Recruitment of Matrix Metalloproteinase-9 (MMP-9) to the Fibroblast Cell Surface by Lysyl Hydroxylase 3 (LH3) Triggers Transforming Growth Factor-β (TGF-β) Activation and Fibroblast Differentiation.

Solid tumor growth triggers a wound healing response. Similar to wound healing, fibroblasts in the tumor stroma differentiate into myofibroblasts (also referred to as cancer-associated fibroblasts) primarily, but not exclusively, in response to transforming growth factor-β (TGF-β). Myofibroblasts in turn enhance tumor progression by remodeling the stroma. Among proteases implicated in stroma remodeling, matrix metalloproteinases (MMPs), including MMP-9, play a prominent role. Recent evidence indicates that MMP-9 recruitment to the tumor cell surface enhances tumor growth and invasion. In the present work, we addressed the potential relevance of MMP-9 recruitment to and activity at the surface of fibroblasts. We show that recruitment of MMP-9 to the fibroblast cell surface occurs through its fibronectin-like (FN) domain and that the molecule responsible for the recruitment is lysyl hydroxylase 3 (LH3). Functional assays suggest that both pro- and active MMP-9 trigger α-smooth muscle actin expression in cultured fibroblasts, reflecting myofibroblast differentiation, possibly as a result of TGF-β activation. Moreover, the recombinant FN domain inhibited both MMP-9-induced TGF-β activation and α-smooth muscle actin expression by displacing MMP-9 from the fibroblast cell surface. Together our results uncover LH3 as a new docking receptor of MMP-9 on the fibroblast cell surface and demonstrate that the MMP-9 FN domain is essential for the interaction. They also show that the recombinant FN domain inhibits MMP-9-induced TGF-β activation and fibroblast differentiation, providing a potentially attractive therapeutic reagent toward attenuating tumor progression where MMP-9 activity is strongly implicated.

Lack of GDAP1 induces neuronal calcium and mitochondrial defects in a knockout mouse model of charcot-marie-tooth neuropathy.

Mutations in GDAP1, which encodes protein located in the mitochondrial outer membrane, cause axonal recessive (AR-CMT2), axonal dominant (CMT2K) and demyelinating recessive (CMT4A) forms of Charcot-Marie-Tooth (CMT) neuropathy. Loss of function recessive mutations in GDAP1 are associated with decreased mitochondrial fission activity, while dominant mutations result in impairment of mitochondrial fusion with increased production of reactive oxygen species and susceptibility to apoptotic stimuli. GDAP1 silencing in vitro reduces Ca2+ inflow through store-operated Ca2+ entry (SOCE) upon mobilization of endoplasmic reticulum (ER) Ca2+, likely in association with an abnormal distribution of the mitochondrial network. To investigate the functional consequences of lack of GDAP1 in vivo, we generated a Gdap1 knockout mouse. The affected animals presented abnormal motor behavior starting at the age of 3 months. Electrophysiological and biochemical studies confirmed the axonal nature of the neuropathy whereas histopathological studies over time showed progressive loss of motor neurons (MNs) in the anterior horn of the spinal cord and defects in neuromuscular junctions. Analyses of cultured embryonic MNs and adult dorsal root ganglia neurons from affected animals demonstrated large and defective mitochondria, changes in the ER cisternae, reduced acetylation of cytoskeletal α-tubulin and increased autophagy vesicles. Importantly, MNs showed reduced cytosolic calcium and SOCE response. The development and characterization of the GDAP1 neuropathy mice model thus revealed that some of the pathophysiological changes present in axonal recessive form of the GDAP1-related CMT might be the consequence of changes in the mitochondrial network biology and mitochondria-endoplasmic reticulum interaction leading to abnormalities in calcium homeostasis.

Review of quantitative phase-digital holographic microscopy: promising novel imaging technique to resolve neuronal network activity and identify cellular biomarkers of psychiatric disorders.

Quantitative phase microscopy (QPM) has recently emerged as a new powerful quantitative imaging technique well suited to noninvasively explore a transparent specimen with a nanometric axial sensitivity. In this review, we expose the recent developments of quantitative phase-digital holographic microscopy (QP-DHM). Quantitative phase-digital holographic microscopy (QP-DHM) represents an important and efficient quantitative phase method to explore cell structure and dynamics. In a second part, the most relevant QPM applications in the field of cell biology are summarized. A particular emphasis is placed on the original biological information, which can be derived from the quantitative phase signal. In a third part, recent applications obtained, with QP-DHM in the field of cellular neuroscience, namely the possibility to optically resolve neuronal network activity and spine dynamics, are presented. Furthermore, potential applications of QPM related to psychiatry through the identification of new and original cell biomarkers that, when combined with a range of other biomarkers, could significantly contribute to the determination of high risk developmental trajectories for psychiatric disorders, are discussed.

The role of Notch receptor signaling in T helper 17 cell differentiation

Antigenic recognition by naive CD4+ T cells induces their proliferation and differentiation into functionally distinct T helper (Th) cell. Each CD4+ Th cell subset expresses specific transcription factors and produces signature cytokines that coordinate immune responses against encountered pathogens. Among the factors influencing CD4+ Th cell differentiation, Notch signaling pathway has been reported to play a role in the differentiation and function of multiple CD4+Thcell subsets. Notch signaling is an evolutionarily conserved cell-to-cell signaling cascade involved in many cell fate decision processes. How Notch signaling modulates the differentiation of CD4+ Th cell subsets and whether Notch signaling alone is sufficient or not for the differentiation of CD4+ Th cells is still a matter of debate. Th17 cells are a distinct subset of CD4+ Th cells. They play a role in the control of extracellular bacterial and fungal infections and may lead to inflammatory and autoimmune diseases if not properly regulated. Th17 cells are defined by the expression of RAR-related orphan receptor (ROR)a and RORyT transcription factors and their secretion of IL-17A, IL-17F cytokines. The involvement of Notch signaling in Th17 cell differentiation has mostly been studied in vitro. However, neither the experimental conditions when Notch signaling might be involved in Th17 cell differentiation in vitro and in vivo nor the precise role of Notch in this process remain clear. To better define how Notch signaling impacts Th17 differentiation, we used mice with T cell specific ablation of Notchl and Notch2 (N1 N2ACD4Cre) or of Notch transcriptional repressor RBP- JK (RBP-J ACD4Cre). We show that impaired Notch signaling in T cells, when TCR activating signal were reduced, increased RORyT and IL-17 mRNA levels during in vitro Th17 cell differentiation. Following immunization with OVA in CFA, an adjuvant that induces mostly Th17 cell response, increased IL-17A mRNA and intracellular IL-17A levels were observed in draining lymph nodes of Notch-deficient CD4+T cells. Our data suggest that Notch limited Th17 cell differentiation. Despite high levels of IL-17 mRNA and intracellular IL-17 proteins observed in Notch-deficient T cells, their release of Th17 cytokines ex vivo was markedly decreased, indicating a role for Notch signaling. During the second part of this thesis, we observed that the impact of Notch on Th17 cell differentiation and effector functions was context-dependent using different in vivo experimental models, in which Th17 cells and IL-17A were reported to contribute in the disease development. Collectively, our data reveal that Notch signaling controls the fine-tuning of Th17 cell differentiation and effector functions by limiting their differentiation but promoting selectively cytokine release through Notch-dependent mechanisms that still need to be defined. -- Lors d'une réponse immunitaire et grâce à la reconnaissance antigénique, les lymphocytes CD4+ T naïfs prolifèrent, puis se différencient en CD4+ T auxiliaires ("T helper" ou Th) fonctionnellement distincts. Chaque sous-population de lymphocytes CD4+ T auxiliaires exprime des facteurs de transcription et des cytokines spécifiques qui coordonnent la réponse immunitaire contre les pathogènes rencontrés. Parmi les facteurs influençant la différenciation des lymphocytes CD4+ T auxiliaires, la voie de signalisation Notch a été identifiée comme ayant un rôle dans la différenciation et la fonction des différents sous-types de cellules CD4+ T auxiliaires. La voie de signalisation Notch est une voie évolutivement conservée, qui est impliquée dans la signalisation entre les cellules et dans de nombreux processus de décisions cellulaires. La manière dont la voie de signalisation Notch régule la différenciation des lymphocytes CD4+ T en sous-types de cellules CD4+ auxiliaires, mais également la question de savoir si la voie de signalisation Notch est capable ou non d'induire la différenciation des cellules CD4+T auxiliaires, restent à débattre. Les cellules T auxiliaires 17 (Th17) sont un sous-type distinct de cellules CD4+T. Elles jouent un rôle important dans la défense immunitaire contre des pathogènes tels que les bactéries extracellulaires et les champignons. Une dérégulation de la réponse des cellules Th17 peut conduire à des inflammations mais également à des maladies auto-immunes. Les cellules Th17 sont définies par l'expression de leurs facteurs de transcription RAR-related orphan receptor (ROR)a, RORyT et par la sécrétion de cytokines comme IL-17A, IL-17F. Le rôle de la voie de signalisation Notch dans la différenciation des cellules Th17 a principalement été démontré in vitro. Malgré tout, ni les conditions expérimentales dans lesquelles cette voie pourrait être impliquée dans la différenciation des cellules Th17 in vitro et in vivo, mais également ni la fonction exacte de Notch dans ces processus, ne sont des questions résolues. Afin de mieux définir comment la voie de signalisation Notch est impliquée dans la différenciation des cellules Th17, nous avons utilisé des souris avec une déficience spécifique dans les cellules T des récepteurs Notchl et Notch2 (N1N2ACD4Cre) ou du répresseur transcriptionnel de Notch RBP-JK (RBP-J ACD4Cre). Nous avons montré que lorsque la voie de signalisation Notch est déficiente, les niveaux d'ARN messager (ARNm) de RORyT et de IL-17A sont augmentés dans les cellules Th17 pendant la différenciation in vitro, en présence de niveaux réduits des signaux activant les cellules T CD4+. Une augmentation dans les niveaux d'ARNm de IL-17A et de IL-17A intracellulaire au niveau protéinique a été observée dans les cellules T CD4+ Notch déficientes, au niveau des ganglions drainants après immunisation avec l'OVA dans le CFA, un adjuvant induisant une réponse des cellules Th17. Nos résultats suggèrent que Notch pourrait réguler négativement l'expression de IL-17A au niveau transcriptionnel mais également protéinique. Malgré une augmentation de IL-17A au niveau de l'ARNm et protéinique dans les cellules CD4+ T Notch déficientes, paradoxalement la sécrétion de IL-17A mais également de cytokines associées aux fonctions effectrices des cellules Th17 sont profondément diminuées 6X vivo, suggérant un rôle de la voie de signalisation Notch dans ce processus. Dans la deuxième partie de ce travail de thèse, nous avons observé que l'impact de Notch dans la différenciation des cellules Th17 et dans leurs fonctions effectrices était dépendant du contexte dans d'autres modèles expérimentaux in vivo, où les cellules Th17 et l'IL-17A ont été identifiées comme ar-.riCociêSM dans le développement ds la pathologie. En résumé, nous avons montré que la voie de la signalisation Notch contrôle la régulation précise de la différenciation des cellules Th17 en limitant leur différenciation, mais en promouvant sélectivement leur relâchement en cytokines associés aux cellules Th17 par l'intermédiaire de mécanismes dépendant de Notch, qui restent toujours à déterminer. -- Lors d'une réponse immunitaire et grâce à la reconnaissance antigénique, les lymphocytes CD4+ T naïfs prolifèrent, puis se différencient en CD4+ T auxiliaires ("T helper" ou Th) fonctionnellement distincts. Chaque sous-population de lymphocytes T auxiliaires exprime des facteurs de transcription et des cytokines spécifiques qui coordonnent une réponse immunitaire contre différents pathogènes. Les mécanismes liés à la différenciation des lymphocytes CD4+ T auxiliaires sont complexes et régulés. Une mauvaise régulation de la différenciation des lymphocytes CD4+ T auxiliaires peut conduire à des maladies auto-immunes, mais également à des processus inflammatoires. Parmi les facteurs influençant la différenciation des lymphocytes T auxiliaires, la voie de signalisation Notch a été identifiée comme ayant un rôle dans la différenciation et la fonction des différents sous-types de cellules CD4+ T auxiliaires. La voie de signalisation Notch est une voie évolutivement conservée, qui est impliquée dans la signalisation entre les cellules, mais également dans de nombreux processus de décisions cellulaires. Quelle est l'implication de la voie de signalisation Notch dans la différenciation des lymphocytes CD4+ en sous-types de cellules CD4+T auxiliaires et comment cette voie agit dans ce processus, sont des questions débattues. Les cellules T auxiliaires 17 (Th17) sont une sous-population distincte de lymphocytes CD4+. Elles jouent un rôle important dans la défense immunitaire contre les bactéries extracellulaires et les champignons. Une dérégulation de la réponse des cellules Th17 a été associée à des maladies auto-immunes et à l'inflammation. Les cellules Th17 sont définies par l'expression du facteur de transcription RAR-related orphan receptor (ROR)yT et des cytokines comme IL-17A, IL-17F. Le rôle de la voie de signalisation Notch dans la différenciation des cellules Th17 a été principalement démontré dans des études expérimentales in vitro. Malgré tout, les conditions expérimentales exactes dans lesquelles la voie de signalisation de Notch pourrait être impliquée dans la différenciation des cellules Th17, mais également le rôle de Notch dans ce processus ne sont pas encore clairement élucidés. Afin de mieux définir comment la voie de signalisation Notch est impliquée dans la différenciation des cellules Th17, nous avons utilisé des souris avec une déficience spécifique dans les cellules T des récepteurs Notchl et Notch2 (N1 N2ACD4Cre) ou du répresseur transcriptionnel de Notch RBP-JK (RBP-JACD4CRE). Nous avons montré que lorsque la voie de signalisation Notch est déficiente, les niveaux d'ARN messager (ARNm) de RORyT et de IL-17 sont augmentés dans les cellules Th17 pendant leur différenciation in vitro. Cet effet de Notch sur la transcription apparaît être facultatif lorsque les conditions environnementales sont en excès in vitro. Après immunisation avec un adjuvant qui induit principalement une réponse des cellules Th17, nous avons observé que les niveaux de ARNm de IL-17A et aussi de IL-17A intracellulaire au niveau protéinique étaient augmentés dans les ganglions drainants dans les cellules CD4+ Notch déficientes. Ces résultats suggèrent que Notch pourrait réguler négativement l'expression de IL- 17 au niveau transcriptionnel mais également protéinique. Malgré des niveaux plus élevés de IL- 17 ARNm et aussi IL-17A intracellulaire dans les cellules T Notch déficientes, le relâchement en cytokines Th17 est profondément diminué indiquant un rôle de la voie de signalisation Notch dans ces processus de sécrétion. Dans la deuxième partie de cette thèse, nous avons observé que le rôle de Notch dans ia différenciation dss cellules Ti,17 et dans leurs fonctions effectrices était dépendant du contexte dans d'autres modèles expérimentaux, qui ont été rapportés comme une réponse induisant des cellules Th17. En résumé, nos données montrent que la voie de la signalisation Notch contrôle la régulation précise de la différenciation des cellules Th17 en limitant leur différenciation mais en promouvant sélectivement le relâchement en cytokines associées aux cellules Th17 par des mécanismes dépendant de Notch qui restent toujours à déterminer. Par conséquent, l'inhibition de la voie de signalisation Notch pourrait être utilisée dans des situations inflammatoires ou d'auto-immunité où la réponse des cellules Th17 est exacerbée.

Neuropathogenesis in glutaric aciduria type I and methylmalonic aciduria

Glutaric aciduria type-I (GA-I) and methylmalonic aciduria (MMA-uria) are two neurometabolic diseases manifesting in neonatal period and early childhood. They belong to the group of organic acidurias and are caused by defects in the catabolism of amino acids, leading to massive accumulation of toxic metabolites in the body and severe brain injury. Therapeutic strategies are mainly based on reversing catabolic state during metabolic crisis and dietary protein restriction that both aim to prevent extra production of toxic metabolites. Specific and neuroprotective treatments are missing because the mechanisms of brain damage in these diseases are only poorly understood. The principal objective of my work was to develop in vitro models for both diseases aiming at elucidation of toxic effects of the main metabolites accumulating in GA-I (glutaric acid (GA) and 3-hydroxy glutaric acid (3-OHGA)) and MMA-uria (methylmalonic acid (MMA), propionic acid (PA) and 2-methylcitric acid (2-MCA)) on developing brain cells, and to study the cellular pathways targeted by these deleterious effects in order to find new therapeutic potentials. We used re-aggregated embryonic rat brain cells in organotypic 3D cultures, which were exposed to toxic metabolites at different developing stages of the cultures. In parallel, we studied the cellular localization of the defected enzyme in GA-I, glutaryl-CoA dehydrogenase (GCDH), in the brain and peripheral tissues of rats in adulthood and during embryonic development. GCDH expression: GCDH showed a strong neuronal expression in embryonic central and peripheral nervous system. In the adult brain, GCDH expression was exclusively neuronal with the strongest signal in cerebral cortex and Purkinje cells. GCDH expression was homogenous in embryonic peripheral organs with high levels in intestinal mucosa at late stages. Strong GCDH expression was also observed in liver and intestinal mucosa and with lower intensity in muscles, convoluted renal tubules and renal collecting tubes in adult peripheral organs. GA-I and MMA-uria in vitro models: 3-OHGA (for GA-I) and 2-MCA (for MMA-uria) showed the most deleterious effects at early stages of the cultures with morphological and biochemical alterations and induction of cell death. 3-OHGA and 2-MCA caused astrocytic cell suffering reflected by astrocytic fiber loss and swelling and retardation in oligodendrocytic maturation and/or differentiation. High ammonium increase concomitant with glutamine decrease was observed in these cultures. Neurons were not substantially affected. Our studies revealed that brain-cell generated ammonia may play a role in the neuropathogenesis of these diseases. Thus, developing neuroprotective strategies that target ammonium toxicity in the brain of GA-I and MMA-uria patients might be important according to our findings. -- L'acidurie glutarique de type I (GA-I) et l'acidurie méthylmalonique (MMA-urie) sont deux maladies neurométaboliques se manifestant durant la période néonatale ou la petite enfance, et qui appartiennent aux aciduries organiques. Elles sont causées par des défauts dans le catabolisme des acides aminés, conduisant à une accumulation des métabolites toxiques dans le corps et aussi des lésions cérébrales sévères. Le traitement est limité à une prise en charge d'urgence pendant la crise métabolique et à une diète restreinte en protéines naturelles. Des traitements spécifiques, neuroprotecteurs manquent principalement parce que les mécanismes conduisant aux lésions cérébrales dans ces maladies sont peu connus. L'objectif principal de mon travail était d'élucider les effets toxiques des métabolites accumulés dans GA-I (l'acide glutarique (GA) et l'acide 3-hydroxyglutarique (3-OHGA)) et MMA-uria (l'acide méthylmalonique (MMA), l'acide propionique (PA) et l'acide 2-méthylcitrique(2-MCA) sur les cellules du cerveau ainsi que les voies cellulaires impliquées, dans le but de trouver de potentielles nouvelles stratégies thérapeutiques. Nous avons utilisé un modèle in vitro de cultures 3D de cellules de cerveau d'embryons de rat (en développement) en les exposant aux métabolites toxiques à différents stades de développement des cultures. En parallèle, nous avons étudié la localisation cellulaire de l'enzyme déficiente dans GA-I, la CoA-glutarly déshydrogénase (GCDH), dans le cerveau et les organes périphériques des rats adultes et pendant le développement embryonnaire. L'expression de GCDH: GCDH a montré une expression neuronale forte dans le système nerveux chez l'embryon et le cerveau adulte. L'expression était homogène dans les organes périphériques avec une forte expression dans l'intestin. Les modèles in vitro de GA-I et MMA-uria : 3-OHGA en modèle GA-I et 2-MCA en modèle MMA-uria ont montré les effets délétères les plus importants avec des altérations morphologiques des cellules et biochimiques dans le milieu de culture et l'induction de mort cellulaire non-apoptotique (3-OHGA) ou apoptotique (2-MCA). 3-OHGA et 2-MCA ont provoqué une souffrance astrocytaire avec perte des fibres et gonflement et un retard de maturation et/ou de différentiation des oligodendrocytes. Une augmentation importante d'ammonium avec une diminution concomitante de glutamine a été observée dans les cultures. Les neurones n'étaient pas vraiment affectés. Nos études ont révélé que l'ammonium généré par les cellules cérébrales pourrait jouer un rôle dans la neuropathogenèse de ces deux maladies. Par conséquent, développer des stratégies neuroprotectrices ciblant la toxicité de l'ammonium dans le cerveau des patients atteints de GA-I ou MMA-urie pourrait être très important selon nos résultats.

Microtubule-associated protein 6 mediates neuronal connectivity through Semaphorin 3E-dependent signalling for axonal growth.

Structural microtubule associated proteins (MAPs) stabilize microtubules, a property that was thought to be essential for development, maintenance and function of neuronal circuits. However, deletion of the structural MAPs in mice does not lead to major neurodevelopment defects. Here we demonstrate a role for MAP6 in brain wiring that is independent of microtubule binding. We find that MAP6 deletion disrupts brain connectivity and is associated with a lack of post-commissural fornix fibres. MAP6 contributes to fornix development by regulating axonal elongation induced by Semaphorin 3E. We show that MAP6 acts downstream of receptor activation through a mechanism that requires a proline-rich domain distinct from its microtubule-stabilizing domains. We also show that MAP6 directly binds to SH3 domain proteins known to be involved in neurite extension and semaphorin function. We conclude that MAP6 is critical to interface guidance molecules with intracellular signalling effectors during the development of cerebral axon tracts.

Neuronal death after perinatal cerebral hypoxia-ischemia: Focus on autophagy-mediated cell death.

Neonatal hypoxic-ischemic encephalopathy is a critical cerebral event occurring around birth with high mortality and neurological morbidity associated with long-term invalidating sequelae. In view of the great clinical importance of this condition and the lack of very efficacious neuroprotective strategies, it is urgent to better understand the different cell death mechanisms involved with the ultimate aim of developing new therapeutic approaches. The morphological features of three different cell death types can be observed in models of perinatal cerebral hypoxia-ischemia: necrotic, apoptotic and autophagic cell death. They may be combined in the same dying neuron. In the present review, we discuss the different cell death mechanisms involved in neonatal cerebral hypoxia-ischemia with a special focus on how autophagy may be involved in neuronal death, based: (1) on experimental models of perinatal hypoxia-ischemia and stroke, and (2) on the brains of human neonates who suffered from neonatal hypoxia-ischemia.

IL-27 Induces Th17 Differentiation in the Absence of STAT1 Signaling.

It is known that differentiation of Th17 cells is promoted by activation of STAT3 and inhibited by activation of STAT1. Although both transcription factors are activated by several cytokines, including IL-6, IL-21, and IL-27, each of these cytokines has a very different effect on Th17 differentiation, ranging from strong induction (IL-6) to strong inhibition (IL-27). To determine the molecular basis for these differences, we measured STAT3 and STAT1 activation profiles for IL-6, IL-21, and IL-27, as well as for cytokine pairs over time. We found that the ratio of activated STAT3/activated STAT1 is crucial in determining whether cytokines promote or inhibit Th17 differentiation. IL-6 and IL-21 induced p-STAT3/p-STAT1 ratios > 1, leading to the promotion of Th17 differentiation, whereas IL-27 or IL-6+IL-27 induced p-STAT3/p-STAT1 ratios < 1, resulting in inhibition of Th17 differentiation. Consistent with these findings, we show that IL-27 induces sufficient p-STAT3 to promote Th17 differentiation in the absence of STAT1. Furthermore, IL-27-induced STAT1-deficient T cells were indistinguishable from bona fide highly proinflammatory Th17 cells because they induced severe experimental autoimmune encephalomyelitis upon adoptive transfer. Our results suggest that the ratio of p-STAT3/p-STAT1 induced by a cytokine or cytokine pairs can be used to predict whether they induce a competent Th17-differentiation program.

The role of geography and ecology in shaping repeated patterns of morphological and genetic differentiation between European minnows (Phoxinus phoxinus) from the Pyrenees and the Alps

Neutral and selective processes c an drive repeated patterns of evolu tion in dif ferent groups of populationsexp eriencing similar ecol ogica l gradients. In this paper, we used a combinat ion of nucl ear and mitochondrialDNA markers, as well as geometric morphometrics, to investigate repeated patterns of morphological andgenetic divergence of E uropean minnows in two mountain ranges : the Pyrenees and the Al ps. Europeanminnows (Phoxinus phoxinus) are cyprinid fish i nha bitin g most freshwater bodies in Europe, including those indifferent mountain r anges that could act as major geographical barriers to gene flow. We explored patterns ofP. phoxinus phenotypic and genetic di versi fication along a gradi ent of alti tude common to the two mountainranges, and tested for isolation by distance (IBD), isolation by environment (IBE) and isolation by adaptation(IBA). The results indicated that populations from the Pyr enees a nd the Alps bel ong to two well differentiated,reciprocally monophyletic mt DNA lineages. Substantial genetic differentiation due to geographical isolationwithin and between populations from the Pyrenees and the Alps was also found using rapidly evolving AFLPsmarkers (isolation by distance or IBD), as well as morphological differences between mountain ranges. Als o,morphology varied strong ly with elevation and so did genetic differentiation to a lower extent. Despitemoderate evidence for IBE and IBA, and therefore of repeated evolution, substantial population heterogeneitywas found at the genetic level, suggesting that selection and population specific genetic drift act in concert toaffect genetic divergence.

Plasma cell and terminal B-cell differentiation in mantle cell lymphoma mainly occur in the SOX11-negative subtype.

Mantle cell lymphoma is a mature lymphoid neoplasm characterized by the t(11;14)(q13;q32) and cyclin D1 overexpression. SOX11 is a transcription factor commonly overexpressed in these tumors but absent in most other mature B-cell lymphomas whose function is not well understood. Experimental studies have shown that silencing of SOX11 in mantle cell lymphoma cells promotes the shift from a mature B cell into an early plasmacytic differentiation phenotype, suggesting that SOX11 may contribute to tumor development by blocking the B-cell differentiation program. The relationship between SOX11 expression and terminal B-cell differentiation in primary mantle cell lymphoma and its relationship to the plasmacytic differentiation observed in occasional cases is not known. In this study we have investigated the terminal B-cell differentiation phenotype in 60 mantle cell lymphomas, 41 SOX11-positive and 19 SOX11-negative. Monotypic plasma cells and lymphoid cells with plasmacytic differentiation expressing cyclin D1 were observed in 7 (37%) SOX11-negative but in none of 41 SOX11-positive mantle cell lymphomas (P<0.001). Intense cytoplasmic expression of a restricted immunoglobulin light chain was significantly more frequent in SOX11-negative than -positive tumors (58 vs 13%) (P=0.001). Similarly, BLIMP1 and XBP1 expression was also significantly more frequent in SOX11-negative than in -positive cases (83 vs 34% and 75 vs 11%, respectively) (P=0.001). However, no differences in the expression of IRF4/MUM1 were observed among these subtypes of mantle cell lymphoma. In conclusion, these results indicate that SOX11-negative mantle cell lymphoma may be a particular subtype of this tumor characterized by more frequent morphological and immunophenotypic terminal B-cell differentiation features that may be facilitated by the absence of SOX11 transcription factor.

Tangential migration of neuronal precursors of glutamatergic neurons in the adult mammalian brain.

In a classic model of mammalian brain formation, precursors of principal glutamatergic neurons migrate radially along radial glia fibers whereas GABAergic interneuron precursors migrate tangentially. These migration modes have significant implications for brain function. Here we used clonal lineage tracing of active radial glia-like neural stem cells in the adult mouse dentate gyrus and made the surprising discovery that proliferating neuronal precursors of glutamatergic granule neurons exhibit significant tangential migration along blood vessels, followed by limited radial migration. Genetic birthdating and morphological and molecular analyses pinpointed the neuroblast stage as the main developmental window when tangential migration occurs. We also developed a partial "whole-mount" dentate gyrus preparation and observed a dense plexus of capillaries, with which only neuroblasts, among the entire population of progenitors, are directly associated. Together, these results provide insight into neuronal migration in the adult mammalian nervous system.

Congenital Nystagmus Gene FRMD7 Is Necessary for Establishing a Neuronal Circuit Asymmetry for Direction Selectivity.

Neuronal circuit asymmetries are important components of brain circuits, but the molecular pathways leading to their establishment remain unknown. Here we found that the mutation of FRMD7, a gene that is defective in human congenital nystagmus, leads to the selective loss of the horizontal optokinetic reflex in mice, as it does in humans. This is accompanied by the selective loss of horizontal direction selectivity in retinal ganglion cells and the transition from asymmetric to symmetric inhibitory input to horizontal direction-selective ganglion cells. In wild-type retinas, we found FRMD7 specifically expressed in starburst amacrine cells, the interneuron type that provides asymmetric inhibition to direction-selective retinal ganglion cells. This work identifies FRMD7 as a key regulator in establishing a neuronal circuit asymmetry, and it suggests the involvement of a specific inhibitory neuron type in the pathophysiology of a neurological disease. VIDEO ABSTRACT.

Synaptic dysfunction, memory deficits and hippocampal atrophy due to ablation of mitochondrial fission in adult forebrain neurons.

Well-balanced mitochondrial fission and fusion processes are essential for nervous system development. Loss of function of the main mitochondrial fission mediator, dynamin-related protein 1 (Drp1), is lethal early during embryonic development or around birth, but the role of mitochondrial fission in adult neurons remains unclear. Here we show that inducible Drp1 ablation in neurons of the adult mouse forebrain results in progressive, neuronal subtype-specific alterations of mitochondrial morphology in the hippocampus that are marginally responsive to antioxidant treatment. Furthermore, DRP1 loss affects synaptic transmission and memory function. Although these changes culminate in hippocampal atrophy, they are not sufficient to cause neuronal cell death within 10 weeks of genetic Drp1 ablation. Collectively, our in vivo observations clarify the role of mitochondrial fission in neurons, demonstrating that Drp1 ablation in adult forebrain neurons compromises critical neuronal functions without causing overt neurodegeneration.

Sodium-dependent phosphate transporters in osteoclast differentiation and function.

Osteoclasts are multinucleated bone degrading cells. Phosphate is an important constituent of mineralized bone and released in significant quantities during bone resorption. Molecular contributors to phosphate transport during the resorptive activity of osteoclasts have been controversially discussed. This study aimed at deciphering the role of sodium-dependent phosphate transporters during osteoclast differentiation and bone resorption. Our studies reveal RANKL-induced differential expression of sodium-dependent phosphate transport protein IIa (NaPi-IIa) transcript and protein during osteoclast development, but no expression of the closely related NaPi-IIb and NaPi-IIc SLC34 family isoforms. In vitro studies employing NaPi-IIa-deficient osteoclast precursors and mature osteoclasts reveal that NaPi-IIa is dispensable for bone resorption and osteoclast differentiation. These results are supported by the analysis of structural bone parameters by high-resolution microcomputed tomography that yielded no differences between adult NaPi-IIa WT and KO mice. By contrast, both type III sodium-dependent phosphate transporters Pit-1 and Pit-2 were abundantly expressed throughout osteoclast differentiation, indicating that they are the relevant sodium-dependent phosphate transporters in osteoclasts and osteoclast precursors. We conclude that phosphate transporters of the SLC34 family have no role in osteoclast differentiation and function and propose that Pit-dependent phosphate transport could be pivotal for bone resorption and should be addressed in further studies.

Adaptation of Root Function by Nutrient-Induced Plasticity of Endodermal Differentiation.

Plant roots forage the soil for minerals whose concentrations can be orders of magnitude away from those required for plant cell function. Selective uptake in multicellular organisms critically requires epithelia with extracellular diffusion barriers. In plants, such a barrier is provided by the endodermis and its Casparian strips-cell wall impregnations analogous to animal tight and adherens junctions. Interestingly, the endodermis undergoes secondary differentiation, becoming coated with hydrophobic suberin, presumably switching from an actively absorbing to a protective epithelium. Here, we show that suberization responds to a wide range of nutrient stresses, mediated by the stress hormones abscisic acid and ethylene. We reveal a striking ability of the root to not only regulate synthesis of suberin, but also selectively degrade it in response to ethylene. Finally, we demonstrate that changes in suberization constitute physiologically relevant, adaptive responses, pointing to a pivotal role of the endodermal membrane in nutrient homeostasis.