Le syndrome de l'X fragile : Une protéine absente et 1001 ARNm déboussolés

Le syndrome du X fragile, première cause de retard mental héréditaire, est une maladie monogénique liée au chromosome X. Le syndrome est causé par l’inactivation du gène Fragile Mental Retardation 1(FMR1) entraînant l’absence de la protéine FMRP dont le rôle présumé est de coordonner le devenir et la traduction d’un grand nombre d’ARNm. Toutefois, s’il est actuellement admis que FMRP se comporte comme un répresseur de la traduction dans certaines conditions expérimentales, et malgré les nombreuses publications sur le sujet, nous devons nous rendre à l’évidence que les fonctions réelles de FMRP sont encore mal connues. De plus, l’existence de deux protéines FXR1P et FXR2P, homologues à FMRP, suggère que la fonction de FMRP est bien plus complexe que celle imaginée à l’origine. Nous limitons les propos de cet article à l’état actuel des connaissances concernant le rôle de FMRP dans l’adressage des ARNm, ainsi qu’aux conséquences possibles de l’absence de FMRP sur le transport et la traduction des ARNm dans les cellules pourvues d’arborescences et de prolongements que sont les neurones.Fragile X syndrome is the most common form of inherited mental retardation. This X-linked disease is due to transcriptional silencing of the Fragile Mental Retardation 1 (FMR1) gene and the absence of its gene product, FMRP. This protein is an RNA-binding protein present in mRNP complexes associated with the translation machinery and is thought to be a key player in the control of mRNA transport in neurons. However, the exact role of FMRP in translation remains unclear. Two homologous proteins, FXR1P and FXR2P, are also found in RNP complexes containing FMRP, suggesting that FMRP’s functions are much more complex than first thought. The molecular mechanisms altered in cells lacking FMRP still remain to be elucidated, as well as the putative roles of FXR1P and FXR2P as compensatory molecules. Here, we review the various possible functions of FMRP in RNA localization and transport in highly differentiated cells containing dendritic extensions such as neurons

Spatial Intensity Distribution Analysis Reveals Abnormal Oligomerization of Proteins in Single Cells

AbstractKnowledge of membrane receptor organization is essential for understanding the initial steps in cell signaling and trafficking mechanisms, but quantitative analysis of receptor interactions at the single-cell level and in different cellular compartments has remained highly challenging. To achieve this, we apply a quantitative image analysis technique—spatial intensity distribution analysis (SpIDA)—that can measure fluorescent particle concentrations and oligomerization states within different subcellular compartments in live cells. An important technical challenge faced by fluorescence microscopy-based measurement of oligomerization is the fidelity of receptor labeling. In practice, imperfect labeling biases the distribution of oligomeric states measured within an aggregated system. We extend SpIDA to enable analysis of high-order oligomers from fluorescence microscopy images, by including a probability weighted correction algorithm for nonemitting labels. We demonstrated that this fraction of nonemitting probes could be estimated in single cells using SpIDA measurements on model systems with known oligomerization state. Previously, this artifact was measured using single-step photobleaching. This approach was validated using computer-simulated data and the imperfect labeling was quantified in cells with ion channels of known oligomer subunit count. It was then applied to quantify the oligomerization states in different cell compartments of the proteolipid protein (PLP) expressed in COS-7 cells. Expression of a mutant PLP linked to impaired trafficking resulted in the detection of PLP tetramers that persist in the endoplasmic reticulum, while no difference was measured at the membrane between the distributions of wild-type and mutated PLPs. Our results demonstrate that SpIDA allows measurement of protein oligomerization in different compartments of intact cells, even when fractional mislabeling occurs as well as photobleaching during the imaging process, and reveals insights into the mechanism underlying impaired trafficking of PLP

Gold nanoparticle-assisted all optical localized stimulation and monitoring of Ca2+ signaling in neurons

Light-assisted manipulation of cells to control membrane activity or intracellular signaling has become a major avenue in life sciences. However, the ability to perform subcellular light stimulation to investigate localized signaling has been limited. Here, we introduce an all optical method for the stimulation and the monitoring of localized Ca2+ signaling in neurons that takes advantage of plasmonic excitation of gold nanoparticles (AuNPs). We show with confocal microscopy that 800 nm laser pulse application onto a neuron decorated with a few AuNPs triggers a transient increase in free Ca2+, measured optically with GCaMP6s. We show that action potentials, measured electrophysiologically, can be induced with this approach. We demonstrate activation of local Ca2+ transients and Ca2+ signaling via CaMKII in dendritic domains, by illuminating a single or few functionalized AuNPs specifically targeting genetically-modified neurons. This NP-Assisted Localized Optical Stimulation (NALOS) provides a new complement to light-dependent methods for controlling neuronal activity and cell signaling

Adaptive Movement Compensation for In Vivo Imaging of Fast Cellular Dynamics within a Moving Tissue

In vivo non-linear optical microscopy has been essential to advance our knowledge of how intact biological systems work. It has been particularly enabling to decipher fast spatiotemporal cellular dynamics in neural networks. The power of the technique stems from its optical sectioning capability that in turn also limits its application to essentially immobile tissue. Only tissue not affected by movement or in which movement can be physically constrained can be imaged fast enough to conduct functional studies at high temporal resolution. Here, we show dynamic two-photon Ca2+ imaging in the spinal cord of a living rat at millisecond time scale, free of motion artifacts using an optical stabilization system. We describe a fast, non-contact adaptive movement compensation approach, applicable to rough and weakly reflective surfaces, allowing real-time functional imaging from intrinsically moving tissue in live animals. The strategy involves enslaving the position of the microscope objective to that of the tissue surface in real-time through optical monitoring and a closed feedback loop. The performance of the system allows for efficient image locking even in conditions of random or irregular movements

Fragile Mental Retardation Protein Interacts with the RNA-Binding Protein Caprin1 in Neuronal RiboNucleoProtein Complexes

Fragile X syndrome is caused by the absence of the Fragile X Mental Retardation Protein (FMRP), an RNA-binding protein. FMRP is associated with messenger RiboNucleoParticles (mRNPs) present in polyribosomes and its absence in neurons leads to alteration in synaptic plasticity as a result of translation regulation defects. The molecular mechanisms by which FMRP plays a role in translation regulation remain elusive. Using immunoprecipitation approaches with monoclonal Ab7G1-1 and a new generation of chicken antibodies, we identified Caprin1 as a novel FMRP-cellular partner. In vivo and in vitro evidence show that Caprin1 interacts with FMRP at the level of the translation machinery as well as in trafficking neuronal granules. As an RNA-binding protein, Caprin1 has in common with FMRP at least two RNA targets that have been identified as CaMKIIα and Map1b mRNAs. In view of the new concept that FMRP species bind to RNA regardless of known structural motifs, we propose that protein interactors might modulate FMRP functions

Factors that affect the extension of dendrites and the expression of nicotinic acetylcholine receptors by rat peripheral neurons

The establishment of neuronal polarity constitutes a central phase in neuronal development and synaptogenesis. In my thesis, I study factors that regulate the development of neuronal polarity and its relationship with neurotransmitter receptor expression. For my experiments, I have investigated the development of sensory neurons from neonatal rat nodose ganglia in culture. Sensory neurons have a pseudo-unipolar morphology, do not extend dendrites, and are devoid of synaptic connections on their somata. However, nodose neurons form synapses de novo in cultures, and I show that the neurons have retained the ability to extend dendrites. Extrinsic factors control dendrite extension by these neurons: the ganglionic satellite cells inhibit the growth of dendrites and induce the neurons to develop a unipolar morphology. In the absence of satellite cells, nodose neurons establish a new multipolar morphology and, in response to nerve growth factor (NGF), extend several dendrites. However, brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) do not induce the neurons to extend dendrites, but promote the expression of properties typical of nodose neurons in vivo.As nodose neurons acquire a new dendrite-axonal polarity in the presence of NGF, they increase the density of functional neuronal nicotinic acetylcholine receptors (nAChRs) on their somato-dendritic domains. To learn more about the relationship between dendrites extension and nAChR gene expression, I have examined the changes in transcript levels of nAChR subunits in neonatal rat sympathetic neurons developing in culture. I show that the developmental pattern of nAChR subunit expression in the cultured neurons follows closely that of sympathetic neurons developing in vivo, with the exception of one specific subunit $alpha sb7$. I show that the increase in $alpha sb3$ mRNA levels correlates well with an increase in the density of functional nAChRs on the neurons. In addition, my results suggest that these increases are regulated by mechanisms intrinsic to neonatal sympathetic neurons. On the other hand, the changes in $alpha sb7$ gene expression, which correlate with changes in $alpha$-bungarotoxin binding, are activity-dependent and regulated by a calcium/calmodulin-dependent protein kinase pathway. The results presented in this thesis provide insights on how neurons are influenced in their extension of dendrites and how this extension affects neurotransmitter receptor expression

Sensitivity of CaM kinase II to the frequency of Ca2+ oscillations: A simple model

The rules that govern the activation and autophosphorylation of the multifunctional Ca2+ -calmodulin kinase II (CaMKII) by Ca2+ and calmodulin (CaM) are thought to underlie its ability to decode Ca2+ oscillations and to control multiple cellular functions. We propose a simple biophysical model for the activation of *CaMKII by Ca2+ and calmodulin. The model describes the transition of the subunits of the kinase between their different possible states (inactive, bound to Ca2+ -CaM, phosphorylated at Thr286, trapped and autonomous). All transitions are described by classical kinetic equations except for the autophosphorylation step, which is modeled in an empirical manner. The model quantitatively reproduces the experimentally demonstrated frequency sensitivity of CaMKII [Science 279 (1998) 227]. We further use the model to investigate the role of several characterized features of the kinase - as well as some that are not easily attainable by experiments - in its frequency-dependent responses. In cellular microdomains, CaMKII is expected to sense very brief Ca2+ spikes; our simulations under such conditions reveal that the enzyme response is tuned to optimal frequencies. This prediction is then confirmed by experimental data. This novel and simple model should help in understanding the rules that govern CaMKII regulation, as well as those involved in decoding intracellular Ca2+ signals.info:eu-repo/semantics/publishe