Project description:RNAseq of WT and TEVsite-titin (TEVs-TTN) neonatal mouse cardiomyocytes before and after titin cleavage with TEV protease (TEVp) expression.

Project description:Single nucleus RNAseq of TEVs-TTN hearts six days post-inoculation of AAVMYO encoding TEV protease.

Project description:Bulk RNAseq of WT and TEVs-TTN hearts six days post-inoculation of AAVMYO encoding TEV protease.

Project description:Tumor derived vesicles (TEVs) promote Angpt2 expression in Ch25h-/- ECs, while Reserpine reversed TEV induced Angpt2 expression in ECs.

Project description:Placental immunity is critical for fetal health during pregnancy, as invading pathogens spread from the parental blood to the fetus through this organ. However, inflammatory responses in the placenta can adversely affect both the fetus and the pregnant person, and the balance between protective placental immune response and detrimental inflammation is poorly understood. Extracellular vesicles (EVs) are membrane-enclosed vesicles that play a critical role in placental immunity. EVs produced by placental trophoblasts mediate immune tolerance to the fetus and to the placenta itself, but these EVs can also activate detrimental inflammatory responses. The regulation of these effects is not well-characterized, and the role of trophoblast EVs (tEVs) in the response to infection has yet to be defined. The Gram-positive pathogen Listera monocytogenes (Lm) infects the placenta, serving as a model to study tEV function in this context. We investigated the effect of Lm infection on the production and function of tEVs, using a trophoblast stem cell (TSC) model. We found that tEVs from infected TSCs can induce the production of the pro-inflammatory cytokine TNF-α in recipient cells. Surprisingly, this tEV treatment could confer increased susceptibility to subsequent Lm infection, which has not previously been reported as an effect of EVs. Proteomic analysis and RNA-sequencing revealed that tEVs from infected TSCs had altered cargo compared to those from uninfected TSCs. However, no Lm proteins were detected in tEVs from infected TSCs. Together, these results suggest an immunomodulatory role for tEVs during prenatal infection.

Project description:Studying the molecular basis for the skeletal muscle mitochondrial stress response could potentially be targeted to counteract metabolic disorders such as obesity. We uncovered a crucial role for the mitochondrial protease LONP1 in controlling the muscle mitochondrial proteostasis stress response that governs systemic metabolic homeostasis. Skeletal muscle-specific ablation of LONP1 led to broad genomic reprogramming of muscle and protected the mice from HFD-induced obesity. To thoroughly analyze pathways that are affected by ATF4 deficiency in the context of LONP1 mKO, we performed RNA-Seq transcriptome analysis of skeletal muscles from WT, LONP1 mKO and LONP1ATF4 DmKO mice. We identified a total of 3017 differentially expressed genes with a cutoff of 1.5-fold, and p < 0.05. Surprisingly, we found that ATF4 loss blunted a subset of regulated genes in LONP1 mKO muscles, whereas the majority of differentially regulated genes in LONP1 mKO muscles were not affected by ATF4 ablation. GO analysis of ATF4-dependent genes regulated by LONP1 ablation revealed significant enrichment in amino acid metabolic processes, Interestingly, however, LONP1 deficiency induced activation of muscle UPR and UPR-related RNA processing as well as myokine pathways were not affected by ATF4 ablation. Therefore, our results highlight a ATF4-independent mechanism in mediating the UPRmt in mammals.

Project description:For additional details see Ebert et al, Identification and Small Molecule Inhibition of an ATF4-dependent Pathway to Age-related Skeletal Muscle Weakness and Atrophy. Quadriceps femoris muscles were harvested from 22-month-old muscle-specfic ATF4 knockout (ATF4 mKO) mice and littermate controls. mRNA levels in ATF4 mKO muscles were normalized to levels in littermate control muscles.

Project description:Tumor-derived small extracellular vesicles (TEVs) were reported to carry various immunosuppressive molecules regulating immune response. We previously reported that TEV could express PD-L1 to systematically inhibit CD8 T cell anti-tumor immunity. Here, we observed that TEV PD-L1 suppressed the phagocytosis and bactericidal capacity of macrophages against E. coli. To investigate the potential mechanisms behind the impaired phagocytosis further, we collected and purified exosomes from the melanoma cell line B16-F10 PD-L1 knockout (KO) or vector culture to challenge RAW264.7 cells. We used RNA sequencing to reveal the key functional associated molecules for inhibiting the phagocytosis-associated pathway.

Project description:To investigate the role of the circadian clock gene Bmal1 in skeletal muscle, we compared the circadian transcriptomes of fast tibialis anterior (TA) and slow soleus (SOL) skeletal muscles from muscle-specific Bmal1 KO (mKO) and their control Cre- littermates (Ctrl). Keyword: Circadian Transcriptome, time course 72 samples were analyzed, comprised of 4 experimental groups (Ctrl SOL, mKO SOL, Ctrl TA, mKO TA), with 3 biological replicates for each time point sampled every 4 hours for 24 hours. SOL and TA muscles were collected from the same animals, as indicated by Source Animal ID data column

Project description:ATF4 is a fasting-induced trascription factor that promotes skeletal muscle atrophy. The goal of these studies was to determine how of loss of ATF4 affects skeletal muscle mRNA expression. For additional details see Ebert et al, Stress-Induced Skeletal Muscle Gadd45a Expression Reprograms Myonuclei and Causes Muscle Atrophy. JBC epub. June 12, 2012. Muscle-specfic ATF4 knockout (ATF4 mKO) mice and littermate controls were fasted for 24 hours and then tibialis anterior muscles were harvested. mRNA levels in ATF4 mKO muscles were normalized to levels in littermate control muscles.