HLA DQ protein changes the cell surface distribution pattern of HLA proteins as monitored by Förster resonance energy transfer and high-resolution electron microscopy.

Peptide presentation by MHC class I and MHC class II molecules plays important roles in the regulation of the immune response. One factor in these displays is the density of antigen, which must exceed a critical threshold for the effective activation of T cells. Nonrandom distribution of MHC class I and class II has already been detected at the nanometer level and at higher hierarchical levels. It is not clear how the absence and reappearance of some protein molecules can influence the nonrandom distribution. Therefore, we performed experiments on HLA II-deficient bare lymphocyte syndrome (BLS1) cells: we created a stable transfected cell line, tDQ6-BLS-1, and were able to detect the effect of the appearance of HLA-DQ6 molecules on the homo and heteroassociation of different cell surface molecules by comparing Förster resonance energy transfer (FRET) efficiency on transfected cells to that on nontransfected BLS-1 and JY human B-cell lines. Our FRET results show a decrease in homoassociation FRET between HLA I chains in HLA-DQ6-transfected tDQ6-BLS-1 cells compared with the parent BLS-1 cell line and an increase in heteroassociation FRET between HLA I and HLA II (compared with JY cells), suggesting a similar pattern of antigen presentation by the HLA-DQ6 allele. Transmission electron microscopy (TEM) revealed that both HLA class I and class II molecules formed clusters at higher hierarchical levels on the tDQ6-BLS-1 cells, and the de novo synthesized HLA DQ molecules did not intersperse with HLA class I islands. These observations could be important in understanding the fine tuning of the immune response.

Opposing Effects of Chelidonine on Tyrosine and Serine Phosphorylation of STAT3 in Human Uveal Melanoma Cells.

STAT3 is a transcription factor that regulates various cellular processes with oncogenic potential, thereby promoting tumorigenesis when activated uncontrolled. STAT3 activation is mediated by its tyrosine phosphorylation, triggering dimerization and nuclear translocation. STAT3 also contains a serine phosphorylation site, with a postulated regulatory role in STAT3 activation and G2/M transition. Interleukin-6, a major activator of STAT3, is present in elevated concentrations in uveal melanomas, suggesting contribution of dysregulated STAT3 activation to their pathogenesis. Here, we studied the impact of chelidonine on STAT3 signaling in human uveal melanoma cells. Chelidonine, an alkaloid isolated from Chelidonium majus, disrupts microtubules, causes mitotic arrest and provokes cell death in numerous tumor cells. According to our flow cytometry and confocal microscopy data, chelidonine abrogated IL-6-induced activation and nuclear translocation, but amplified constitutive serine phosphorylation of STAT3. Both effects were restricted to a fraction of cells only, in an all-or-none fashion. A partial overlap could be observed between the affected subpopulations; however, no direct connection could be proven. This study is the first proof on a cell-by-cell basis for the opposing effects of a microtubule-targeting agent on the two types of STAT3 phosphorylation.

Minimum degree of overlap between IL-9R and IL-2R on human T lymphoma cells: A quantitative CLSM and FRET analysis.

The heterodimeric receptor complex of IL-9 consists of the cytokine-specific α-subunit and the common γc -chain shared with other cytokines, including IL-2, a central regulator of T cell function. We have shown previously the bipartite spatial relationship of IL-9 and IL-2 receptors at the surface of human T lymphoma cells: in addition to common clusters, expression of the two receptor kinds could also be observed in segregated membrane areas. Here we analyzed further the mutual cell surface organization of IL-9 and IL-2 receptors. Complementing Pearson correlation data with co-occurrence analysis of confocal microscopic images revealed that a minimum degree of IL-9R/IL-2R co-localization exists at the cell surface regardless of the overall spatial correlation of the two receptor kinds. Moreover, our FRET experiments demonstrated molecular scale assemblies of the elements of the IL-9/IL-2R system. Binding of IL-9 altered the structure and/or composition of these clusters. It is hypothesized, that by sequestering receptor subunits in common membrane areas, the overlapping domains of IL-9R and IL-2R provide a platform enabling both the formation of the appropriate receptor complex as well as subunit sharing between related cytokines. © 2018 International Society for Advancement of Cytometry.

Distinct spatial relationship of the interleukin-9 receptor with interleukin-2 receptor and major histocompatibility complex glycoproteins in human T lymphoma cells.

The interleukin-9 receptor (IL-9R) consists of an α subunit and a γ(c) chain that are shared with other cytokine receptors, including interleukin-2 receptor (IL-2R), an important regulator of T cells. We previously showed that IL-2R is expressed in common clusters with major histocompatibility complex (MHC) glycoproteins in lipid rafts of human T lymphoma cells, which raised the question about what the relationship between clusters of IL-2R/MHC and IL-9R is. Confocal microscopy colocalization and fluorescence resonance energy transfer experiments capable of detecting membrane protein organization at different size scales revealed nonrandom association of IL-9R with IL-2R/MHC clusters at the surface of human T lymphoma cells. Accommodation of IL-9Rα in membrane areas segregated from the IL-2R/MHC domains was also detected. The bipartite nature of IL-9R distribution was mirrored by signal transducer and activator of transcription (STAT) activation results. Our data indicate that co-compartmentalization with MHC glycoproteins is a general property of γ(c) receptors. Distribution of receptor chains between different membrane domains may regulate their function.

Novel Transmission Electron Microscopic Method to Quantify Protein Clustering on the Cell Surface.

The cell surface distribution patterns (clustering) of membrane proteins have been widely investigated in cell biology. Here we describe a novel transmission electron microscopic (TEM) protocol designed to improve the quality of information obtained about the protein distribution patterns detected. This novel method makes it possible to study the clustering of all transmembrane proteins on one half of the cytoplasmic membrane of a whole cell. To achieve better imaging, we combine various methods, including critical-point drying, fixation of gold beads with a carbon layer, and a newly developed chemical thinning method. In addition, in our image-processing algorithm, we implemented pair correlation and pair cross-correlation functions, providing more details and better quantitative accuracy in characterizing the size and numbers of possible protein clusters. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Sample preparation and transmission electron micrography Alternate Protocol: Direct cell labeling for transmission electron micrography Basic Protocol 2: Analysis of TEM images to detect immunogold-labeled proteins.

Strength in numbers: effects of acceptor abundance on FRET efficiency.

Fluorescence resonance energy transfer (FRET) is a strongly distance-dependent process between a donor and an acceptor molecule, which can be used for sensitive distance measurements and characterization of molecular interactions at the nanometer level. The original mathematical description of this process, however, is only valid for the interaction of one donor with one acceptor. This criterion is not always met, especially in biological systems, where multiple structures can interact simultaneously, often making distance estimations based on transfer efficiency values error-prone. Herein we investigate how the interaction of multiple acceptors and donors influences the transfer efficiency value in an intramolecular cellular FRET system by manipulating the fluorophore/protein ratio of the fluorophore-conjugated antibodies. We show that the labeling ratio of the acceptor has the largest influence on measured transfer efficiency and decreasing or increasing the acceptor labeling ratio can be utilized to manipulate the FRET response of the acceptor-donor pair and therefore is a tool for optimizing sensitivity of FRET measurements.

The present and the future of medical simulation education in Hungary / Az egészségügyi szimulációs oktatás jelene és jövoje Magyarországon

Simulation-based medical education aims to model clinical situations and tasks using simulators, computers or even human beings. By using this system, the students are able to learn and master technical, also non-technical skills in lifelike situations. This publication contains a historical review of simulation-based education system, and its actualities in Hungary. Simulation has an unquestionable role in medical education. It is beneficial for the students, for the teachers, and for the teaching hospitals as well, since it saves clinical equipment and reduces the human burden. Its main purpose is to establish connection between theoretical and practical competencies, preparing the students for real medical challenges. Simulation has been a known teaching method for centuries, but only the 21st century brought real breakthrough due to the sudden development of technology. As a result of the recent years' innovative development and accepted innovative solutions, the modeling of complex medical procedures turned into more realistic. In Hungary, 3D-printed tools, virtual reality and augmented reality approaches are already adopted for education purposes. The national simulation network contains 3 universities and 16 hospitals. The initial developments are shown to be successful, as simulation-based training is progressively involved in undergraduate and post-graduate education, and the overall feedback is positive from the involved students. The evolvement of comprehensive national methodology for education has started also, by publishing reference books. This review is about the state of the national simulation education and offers development possibilities. Orv Hetil. 2020; 161(26): 1078-1087.

Non-random distribution of interleukin receptors on the cell surface.

Spatial organization of cell surface proteins plays a key role in the process of transmembrane signalling. Receptor clustering and changes in their cell surface distribution are often determining factors in the final outcome of ligand-receptor interactions. There are several techniques for assessing the distribution of protein molecules. Fluorescence resonance energy transfer (FRET) is an excellent tool for determining distance relationships of cell surface molecules. However, it does not provide information on the distribution of molecular clusters. Different kinds of microscopies fill this gap. The evaluation of the images provided by the listed techniques is often questionable. Herein we show the applicability of Ripley's K(t) function as a tool for analyzing the cell surface receptor patterns (Y. Nakamura, et al., Nature 1994, 369, 330-333). We have implemented an effective image processing algorithm for fast localization of gold labels on biological samples. We investigated spatial organization of Interleukin-2R alpha and -15R alpha (IL-2R alpha and IL-15R alpha) on a human CD4+leukaemia T-cell line, Kit225 FT7.10 by using transmission electron microscopy (TEM). TEM analysis showed co-clustering of the two types of alpha-chains even on the few-hundred-nanometer scale. The analysis of our data may contribute to our understanding the action of the IL-2/IL-15 receptor system in T-cell function.

DNA flow cytometry of human spermatozoa: consistent stoichiometric staining of sperm DNA using a novel decondensation protocol.

Rapid flow cytometric measurement of the frequency of aneuploid human sperms is in increasing demand but development of an exploitable method is hindered by difficulties of stoichiometric staining of sperm DNA. An aggressive decondensation protocol is needed after which cell integrity still remains intact. We used flow cytometry to examine the effect of lithium diiodosalicylate (LIS, chaotropic agent) on fluorescence intensity of propidium iodide-treated human spermatozoa from 10 normozoospermic men. When flow cytometric identification of diploid spermatozoa was achieved, validation was performed after sorting by three-color FISH. In contrast with the extremely variable histograms of nondecondensed sperms, consistent identification of haploid and diploid spermatozoa was possible if samples were decondensed with LIS prior to flow cytometry. A 76-fold enrichment of diploid sperms was observed in the sorted fractions by FISH. A significant correlation was found between the proportion of sorted cells and of diploid sperms by FISH. Application of LIS during the preparation of sperm for flow cytometry appears to ensure the stoichiometric staining of sperm DNA, making quantification of aneuploid sperm percentage possible. To our knowledge this is the first report in terms of separating spermatozoa with confirmedly abnormal chromosomal content. High correlation between the proportion of cells identified as having double DNA content by flow cytometry and diploid sperm by FISH allows rapid calculation of diploidy rate.

Steady-state fluorescence quenching applications for studying protein structure and dynamics.

Fluorescence quenching methods are useful to obtain information about the conformational and/or dynamic changes of proteins in complex macromolecular systems. In this review steady-state methods are described and the data interpretation is thoroughly discussed. As a special case of fluorescence quenching mechanism, fluorescence resonance energy transfer (FRET) phenomenon is also presented. Application of a FRET based method to characterize the temperature dependence of the flexibility of protein matrix is clearly demonstrated.

Does mosaicism of the plasma membrane at molecular and higher hierarchical levels in human lymphocytes carry information on the immediate history of cells?

A theoretical analysis of experimental data is presented in this mini-review on non-random homo- and hetero-associations of cell surface receptors, which can be recruited in the plasma membrane or at the surface of the rough endoplasmic reticulum during the protein synthesis. In the latter case, the likely genetic origin of these supramolecular formations is analyzed, contrasting this concept to the mobility of the cell surface proteins. A model is offered which, on the one hand, allows the mobility in a restricted way even among microdomain-confined receptor proteins through 'swapping partners'. On the other hand, the lack of mixing molecular components of protein clusters will be analyzed, when homo-and hetero-associations are studied through cell fusion experiments. The most frequently studied cell surface patterns have included lipid raft organized HLA class I and II, ICAM-1, tetraspan molecules, IL2 and IL15 and other receptors, as well. On the contrary coated pit-associated transferrin receptors would not mix with the above lipid raft associated receptor patterns, although transferrin receptor would readily oligomerize into homo-associates. The functional consequences of these superstructures are also analyzed. On the 30th anniversary of the Singer-Nicolson fluid mosaic membrane model one has to pay tribute to the authors, because of their deep insight emphasizing also the mosaicism of the membranes in general and that of the plasma membrane, in particular.

Signal transduction in T lymphocytes and aging.

Subclasses of cells in different compartments of the immune system possesses all those attributes, that make them suitable though somewhat limited models for the investigation of cellular processes during aging. Blood samples provide relative easily high amount of cells belonging to the same subclass, all of them having complex cascade processes in their signal transduction mechanisms, therefore being excellent targets for such investigations. One such subclass comprises peripheral blood lymphocytes. The signal-transduction cascade across the plasma membrane of lymphocytes displays many of the general features enabling us to draw conclusions for other cellular signaling problems that may arise during aging in other cell types not directly related to the immune system. The advantage of this approach lies in the fact that sometimes it is extremely difficult to study signal transduction processes in certain cell types under physiological conditions. The simultaneous occurrence of physical, chemical and molecular biological regulation of the immune processes at cellular and network levels make them very good examples for focusing our interest also on similar processes in other systems and cells. The fast developing new measuring techniques and the rapidly accumulating experimental data make it relatively easy to provide interesting new aspects, and ideas in this field. Finally, the immune system itself has its great importance and after all, it has an obvious declination with aging, the immune-senescence.

Applications of fluorescence resonance energy transfer for mapping biological membranes.

The interaction of the cell surface proteins plays a key role in the process of transmembrane signaling. Receptor clustering and changes in their conformation are often essential factors in the final outcome of ligand receptor interactions. Fluorescence resonance energy transfer (FRET) is an excellent tool for determining distance relationships and supramolecular organization of cell surface molecules. This paper reviews the theoretical background of fluorescence resonance energy transfer, its flow cytometric and microscopic applications (including the intensity based and photobleaching versions), and provides a critical evaluation of the methods as well. In order to illustrate the applicability of the method, we summarize a few biological results: clustering of lectin receptors, cell surface distribution of hematopoietic cluster of differentiation (CD) molecules, and that of the receptor tyrosine kinases, conformational changes of Major Histocompatibility Complex (MHC) I molecules upon membrane potential change and ligand binding.

Computer program for determining fluorescence resonance energy transfer efficiency from flow cytometric data on a cell-by-cell basis.

The determination of fluorescence resonance energy transfer (FRET) with flow cytometry (FCET) is one of the most efficient tools to study the proximity relationships of cell membrane components in cell populations on a cell-by-cell basis. Because of the high amount of data and the relatively tedious calculations, this procedure should be assisted by powerful data processing software. The currently available programs are not able to fulfill this requirement. We developed a Windows-based program to calculate fluorescence resonance energy transfer efficiency values from list mode flow cytometry standard (FCS) files. This program displays the measured data in standard plots by generating one- and two-parameter histograms on linear or logarithmic scales. A graphical gating tool allows the user to select the desired cell population according to any combination of the parameter values. The program performs several statistical calculations, including mean, S.D., percent of the gated data. We have implemented two types of data sheet for FRET calculations to aid and guide the user during the analysis: one with population-mean-based autofluorescence correction and the other with spectrum-based cell-by-cell autofluorescence correction. In this paper, we describe the gating algorithms, the file opening procedure and the rules of gating. The structure of the program and a short description of the graphical user-interface (GUI) are also presented in this article.

Principles of resonance energy transfer.

This unit describes the basic principles of the fluorescence resonance energy (FRET) process. In addition, it characterizes available parameters and instruments for FRET measurements, discusses limitations, and shows a few examples of the application of FRET.

Measuring FRET in flow cytometry and microscopy.

This unit presents protocols describing the measurement of protein associations using FRET as determined by flow and image cytometry. The proteins under investigation can be labeled by fluorescent antibodies or fluorescent protein (FP) variants. The flow cytometry protocols determine FRET based on the measurement of donor quenching, which provides a FRET value on a population basis, or based on the measurement of fluorescence intensities in the donor, FRET, and acceptor channels, which provides cell-by-cell FRET values. An extension of this protocol is based on cell-by-cell correction for autofluorescence and requires the measurement of four fluorescence intensities. The algorithm described can be applied in image cytometric FRET as well. The image protocol determines FRET resolved by donor photobleaching. The authors provide extensive discussion of pitfalls, limitations, and interpretation.

Nanoparticle energy transfer on the cell surface.

Membrane topology of receptors plays an important role in shaping transmembrane signalling of cells. Among the methods used for characterizing receptor clusters, fluorescence resonance energy transfer between a donor and acceptor fluorophore plays a unique role based on its capability of detecting molecular level (2-10 nm) proximities of receptors in physiological conditions. Recent development of biotechnology has made possible the usage of colloidal gold particles in a large size range for specific labelling of cells for the purposes of electron microscopy. However, by combining metal and fluorophore labelling of cells, the versatility of metal-fluorophore interactions opens the way for new applications by detecting the presence of the metal particles by the methods of fluorescence spectroscopy. An outstanding feature of the metal nanoparticle-fluorophore interaction is that the metal particle can enhance spontaneous emission of the fluorophore in a distance-dependent fashion, in an interaction range essentially determined by the size of the nanoparticle. In our work enhanced fluorescence of rhodamine and cyanine dyes was observed in the vicinity of immunogold nanoparticles on the surface of JY cells in a flow cytometer. The dyes and the immunogold were targetted to the cell surface receptors MHCI, MHCII, transferrin receptor and CD45 by monoclonal antibodies. The fluorescence enhancement was sensitive to the wavelength of the exciting light, the size and amount of surface bound gold beads, as well as the fluorophore-nanoparticle distance. The intensity of 90 degrees scattering of the incident light beam was enhanced by the immunogold in a concentration and size-dependent fashion. The 90 degrees light scattering varied with the wavelength of the incident light in a manner characteristic to gold nanoparticles of the applied sizes. A reduction in photobleaching time constant of the cyanine dye was observed in the vicinity of gold particles in a digital imaging microscope. Modulations of 90 degrees light scattering intensity and photobleaching time constant indicate the role of the local field in the fluorescence enhancement. A mathematical simulation based on the electrodynamic theory of fluorescence enhancement showed a consistency between the measured enhancement values, the inter-epitope distances and the quantum yields. The feasibility of realizing proximity sensors operating at distance ranges larger than that of the conventional Forster transfer is demonstrated on the surface of living cells.

Computer program for analyzing donor photobleaching FRET image series.

BACKGROUND: The photobleaching fluorescence resonance energy transfer (pbFRET) technique is a spectroscopic method to measure proximity relations between fluorescently labeled macromolecules using digital imaging microscopy. To calculate the energy transfer values one has to determine the bleaching time constants in pixel-by-pixel fashion from the image series recorded on the donor-only and donor and acceptor double-labeled samples. Because of the large number of pixels and the time-consuming calculations, this procedure should be assisted by powerful image data processing software. There is no commercially available software that is able to fulfill these requirements. METHODS: New evaluation software was developed to analyze pbFRET data for Windows platform in National Instrument LabVIEW 6.1. This development environment contains a mathematical virtual instrument package, in which the Levenberg-Marquardt routine is also included. As a reference experiment, FRET efficiency between the two chains (beta2-microglobulin and heavy chain) of major histocompatibility complex (MHC) class I glycoproteins and FRET between MHC I and MHC II molecules were determined in the plasma membrane of JY, human B lymphoma cells. RESULTS: The bleaching time constants calculated on pixel-by-pixel basis can be displayed as a color-coded map or as a histogram from raw image format. CONCLUSION: In this report we introduce a new version of pbFRET analysis and data processing software that is able to generate a full analysis pattern of donor photobleaching image series under various conditions. .

IL-2 and IL-15 receptor alpha-subunits are coexpressed in a supramolecular receptor cluster in lipid rafts of T cells.

The private alpha-chains of IL-2 and IL-15 receptors (IL-2R and IL-15R) share the signaling beta- and gamma(c)-subunits, resulting in both common and contrasting roles of IL-2 and IL-15 in T cell function. Knowledge of the cytokine-dependent subunit assembly is indispensable for understanding the paradox of distinct signaling capacities. By using fluorescence resonance energy transfer and confocal microscopy, we have shown that IL-2R alpha, IL-15R alpha, IL-2/15R beta and gamma(c)-subunits, as well as MHC class I and II glycoproteins formed supramolecular receptor clusters in lipid rafts of the T lymphoma line Kit 225 FT7.10. Fluorescence crosscorrelation microscopy demonstrated the comobility of IL-15R alpha with IL-2R alpha and MHC class I. A model was generated for subunit switching between IL-2R alpha and IL-15R alpha upon the binding of the appropriate cytokine resulting in the formation of high-affinity heterotrimeric receptors. This model suggests a direct role for the alpha-subunits, to which no definite function has been assigned so far, in tuning cellular responses to IL-2 or IL-15. In addition, both alpha-chains were at least partially homodimerized/oligomerized, which could be the basis of distinct signaling pathways by the two cytokines.