Pluripotent stem cell derived dopaminergic subpopulations model the selective neuron degeneration in Parkinson's disease.

In Parkinson's disease (PD), substantia nigra (SN) dopaminergic (DA) neurons degenerate, while related ventral tegmental area (VTA) DA neurons remain relatively unaffected. Here, we present a methodology that directs the differentiation of mouse and human pluripotent stem cells toward either SN- or VTA-like DA lineage and models their distinct vulnerabilities. We show that the level of WNT activity is critical for the induction of the SN- and VTA-lineage transcription factors Sox6 and Otx2, respectively. Both WNT signaling modulation and forced expression of these transcription factors can drive DA neurons toward the SN- or VTA-like fate. Importantly, the SN-like lineage enriched DA cultures recapitulate the selective sensitivity to mitochondrial toxins as observed in PD, while VTA-like neuron-enriched cultures are more resistant. Furthermore, a proteomics approach led to the identification of compounds that alter SN neuronal survival, demonstrating the utility of our strategy for disease modeling and drug discovery.

Nolz1 expression is required in dopaminergic axon guidance and striatal innervation.

Midbrain dopaminergic (DA) axons make long longitudinal projections towards the striatum. Despite the importance of DA striatal innervation, processes involved in establishment of DA axonal connectivity remain largely unknown. Here we demonstrate a striatal-specific requirement of transcriptional regulator Nolz1 in establishing DA circuitry formation. DA projections are misguided and fail to innervate the striatum in both constitutive and striatal-specific Nolz1 mutant embryos. The lack of striatal Nolz1 expression results in nigral to pallidal lineage conversion of striatal projection neuron subtypes. This lineage switch alters the composition of secreted factors influencing DA axonal tract formation and renders the striatum non-permissive for dopaminergic and other forebrain tracts. Furthermore, transcriptomic analysis of wild-type and Nolz1-/- mutant striatal tissue led to the identification of several secreted factors that underlie the observed guidance defects and proteins that promote DA axonal outgrowth. Together, our data demonstrate the involvement of the striatum in orchestrating dopaminergic circuitry formation.

Sox6 and Otx2 control the specification of substantia nigra and ventral tegmental area dopamine neurons.

Distinct midbrain dopamine (mDA) neuron subtypes are found in the substantia nigra pars compacta (SNc) and the ventral tegmental area (VTA), but it is mainly SNc neurons that degenerate in Parkinson's disease. Interest in how mDA neurons develop has been stimulated by the potential use of stem cells in therapy or disease modeling. However, very little is known about how specific dopaminergic subtypes are generated. Here, we show that the expression profiles of the transcription factors Sox6, Otx2, and Nolz1 define subpopulations of mDA neurons already at the neural progenitor cell stage. After cell-cycle exit, Sox6 selectively localizes to SNc neurons, while Otx2 and Nolz1 are expressed in a subset of VTA neurons. Importantly, Sox6 ablation leads to decreased expression of SNc markers and a corresponding increase in VTA markers, while Otx2 ablation has the opposite effect. Moreover, deletion of Sox6 affects striatal innervation and dopamine levels. We also find reduced Sox6 levels in Parkinson's disease patients. These findings identify Sox6 as a determinant of SNc neuron development and should facilitate the engineering of relevant mDA neurons for cell therapy and disease modeling.

SoxB1-driven transcriptional network underlies neural-specific interpretation of morphogen signals.

The reiterative deployment of a small cadre of morphogen signals underlies patterning and growth of most tissues during embyogenesis, but how such inductive events result in tissue-specific responses remains poorly understood. By characterizing cis-regulatory modules (CRMs) associated with genes regulated by Sonic hedgehog (Shh), retinoids, or bone morphogenetic proteins in the CNS, we provide evidence that the neural-specific interpretation of morphogen signaling reflects a direct integration of these pathways with SoxB1 proteins at the CRM level. Moreover, expression of SoxB1 proteins in the limb bud confers on mesodermal cells the potential to activate neural-specific target genes upon Shh, retinoid, or bone morphogenetic protein signaling, and the collocation of binding sites for SoxB1 and morphogen-mediatory transcription factors in CRMs faithfully predicts neural-specific gene activity. Thus, an unexpectedly simple transcriptional paradigm appears to conceptually explain the neural-specific interpretation of pleiotropic signaling during vertebrate development. Importantly, genes induced in a SoxB1-dependent manner appear to constitute repressive gene regulatory networks that are directly interlinked at the CRM level to constrain the regional expression of patterning genes. Accordingly, not only does the topology of SoxB1-driven gene regulatory networks provide a tissue-specific mode of gene activation, but it also determines the spatial expression pattern of target genes within the developing neural tube.

Mechanistic differences in the transcriptional interpretation of local and long-range Shh morphogen signaling.

Morphogens orchestrate tissue patterning in a concentration-dependent fashion during vertebrate embryogenesis, yet little is known of how positional information provided by such signals is translated into discrete transcriptional outputs. Here we have identified and characterized cis-regulatory modules (CRMs) of genes operating downstream of graded Shh signaling and bifunctional Gli proteins in neural patterning. Unexpectedly, we find that Gli activators have a noninstructive role in long-range patterning and cooperate with SoxB1 proteins to facilitate a largely concentration-independent mode of gene activation. Instead, the opposing Gli-repressor gradient is interpreted at transcriptional levels, and, together with CRM-specific repressive input of homeodomain proteins, comprises a repressive network that translates graded Shh signaling into regional gene expression patterns. Moreover, local and long-range interpretation of Shh signaling differs with respect to CRM context sensitivity and Gli-activator dependence, and we propose that these differences provide insight into how morphogen function may have mechanistically evolved from an initially binary inductive event.

Tcf/Lef repressors differentially regulate Shh-Gli target gene activation thresholds to generate progenitor patterning in the developing CNS.

During neural tube development, Shh signaling through Gli transcription factors is necessary to establish five distinct ventral progenitor domains that give rise to unique classes of neurons and glia that arise in specific positions along the dorsoventral axis. These cells are generated from progenitors that display distinct transcription factor gene expression profiles in specific domains in the ventricular zone. However, the molecular genetic mechanisms that control the differential spatiotemporal transcriptional responses of progenitor target genes to graded Shh-Gli signaling remain unclear. The current study demonstrates a role for Tcf/Lef repressor activity in this process. We show that Tcf3 and Tcf7L2 (Tcf4) are required for proper ventral patterning and function by independently regulating two Shh-Gli target genes, Nkx2.2 and Olig2, which are initially induced in a common pool of progenitors that ultimately segregate into unique territories giving rise to distinct progeny. Genetic and functional studies in vivo show that Tcf transcriptional repressors selectively elevate the strength and duration of Gli activity necessary to induce Nkx2.2, but have no effect on Olig2, and thereby contribute to the establishment of their distinct expression domains in cooperation with graded Shh signaling. Together, our data reveal a Shh-Gli-independent transcriptional input that is required to shape the precise spatial and temporal response to extracellular morphogen signaling information during lineage segregation in the CNS.

Two functionally distinct Axin-like proteins regulate canonical Wnt signaling in C. elegans.

Axin is a central component of the canonical Wnt signaling pathway that interacts with the adenomatous polyposis coli protein APC and the kinase GSK3beta to downregulate the effector beta-catenin. In the nematode Caenorhabditis elegans, canonical Wnt signaling is negatively regulated by the highly divergent Axin ortholog PRY-1. Mutation of pry-1 leads to constitutive activation of BAR-1/beta-catenin-dependent Wnt signaling and results in a range of developmental defects. The pry-1 null phenotype is however not fully penetrant, indicating that additional factors may partially compensate for PRY-1 function. Here, we report the cloning and functional analysis of a second Axin-like protein, which we named AXL-1. We show that despite considerable sequence divergence with PRY-1 and other Axin family members, AXL-1 is a functional Axin ortholog. AXL-1 functions redundantly with PRY-1 in negatively regulating BAR-1/beta-catenin signaling in the developing vulva and the Q neuroblast lineage. In addition, AXL-1 functions independently of PRY-1 in negatively regulating canonical Wnt signaling during excretory cell development. In contrast to vertebrate Axin and the related protein Conductin, AXL-1 and PRY-1 are not functionally equivalent. We conclude that Axin function in C. elegans is divided over two different Axin orthologs that have specific functions in negatively regulating canonical Wnt signaling.

Expression of retinaldehyde dehydrogenase II and sequential activation of 5' Hoxb genes in the mouse caudal hindbrain.

The precise anterior boundaries of Hox expression domains are critical for correct antero-posterior (A-P) patterning of the vertebrate longitudinal axis. Retinoic acid (RA) signalling has been shown to play an important role in the specification of pre-otic rhombomere boundaries, and in the regulation of 3' Hox expression within this territory. In addition, we recently showed that RA signalling controls 5'Hoxb gene expression in the caudal hindbrain, which had not been discovered before. We show here that the expression domain of these 5'Hoxb genes undergoes a sequential, colinear rostral expansion between E9.5 and E11.5 in the caudal hindbrain, and that this differential expansion occurs just rostrally to the localisation of the transcripts for the RA biosynthetic enzyme Raldh2 in the cervical mesenchyme.

Randomly inserted and targeted Hox/reporter fusions transcriptionally silenced in Polycomb mutants.

Polycomb-group (Pc-G) proteins ensure late maintenance of transcriptional repression outside the expression domain of target genes in flies and vertebrates. They act in complexes, presumably by modulating chromatin structure. In Drosophila, they have been found to be associated with transcriptionally inactive loci but seem to be present in association with actively transcribed promoters as well, a feature which is not yet understood. In the mouse, mutations in several Pc-G genes result in an often subtle, local derepression of only a subset of the Hox genes rostral to their expression domains. We report here that Hox/reporter fusion genes, either randomly integrated as transgenes or as insertions within endogenous loci, are transcriptionally silenced in two mouse Pc-G-null mutants, Mel18 and rae28. Transcriptional silencing of Hox/reporter transgenes in Pc-G mutants was accompanied by increased DNA methylation in the promoter region. Gene silencing was observed at early developmental stages, long before Pc-G and trithorax-group proteins exert their function in maintenance of the Hox patterns. Although all five Hox genes tested as Hox/reporter fusions were silenced in the Pc-G mutants, transcription of the endogenous loci was mildly decreased in a subset of these Hox genes, and Hoxb1 was the most strongly affected. We discuss the possibilities that the observed negative effect of Pc-G mutations on Hox and Hox/reporter expression may reflect a positive involvement of the Pc-G epigenetic repressors in initial Hox gene transcription and that this requirement is exacerbated by the reporter insertion.

The direct context of a hox retinoic acid response element is crucial for its activity.

During embryogenesis, target genes of retinoid signaling are able to respond differently to identical concentrations of retinoids. Small differences in the retinoic acid response elements (RARE) may be essential for these distinct responses. Recently, we identified a RARE in a Hox enhancer (dubbed distal element) that is active relatively late during mouse development. We now show that the RARE motif in the distal element is necessary and sufficient for the induction of gene expression by retinoic acid (RA) in P19 embryonic carcinoma cells. Furthermore, the significance of these results was established by RA treatment of transgenic mouse lines carrying the distal element containing the wild-type or a mutated RARE. We compared the in vitro activity of the distal element-RARE with that of the direct repeat with 5-bp spacer RARE of the RARbeta2 gene, which is active during early during mouse development. We found that these RAREs, despite their similarity, responded differently to RA. By making single point mutations we show that the specificity resides in their retinoid X receptor-binding sites and is determined by base pairs located just outside the RARE consensus sequence. We suggest that the context of RARE motifs is important for the distinct transcriptional activities of genes under control of retinoid signaling.

Retinoids regulate the anterior expression boundaries of 5' Hoxb genes in posterior hindbrain.

We describe the regulatory interactions that cause anterior extension of the mouse 5' Hoxb expression domains from spinal cord levels to their definitive boundaries in the posterior hindbrain between embryonic day E10 and E11.5. This anterior expansion is retinoid dependent since it does not occur in mouse embryos deficient for the retinoic acid-synthesizing enzyme retinaldehyde dehydrogenase 2. A retinoic acid response element (RARE) was identified downstream of Hoxb5 and shown to be essential for expression of Hoxb5 and Hoxb8 reporter transgenes in the anterior neural tube. The spatio-temporal activity of this element overlaps with rostral extension of the expression domain of endogenous Hoxb5, Hoxb6 and Hoxb8 into the posterior hindbrain. The RARE and surrounding sequences are found at homologous positions in the human, mouse and zebrafish genome, which supports an evolutionarily conserved regulatory function.