Surface protein analysis of breast cancer exosomes using visualized strategy on centrifugal disk chip.

Breast cancer, the most common cancer among women worldwide, lacks specific tumor markers for accurate diagnosis. Recent advances have highlighted tumor-derived exosomes as a promising non-invasive biomarker for cancer detection. Continuous monitoring of surface protein markers on exosomes in the blood could offer valuable insights for breast cancer diagnosis. However, integrating the isolation and detection of exosomes from whole blood is bulky, time-consuming, and requires professional operations. To address this difficulty, we developed a method of integrated centrifugal disk chip (CD chip) exosome enrichment directly from whole blood followed by a colorimetric visualization strategy for multiplex analysis. The disc consists of multi-chambers and multi-microchannels with immediate smartphone-enabled processing of colorimetric results. The combination of CEA + CA125 + EGFR on-chip detection could significantly differentiate the different stages of cancer in tumor-bearing mice and successfully distinguish between breast cancer patients and healthy individuals. Crucially, small volumes (100 µL) of blood samples were adequate. In addition, the chip was simple and fast, with results within 10 min, which provides immediate exosomal information through consecutive blood sampling, which could potentially result in a more timely and well-informed clinical breast cancer diagnosis.

Bioluminescence assay for rapid detection of live Staphylococcus aureus based on the enrichment of egg yolk antibody modified magnetic metal organic framework immunobeads.

Specific and rapid detection of live Staphylococcus aureus (S.A) in environmental and food samples is critically important for protecting human health. In order to fulfill this purpose, two kinds of novel egg yolk antibody (IgY) immobilized immunomagnetic beads (IMBs; mSiO2-IgY and mMOF-IgY), with core-shell mSiO2 and mMOF as substrate, were prepared for selectively enriching S.A from samples. Furthermore, the IMBs with captured S.A were collected and re-dissolved in 0.5 mL PBS. After that, a cotton swab coated with sodium dodecylsulfate (SDS) was put in the solution to lyse S.A cells and emit ATP bioluminescence of the luciferin/luciferase system. Finally, a portable bioluminescence detector was used for quantification of ATP corresponding to S.A concentration. The results demonstrated that mMOF-IgY can enrich more S.A than mSiO2-IgY and emit a stronger signal. The reasons may be due to the higher immobilization amount of IgY on the IMBs. Under optimal conditions, the calibration line of S.A concentration was 10-105 CFU mL-1 by mMOF-IgY within 30 min. The low detection limit of S.A was 3 CFU mL-1. The results demonstrated that the assay takes much shorter time than plate counting. Its portability and excellent detection capability are suitable for rapid monitoring of specific pathogens in foods.

A filter-electrochemical microfluidic chip for multiple surface protein analysis of exosomes to detect and classify breast cancer.

Breast cancer (BC) is a complex disease with high variability and no specific tumor markers available for diagnosis. Exosomes contain rich maternal tumor information and are a novel non-invasive biomarker with the potential for cancer diagnosis and prognosis. However, analysis of exosomal protein markers in blood samples is challenging due to lengthy sample workups and insufficient sensitivity. To address this difficulty, we developed a novel filter-electrochemical microfluidic chip (FEMC) to detect and classify BC directly in whole blood without requiring heavy purification methods. In our system, exosome enrichment was performed using a dual filtration system. The target was directed through a curved channel onto four screen-printed electrodes (SPEs), where it was captured by the previously modified antibodies. Simultaneously, Zr-MOFs encapsulated with a large number of methylene blue molecules (MB@UiO-66) were absorbed on the surface of exosomes due to the high affinity for phosphate groups. This process leads to the amplification of electrical signals. The approach demonstrated that the utilization of BC exosome-associated tumor biomarkers (i.e., PMSA, EGFR, CD81, and CEA), enabled the classification of various BC mouse models samples and clinical BC samples. The entire FEMC assay was completed in 1 h with a limit of detection of 1 × 104 particles/mL. Thus, the FEMC assay can provide real-time detection information, allowing timely and better-informed opportunities for clinical BC diagnosis and typing.

Portable ATP bioluminescence sensor with high specificity for live Escherichia coli O157:H7 strain synergistically enhanced by orientated phage-modified stir bar extraction and bio-proliferation.

Live foodborne pathogens proliferate rapidly and do great harm to human health, which requires appropriate methods to supervise. In this work, a portable adenosine triphosphate (ATP) bioluminescence sensor with high specificity for live E. coli O157:H7 strain synergistically enhanced by orientated phage-modified stir bar extraction and bio-proliferation was developed. In brief, the selected phages were directionally immobilized on the poly(diallyldimethylammonium chloride)-modified gold stir bar as the bioreceptor. Following the simple stir bar absorptive extraction and bio-proliferation in the Luria-Bertani medium, the number of captured E. coli O157:H7 exploded. Finally, it was quantified by a portable ATP bioluminescence sensor. Benefitting from the high specificity of phage and simple signal dual-amplification strategy, the proposed biosensor achieved the recognition of live bacteria at strain level with superior sensitivity. Also, the portable signal readout made it suitable for on-site detection. Under optimal conditions, this bioassay provided a detectable range of 102-107 CFU mL-1 with a low detection limit of 30 CFU mL-1 within 30 min. The detection results for real samples demonstrated that there were no differences between the assay and the plate counting method, while the detection time was largely shortened. Furthermore, the assay gives a novel path for the point-of-care test (POCT) of live E. coli strain, which is promising to be extended to other virulent strains measurement with corresponding phages.

Ultrasensitive Analysis of Exosomes Using a 3D Self-Assembled Nanostructured SiO2 Microfluidic Chip.

Conventional microfluidics with a solid mixer for exosome detection is constrained by the low binding efficiency of the solid-liquid boundary effects and reduced sensitivity of individual markers. Here, we report a 3D-SiO2 porous chip that combines nanoscale porous characteristics and multiple exosome specific markers to greatly improve the sensitivity for biosensing. The lower limit of detection was 220 particles/µL exosomes in PBS. We applied the 3D-SiO2 porous chip for prostate cancer (PCa) staging in mice and early detection of clinical PCa patients. The developed method could significantly differentiate the different stages of PCa in mice and improve the early detection rate in clinical patients. Expression of multiple specific markers in clinical serum samples identified disease fingerprints, alongside histological results, which supports the potential application of exosomes as a noninvasive surrogate biopsy for PCa.

Progress in infrared spectroscopy as an efficient tool for predicting protein secondary structure.

Infrared (IR) spectroscopy is a highly sensitive technique that provides complete information on chemical compositions. The IR spectra of proteins or peptides give rise to nine characteristic IR absorption bands. The amide I bands are the most prominent and sensitive vibrational bands and widely used to predict protein secondary structures. The interference of H2O absorbance is the greatest challenge for IR protein secondary structure prediction. Much effort has been made to reduce/eliminate the interference of H2O, simplify operation steps, and increase prediction accuracy. Progress in sampling and equipment has rendered the Fourier transform infrared (FTIR) technique suitable for determining the protein secondary structure in broader concentration ranges, greatly simplifying the operating steps. This review highlights the recent progress in sample preparation, data analysis, and equipment development of FTIR in A/T mode, with a focus on recent applications of FTIR spectroscopy in the prediction of protein secondary structure. This review also provides a brief introduction of the progress in ATR-FTIR for predicting protein secondary structure and discusses some combined IR methods, such as AFM-based IR spectroscopy, that are used to analyze protein structural dynamics and protein aggregation.

Highly efficient synergistic biocatalysis driven by stably loaded enzymes within hierarchically porous iron/cobalt metal-organic framework via biomimetic mineralization.

The integration of multimodal chemo-/bio-catalysis for efficient cascade reactions has long provided broad prospects in the field of biotechnology for ages. In this work, we describe the synthesis of a biomimetic multienzyme hybrid with hierarchically porous structure and outstanding catalytic activity via in situ encapsulation of natural enzymes in an iron-cobalt bimetallic metal-organic framework (Fe/Co-MOF, FCM). The combination of a single enzyme (glucose oxidase) or dual enzyme (ß-galactosidase and glucose oxidase) with FCM resulted in remarkable synergistic biocatalysis ability; in contrast to simple biocatalyst mixtures in solution, the prepared multienzyme hybrid resulted in 3.2-fold and 2.1-fold improvements in activity for tandem reactions, respectively. The reinforced cascade bioactivity of the multienzyme hybrid benefitted from the synergistic effect between iron/cobalt in the FCM nanozyme, the opened substrate channel between enzymes/nanozymes, and the beneficial effect provided by the hierarchical MOF pores. The enlarged pores not only provided adequate space for immobilized proteins to diffuse and reorientate in FCM with low surface energy, but also reduced the intrinsic mass transfer obstacle to increase the diffusional efficiency of reactants/intermediates. In addition, on account of the shielding effect provided by FCM, the multienzyme hybrid exhibited enhanced tolerance towards severe circumstances and excellent reusability and has been successfully applied in small molecule detection, such as glucose and lactose. The current study highlights the superiority of synergistic bioreactors integrated with the MOF nanozyme and natural enzymes, suggesting great potential for applications in sustainable biomimetic catalysis.

Evolution of the protein corona affects macrophage polarization.

When nanoparticles (NPs) come into contact with bioenvironments, a protein corona forms on the NP surface. Previous reports showed that the constituents of the corona change with time. However, how different protein corona compositions influence cells, especially immune cells, has received less attention. Macrophages are important immune cells that can be polarized into a pro-inflammatory (M1) or anti-inflammatory (M2) phenotype. In this study, AuNPs were incubated with human plasma for different periods to obtain time-related AuNP-coronas, and the influences of time-related AuNP-coronas on macrophage polarization were investigated. The macrophage morphology, biomarkers, cytokine secretion studies show that the pristine AuNPs and 4 h-AuNP-corona induced macrophage cells into M2 phenotype, while the co-incubation of 12 h-AuNP-corona and macrophage cells result in M1 phenotype. Further proteomic analysis showed that the compositions of protein corona were changing constantly after AuNPs contacted with plasma. When the incubation time increased to 12 h, the immune proteins in protein corona were increased significantly, which play a key role in modulation of the different macrophages polarization. Our findings demonstrated that plasma incubation time is an important parameter that needs to be taken into account in the study of nano-immune interactions and safe use of NPs in biological systems. Moreover, our finding can be a new efficient strategy for activating inflammatory or anti-inflammatory in medical treatment.

Rapid and specific detection nanoplatform of serum exosomes for prostate cancer diagnosis.

Tumor exosomes that inherit specific molecules from their parent cells are emerging as ideal biomarkers in cancer diagnostics. Most currently available exosome isolation and detection methods are time-consuming and non-specific; thus, rapid and specific exosome detection methods are needed both clinically and in research. Here, a dual-functional platform is reported composed of reversible conjunction and "off-on" signal responses. Fe3O4@SiO2@TiO2 particles with high affinity were applied to capture exosomes, and model exosomes could be isolated from solution within 20 min with a capture efficiency of 91.5%. An "on-off" fluorescence response PSMA aptasensor was constructed with improved selectivity to detect tumor exosomes by recording the fluorescence intensity with λex/em = 557/580 nm. The standard curve for detecting tumor exosomes with the aptasensor was calculated as y = 371.7x + 66.17, ranging from 0.05 to 1 × 104 particles/µL, with R2 = 0.9737, and a detection limit of 5 × 102 particles/µL in solution. This method was successfully applied to clinical samples, and the results showed better performance in distinguishing prostate cancer patients and healthy samples than the traditional nanoparticle-tracking analysis (NTA) method. This rapid and accurate detection method for prostate cancer may aid in rapid clinical diagnosis. Integrating quickly TiO2-based isolation with sensitive and specific "on-off" detection of PCa exosomes.

Direct distinction of ibuprofen and flurbiprofen enantiomers by ion mobility mass spectrometry of their ternary complexes with metal cations and cyclodextrins in the gas phase.

Enantiomeric drugs are widely used and play important roles in pharmaceuticals. Ion mobility spectrometry coupled with mass spectrometry technology provides a unique method for distinguishing the enantiomeric drugs, enantiomeric identification, and quantitation in the gas phase. In this study, enantiomeric molecules of ibuprofen and flurbiprofen were clearly recognized by forming host-guest complex ions using trapped ion mobility time-of-flight mass spectrometry. Ternary complex ions can be produced easily by electrospray ionization of the mixed solutions of ibuprofen, cyclodextrins, and CaCl2 , LiCl, or NaCl, as well as flurbiprofen, cyclodextrins, and CaCl2 . The relative contents of different chiral ibuprofens in a mixed solution were also quantitatively measured. This new method is a simple, effective, and a convenient enantioselective analysis method.

Discrimination of Aminobiphenyl Isomers in the Gas Phase and Investigation of Their Complex Conformations.

The analysis of positional isomers is of great significance because their different chemical properties but similar structures make separation difficult. In this work, a simple method for simultaneously discriminating three positional isomers of 2-aminobiphenyl (2-ABP), 3-ABP, and 4-ABP was studied by ion mobility spectrometry (IMS) and quantum mechanical calculations at the molecular level. In the experiments, three ABP isomers were mixed with α-, ß-, and γ-cyclodextrins (CD), and the IMS results show that the three ABP isomers were clearly recognized by the formed complex of [α-CD + ABP + H]+ via measuring their IMS, in which the different ion mobilities of 1.515, 1.544, 1.585 V·s·com-2 with the collision cross sections (CCS) of 307.3, 312.5, 320.8 Å2 were obtained for [α-CD + 2-ABP + H]+, [α-CD + 3-ABP + H]+, and [α-CD + 4-ABP + H]+, respectively. Collision induced dissociation analysis of the three [α-CD + ABP + H]+ isomer complexes were further studied, indicating that the same fragmentation process required different collisional energies, and the greater the CCS for the [α-CD + ABP + H]+ with looser structure and the smaller energy required. Besides, the favorable conformation and the CCS value of the different [CD + ABP + H]+ isomer complexes were measured via quantum mechanical calculations to detail their intermolecular interactions. It revealed that the intermolecular binding between 2-ABP and α-CD is different from that of 3- and 4-ABP, resulting in different molecular conformations and CCS, and the interaction modes of ABP with ß-CD are similar to that with γ-CD, which are very consistent with the experimental observations. Finally, relative quantification of the method was performed, and satisfactory linearity with correlation coefficients (R2) greater than 0.99 was obtained. This method for isomer discrimination and conformation analysis possesses the advantages of simplicity, sensitivity, cost-effectiveness, and as such it may be widely applied in chemistry and pharmaceutical sciences.

CaCO3-Encapsulated Au Nanoparticles Modulate Macrophages toward M1-like Phenotype.

Macrophage cells are plastic and can be polarized into opposing phenotypes, pro-inflammatory (M1-like cells) or anti-inflammatory (M2-like cells). Reprograming of M2-like cells into M1 phenotype will contribute significantly to combatting cancer. Gold nanoparticles (AuNPs) are intensively studied in various fields for their distinctive photo-chemical properties. However, the immune response of AuNPs is still unclear. In this study, AuNPs and CaCO3-encapsulated Au nanoparticles (Au@CaCO3 NPs) were synthesized as stimuli for macrophage modulation. Co-incubation of AuNPs and macrophages leads to a dramatically elongated macrophage cell morphology. Moreover, increased expression of M2 biomarker and M2-inducing cytokines suggests that AuNPs induce macrophage polarization toward M2 phenotype. More interestingly, the co-incubation of Au@CaCO3 NPs and macrophage cells resulted in a round cellular morphology and induced the secretion of M1 biomarker and inflammatory cytokines. Our studies demonstrate that the strategy of CaCO3-encapsulated Au nanoparticles can be used in modulating the polarization of M1 macrophages. Our strategy provides an efficient method for activating inflammation in macrophages, which will be useful for the application of nanoparticles in cancer therapy.

Microfluidic Raman biochip detection of exosomes: a promising tool for prostate cancer diagnosis.

Tumor-derived exosomes, which contain RNA, DNA, and proteins, are a potentially rich non-invasive source of biomarkers. However, no efficient isolation or detection methods are yet available. Here, we developed a microfluidic Raman biochip designed to isolate and analyze exosomes in situ. Anti-CD63 magnetic nanoparticles were used to enrich exosomes through mixing channels of a staggered triangular pillar array. EpCAM-functionalized Raman-active polymeric nanomaterials (Raman beads) allow rapid analysis of exosome samples within 1 h, with a quantitative signal at 2230 cm-1. The limit of detection of this biochip approaches 1.6 × 102 particles per mL with 20 µL samples. The newly developed biochip assay was successfully applied in the determination of exosomes from clinical serum samples. Thus, this novel device may have potential as a clinical exosome analysis tool for prostate cancer.

Evaluation of prostate cancer based on MALDI-TOF MS fingerprinting of nanoparticle-treated serum proteins/peptides.

The serum MALDI-TOF MS spectrum includes signals for serum proteins and peptides between 1000 and 12,000 Da in size, presenting a fingerprint-like pattern. However, whole serum MALDI-TOF MS signals are complex and prejudiced for data analysis. Pre-treatment with specific nanomaterials can simplify the mass spectrum while retaining the characteristics of the fingerprint pattern. In the present study, we used hydrophilic interaction chromatography nanoparticles (HICNPs) to enrich proteins and peptides in serum from a large number prostate cancer samples and controls. After pre-treatment with HICNPs, the serum MALDI-TOF MS signals for samples were simpler, with more analysable fingerprint-like patterns. Principal component analysis and partial least squares discriminant analysis of the samples demonstrated a significant difference in the MALDI-TOF signals between prostate cancer and controls, with an analytical accuracy of 77%, approaching that of methods based on prostate-specific antigen. Due to the low cost and high flux, MALDI-TOF MS fingerprinting can be used in large-scale evaluation of various cancers, including prostate cancer.

Labeled-protein corona-coated Bi2S3 nanorods targeted to lysosomes for bioimaging and efficient photothermal cancer therapy.

One of the main diseases contributing to human death are malignant tumors. Phototherapy is a promising approach for cancer therapy, and functional nanoparticles with targeting ligands are commonly used to improve the therapeutic efficiency. However, recent studies have shown that nanoparticles in contact with a biological fluid can rapidly form a "protein corona" on their surface, which will remarkably decrease the targeting ability. Here, we describe the preparation of hybrid nanomaterials with Bi2S3 nanorods as the core, and fluorescein-isothiocyanate and folic acid-modified human serum albumin (HSA-FITC-FA) as the shell. By using fluorescent binding label (FITC) and imaging techniques, we discovered the image of the cell lysosomes, indicating that the photothermal therapy agent was predominantly targeted to and accumulated in lysosomes. Combined with photothermal therapy agent (Bi2S3 nanorods) and targeting ligand (FA), the obtained product shows enhanced photothermal therapy under near-infrared region laser irradiation. Additionally, SDS-PAGE shows that the modified HSA shell could remarkably reduce the reabsorption of protein corona from blood serum, minimized the adverse effect of protein corona on targetability. Taken together, the results indicate that our strategy has the potential for preparing efficient photothermal nanomaterials with image-guided subcellular organelle-targeting cancer cell ablation ability.

Fluorescent polymer dots and graphene oxide based nanocomplexes for "off-on" detection of metalloproteinase-9.

Numerous studies have demonstrated that cancer-related matrix metalloproteinase-9 (MMP-9) is an ideal biomarker for cancer diagnosis. However, most MMP-9 detection methods are expensive and time-consuming, and more convenient and specific MMP-9 detection methods are needed both clinically and in research. In the present study, peptide-linked polymer dots were assembled onto a graphene oxide surface to construct a graphene oxide-peptide-polymer dot (GO-Pep-Pdot) nanocomplex for sensitive, rapid, and accurate detection of MMP-9. In the absence of MMP-9, the nanocomplex was in an "off" state, whereas in the presence of MMP-9, the nanocomplex was turned "on", resulting in the emission of a fluorescence signal that is linearly correlated with the MMP-9 concentration. The limit of detection of the nanocomplex was 3.75 ng mL-1, lower than most methods. This method was successfully verified by detecting MMP-9 in clinical serum samples of prostate cancer. The results suggest that this protease nanocomplex is generic and can be adopted to respond to other proteases by selecting specific peptides with suitable cleavage sites in clinics.

Thuricin†Z: A Narrow-Spectrum Sactibiotic that Targets the Cell Membrane.

Sactionine-containing antibiotics (sactibiotics) are a growing class of peptide antibiotics belonging to the ribosomally synthesized and post-translationally modified peptide (RiPP) superfamily. We report the characterization of thuricin Z, a novel sactibiotic from Bacillus thuringiensis. Unusually, the biosynthesis of thuricin Z involves two radical S-adenosylmethionine (SAM) enzymes, ThzC and ThzD. Although ThzC and ThzD are highly divergent from each other, these two enzymes produced the same sactionine ring in the precursor peptide ThzA in vitro. Thuricin Z exhibits narrow-spectrum antibacterial activity against Bacillus cereus. A series of analyses, including confocal laser scanning microscopy, ultrathin-sectioning transmission electron microscopy, scanning electron microscopy, and large-unilamellar-vesicle-based fluorescence analysis, suggested that thuricin Z binds to the bacterial cell membrane and leads to membrane permeabilization.

Movements of the Substrate-Binding Clamp of Cypemycin Decarboxylase CypD.

Linaridins are a small but growing class of natural products belonging to the ribosomally synthesized and post-translationally modified peptide (RiPP) superfamily. The class A linaridins, exemplified by cypemycin, possess an unusual S-[( Z)-2-aminovinyl]-d-cysteine (AviCys) residue. Formation of the AviCys in cypemycin requires an oxidative decarboxylation of the precursor peptide C-terminal Cys, and this reaction is catalyzed by a flavin-dependent decarboxylase CypD. In this work, we investigate the molecular recognition processes of CypD by a combination of computational and biochemical analysis. We show that the substrate binding clamp of CypD undergoes dramatic fluctuation, mediating both the substrate entrance into and product release from the catalytic pocket. Extensive molecular dynamic simulations and Fourier transform IR analyses indicated that binding of the substrate induces substantial structural change of the enzyme, converting the substrate-binding clamp from a random loop to a more ordered structure comprising two ß sheets and a ß turn. The salt bridge between Arg159 guanine and the Cys carboxylate of substrate plays an important role in mediating substrate binding, while hydrophobic interactions are also important in this process. These results provide important mechanistic insights into CypD and other flavin-dependent Cys decarboxylases, and could facilitate future biosynthetic and bioengineering efforts in studying AviCys-containing RiPPs.

Convergent evolution of the Cys decarboxylases involved in aminovinyl-cysteine (AviCys) biosynthesis.

S-[(Z)-2-aminovinyl]-d-cysteine (AviCys) is a unique motif found in several classes of ribosomally synthesized and post-translationally modified peptides (RiPPs). Biosynthesis of AviCys requires flavin-dependent Cys decarboxylases, which are highly divergent among different RiPP classes. In this study, we solved the crystal structure of the cypemycin decarboxylase CypD. We show that CypD is structurally highly similar to lanthipeptide decarboxylases despite the absence of sequence similarities between them. We further show that Cys decarboxylases from four RiPP classes have evolved independently and form two major clusters. These results reveal the convergent evolution of AviCys biosynthesis and suggest that all the flavin-dependent Cys decarboxylases likely have a similar Rossmann fold despite their sequence divergences.

Biosynthetic Insights into Linaridin Natural Products from Genome Mining and Precursor Peptide Mutagenesis.

Linaridin is a small class of peptide natural products belonging to the ribosomally synthesized and post-translationally modified peptides (RiPPs) superfamily. By an extensive genome-wide survey of linaridin biosynthetic genes, we show that this class of natural products is widespread in nature and possesses vast structural diversity. The linaridin precursor peptides are relatively conserved in the N-termini but have diverse sequences in the core region, which appear to have coevolved with the biosynthetic enzymes. Using the prototypic linaridin cypemycin as a model, we have explored the structure-activity relationships involved in precursor peptide maturation and generated a diverse set of novel cypemycin variants, among which the T2S variant exhibits enhanced activity against Micrococcus luteus. Our results reveal valuable insights into linaridin biosynthesis and highlight the potential to explore this class of natural products by genome mining and by biosynthetic engineering studies.