Project description:Enterococcus faecalis is often co-isolated with Pseudomonas aeruginosa in mixed-species biofilm-associated infections of wounds and the urinary tract. As a defence strategy, the host innately restricts iron availability at infection sites. Despite their co-prevalence, the polymicrobial interactions of these two pathogens in low iron conditions, such as those found in the host, remains unexplored. Here we show that E. faecalis inhibits P. aeruginosa growth within macrocolony biofilms when iron is restricted. E. faecalis lactate dehydrogenase (ldh1) gives rise to L-lactate production during fermentative growth. We find that E. faecalis ldh1 mutant fails to inhibit P. aeruginosa growth. Additionally, we demonstrate that ldh1 expression is induced when iron is restricted, resulting in increased lactic acid exported and consequently, a reduction in pH. Together, our results suggest that E. faecalis synergistically impact P. aeruginosa growth negatively by decreasing environmental pH and L-lactate-mediated iron chelation. Overall, this study highlights that the microenvironment in which the infection occurs is important for understanding its pathophysiology.

Project description:Enterococcus faecalis-derived lactate mediated suppression of NF-κB and ERK pathways in macrophages to promote polymicrobial wound infection

Project description:D-lactic acid is a three-carbon organic acid with a chiral structure and can improve the thermostability of polylactic acid. Microorganisms such as the methylotrophic yeast Pichia pastoris, which lack the natural ability to produce or accumulate high amounts of D-lactic acid, have been engineered to produce it in high titers. However, tolerance to D-lactic acid remains a challenge. In this study, we demonstrate that cell flocculation improves tolerance to D-lactic acid and leads to increased D-lactic acid production in Pichia pastoris. By incorporating a flocculation gene from Saccharomyces cerevisiae (ScFLO1) into P. pastoris KM71, we created a strain (KM71-ScFlo1) that demonstrated up to a 1.6-fold improvement in specific growth rate at high D-lactic acid concentrations. Furthermore, integrating a D-lactate dehydrogenase gene from Leuconostoc pseudomesenteroides (LpDLDH) into KM71-ScFlo1 resulted in an engineered strain (KM71-ScFlo1-LpDLDH) that can produce D-lactic acid at a titer of 5.12  0.35 g/L in 48 hours , a 2.6-fold improvement over the control strain lacking ScFLO1 expression. Transcriptomics analysis of this strain provided insights into the mechanism of increased tolerance to D-lactic acid including the upregulations of genes involved in lactate transport and iron metabolism. Overall, our work represents an advancement in the efficient microbial production of D-lactic acid by manipulating yeast flocculation.

Project description:Enterococcus faecalis is commonly isolated from different wound types. However, despite its prevalence, the pathogenic mechanisms of E. faecalis during wound infections remain poorly understood. We adopted an in vivo E. faecalis transposon sequencing and RNA sequencing approach to identify fitness determinants that are crucial for replication and persistence of E. faecalis during wound infections in a mouse model. We demonstrated that E. faecalis purine biosynthesis genes are important for replication as purine metabolites are low in wounds during the early phase of wound infections. Furthermore, we found that the E. faecalis MptABCD phosphotransferase system (PTS) involved in the uptake of galactose and mannose, is crucial for E. faecalis persistence in wounds, and that carbohydrate availability changes as the infection progresses. To understand how MptABCD PTS contributes to the reduced fitness observed during E. faecalis wound persistence, we performed an in vitro transcriptomic analysis using the galactose/mannose PTS gene deletion mutant (∆mptD). When mannose was the sole carbohydrate source, shikimate and purine biosynthesis genes in the ∆mptD mutant were downregulated compared to the isogenic wild-type strain, indicating that mannose transport is interconnected with shikimate and purine biosynthesis. Together, our results suggest that dynamic and temporal microenvironment changes at the wound site affects pathogenic requirements and mechanisms of E. faecalis during infections and raise the possibility of inhibiting purine biosynthesis and/or MptABCD PTS to control wound infections.

Project description:Enterococcus faecalis is commonly isolated from different wound types. However, despite its prevalence, the pathogenic mechanisms of E. faecalis during wound infections remain poorly understood. We adopted an in vivo E. faecalis transposon sequencing and RNA sequencing approach to identify fitness determinants that are crucial for replication and persistence of E. faecalis during wound infections in a mouse model. We demonstrated that E. faecalis purine biosynthesis genes are important for replication as purine metabolites are low in wounds during the early phase of wound infections. Furthermore, we found that the E. faecalis MptABCD phosphotransferase system (PTS) involved in the uptake of galactose and mannose, is crucial for E. faecalis persistence in wounds, and that carbohydrate availability changes as the infection progresses. To understand how MptABCD PTS contributes to the reduced fitness observed during E. faecalis wound persistence, we performed an in vitro transcriptomic analysis using the galactose/mannose PTS gene deletion mutant (∆mptD). When mannose was the sole carbohydrate source, shikimate and purine biosynthesis genes in the ∆mptD mutant were downregulated compared to the isogenic wild-type strain, indicating that mannose transport is interconnected with shikimate and purine biosynthesis. Together, our results suggest that dynamic and temporal microenvironment changes at the wound site affects pathogenic requirements and mechanisms of E. faecalis during infections and raise the possibility of inhibiting purine biosynthesis and/or MptABCD PTS to control wound infections.

Project description:Enterococcus faecalis (E. faecalis) is a Gram-(+) opportunistic pathogen associated with predominantly nosocomial wound infections. E. faecalis has been shown to suppress or evade immune-mediated clearance by the immune system and promote persistent infection. Here, we sought to interrogate whether E. faecalis infection induces transcriptomic changes in the host at the single-cell resolution using a mouse excisional wound model. Keratinocyte, fibroblast, endothelial and immune cell populations reveal unique clusters in the infected wounds. Cell communication analysis discovered strong ligand-receptor interactions between macrophages and endothelial cells in the infected niche, whilst fibroblast and keratinocytes instruct healing cellular interactions in untreated skin wounds. We also identified differential terminal lineage driving genes, following RNA velocity in each condition. Together, results suggest that E. faecalis infection alters the skin transcriptome, which may help promote the chronicity of bacteria-infected wounds.

Project description:Macrophage-Specific Lactate Dehydrogenase Expression Modulates Inflammatory Function In Vitro

Project description:Lactic acidosis and hypoxia are two prominent tumor microenvironmental stresses that are both known to exert important influences on gene expression and phenotypes of cancer cells. But very little is known about the cross-talk and interaction between these two stresses. We performed gene expression analysis of MCF7 cells exposed to lactic acidosis, hypoxia and combined lactic acidosis and hypoxia. We found the hypoxia response elicited under hypoxia was mostly abolished upon simultaneous exposure to lactic acidosis. The repression effects are due to loss of HIF-1α protein synthesis under lactic acidosis. In addition, we showed lactic acidosis strongly synergizes with hypoxia to activate the unfold protein response (UPR) and inflammation response which are highly similar to amino acid deprivation responses (AAR). The statistical factor analysis of hypoxia and lactic acidosis responses indicated that ATF4 locus, an important activator in the UPR/AAR pathway, is amplified in subsets of breast tumors and cancer cell lines. Varying ATF4 levels dramatically affect the ability to survive the post-stress recovery from hypoxia and lactic acidosis and may suggest its selection of ATF4 amplification in human cancers. These data suggest that lactic acidosis interacts with hypoxia by both inhibiting the canonical hypoxia response and while activating the UPR and inflammation response. Gain of ATF4 locus may offer survival advantages to allow successful adaptation to frequent fluctuations of oxygen and acidity in tumor microenvironment. Collectively, our studies have provided linkage between the short-term transcriptional responses to the long term selection of the DNA copy number alterations (CNAs) under tumor microenvironmental stresses. RNAs from MCF7 cells exposed to control condition (ambient air ~21% O2, no lactate and neutral pH), lactic acidosis (ambient air, 10 mM Lactate and pH 6.7), hypoxia (1% pO2, no lactate and neutral pH) and the combined lactic acidosis and hypoxia (1% pO2, 10 mM Lactate and pH 6.7) condition for 24 hours were extracted by miRVana kits (Ambion) and hybridized to Affymetrix Human genome 133A 2.0 arrays with standard protocol.

Project description:Wound healing is associated with high rates of cell replication and lactate accumulation even under normoxic and hyperoxic conditions. Lactate accounts for various effects in tissue regeneration, such as collagen synthesis, angiogenesis, modulation of cytokine patterns and as recently shown for stem cell homing. Its influence on genes involved in cell replication has not been shown yet. Therefore, the effect of lactate considering genes involved in different cellular processes was investigated. Human umbilical vein endothelial cells (HUVEC) were cultured and incubated with lactate for different periods of time. Gene expression analysis was performed using custom-designed oligonucleotide microarrays. Keywords: Human gene expression study Reference design with Cy3 labeled uniRNA and Cy5 labeled sample RNA.

Project description:MYC activates different metabolic programs in a cell-type and cell-status dependent manner. However, the role of MYC in inflammatory macrophages has not yet been determined. Metabolic and molecular analyses reveal that MYC, but not HIF1, is involved in enhancing early glycolytic flux during inflammatory macrophage polarization. Ablation of MYC decreases lactate production by regulating lactate dehydrogenase (LDH) activity and causes increased inflammatory cytokines by regulating interferon regulatory factor 4 (IRF4) in response to lipopolysaccharide (LPS). Moreover, myeloid-specific deletion of MYC and pharmacological inhibition of MYC/LDH axis enhance inflammation and the bacterial clearance in vivo. These results elucidate the potential role of the MYC/LDH/IRF4 axis in inflammatory macrophages by connecting early glycolysis and inflammatory responses and suggest that modulating early glycolytic flux mediated by the MYC/LDH axis can be utilized to open new avenues for the therapeutic modulation of macrophage polarization to fight against bacterial infection.