Project description:Microplastics (MPs) as widespread contamination pose high risk for aquatic organisms. However, current understanding of MP toxicities are based on cell population-averaged measurements. Here we used single-cell RNA sequencing to provide the transcriptome heterogeneity of 12000 intestinal cells obtained from zebrafishes exposed to 100nm, 5μm and 200μm polystyrene MPs (PS-MPs) for 21 days. Eight intestinal cell populations were identified. We found that all the three sizes of PS-MPs induced dysfunction of intestinal immune cells (including phagosome and regulation of immune system process).

Project description:In the past years, the research focus on the effects of microplastics (MP) on aquatic organisms extended from marine systems towards freshwater systems. An important freshwater model organism in the MP field is the cladoceran Daphnia, which plays a central role in lacustrine ecosystems and has been established as a test organism in ecotoxicology. To investigate the effects of MP on Daphnia magna, we performed a chronic exposure experiment with polystyrene MP under strictly standardized conditions. Chronic exposure of D. magna to PS microparticles led to a significant reduction in body length and number of offspring. To shed light on underlying molecular mechanisms induced by microplastic ingestion in D. magna, we assessed the effects of PS-MP at the proteomic level.

Project description:Microplastics (MPs) as widespread contamination pose high risk for aquatic organisms.Intestinal microbiotahas have high interaction with immune system of host body. In this study, intestinal microbiota of zebrafish after Polystyrene (PS-MPs) exposure were characterized by 16S rDNA amplicon sequencing. We found that 100nm and 200μm PS-MPs exposure significantly increased diversity of intestinal microbiota and all the three sizes of PS-MPs increased abundance of pathogenic bacteria.

Project description:Plastics are persistent synthetic polymers that accumulate in the marine environment as waste. Microplastic (MP) particles are derived from the breakdown of larger debris or can enter the environment as microscopic fragments. Filter-feeder organisms ingest MP while feeding and are likely to be impacted by MP pollution. To assess the impact of polystyrene microspheres (PS) on the physiology of the Pacific oyster, adult oysters were experimentally exposed to virgin micro-PS (2 and 6 µm in diameter; 32 µg L-1) for two months during a reproductive cycle. Effects were investigated on transcriptomic responses, in digestive gland gonads and oocytes of exposed oysters. Transcriptomic profiles in the tissues of the exposed oyster showed endocrine disrupting signals, notably highlighting alteration in glucocorticoid response, insulin pathway and fatty-acid metabolism in response to micro-PS exposition. In oocytes from exposed females, several transcripts coding for proteins involved in Ca2+ binding were differentially expressed suggesting a disruption of the Ca2+ signaling pathway with crucial consequences on oocyte maturation.

Project description:Microparticles (MP) are small membranous particles (100-1000 nm) released under normal steady-state conditions and are thought to provide a communication network between host cells. Previous studies demonstrated that Mycobacterium tuberculosis (M.tb) infection of macrophages increased the release of MPs, and these MPs induced a proinflammatory response from uninfected macrophages in vitro and in vivo following their transfer into uninfected mice. To determine how M.tb infection modulates the protein composition of the MPs, and if this contributes to their proinflammatory properties, we compared the proteomes of MPs derived from M.tb-infected (TBinf-MP) and uninfected human THP-1 monocytic cells. MP proteins were analysed by GeLC-MS/MS with spectral counting revealing 68 proteins with statistically significant differential abundances. The 42 proteins increased in abundance in TBinf-MPs included proteins associated with immune function (7), lysosomal/endosomal maturation (4), vesicular formation (12), nucleosome proteins (4) and antigen processing (9). Prominent among these were the type I interferon inducible proteins, ISG15, IFIT1, IFIT2, and IFIT3. Exposure of uninfected THP-1 cells to TBinf-MPs induced increased gene expression of isg15, ifit1, ifit2, and ifit3 and the release of proinflammatory cytokines. These proteins may regulate the proinflammatory potential of the MPs and provide candidate biomarkers for M.tb infection.

Project description:Human ingestion of microplastics (MPs) is common and inevitable due to the widespread contamination of food items, but implications on the gastric digestion of food proteins are still unknown. In this study, the interaction between pepsin and polystyrene (PS) MPs was uncovered by investigating its effect on enzyme activity and conformation while in a simulated human gastric environment. The impact on food digestion was also determined by monitoring the kinetics of protein hydrolysis through static in vitro gastric digestion of cow’s milk contaminated with PS. The binding of pepsin to PS showed that surface chemistry of MPs dictates binding affinity. The key contributor to pepsin adsorption seems to be π−π interactions between the aromatic residues and the PS phenyl rings. During quick exposure (10 minutes) of pepsin to increasing concentrations (222, 2219, 22188 particles/mL) of 10 μm PS (PS10) and 100 μm PS (PS100), total enzymatic activities were not affected remarkably. However, upon prolonged exposure at 1 and 2 hours, preferential binding of pepsin to the small, low zeta-potential PS caused structural changes in the protein which led to a significant reduction of its activity. Digestion of cow’s milk mixed with PS10 resulted in transient accumulation of larger peptides (10-35 kDa) and reduced bioavailability of short peptides (2-9 kDa) in the gastric phase. This, however, was only observed at extremely high PS10 concentration (0.3 mg/mL or 5.46E+05 particles/mL). The digestion of milk peptides, bound preferentially over pepsin on the hard corona around PS10, was delayed up to 15 minutes in comparison to bulk protein digestion. Intact caseins, otherwise rapidly digested, remained bound to PS10 in hard corona for up to 15 minutes. This work presents valuable insights regarding the interaction of MPs, food proteins, and pepsin, and their dynamics during gastric digestion which provides new knowledge and understanding on the potential risks of MPs to human health.

Project description:The mononuclear phagocyte (MP) system consists of macrophages, monocytes, and dendritic cells. MP subtypes play distinct functional roles in steady-state and inflammatory conditions. Though murine MPs are well characterized, their human homologues remain poorly understood, particularly in the lung and draining lymph nodes (LNs). Understanding these homologies, and their similarities and differences with murine MPs, is critical for identifying human genetic targets and thus developing human immunotherapies. To address this gap, we performed transcriptome-based alignment across fifteen distinct human and nine distinct murine lung and LN MPs. As controls to validate the analytical quality of cross-species pulmonary MP analysis, human blood and murine spleen MPs were used. Constrained canonical correlation, t-SNE and catplot visualization was used to align human and mouse MPs and identify MP subtypes with maximal correspondence across species. Among the top marker genes expressed in corresponding human-mouse MP pairs, only 30-10% of the genes overlapped, indicating a need for caution when identifying human gene variants and functions from mice. For instance, SPP1 is highly expressed in human interstitial macrophages but not alveolar macrophages (AMs), whereas in mice SSP1 is only expressed in AMs. Moreover, human LN dendritic cells (DCs) align best with murine LN DCs but not murine splenic DCs indicating cross-species similarity in tissue. Lastly, in both species, CD88 was the most useful cell surface marker for distinguishing monocyte/macrophages from DCs. Overall, these data provide a reference for analyzing cross-species transcriptome data and evaluating whether specific murine genes are suitable guides to identify the functionality of human MPs, or conversely, whether pursuing specific human genes in mice, is likely to be a valid and fruitful approach. 

Project description:Microglia (MG) and macrophages (MPs) represent a significant component of the inflammatory response to gliomas. When activated, MG/MP release a variety of pro-inflammatory cytokines, however, they also secrete anti-inflammatory factors that limit their cytotoxic function. The balance between pro and anti-inflammatory functions dictates their antitumor activity. To evaluate potential variations in MG and MP function in gliomas, we isolated these cells (and other Gr1+ cells) from intracranial GL261 murine gliomas by FACS and evaluated their gene expression profiles by microarray analysis. As expected, arginase 1 (Arg1, M2 marker) was highly expressed by tumor-associated Gr1+, MG and MP. However, in contrast to MP and Gr1+ cells that expressed Arg1 shortly after tumor trafficking, Arg1 expression in MG was delayed and occurred in larger tumors. Interestingly, depletion of MPs in tumors did not prevent MG polarization, suggesting direct influence of tumor-specific factors on MG Arg1 upregulation. Finally, Arg1 expression was confirmed in human GBM samples, but most Arg1+ cells were neutrophils and not MPs. These findings confirm variations in tumor MG and MP polarization states and its dependency on tumor microenvironmental factors.

Project description:The important role of mesenchymal progenitors is quickly emerging in various biological processes. Thus far an appropriate marker has been lacking. Here the fractionation of dissociated skeletal muscle and subsequent enrichment of MPs by an established method was employed. Endothelial and blood derived cells comprised the lineage positive fraction and the remaining cell suspension was fractionated using the surface marker Sca1(Ly6a) to enrich for MPs. RNA sequencing was performed on all fractions and subsequent transcriptomic data was interrogated for MP specific transcription factors. Hic1 was found to be highly enriched in the MP fraction.

Project description:Tissue macrophages (MPs) develop distinctive functions due to unique transcriptional programs driven by local environmental ques. In the intestine, it is known that MPs are heterogeneous cells that differentiate from blood monocytes and embryonic precursors, and are essential for homeostasis with the vast microbiome through their ability to kill invading microbes, clear apoptotic cells, and produce regulatory cytokines. However, the full extent of MP heterogeneity, their developmental relationships, and how the intestinal microbiota affects MP generation is not known. Here, we performed single cell RNA sequencing of colonic myeloid cells from specific pathogen free (SPF) and germ free (GF) C57BL/6 mice and found extensive heterogeneity of colon MP, with at least six different identifiable populations, with less heterogeneity of dendritic cells (DCs). Unsupervised modeling of developmental pathways combined with inference of gene regulatory networks suggested two major trajectories from common CCR2+ precursors resulting in CD11c+CD9+MMRintCD121b+ and CD11c-CD9intMMRhiCD121b- MP populations with unique transcription factors activities to coordinate downstream target molecules. The generation of both mature populations of colon MPs was impaired in germ-free mice, which coincided with the appearance of a dominant unique population of MPs, whereas the generation of DC populations in GF mice were unaffected or increased. Furthermore, the two major MP populations were clearly distinct from other populations regarding their gene expression profile, localization within the lamina propria, and ability to phagocytose macromolecules from the blood. These data uncover the diversity of intestinal myeloid cell populations, highlight the importance of microbiota on the unique developmental as well as anatomical and functional fates of colon MPs. We anticipate that these findings will form the basis for future studies on how tissue myeloid cell development is influenced either directly or indirectly by signals from endogenous microbiota in the intestine, as well as other tissues.