Project description:Biomolecular condensates are implicated in many cellular processes, and are thought to create subcellular microenvironments that regulate specific biochemical activities 1-7. For example, in vitro experiments suggest that condensates enable non-stochiometric enrichment of small molecules within condensates 8-12. However, probing the microenvironments of condensates in cells is a major challenge, because tools to selectively manipulate specific condensates in living cells are limited. Here we developed a non-natural micropeptide (i.e., the “killswitch”) and a Nanobody-based recruitment system as a universal approach to probe endogenous condensates, and demonstrate direct links between condensate microenvironments and function in cells. The killswitch is a hydrophobic, aromatic-rich sequence with an ability to self-associate, and no homology to human proteins. When recruited to endogenous and disease-specific condensates in human cells, the killswitch arrested the dynamics of the condensate-forming proteins, which led to predicted and unexpected effects. Targeting the killswitch to the nucleolar protein NPM1 altered nucleolar composition, and inhibited the dynamics of a ribosomal protein within nucleoli. Targeting the killswitch to fusion oncoprotein condensates inhibited the dynamics of effector proteins in the condensates, altered condensate composition, and inhibited proliferation of condensate-driven leukemia cells. In adenoviral nuclear condensates, the killswitch inhibited partitioning of capsid protein into condensates, and suppressed viral particle assembly. The results suggest that the microenvironment within cellular condensates has an essential contribution to non-stochiometric enrichment and the dynamics of effector proteins. The killswitch is a widely applicable tool to alter the material properties of endogenous condensates, and as a consequence, to probe functions of condensates linked to diverse physiological and pathological processes in living systems.

Project description:Polycomb-mediated repression of Dkk-1 activates Wnt signaling and enhances tumorigenic potential of lung cancer cells following tobacco smoke exposure Experiment Overall Design: microarray techniques were used to examine proliferation and gene expression in A549 and Calu-6 lung cancer cells cultured in normal media with or without tobacco smoke condensate (TSC)

Project description:Like tobacco smoking, habitual marijuana smoking causes numerous adverse pulmonary effects. However, the mechanisms of action involved, especially as compared to tobacco smoke, are still unclear. To uncover putative modes of action, this study employed a toxicogenomics approach to compare the toxicological pathways perturbed following exposure to marijuana and tobacco smoke condensate in vitro. Condensates of mainstream smoke from hand-rolled tobacco and marijuana cigarettes were similarly prepared using identical smoking conditions. Murine lung epithelial cells were exposed to low, medium and high concentrations of the smoke condensates for 6 hr. RNA was extracted immediately or after a 4-hr recovery period and hybridized to mouse whole genome microarrays. Tobacco smoke condensate (TSC) exposure was associated with changes in xenobiotic metabolism, oxidative stress, inflammation, and DNA damage response. These same pathways were also significantly affected following marijuana smoke condensate (MSC) exposure. Although the effects of the condensates were largely similar, dose-response analysis indicates that the MSC is substantially more potent than TSC. In addition, steroid biosynthesis, apoptosis, and inflammation pathways were more significantly affected following MSC exposure, whereas m-phase cell cycle pathways were more significantly affected following TSC exposure. MSC exposure also appeared to elicit more severe oxidative stress than TSC exposure, which may account for the greater cytotoxicity of MSC. This study shows that in general, MSC impacts many of the same molecular processes as TSC. However, subtle pathway differences can provide insight into the differential toxicities of the two complex mixtures. Murine epithelial lung cells were exposed to tobacco smoke condensates (0, 25, 50, 90 μg/ml) or marijuana smoke condensates (0, 2.5, 5, 10 μg/ml) in serum-free medium for a six hour period. Following the six-hour exposure, cells were either harvested immediately or washed with phosphate-buffered saline and incubated in fresh serum-free medium for a four hour recovery period. Total RNA was extracted from the cells and hybridized against Universal Mouse Reference RNA (Agilent Technologies Canada, Inc.) to Agilent whole mouse genome microarray slides containing 44,000 transcripts. A LOWESS normalization was applied to expression results, and statistically significant genes were identified using the R library MAANOVA. Microarray results were validated by real time RT-PCR.

Project description:MeCP2 (methyl CpG binding protein 2) is a key component of constitutive heterochromatin, which plays important roles in chromosome maintenance and transcriptional silencing. Mutations in MeCP2 cause Rett syndrome (RTT), a postnatal progressive neurodevelopmental disorder associated with severe mental disability and autism-like symptoms that manifests in girls during early childhood. Heterochromatin, long considered a dense and relatively static structure, is now understood to exhibit properties consistent with a liquid-like condensate. Here we report that MeCP2 is a dynamic component of heterochromatin condensates in cells, is stimulated by DNA to form liquid-like condensates, contains multiple domains that contribute to condensate formation, manifests physicochemical properties that selectively concentrate heterochromatin cofactors compared to components of transcriptionally active condensates, and when altered by RTT-causing mutations is disrupted in its ability to form condensates. We propose that MeCP2 enhances heterochromatin/euchromatin separation through its condensate partitioning properties and that condensate disruption may be a common consequence of RTT patient mutations.

Project description:The polycyclic aromatic hydrocarbon (PAH), benzo[a]pyrene (BaP), was compared to dibenzo[def,p]chrysene (DBC) and combinations of three environmental PAH mixtures (coal tar, diesel particulate and cigarette smoke condensate) using a two stage, FVB/N mouse skin tumor model. DBC (4 nmol) was most potent, reaching 100% tumor incidence with a shorter latency to tumor formation, less than 20 weeks of 12-O-tetradecanoylphorbol-13-acetate (TPA) promotion compared to all other treatments. Multiplicity was 4 times greater than BaP (400 nmol). Both PAHs produced primarily papillomas followed by squamous cell carcinoma and carcinoma in situ. Diesel particulate extract (1 mg SRM 1650b; mix 1 ) did not differ from toluene controls and failed to elicit a carcinogenic response. Addition of coal tar extract (1 mg SRM 1597a; mix 2) produced a response similar to BaP. Further addition of 2 mg of cigarette smoke condensate (mix 3) did not alter the response of mix 2. PAH-DNA adducts measured in epidermis 12 h post initiation and analyzed by 32P post- labeling, did not correlate with tumor incidence. PAH dependent alteration in transcriptome of skin 12 h post initiation was assessed by microarray. Principal component analysis (sum of all treatments) of the 922 significantly altered genes (p<0.05), showed DBC and BaP to cluster distinct from PAH mixtures and each other. BaP and mixtures up-regulated phase 1 and 2 metabolizing enzymes while DBC did not. The carcinogenicity with DBC and two of the mixtures was much greater than would be predicted based on published Relative Potency Factors (RPFs). Gene expression was measured in mouse skin 12 hours after initiation with PAH carcinogens. The following initiation treatments were applied to mice (N=4 or 5 per biological replicates treatment); toluene vehicle control (200 M-NM-<l), BaP 400 nmol (100 M-NM-<g), DBC 4 nmol (1.2 M-NM-<g), or to mixtures of environmental PAH mixtures containing diesel particulate extract, coal tar extract, or cigarette smoke condensate.

Project description:Posttranslational modification of proteins by N-linked glycosylation is crucial for many life processes. However, the exact contribution of N-glycosylation to mammalian female reproduction remains largely undefined. Here, DPAGT1, the enzyme that catalyzes the first step of protein N-glycosyation, is identified to be indispensable for oocyte development in mice. A recessive missense mutation (c. 497A>G; p. Asp166Gly) of Dpagt1 causes female subfertility without grossly affecting other functions. Mutant females ovulate fewer eggs owing to defects of follicular development beyond the late secondary stage. Oocytes ovulated by mutants carry a thin and fragile zona pellucida, and display poor developmental competence after fertilization in vitro. Moreover, completion of the first meiosis is accelerated in mutant oocytes, which is coincident with the elevation of aneuploidy. Mechanistically, transcriptomic analysis reveals the downregulation of a number of transcripts essential for oocyte meiotic progression and preimplantation development (e.g., Pttgt1, Esco2, Orc6, and Npm2) in mutant oocytes, which could account for the defects observed. Furthermore, conditional knockout (CKO) of Dpagt1 in oocytes recapitulates the phenotypes observed in Dpagt1 mutant females, and causes complete infertility. Taken together, these data indicate that protein N-glycosylation in oocytes is essential for female fertility in mammals by specific control of oocyte development.

Project description:Insulin resistance is accompanied by chronic hyperinsulinemia and is associated with type 2 diabetes and other metabolic syndromes in a substantial portion of the population. The risk factors and features of insulin resistance have been thoroughly described but its mechanistic triggers are still under study. Here we consider a condensate model for insulin receptor (IR) function in normal conditions and when dysregulated in chronic hyperinsulinemia-induced insulin resistance. We find that IR is incorporated into liquid-like condensates at the plasma membrane, in the cytoplasm and in the nucleus of liver cells, and provide evidence for insulin-dependent IR function in condensates. Insulin stimulation promotes further incorporation of IR into these dynamic condensates in insulin sensitive cells, which form and dissolve on short, sub-minute time-scales. In contrast, insulin stimulation does not promote further incorporation of IR into condensates in insulin resistant cells, where IR molecules within condensates exhibit less dynamic behavior. Metformin treatment of insulin resistant cells rescues IR condensate dynamics and insulin responsiveness. Insulin resistant cells experience high levels of oxidative stress, which causes reduced condensate dynamics, and treatment of these cells with metformin reduces ROS levels and returns condensates to their normal dynamic behavior. The condensate model we propose can account for features of normal and dysregulated insulin response and has implications for improved therapeutic approaches to insulin resistance.

Project description:Myeloid-derived suppressor cells (MDSCs) potently suppress the anti-tumor immune responses and also orchestrate the tumor microenvironment that favors tumor angiogenesis and metastasis. The immunosuppressive activity of MDSCs has been extensively investigated, however the molecular networks regulating the non-immunological functions of tumor-expanded MDSCs, are largely unknown. In this study, we identified microRNA-494 (miR-494), whose expression was dramatically induced by tumor-derived factors (TDFs), as an essential player, in regulating the non-immunological activity of MDSCs by targeting PTEN and activating the Akt pathway. TGF-beta 1 was found to be a main tumor-derived factor responsible for the up-regulation of miR-494 in MDSCs. Expression of miR-494 not only enhanced CXCR4-mediated MDSC chemotaxis but also altered the intrinsic apoptotic/survival signal by targeting PTEN, thus contributing to the accumulation of MDSCs in tumor tissues. Consequently, down-regulation of PTEN resulted in increased activity of the Akt pathway and the subsequent up-regulation of matrix metalloproteinases (MMPs) for facilitating tumor cell invasion and metastasis. Knock down of miR-494 significantly reversed the activity of MDSCs and inhibited the tumor growth and metastasis of 4T1 murine breast cancer in vivo. Collectively, our findings reveal that TGF-beta 1-induced miR-494 expression in MDSCs plays a critical role in the molecular events governing the accumulation and non-immunological functions of tumor-expanded MDSCs, and might be identified as a potential target in cancer therapy. BALB/c mice (female, 6- to 8-wk-old) were injected subcutaneously in the mammary fat pad with 100,000 4T1 tumor cells. Three weeks later, tumor-bearing animals were used for the indicated studies. Gr-1+ CD11b+ cells were isolated by immunomagnetic selection from the bone marrow of 4T1 tumor-bearing mice (n=3) and tumor-free BALB/c mice (n=3), then the miRNA expression profile were analyzed using miRCURY LNAM-bM-^DM-" microRNA Arrays.

Project description:During development, cells make switch-like decisions to activate new gene programs specifying cell lineage. The mechanisms underlying these decisive choices remain unclear. Here we show that the cardiovascular transcriptional coactivator, Myocardin (MYOCD), activates cell identity genes by concentration-dependent and switch-like formation of transcriptional condensates. MYOCD forms such condensates and activates cell identity genes at critical concentration thresholds achieved during smooth muscle cell and cardiomyocyte differentiation. The C-terminal disordered region of MYOCD is necessary and sufficient for condensate formation. Disrupting this region’s ability to form condensates disrupts gene activation. Rescuing condensate formation by replacing this region with disordered regions from functionally unrelated proteins rescues gene activation. Our findings demonstrate that MYOCD condensate formation is required for gene activation during differentiation. We propose that the formation of transcriptional condensates at critical concentrations of cell type-specific regulators provides a molecular switch underlying the activation of key cell identity genes during cell lineage specification.

Project description:Until now, acute respiratory distress syndrome (ARDS) has been a difficult clinical condition with a high mortality and morbidity rate, and is characterized by a build-up of alveolar fluid and impaired clearance. The underlying mechanism is not yet fully understood and no specific treatment available. Autophagy activation is associated with ARDS caused by different pathogenic factors. It represents a new direction of prevention and treatment of ARDS to restrain autophagy to a reasonable level through pharmacological and molecular genetic methods. Na, K-ATPase is the main gradient driver of pulmonary water clearance in ARDS and could be degraded by the autophagy-lysosome pathway to affect its abundance and enzyme activity. As a normal growth hormone in human body, insulin has been widely used in clinical for a long time. To investigate the association of insulin with Na, K-ATPase, autophagy and inflammatory markers in LPS-treated C57BL/6 mice by survival assessment, proteomic analysis, histologic examination, inflammatory cell counting, myeloperoxidase, TNF-α, IL-1β activity analysis etc. This was also verified on mouse alveolar epithelial type Ⅱ (AT Ⅱ) and A549 cells by transmission electron microscopy. We found that insulin restored the transport efficiency of Na, K-ATPase, inhibited the activation of autophagy and reduced the release of inflammatory factors caused by alveolar epithelial damage. The regulation mechanism of insulin on Na, K-ATPase by inhibiting autophagy function may provide new drug targets for the treatment of ARDS.