Your search keyword '"single-cell resolution"' showing total 6 results

1. N6-methyladenosine (m

Author

Kang-Xuan, Jin, Rujuan, Zuo, Konstantinos, Anastassiadis, Arne, Klungland, Carsten, Marr, and Adam, Filipczyk

Subjects

Adenosine, MAP Kinase Signaling System, Cell Biology, m6A, Biological Sciences, pluripotency, Cell Line, Mice, single-cell resolution, Animals, formative stem cells, signaling, Embryonic Stem Cells, Germ Layers

Abstract

Significance Dynamic deposition of the N6-methyladenosine (m6A) modification on messenger RNA (mRNA) regulates pluripotency in embryonic stem cells. Reports show that depletion of m6A abundances increases the mRNA stability of pluripotency and lineage transcription factors (TFs) alike. If the mRNAs of these two TF groups become stabilized, it remains unclear how the pluripotency or lineage commitment decision is implemented. Quantification of pluripotency TFs live at single-cell resolution over generations shows long-term preservation of both pluripotency and priming. m6A depletion activates key signaling pathways involved in pluripotency versus commitment decisions. This occurs independently of m6A control over TF mRNA transcript stability. m6A deposition regulates TF protein expression levels by activating pErk and pAkt signaling to enact cell-fate determination in pluripotent stem cells., N6-methyladenosine (m6A) deposition on messenger RNA (mRNA) controls embryonic stem cell (ESC) fate by regulating the mRNA stabilities of pluripotency and lineage transcription factors (TFs) [P. J. Batista et al., Cell Stem Cell 15, 707–719 (2014); Y. Wang et al., Nat. Cell Biol. 16, 191–198 (2014); and S. Geula et al., Science 347, 1002–1006 (2015)]. If the mRNAs of these two TF groups become stabilized, it remains unclear how the pluripotency or lineage commitment decision is implemented. We performed noninvasive quantification of Nanog and Oct4 TF protein levels in reporter ESCs to define cell-state dynamics at single-cell resolution. Long-term single-cell tracking shows that immediate m6A depletion by Mettl3 knock-down in serum/leukemia inhibitory factor supports both pluripotency maintenance and its departure. This is mediated by differential and opposing signaling pathways. Increased FGF5 mRNA stability activates pErk, leading to Nanog down-regulation. FGF5-mediated coactivation of pAkt reenforces Nanog expression. In formative stem cells poised toward differentiation, m6A depletion activates both pErk and pAkt, increasing the propensity for mesendodermal lineage induction. Stable m6A depletion by Mettl3 knock-out also promotes pErk activation. Higher pErk counteracts the pluripotency exit delay exhibited by stably m6A-depleted cells upon differentiation. At single-cell resolution, we illustrate that decreasing m6A abundances activates pErk and pAkt-signaling, regulating pluripotency departure.

Published

2021

2. Combined whole-organ imaging at single-cell resolution and immunohistochemical analysis of prostate cancer and its liver and brain metastases

Author

Grinu Mathew, Lloyd C. Trotman, Kaitlin Watrud, Tse-Luen Wee, Anastasiia Bludova, Matthew F. Lee, John E. Wilkinson, Pavel Osten, Julian Taranda, Sintia Escobar Avelar, Corey Elowsky, Nour El-Amine, and Dawid G. Nowak

Subjects

Male, Entire prostate, Focus (geometry), QH301-705.5, Cell, serial two-photon tomography, General Biochemistry, Genetics and Molecular Biology, Metastasis, whole-organ imaging, Mice, Prostate cancer, Metastatic cell, single-cell resolution, medicine, Animals, Biology (General), Neoplasm Metastasis, early metastasis, Brain Neoplasms, business.industry, Prostate, Brain, Prostatic Neoplasms, Cancer, prostate cancer, medicine.disease, Immunohistochemistry, Mice, Inbred C57BL, Disease Models, Animal, medicine.anatomical_structure, Liver, Cancer research, Single-Cell Analysis, business, Tomography, Emission-Computed

Abstract

Summary: Early steps of cancer initiation and metastasis, while critical for understanding disease mechanisms, are difficult to visualize and study. Here, we describe an approach to study the processes of initiation, progression, and metastasis of prostate cancer (PC) in a genetically engineered RapidCaP mouse model, which combines whole-organ imaging by serial two-photon tomography (STPT) and post hoc thick-section immunofluorescent (IF) analysis. STPT enables the detection of single tumor-initiating cells within the entire prostate, and consequent IF analysis reveals a transition from normal to transformed epithelial tissue and cell escape from the tumor focus. STPT imaging of the liver and brain reveal the distribution of multiple metastatic foci in the liver and an early-stage metastatic cell invasion in the brain. This imaging and data analysis pipeline can be readily applied to other mouse models of cancer, offering a highly versatile whole-organ platform to study in situ mechanisms of cancer initiation and progression.

Published

2021

3. Spatiotemporal mapping of RNA editing in the developing mouse brain using in situ sequencing reveals regional and cell-type-specific regulation

Author

Jens Hjerling-Leffler, Chenglin Wu, Mats Nilsson, Mikaela Behm, Elin Lundin, Albin Widmark, Chammiran Daniel, and Marie Öhman

Subjects

In situ, RNA editing, Adenosine, Physiology, Cell, Cell type specific, Spatially resolved transcriptomics, Single-cell resolution, Plant Science, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, Mice, Spatio-Temporal Analysis, Structural Biology, medicine, Animals, lcsh:QH301-705.5, Ecology, Evolution, Behavior and Systematics, Cell specific, chemistry.chemical_classification, Sequence Analysis, RNA, Methodology Article, Brain, RNA, Cell Biology, Brain development, Inosine, medicine.anatomical_structure, Enzyme, lcsh:Biology (General), chemistry, ADAR, General Agricultural and Biological Sciences, Developmental Biology, Biotechnology

Abstract

Background Adenosine-to-inosine (A-to-I) RNA editing is a process that contributes to the diversification of proteins that has been shown to be essential for neurotransmission and other neuronal functions. However, the spatiotemporal and diversification properties of RNA editing in the brain are largely unknown. Here, we applied in situ sequencing to distinguish between edited and unedited transcripts in distinct regions of the mouse brain at four developmental stages, and investigate the diversity of the RNA landscape. Results We analyzed RNA editing at codon-altering sites using in situ sequencing at single-cell resolution, in combination with the detection of individual ADAR enzymes and specific cell type marker transcripts. This approach revealed cell-type-specific regulation of RNA editing of a set of transcripts, and developmental and regional variation in editing levels for many of the targeted sites. We found increasing editing diversity throughout development, which arises through regional- and cell type-specific regulation of ADAR enzymes and target transcripts. Conclusions Our single-cell in situ sequencing method has proved useful to study the complex landscape of RNA editing and our results indicate that this complexity arises due to distinct mechanisms of regulating individual RNA editing sites, acting both regionally and in specific cell types.

Published

2020

4. High-throughput Measurement of Dictyostelium discoideum Macropinocytosis by Flow Cytometry

Author

Thomas, Williams and Robert R, Kay

Subjects

macropinocytosis, flow cytometry, single-cell resolution, Issue 139, Animals, Pinocytosis, endocytosis, Dictyostelium, Dictyostelium discoideum, Biology, fluid uptake, high-throughput

Abstract

Large-scale non-specific fluid uptake by macropinocytosis is important for the proliferation of certain cancer cells, antigen sampling, host cell invasion and the spread of neurodegenerative diseases. The commonly used laboratory strains of the amoeba Dictyostelium discoideum have extremely high fluid uptake rates when grown in nutrient medium, over 90% of which is due to macropinocytosis. In addition, many of the known core components of mammalian macropinocytosis are also present, making it an excellent model system for studying macropinocytosis. Here, the standard technique to measure internalized fluid using fluorescent dextran as a label is adapted to a 96-well plate format, with the samples analyzed by flow cytometry using a high-throughput sampling (HTS) attachment. Cells are fed non-quenchable fluorescent dextran for a pre-determined length of time, washed by immersion in ice-cold buffer and detached using 5 mM sodium azide, which also stops exocytosis. Cells in each well are then analyzed by flow cytometry. The method can also be adapted to measure membrane uptake and phagocytosis of fluorescent beads or bacteria. This method was designed to allow measurement of fluid uptake by Dictyostelium in a high-throughput, labor and resource efficient manner. It allows simultaneous comparison of multiple strains (e.g. knockout mutants of a gene) and conditions (e.g. cells in different media or treated with different concentrations of inhibitor) in parallel and simplifies time-courses.

Published

2018

5. Chemical probes for visualizing intact animal and human brain tissue

Author

Steve M. Gentleman, Wutian Wu, Wai-Lung Ng, Hei Ming Lai, and Parkinson's UK

Subjects

0301 basic medicine, IN-VIVO DETECTION, CYANINE DYES, Biochemistry & Molecular Biology, tissue clearing, Optical sectioning, ALPHA-SYNUCLEIN, Clinical Biochemistry, Nanotechnology, Biology, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, fluorescent probes, Drug Discovery, small-molecule probes, medicine, human neuroscience, Animals, Humans, Molecular Biology, A-BETA, Pharmacology, BETA-AMYLOID PLAQUES, Tissue clearing, Science & Technology, CONGO RED, 3D histology, Brain, Human brain, MOLECULE RNA DETECTION, Structure and function, Molecular Imaging, ALZHEIMERS-DISEASE, Fluorescent labelling, 030104 developmental biology, medicine.anatomical_structure, mammalian brain tissues, Molecular Probes, Molecular Medicine, brain mapping, SINGLE-CELL RESOLUTION, Life Sciences & Biomedicine, 030217 neurology & neurosurgery, Chemical labeling, Biomedical engineering, Clearance, WHOLE-BODY

Abstract

Newly developed tissue clearing techniques can be used to render intact tissues transparent. When combined with fluorescent labeling technologies and optical sectioning microscopy, this allows visualization of fine structure in three dimensions. Gene-transfection techniques have proved very useful in visualizing cellular structures in animal models, but they are not applicable to human brain tissue. Here, we discuss the characteristics of an ideal chemical fluorescent probe for use in brain and other cleared tissues, and offer a comprehensive overview of currently available chemical probes. We describe their working principles and compare their performance with the goal of simplifying probe selection for neuropathologists and stimulating probe development by chemists. We propose several approaches for the development of innovative chemical labeling methods which, when combined with tissue clearing, have the potential to revolutionize how we study the structure and function of the human brain.

Published

2017

6. Antigen retrieval and clearing for whole-organ immunofluorescence by FLASH

Author

Antonio Tedeschi, Laura Blackie, Alessandro Ciccarelli, Axel Behrens, May Zaw Thin, Jorge Almagro, Hendrik A. Messal, Jacco van Rheenen, Irene Miguel-Aliaga, Kurt I. Anderson, and Commission of the European Communities

Subjects

Male, Fluorescence-lifetime imaging microscopy, Fluorescent Antibody Technique, MOUSE, Kidney, Epitope, law.invention, Epitopes, Mice, chemistry.chemical_compound, Immunolabeling, 0302 clinical medicine, law, BRAIN, Lung, 11 Medical and Health Sciences, 0303 health sciences, Microscopy, Confocal, medicine.diagnostic_test, Stomach, Lacrimal Apparatus, MICROSCOPY, EXPANSION, Protein subcellular localization prediction, Cell biology, Organoids, Liver, Antigen retrieval, Drosophila, Female, SINGLE-CELL RESOLUTION, 03 Chemical Sciences, Life Sciences & Biomedicine, Biochemistry & Molecular Biology, DEEP, Bioinformatics, Biology, Immunofluorescence, Biochemical Research Methods, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Imaging, Three-Dimensional, Confocal microscopy, medicine, Animals, Humans, CANCER METASTASIS, Antigens, Mammary Glands, Human, Pancreas, 030304 developmental biology, Science & Technology, 06 Biological Sciences, chemistry, TISSUE, Light sheet fluorescence microscopy, 030217 neurology & neurosurgery

Abstract

Advances in light-sheet and confocal microscopy now allow imaging of cleared large biological tissue samples and enable the 3D appreciation of cell and protein localization in their native organ environment. However, the sample preparations for such imaging are often onerous, and their capability for antigen detection is limited. Here, we describe FLASH (fast light-microscopic analysis of antibody-stained whole organs), a simple, rapid, fully customizable technique for molecular phenotyping of intact tissue volumes. FLASH utilizes non-degradative epitope recovery and membrane solubilization to enable the detection of a multitude of membranous, cytoplasmic and nuclear antigens in whole mouse organs and embryos, human biopsies, organoids and Drosophila. Retrieval and immunolabeling of epithelial markers, an obstacle for previous clearing techniques, can be achieved with FLASH. Upon volumetric imaging, FLASH-processed samples preserve their architecture and integrity and can be paraffin-embedded for subsequent histopathological analysis. The technique can be performed by scientists trained in light microscopy and yields results in