Nanog safeguards pluripotency and mediates germline development.

Nanog is a divergent homeodomain protein found in mammalian pluripotent cells and developing germ cells. Deletion of Nanog causes early embryonic lethality, whereas constitutive expression enables autonomous self-renewal of embryonic stem cells. Nanog is accordingly considered a core element of the pluripotent transcriptional network. However, here we report that Nanog fluctuates in mouse embryonic stem cells. Transient downregulation of Nanog appears to predispose cells towards differentiation but does not mark commitment. By genetic deletion we show that, although they are prone to differentiate, embryonic stem cells can self-renew indefinitely in the permanent absence of Nanog. Expanded Nanog null cells colonize embryonic germ layers and exhibit multilineage differentiation both in fetal and adult chimaeras. Although they are also recruited to the germ line, primordial germ cells lacking Nanog fail to mature on reaching the genital ridge. This defect is rescued by repair of the mutant allele. Thus Nanog is dispensible for expression of somatic pluripotency but is specifically required for formation of germ cells. Nanog therefore acts primarily in construction of inner cell mass and germ cell states rather than in the housekeeping machinery of pluripotency. We surmise that Nanog stabilizes embryonic stem cells in culture by resisting or reversing alternative gene expression states.

Fibroblast growth factor induces a neural stem cell phenotype in foetal forebrain progenitors and during embryonic stem cell differentiation.

Neural stem (NS) cell lines may be derived via differentiation of pluripotent embryonic stem (ES) cells or from foetal forebrain. However, because NS cells arise in vitro from heterogeneous populations their immediate cellular origin remains unclear. We used microarray-based expression profiling to identify a set of markers expressed by mouse NS cells but not ES cells. One differentially expressed gene encodes the cell surface protein, CD44. CD44 expression is activated by FGF-2 in a subset of cells in both differentiating ES cells and foetal forebrain cultures. Following isolation by flow cytometry the CD44+ population was found to be highly enriched for NS cell founders. We found that other NS cell marker genes are also induced by FGF in culture, including: Adam12, Cadherin20, Cx3cl1, EGFR, Frizzled9, Kitl, Olig1, Olig2 and Vav3. We speculate that the self-renewing NS cell state may be generated in vitro following transcriptional resetting induced by FGF.

Bmp, Fgf and Wnt signalling in programmed cell death and chondrogenesis during vertebrate limb development: the role of Dickkopf-1.

Dickkopf-1 (Dkk-1) is a potent head inducer in Xenopus. This effect can be attributed to its capability to specifically inhibit Wnt/beta-catenin signalling. Recent data point to a crucial role for Dkk-1 in the control of programmed cell death during vertebrate limb development. In this paper, we present a comparative expression analysis of Dkk-1, Bmp-4 and Sox-9 as well as data on the regulation of Dkk-1 by Wnt. Finally, we summarize the current knowledge of its potential function in the developing limb and present a model how the interplay of the Bmp, Fgf and Wnt signalling pathways might differentially regulate programmed cell death versus chondrogenic differentiation in limb mesodermal cells.

Oct4 and LIF/Stat3 additively induce Krüppel factors to sustain embryonic stem cell self-renewal.

Embryonic stem cell (ESC) pluripotency is dependent on an intrinsic gene regulatory network centered on Oct4. Propagation of the pluripotent state is stimulated by the cytokine leukemia inhibitory factor (LIF) acting through the transcriptional regulator Stat3. Here, we show that this extrinsic stimulus converges with the intrinsic circuitry in Krüppel-factor activation. Oct4 primarily induces Klf2 while LIF/Stat3 selectively enhances Klf4 expression. Overexpression of either factor reduces LIF dependence, but with quantitative and qualitative differences. Unlike Klf4, Klf2 increases ESC clonogenicity, maintains undifferentiated ESCs in the genetic absence of Stat3, and confers resistance to BMP-induced differentiation. ESCs expanded with Klf2 remain capable of contributing to adult chimeras. Postimplantation-embryo-derived EpiSCs lack both Klf2 and Klf4 and expression of either can reinstate naive pluripotency. These findings indicate that Oct4 and Stat3 intersect in directing expression of Klf transcriptional regulators with overlapping properties that additively reinforce ground-state ESC pluripotency, identity, and self-renewal.

Comparative proteomic analysis reveals a function of the novel death receptor-associated protein BRE in the regulation of prohibitin and p53 expression and proliferation.

The brain and reproductive organ expressed (BRE) gene encodes a highly conserved stress-modulating protein. To gain further insight into the function of this gene, we used comparative proteomics to investigate the protein profiles of C2C12 and D122 cells resulting from small interfering RNA (siRNA)-mediated silencing as well as overexpression of BRE. Silencing of BRE in C2C12 cells, using siRNA, resulted in up-regulated Akt-3 and carbonic anhydrase III expression, while the 26S proteasome regulatory subunit S14 and prohibitin were down-regulated. Prohibitin is a potential tumour suppressor gene, which can directly interact with p53. We found that cell proliferation was significantly increased after knockdown of BRE, concomitant with reduced p53 and prohibitin expression. In contrast, we observed decreased proliferation and up-regulation of p53 and prohibitin when BRE was overexpressed in the D122 cell line. In total, five proteins were found to be up-regulated after BRE over-expression. The majority of these proteins can target or crosstalk with NF-kappaB, which plays a central role in regulating cell proliferation, differentiation and survival. Our results establish a crucial role for BRE in the regulation of key proteins of the cellular stress-response machinery and provide an explanation for the multifunctional nature of BRE.

The Fused toes (Ft) mouse mutation causes anteroposterior and dorsoventral polydactyly.

Mouse mutants have been proven to be a valuable system to analyze the molecular network governing vertebrate limb development. In the present study, we report on the molecular and morphological consequences of the Fused toes (Ft) mutation on limb morphogenesis in homozygous embryos. We show that Ft affects all three axes as the mutant limbs display severe distal truncations of skeletal elements as well as an anteroposterior and an unusual form of dorsoventral polydactyly. Ectopic activation of the Shh signalling cascade in the distal-most mesoderm together with malformations of the AER likely account for these alterations. Moreover, we provide evidence that a deregulated control of programmed cell death triggered by Bmp-4 and Dkk-1 significantly contributes to the complex limb phenotype. In addition, our analysis reveals a specific requirement of the genes deleted by the Ft mutation in hindlimb morphogenesis.

The Wnt antagonist Dickkopf-1 is regulated by Bmp signaling and c-Jun and modulates programmed cell death.

Dickkopf-1 (Dkk-1) has been shown to be a potent inhibitor of Wnt/beta-catenin signaling in a variety of assays and organisms. In this study, we show that expression of Dkk-1 overlaps significantly with the sites of programmed cell death in normal as well as mutant vertebrate limb development, and identify several of its upstream regulators, one of which is Bmp-4. Interestingly, Bmp-4 only activates Dkk-1 when it concomitantly induces apoptosis. Moreover, Dkk-1 is heavily up-regulated by UV irradiation and several other genotoxic stimuli. We further show that normal expression of Dkk-1 is dependent on the Ap-1 family member c-Jun and that overexpression of Dkk-1 enhances Bmp-triggered apoptosis in the vertebrate limb. Taken together, our results provide evidence for an important role of Dkk-1-mediated inhibition of Wnt/beta-catenin signaling in response to different stress signals that all converge on the activation of c-Jun in vivo.

Pallister-Hall syndrome phenotype in mice mutant for Gli3.

Mutations in the GLI3 gene have been identified in several human malformation syndromes. One of these autosomal dominant developmental disorders is Pallister-Hall syndrome (PHS; MIM146510), which is associated with central polydactyly and other malformations. Interestingly, the mutations in the GLI3 transcription factor gene identified in patients with PHS are restricted to the region 3' of the zinc finger-encoding domain, leaving this DNA-binding domain intact. We have investigated the consequences of this mutation on the development of multiple organ systems by introducing a targeted mutation in mice. We found that mice homozygous for the mutation showed a central polydactyly, thus modeling one of the major abnormalities of the human syndrome. Moreover, Gli3-mutant mice displayed a wide range of developmental abnormalities encompassing almost all of the common PHS features, including imperforate anus, gastrointestinal, epiglottis and larynx defects, abnormal kidney development, and absence of adrenal glands. Thus, our Gli3-mutant mice provide an excellent model for studies of both the pathogenesis of PHS and Gli3 functions in the development of the affected organ systems.

Wnt and Bmp signalling cooperatively regulate graded Emx2 expression in the dorsal telencephalon.

Pattern formation of the dorsal telencephalon is governed by a regionalisation process that leads to the formation of distinct domains, including the future hippocampus and neocortex. Recent studies have implicated signalling proteins of the Wnt and Bmp gene families as well as several transcription factors, including Gli3 and the Emx homeobox genes, in the molecular control of this process. The regulatory relationships between these genes, however, remain largely unknown. We have used transgenic analysis to investigate the upstream mechanisms for regulation of Emx2 in the dorsal telencephalon. We have identified an enhancer from the mouse Emx2 gene that drives specific expression of a lacZ reporter gene in the dorsal telencephalon. This element contains binding sites for Tcf and Smad proteins, transcriptional mediators of the Wnt and Bmp signalling pathway, respectively. Mutations of these binding sites abolish telencephalic enhancer activity, while ectopic expression of these signalling pathways leads to ectopic activation of the enhancer. These results establish Emx2 as a direct transcriptional target of Wnt and Bmp signalling and provide insights into a genetic hierarchy involving Gli3, Emx2 and Bmp and Wnt genes in the control of dorsal telencephalic development.