Mesoporous Silica as Sorbents and Enzymatic Nanoreactors for Microbial Membrane Proteomics

Zhao, Jinzhi; Jian, Ruijun; Wang, Yuning; Yang, Baofeng; Zhao, Dan; Shen, Chengpin; Qiao, Liang; Liu, Baohong

doi:10.1021/acsami.0c19528

Cited by 7 publications

(11 citation statements)

References 37 publications

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“…On the basis of these considerations, multifunctional mesoporous materials are considered as potential candidates to form such an integrated approach. Multifunctional mesoporous materials have attracted great attention and provided unique advantages in biological separation and analysis. , For example, periodic mesoporous organosilica (PMO) have been developed for the enrichment and large-scale characterization of membrane proteins . Leveraging its relatively large surface area and sufficient functional groups, target proteins can be efficiently and selectively enriched by PMO.…”

Section: Introductionmentioning

confidence: 99%

All-in-One Strategy for Downstream Molecular Profiling of Tumor-Derived Exosomes

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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In light of the significance of exosomes in cancer diagnosis and treatment, it is important to understand the components and functions of exosomes. Herein, an all-in-one strategy has been proposed for comprehensive characterization of exosomal proteins based on nanoporous TiO 2 clusters acting as both an extractor for exosome isolation and a nanoreactor for downstream molecular profiling. With the improved hydrophilicity and inherent properties of TiO 2 , exosomes can be captured by a versatile nanodevice through the specific binding and hydrophilicity interaction synergistically. The strong concerted effect between exosomes and nanodevices ensured high efficiency and specificity of exosome isolation with high recovery and low contaminations. Meanwhile, highly efficient downstream proteomic analysis of the purified exosomes was also enabled by the nanoporous TiO 2 clusters. Benefiting from the porous structure of the nanodevice, the lysed exosomal proteins are highly concentrated in the nanopore to achieve high-efficiency in situ proteolytic digestion. Therefore, the unique features of the TiO 2 clusters ensured that all the complex steps about isolation and analysis of exosomes were completed efficiently in one simple nanodevice. The concept was first proved with exosomes from cell culture medium, where a high number of identified total proteins and protein groups in exosomes were obtained. Taking advantage of these attractive merits, the first example of the integrated platform has been successfully applied to the analysis of exosomes in complex real-case samples. Not only 196 differential protein biomarker candidates were discovered, but also many more significant cellular components and functions related to gastric cancer were found. These results suggest that the nanoporous TiO 2 cluster-based all-in-one strategy can serve as a simple, cost-effective, and integrated platform to facilitate comprehensive analysis of exosomes. Such an approach will provide a valuable tool for the study of exosome markers and their functions.

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Section: Introductionmentioning

confidence: 99%

All-in-One Strategy for Downstream Molecular Profiling of Tumor-Derived Exosomes

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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“…Proteins execute important functions at the cellular level, involving in diverse biological processes in living organisms. ,, Proteomic analysis, currently relying on MS techniques, provides valuable insights into the key biological processes in which the specific protein participates. − However, the macromolecular weight strains access to the direct ionization of proteins, which affects the potential application of large-scale protein identification. Therefore, tedious sample preparation is fundamentally important for bottom-up proteomics workflows, among which proteolysis converts the poorly ionized proteins into peptide fragments and benefits the downstream ionization and detection. , Traditional proteolysis including in-gel digestion and in-solution digestion is time-consuming (e.g., at least 12 h) and leads to artificial modification of substrate proteins. , Immobilization of enzymes in porous materials, owing to their unique properties such as high surface areas, tunable surface chemistry, and controllable size distribution, is a key strategy for improving proteolysis performance.…”

Section: Functionsmentioning

confidence: 99%

Porous Inorganic Materials for Bioanalysis and Diagnostic Applications

Liu

Song

Qian

et al. 2021

ACS Biomater. Sci. Eng.

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Porous inorganic materials play an important role in adsorbing targeted analytes and supporting efficient reactions in analytical science. The detection performance relies on the structural properties of porous materials, considering the tunable pore size, shape, connectivity, etc. Herein, we first clarify the enhancement mechanisms of porous materials for bioanalysis, concerning the detection sensitivity and selectivity. The diagnostic applications of porous material-assisted platforms by coupling with various analytical techniques, including electrochemical sensing, optical spectrometry, and mass spectrometry, etc., are then reviewed. We foresee that advanced porous materials will bring far-reaching implications in bioanalysis toward real-case applications, especially as diagnostic assays in clinical settings.

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“…For instance, magnetic nanocomposites have been used to purify proteins, significantly reducing the processing time. Mesoporous NPs, due to the adjustable pore size and large specific surface area, have been explored in size-based separation and membrane proteomics 12 , 13 . From the technical point of view of material science, several recent review articles have summarized the manufacturing of NPs and their applications in biomedical science 14 .…”

Section: Introductionmentioning

confidence: 99%

Application of nanomaterials in proteomics-driven precision medicine

Zhang

Yang

et al. 2022

Theranostics

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Nanostructured devices and nanoparticles have fundamentally reshaped the development of precision healthcare in recent decades. Meanwhile, mass spectrometry (MS)-based proteomics has evolved from simple protein sequencing to a powerful approach that identifies disease patterns and signatures, reveals molecular mechanisms of pathological processes, and develops therapeutic or preventive drugs. Significantly, the two distinct disciplines have synergized and expanded our knowledge about human health and disease, as evidenced by a variety of nanotechnology-assisted sample processing strategies, facilitating in-depth proteome profiling and post-translational modifications (PTMs) characterization. This review summarizes recent advances in nanoparticle design for better enrichment of marker proteins and their PTMs from various bio-specimens and emerging nanotechnologies that are applied to MS-based proteomics for precision medicine discovery.

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Mesoporous Silica as Sorbents and Enzymatic Nanoreactors for Microbial Membrane Proteomics

Cited by 7 publications

References 37 publications

All-in-One Strategy for Downstream Molecular Profiling of Tumor-Derived Exosomes

All-in-One Strategy for Downstream Molecular Profiling of Tumor-Derived Exosomes

Porous Inorganic Materials for Bioanalysis and Diagnostic Applications

Application of nanomaterials in proteomics-driven precision medicine

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