Comprehensive and deep profiling of the plasma proteome with protein corona on zeolite NaY

Proteomic characterization of plasma is critical for the development of novel pharmacodynamic biomarkers.However,the vast dynamic range renders the profiling of proteomes extremely challenging.Here,we synthesized zeolite NaY and developed a simple and rapid method to achieve comprehensive and deep profiling of the plasma proteome using the plasma protein corona formed on zeolite NaY.Specifically,zeolite NaY and plasma were co-incubated to form plasma protein corona on zeolite NaY(NaY-PPC),followed by conventional protein identification using liquid chromatography-tandem mass spectrometry.NaY was able to significantly enhance the detection of low-abundance plasma proteins,minimizing the“masking”effect caused by high-abundance proteins.The relative abundance of middleand low-abundance proteins increased substantially from 2.54%to 54.41%,and the top 20 highabundance proteins decreased from 83.63%to 25.77%.Notably,our method can quantify approximately 4000 plasma proteins with sensitivity up to pg/mL,compared to only about 600 proteins identified from untreated plasma samples.A pilot study based on plasma samples from 30 lung adenocarcinoma patients and 15 healthy subjects demonstrated that our method could successfully distinguish between healthy and disease states.In summary,this work provides an advantageous tool for the exploration of plasma proteomics and its translational applications.

Genome mining reveals the biosynthetic potential of the marinederived strain Streptomyces marokkonensis M10

Marine streptomycetes are rich sources of natural products with novel structures and interesting biological activities,and genome mining of marine streptomycetes facilitates rapid discovery of their useful products.In this study,a marine-derived Streptomyces sp.M10 was revealed to share a 99.02%16S rDNA sequence identity with that of Streptomyces marokkonensis Ap1T,and was thus named S.marokkonensis M10.To further evaluate its biosynthetic potential,the 7,207,169 bps of S.marokkonensis M10 genome was sequenced.Genomic sequence analysis for potential secondary metaboliteassociated gene clusters led to the identification of at least three polyketide synthases(PKSs),six non-ribosomal peptide synthases(NRPSs),one hybrid NRPS-PKS,two lantibiotic and five terpene biosynthetic gene clusters.One type I PKS gene cluster was revealed to share high nucleotide similarity with the candicidin/FR008 gene cluster,indicating the capacity of this microorganism to produce polyene macrolides.This assumption was further verified by isolation of two polyene family compounds PF1 and PF2,which have the characteristic UV adsorption at 269,278,290 nm(PF1)and 363,386 and 408 nm(PF2),respectively.S.marokkonensis M10 is therefore a new source of polyene metabolites.Further studies on S.marokkonensis M10 will provide more insights into natural product biosynthesis potential of related streptomycetes.This is also the first report to describe the genome sequence of S.marokkonensis-related strain.