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1. Harmonizing the Generation and Pre-publication Stewardship of FAIR Image Data

Author

Bialy, Nikki, Alber, Frank, Andrews, Brenda, Angelo, Michael, Beliveau, Brian, Bintu, Lacramioara, Boettiger, Alistair, Boehm, Ulrike, Brown, Claire M., Maina, Mahmoud Bukar, Chambers, James J., Cimini, Beth A., Eliceiri, Kevin, Errington, Rachel, Faklaris, Orestis, Gaudreault, Nathalie, Germain, Ronald N., Goscinski, Wojtek, Grunwald, David, Halter, Michael, Hanein, Dorit, Hickey, John W., Lacoste, Judith, Laude, Alex, Lundberg, Emma, Ma, Jian, Malacrida, Leonel, Moore, Josh, Nelson, Glyn, Neumann, Elizabeth Kathleen, Nitschke, Roland, Onami, Shuichi, Pimentel, Jaime A., Plant, Anne L., Radtke, Andrea J., Sabata, Bikash, Schapiro, Denis, Schöneberg, Johannes, Spraggins, Jeffrey M., Sudar, Damir, Vierdag, Wouter-Michiel Adrien Maria, Volkmann, Niels, Wählby, Carolina, Siyuan, Wang, Yaniv, Ziv, and Strambio-De-Castillia, Caterina

Subjects
Quantitative Biology - Other Quantitative Biology
Abstract

Together with the molecular knowledge of genes and proteins, biological images promise to significantly enhance the scientific understanding of complex cellular systems and to advance predictive and personalized therapeutic products for human health. For this potential to be realized, quality-assured image data must be shared among labs at a global scale to be compared, pooled, and reanalyzed, thus unleashing untold potential beyond the original purpose for which the data was generated. There are two broad sets of requirements to enable image data sharing in the life sciences. One set of requirements is articulated in the companion White Paper entitled Enabling Global Image Data Sharing in the Life Sciences, which is published in parallel and addresses the need to build the cyberinfrastructure for sharing the digital array data. In this White Paper, we detail a broad set of requirements, which involves collecting, managing, presenting, and propagating contextual information essential to assess the quality, understand the content, interpret the scientific implications, and reuse image data in the context of the experimental details. We start by providing an overview of the main lessons learned to date through international community activities, which have recently made considerable progress toward generating community standard practices for imaging Quality Control (QC) and metadata. We then provide a clear set of recommendations for amplifying this work. The driving goal is to address remaining challenges and democratize access to everyday practices and tools for a spectrum of biomedical researchers, regardless of their expertise, access to resources, and geographical location., Comment: This manuscript is published with a closely related companion entitled, Enabling Global Image Data Sharing in the Life Sciences, which can be found at the following link, arXiv:2401.13023 [q-bio.OT]

Published
2024

4. In vivo macromolecular crowding is differentially modulated by aquaporin 0 in zebrafish lens: Insights from a nanoenvironment sensor and spectral imaging

Author

Vorontsova, Irene, Vallmitjana, Alexander, Torrado, Belén, Schilling, Thomas F, Hall, James E, Gratton, Enrico, and Malacrida, Leonel

Subjects
Aging, Eye Disease and Disorders of Vision, Underpinning research, 1.1 Normal biological development and functioning, Animals, Aquaporins, Eye Proteins, Lens, Crystalline, Water, Zebrafish
Abstract

Macromolecular crowding is crucial for cellular homeostasis. In vivo studies of macromolecular crowding and water dynamics are needed to understand their roles in cellular physiology and fate determination. Macromolecular crowding in the lens is essential for normal optics, and an understanding of its regulation will help prevent cataract and presbyopia. Here, we combine the use of the nanoenvironmental sensor [6-acetyl-2-dimethylaminonaphthalene (ACDAN)] to visualize lens macromolecular crowding with in vivo studies of aquaporin 0 zebrafish mutants that disrupt its regulation. Spectral phasor analysis of ACDAN fluorescence reveals water dipolar relaxation and demonstrates that mutations in two zebrafish aquaporin 0s, Aqp0a and Aqp0b, alter water state and macromolecular crowding in living lenses. Our results provide in vivo evidence that Aqp0a promotes fluid influx in the deeper lens cortex, whereas Aqp0b facilitates fluid efflux. This evidence reveals previously unidentified spatial regulation of macromolecular crowding and spatially distinct roles for Aqp0 in the lens.

Published
2022

5. Phasor-based hyperspectral snapshot microscopy allows fast imaging of live, three-dimensional tissues for biomedical applications.

Author

Hedde, Per Niklas, Cinco, Rachel, Malacrida, Leonel, Kamaid, Andrés, and Gratton, Enrico

Abstract

Hyperspectral imaging is highly sought after in many fields including mineralogy and geology, environment and agriculture, astronomy and, importantly, biomedical imaging and biological fluorescence. We developed ultrafast phasor-based hyperspectral snapshot microscopy based on sine/cosine interference filters for biomedical imaging not feasible with conventional hyperspectral detection methods. Current approaches rely on slow spatial or spectral scanning limiting their application in living biological tissues, while faster snapshot methods such as image mapping spectrometry and multispectral interferometry are limited in spatial and/or spectral resolution, are computationally demanding, and imaging devices are very expensive to manufacture. Leveraging light sheet microscopy, phasor-based hyperspectral snapshot microscopy improved imaging speed 10-100 fold which, combined with minimal light exposure and high detection efficiency, enabled hyperspectral metabolic imaging of live, three-dimensional mouse tissues not feasible with other methods. As a fit-free method that does not require any a priori information often unavailable in complex and evolving biological systems, the rule of linear combinations of the phasor could spectrally resolve subtle differences between cell types in the developing zebrafish retina and spectrally separate and track multiple organelles in 3D cultured cells over time. The sine/cosine snapshot method is adaptable to any microscope or imaging device thus making hyperspectral imaging and fit-free analysis based on linear combinations broadly available to researchers and the public.

Published
2021

8. LAURDAN since Weber: The Quest for Visualizing Membrane Heterogeneity

Author

Gunther, German, Malacrida, Leonel, Jameson, David M, Gratton, Enrico, and Sánchez, Susana A

Subjects
Bioengineering, Generic health relevance, 2-Naphthylamine, Animals, Cell Membrane, Fluorescent Dyes, HEK293 Cells, Humans, Huntingtin Protein, Hydrogen Peroxide, Laurates, Liposomes, Mice, Microscopy, Fluorescence, NIH 3T3 Cells, Polymorphism, Single Nucleotide, Spectrometry, Fluorescence, Chemical Sciences, General Chemistry
Abstract

Any chemist studying the interaction of molecules with lipid assemblies will eventually be confronted by the topic of membrane bilayer heterogeneity and may ultimately encounter the heterogeneity of natural membranes. In artificial bilayers, heterogeneity is defined by phase segregation that can be in the nano- and micrometer range. In biological bilayers, heterogeneity is considered in the context of small (10-200 nm) sterol and sphingolipid-enriched heterogeneous and highly dynamic domains. Several techniques can be used to assess membrane heterogeneity in living systems. Our approach is to use a fluorescent reporter molecule immersed in the bilayer, which, by changes in its spectroscopic properties, senses physical-chemistry aspects of the membrane. This dye in combination with microscopy and fluctuation techniques can give information about membrane heterogeneity at different temporal and spatial levels: going from average fluidity to number and diffusion coefficient of nanodomains. LAURDAN (6-dodecanoyl-2-(dimethylamino) naphthalene), is a fluorescent probe designed and synthesized in 1979 by Gregorio Weber with the purpose to study the phenomenon of dipolar relaxation. The spectral displacement observed when LAURDAN is either in fluid or gel phase permitted the use of the technique in the field of membrane dynamics. The quantitation of the spectral displacement was first addressed by the generalized polarization (GP) function in the cuvette, a ratio of the difference in intensity at two wavelengths divided by their sum. In 1997, GP measurements were done for the first time in the microscope, adding to the technique the spatial resolution and allowing the visualization of lipid segregation both in liposomes and cells. A new prospective to the membrane heterogeneity was obtained when LAURDAN fluorescent lifetime measurements were done in the microscope. Two channel lifetime imaging provides information on membrane polarity and dipole relaxation (the two parameters responsible for the spectral shift of LAURDAN), and the application of phasor analysis allows pixel by pixel understanding of these two parameters in the membrane. To increase temporal resolution, LAURDAN GP was combined with fluctuation correlation spectroscopy (FCS) and the motility of nanometric highly packed structures in biological membranes was registered. Lately the application of phasor analysis to spectral images from membranes labeled with LAURDAN allows us to study the full spectra pixel by pixel in an image. All these methodologies, using LAURDAN, offer the possibility to address different properties of membranes depending on the question being asked. In this Account, we will focus on the principles, advantages, and limitations of different approaches to orient the reader to select the most appropriate technique for their research.

Published
2021

9. CAPRYDAA, an anthracene dye analog to LAURDAN: a comparative study using cuvette and microscopy

Author

Castro-Castillo, Vicente, Gajardo, Javier, Sandoval-Altamirano, Catalina, Gratton, Enrico, Sanchez, Susana, Malacrida, Leonel, and Gunther, German

Subjects
Generic health relevance, 2-Naphthylamine, Animals, Anthracenes, Cell Membrane, Fluorescent Dyes, Membrane Lipids, Mice, Microscopy, Fluorescence, NIH 3T3 Cells, Spectrometry, Fluorescence, Macromolecular and Materials Chemistry, Biomedical Engineering
Abstract

We synthesized an anthracene derivative with solvatochromic properties to be used as a molecular probe for membrane dynamics and supramolecular organization. A nine carbon atom acyl chain and a dimethylamino substitution were introduced at positions 2 and 6 of the anthracene ring, respectively. This derivative, 2-nonanoyl-6-(dimethylamino)anthracene (termed CAPRYDAA), is a molecular probe designed to mimic the well-known membrane probe LAURDAN's location and response in the lipid membranes. Due to the larger distance between the electron donor and acceptor groups, its absorption and emission bands are red-shifted according to the polarity of the media. The photophysical behavior of CAPRYDAA was measured in homogeneous media, synthetic bilayer and cells, both in a cuvette and in a fluorescence microscope, using one and two-photon excitation. Our results show a comparable physicochemical behavior of CAPRYDAA with LAURDAN, but with the advantage of using visible light (488 nm) as an excitation source. CAPRYDAA was also excitable by two-photon laser sources, making it easy to combine CAPRYDAA with either blue or red emission probes. In GUVs or cells, CAPRYDAA can discriminate the lipid phases and liquid-liquid phase heterogeneity. This new membrane probe shows the bathochromic properties of the PRODAN-based probes designed by Weber, overcoming the need for UV or two-photon excitation and facilitating the studies on the membrane properties using regular confocal microscopes.

Published
2020

11. Determination of the metabolic index using the fluorescence lifetime of free and bound nicotinamide adenine dinucleotide using the phasor approach

Author

Ranjit, Suman, Malacrida, Leonel, Stakic, Milka, and Gratton, Enrico

Subjects
Analytical Chemistry, Medicinal and Biomolecular Chemistry, Chemical Sciences, L-Lactate Dehydrogenase, NAD, Optical Imaging, autofluorescence, FLIM, lifetime, NADH, phasor, TCSPC, Optical Physics, Medical Biotechnology, Optoelectronics & Photonics, Analytical chemistry, Medicinal and biomolecular chemistry
Abstract

The fluorescence lifetime of nicotinamide adenine dinucleotide (NADH) is commonly used in conjunction with the phasor approach as a molecular biomarker to provide information on cellular metabolism of autofluorescence imaging of cells and tissue. However, in the phasor approach, the bound and free lifetime defining the phasor metabolic trajectory is a subject of debate. The fluorescence lifetime of NADH increases when bound to an enzyme, in contrast to the short multiexponential lifetime displayed by NADH in solution. The extent of fluorescence lifetime increase depends on the enzyme to which NADH is bound. With proper preparation of lactate dehydrogenase (LDH) using oxalic acid (OA) as an allosteric factor, bound NADH to LDH has a lifetime of 3.4 ns and is positioned on the universal semicircle of the phasor plot, inferring a monoexponential lifetime for this species. Surprisingly, measurements in the cellular environments with different metabolic states show a linear trajectory between free NADH at about 0.37 ns and bound NADH at 3.4 ns. These observations support that in a cellular environment, a 3.4 ns value could be used for bound NADH lifetime. The phasor analysis of many cell types shows a linear combination of fractional contributions of free and bound species NADH.

Published
2019

12. The DIVER Microscope for Imaging in Scattering Media.

Author

Dvornikov, Alexander, Malacrida, Leonel, and Gratton, Enrico

Subjects
FLIM, fluorescence, hyperspectral imaging, non-linear microscopy, scattering media, Bioengineering, Biomedical Imaging
Abstract

We describe an advanced DIVER (Deep Imaging Via Emission Recovery) detection system for two-photon fluorescence microscopy that allows imaging in multiple scattering media, including biological tissues, up to a depth of a few mm with micron resolution. This detection system is more sensitive to low level light signals than conventional epi-detection used in two-photon fluorescence microscopes. The DIVER detector efficiently collects scattered emission photons from a wide area of turbid samples at almost any entrance angle in a 2π spherical angle. Using an epi-detection scheme only photons coming from a relatively small area of a sample and at narrow acceptance angle can be detected. The transmission geometry of the DIVER imaging system makes it exceptionally suitable for Second and Third Harmonic Generation (SHG, THG) signal detection. It also has in-depth fluorescence lifetime imaging (FLIM) capability. Using special optical filters with sin-cos spectral response, hyperspectral analysis of images acquired in-depth in scattering media can be performed. The system was successfully employed in imaging of various biological tissues. The DIVER detector can be plugged into a standard microscope stage and used as an external detector with upright commercial two-photon microscopes.

Published
2019

13. StarD5: an ER stress protein regulates plasma membrane and intracellular cholesterol homeostasis

Author

Rodriguez-Agudo, Daniel, Malacrida, Leonel, Kakiyama, Genta, Sparrer, Tavis, Fortes, Carolina, Maceyka, Michael, Subler, Mark A, Windle, Jolene J, Gratton, Enrico, Pandak, William M, and Gil, Gregorio

Subjects
Digestive Diseases, Adaptor Proteins, Vesicular Transport, Animals, CHO Cells, Cell Membrane, Cells, Cultured, Cholesterol, Cricetulus, Endoplasmic Reticulum, Female, Homeostasis, Immunoblotting, Lipid Metabolism, Macrophages, Peritoneal, Mice, Mice, Inbred C57BL, Mice, Knockout, Microscopy, Fluorescence, RNA, Messenger, Triglycerides, cholesterol trafficking, macrophages, endoplasmic reticulum, Niemann-Pick C, fluorescence, steroidogenic acute regulatory protein-related lipid transfer proteins, fatty liver, steroidogenic acute regulatory-related lipid transfer domain 5, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology
Abstract

How plasma membrane (PM) cholesterol is controlled is poorly understood. Ablation of the gene encoding the ER stress steroidogenic acute regulatory-related lipid transfer domain (StarD)5 leads to a decrease in PM cholesterol content, a decrease in cholesterol efflux, and an increase in intracellular neutral lipid accumulation in macrophages, the major cell type that expresses StarD5. ER stress increases StarD5 expression in mouse hepatocytes, which results in an increase in accessible PM cholesterol in WT but not in StarD5-/- hepatocytes. StarD5-/- mice store higher levels of cholesterol and triglycerides, which leads to altered expression of cholesterol-regulated genes. In vitro, a recombinant GST-StarD5 protein transfers cholesterol between synthetic liposomes. StarD5 overexpression leads to a marked increase in PM cholesterol. Phasor analysis of 6-dodecanoyl-2-dimethylaminonaphthalene fluorescence lifetime imaging microscopy data revealed an increase in PM fluidity in StarD5-/- macrophages. Taken together, these studies show that StarD5 is a stress-responsive protein that regulates PM cholesterol and intracellular cholesterol homeostasis.

Published
2019

15. LAURDAN fluorescence and phasor plots reveal the effects of a H2O2 bolus in NIH-3T3 fibroblast membranes dynamics and hydration

Author

Malacrida, Leonel and Gratton, Enrico

Subjects
Biochemistry and Cell Biology, Biological Sciences, 2-Naphthylamine, Animals, Cell Membrane, Fluorescence, Fluorescent Dyes, Hydrogen Peroxide, Laurates, Membrane Fluidity, Mice, Microscopy, Fluorescence, NIH 3T3 Cells, Oxidants, LAURDAN, Phasor plots, Membrane dynamics, Dipolar relaxation, Hydrogen peroxide, Oxidative stress, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics
Abstract

Fluorescence spectroscopy, coupled with microscopy, opens new frontiers for the study of dynamic processes with high spatio-temporal resolution. The application of phasor plots to FLIM and hyperspectral imaging demonstrate unprecedented capabilities to study complex photophysics at the subcellular level. Using these approaches we studied the effects of an H2O2 bolus on NIH-3T3 membranes dynamics monitored by LAURDAN fluorescence. Exposure of NIH-3T3 cells to a bolus of H2O2 modifies the cell membranes and, in particular, the plasma membrane in a complex manner. The LAURDAN results reveal that the peroxide treatment decreases membrane fluidity but surprisingly increases dipolar relaxation around the excited probe. Using the Multidimensional-phasor approach we elucidated the complex photophysics of LAURDAN incorporated into cell membrane after H2O2 exposure. The results indicate the occurrence of LAURDAN fast-diffusion from gel↔ld phases in membranes exposed to a H2O2 bolus. An ad hoc hypothesis is presented to interpret the results in the context of H2O2 oxidative distress/eustress.

Published
2018

16. Differences between FLIM phasor analyses for data collected with the Becker and Hickl SPC830 card and with the FLIMbox card

Author

Ranjit, Suman, Malacrida, Leonel, and Gratton, Enrico

Subjects
Chemical Sciences, Physical Chemistry, Bioengineering, phasor analysis, FLIM, lifetime, fluorescence, FLIMBox, Becker & Hickl, Other Physical Sciences, Biochemistry and Cell Biology, Materials Engineering, Microscopy, Physical chemistry
Abstract

The phasor approach to FLIM (Fluorescence Lifetime Imaging Microscopy) is becoming popular due to the powerful fit free analysis and the visualization of the decay at each point in images of cells and tissues. However, although several implementation of the method are offered by manufactures of FLIM accessories for microscopes, the details of the conversion of the decay to phasors at each point in an image requires some consideration. Here, we show that if the decay is not properly acquired, the apparently simple phasor transformation can provide incorrect phasor plots and the results may be misinterpreted. In particular, we show the disagreement in experimental data acquired on the same samples using the two cards (FLIMbox, frequency domain and Becker & Hickl BH 830, time domain) and the effect produced by using the BH 830 card with different settings. This difference in data acquisition translates to the assignment of phasor components calculated using different acquisition parameters. This effect is already present in the original data that are not acquired with the proper parameters for the phasor conversion. We also show that the difference in the resolution of components already exists in the data acquired in the time domain when used with settings that do not allow acquisition of the fluorescence decay on a sufficient large time scale. RESEARCH HIGHLIGHTS: This paper is intended to made researchers aware of some simple requirements for the conversion of time-domain data (typically TCSPC) to phasors. The use of phasors for FLIM analysis has seen a surge of popularity. Since the phasor approach is a fit free method and has a powerful visualization of the data, it appears very simple to use. This paper shows that when the original data in the time domain is not acquired with the proper time range to cover the lifetimes in a sample, the conversion to phasors can produce very erroneous results. These results are appearing more frequently in the literature since many of the manufacturers of FLIM accessories for microscopes are now offering the phasor analysis in their software. Here, we show that the phasor transformation per se cannot correct for the problems with data acquisition and that one is misled to think that the "phasor approach" is a universal fix for the lack of the proper time range for data acquisition.

Published
2018

17. PTEN deficiency and AMPK activation promote nutrient scavenging and anabolism in prostate cancer cells

Author

Kim, Seong M, Nguyen, Tricia T, Ravi, Archna, Kubiniok, Peter, Finicle, Brendan T, Jayashankar, Vaishali, Malacrida, Leonel, Hou, Jue, Robertson, Jane, Gao, Dong, Chernoff, Jonathan, Digman, Michelle A, Potma, Eric O, Tromberg, Bruce J, Thibault, Pierre, and Edinger, Aimee L

Subjects
Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Biological Sciences, Prostate Cancer, Aging, Nutrition, Cancer, Urologic Diseases, 2.1 Biological and endogenous factors, Aetiology, AMP-Activated Protein Kinases, Animals, Gene Deletion, Humans, Male, Mice, Mice, Inbred C57BL, Nutrients, PTEN Phosphohydrolase, Pinocytosis, Prostatic Neoplasms, Stress, Physiological, Biochemistry and cell biology, Oncology and carcinogenesis
Abstract

We report that PTEN-deficient prostate cancer cells use macropinocytosis to survive and proliferate under nutrient stress. PTEN loss increased macropinocytosis only in the context of AMPK activation, revealing a general requirement for AMPK in macropinocytosis and a novel mechanism by which AMPK promotes survival under stress. In prostate cancer cells, albumin uptake did not require macropinocytosis, but necrotic cell debris proved a specific macropinocytic cargo. Isotopic labeling confirmed that macropinocytosed necrotic cell proteins fueled new protein synthesis in prostate cancer cells. Supplementation with necrotic debris, but not albumin, also maintained lipid stores, suggesting that macropinocytosis can supply nutrients other than amino acids. Nontransformed prostatic epithelial cells were not macropinocytic, but patient-derived prostate cancer organoids and xenografts and autochthonous prostate tumors all exhibited constitutive macropinocytosis, and blocking macropinocytosis limited prostate tumor growth. Macropinocytosis of extracellular material by prostate cancer cells is a previously unappreciated tumor-microenvironment interaction that could be targeted therapeutically.Significance: As PTEN-deficient prostate cancer cells proliferate in low-nutrient environments by scavenging necrotic debris and extracellular protein via macropinocytosis, blocking macropinocytosis by inhibiting AMPK, RAC1, or PI3K may have therapeutic value, particularly in necrotic tumors and in combination with therapies that cause nutrient stress. Cancer Discov; 8(7); 866-83. ©2018 AACR.See related commentary by Commisso and Debnath, p. 800This article is highlighted in the In This Issue feature, p. 781.

Published
2018

18. Comparison between iMSD and 2D-pCF analysis for molecular motion studies on in vivo cells: The case of the epidermal growth factor receptor

Author

Malacrida, Leonel, Rao, Estella, and Gratton, Enrico

Subjects
Biochemistry and Cell Biology, Biological Sciences, Algorithms, Animals, CHO Cells, Cricetulus, Diffusion, ErbB Receptors, Green Fluorescent Proteins, Image Processing, Computer-Assisted, Intravital Microscopy, Microscopy, Fluorescence, Models, Chemical, Fluorescence fluctuation spectroscopy, Diffusion anisotropy, Barrier to diffusion, Connectivity maps
Abstract

Image correlation analysis has evolved to become a valuable method of analysis of the diffusional motion of molecules in every points of a live cell. Here we compare the iMSD and the 2D-pCF approaches that provide complementary information. The iMSD method provides the law of diffusion and it requires spatial averaging over a small region of the cell. The 2D-pCF does not require spatial averaging and it gives information about obstacles for diffusion at pixel resolution. We show the analysis of the same set of data by the two methods to emphasize that both methods could be needed to have a comprehensive understanding of the molecular diffusional flow in a live cell.

Published
2018

20. Alteration in Fluidity of Cell Plasma Membrane in Huntington Disease Revealed by Spectral Phasor Analysis.

Author

Sameni, Sara, Malacrida, Leonel, Tan, Zhiqun, and Digman, Michelle A

Subjects
Cell Line, Cell Membrane, Humans, Huntington Disease, 2-Naphthylamine, Oxazines, Laurates, Phospholipids, Fluorescent Dyes, Staining and Labeling, Membrane Fluidity
Abstract

Huntington disease (HD) is a late-onset genetic neurodegenerative disorder caused by expansion of cytosine-adenine-guanine (CAG) trinucleotide in the exon 1 of the gene encoding the polyglutamine (polyQ). It has been shown that protein degradation and lipid metabolism is altered in HD. In many neurodegenerative disorders, impaired lipid homeostasis is one of the early events in the disease onset. Yet, little is known about how mutant huntingtin may affect phospholipids membrane fluidity. Here, we investigated how membrane fluidity in the living cells (differentiated PC12 and HEK293 cell lines) are affected using a hyperspectral imaging of widely used probes, LAURDAN. Using phasor approach, we characterized the fluorescence of LAURDAN that is sensitive to the polarity of the immediate environment. LAURDAN is affected by the physical order of phospholipids (lipid order) and reports the membrane fluidity. We also validated our results using a different fluorescent membrane probe, Nile Red (NR). The plasma membrane in the cells expressing expanded polyQ shows a shift toward increased membrane fluidity revealed by both LAURDAN and NR spectral phasors. This finding brings a new perspective in the understanding of the early stages of HD that can be used as a target for drug screening.

Published
2018

21. Visualization of barriers and obstacles to molecular diffusion in live cells by spatial pair-cross-correlation in two dimensions.

Author

Malacrida, Leonel, Hedde, Per Niklas, Ranjit, Suman, Cardarelli, Francesco, and Gratton, Enrico

Subjects
Bioengineering, (110.2960) Image analysis, (110.4155) Multiframe image processing, (170.2520) Fluorescence microscopy, Optical Physics, Materials Engineering
Abstract

Despite recent advances in optical super-resolution, we lack a method that can visualize the path followed by diffusing molecules in the cytoplasm or in the nucleus of cells. Fluorescence correlation spectroscopy (FCS) provides molecular dynamics at the single molecule level by averaging the behavior of many molecules over time at a single spot, thus achieving very good statistics but at only one point in the cell. Earlier image-based methods including raster-scan and spatiotemporal image correlation need spatial averaging over relatively large areas, thus compromising spatial resolution. Here, we use spatial pair-cross-correlation in two dimensions (2D-pCF) to obtain relatively high resolution images of molecular diffusion dynamics and transport in live cells. The 2D-pCF method measures the time for a particle to go from one location to another by cross-correlating the intensity fluctuations at specific points in an image. Hence, a visual map of the average path followed by molecules is created.

Published
2018

22. Building momentum through networks: Bioimaging across the Americas

Author

De Niz, Mariana, primary, Escobedo García, Rodrigo, additional, Terán Ramirez, Celina, additional, Pakowski, Ysa, additional, Abonza, Yuriney, additional, Bialy, Nikki, additional, Orr, Vanessa L., additional, Olivera, Andres, additional, Abonza, Victor, additional, Alleva, Karina, additional, Allodi, Silvana, additional, Almeida, Michael F., additional, Becerril Cuevas, Alexis Ricardo, additional, Bonnet, Frederic, additional, Burgos Solorio, Armando, additional, Chew, Teng‐Leong, additional, Chiabrando, Gustavo, additional, Cimini, Beth, additional, Cleret‐Buhot, Aurélie, additional, Contreras Jiménez, Gastón, additional, Daza, Laura, additional, De Sá, Vanessa, additional, De Val, Natalia, additional, Delgado‐Álvarez, Diego L., additional, Eliceiri, Kevin, additional, Fiolka, Reto, additional, Grecco, Hernan, additional, Hanein, Dorit, additional, Hernández Herrera, Paúl, additional, Hockberger, Phil, additional, Hernandez, Haydee O., additional, Hernandez Guadarrama, Yael, additional, Itano, Michelle, additional, Jacobs, Caron A., additional, Jiménez‐García, Luis F., additional, Jiménez Sabinina, Vilma, additional, Kamaid, Andres, additional, Keppler, Antje, additional, Kumar, Abhishek, additional, Lacoste, Judith, additional, Lovy, Alenka, additional, Luby‐Phelps, Kate, additional, Mahadevan‐Jansen, Anita, additional, Malacrida, Leonel, additional, Mehta, Shalin B., additional, Miller, Caroline, additional, Miranda, Kildare, additional, Moore, Joshua A., additional, North, Alison, additional, O'Toole, Peter, additional, Olivares Urbano, Mariana, additional, Pietrasanta, Lía I., additional, Portugal, Rodrigo V., additional, Rossi, Andrés H., additional, Sanchez Contreras, Jonathan, additional, Strambio‐De‐Castilla, Caterina, additional, Soldevila, Gloria, additional, Vale, Bruno, additional, Vazquez, Diana, additional, Wood, Chris, additional, Brown, Claire M., additional, and Guerrero, Adan, additional

Published
2024
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23. sideSPIM – selective plane illumination based on a conventional inverted microscope

Author

Siryaporn, Albert, Gratton, Enrico, Malacrida, Leonel, Hedde, Per Niklas, and Ahrar, Siavash

Subjects
Engineering, Nanotechnology, Biotechnology, (110.6880) Three-dimensional image acquisition, (170.2520) Fluorescence microscopy, (180.6900) Three-dimensional microscopy, (220.1000) Aberration compensation, (220.2945) Illumination design, Optical Physics, Materials Engineering, Ophthalmology and optometry, Biomedical engineering, Atomic, molecular and optical physics
Abstract

Previously described selective plane illumination microscopy techniques typically offset ease of use and sample handling for maximum imaging performance or vice versa. Also, to reduce cost and complexity while maximizing flexibility, it is highly desirable to implement light sheet microscopy such that it can be added to a standard research microscope instead of setting up a dedicated system. We devised a new approach termed sideSPIM that provides uncompromised imaging performance and easy sample handling while, at the same time, offering new applications of plane illumination towards fluidics and high throughput 3D imaging of multiple specimen. Based on an inverted epifluorescence microscope, all of the previous functionality is maintained and modifications to the existing system are kept to a minimum. At the same time, our implementation is able to take full advantage of the speed of the employed sCMOS camera and piezo stage to record data at rates of up to 5 stacks/s. Additionally, sample handling is compatible with established methods and switching magnification to change the field of view from single cells to whole organisms does not require labor intensive adjustments of the system.

Published
2017

24. A multidimensional phasor approach reveals LAURDAN photophysics in NIH-3T3 cell membranes.

Author

Malacrida, Leonel, Jameson, David M, and Gratton, Enrico

Subjects
NIH 3T3 Cells, Cell Membrane, Animals, Mice, Lipids, Microscopy, Fluorescence, Spectrometry, Fluorescence, Spectrum Analysis, Microscopy, Fluorescence, Spectrometry, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Mammalian cell membranes have different phospholipid composition and cholesterol content, displaying a profile of fluidity that depends on their intracellular location. Among the dyes used in membrane studies, LAURDAN has the advantage to be sensitive to the lipid composition as well as to membrane fluidity. The LAURDAN spectrum is sensitive to the lipid composition and dipolar relaxation arising from water penetration, but disentangling lipid composition from membrane fluidity can be obtained if time resolved spectra could be measured at each cell location. Here we describe a method in which spectral and lifetime information obtained in different measurements at the same plane in a cell are used in the phasor plot providing a solution to analyze multiple lifetime or spectral data through a common visualization approach. We exploit a property of phasor plots based on the reciprocal role of the phasor plot and the image. In the phasor analysis each pixel of the image is associated with a phasor and each phasor maps to pixels and features in the image. In this paper the lifetime and spectral fluorescence data are used simultaneously to determine the contribution of polarity and dipolar relaxations of LAURDAN in each pixel of an image.

Published
2017

25. Spectral phasor analysis of LAURDAN fluorescence in live A549 lung cells to study the hydration and time evolution of intracellular lamellar body-like structures

Author

Malacrida, Leonel, Astrada, Soledad, Briva, Arturo, Bollati-Fogolín, Mariela, Gratton, Enrico, and Bagatolli, Luis A

Subjects
Biological Sciences, Physical Sciences, 2-Naphthylamine, A549 Cells, Biological Transport, Entropy, Fluorescent Dyes, Humans, Intracellular Membranes, Laurates, Organelle Size, Organelles, Osmolar Concentration, Spectrometry, Fluorescence, Water, LAURDAN, Spectral phasor, Lamellar bodies, Membrane biophysics, Microscopic imaging, Macromolecular crowding, Biological sciences, Physical sciences
Abstract

Using LAURDAN spectral imaging and spectral phasor analysis we concurrently studied the growth and hydration state of subcellular organelles (lamellar body-like, LB-like) from live A549 lung cancer cells at different post-confluence days. Our results reveal a time dependent two-step process governing the size and hydration of these intracellular LB-like structures. Specifically, a first step (days 1 to 7) is characterized by an increase in their size, followed by a second one (days 7 to 14) where the organelles display a decrease in their global hydration properties. Interestingly, our results also show that their hydration properties significantly differ from those observed in well-characterized artificial lamellar model membranes, challenging the notion that a pure lamellar membrane organization is present in these organelles at intracellular conditions. Finally, these LB-like structures show a significant increase in their hydration state upon secretion, suggesting a relevant role of entropy during this process.

Published
2016

26. Measurements of absolute concentrations of NADH in cells using the phasor FLIM method.

Author

Ma, Ning, Digman, Michelle A, Malacrida, Leonel, and Gratton, Enrico

Subjects
(180.0180) Microscopy, (180.2520) Fluorescence microscopy, Optical Physics, Materials Engineering
Abstract

We propose a graphical method using the phasor representation of the fluorescence decay to derive the absolute concentration of NADH in cells. The method requires the measurement of a solution of NADH at a known concentration. The phasor representation of the fluorescence decay accounts for the differences in quantum yield of the free and bound form of NADH, pixel by pixel of an image. The concentration of NADH in every pixel in a cell is obtained after adding to each pixel in the phasor plot a given amount of unmodulated light which causes a shift of the phasor towards the origin by an amount that depends on the intensity at the pixel and the fluorescence lifetime at the pixel. The absolute concentration of NADH is obtained by comparison of the shift obtained at each pixel of an image with the shift of the calibrated solution.

Published
2016

28. Model-free methods to study membrane environmental probes: a comparison of the spectral phasor and generalized polarization approaches.

Author

Malacrida, Leonel, Gratton, Enrico, and Jameson, David M

Subjects
LAURDAN, generalized polarization, lung surfactant, membrane biophysics, spectral phasor
Abstract

In this note, we present a discussion of the advantages and scope of model-free analysis methods applied to the popular solvatochromic probe LAURDAN, which is widely used as an environmental probe to study dynamics and structure in membranes. In particular, we compare and contrast the generalized polarization approach with the spectral phasor approach. To illustrate our points we utilize several model membrane systems containing pure lipid phases and, in some cases, cholesterol or surfactants. We demonstrate that the spectral phasor method offers definitive advantages in the case of complex systems.

Published
2015

47. ZebraFishACDAN_Data_Code

Author

Vorontsova, Irene, Vallmitjana, Alexander, Torrado, Bel��n, Gratton, Enrico, and Malacrida, Leonel

Abstract

Raw lsm spectral files of zebrafish lens and MATLAB code to export them, analyze them and plot figures for the paper.

Published
2021
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