Fluorescent Peptide Biosensor for Probing the Relative Abundance of Cyclin-Dependent Kinases in Living Cells

Cyclin-dependant kinases play a central role in coordinating cell growth and division, and in sustaining proliferation of cancer cells, thereby constituting attractive pharmacological targets. However, there are no direct means of assessing their relative abundance in living cells, current approaches being limited to antigenic and proteomic analysis of fixed cells. In order to probe the relative abundance of these kinases directly in living cells, we have developed a fluorescent peptide biosensor with biligand affinity for CDKs and cyclins in vitro, that retains endogenous CDK/cyclin complexes from cell extracts, and that bears an environmentally-sensitive probe, whose fluorescence increases in a sensitive fashion upon recognition of its targets. CDKSENS was introduced into living cells, through complexation with the cell-penetrating carrier CADY2 and applied to assess the relative abundance of CDK/Cyclins through fluorescence imaging and ratiometric quantification. This peptide biosensor technology affords direct and sensitive readout of CDK/cyclin complex levels, and reports on differences in complex formation when tampering with a single CDK or cyclin. CDKSENS further allows for detection of differences between different healthy and cancer cell lines, thereby enabling to distinguish cells that express high levels of these heterodimeric kinases, from cells that present decreased or defective assemblies. This fluorescent biosensor technology provides information on the overall status of CDK/Cyclin complexes which cannot be obtained through antigenic detection of individual subunits, in a non-invasive fashion which does not require cell fixation or extraction procedures. As such it provides promising perspectives for monitoring the response to therapeutics that affect CDK/Cyclin abundance, for cell-based drug discovery strategies and fluorescence-based cancer diagnostics

Development of fluorescent peptide-based biosensors for probing Cdk-cyclins in living cells

Chez les eucaryotes supérieurs, la progression ordonnée du cycle cellulaire est régie par une dizaine de kinases Cdk-cyclines. Les altérations génétiques ou épigénétiques impliquant des oncogènes ou des gènes codant pour des suppresseurs de tumeurs sont souvent associées à l'expression ou l'activation aberrante des Cdks, favorisant ainsi la prolifération cellulaire incontrôlée et notamment le développement de cancers. Malgré la pertinence oncogénique et thérapeutique de ces protéines, leur détection est restée jusqu'à présent limitée à des méthodes indirectes et invasives. Dans ce contexte, mes travaux de thèse ont permis de développer un biosenseur peptidique fluorescent permettant de reconnaître spécifiquement les Cdk-cyclines. Associé à une stratégie de vectorisation non invasive basée sur l'utilisation de peptides vecteurs pénétrants, le biosenseur a été délivré efficacement dans les cellules. La mise au point d'une quantification ratiométrique du signal a par ailleurs permis d'évaluer l'abondance relative des Cdk-cyclines endogènes. Deux variants plus spécifiques de certains complexes ont pu être développés. Enfin, d'autres versions du biosenseur ont quant à elles permis d'évaluer sa biodistribution in vivo et de mettre au point un essai cellulaire en vue d'un criblage de petites molécules ayant un effet sur l'abondance relative des Cdk-cyclines.Cdk-cyclins represent key regulators of cell cycle progression among superior eukaryotes. Genetic and epigenetic alterations involving oncogenes or tumor suppressor genes are often associated with aberrant expression or activation of Cdks, leading to the sustained proliferation of cells and by the way to the development of cancers. Despite the oncogenic and therapeutic relevance of these proteins, their detection has so far remained limited to indirect and invasive methods. My Ph.D. thesis work aimed in this context at developing peptidic fluorescent biosensors that specifically recognize Cdk-cyclins. Combined to cell-penetrating peptides, the biosensor was efficiently delivered into cells. Following the development of the signal ratiometric quantification, the relative abundance of endogenous Cdk-cyclins was directly evaluated in living cells. Two other variants, that are more specific towards specific Cdk-cyclin complexes, were also designed. Finally, the development of novel versions of the biosensor allowed us to evaluate its biodistribution in vivo and to set up a cell-based assay to screen small molecules having an effect on Cdk-cyclin relative abundance

Lost in mechanobiology, what's next?: Missing tools related to the physics of the system

International audienc

Lost in mechanobiology, what's next?: Missing tools related to the physics of the system

International audienc

Cell-cycle markers and biosensors.

International audienceSince the first schematic illustrations of dividing cells, we have come a long way in characterising eukaryotic cells and defining their cell-cycle status thanks to a number of complementary approaches. Although most of these approaches rely on cell-fixation procedures to identify molecular components in cell lysates, cultured cells or tissues, the development of GFP technology has enabled visualisation of virtually any fusion protein in cellulo and in vivo, and the exploitation of functional elements with well-defined spatiotemporal characteristics has enabled the development of genetically encoded fluorescent markers of cell-cycle phases, thus providing novel means of characterising the status of living cells in real time with high resolution. Together with technological advances in fluorescence chemistry and imaging approaches, the more recent development of fluorescent biosensors has provided direct means of probing cell-cycle regulators and of studying their dynamics with high spatial and temporal resolution. Here we review classical approaches that rely on cell fixation to characterise the cell-cycle status and its regulatory enzymes, and we describe the more recent development of cell-cycle markers based on genetically encoded fusions of fluorescent proteins with characteristic cell-cycle features, and of fluorescent biosensor technology to probe cell-cycle regulators in living cells. Biosensors not only provide a means of characterising the behaviour of cell-cycle regulators in their natural environment, they are also very useful for comparative studies of biological processes in healthy and pathological conditions, and can be further applied to diagnostic approaches to assess the status of a specific target, and to monitor response to therapeutic intervention

Développement de biosenseurs peptidiques fluorescents pour la détection des Cdk-cyclines dans les cellules vivantes

Chez les eucaryotes supérieurs, la progression ordonnée du cycle cellulaire est régie par une dizaine de kinases Cdk-cyclines. Les altérations génétiques ou épigénétiques impliquant des oncogènes ou des gènes codant pour des suppresseurs de tumeurs sont souvent associées à l'expression ou l'activation aberrante des Cdks, favorisant ainsi la prolifération cellulaire incontrôlée et notamment le développement de cancers. Malgré la pertinence oncogénique et thérapeutique de ces protéines, leur détection est restée jusqu'à présent limitée à des méthodes indirectes et invasives. Dans ce contexte, mes travaux de thèse ont permis de développer un biosenseur peptidique fluorescent permettant de reconnaître spécifiquement les Cdk-cyclines. Associé à une stratégie de vectorisation non invasive basée sur l'utilisation de peptides vecteurs pénétrants, le biosenseur a été délivré efficacement dans les cellules. La mise au point d'une quantification ratiométrique du signal a par ailleurs permis d'évaluer l'abondance relative des Cdk-cyclines endogènes. Deux variants plus spécifiques de certains complexes ont pu être développés. Enfin, d'autres versions du biosenseur ont quant à elles permis d'évaluer sa biodistribution in vivo et de mettre au point un essai cellulaire en vue d'un criblage de petites molécules ayant un effet sur l'abondance relative des Cdk-cyclines.Cdk-cyclins represent key regulators of cell cycle progression among superior eukaryotes. Genetic and epigenetic alterations involving oncogenes or tumor suppressor genes are often associated with aberrant expression or activation of Cdks, leading to the sustained proliferation of cells and by the way to the development of cancers. Despite the oncogenic and therapeutic relevance of these proteins, their detection has so far remained limited to indirect and invasive methods. My Ph.D. thesis work aimed in this context at developing peptidic fluorescent biosensors that specifically recognize Cdk-cyclins. Combined to cell-penetrating peptides, the biosensor was efficiently delivered into cells. Following the development of the signal ratiometric quantification, the relative abundance of endogenous Cdk-cyclins was directly evaluated in living cells. Two other variants, that are more specific towards specific Cdk-cyclin complexes, were also designed. Finally, the development of novel versions of the biosensor allowed us to evaluate its biodistribution in vivo and to set up a cell-based assay to screen small molecules having an effect on Cdk-cyclin relative abundance.MONTPELLIER-BU Sciences (341722106) / SudocSudocFranceF

PEP and CADY-mediated delivery of fluorescent peptides and proteins into living cells.

International audienceCell-penetrating peptides (CPPs) constitute a family of peptides with the characteristic ability to cross biological membranes and deliver cargo into the intracellular milieu. Several CPPs have been proposed for delivery of polypeptides and proteins into cells through either of two strategies: covalent or complexed in a non-covalent fashion. Members of the PEP family are primary amphipathic peptides which have been shown to deliver peptides and proteins into a wide variety of cells through formation of non-covalent complexes. CADY is a secondary amphipathic peptide which has been demonstrated to deliver short nucleic acids, in particular siRNA with high efficiency. Here we review the characteristics of the PEP and CADY carriers and describe a novel derivative of CADY termed CADY2, which also presents sequence similarities to Pep1. We have compared Pep1, CADY and CADY2 in their efficiency to interact with and internalize short fluorogenic peptides and proteins into cultured cells, and provide evidence that CADY2 can interact with proteins and peptides and deliver them efficiently into living cells, similar to Pep1, but in contrast to CADY which is unable to deliver any peptide, even short negatively charged peptides. This is the first study to investigate the influence of the cargo on the interactions between PEP and CADY carriers, thereby providing novel insights into the physicochemical parameters underlying interactions and cellular uptake of peptides and proteins by these non-covalent CPPs

Spatial integration of mechanical forces by α-actinin establishes actin network symmetry

International audienceCell and tissue morphogenesis depend on the production and spatial organization of tensional forces in the actin cytoskeleton. Actin network architecture is made of distinct modules characterized by specific filament organizations. The assembly of these modules are well described but their integration in a cellular network is less understood. Here we investigated the mechanism regulating the interplay between network architecture and the geometry of cell's extracellular environment. We found that α-actinin, a filament crosslinker, is essential for network symmetry to be consistent with extracellular microenvironment symmetry. It is required for the interconnection of transverse arcs with radial fibres to ensure an appropriate balance between forces at cell adhesions and across the actin network. Furthermore, this connectivity appeared necessary for the cell ability to integrate and to adapt to complex patterns of extracellular cues as they migrate. Our study has unveiled a role of actin-filament crosslinking in the spatial integration of mechanical forces that ensures the adaptation of intracellular symmetry axes in accordance with the geometry of extracellular cues

Measurement of cell traction forces with ImageJ.

Equipe Physique du Cytosquelette et de la morphogenèse (CytoMorpho)International audienceThe quantification of cell traction forces requires three key steps: cell plating on a deformable substrate, measurement of substrate deformation, and the numerical estimation of the corresponding cell traction forces. The computing steps to measure gel deformation and estimate the force field have somehow limited the adoption of this method in cell biology labs. Here we propose a set of ImageJ plug-ins so that every lab equipped with a fluorescent microscope can measure cell traction forces

A role for the microtubule +end protein Bik1 (CLIP170) and the Rho1 GTPase in Snc1 trafficking

International audienceThe diversity of microtubule functions is dependent on the status of tubulin C-termini. To address the physiological role of the C-terminal aromatic residue of -tubulin, a tub1-Glu yeast strain expressing an -tubulin devoid of its C-terminal amino-acid was used to perform a genome-wide-lethality screen. The identified synthetic lethal genes suggested links with endocytosis and related processes. In the tub1-Glu strain, the routing of the v-SNARE Snc1 was strongly impaired, with a loss of its polarized distribution in the bud and Abp1, an actin patch/endocytic marker, developed comet-tails structures. Snc1 trafficking necessitated dynamic microtubules but not dynein and kinesin motors. Interestingly, deletion of the microtubule +end protein Bik1 (CLIP170), which is preferentially recruited to the C-terminal residue of -tubulin, similarly resulted in Snc1 trafficking defects. Finally, constitutively active Rho1 rescued both Bik1 localization at microtubule +ends in tub1-Glu strain and a correct Snc1 trafficking in a Bik1-dependent manner. Our results provide the first evidence for a role of microtubule +ends in membrane-cargo trafficking in yeast, through Rho1- and Bik1-dependent mechanisms and highlight the importance of -tubulin last amino-acid in this process