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Dive into the research topics where Marc Tramier is active.

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Featured researches published by Marc Tramier.


Biophysical Journal | 2001

Homo-FRET Microscopy in Living Cells to Measure Monomer-Dimer Transition of GFP-Tagged Proteins

Isabelle Gautier; Marc Tramier; Christiane Durieux; Jacques Coppey; Robert Pansu; Jean-Claude Nicolas; Klaus Kemnitz; Maı̈té Coppey-Moisan

Fluorescence anisotropy decay microscopy was used to determine, in individual living cells, the spatial monomer-dimer distribution of proteins, as exemplified by herpes simplex virus thymidine kinase (TK) fused to green fluorescent protein (GFP). Accordingly, the fluorescence anisotropy dynamics of two fusion proteins (TK27GFP and TK366GFP) was recorded in the confocal mode by ultra-sensitive time-correlated single-photon counting. This provided a measurement of the rotational time of these proteins, which, by comparing with GFP, allowed the determination of their oligomeric state in both the cytoplasm and the nucleus. It also revealed energy homo-transfer within aggregates that TK366GFP progressively formed. Using a symmetric dimer model, structural parameters were estimated; the mutual orientation of the transition dipoles of the two GFP chromophores, calculated from the residual anisotropy, was 44.6 +/- 1.6 degrees, and the upper intermolecular limit between the two fluorescent tags, calculated from the energy transfer rate, was 70 A. Acquisition of the fluorescence steady-state intensity, lifetime, and anisotropy decay in the same cells, at different times after transfection, indicated that TK366GFP was initially in a monomeric state and then formed dimers that grew into aggregates. Picosecond time-resolved fluorescence anisotropy microscopy opens a promising avenue for obtaining structural information on proteins in individual living cells, even when expression levels are very low.


Journal of Virology | 2001

Close but Distinct Regions of Human Herpesvirus 8 Latency-Associated Nuclear Antigen 1 Are Responsible for Nuclear Targeting and Binding to Human Mitotic Chromosomes

Tristan Piolot; Marc Tramier; Maïté Coppey; Jean-Claude Nicolas; Vincent Maréchal

ABSTRACT Human herpesvirus 8 is associated with all forms of Kaposis sarcoma, AIDS-associated body cavity-based lymphomas, and some forms of multicentric Castlemans disease. Herpesvirus 8, like other gammaherpesviruses, can establish a latent infection in which viral genomes are stably maintained as multiple episomes. The latent nuclear antigen (LANA or LNAI) may play an essential role in the stable maintenance of latent episomes, notably by interacting concomitantly with the viral genomes and the metaphase chromosomes, thus ensuring an efficient transmission of the neoduplicated episomes to the daughter cells. To identify the regions responsible for its nuclear and subnuclear localization in interphase and mitotic cells, LNAI and various truncated forms were fused to a variant of green fluorescent protein. This enabled their localization and chromosome binding activity to be studied by low-light-level fluorescence microscopy in living HeLa cells. The results demonstrate that nuclear localization of LNAI is due to a unique signal, which maps between amino acids 24 and 30. Interestingly, this nuclear localization signal closely resembles those identified in EBNA1 from Epstein-Barr virus and herpesvirus papio. A region encompassing amino acids 5 to 22 was further proved to mediate the specific interaction of LNA1 with chromatin during interphase and the chromosomes during mitosis. The presence of putative phosphorylation sites in the chromosome binding sites of LNA1 and EBNA1 suggests that their activity may be regulated by specific cellular kinases.


Biophysical Journal | 2002

Picosecond-Hetero-FRET Microscopy to Probe Protein-Protein Interactions in Live Cells

Marc Tramier; Isabelle Gautier; Tristan Piolot; Sylvie Ravalet; Klaus Kemnitz; Jacques Coppey; Christiane Durieux; Vincent Mignotte; Maïté Coppey-Moisan

By using a novel time- and space-correlated single-photon counting detector, we show that fluorescence resonance energy transfer (FRET) between cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP) fused to herpes simplex virus thymidine kinase (TK) monomers can be used to reveal homodimerization of TK in the nucleus and cytoplasm of live cells. However, the quantification of energy transfer was limited by the intrinsic biexponential fluorescence decay of the donor CFP (lifetimes of 1.3 +/- 0.2 ns and 3.8 +/- 0.4 ns) and by the possibility of homodimer formation between two TK-CFP. In contrast, the heterodimerization of the transcriptional factor NF-E2 in the nucleus of live cells was quantified from the analysis of the fluorescence decays of GFP in terms of 1) FRET efficiency between GFP and DsRed chromophores fused to p45 and MafG, respectively, the two subunits of NF-E2 (which corresponds to an interchromophoric distance of 39 +/- 1 A); and 2) fractions of GFP-p45 bound to DsRed-MafG (constant in the nucleus, varying in the range of 20% to 70% from cell to cell). The picosecond resolution of the fluorescence kinetics allowed us to discriminate between very short lifetimes of immature green species of DsRed-MafG and that of GFP-p45 involved in FRET with DsRed-MafG.


BioEssays | 2012

FRET microscopy in the living cell: Different approaches, strengths and weaknesses

Sergi Padilla-Parra; Marc Tramier

New imaging methodologies in quantitative fluorescence microscopy, such as Förster resonance energy transfer (FRET), have been developed in the last few years and are beginning to be extensively applied to biological problems. FRET is employed for the detection and quantification of protein interactions, and of biochemical activities. Herein, we review the different methods to measure FRET in microscopy, and more importantly, their strengths and weaknesses. In our opinion, fluorescence lifetime imaging microscopy (FLIM) is advantageous for detecting inter‐molecular interactions quantitatively, the intensity ratio approach representing a valid and straightforward option for detecting intra‐molecular FRET. Promising approaches in single molecule techniques and data analysis for quantitative and fast spatio‐temporal protein‐protein interaction studies open new avenues for FRET in biological research.


Journal of Biological Chemistry | 2005

Homo- and Hetero-oligomerization of β-Arrestins in Living Cells

Hélène Storez; Mark G. H. Scott; Hassan Issafras; Anne Burtey; Alexandre Benmerah; Olivier Muntaner; Tristan Piolot; Marc Tramier; Maïté Coppey-Moisan; Michel Bouvier; Catherine Labbé-Jullié; Stefano Marullo

Arrestins are important proteins, which regulate the function of serpentine heptahelical receptors and contribute to multiple signaling pathways downstream of receptors. The ubiquitous β-arrestins are believed to function exclusively as monomers, although self-association is assumed to control the activity of visual arrestin in the retina, where this isoform is particularly abundant. Here the oligomerization status of β-arrestins was investigated using different approaches, including co-immunoprecipitation of epitope-tagged β-arrestins and resonance energy transfer (BRET and FRET) in living cells. At steady state and at physiological concentrations, β-arrestins constitutively form both homo- and hetero-oligomers. Co-expression of β-arrestin2 and β-arrestin1 prevented β-arrestin1 accumulation into the nucleus, suggesting that hetero-oligomerization may have functional consequences. Our data clearly indicate that β-arrestins can exist as homo- and hetero-oligomers in living cells and raise the hypothesis that the oligomeric state may regulate their subcellular distribution and functions.


Biophysical Journal | 2009

Quantitative Comparison of Different Fluorescent Protein Couples for Fast FRET-FLIM Acquisition

Sergi Padilla-Parra; Nicolas Audugé; Hervé Lalucque; Jean-Claude Mevel; Maïté Coppey-Moisan; Marc Tramier

The fluorescent-protein based fluorescence resonance energy transfer (FRET) approach is a powerful method for quantifying protein-protein interactions in living cells, especially when combined with fluorescence lifetime imaging microscopy (FLIM). To compare the performance of different FRET couples for FRET-FLIM experiments, we first tested enhanced green fluorescent protein (EGFP) linked to different red acceptors (mRFP1-EGFP, mStrawberry-EGFP, HaloTag (TMR)-EGFP, and mCherry-EGFP). We obtained a fraction of donor engaged in FRET (f(D)) that was far from the ideal case of one, using different mathematical models assuming a double species model (i.e., discrete double exponential fixing the donor lifetime and double exponential stretched for the FRET lifetime). We show that the relatively low f(D) percentages obtained with these models may be due to spectroscopic heterogeneity of the acceptor population, which is partially caused by different maturation rates for the donor and the acceptor. In an attempt to improve the amount of donor protein engaged in FRET, we tested mTFP1 as a donor coupled to mOrange and EYFP, respectively. mTFP1 turned out to be at least as good as EGFP for donor FRET-FLIM experiments because 1), its lifetime remained constant during light-induced fluorescent changes; 2), its fluorescence decay profile was best fitted with a single exponential model; and 3), no photoconversion was detected. The f(D) value when combined with EYFP as an acceptor was the highest of all tandems tested (0.7). Moreover, in the context of fast acquisitions, we obtained a minimal f(D) (mf(D)) for mTFP1-EYFP that was almost two times greater than that for mCherry-EGFP (0.65 vs. 0.35). Finally, we compared EGFP and mTFP1 in a biological situation in which the fusion proteins were highly immobile, and EGFP and mTFP1 were linked to the histone H4 (EGFP-H4 and mTFP1-H4) in fast FLIM acquisitions. In this particular case, the fluorescence intensity was more stable for EGFP-H4 than for mTFP1-H4. Nevertheless, we show that mTFP1/EYFP stands alone as the best FRET-FLIM couple in terms of f(D) analysis.


Biophysical Journal | 2008

Quantitative FRET Analysis by Fast Acquisition Time Domain FLIM at High Spatial Resolution in Living Cells

Sergi Padilla-Parra; Nicolas Audugé; Maïté Coppey-Moisan; Marc Tramier

Quantitative analysis in Förster resonance energy transfer (FRET) experiments in live cells for protein interaction studies is still a challenging issue. In a two-component system (FRET and no FRET donor species), fitting of fluorescence lifetime imaging microscopy (FLIM) data gives the fraction of donor molecules involved in FRET (f(D)) and the intrinsic transfer efficiency. But when fast FLIM acquisitions are used to monitor dynamic changes in protein-protein interactions at high spatial and temporal resolutions in living cells, photon statistics and time resolution are limited. In this case, fitting procedures are not reliable, even for single lifetime donors. We introduce the new concept of a minimal fraction of donor molecules involved in FRET (mf(D)), coming from the mathematical minimization of f(D). We find particular advantage in the use of mf(D) because it can be obtained without fitting procedures and it is derived directly from FLIM data. mf(D) constitutes an interesting quantitative parameter for live cell studies because it is related to the minimal relative concentration of interacting proteins. For multi-lifetime donors, the process of fitting complex fluorescence decays to find at least four reliable lifetimes is a near impossible task. Here, mf(D) extension for multi-lifetime donors is the only quantitative determinant. We applied this methodology for imaging the interaction between the bromodomains of TAF(II250) and acetylated histones H4 in living cells at high resolution. We show the existence of discrete acetylated chromatin domains where the minimal fraction of bromodomain interacting with acetylated H4 oscillates from 0.26 to 0.36 and whose size is smaller than half of one micron cube. We demonstrate that mf(D) by itself is a useful tool to investigate quantitatively protein interactions in live cells, especially when using fast FRET-FLIM acquisition times.


Applied Physics Letters | 2003

Low-intensity two-dimensional imaging of fluorescence lifetimes in living cells

Valentina Emiliani; Daniele Sanvitto; Marc Tramier; T. Piolot; Zdeněk Petrášek; Klaus Kemnitz; Christiane Durieux; Maïté Coppey-Moisan

The use of a time- and space-correlated single-photon counting detector enables us to perform fluorescence lifetime imaging microscopy in living cells with a temporal resolution of less than 100 ps and a spatial resolution of 500 nm. Two-dimensional (2D) maps of the fluorescence lifetimes and the corresponding prefactors are extracted by the use of a fitting program based on the Levenberg–Marquardt algorithm (Globals Unlimited). We applied this technique to extract 2D maps of protein localization in multilabeled living cells and to study protein–protein interaction by fluorescence resonance energy transfer.


Methods in Cell Biology | 2008

Fluorescence anisotropy imaging microscopy for homo-FRET in living cells.

Marc Tramier; Maïté Coppey-Moisan

In this chapter, we present the basic physical principles of the fluorescence anisotropy imaging microscopy (FAIM) and its application to study FP-tagged protein dynamics and interaction in live cells. The Förster mechanism of electronic energy transfer can occur between like chromophores (homo-fluorescence resonance energy transfer, homo-FRET) inducing fluorescence depolarization and can be monitored by fluorescence anisotropy. The energy transfer rate is fast compared to the rotational time of proteins, and therefore its detection as a fast depolarization process in the fluorescence anisotropy can be easily discriminated from rotational motion. Quantitative analysis of fluorescence anisotropy decays provides information on structural parameters: distance between the two interacting chromophores and spatial orientation between the chromophores within dimeric proteins. Fluorescence anisotropy decay is not easy to measure in living cells under the microscope and the instrumentations are necessarily sophisticated. In contrast, any type of microscope can be used to measure the steady-state anisotropy. Interestingly, two-photon excitation steady-state FAIM is a powerful tool for qualitative analysis of macromolecule interactions in living cells and can be used easily for time-lapse homo-FRET.


Proceedings of the National Academy of Sciences of the United States of America | 2007

β-arrestin 2 oligomerization controls the Mdm2-dependent inhibition of p53

Cédric Boularan; Mark G. H. Scott; Karima Bourougaa; Myriam Bellal; Emmanuel Esteve; Alain Thuret; Alexandre Benmerah; Marc Tramier; Maïté Coppey-Moisan; Catherine Labbé-Jullié; Robin Fåhraeus; Stefano Marullo

β-arrestins (β-arrs), two ubiquitous proteins involved in serpentine heptahelical receptor regulation and signaling, form constitutive homo- and heterooligomers stabilized by inositol 1,2,3,4,5,6-hexakisphosphate (IP6). Monomeric β-arrs are believed to interact with receptors after agonist activation, and therefore, β-arr oligomers have been proposed to represent a resting biologically inactive state. In contrast to this, we report here that the interaction with and subsequent titration out of the nucleus of the protooncogene Mdm2 specifically require β-arr2 oligomers together with the previously characterized nucleocytoplasmic shuttling of β-arr2. Mutation of the IP6-binding sites impair oligomerization, reduce interaction with Mdm2, and inhibit p53-dependent antiproliferative effects of β-arr2, whereas the competence for receptor regulation and signaling is maintained. These observations suggest that the intracellular concentration of β-arr2 oligomers might control cell survival and proliferation.

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Maïté Coppey-Moisan

Centre national de la recherche scientifique

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Julien Roul

Centre national de la recherche scientifique

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Christiane Durieux

Centre national de la recherche scientifique

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Jacques Pecreaux

Centre national de la recherche scientifique

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Klaus Kemnitz

Centre national de la recherche scientifique

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Maı̈té Coppey-Moisan

Centre national de la recherche scientifique

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Claude Prigent

Centre national de la recherche scientifique

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