[GDF5: a therapeutic candidate for combating sarcopenia]. / GDF5 - Un candidat thérapeutique dans la lutte contre la sarcopénie.

Sarcopenia is a complex age-related muscular disease affecting 10 to 16 % of people over 65 years old. It is characterized by excessive loss of muscle mass and strength. Despite a plethora of studies aimed at understanding the physiological mechanisms underlying this pathology, the pathophysiology of sarcopenia remains poorly understood. To date, there is no pharmacological treatment for this disease. In this context, our team develop therapeutic approaches based on the GDF5 protein to counteract the loss of muscle mass and function in various pathological conditions, including sarcopenia. After deciphering one of the molecular mechanisms governing GDF5 expression, we have demonstrated the therapeutic potential of this protein in the preservation of muscle mass and strength in aged mice.

Title: GDF5 - Un candidat thérapeutique dans la lutte contre la sarcopénie. Abstract: La sarcopénie est une maladie musculaire complexe liée à l'âge qui affecte entre 10 à 16 % des personnes âgées de plus 65 ans. Elle se caractérise par une perte excessive de la masse musculaire et de la force. Malgré la multitude d'études visant à comprendre les mécanismes physiologiques qui sous-tendent cette pathologie, la physiopathologie de la sarcopénie reste encore mal comprise. A ce jour, il n'existe pas de traitement pharmacologique pour lutter contre cette pathologie. Dans ce contexte, notre équipe développe des approches thérapeutiques basées sur l'utilisation de la protéine GDF5 pour contrecarrer la perte de la masse et de la fonction musculaire dans diverses conditions pathologiques dont la sarcopénie. Après avoir décrypté un des mécanismes moléculaires régulant l'expression du GDF5, nous avons démontré le potentiel thérapeutique de cette protéine dans la préservation de la masse et la force musculaire chez les souris âgées.

New Insights in CaVß Subunits: Role in the Regulation of Gene Expression and Cellular Homeostasis.

The voltage-gated calcium channels (CaVs or VGCCs) are fundamental regulators of intracellular calcium homeostasis. When electrical activity induces their activation, the influx of calcium that they mediate or their interaction with intracellular players leads to changes in intracellular Ca2+ levels which regulate many processes such as contraction, secretion and gene expression, depending on the cell type. The essential component of the pore channel is the CaVα1 subunit. However, the fine-tuning of Ca2+-dependent signals is guaranteed by the modulatory role of the auxiliary subunits ß, α2δ, and γ of the CaVs. In particular, four different CaVß proteins (CaVß1, CaVß2, CaVß3, and CaVß4) are encoded by four different genes in mammalians, each of them displaying several splice variants. Some of these isoforms have been described in regulating CaVα1 docking and stability at the membrane and controlling the channel complex's conformational changes. In addition, emerging evidences have highlighted other properties of the CaVß subunits, independently of α1 and non-correlated to its channel or voltage sensing functions. This review summarizes the recent findings reporting novel roles of the auxiliary CaVß subunits and in particular their direct or indirect implication in regulating gene expression in different cellular contexts.

Lkb1 suppresses amino acid-driven gluconeogenesis in the liver.

Excessive glucose production by the liver is a key factor in the hyperglycemia observed in type 2 diabetes mellitus (T2DM). Here, we highlight a novel role of liver kinase B1 (Lkb1) in this regulation. We show that mice with a hepatocyte-specific deletion of Lkb1 have higher levels of hepatic amino acid catabolism, driving gluconeogenesis. This effect is observed during both fasting and the postprandial period, identifying Lkb1 as a critical suppressor of postprandial hepatic gluconeogenesis. Hepatic Lkb1 deletion is associated with major changes in whole-body metabolism, leading to a lower lean body mass and, in the longer term, sarcopenia and cachexia, as a consequence of the diversion of amino acids to liver metabolism at the expense of muscle. Using genetic, proteomic and pharmacological approaches, we identify the aminotransferases and specifically Agxt as effectors of the suppressor function of Lkb1 in amino acid-driven gluconeogenesis.

An embryonic CaVß1 isoform promotes muscle mass maintenance via GDF5 signaling in adult mouse.

Deciphering the mechanisms that govern skeletal muscle plasticity is essential to understand its pathophysiological processes, including age-related sarcopenia. The voltage-gated calcium channel CaV1.1 has a central role in excitation-contraction coupling (ECC), raising the possibility that it may also initiate the adaptive response to changes during muscle activity. Here, we revealed the existence of a gene transcription switch of the CaV1.1 ß subunit (CaVß1) that is dependent on the innervation state of the muscle in mice. In a mouse model of sciatic denervation, we showed increased expression of an embryonic isoform of the subunit that we called CaVß1E. CaVß1E boosts downstream growth differentiation factor 5 (GDF5) signaling to counteract muscle loss after denervation in mice. We further reported that aged mouse muscle expressed lower quantity of CaVß1E compared with young muscle, displaying an altered GDF5-dependent response to denervation. Conversely, CaVß1E overexpression improved mass wasting in aging muscle in mice by increasing GDF5 expression. We also identified the human CaVß1E analogous and show a correlation between CaVß1E expression in human muscles and age-related muscle mass decline. These results suggest that strategies targeting CaVß1E or GDF5 might be effective in reducing muscle mass loss in aging.

LKB1 signaling is activated in CTNNB1-mutated HCC and positively regulates ß-catenin-dependent CTNNB1-mutated HCC.

Hepatocellular carcinomas (HCCs) are known to be highly heterogenous. Within the extensive histopathological and molecular heterogeneity of HCC, tumors with mutations in CTNNB1, encoding ß-catenin (CTNNB1-mutated HCC), constitute a very homogeneous group. We previously characterized a distinctive metabolic and histological phenotype for CTNNB1-mutated HCC. They were found to be well-differentiated, almost never steatotic, and often cholestatic, with a microtrabecular or acinar growth pattern. Here, we investigated whether LKB1, which controls energy metabolism, cell polarity, and cell growth, mediates the specific phenotype of CTNNB1-mutated HCC. The LKB1 protein was overexpressed in CTNNB1-mutated HCC and oncogenic activation of ß-catenin in human HCC cells induced the post-transcriptional accumulation of the LKB1 protein encoded by the LKB1 (STK11) gene. Hierarchical clustering, based on the expression of a murine hepatic liver Lkb1 (Stk11) signature in a human public dataset, identified a HCC cluster, composed of almost all the CTNNB1-mutated HCC, that expresses a hepatic liver LKB1 program. This was confirmed by RT-qPCR of an independent cohort of CTNNB1-mutated HCC and the suppression of the LKB1-related profile upon ß-catenin silencing of CTNNB1-mutated human hepatoma cell lines. Previous studies described an epistatic relationship between LKB1 and CTNNB1 in which LKB1 acts upstream of CTNNB1. Thus, we also analyzed the consequences of Lkb1 deletion on the zonation of hepatic metabolism, known to be the hallmark of ß-catenin signaling in the liver. Lkb1 was required for the establishment of metabolic zonation in the mouse liver by positively modulating ß-catenin signaling. We identified positive reciprocal cross talk between the canonical Wnt pathway and LKB1, both in normal liver physiology and during tumorigenesis that likely participates in the amplification of the ß-catenin signaling by LKB1 and the distinctive phenotype of the CTNNB1-mutated HCC. Copyright © 2018 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.

LKB1 and Notch Pathways Interact and Control Biliary Morphogenesis.

BACKGROUND: LKB1 is an evolutionary conserved kinase implicated in a wide range of cellular functions including inhibition of cell proliferation, regulation of cell polarity and metabolism. When Lkb1 is inactivated in the liver, glucose homeostasis is perturbed, cellular polarity is affected and cholestasis develops. Cholestasis occurs as a result from deficient bile duct development, yet how LKB1 impacts on biliary morphogenesis is unknown. METHODOLOGY/PRINCIPAL FINDINGS: We characterized the phenotype of mice in which deletion of the Lkb1 gene has been specifically targeted to the hepatoblasts. Our results confirmed that lack of LKB1 in the liver results in bile duct paucity leading to cholestasis. Immunostaining analysis at a prenatal stage showed that LKB1 is not required for differentiation of hepatoblasts to cholangiocyte precursors but promotes maturation of the primitive ductal structures to mature bile ducts. This phenotype is similar to that obtained upon inactivation of Notch signaling in the liver. We tested the hypothesis of a functional overlap between the LKB1 and Notch pathways by gene expression profiling of livers deficient in Lkb1 or in the Notch mediator RbpJκ and identified a mutual cross-talk between LKB1 and Notch signaling. In vitro experiments confirmed that Notch activity was deficient upon LKB1 loss. CONCLUSION: LKB1 and Notch share a common genetic program in the liver, and regulate bile duct morphogenesis.