Concomitant multipotent and unipotent dental pulp progenitors and their respective contribution to mineralised tissue formation.

Upon in vitro induction or in vivo implantation, the stem cells of the dental pulp display hallmarks of odontoblastic, osteogenic, adipogenic or neuronal cells. However, whether these phenotypes result from genuine multipotent cells or from coexistence of distinct progenitors is still an open question. Furthermore, determining whether a single cell-derived progenitor is capable of undergoing a differentiation cascade leading to tissue repair in situ is important for the development of cell therapy strategies. Three clonal pulp precursor cell lines (A4, C5, H8), established from embryonic ED18 first molars of mouse transgenic for a recombinant plasmid adeno-SV40, were induced to differentiate towards the odonto/osteogenic, chondrogenic or adipogenic programme. Expression of phenotypic markers of each lineage was evaluated by RT-PCR, histochemistry or immunocytochemistry. The clones were implanted into mandibular incisors or calvaria of adult mice. The A4 clone was capable of being recruited towards at least 3 mesodermal lineages in vitro and of contributing to dentin-like or bone formation, in vivo, thus behaving as a multipotent cell. In contrast, the C5 and H8 clones displayed a more restricted potential. Flow cytometric analysis revealed that isolated monopotent and multipotent clones could be distinguished by a differential expression of CD90. Altogether, isolation of these clonal lines allowed demonstrating the coexistence of multipotential and restricted-lineage progenitors in the mouse pulp. These cells may further permit unravelling specificities of the different types of pulp progenitors, hence facilitating the development of cell-based therapies of the dental pulp or other cranio-facial tissues.

Pulpal progenitors and dentin repair.

Mesenchymal stem cells are present in the dental pulp. They have been shown to contribute to dentin-like tissue formation in vitro and to participate in bone repair after a mandibular lesion. However, their capacity to contribute efficiently to reparative dentin formation after pulp lesion has never been explored. After pulp exposure, we have identified proliferative cells within 3 zones. In the crown, zone I is near the cavity, and zone II corresponds to the isthmus between the mesial and central pulp. In the root, zone III, near the apex, at a distance from the inflammatory site, contains mitotic stromal cells which may represent a source of progenitor cells. Stem-cell-based strategies are promising treatments for tissue injury in dentistry. Our experiments focused on (1) location of stem cells induced to leave their quiescent state early after pulp injury and (2) implantation of pulp progenitors, a substitute for classic endodontic treatments, paving the way for pulp stem-cell-based therapies.

Controlled conversion of an immortalized mesodermal progenitor cell towards osteogenic, chondrogenic, or adipogenic pathways.

The teratocarcinoma-derived C1 clone behaves as a mesodermal tripotential progenitor cell whose choice of fate, either osteoblast, chondroblast, or adipoblast, is strictly dependent on the spatial organization of the cells and the nature of the induction. In the absence of cell contact before the addition of inducers, the C1 cells maintain a stable undifferentiated phenotype while expressing potential regulators of embryonic mesodermal stem cell fate such a M-twist and Id1. Upon establishment of cell contacts before the induction of differentiation, the early genes characteristic of the three fates become expressed. In the presence of beta glycerophosphate and ascorbate, provided the cells have formed aggregates, 95% of the C1 cells mineralize with a kinetics of gene expression close to that of osteoblasts (Poliard, A., D. Lamblin, P. J. Marie, M. H. Buc, and O. Kellerman. 1993. J. Cell Sci. 106:503-512). With 10(-6)M dexamethasone, 80% of the same aggregates differentiate into foci of chondroblast-like cells. The kinetics of expression of the genes encoding type II, IX, X, and XI collagens, aggrecan and link protein during the conversion toward cartilage hypertrophy resembles that accompanying in vivo chondrogenesis. The synergistic action of dexamethasone and insulin convert most confluent C1 cells into functional adipocytes and induce a pattern of gene expression close to that reported for adipoblast cell lines. The C1 clone with its capacity to differentiate along three alternative pathways with high frequency, therefore appears as a valid in vitro model for deciphering the molecular basis of mesoblast ontogeny.

An immortalized osteogenic cell line derived from mouse teratocarcinoma is able to mineralize in vivo and in vitro.

The hybrid plasmid pK4 containing the early genes of the simian virus SV-40, under the control of the adenovirus type 5 E1a promoter, was introduced into the multipotent embryonal carcinoma (EC) 1003. Expression of the SV-40 oncogenes was observed at the EC cell stage, and this allowed the derivation of immortalized cells corresponding to early stages of differentiation. Among the immortalized mesodermal derivatives obtained, one clone, C1, is committed to the osteogenic pathway. C1 cells have a stable phenotype, synthesize type I collagen, and express alkaline phosphatase activity. Although immortalized and expressing the SV-40 T antigen, the cells continue to be able to differentiate in vivo and in vitro. In vivo, after injection into syngeneic mice, they produce osteosarcomas. In vitro, the cells form nodules and deposit a collagenous matrix that mineralizes, going to hydroxyapatite crystal formation, in the presence of beta-glycerophosphate. This clonal cell line, which originates from an embryonal carcinoma, therefore differentiates into osteogenic cells in vivo and in vitro. This immortalized cell line will be useful in identifying specific molecular markers of the osteogenic pathway, to investigate gene regulation during osteogenesis and to study the ontogeny of osteoblasts.

Signal transduction through prion protein.

The cellular prion protein PrPc is a glycosylphosphatidylinositol-anchored cell-surface protein whose biological function is unclear. We used the murine 1C11 neuronal differentiation model to search for PrPc-dependent signal transduction through antibody-mediated cross-linking. A caveolin-1-dependent coupling of PrPc to the tyrosine kinase Fyn was observed. Clathrin might also contribute to this coupling. The ability of the 1C11 cell line to trigger PrPc-dependent Fyn activation was restricted to its fully differentiated serotonergic or noradrenergic progenies. Moreover, the signaling activity of PrPc occurred mainly at neurites. Thus, PrPc may be a signal transduction protein.

Computational approaches for the study of serotonin and its membrane transporter SERT: implications for drug design in neurological sciences.

Serotonin (5-hydroxytryptamine, 5-HT), a monoamine neurotransmitter of the central nervous and peripheral systems (CNS), plays a critical role in a wide variety of physiological and behavioral processes. In the serotonergic system, deregulation of the tightly controlled extracellular concentration of 5-HT appears to be at the origin of a host of metabolic and psychiatric disorders. A key step that regulates 5-HT external level is the re-uptake of 5-HT into cells by the 5-HT transporter (SERT), which is besides the target of numerous drugs interacting with the serotonergic system. Therapeutic strategies have mainly focused on the development of compounds that block the activity of SERT, for instance reuptake inhibitors (e.g. tricyclics, "selective" serotonin reuptake inhibitors) and in the past, specific substrate-type releasers (e.g. amphetamine and cocaine derivatives). Today, generation of new drugs targetting SERT with enhanced selectivity and reduced toxicity is one of the most challenging tasks in drug design. In this context, studies aiming at characterizing the physicochemical properties of 5-HT as well as the biological active conformation of SERT are a prerequisite to the design of new leads. However, the absence of a high-resolution 3D-structure for SERT has hampered the design of new transporter inhibitors. Using computational approaches, numerous efforts were made to shed light on the structure of 5-HT and its transporter. In this review, we compared several in silico methods dedicated to the modeling of 5-HT and SERT with an emphasis on i) quantum chemistry for study of 5-HT conformation and ii) ligand-based (QSAR and pharmacophore models) and transporter-based (homology models) approaches for studying SERT molecule. In addition, we discuss some methodological aspects of the computational work in connection with the construction of putative but reliable 3D structural models of SERT that may help to predict the mechanisms of neurotransmitter transport.

Stepwise control of osteogenic differentiation by 5-HT(2B) receptor signaling: nitric oxide production and phospholipase A2 activation.

During development, antagonists of 5-HT(2) receptor subtypes cause morphological defects of mesodermal and neural crest derivatives including the craniofacial skeleton. We used an inducible mesoblastic cell line, C1, able to fully convert into osteocytes within 12 days, to assess the involvement of 5-HT(2) receptors during osteogenic differentiation. On day 5 of the osteogenic program, immediately before matrix mineralization, the cells selectively implement 5-HT(2B) receptors (5-HT(2B)R) which remain functional until terminal differentiation. In 5-HT-depleted medium, the receptor exhibits a constitutive activity leading to basal nitric oxide (NO) release and phospholipase A2 (PLA2)-dependent arachidonic acid (AA) production. Blockade of this intrinsic activity affects the efficiency of mineralization by decreasing calcium incorporation within the matrix by 40%. Optimal bone matrix mineralization involves both NO and PLA2 signaling pathways. Moreover, between day 5 and day 10, at the beginning of mineral deposition, the 5-HT(2B)R promotes prostaglandin E2 production through AA-dependent cyclooxygenase (COX) activation. From day 10 onwards, when C1 osteoblasts undergo conversion into osteocyte-like cells, COX activity is quenched. Altogether these observations indicate that the 5-HT(2B)R contributes in an autocrine manner to osteogenic differentiation and highlight a switch in the downstream targets of the receptor at the terminal stage of the program. Finally, in addition to its autocrine function, the 5-HT(2B)R responds to 5-HT by increasing NO production and AA release. These findings raise concern regarding the use of 5-HT(2B)R-related drugs that may interfere with bone metabolism in physiological or pathological situations.

Overexpression of murine small heat shock protein HSP25 interferes with chondrocyte differentiation and decreases cell adhesion.

Although multiple functions for the small heat shock protein HSP25 have been proposed, its specific role during developmental and differentiation processes is not known. Cartilage is one of the tissues in which HSP25 is specifically and highly expressed during development. C1 cells, able to form aggregates in vitro, can be induced to differentiate into chondrocytes. In this study, we generated two stable transfected clones overexpressing HSP25 at two different levels. Cell morphology and growth rate were modified in both clones, although the actin content and distribution did not seem to be altered. Overexpressing clones had more difficulties in coalescing, leading to smaller aggregates and they did not differentiate into chondrocytes. Subsequently, these aggregates tended to dissociate into loose masses of dying cells. The strength of all these effects was directly correlated to the level of HSP25 overexpression. These data suggest that overexpressing HSP25 decreases cellular adhesion and interferes with chondrocyte differentiation.

New cellular models for tracking the odontoblast phenotype.

Odontoblasts and osteoblasts differ functionally and histologically. Because of their close relationship, mesenchymal cells derived from teeth and bone are difficult to distinguish ex vivo. Indeed, the main non-collagenous components of the odontoblastic extracellular matrix, dentin sialoprotein (DSP) or dentin matrix protein 1 (DMP1), have also been detected in osteoblasts. The need to develop cellular models of odontoblast differentiation and to identify markers specific for the odontoblast lineage, has led us to establish clonal cell lines from tooth germs of day 18 mouse embryos transgenic for an adenovirus-SV40 recombinant plasmid. In this study, we analyzed the phenotypes of three independent clones by RT-PCR and Western blot. These clones synthesised DSP, DMP1 and other extracellular matrix proteins typical of the odontoblast and are therefore likely to be derived from the pulp. Transcripts encoding a set of homeobox proteins involved in craniofacial development, such as Pax9, Msx1, Cbfa1, Dlx2 and 5 were also expressed albeit at a different level. These features of the pulpal clones are shared by the C1 mesodermal cells that are capable of differentiating along osteogenic, chondrogenic or adipogenic lineages In contrast, transcripts for two LIM-domain homeobox family genes (Lhx6 and Lhx7) were only detected in the dental clones. Since these genes are preferentially expressed in the mesenchyme of the developing tooth, this suggests that our transgenic-derived cell lines retain intrinsic properties of odontoblastic cells. They may help to characterise genes specifying the odontoblast phenotype and the signalling pathways underlying odontoblast differentiation.

Bone morphogenetic protein regulation of forkhead/winged helix transcription factor Foxc2 (Mfh1) in a murine mesodermal cell line C1 and in skeletal precursor cells.

Mfh1/Foxc2 is a member of forkhead/winged helix transcription factor family in which its members serve as key regulators in embryogenesis and cell differentiation in various species. Mutant mice null for Mfh1 show defects in axial and cranial skeletogenesis, suggesting requirement of Mfh1 for skeletal tissue development. However, the roles of Mfh1 and its regulation during early skeletogenesis have not been understood fully yet. In this study, we investigated developmental regulation of Mfh1 expression during embryonic skeletogenesis in vivo and in vitro chondrogenic cell differentiation using a mesodermal progenitor-like cell line C1. We first examined expression patterns of Mfh1 in relation to the cartilage phenotype-related molecules including bone morphogenetic proteins (BMPs) during mouse embryogenesis by in situ hybridization. In 10.5 days postcoitum (dpc) mouse limb, Mfh1 messenger RNA (mRNA) was expressed in the mesenchymal cells in the tissues that later give rise to skeleton. In 11.5 dpc embryos, Mfh1 transcripts were expressed in the cell condensation of skeletal blastemas. BMP2 transcripts were expressed in the cell condensation proximal to the Mfh1-expressing cells in the limbs and those of BMP-7 were expressed in the mesenchymal tissue surrounding the Mfh1-positive cell condensation. In 12.5 dpc and 13.5 dpc embryos, the expression of Mfh1 was localized to the perichondrium, which surrounds cells that express noggin and SOX9 mRNA. BMP-2 expression was overlapped with that of Mfh1 in the peripheral layer of 12.5 dpc and 13.5 dpc limb skeletal blastemas. Mfh1 expression persisted in the perichondrium of 15.5 dpc embryos though its level was reduced. We then examined the expression of Mfh1 in the mouse mesodermal cell line C1 that differentiates into chondrocytes in vitro. Mfh1 mRNA was expressed constitutively at low levels in C1 cells before the induction of its differentiation. On the differentiation of C1 cells into chondrocytes by the treatment with dexamethasone (Dex), Mfh1 expression was increased and peaked on day 4 of Dex treatment. Treatment with BMP-4/7 and BMP-7 protein also enhanced Mfh1 expression in C1 cells. To further examine the causative relationship between BMP and Mfh1 in mesenchymal tissue, we performed a mouse limb bud organ culture to implant BMP proteins with carriers into the mesenchymal tissue of the limb bud. Implantation of BMP-7 protein in the limb bud of 11.5 dpc embryos induced Mfh1 expression, suggesting that BMP regulates Mfh1 expression in limb mesenchyme. These results indicate that Mfh1 expression is associated with the early stage of chondrogenic differentiation both in vivo and in vitro and that BMPs regulate Mfh1 expression in skeletal precursor cells.

Perturbation of BMP signaling in somitogenesis resulted in vertebral and rib malformations in the axial skeletal formation.

Axial skeletons such as vertebrae, ribs, and scapulae develop from the embryonic somitic mesoderm through interactions with neural tube/notochord and skin ectoderm. Bone morphogenetic proteins (BMPs) seem to play important roles in these tissue interactions; however, the relationship between BMP signaling and the early development of axial skeletons is poorly understood. In this report, we investigated possible roles of BMP signaling in axial skeletal formation. First, we describe the expression patterns of BMP4 and type I receptors for BMP during somitogenesis in chick embryos based on whole mount in situ hybridization. Next, the effects of BMP on axial skeletal morphogenesis were investigated by implantation of BMP proteins into the dorsal mesoderm at the time of somitogenesis. Transcripts for both BMP4 ligand and its receptors are expressed in the dorsal ectoderm and mesoderm. Implantation of BMP4 and BMP2 into the dorsal regions of embryos result in subsequent anomalies of vertebrae, ribs, and scapulae. The effects of BMP implantation on the skeleton are shown to be dependent upon the somitic stage. Vertebral anomalies are restricted to the dorsolateral elements of the vertebrae and specifically observed after BMP implantation into embryonic day 2 (E2) embryos, but not E3 embryos. These results indicate that implantation of BMP into the dorsal part of embryos where endogenous BMP ligand and BMP receptors are expressed perturbs BMP signaling and causes axial skeletal malformations. The findings presented here suggest that BMP signaling may be involved in the early developmental process of the axial skeleton.

Prion protein and neuronal differentiation: quantitative analysis of prnp gene expression in a murine inducible neuroectodermal progenitor.

The biological function of the cellular prion protein, PrP(c), is currently unknown. The presence of PrP(c) transcripts in the developing neural tube from embryonic day 13.5 and the predominant expression of PrP(c) in the adult brain is suggestive of a role in the onset and/or modulation of neuronal functions. We took advantage of the bipotential neuroectodermal 1C11 cell line to monitor PrP(c) expression during its bioaminergic differentiations. The F9-derived 1C11 precursor cell line displays a stable and immature phenotype in the absence of extracellular signal and, upon induction, has the capacity to acquire a complete serotonergic or noradrenergic phenotype, the two pathways being mutually exclusive. A real-time quantitative PCR assay was developed to assess PrP(c) gene expression at definite times of the two programs that correspond to sequential acquisition of neurotransmitter-specific functions. 1C11 cells and their differentiated progenies express significant amounts of PrP transcripts and of the corresponding protein. A unique decrease in prnp gene expression is observed upon entry into the serotonergic pathway, correlating with a downregulation at the protein level. Moreover, nerve growth factor (NGF) is shown to induce a decrease in the level of prnp gene expression along the serotonergic - but not the noradrenergic - pathway. Our study accurately establishes that prnp gene expression (i) is strongly upregulated concomitantly with cell fate restriction of multipotential cells towards the neural lineage; (ii) is differentially regulated along the serotonergic versus noradrenergic differentiation program of a unique neuroectodermal progenitor. The 1C11 cell line may provide a new tool for studying prion infectivity in a well-defined neuronal context.

Evolving views in prion glycosylation: functional and pathological implications.

Prion diseases form a group of neurodegenerative disorders with the unique feature of being transmissible. These diseases involve a pathogenic protein, called PrP(Sc) for the scrapie isoform of the cellular prion protein (PrP(C)) which is an abnormally-folded counterpart of PrP(C). Many questions remain unresolved concerning the function of PrP(C) and the mechanisms underlying prion replication, transmission and neurodegeneration. PrP(C) is a glycosyl-phosphatidylinositol-anchored glycoprotein expressed at the cell surface of neurons and other cell types. PrP(C) may be present as distinct isoforms depending on proteolytic processing (full length and truncated), topology(GPI-anchored, transmembrane or soluble) and glycosylation (non- mono- and di-glycosylated). The present review focuses on the implications of PrP(C) glycosylation as to the function of the normal protein, the cellular pathways of conversion into PrP(Sc), the diversity of prion strains and the related selective neuronal targeting.

Sequential onset of three 5-HT receptors during the 5-hydroxytryptaminergic differentiation of the murine 1C11 cell line.

1. The murine 1C11 clone, which derives from a multipotential embryonal carcinoma cell line, has the features of a neuroectodermal precursor. When cultured in the presence of dibutyryl cyclic AMP, the 1C11 cells extend bipolar extensions and express neurone-associated markers. After 4 days, the resulting cells have acquired the ability to synthesize, take up, store and catabolize 5-hydroxytryptamine (5-HT). We have thus investigated the presence of 5-HT receptors during the 5-hydroxytryptaminergic differentiation of this inducible 1C11 cell line. 2. As shown by the binding of [125I]-GTI and the CGS 12066-dependent inhibition of the forskolin-induced cyclic AMP production, functional 5-HT1B/1D receptors become expressed on day 2 of 1C11 cell differentiation. The density of these receptors remained unchanged until day 4. 3. The same holds true for the 5-HT2B receptor, also identified by its pharmacological profile and its positive coupling to the phosphoinositide cascade. 4. On day 4 of 1C11 cell differentiation, a third 5-HT receptor, pharmacologically and functionally similar to 5-HT2A, had become induced. 5. Strikingly, the amounts of each transcript encoding 5-HT1B, 5-HT2A and 5-HT2B receptor did not very significantly during the time course of the 1C11 5-hydroxytryptaminergic differentiation. 6. The clone 1C11 may thus provide a useful in vitro model for studying regulation(s) between multiple G-linked receptors as well as the possible role of 5-HT upon the expression of a complete 5-hydroxytryptamine phenotype.

Mouse 5-HT2B receptor-mediated serotonin trophic functions.

5-HT2B receptors, in addition to phospholipase C stimulation, are able to trigger activation of the proto-oncogene product p21ras. During mouse embryogenesis, a peak of 5-HT2B receptor expression is detected at the neurulation stage; we localized the 5-HT2B expression in neural crest cells, heart myocardium, and somites. The requirement for functional 5-HT2B receptors shortly after gastrulation, is supported by culture of embryos exposed to 5-HT2B-high affinity antagonist such as ritanserin, which induces morphological defects in the cephalic region, heart and neural tube. Functional 5-HT2B receptors are also expressed during the serotonergic differentiation of the mouse F9 teratocarcinoma-derived clonal cell line 1C11. Upon 2 days of induction by cAMP, 5-HT2B receptors become functional, and on day 4, the appearance of 5-HT2A receptors coincides with the onset of active serotonin transporter by these cells. Active serotonin uptake is modulated by serotonin suggesting autoreceptor functions for 5-HT2B receptors.

The mouse 5-HT2B receptor: homologous subtype or species variant?

The recently characterized 5-HT2B subfamily of serotonin receptors has now been reported from three different species: human, rat and mouse. Their genomic structures include 2 introns present at identical positions. Despite this similarity, their respective protein sequences show some diversities. In addition, the pharmacology of these receptors is distantly related, and their sites of expression vary amongst species. Thus, it appears difficult at present to unambiguously classify these receptors into the same subfamily, raising the possibility of the existence of other 5-HT2B-like receptors, yet to be discovered.

[Results of magnetic resonance tomography of the temporomandibular joint using optimized surface coils]. / Ergebnisse der Kernspintomographie des Temporomandibulargelenkes mittels optimierter Oberflächenspulen.

One hundred temporo-mandibular joints were examined with a super-conducting nuclear resonance tomograph (1.0 Tesla) using various high resolution surface coils. The optimal method proved to be a spin echo sequence with a repetition time of 1,000 msec and an echo period of 28 msec with a 4 mm slice width. There were significant advantages from the non-invasive MRT diagnosis of the temporo-mandibular joints when compared with CT and with arthrography in recognising abnormal discs, changes in the tissues and for post-operative control.

Comparative studies between mice molars and incisors are required to draw an overview of enamel structural complexity.

In the field of dentistry, the murine incisor has long been considered as an outstanding model to study amelogenesis. However, it clearly appears that enamel from wild type mouse incisors and molars presents several structural differences. In incisor, exclusively radial enamel is observed. In molars, enamel displays a high level of complexity since the inner part is lamellar whereas the outer enamel shows radial and tangential structures. Recently, the serotonin 2B receptor (5-HT2BR) was shown to be involved in ameloblast function and enamel mineralization. The incisors from 5HT2BR knockout (KO) mice exhibit mineralization defects mostly in the outer maturation zone and porous matrix network in the inner zone. In the molars, the mutation affects both secretory and maturation stages of amelogenesis since pronounced alterations concern overall enamel structures. Molars from 5HT2BR KO mice display reduction in enamel thickness, alterations of inner enamel architecture including defects in Hunter-Schreger Bands arrangements, and altered maturation of the outer radial enamel. Differences of enamel structure were also observed between incisor and molar from other KO mice depleted for genes encoding enamel extracellular matrix proteins. Thus, upon mutation, enamel analysis based exclusively on incisor defects would be biased. In view of the functional relationship between enamel structure and tooth morphogenesis, identification of molecular actors involved in amelogenesis requires comparative studies between mice molars and incisors.

Pathogenic prions deviate PrP(C) signaling in neuronal cells and impair A-beta clearance.

The subversion of the normal function exerted by the cellular prion protein (PrP(C)) in neurons by pathogenic prions is assumed to have a central role in the pathogenesis of transmissible spongiform encephalopathies. Using two murine models of prion infection, the 1C11 neuronal cell line and neurospheres, we document that prion infection is associated with the constitutive activation of signaling targets normally coupled with PrP(C), including the Fyn kinase, the mitogen-associated protein kinases ERK1/2 and the CREB transcription factor. PrP(C)-dependent signaling overactivation in infected cells is associated with the recruitment of p38 and JNK stress-associated kinases. Downstream from CREB, prion-infected cells exhibit reduced activity of the matrix metalloprotease (MMP)-9. As MMP-9 catalyzes the degradation of the amyloid A-beta peptide, the decrease in MMP-9 activity in prion-infected cells causes a significant impairment of the clearance of A-beta, leading to its accumulation. By exploiting two 1C11-infected clones accumulating high or moderate levels of prions, we show that the prion-induced changes are correlated with the level of infectivity. Of note, a dose-dependent increase in A-beta levels was also found in the cerebrospinal fluid of mice inoculated with these infected clones. By demonstrating that pathogenic prions trigger increases in A-beta levels through the deviation of PrP(C) signaling, our data argue that A-beta may exacerbate prion-induced toxicity.

Raphe-mediated signals control the hippocampal response to SRI antidepressants via miR-16.

Serotonin reuptake inhibitor (SRI) antidepressants such as fluoxetine (Prozac), promote hippocampal neurogenesis. They also increase the levels of the bcl-2 protein, whose overexpression in transgenic mice enhances adult hippocampal neurogenesis. However, the mechanisms underlying SRI-mediated neurogenesis are unclear. Recently, we identified the microRNA miR-16 as an important effector of SRI antidepressant action in serotonergic raphe and noradrenergic locus coeruleus (LC). We show here that miR-16 mediates adult neurogenesis in the mouse hippocampus. Fluoxetine, acting on serotonergic raphe neurons, decreases the amount of miR-16 in the hippocampus, which in turn increases the levels of the serotonin transporter (SERT), the target of SRI, and that of bcl-2 and the number of cells positive for Doublecortin, a marker of neuronal maturation. Neutralization of miR-16 in the hippocampus further exerts an antidepressant-like effect in behavioral tests. The fluoxetine-induced hippocampal response is relayed, in part, by the neurotrophic factor S100ß, secreted by raphe and acting via the LC. Fluoxetine-exposed serotonergic neurons also secrete brain-derived neurotrophic factor, Wnt2 and 15-Deoxy-delta12,14-prostaglandin J2. These molecules are unable to mimic on their own the action of fluoxetine and we show that they act synergistically to regulate miR-16 at the hippocampus. Of note, these signaling molecules are increased in the cerebrospinal fluid of depressed patients upon fluoxetine treatment. Thus, our results demonstrate that miR-16 mediates the action of fluoxetine by acting as a micromanager of hippocampal neurogenesis. They further clarify the signals and the pathways involved in the hippocampal response to fluoxetine, which may help refine therapeutic strategies to alleviate depressive disorders.