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1.
Development ; 140(18): 3799-808, 2013 Sep.
Article in English | MEDLINE | ID: mdl-23924634

ABSTRACT

Genetic regulation of the cell fate transition from lateral plate mesoderm to the specification of cardiomyocytes requires suppression of Wnt/ß-catenin signaling, but the mechanism for this is not well understood. By analyzing gene expression and chromatin dynamics during directed differentiation of human embryonic stem cells (hESCs), we identified a suppressor of Wnt/ß-catenin signaling, transmembrane protein 88 (TMEM88), as a potential regulator of cardiovascular progenitor cell (CVP) specification. During the transition from mesoderm to the CVP, TMEM88 has a chromatin signature of genes that mediate cell fate decisions, and its expression is highly upregulated in advance of key cardiac transcription factors in vitro and in vivo. In early zebrafish embryos, tmem88a is expressed broadly in the lateral plate mesoderm, including the bilateral heart fields. Short hairpin RNA targeting of TMEM88 during hESC cardiac differentiation increases Wnt/ß-catenin signaling, confirming its role as a suppressor of this pathway. TMEM88 knockdown has no effect on NKX2.5 or GATA4 expression, but 80% of genes most highly induced during CVP development have reduced expression, suggesting adoption of a new cell fate. In support of this, analysis of later stage cell differentiation showed that TMEM88 knockdown inhibits cardiomyocyte differentiation and promotes endothelial differentiation. Taken together, TMEM88 is crucial for heart development and acts downstream of GATA factors in the pre-cardiac mesoderm to specify lineage commitment of cardiomyocyte development through inhibition of Wnt/ß-catenin signaling.


Subject(s)
Membrane Proteins/metabolism , Myocytes, Cardiac/cytology , Myocytes, Cardiac/metabolism , Wnt Proteins/metabolism , Zebrafish Proteins/metabolism , Zebrafish/embryology , Animals , Cell Lineage/genetics , Down-Regulation/genetics , Embryo, Nonmammalian/cytology , Embryo, Nonmammalian/metabolism , Endothelial Cells/cytology , Endothelial Cells/metabolism , Gene Expression Regulation, Developmental , Gene Knockdown Techniques , Humans , Membrane Proteins/genetics , Mice , Models, Biological , Signal Transduction/genetics , Stem Cells/cytology , Stem Cells/metabolism , Up-Regulation/genetics , Zebrafish/genetics , Zebrafish Proteins/genetics , beta Catenin/metabolism
2.
Cell ; 151(1): 221-32, 2012 Sep 28.
Article in English | MEDLINE | ID: mdl-22981225

ABSTRACT

Directed differentiation of human embryonic stem cells (ESCs) into cardiovascular cells provides a model for studying molecular mechanisms of human cardiovascular development. Although it is known that chromatin modification patterns in ESCs differ markedly from those in lineage-committed progenitors and differentiated cells, the temporal dynamics of chromatin alterations during differentiation along a defined lineage have not been studied. We show that differentiation of human ESCs into cardiovascular cells is accompanied by programmed temporal alterations in chromatin structure that distinguish key regulators of cardiovascular development from other genes. We used this temporal chromatin signature to identify regulators of cardiac development, including the homeobox gene MEIS2. Using the zebrafish model, we demonstrate that MEIS2 is critical for proper heart tube formation and subsequent cardiac looping. Temporal chromatin signatures should be broadly applicable to other models of stem cell differentiation to identify regulators and provide key insights into major developmental decisions.


Subject(s)
Cell Differentiation , Chromatin , Embryonic Stem Cells/metabolism , Heart/embryology , Myocardium/cytology , Animals , Epigenesis, Genetic , Homeodomain Proteins/metabolism , Humans , Zebrafish/embryology , Zebrafish Proteins/metabolism
3.
Cell ; 136(6): 1136-47, 2009 Mar 20.
Article in English | MEDLINE | ID: mdl-19303855

ABSTRACT

Interactions between developmental signaling pathways govern the formation and function of stem cells. Prostaglandin (PG) E2 regulates vertebrate hematopoietic stem cells (HSC). Similarly, the Wnt signaling pathway controls HSC self-renewal and bone marrow repopulation. Here, we show that wnt reporter activity in zebrafish HSCs is responsive to PGE2 modulation, demonstrating a direct interaction in vivo. Inhibition of PGE2 synthesis blocked wnt-induced alterations in HSC formation. PGE2 modified the wnt signaling cascade at the level of beta-catenin degradation through cAMP/PKA-mediated stabilizing phosphorylation events. The PGE2/Wnt interaction regulated murine stem and progenitor populations in vitro in hematopoietic ES cell assays and in vivo following transplantation. The relationship between PGE2 and Wnt was also conserved during regeneration of other organ systems. Our work provides in vivo evidence that Wnt activation in stem cells requires PGE2, and suggests the PGE2/Wnt interaction is a master regulator of vertebrate regeneration and recovery.


Subject(s)
Dinoprostone/metabolism , Embryonic Development , Hematopoietic Stem Cells/metabolism , Wnt Proteins/metabolism , Zebrafish/metabolism , Animals , Cell Proliferation , Cell Survival , Embryonic Stem Cells/metabolism , Liver/physiology , Mice , Regeneration , Signal Transduction , Zebrafish/embryology , beta Catenin/metabolism
4.
Sci Signal ; 1(45): ra12, 2008 Nov 11.
Article in English | MEDLINE | ID: mdl-19001663

ABSTRACT

The identification and characterization of previously unidentified signal transduction molecules has expanded our understanding of biological systems and facilitated the development of mechanism-based therapeutics. We present a highly validated small interfering RNA (siRNA) screen that functionally annotates the human genome for modulation of the Wnt/beta-catenin signal transduction pathway. Merging these functional data with an extensive Wnt/beta-catenin protein interaction network produces an integrated physical and functional map of the pathway. The power of this approach is illustrated by the positioning of siRNA screen hits into discrete physical complexes of proteins. Similarly, this approach allows one to filter discoveries made through protein-protein interaction screens for functional contribution to the phenotype of interest. Using this methodology, we characterized AGGF1 as a nuclear chromatin-associated protein that participates in beta-catenin-mediated transcription in human colon cancer cells.


Subject(s)
Trans-Activators/metabolism , Wnt Proteins/physiology , beta Catenin/physiology , Angiogenic Proteins/genetics , Angiogenic Proteins/physiology , Cell Line, Tumor , Colonic Neoplasms , Gene Expression Profiling , Genome, Human , Humans , Protein Binding , Protein Interaction Mapping , RNA, Small Interfering/metabolism , Signal Transduction , Wnt Proteins/genetics , beta Catenin/genetics
5.
Hum Mol Genet ; 17(3): 402-12, 2008 Feb 01.
Article in English | MEDLINE | ID: mdl-17981814

ABSTRACT

Missense mutations in the PRESENILIN1 (PSEN1) gene frequently underlie familial Alzheimer's disease (FAD). Nonsense and most splicing mutations result in the synthesis of truncated peptides, and it has been assumed that truncated PSEN1 protein is functionless so that heterozygotes for these mutations are unaffected. Some FAD mutations affecting PSEN1 mRNA splicing cause loss of exon 8 or 9 sequences while maintaining the reading frame. We attempted to model these exon-loss mutations in zebrafish embryos by injecting morpholino antisense oligonucleotides (morpholinos) directed against splice acceptor sites in zebrafish psen1 transcripts. However, this produced cryptic changes in splicing potentially forming mRNAs encoding truncated presenilin proteins. Aberrant splicing in the region between exons 6 and 8 produces potent dominant negative effects on Psen1 protein activity, including Notch signalling, and causes a hydrocephalus phenotype. Reductions in Psen1 activity feedback positively to increase psen1 transcription through a mechanism apparently independent of gamma-secretase. We present evidence that the dominant negative effects are mediated through production of truncated Psen1 peptides that interfere with the normal activity of both Psen1 and Psen2. Mutations causing such truncations would be dominant lethal in embryo development. Somatic cellular changes in ageing cells that interfere with PSEN1 splicing, or otherwise cause protein truncation, might contribute to sporadic Alzheimer's disease, cancer and other diseases.


Subject(s)
Mutation , Presenilin-1/genetics , Presenilin-1/metabolism , RNA Splicing , Zebrafish Proteins/genetics , Zebrafish Proteins/metabolism , Zebrafish/genetics , Zebrafish/metabolism , Alzheimer Disease/genetics , Alzheimer Disease/metabolism , Animals , Base Sequence , Cell Line , Codon, Nonsense , DNA Primers/genetics , Disease Models, Animal , Exons , Humans , Hydrocephalus/embryology , Hydrocephalus/genetics , Mutation, Missense , Oligodeoxyribonucleotides, Antisense/genetics , Phenotype , Pick Disease of the Brain/genetics , Presenilin-1/chemistry , Presenilin-2/chemistry , Presenilin-2/genetics , Presenilin-2/metabolism , Protein Biosynthesis , Transcription, Genetic , Zebrafish/embryology , Zebrafish Proteins/chemistry
6.
Genes Dev ; 21(11): 1292-315, 2007 Jun 01.
Article in English | MEDLINE | ID: mdl-17545465

ABSTRACT

While all animals have evolved strategies to respond to injury and disease, their ability to functionally recover from loss of or damage to organs or appendages varies widely damage to skeletal muscle, but, unlike amphibians and fish, they fail to regenerate heart, lens, retina, or appendages. The relatively young field of regenerative medicine strives to develop therapies aimed at improving regenerative processes in humans and is predicated on >40 years of success with bone marrow transplants. Further progress will be accelerated by implementing knowledge about the molecular mechanisms that regulate regenerative processes in model organisms that naturally possess the ability to regenerate organs and/or appendages. In this review we summarize the current knowledge about the signaling pathways that regulate regeneration of amphibian and fish appendages, fish heart, and mammalian liver and skeletal muscle. While the cellular mechanisms and the cell types involved in regeneration of these systems vary widely, it is evident that shared signals are involved in tissue regeneration. Signals provided by the immune system appear to act as triggers of many regenerative processes. Subsequently, pathways that are best known for their importance in regulating embryonic development, in particular fibroblast growth factor (FGF) and Wnt/beta-catenin signaling (as well as others), are required for progenitor cell formation or activation and for cell proliferation and specification leading to tissue regrowth. Experimental activation of these pathways or interference with signals that inhibit regenerative processes can augment or even trigger regeneration in certain contexts.


Subject(s)
Muscle, Skeletal/physiology , Regeneration/physiology , Regenerative Medicine , Signal Transduction , Animals , Humans , Vertebrates/physiology
7.
Dev Biol ; 306(1): 170-8, 2007 Jun 01.
Article in English | MEDLINE | ID: mdl-17442299

ABSTRACT

Anuran (frog) tadpoles and urodeles (newts and salamanders) are the only vertebrates capable of fully regenerating amputated limbs. During the early stages of regeneration these amphibians form a "blastema", a group of mesenchymal progenitor cells that specifically directs the regrowth of the limb. We report that wnt-3a is expressed in the apical epithelium of regenerating Xenopus laevis limb buds, at the appropriate time and place to play a role during blastema formation. To test whether Wnt/beta-catenin signaling is required for limb regeneration, we created transgenic X. laevis tadpoles that express Dickkopf-1 (Dkk1), a specific inhibitor of Wnt/beta-catenin signaling, under the control of a heat-shock promoter. Heat-shock immediately before limb amputation or during early blastema formation blocked limb regeneration but did not affect the development of contralateral, un-amputated limb buds. When the transgenic tadpoles were heat-shocked following the formation of a blastema, however, they retained the ability to regenerate partial hindlimb structures. Furthermore, heat-shock induced Dkk1 blocked fgf-8 but not fgf-10 expression in the blastema. We conclude that Wnt/beta-catenin signaling has an essential role during the early stages of limb regeneration, but is not absolutely required after blastema formation.


Subject(s)
Extremities/physiology , Regeneration , Wnt Proteins/physiology , beta Catenin/physiology , Animals , Animals, Genetically Modified , Fibroblast Growth Factor 10/analysis , Fibroblast Growth Factor 10/antagonists & inhibitors , Fibroblast Growth Factor 10/metabolism , Fibroblast Growth Factor 8/analysis , Fibroblast Growth Factor 8/antagonists & inhibitors , Fibroblast Growth Factor 8/metabolism , HSP70 Heat-Shock Proteins/genetics , Intercellular Signaling Peptides and Proteins/genetics , Limb Buds , Promoter Regions, Genetic , Signal Transduction , Wnt Proteins/antagonists & inhibitors , Wnt Proteins/metabolism , Wnt3 Protein , Wnt3A Protein , Xenopus Proteins/genetics , Xenopus laevis , beta Catenin/antagonists & inhibitors , beta Catenin/metabolism
8.
Development ; 134(3): 479-89, 2007 Feb.
Article in English | MEDLINE | ID: mdl-17185322

ABSTRACT

In contrast to mammals, lower vertebrates have a remarkable capacity to regenerate complex structures damaged by injury or disease. This process, termed epimorphic regeneration, involves progenitor cells created through the reprogramming of differentiated cells or through the activation of resident stem cells. Wnt/beta-catenin signaling regulates progenitor cell fate and proliferation during embryonic development and stem cell function in adults, but its functional involvement in epimorphic regeneration has not been addressed. Using transgenic fish lines, we show that Wnt/beta-catenin signaling is activated in the regenerating zebrafish tail fin and is required for formation and subsequent proliferation of the progenitor cells of the blastema. Wnt/beta-catenin signaling appears to act upstream of FGF signaling, which has recently been found to be essential for fin regeneration. Intriguingly, increased Wnt/beta-catenin signaling is sufficient to augment regeneration, as tail fins regenerate faster in fish heterozygous for a loss-of-function mutation in axin1, a negative regulator of the pathway. Likewise, activation of Wnt/beta-catenin signaling by overexpression of wnt8 increases proliferation of progenitor cells in the regenerating fin. By contrast, overexpression of wnt5b (pipetail) reduces expression of Wnt/beta-catenin target genes, impairs proliferation of progenitors and inhibits fin regeneration. Importantly, fin regeneration is accelerated in wnt5b mutant fish. These data suggest that Wnt/beta-catenin signaling promotes regeneration, whereas a distinct pathway activated by wnt5b acts in a negative-feedback loop to limit regeneration.


Subject(s)
Regeneration/physiology , Wnt Proteins/physiology , Zebrafish Proteins/physiology , Zebrafish/physiology , Adult Stem Cells/cytology , Adult Stem Cells/physiology , Animals , Animals, Genetically Modified , Base Sequence , DNA Primers/genetics , Feedback , Regeneration/genetics , Signal Transduction , Tail , Wnt Proteins/genetics , Wnt-5a Protein , Zebrafish/genetics , Zebrafish Proteins/genetics , beta Catenin/genetics , beta Catenin/physiology
9.
Nat Genet ; 39(1): 106-12, 2007 Jan.
Article in English | MEDLINE | ID: mdl-17128274

ABSTRACT

Fungiform taste papillae form a regular array on the dorsal tongue. Taste buds arise from papilla epithelium and, unusually for epithelial derivatives, synapse with neurons, release neurotransmitters and generate receptor and action potentials. Despite the importance of taste as one of our five senses, genetic analyses of taste papilla and bud development are lacking. We demonstrate that Wnt-beta-catenin signaling is activated in developing fungiform placodes and taste bud cells. A dominant stabilizing mutation of epithelial beta-catenin causes massive overproduction of enlarged fungiform papillae and taste buds. Likewise, genetic deletion of epithelial beta-catenin or inhibition of Wnt-beta-catenin signaling by ectopic dickkopf1 (Dkk1) blocks initiation of fungiform papilla morphogenesis. Ectopic papillae are innervated in the stabilizing beta-catenin mutant, whereas ectopic Dkk1 causes absence of lingual epithelial innervation. Thus, Wnt-beta-catenin signaling is critical for fungiform papilla and taste bud development. Altered regulation of this pathway may underlie evolutionary changes in taste papilla patterning.


Subject(s)
Taste Buds/embryology , Wnt Proteins/physiology , beta Catenin/physiology , Animals , Animals, Newborn , Cells, Cultured , Female , Intercellular Signaling Peptides and Proteins/genetics , Mice , Mice, Transgenic , Morphogenesis/genetics , Pregnancy , Signal Transduction/genetics , Taste Buds/growth & development , beta Catenin/genetics
10.
Arch Histol Cytol ; 69(3): 189-98, 2006 Sep.
Article in English | MEDLINE | ID: mdl-17031025

ABSTRACT

Taste buds are multicellular receptor organs embedded in the lingual epithelium of vertebrates. Taste cells within these buds are modified epithelial cells as they lack axons and turnover rapidly throughout life, yet have neuronal properties enabling them to transduce taste stimuli and transmit this information to the nervous system. Taste cells are heterogeneous, comprising types I, II, III and basal cells, and are continually replaced during adult life, raising the question of how these different cells are generated. The molecular mechanisms governing taste cell differentiation are unknown, but the Notch signaling system has been implicated in this process based upon recent gene expression data. Here we investigate the expression in mature taste buds of Notch related transcription factors, Hes6 and Mash1, which are among the first genes expressed in embryonic taste buds. We further compare these patterns with those of immunocytochemical markers of discrete taste cell types. We find that Hes6 is expressed in a subset of basally located, possibly progenitor cells, yet is rarely coexpressed with taste cell markers. In contrast, Mash1 is detected in some basal cells and in the majority of differentiated type III taste cells, but never in type II cells. These data suggest a role for Notch signaling in taste cell differentiation in adult taste buds.


Subject(s)
Basic Helix-Loop-Helix Transcription Factors/biosynthesis , Repressor Proteins/biosynthesis , Taste Buds/cytology , Taste Buds/metabolism , Animals , Cell Differentiation/physiology , Fluorescent Antibody Technique , Immunohistochemistry , In Situ Hybridization , Mice
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