Epithelial-to-mesenchymal transition as the driver of changing carcinoma and glioblastoma microenvironment
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01.10.2020 |
Majc B.
Sever T.
Zarić M.
Breznik B.
Turk B.
Lah T.T.
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Biochimica et Biophysica Acta - Molecular Cell Research |
10.1016/j.bbamcr.2020.118782 |
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© 2020 Epithelial-to-mesenchymal transition (EMT) is an essential molecular and cellular process that is part of normal embryogenesis and wound healing, and also has a ubiquitous role in various types of carcinoma and glioblastoma. EMT is activated and regulated by specific microenvironmental endogenous triggers and a complex network of signalling pathways. These mostly include epigenetic events that affect protein translation-controlling factors and proteases, altogether orchestrated by the switching on and off of oncogenes and tumour-suppressor genes in cancer cells. The hallmark of cancer-linked EMT is that the process is incomplete, as it is opposed by the reverse process of mesenchymal-to-epithelial transition, which results in a hybrid epithelial/mesenchymal phenotype that shows notable cell plasticity. This is a characteristic of cancer stem cells (CSCs), and it is of the utmost importance in their niche microenvironment, where it governs CSC migratory and invasive properties, thereby creating metastatic CSCs. These cells have high resistance to therapeutic treatments, in particular in glioblastoma.
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Capillary-assisted microfluidic biosensing platform captures single cell secretion dynamics in nanoliter compartments
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01.05.2020 |
Hassanzadeh-Barforoushi A.
Warkiani M.E.
Gallego-Ortega D.
Liu G.
Barber T.
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Biosensors and Bioelectronics |
10.1016/j.bios.2020.112113 |
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© 2020 Elsevier B.V. Cancer cells continuously secrete inflammatory biomolecules which play significant roles in disease progression and tumor metastasis toward secondary sites. Despite recent efforts to capture cancer cells' intercellular secretion heterogeneity using microfluidics, the challenges in operation of these systems as well as the complexity of designing a biosensing assay for long-term and real-time measurement of single cell secretions have become grand research barriers. Here, we present a new capillary-based microfluidic biosensing approach to easily and reliably capture ~500 single cells inside isolated dead-end nanoliter compartments using simple pipette injection, and quantify their individual secretion dynamics at the single cell resolution over a long period of culture (~16 h). We first present a detailed investigation of the fluid mechanics underlying the formation of nanoliter compartments in the microfluidic system. Based on the measurement of single cell capture efficiency, we employ a one-step FRET-based biosensor which monitors the single cancer cells' protease activity. The sensor reports the fluorescent signal as a product of amino acid chain cleavage and reduction in its quenching capability. Using the single cell protease secretion data, we identified modes of cell secretion dynamics in our cell sample. While most of the cells had low secretion levels, two other smaller and more aggressive secretion dynamics were cells with secretion modes that include sharp spikes or slow but progressive trend. The method presented here overcomes the difficulties associated with performing single cell secretion assays, enabling a feasible and reliable technique for high throughput measurement of metabolic activities in cancer cells.
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Capillary-assisted microfluidic biosensing platform captures single cell secretion dynamics in nanoliter compartments
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01.05.2020 |
Hassanzadeh-Barforoushi A.
Warkiani M.E.
Gallego-Ortega D.
Liu G.
Barber T.
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Biosensors and Bioelectronics |
10.1016/j.bios.2020.112113 |
0 |
Ссылка
© 2020 Elsevier B.V. Cancer cells continuously secrete inflammatory biomolecules which play significant roles in disease progression and tumor metastasis toward secondary sites. Despite recent efforts to capture cancer cells' intercellular secretion heterogeneity using microfluidics, the challenges in operation of these systems as well as the complexity of designing a biosensing assay for long-term and real-time measurement of single cell secretions have become grand research barriers. Here, we present a new capillary-based microfluidic biosensing approach to easily and reliably capture ~500 single cells inside isolated dead-end nanoliter compartments using simple pipette injection, and quantify their individual secretion dynamics at the single cell resolution over a long period of culture (~16 h). We first present a detailed investigation of the fluid mechanics underlying the formation of nanoliter compartments in the microfluidic system. Based on the measurement of single cell capture efficiency, we employ a one-step FRET-based biosensor which monitors the single cancer cells' protease activity. The sensor reports the fluorescent signal as a product of amino acid chain cleavage and reduction in its quenching capability. Using the single cell protease secretion data, we identified modes of cell secretion dynamics in our cell sample. While most of the cells had low secretion levels, two other smaller and more aggressive secretion dynamics were cells with secretion modes that include sharp spikes or slow but progressive trend. The method presented here overcomes the difficulties associated with performing single cell secretion assays, enabling a feasible and reliable technique for high throughput measurement of metabolic activities in cancer cells.
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Novel applications of modification of thiol enzymes and redox-regulated proteins using S-methyl methanethiosulfonate (MMTS)
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01.11.2019 |
Makarov V.
Tikhomirova N.
Savvateeva L.
Petushkova A.
Serebryakova M.
Baksheeva V.
Gorokhovets N.
Zernii E.
Zamyatnin A.
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Biochimica et Biophysica Acta - Proteins and Proteomics |
10.1016/j.bbapap.2019.07.012 |
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© 2019 Elsevier B.V. S-Methyl methanethiosulfonate (MMTS) is used in experimental biochemistry for alkylating thiol groups of protein cysteines. Its applications include mainly trapping of natural thiol-disulfide states of redox-sensitive proteins and proteins which have undergone S-nitrosylation. The reagent can also be employed as an inhibitor of enzymatic activity, since nucleophilic cysteine thiolates are commonly present at active sites of various enzymes. The advantage of using MMTS for this purpose is the reversibility of the formation of methylthio mixed disulfides, compared to irreversible alkylation using conventional agents. Additional benefits include good accessibility of MMTS to buried protein cysteines due to its small size and the simplicity of the protection and deprotection procedures. In this study we report examples of MMTS application in experiments involving oxidoreductase (glyceraldehyde-3-phosphate dehydrogenase, GAPDH), redox-regulated protein (recoverin) and cysteine protease (triticain-α). We demonstrate that on the one hand MMTS can modify functional cysteines in the thiol enzyme GAPDH, thereby preventing thiol oxidation and reversibly inhibiting the enzyme, while on the other hand it can protect the redox-sensitive thiol group of recoverin from oxidation and such modification produces no impact on the activity of the protein. Furthermore, using the example of the papain-like enzyme triticain-α, we report a novel application of MMTS as a protector of the primary structure of active cysteine protease during long-term purification and refolding procedures. Based on the data, we propose new lines of MMTS employment in research, pharmaceuticals and biotechnology for reversible switching off of undesirable activity and antioxidant protection of proteins with functional thiol groups.
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Lost or Forgotten: The nuclear cathepsin protein isoforms in cancer
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10.10.2019 |
Soond S.
Kozhevnikova M.
Frolova A.
Savvateeva L.
Plotnikov E.
Townsend P.
Han Y.
Zamyatnin A.
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Cancer Letters |
10.1016/j.canlet.2019.07.020 |
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Ссылка
© 2019 Elsevier B.V. While research into the role of cathepsins has been progressing at an exponential pace over the years, research into their respective isoform proteins has been less frenetic. In view of the functional and biological potential of such protein isoforms in model systems for cancer during their initial discovery, much later they have offered a new direction in the field of cathepsin basic and applied research. Consequently, the analysis of such isoforms has laid strong foundations in revealing other important regulatory aspects of the cathepsin proteins in general. In this review article, we address these key aspects of cathepsin isoform proteins, with particular emphasis on how they have shaped what is now known in the context of nuclear cathepsin localization and what potential these hold as nuclear-based therapeutic targets in cancer.
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Indispensable role of proteases in plant innate immunity
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23.02.2018 |
Balakireva A.
Zamyatnin A.
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International Journal of Molecular Sciences |
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10 |
Ссылка
© 2018 by the authors. Licensee MDPI, Basel, Switzerland. Plant defense is achieved mainly through the induction of microbe-associated molecular patterns (MAMP)-triggered immunity (MTI), effector-triggered immunity (ETI), systemic acquired resistance (SAR), induced systemic resistance (ISR), and RNA silencing. Plant immunity is a highly complex phenomenon with its own unique features that have emerged as a result of the arms race between plants and pathogens. However, the regulation of these processes is the same for all living organisms, including plants, and is controlled by proteases. Different families of plant proteases are involved in every type of immunity: some of the proteases that are covered in this review participate in MTI, affecting stomatal closure and callose deposition. A large number of proteases act in the apoplast, contributing to ETI by managing extracellular defense. A vast majority of the endogenous proteases discussed in this review are associated with the programmed cell death (PCD) of the infected cells and exhibit caspase-like activities. The synthesis of signal molecules, such as salicylic acid, jasmonic acid, and ethylene, and their signaling pathways, are regulated by endogenous proteases that affect the induction of pathogenesis-related genes and SAR or ISR establishment. A number of proteases are associated with herbivore defense. In this review, we summarize the data concerning identified plant endogenous proteases, their effect on plant-pathogen interactions, their subcellular localization, and their functional properties, if available, and we attribute a role in the different types and stages of innate immunity for each of the proteases covered.
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Indispensable Role of Proteases in Plant Innate Immunity
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Замятнин Андрей Александрович
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International Journal of Molecular Sciences |
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Plant defense is achieved mainly through the induction of microbe-associated molecular patterns (MAMP)-triggered immunity (MTI), effector-triggered immunity (ETI), systemic acquired resistance (SAR), induced systemic resistance (ISR), and RNA silencing. Plant immunity is a highly complex phenomenon with its own unique features that have emerged as a result of the arms race between plants and pathogens. However, the regulation of these processes is the same for all living organisms, including plants, and is controlled by proteases. Different families of plant proteases are involved in every type of immunity: some of the proteases that are covered in this review participate in MTI, affecting stomatal closure and callose deposition. A large number of proteases act in the apoplast, contributing to ETI by managing extracellular defense. A vast majority of the endogenous proteases discussed in this review are associated with the programmed cell death (PCD) of the infected cells and exhibit caspase-like activities. The synthesis of signal molecules, such as salicylic acid, jasmonic acid, and ethylene, and their signaling pathways, are regulated by endogenous proteases that affect the induction of pathogenesis-related genes and SAR or ISR establishment. A number of proteases are associated with herbivore defense. In this review, we summarize the data concerning identified plant endogenous proteases, their effect on plant-pathogen interactions, their subcellular localization, and their functional properties, if available, and we attribute a role in the different types and stages of innate immunity for each of the proteases covered. View Full-Text
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Indispensable Role of Proteases in Plant Innate Immunity
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Замятнин Андрей Александрович (директор)
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International Journal of Molecular Sciences |
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Plant defense is achieved mainly through the induction of microbe-associated molecular patterns (MAMP)-triggered immunity (MTI), effector-triggered immunity (ETI), systemic acquired resistance (SAR), induced systemic resistance (ISR), and RNA silencing. Plant immunity is a highly complex phenomenon with its own unique features that have emerged as a result of the arms race between plants and pathogens. However, the regulation of these processes is the same for all living organisms, including plants, and is controlled by proteases. Different families of plant proteases are involved in every type of immunity: some of the proteases that are covered in this review participate in MTI, affecting stomatal closure and callose deposition. A large number of proteases act in the apoplast, contributing to ETI by managing extracellular defense. A vast majority of the endogenous proteases discussed in this review are associated with the programmed cell death (PCD) of the infected cells and exhibit caspase-like activities. The synthesis of signal molecules, such as salicylic acid, jasmonic acid, and ethylene, and their signaling pathways, are regulated by endogenous proteases that affect the induction of pathogenesis-related genes and SAR or ISR establishment. A number of proteases are associated with herbivore defense. In this review, we summarize the data concerning identified plant endogenous proteases, their effect on plant-pathogen interactions, their subcellular localization, and their functional properties, if available, and we attribute a role in the different types and stages of innate immunity for each of the proteases covered. View Full-Text
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