Project description:The increasing number of biological applications for black phosphorus (BP) nanomaterials has precipitated considerable concern about their interactions with physiological systems. Here, we demonstrate the adsorption of plasma protein onto BP nanomaterials and the subsequent immune perturbation effect on macrophages. Using liquid chromatography tandem mass spectrometry, we discovered that BP nanosheets (BPNSs) were able to bind 23.3 percent of immune proteins from plasma, while BP quantum dots (BPQDs) bound 41.8 percent of immune proteins. In particular, the protein corona dramatically reshaped BP nanomaterial-corona complexes, influenced cellular uptake, activated the NF-κB pathway and even increased cytokine secretion by 2-5-fold. BP nanomaterials induced immunotoxicity and immune perturbation in macrophages in the presence of a plasma corona. These findings offer important insights into the development of safe and effective BP nanomaterial-based therapies.

Project description:The composition and structure of protein corona represents a crucial factor that controls the biological properties and fate of nanomaterials. While the composition of the corona can relatively easily be investigated by conventional bottom-up proteomics, assessing the spatial orientation of a protein in the corona (i.e assessing which epitopes are exposed on the outer surface) is still a challenging and time-consuming task. In this paper, we show that labeling the corona proteins with isobaric tags in their native conditions, and the subsequent analysis of MS/MS spectra of tryptic peptides, allows an easy and high-troughput assessment of the inner/outer orientation of the corresponding proteins in the original corona.

Project description:We are human embryologists from center for reproductive medicinel of Anhui Provincial Hospital Affiliated to Anhui Medical University, and we have the expertise to do all that properly in humans. By deep sequencing, the current experiment determined the miRNA profile of two intrafollicular somatic cell types: CRCs and COCs, isolated from women undergoing controlled ovarian stimulation and in vitro fertilization treatment. Ovarian follicles, which are a densely-packed shell of granulosa cells that contains an immature or mature oocyte, are above all responsible for the development, maturation, and release of mature egg for fertilization. They are also responsible for synthesizing and secreting hormones that are essential for follicular development, menstrual and estrous cycle, maintenance of the reproductive tracts and their functions, development of female secondary sex characteristics, and metabolism. During folliculogenesis, ovarian granulosa cells surrounding the oocyte differentiate into mural granulosa cells, involved in gonadal steroidogenesis, and into cumulus cells, which are ovulated with the oocyte at ovulation. These cumulus cells derive from the same population of early follicles, but differentiate into two distinct groups of cells: 1) Those directly lie on the zona pellucida are composed of the so called corona radiata cells.(CRCs) 2) The other group surrounds the CRCs and consists of more numerous cells, forming the so called cumulus oophorus cells (COCs). In the present study, we described the miRNA expression profile to characterize the ensemble of both known and novel miRNAs expressed in CRCs, as well as in COCs, by using high-throughput Solexa technology.

Project description:We determined the composition of the plasma protein corona on silica-coated versus dextran-coated iron oxide nanoparticles using mass spectrometry-based proteomics approaches. Gene ontology (GO) enrichment analysis and Ingenuity Pathway Analysis (IPA) revealed distinct protein corona compositions for the two different SPIONs. Relaxivity of silica-coated SPIONs was modulated by the presence of a protein corona. Moreover, the viability of primary human monocyte-derived macrophages was influenced by the protein corona on silica-coated, but not dextran-coated SPIONs, and the protein corona promoted cellular uptake of silica-coated SPIONs, but did not affect internalization of dextran-coated SPIONs.

Project description:Nanomaterials in blood must mitigate the immune response to have prolonged residency, a property that is highly relevant to biocompatibility, toxicity, and the generation of long acting therapeutics. The composition of the protein corona that forms at the nano-biointerface may be directing this, however, it is currently unknown the possible correlation of corona composition with blood residency. We developed a panel of new soft single molecule polymer nanomaterials (SMPNs) with varying circulation times in mice (t1/2 ~22 to 65 h) and used proteomics to probe the nano-biointerface to elucidate the mechanism of blood residency of nanomaterials. The composition of the protein opsonins on SMPNs was qualitatively and quantitatively dynamic with time in circulation, and SMPNs that circulated longer were able to clear some of the initial surface-bound common opsonins, including immunoglobulins, complement, and coagulation proteins. This continuous remodelling of protein opsonins, a phenomenon first of its kind observed, may be a decisive step in directing elimination or residence of the reported soft nanomaterials in vivo.

Project description:The protein corona, a dynamic biomolecular layer that forms on nanoparticle (NP) surfaces upon exposure to biological fluids is emerging as a valuable diagnostic tool for improving plasma proteome coverage analyzed by liquid chromatography-mass spectrometry (LC-MS/MS). Here, we show that spiking phosphatidylcholine into plasma can induce diverse protein corona patterns on otherwise identical NPs, significantly enhancing the depth of plasma proteome profiling. This significant achievement is made utilizing only a single NP type and one small molecule to analyze a single plasma sample, setting a new standard in proteomic depth of the plasma sample. Given the critical role of plasma proteomics in biomarker discovery and disease monitoring, we anticipate widespread adoption of this methodology for identification and clinical translation of proteomic biomarkers into FDA approved diagnostics.

Project description:Nanoparticles exposed to biological fluids are rapidly surrounded by proteins. It is known that this formed protein corona influences the interplay of nanoparticles with cells or tissue barriers. In this study, we report the impact of a formed human plasma protein corona on the transfer of 80 nm polystyrene (PS) nanoparticles across the human placenta. We used the human ex-vivo placental perfusion model, as it reflects the intact and physiological tissue barrier between mother and unborn. Our results show an enhanced transfer of polystyrenes, exposed to human plasma, across the placenta compared to bovine serum albumin which served as control setting. We isolated nanoparticles before and after tissue exposure and analyzed their protein corona via shotgun proteomics and LC-MS/MS. The corona profile of particles that crossed the placenta highlighted several proteins as possible drivers for elevated tissue transfer. Subsequently two distinct proteins, human albumin and immunoglobulin G, were selected and incubated with the nanoparticles to form a sole protein corona. Strikingly, the protein corona formed by albumin induced significantly the transfer of polystyrenes across the tissue as compared to corona formed by immunoglobulins. To conclude, our study provides a comparative analysis between different formed protein coronas on nanoparticles and a corona dependent transfer behavior of polystyrenes across placental tissue. Our findings suggest that protein corona analyses of nanoparticles might help to understand better their properties at biological barriers.

Project description:Conventional mass spectrometry (MS)-based bottom-up proteomics (BUP) analysis of protein corona [i.e., an evolving layer of biomolecules, mostly proteins, formed on the surface of nanoparticles (NPs) during their interactions with biomolecular fluids] enabled nanomedicine community to partly identify the biological identity of NPs. Such an approach, however, fails pinpoint the specific proteoforms—distinct molecular variants of proteins, which is essential for prediction of the biological fate and pharmacokinetics of nanomedicines. Recognizing this limitation, this study pioneers a robust and reproducible MS-based top-down proteomics (TDP) technique for precisely characterizing proteoforms in the protein corona. Our TDP approach has successfully identified hundreds of proteoforms in the protein corona of polystyrene NPs, ranging from 3-70 kDa, revealing over 20 protein biomarkers with combinations of post-translational modifications, signal peptide cleavages, and/or truncations—details that BUP could not fully discern. This advancement in MS-based TDP offers a more comprehensive and exact characterization of NP protein coronas, deepening our understanding of NPs' biological identities and potentially revolutionizing the field of nanomedicine.

Project description:Identification of corona proteins in serum and plasma of healthy donors

Project description:Two-dimensional (2D) nanomaterials, an ultrathin class of materials such as graphene, nanoclays, transition metal dichalcogenides (TMDs), and transition metal oxides (TMOs), have emerged as a new generation of materials due to their unique properties relative to macroscale counterparts. However, little is known about the transcriptome dynamics following exposure to these nanomaterials. Here we investigate the interactions of 2D nanosilicates, a layered clay, with human mesenchymal stem cells (hMSCs) at the whole transcriptome level by high-throughput sequencing (RNA-seq). Analysis of cell-nanosilicate interactions by monitoring change in transcriptome profile uncovers key biophysical and biochemical cellular pathways triggered by nanosilicates. A widespread alteration of genes is observed due to nanosilicate exposure as more than 4,000 genes are differentially expressed. The change in mRNA expression levels reveal clathrin-mediated endocytosis of nanosilicates. Nanosilicate attachment to cell membrane and subsequent cellular internalization activate stress-responsive pathways such as mitogen activated protein kinase (MAPK), which subsequently directs hMSC differentiation towards osteogenic and chondrogenic lineages. This study provides transcriptomic insight on the role of surface-mediated cellular signaling triggered by nanomaterials and enables development of nanomaterials-based therapeutics for regenerative medicine. This approach in understanding nanomaterial-cell interactions, illustrates how change in transcriptomic profile can predict downstream effects following nanomaterial treatment.