Project description:Once NPs were administered into the physiological condition, several serum proteins could adsorb rapidly onto the NPs to form a protein layer (also called protein corona). The effect of protein corona surrounding the NPs depends on several parameters such as size, charge and other surface properties of NPs, which could contribute a great deal of influence in determining the NP's fate.

Project description:How soft corona i.e., the protein corona’s outer layer contributes to “biological” identity of nanomaterials (NMs) is largely unknown due to a longstanding challenge in capturing protein composition of the soft corona in situ. We herein develop an in situ “Fishing” method that can monitor the dynamic formation of protein corona on ultra-small chiral Cu2S nanoparticles (NPs) allowing us to directly separate and identify their protein composition. This method can detect spatiotemporal processes in the evolution of hard and soft coronas on chiral NPs, revealing subtle differences in their composition even within several minutes. This study highlights the importance of in situ and dynamic analysis of soft/hard corona composition, provides detailed insights into the roles of protein corona composition in mediating the biological responses of NPs, and offers a universal strategy to characterize the soft corona that will serve as a powerful tool for rational design of biomedical NMs.

Project description:Infection-related development of phytopathogenic fungi is initiated by sensing and responding to plant surface cues. This response results in the formation of specialized infection structures, so-called appressoria. To unravel the program inducing appressoria in the biotrophic smut fungus Ustilago maydis, we exposed cells to a hydrophobic surface and the cutin monomer 16-hydroxy hexadecanoic acid. Genome-wide transcriptional profiling under these appressorium-inducing in vitro conditions revealed dramatic transcriptional changes in almost 20% of the genes. Comparisons with the U. maydis sho1 msb2 double mutant, lacking two putative sensors for plant surface cues, revealed that these plasma membrane receptors regulate a small subset of the surface cue-induced genes. These genes comprised mainly secreted proteins including plant cell wall degrading enzymes that facilitate plant penetration and secreted effectors that are essential virulence factors, with functions after penetration. Our data also demonstrate specific effects on two transcription factors that redirect the transcriptional regulatory network towards appressorium formation and plant penetration. Thus, plant surface cues prime U. maydis for biotrophic development. Solopathogenic Ustilago maydis strain AM1 and its derivate AM1Δsho1Δmsb2 were grown to mid-log phase in YEPSL medium and resuspended in 2% YEPSL plus/minus 16-hydroxy hexadecanoic acid (HDA). The cell suspensions were sprayed on hydrophobic surface (Parafilm) and incubated for 12 h. As control, cells were sprayed on hydrophilic glass surface and incubated for 2 h. After RNA extraction Affymetrix microarrays were performed.

Project description:We report a highly parallel protein quantitation platform integrating nanoparticle (NP) protein coronas with liquid chromatography-mass spectrometry for large-scale, efficient proteomic profiling. A protein corona is a protein layer adsorbed onto NPs upon contact with biofluids. Varying the physicochemical properties of engineered NPs translates to distinct protein corona patterns enabling differential and reproducible interrogation of biological samples. Spike experiments confirmed a linear signal response. The median coefficient of variation was ~22%. The NP corona formation enables deep sampling of the plasma proteome. We screened 43 NPs and selected a panel of 5, which detected more than 2,000 proteins from 141 plasma samples using a 96-well automated workflow in a pilot cancer classification study. Our streamlined workflow combines depth of coverage and throughput with precise relative quantification based on unique interactions between proteins and a panel of engineered NPs for deep and scalable quantitative proteomic studies and biomarker discovery.

Project description:We describe the concentration and composition of the protein corona as a function of incubation time (30 min and 1 day) and the concentration of fetal bovine serum (FBS) used to form the corona (5%, 10%, and 100%) on 200 nm carboxylate-modified magnetic NPs, using semi-automated processes.

Project description:How to separate hydrophobic peptides and to prevent loss of such peptides, nevertheless, have not been drawn enough attention (19). As a membrane protein possesses higher hydrophobicity, especially for one with multiple bilayer-exposed domains, efficient detection of hydrophobic peptides becomes a critical issue for its identification. It is generally recognized that MPs have two characteristics, relatively shorter sequences of amino acids and higher hydrophobicity.

Project description:Nano-sized objects such as liposomes are modified by adsorption of biomolecules in biological fluids. The resulting corona critically changes nanoparticle behavior at cellular level. A better control of corona composition could allow to modulate uptake by cells. Within this context, in this work, liposomes of different charge were prepared by mixing negatively charged and zwitterionic lipids to different ratios. The series obtained was used as a model system with tailored surface properties to modulate corona composition and determine the effects on liposome interactions with cells. Uptake efficiency and uptake kinetics of the different liposomes were determined by flow cytometry and fluorescence imaging. Particular care was taken in optimizing the methods to isolate the corona forming in human serum to prevent liposome agglomeration and to exclude residual free proteins which could confuse the results. Thanks to the optimized methods, mass spectrometry of replicate corona isolations showed excellent reproducibility and this allowed semi-quantitative analysis to determine for each formulation the most abundant proteins in the corona. The results showed that by changing the fraction of zwitterionic and charged lipids in the bilayer, the amount and identity of the most abundant proteins adsorbed from serum differed. Interestingly, the formulations also showed very different uptake kinetics. Similar approaches can be used to tune lipid composition in a systematic way in order to obtain formulations with the desired corona and cell uptake behavior.

Project description:Nanodrugs need a completely characterization by both chemically and biological point of view. As nanoparticles have evolved as multi-functional systems combining different custom anchorages, their pharmacological involvements require more comprehensive analysis. In this work, we present the design and synthesis of novel iron-NPs conjugated with a cisplatin derivate and their biological evaluation by quantitative proteomics approches. To decipher detailed insights related to the NP interactions with environment (as protein corona) and pharmacodynamics functionalities of the nanodrugs conjugates, LC-MS/MS analysis was perform to stablish protein profile. Biocompatibility and animal model provided complete insights of the potential of multifunctional iron NPs.

Project description:Dr. Panjwani's laboratory is focusing on the mechanism by which galectins-3 and 7 mediate corneal epithelial cell migration. We are currently performing studies to: (i) identify and characterize the corneal epithelial cell surface and extracellular matrix (ECM) molecules which serve as counterreceptors of galectin-3 and -7, to establish whether the lectins modulate corneal epithelial cell migration by binding to well known integrins, growth factor receptors, and/or ECM molecules and (ii) determine whether galectin-3 mediates corneal epithelial cell migration indirectly by modulating the expression of key adhesion and/or signal transduction molecules by using small interfering RNA, cDNA microarrays and glycogene arrays. It is known that a carbohydrate-binding protein, ELAM, serves as a marker for glaucoma. Other preliminary studies in my lab have shown that galectin-8 plays a role in the adhesion and spreading of trabecular meshwork cells (TM;the cells which modulate ocular pressure) and galectin-3 influences phagocytic capacity of TM cells. These studies suggest that galectins as well as ELAM and their counterreceptors may contribute to the pathogenesis of glaucoma. We have RNA preparations of five each of normal and glaucoma TM samples harvested over the last year from cadavers. We have RNA preparations of five each of normal and glaucoma TM samples harvested over the last yeat from cadavers.

Project description:Soybean cultivars,Soybean Hydrophobic Protein(HPS) comparison