Browsing by Author "Yuan, Ruoxi"

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    Alteration of Lysosome Fusion and Low-grade Inflammation Mediated by Super-low-dose Endotoxin
    Baker, Bianca; Geng, Shuo; Chen, Keqiang; Diao, Na; Yuan, Ruoxi; Xu, Xiguang; Dougherty, Sean; Stephenson, Caroline; Xiong, Huabao; Chu, Hong Wei; Li, Liwu (American Society for Biochemistry and Molecular Biology, Inc, 2015-01-13)
    Background: Super-low-dose endotoxemia contributes to cell stress and low-grade inflammation. Results: Super-low-dose LPS removed Tollip from late endosomes/lysosomes and blocked lysosome fusion with endosomes or autophagosomes. Tollip knock-out mice had impaired wound healing. Conclusion: Super-low-dose LPS leads to cell stress through clearing Tollip and blocking lysosome fusion. Significance: Our data reveal molecular dynamics of innate immunity regulation.
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    Control of lupus nephritis by changes of gut microbiota
    Mu, Qinghui; Zhang, Husen; Liao, Xiaofeng; Lin, Kaisen; Liu, Hualan; Edwards, Michael R.; Ahmed, Sattar Ansar; Yuan, Ruoxi; Li, Liwu; Cecere, Thomas E.; Branson, David B.; Kirby, Jay L.; Goswami, Poorna; Leeth, Caroline M.; Read, Kaitlin A.; Oestreich, Kenneth J.; Vieson, Miranda D.; Reilly, Christopher M.; Luo, Xin M. (2017-07-11)
    Background: Systemic lupus erythematosus, characterized by persistent inflammation, is a complex autoimmune disorder with no known cure. Immunosuppressants used in treatment put patients at a higher risk of infections. New knowledge of disease modulators, such as symbiotic bacteria, can enable fine-tuning of parts of the immune system, rather than suppressing it altogether. Results: Dysbiosis of gut microbiota promotes autoimmune disorders that damage extraintestinal organs. Here we report a role of gut microbiota in the pathogenesis of renal dysfunction in lupus. Using a classical model of lupus nephritis, MRL/lpr, we found a marked depletion of Lactobacillales in the gut microbiota. Increasing Lactobacillales in the gut improved renal function of these mice and prolonged their survival. We used a mixture of 5 Lactobacillus strains (Lactobacillus oris, Lactobacillus rhamnosus, Lactobacillus reuteri, Lactobacillus johnsonii, and Lactobacillus gasseri), but L. reuteri and an uncultured Lactobacillus sp. accounted for most of the observed effects. Further studies revealed that MRL/lpr mice possessed a “leaky” gut, which was reversed by increased Lactobacillus colonization. Lactobacillus treatment contributed to an anti-inflammatory environment by decreasing IL-6 and increasing IL-10 production in the gut. In the circulation, Lactobacillus treatment increased IL-10 and decreased IgG2a that is considered to be a major immune deposit in the kidney of MRL/lpr mice. Inside the kidney, Lactobacillus treatment also skewed the Treg-Th17 balance towards a Treg phenotype. These beneficial effects were present in female and castrated male mice, but not in intact males, suggesting that the gut microbiota controls lupus nephritis in a sex hormone-dependent manner. Conclusions: This work demonstrates essential mechanisms on how changes of the gut microbiota regulate lupusassociated immune responses in mice. Future studies are warranted to determine if these results can be replicated in human subjects.
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    Deficiency in Toll-interacting protein (Tollip) skews inflamed yet incompetent innate leukocytes in vivo during DSS-induced septic Colitis
    Diao, Na; Zhang, Yao; Chen, Keqiang; Yuan, Ruoxi; Lee, Christina K.; Geng, Shuo; Kowalski, Elizabeth A.; Li, Liwu (Nature, 2016-10-05)
    Functionally compromised neutrophils contribute to adverse clinical outcomes in patients with severe inflammation and injury such as colitis and sepsis. However, the ontogeny of dysfunctional neutrophil during septic colitis remain poorly understood. We report that the dysfunctional neutrophil may be derived by the suppression of Toll-interacting-protein (Tollip). We observed that Tollip deficient neutrophils had compromised migratory capacity toward bacterial product fMLF due to reduced activity of AKT and reduction of FPR2, reduced potential to generate bacterial-killing neutrophil extra-cellular trap (NET), and compromised bacterial killing activity. On the other hand, Tollip deficient neutrophils had elevated levels of CCR5, responsible for their homing to sterile inflamed tissues. The inflamed and incompetent neutrophil phenotype was also observed in vivo in Tollip deficient mice subjected to DSSinduced colitis. We observed that TUDCA, a compound capable of restoring Tollip cellular function, can potently alleviate the severity of DSS-induced colitis. In humans, we observed significantly reduced Tollip levels in peripheral blood collected from human colitis patients as compared to blood samples from healthy donors. Collectively, our data reveal a novel mechanism in Tollip alteration that underlies the inflamed and incompetent polarization of neutrophils leading to severe outcomes of colitis.
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    Dynamic modulation of innate immunity programming and memory
    Yuan, Ruoxi; Li, Liwu (Springer, 2016-01)
    Recent progress harkens back to the old theme of immune memory, except this time in the area of innate immunity, to which traditional paradigm only prescribes a rudimentary first-line defense function with no memory. However, both in vitro and in vivo studies reveal that innate leukocytes may adopt distinct activation states such as priming, tolerance, and exhaustion, depending upon the history of prior challenges. The dynamic programming and potential memory of innate leukocytes may have far-reaching consequences in health and disease. This review aims to provide some salient features of innate programing and memory, patho-physiological consequences, underlying mechanisms, and current pressing issues.
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    Dynamic Programming of Innate Immunity in Health and Disease
    Yuan, Ruoxi (Virginia Tech, 2016-11-02)
    Whether innate immune cells may be adapted into potential memory states has becoming an important question in the field of immunity. Although previous conceptual paradigm failed to acknowledge this important question, emerging clinical and basic observations have started to shed intriguing clues to shake the previous dogma regarding innate immunity of being "simple", "raw", "first-line defense with no memory". We have aimed to further address this fundamental issue in this dissertation work, under the close guidance of Dr. Liwu Li. We have chosen to use the model system of Toll-Like-Receptor (TLR) signaling networks within primary monocytes. TLRs play fundamental roles in sensing pathogen-associated molecular patterns (PAMPs) and modulation of innate immunity. Lipopolysaccharide (LPS), an endotoxin found on the cell membrane of gram-negative bacteria, is the ligand of TLR4 and induces a range of inflammatory as well as anti-inflammatory responses. Higher dosages of LPS were known to cause robust yet transient expression of pro-inflammatory mediators. On the other hand, the effects of super-low dose LPS, commonly manifested in humans with adverse health conditions, have been largely ignored in the basic research field. Super-low dose LPS may skew host immune environment into a mild non-resolving pro-inflammatory state, which is a risk factor for inflammatory diseases such as atherosclerosis, compromised wound healing, and elevated risks for sepsis. Our central hypothesize is that monocytes may be adapted by super-low dose LPS into a non-resolving low-grade inflammatory state conducive for the pathogenesis of inflammatory diseases. We have employed both in vitro cell culture system as well as in vivo disease models to test this hypothesis. For the in vitro system, we have cultured primary murine monocytes with increasing signal strength of LPS. Monocyte phenotypes such as the expression of key inflammatory mediators including cytokines, chemokines, and cellular surface markers were studied. Potential molecular and cellular mechanisms were examined. We revealed a novel low-grade inflammatory monocyte phenotype termed ML adapted by super-low dose LPS, mediated through IRF5. For the in vivo system, we have employed both acute and chronic models of inflammation. For the chronic model, we have tested the effects of super-low dose LPS on monocyte polarization in vivo, as well as its contribution to the pathogenesis of atherosclerosis. Furthermore, we have tested the effects of programmed monocytes on wound healing. For the acute model, we have tested the effects of pre-conditioning with super-low dose LPS on the subsequence risks of sepsis elicited by cecal ligation and puncture. We have demonstrated aggravated atherosclerosis, compromised wound healing, and increased sepsis mortality in mice pre-conditioned with super-low dose LPS. Taken together, our findings reveal that monocytes can be differentially programmed into distinct states, depending on the signal strength of LPS. The differential programming and adaptation of monocytes can occur both in vitro and in vivo, and may bear profound pathological consequences.
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    Molecular Mechanisms That Underlie the Dynamic adaptation of innate Monocyte Memory to Varying stimulant strength of Tlr ligands
    Yuan, Ruoxi; Geng, Shuo; Li, Liwu (Frontiers, 2016-11-10)
    In adaptation to rising stimulant strength, innate monocytes can be dynamically programed to preferentially express either pro- or anti-inflammatory mediators. Such dynamic innate adaptation or programing may bear profound relevance in host health and disease. However, molecular mechanisms that govern innate adaptation to varying strength of stimulants are not well understood. Using lipopolysaccharide (LPS), the model stimulant of toll-like-receptor 4 (TLR4), we reported that the expressions of pro-inflammatory mediators are preferentially sustained in monocytes adapted by lower doses of LPS, and suppressed/tolerized in monocytes adapted by higher doses of LPS. Mechanistically, monocytes adapted by super-low dose LPS exhibited higher levels of transcription factor, interferon regulatory factor 5 (IRF5), and reduced levels of transcriptional modulator B lymphocyte-induced maturation protein-1 (Blimp-1). Intriguingly, the inflammatory monocyte adaptation by super-low dose LPS is dependent upon TRAM/TRIF but not MyD88. Similar to LPS, we also observed biphasic inflammatory adaptation and tolerance in monocytes challenged with varying dosages of TLR7 agonist. In sharp contrast, rising doses of TLR3 agonist preferentially caused inflammatory adaptation without inducing tolerance. At the molecular level, the differential regulation of IRF5 and Blimp-1 coincides with unique monocyte adaptation dynamics by TLR4/7 and TLR3 agonists. Our study provides novel clue toward the understanding of monocyte adaptation and memory toward distinct TLR ligands.
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    The persistence of low-grade inflammatory monocytes contributes to aggravated Atherosclerosis
    Geng, Shuo; Chen, Keqiang; Yuan, Ruoxi; Maitra, Urmila; Na, Diao; Chen, Chun; Zhang, Yao; Li, Liwu; Xiong, Huabao; Peng, Liang; Hu, Yuan; Qi, Chen-Feng; Pierce, Susan; Ling, Wenhua (Nature, 2016-11-08)
    Sustained low-grade inflammation mediated by non-resolving inflammatory monocytes has long been suspected in the pathogenesis of atherosclerosis; however, the molecular mechanisms responsible for the sustainment of non-resolving inflammatory monocytes during atherosclerosis are poorly understood. Here we observe that subclinical endotoxemia, often seen in humans with chronic inflammation, aggravates murine atherosclerosis through programming monocytes into a non-resolving inflammatory state with elevated Ly6C, CCR5, MCP-1 and reduced SR-B1. The sustainment of inflammatory monocytes is due to the disruption of homeostatic tolerance through the elevation of miR-24 and reduction of the key negative-feedback regulator IRAK-M. miR-24 reduces the levels of Smad4 required for the expression of IRAK-M and also downregulates key lipid-processing molecule SR-B1. IRAK-M deficiency in turn leads to elevated miR-24 levels, sustains disruption of monocyte homeostasis and aggravates atherosclerosis. Our data define an integrated feedback circuit in monocytes and its disruption may lead to non-resolving low-grade inflammation conducive to atherosclerosis.
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    Super-low Dose Endotoxin Pre-conditioning Exacerbates Sepsis Mortality
    Cheng, Keqiang; Geng, Shuo; Yuan, Ruoxi; Diao, Na; Upchurch, Zachary; Li, Liwu (Elsevier, 2015-03-06)
    Sepsis mortality varies dramatically in individuals of variable immune conditions, with poorly defined mechanisms. This phenomenon complements the hypothesis that innate immunity may adopt rudimentary memory, as demonstrated in vitro with endotoxin priming and tolerance in cultured monocytes. However, previous in vivo studies only examined the protective effect of endotoxin tolerance in the context of sepsis. In sharp contrast, we report herein that pre-conditioning with super-low or low dose endotoxin lipopolysaccharide (LPS) cause strikingly opposite survival outcomes. Mice pre-conditioned with super-low dose LPS experienced severe tissue damage, inflammation, increased bacterial load in circulation, and elevatedmortalitywhen theywere subjected to cecal-ligation and puncture (CLP). This is in contrast to thewell-reported protective phenomenon with CLPmice pre-conditioned with lowdose LPS.Mechanistically,we demonstrated that super-lowand lowdose LPS differentially modulate the formation of neutrophil extracellular trap (NET) in neutrophils. Instead of increased ERK activation and NET formation in neutrophils pre-conditioned with low dose LPS, we observed significantly reduced ERK activation and compromised NET generation in neutrophils pre-conditioned with super-low dose LPS. Collectively, our findings reveal amechanismpotentially responsible for the dynamic programming of innate immunity in vivo as it relates to sepsis risks.
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    Tollip Deficiency Alters Atherosclerosis and Steatosis by Disrupting Lipophagy
    Chen, Keqiang; Yuan, Ruoxi; Zhang, Yao; Geng, Shuo; Li, Liwu (Wolters Kluwer Health, 2017-04-10)
    Background Compromised lipophagy with unknown mechanisms may be critically involved in the intracellular accumulation of lipids, contributing to elevated atherosclerosis and liver steatosis. We hypothesize that toll‐interacting protein (Tollip), a key innate immune molecule involved in the fusion of autolysosome, may play a significant role in lipophagy and modulate lipid accumulation during the pathogenesis of atherosclerosis and liver steatosis. Methods and Results By comparing mice fed with either a Western high‐fat diet or a regular chow diet, we observed that both atherosclerosis and liver steatosis were aggravated in apolipoprotein E–deficient (ApoE−/−)/Tollip−/− mice as compared with ApoE−/− mice. Through electron microscopy analyses, we observed compromised fusion of lipid droplets with lysosomes within aortic macrophages as well as liver hepatocytes from ApoE−/−/Tollip−/− mice as compared with ApoE−/− mice. As a molecular indicator for disrupted lysosome fusion, the levels of p62 were significantly elevated in aortic and liver tissues from ApoE−/−/Tollip−/− mice. Molecules involved in facilitating lipophagy completion such as Ras‐related protein 7 and gamma‐aminobutyric acid receptor‐associated protein were reduced in ApoE−/−/Tollip−/− mice as compared with ApoE−/− mice. Intriguingly, ApoE−/−/Tollip−/− mice had reduced circulating levels of inflammatory cytokines such as tumor necrosis factor‐α and increased levels of transforming growth factor‐β. The reduced inflammation due to Tollip deficiency is consistent with a stable atherosclerotic plaque phenotype with increased levels of plaque collagen and smooth muscle cells in ApoE−/−/Tollip−/− mice. Conclusions Tollip deficiency selectively leads to enlarged yet stable atherosclerotic plaques, increased circulating lipids, liver steatosis, and reduced inflammation. Compromised lipophagy and reduced expression of inflammatory mediators due to Tollip deficiency may be the underlying causes. Our data suggest that lipid accumulation and inflammation may be intertwined yet independent processes during the progression of atherosclerosis and steatosis.