N-acetylcysteine treatment ameliorates the skeletal phenotype of a mouse model of diastrophic dysplasia.

Diastrophic dysplasia (DTD) is a recessive chondrodysplasia caused by mutations in SLC26A2, a cell membrane sulfate-chloride antiporter. Sulfate uptake impairment results in low cytosolic sulfate, leading to cartilage proteoglycan (PG) undersulfation. In this work, we used the dtd mouse model to study the role of N-acetyl-l-cysteine (NAC), a well-known drug with antioxidant properties, as an intracellular sulfate source for macromolecular sulfation. Because of the important pre-natal phase of skeletal development and growth, we administered 30 g/l NAC in the drinking water to pregnant mice to explore a possible transplacental effect on the fetuses. When cartilage PG sulfation was evaluated by high-performance liquid chromatography disaccharide analysis in dtd newborn mice, a marked increase in PG sulfation was observed in newborns from NAC-treated pregnancies when compared with the placebo group. Morphometric studies of the femur, tibia and ilium after skeletal staining with alcian blue and alizarin red indicated a partial rescue of abnormal bone morphology in dtd newborns from treated females, compared with pups from untreated females. The beneficial effect of increased macromolecular sulfation was confirmed by chondrocyte proliferation studies in cryosections of the tibial epiphysis by proliferating cell nuclear antigen immunohistochemistry: the percentage of proliferating cells, significantly reduced in the placebo group, reached normal values in dtd newborns from NAC-treated females. In conclusion, NAC is a useful source of sulfate for macromolecular sulfation in vivo when extracellular sulfate supply is reduced, confirming the potential of therapeutic approaches with thiol compounds to improve skeletal deformity and short stature in human DTD and related disorders.

Contribution of estrogen and GluN2B subunit to the HtraKO mouse phenotype

Htr1a is one of the most widespread serotonin receptor across the brain, strongly expressed in CAI region of hippocampus. Our laboratory studies the phenotypic alteration in 5HTla- deficient mice (Htr1aK0), characterized an abnormal anxious-like behavior. Our aim is to evaluate the regulation of this cognitive process by understanding the circuitry involved. This phenotype sets up early during development and has durable effect in adulthood. Our laboratory showed that adult Htr1aK0 male mice displaying exuberant dendritic growth of oblique dendrites in a specific layer of a CAI pyramidal neurons, the stratum radiatum. Application of drugs in organotypic cultures and by in vivo injections revealed that GluN2B, a subunit of NMDA receptor highly expressed during development, is responsible for this dendritic exuberance. Immunohistochemistry highlighted in particular a synaptic enrichment of GluN2B in stratum radiatum of Htr1aK0 CAI pyramidal neurons at puberty. Finally, original analysis of Htr1aK0 mouse behavior showed a different response to anxiety between male and female. Htr1a activation down-regulates the CaMKII activity in the CAI pyramidal neurons. CaMKII directly favors the membrane conductance and stability of GluN2B at the synapse. In the context of the Htr1aK0 mouse, GluN2B is the final common pathway of our phenotype. This subunit is well known to regulate the threshold of LTD/LTP and the dendritogenesis during development. In my thesis, I establish a link between the gender differences in the morphology and the physiology in the Htr1aK0 mice during development to understand how these characteristics shape the circuit with prominent cognitive impacts in adulthood. My study highlighted that during development, Htr1aK0 male mice show a constant increase of the dendritic growth of oblique dendrites from early ages until adulthood associated with an increased physiological impact of altered GluN2A/GluN2B ratio. Whereas during puberty, synaptic contribution of GluN2B to NMDA response is higher in Htr1aK0 compared to WT male mice, this ratio comes back to normal values towards adulthood. However, this recovery of the ratio of GluN2A/GluN2B located at the synaptic level is concomitant with the lateral diffusion of excess GluN2B subunits, leading to extrasynaptic enrichment. The main impact was a lowering of the LTP threshold characterized by strong increased potentiation of synaptic strength after 5 Hz low frequency stimulation. Moreover, the extrasynaptic GluN2B overexpression leads to a shift of the maturation phase switch explaining the exuberant morphology. However, Htr1aK0 females characterized during the 3 first weeks of development by an increase of the dendritic growth of oblique dendrites showed starting at puberty that the dendrite arborization returns progressively to WT values. The physiological impact of GluN2B was investigated and directly linked to this morphology, since Htr1aK0 female mice does not show alteration of the synaptic strength during development. These observations show a compensation occurring in Htr1aK0 female, responsible for a rescue of the phenotype morphologically, physiologically and to be tested behaviorally. We highlighted then the biological processes underlying this compensation. During development, sexual hormones such as testosterone and estrogen are responsible to induce sexual differentiation of specific brain regions. I demonstrated that estrogen, but not testosterone, was able to reduce both in vitro and in vivo the dendritic arborization early during development, through activation of GPER-1, a G-coupled protein estrogen receptor, which phenocopy the activation of Htr1a by reducing GluN2B conductance and stability. I then identified a pathway, parallel to Htr1a, able to regulate GluN2B and responsible for the morphological and physiological phenotype in Htr1aK0 female mice. The specific rise of estrogen occurring at puberty in female is responsible for the compensation observed and induces a late rescue of the Htr1aK0 phenotype by activation GPER-1. -- Htr1a est un des récepteurs à la sérotonine les plus répandus dans le cerveau, fortement exprimé dans la région CAI de l'hippocampe. Notre laboratoire étudie les altérations phénotypiques de souris déficientes pour ce récepteur (Htr1aK0), caractérisées par un comportement avec des traits anxieux. Notre objectif est d'évaluer la régulation de ces processus cognitifs en comprenant les connexions nerveuses impliquées. Ce phénotype se met en place tôt au cours du développement et présente un effet durable à l'âge adulte. Notre laboratoire a montré que les souris Htr1aK0 mâles adultes se caractérisent par une croissance exubérante des dendrites obliques dans une couche spécifique des neurones pyramidaux du CAI, le stratum radiatum. L'application de drogues sur cultures organotypiques et par injections in vivo ont révélé que GluN2B, une sous-unité du récepteur NMDA fortement exprimée au cours du développement, est responsable de cette exubérance dendritique. Des expériences d'immunohistochimie ont notamment mis en évidence un enrichissement synaptique de GluN2B durant la puberté dans le stratum radiatum des neurones de la région CAI des souris Htr1aK0. Finalement, l'analyse originale du comportement des souris Htr1aK0 a montré une différence de réponse à l'anxiété entre mâles et femelles. L'activation de Htr1a diminue l'activité de la CaMKII dans les neurones pyramidaux du CAI. La CaMKII favorise directement la conductance et la stabilité de la sous-unité GluN2B à la synapse. Dans le contexte de la souris Htr1aK0, GluN2B est le « médiateur » de notre phénotype. Cette sous-unité est particulièrement connue pour réguler le seuil de LTD-LTP ainsi que la dendritogénèse durant le développement. Dans ma thèse, j'ai établi le lien entre les différences dépendant du genre dans la morphologie et physiologie des souris Htr1aK0 au cours du développement pour comprendre comment ces caractéristiques modulent le circuit accompagnés d'impacts cognitifs visibles à l'âge adulte. Mon étude a mis en évidence que durant le développement, les souris mâles Htr1aK0 montrent une constante augmentation de la croissance des dendrites obliques entre les premières semaines et l'âge adulte associée à une augmentation de l'impact physiologique du ratio GluN2A/GluN2B altéré. Alors que durant la puberté, la contribution synaptique de GluN2B à la réponse NMDA est plus haute chez la souris mâle Htr1aK0 que le WT, ce ratio revient à des valeurs normales à l'âge adulte. Cependant, cette récupération de l'expression du récepteur au niveau synaptique est concomitante avec la diffusion des sous-unités GluN2B excédantes, amenant alors à un enrichissement extrasynaptique. Le principal impact est une diminution du seuil de la LTP caractérisée par une forte potentiation de la plasticité après une stimulation basse fréquence à 5 Hz. De plus, la surexpression des GluN2B extrasynaptiques conduit à un décalage de la bascule à la phase de maturation, expliquant la morphologie dendritique exubérante. Cependant, les femelles Htr1aK0 initialement caractérisées pendant les 3 premières semaines du développement par une augmentation de la croissance des dendrites obliques montrent à partir de la puberté que cette arborisation dendritique retourne à des valeurs WT. L'impact physiologique de GLuN2B a été investigué et mis en lien avec cette morphologie, étant donné que les femelles Htr1aK0 ne montrent pas d'altération de la plasticité durant le développement. Ces observations montrent une compensation se produisant chez la femelle Htr1aK0, responsable d'une récupération du phénotype morphologique, physiologique et peut-être comportemental. Nous avons souligné les processus biologiques sous-jacent à cette compensation. Au cours du développement, les hormones sexuelles telles que la testostérone et l'estrogène sont responsables de la différentiation sexuelle de régions du cerveau spécifiques. J'ai démontré que l'estrogène, mais pas la testostérone, était capable de réduire in vitro et in vivo l'arborisation dendritique tôt dans le développement au travers de l'activation du récepteur GPER-1, un récepteur aux estrogènes couplés à un protéine G, qui phénocopie l'activation de Htr1a en réduisant la conductance et la stabilité de GluN2B à la membrane. J'ai identifié une voie de signalisation parallèle à celle de Htr1a, capable de réguler GluN2B et responsable du phénotype morphologique et physiologique de la souris femelle Htr1aK0. La montée spécifique d'estrogène se déroulant à la puberté chez la femelle est responsable de cette compensation et implique une récupération tardive du phénotype Htr1aK0 par l'activation de GPER-1.

Circadian and feeding rhythms differentially affect rhythmic mRNA transcription and translation in mouse liver.

Diurnal oscillations of gene expression are a hallmark of rhythmic physiology across most living organisms. Such oscillations are controlled by the interplay between the circadian clock and feeding rhythms. Although rhythmic mRNA accumulation has been extensively studied, comparatively less is known about their transcription and translation. Here, we quantified simultaneously temporal transcription, accumulation, and translation of mouse liver mRNAs under physiological light-dark conditions and ad libitum or night-restricted feeding in WT and brain and muscle Arnt-like 1 (Bmal1)-deficient animals. We found that rhythmic transcription predominantly drives rhythmic mRNA accumulation and translation for a majority of genes. Comparison of wild-type and Bmal1 KO mice shows that circadian clock and feeding rhythms have broad impact on rhythmic gene expression, Bmal1 deletion affecting surprisingly both transcriptional and posttranscriptional levels. Translation efficiency is differentially regulated during the diurnal cycle for genes with 5'-Terminal Oligo Pyrimidine tract (5'-TOP) sequences and for genes involved in mitochondrial activity, many harboring a Translation Initiator of Short 5'-UTR (TISU) motif. The increased translation efficiency of 5'-TOP and TISU genes is mainly driven by feeding rhythms but Bmal1 deletion also affects amplitude and phase of translation, including TISU genes. Together this study emphasizes the complex interconnections between circadian and feeding rhythms at several steps ultimately determining rhythmic gene expression and translation.

Tgfbi/Bigh3 silencing activates ERK in mouse retina.

BIGH3 is a secreted protein, part of the extracellular matrix where it interacts with collagen and integrins on the cell surface. BIGH3 can play opposing roles in cancer, acting as either tumor suppressor or promoter, and its mutations lead to different forms of corneal dystrophy. Although many studies have been carried out, little is known about the physiological role of BIGH3. Using the cre-loxP system, we generated a mouse model with disruption of the Bigh3 genomic locus. Bigh3 silencing did not result in any apparent phenotype modifications, the mice remained viable and fertile. We were able to determine the presence of BIGH3 in the retinal pigment epithelium (RPE). In the absence of BIGH3, a transient decrease in the apoptotic process involved in retina maturation was observed, leading to a transient increase in the INL thickness at P15. This phenomenon was accompanied by an increased activity of the pro-survival ERK pathway.

Development of a systematic computer vision-based method to analyse and compare images of false identity documents for forensic intelligence purposes-Part I: acquisition, calibration and validation issues

Following their detection and seizure by police and border guard authorities, false identity and travel documents are usually scanned, producing digital images. This research investigates the potential of these images to classify false identity documents, highlight links between documents produced by a same modus operandi or same source, and thus support forensic intelligence efforts. Inspired by previous research work about digital images of Ecstasy tablets, a systematic and complete method has been developed to acquire, collect, process and compare images of false identity documents. This first part of the article highlights the critical steps of the method and the development of a prototype that processes regions of interest extracted from images. Acquisition conditions have been fine-tuned in order to optimise reproducibility and comparability of images. Different filters and comparison metrics have been evaluated and the performance of the method has been assessed using two calibration and validation sets of documents, made up of 101 Italian driving licenses and 96 Portuguese passports seized in Switzerland, among which some were known to come from common sources. Results indicate that the use of Hue and Edge filters or their combination to extract profiles from images, and then the comparison of profiles with a Canberra distance-based metric provides the most accurate classification of documents. The method appears also to be quick, efficient and inexpensive. It can be easily operated from remote locations and shared amongst different organisations, which makes it very convenient for future operational applications. The method could serve as a first fast triage method that may help target more resource-intensive profiling methods (based on a visual, physical or chemical examination of documents for instance). Its contribution to forensic intelligence and its application to several sets of false identity documents seized by police and border guards will be developed in a forthcoming article (part II).

In Vivo Longitudinal (1)H MRS Study of Transgenic Mouse Models of Prion Disease in the Hippocampus and Cerebellum at 14.1 T.

In vivo (1)H MR spectroscopy allows the non invasive characterization of brain metabolites and it has been used for studying brain metabolic changes in a wide range of neurodegenerative diseases. The prion diseases form a group of fatal neurodegenerative diseases, also described as transmissible spongiform encephalopathies. The mechanism by which prions elicit brain damage remains unclear and therefore different transgenic mouse models of prion disease were created. We performed an in vivo longitudinal (1)H MR spectroscopy study at 14.1 T with the aim to measure the neurochemical profile of Prnp -/- and PrPΔ32-121 mice in the hippocampus and cerebellum. Using high-field MR spectroscopy we were able to analyze in details the in vivo brain metabolites in Prnp -/- and PrPΔ32-121 mice. An increase of myo-inositol, glutamate and lactate concentrations with a decrease of N-acetylaspartate concentrations were observed providing additional information to the previous measurements.

Characterization of a MAF1 knockout mouse model

L'ARN polymérase 3 transcrit un petit groupe de gènes fortement exprimés et impliqués dans plusieurs mécanismes moléculaires. Les ARNs de transfert ou ARNt représentent plus ou moins la moitié du transcriptome de l'ARN polymérase 3. Ils sont directement impliqués dans la traduction des protéines en agissant comme transporteurs d'acides aminés qui sont incorporés à la chaîne naissante de polypeptides. Chez des levures cultivées dans un milieu jusqu'à épuisement des nutriments, Maf1 réprime la transcription par l'ARN polymérase 3, favorisant ainsi l'économie énergétique cellulaire. Dans un modèle de cellules de mammifères, MAF1 réprime aussi la transcription de l'ARN polymérase 3 dans des conditions de stress, cependant il n'existe aucune donnée quant à son rôle chez un mammifère vivant. Pendant mon doctorat, j'ai utilisé une souris délétée pour le gène Maf1 afin de connaître les effets de ce gène chez un mammifère. Etonnamment, la souris Maf1-­‐/-­‐ est résistante à l'obésité même si celle-­‐ci est nourrie avec une nourriture riche en matières grasses. Des études moléculaires et de métabolomiques ont montré qu'il existe des cycles futiles de production et dégradation des lipides et des ARNt, ce qui entraîne une augmentation de la dépense énergique et favorise la résistance à l'obésité. En plus de la caractérisation de la souris Maf1-­‐/-­‐, pendant ma thèse j'ai également développé une méthode afin de normaliser les données de ChIP-­‐sequencing. Cette méthode est fondée sur l'utilisation d'un contrôle interne, représenté ici par l'ajout d'une quantité fixe de chromatine provenant d'un organisme différent de celui étudié. La méthode a amélioré considérablement la reproductibilité des valeurs entre réplicas biologiques. Elle a aussi révélé des différences entre échantillons issus de conditions différentes. Une occupation supérieure de l'ARN polymérase 3 sur les gènes Pol 3 chez les souris Maf1 KO entraîne une augmentation du niveau de précurseurs d'ARNt, ayant pour effet probable la saturation de la machinerie de maturation des ARNt. En effet, chez les souris Maf1 KO, le pourcentage d'ARNt modifiés est plus faible que chez les souris type sauvage. Ce déséquilibre entre le niveau de précurseurs et d'ARNt matures entraîne une diminution de la traduction protéique. Ces résultats ont permis d'identifier de nouvelles fonctions pour la protéine MAF1, comme étant une protéine régulatrice à la fois de la transcription mais aussi de la traduction et en étant un cible potentielle au traitement à l'obésité. -- RNA polymerase III (Pol 3) transcribes a small set of highly expressed genes involved in different molecular mechanisms. tRNAs account for almost half of the Pol 3 transcriptome and are involved in translation, bringing a new amino into the nascent polypeptide chain. In yeast, under nutrient deprivation, Maf1 acts for cell energetic economy by repressing Pol 3 transcription. In mammalian cells, MAF1 also represses Pol 3 activity under conditions of serum deprivation or DNA damages but nothing is known about its role in a mammalian organism. During my thesis studies, I used a Maf1 KO mouse model to characterize the effects of Maf1 deletion in a living animal. Surprisingly, the MAF1 KO mouse developed an unexpected phenotype, being resistant to high fat diet-­‐induced obesity and displaying an extended lifespan. Molecular and metabolomics characterizations revealed futile cycles of lipids and tRNAs, which are produced and immediately degraded, which increases energy consumption in the Maf1 KO mouse and probably explains in part the protection to obesity. Additionally to the mouse characterization, I also developed a method to normalize ChIP-­‐seq data, based on the addition of a foreign chromatin to be used as an internal control. The method improved reproducibility between replicates and revealed differences of Pol 3 occupancy between WT and Maf1 KO samples that were not seen without normalization to the internal control. I then established that increased Pol 3 occupancy in the Maf1 KO mouse liver was associated with increased levels of tRNA precursor but not of mature tRNAs, the effective molecules involved in translation. The overproduction of precursor tRNAs associated with the deletion of Maf1 apparently overwhelms the tRNA processing machinery as the Maf1 KO mice have lower levels of fully modified tRNAs. This maturation defect directly impacts on translation efficiency as polysomic fractions and newly synthetized protein levels were reduced in the liver of the Maf1 KO mouse. Altogether, these results indicate new functions for MAF1, a regulator of both transcription and translation as well as a potential target for obesity treatment.

Mouse Model of Respiratory Tract Infection Induced by Waddlia chondrophila.

Waddlia chondrophila, an obligate intracellular bacterium belonging to the Chlamydiales order, is considered as an emerging pathogen. Some clinical studies highlighted a possible role of W. chondrophila in bronchiolitis, pneumonia and miscarriage. This pathogenic potential is further supported by the ability of W. chondrophila to infect and replicate within human pneumocytes, macrophages and endometrial cells. Considering that W. chondrophila might be a causative agent of respiratory tract infection, we developed a mouse model of respiratory tract infection to get insight into the pathogenesis of W. chondrophila. Following intranasal inoculation of 2 x 108 W. chondrophila, mice lost up to 40% of their body weight, and succumbed rapidly from infection with a death rate reaching 50% at day 4 post-inoculation. Bacterial loads, estimated by qPCR, increased from day 0 to day 3 post-infection and decreased thereafter in surviving mice. Bacterial growth was confirmed by detecting dividing bacteria using electron microscopy, and living bacteria were isolated from lungs 14 days post-infection. Immunohistochemistry and histopathology of infected lungs revealed the presence of bacteria associated with pneumonia characterized by an important multifocal inflammation. The high inflammatory score in the lungs was associated with the presence of pro-inflammatory cytokines in both serum and lungs at day 3 post-infection. This animal model supports the role of W. chondrophila as an agent of respiratory tract infection, and will help understanding the pathogenesis of this strict intracellular bacterium.

Biological Characterization of Gene Response to Insulin-Induced Hypoglycemia in Mouse Retina.

Glucose is the most important metabolic substrate of the retina and maintenance of normoglycemia is an essential challenge for diabetic patients. Chronic, exaggerated, glycemic excursions could lead to cardiovascular diseases, nephropathy, neuropathy and retinopathy. We recently showed that hypoglycemia induced retinal cell death in mouse via caspase 3 activation and glutathione (GSH) decrease. Ex vivo experiments in 661W photoreceptor cells confirmed the low-glucose induction of death via superoxide production and activation of caspase 3, which was concomitant with a decrease of GSH content. We evaluate herein retinal gene expression 4 h and 48 h after insulin-induced hypoglycemia. Microarray analysis demonstrated clusters of genes whose expression was modified by hypoglycemia and we discuss the potential implication of those genes in retinal cell death. In addition, we identify by gene set enrichment analysis, three important pathways, including lysosomal function, GSH metabolism and apoptotic pathways. Then we tested the effect of recurrent hypoglycemia (three successive 4h periods of hypoglycemia spaced by 48 h recovery) on retinal cell death. Interestingly, exposure to multiple hypoglycemic events prevented GSH decrease and retinal cell death, or adapted the retina to external stress by restoring GSH level comparable to control situation. We hypothesize that scavenger GSH is a key compound in this apoptotic process, and maintaining "normal" GSH level, as well as a strict glycemic control, represents a therapeutic challenge in order to avoid side effects of diabetes, especially diabetic retinopathy.

Analyzing the temporal regulation of translation efficiency in mouse liver.

Mammalian physiology and behavior follow daily rhythms that are orchestrated by endogenous timekeepers known as circadian clocks. Rhythms in transcription are considered the main mechanism to engender rhythmic gene expression, but important roles for posttranscriptional mechanisms have recently emerged as well (reviewed in Lim and Allada (2013) [1]). We have recently reported on the use of ribosome profiling (RPF-seq), a method based on the high-throughput sequencing of ribosome protected mRNA fragments, to explore the temporal regulation of translation efficiency (Janich et al., 2015 [2]). Through the comparison of around-the-clock RPF-seq and matching RNA-seq data we were able to identify 150 genes, involved in ribosome biogenesis, iron metabolism and other pathways, whose rhythmicity is generated entirely at the level of protein synthesis. The temporal transcriptome and translatome data sets from this study have been deposited in NCBI's Gene Expression Omnibus under the accession number GSE67305. Here we provide additional information on the experimental setup and on important optimization steps pertaining to the ribosome profiling technique in mouse liver and to data analysis.

Reciprocal Effects on Neurocognitive and Metabolic Phenotypes in Mouse Models of 16p11.2 Deletion and Duplication Syndromes.

The 16p11.2 600 kb BP4-BP5 deletion and duplication syndromes have been associated with developmental delay; autism spectrum disorders; and reciprocal effects on the body mass index, head circumference and brain volumes. Here, we explored these relationships using novel engineered mouse models carrying a deletion (Del/+) or a duplication (Dup/+) of the Sult1a1-Spn region homologous to the human 16p11.2 BP4-BP5 locus. On a C57BL/6N inbred genetic background, Del/+ mice exhibited reduced weight and impaired adipogenesis, hyperactivity, repetitive behaviors, and recognition memory deficits. In contrast, Dup/+ mice showed largely opposite phenotypes. On a F1 C57BL/6N × C3B hybrid genetic background, we also observed alterations in social interaction in the Del/+ and the Dup/+ animals, with other robust phenotypes affecting recognition memory and weight. To explore the dosage effect of the 16p11.2 genes on metabolism, Del/+ and Dup/+ models were challenged with high fat and high sugar diet, which revealed opposite energy imbalance. Transcriptomic analysis revealed that the majority of the genes located in the Sult1a1-Spn region were sensitive to dosage with a major effect on several pathways associated with neurocognitive and metabolic phenotypes. Whereas the behavioral consequence of the 16p11 region genetic dosage was similar in mice and humans with activity and memory alterations, the metabolic defects were opposite: adult Del/+ mice are lean in comparison to the human obese phenotype and the Dup/+ mice are overweight in comparison to the human underweight phenotype. Together, these data indicate that the dosage imbalance at the 16p11.2 locus perturbs the expression of modifiers outside the CNV that can modulate the penetrance, expressivity and direction of effects in both humans and mice.