act differentially as an antioxidant or pro-oxidant can be either beneficial or harmful for the host. It exhibits antioxidant properties at concentrations achievable in the body; this can make the host vulnerable to infections due to the suppression of innate immune responses. Curcumin also suppresses the type 1 immune response, which might lead to alleviation of type 1 immune response disorders. However, the inhibition of type 1 immune response might invite infections with opportunistic pathogens.
We have chosen curcumin to assess the effect of diet on the regulation of pathogenesis of Salmonella along with few medically important pathogens like Yersinia enterocolitica, Staphylococcus aureus, Shigella flexneri and Listeria monocytogenes. The thesis is divided into five chapters. As the main focus of the thesis is on Salmonella, in Chapter 1 we introduce diverse aspects of curcumin and the basic biology of Salmonella. Initially the properties of curcumin, the molecule of interest are introduced followed by brief overview to Salmonella biology and pathogenesis. Various activities of curcumin dealing with the variety of diseases are discussed. Further, the introduction to the intricate underlying mechanisms and the functional determinants of curcumin is given. The subsequent sections give an overview of different phases of Salmonella pathogenesis and the molecular mechanisms of Salmonella virulence and host defense. Towards the end of the chapter we discuss the strength, limitations and the distinctive characteristics of the murine model of typhoid fever.
Curcumin has gained immense importance for its vast therapeutic and prophylactic applications. Its anti-bacterial effect has been demonstrated in bacteria, like B. subtilis, H. pylori and E. coli. Contrary to this, the results of the Chapter 2 reveals that curcumin at a nontoxic concentration to both host and pathogen, regulates the defense pathways of Salmonella enterica serovar Typhimurium (S. Typhimurium) to enhance its pathogenicity. In a murine model of typhoid fever, we observed higher bacterial load in reticuloendothelial organs when infected with curcumin-treated Salmonella. Curcumin increased the resistance of S. Typhimurium against antimicrobial agents like antimicrobial peptides, reactive oxygen and nitrogen species. It up-regulated the genes involved in resistance against antimicrobial peptides - pmrD and pmrHFIJKLM and genes with antioxidant function - mntH, sodA and sitA. We implicate that the iron chelation property of curcumin has a role in regulating mntH and sitA. Interestingly, we see that the curcumin-mediated modulation of pmr genes is through the PhoPQ two-component regulatory system (TCS). Curcumin downregulates SPI-1 genes required for entry into epithelial cells and upregulates SPI-2 genes required for intracellular survival, through PhoPQ TCS. Thus, this common regulator (PhoPQ) could explain curcumin's mode of action.
Another important factor for the pathogen’s success is its ability to counteract the action of antibiotics. Almost all the bactericidal antibiotics act via production of reactive oxygen species in the bacteria. Curcumin has anti-oxidant property that might interfere with the action of antibiotics. Ciprofloxacin is a commonly used anti-typhoidal drug. It kills the bacteria by inhibiting DNA replication and increasing reactive oxygen species in bacterial cell. In Chapter 3 we present the results obtained after the investigation of the interference of curcumin with the anti-bacterial action of ciprofloxacin against Salmonella. We found that curcumin indeed increased the proliferation of Salmonella Typhi and Salmonella Typhimurium in ciprofloxacin treated macrophages by reducing the ciprofloxacin-induced reactive oxygen species. It also inhibited ciprofloxacin mediated DNA damage and the resultant SOS response and filamentation. However, curcumin was unable to rescue the ciprofloxacin induced gyrase inhibition. The reduced antibiotic (ciprofloxacin) efficacy against Salmonella by curcumin might aggravate the disease. Thus, the results of chapter 1 and 2 urge us to rethink the indiscriminate use of curcumin especially during Salmonella outbreaks.
Bacteria modulate its virulence determinants in response to the environmental cues. Salmonella being a foodborne pathogen has a very likely chance of getting exposed to turmeric and hence curcumin. In Chapter 4 we have assessed the modulation of motility of S. Typhimurium, an important virulence determinant, by curcumin. We show that curcumin reduced the motility of the S. Typhimurium by decreasing the flagellar density around it. Surprisingly, this was achieved without affecting the expression of the flagellin gene and protein. Curcumin physically adhered to the flagella making it fragile and breaking it into fragments. This can hinder bacterial motility, chemotaxis, adherence and invasion into the host cells. However, aflagellate bacteria are hypervirulent as is the case with our experimental results with curcumin treated bacteria.
Curcumin regulates myriad of bacterial (Salmonella) activities increasing its pathogenicity. Curcumin is known to regulate the host defenses in response to the disease. In Chapter 5 we have sought to address the effect of curcumin treatment of host cells on the outcome of infection by different pathogens. Pathogens have evolved different strategies to evade the host innate immune system, one of them being avoiding lysosome mediated degradation. Pathogens like Salmonella, Yersinia, Mycobacterium and Staphylococcus have acquired molecular machinery to inhibit the fusion of the pathogen containing vacuole with lysosomes and multiply within the vacuole whereas other pathogens like Shigella, Listeria and Rickettsia escape into and multiply in the cytosol. In our study we show that pretreatment of macrophage with curcumin increased the fold proliferation of S. Typhimurium, S. aureus and Y. enterocolitica whereas decreased that of S. flexneri and L. monocytogenes. From the results obtained, we can state that curcumin differentially regulates the pathogenesis of vacuolar and cytosolic pathogen. We hypothesized that curcumin pretreatment stabilizes the membrane of pathogen containing vacuole retarding the lysis of the phagolysosome harboring the cytosolic pathogen and hence facilitating its clearance. We indeed observed that the membrane stabilizing effect of curcumin led to increased fusion of cytosolic pathogen with the lysosome, decreasing its proliferation in the cells. As the vacuolar pathogens have an inherent ability to inhibit this fusion, they proliferate better in curcumin treated cells.
In a nutshell curcumin can have multiple and sometimes unexpected effects not only on a pathogen’s potential to successfully cause infection but also on the host’s ability to counter it.
A brief summary of the study that does not directly deal with the modulation of bacterial pathogenesis by curcumin is included in the Appendix. In this study a novel, simple, sensitive and efficient PCR based assay was devised to detect Salmonella contamination in milk, fruit juice and ice-cream without any pre-enrichment.
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