Arun Padmanabhan

Ataxin-2 intermediate-length polyglutamine expansions are associated with increased risk for ALS

The causes of amyotrophic lateral sclerosis (ALS), a devastating human neurodegenerative disease, are poorly understood, although the protein TDP-43 has been suggested to have a critical role in disease pathogenesis. Here we show that ataxin 2 (ATXN2), a polyglutamine (polyQ) protein mutated in spinocerebellar ataxia type 2, is a potent modifier of TDP-43 toxicity in animal and cellular models. ATXN2 and TDP-43 associate in a complex that depends on RNA. In spinal cord neurons of ALS patients, ATXN2 is abnormally localized; likewise, TDP-43 shows mislocalization in spinocerebellar ataxia type 2. To assess the involvement of ATXN2 in ALS, we analysed the length of the polyQ repeat in the ATXN2 gene in 915 ALS patients. We found that intermediate-length polyQ expansions (27–33 glutamines) in ATXN2 were significantly associated with ALS. These data establish ATXN2 as a relatively common ALS susceptibility gene. Furthermore, these findings indicate that the TDP-43–ATXN2 interaction may be a promising target for therapeutic intervention in ALS and other TDP-43 proteinopathies.

Rapid 3D phenotyping of cardiovascular development in mouse embryos by micro-CT with iodine staining.

Background—Microcomputed tomography (micro-CT) has been used extensively in research to generate high-resolution 3D images of calcified tissues in small animals nondestructively. It has been especially useful for the characterization of skeletal mutations but limited in its utility for the analysis of soft tissue such as the cardiovascular system. Visualization of the cardiovascular system has been largely restricted to structures that can be filled with radiopaque intravascular contrast agents in adult animals. Recent ex vivo studies using osmium tetroxide, iodinated contrast agents, inorganic iodine, and phosphotungstic acid have demonstrated the ability to stain soft tissues differentially, allowing for high intertissue contrast in micro-CT images. In the present study, we demonstrate the application of this technology for visualization of cardiovascular structures in developing mouse embryos using Lugol solution (aqueous potassium iodide plus iodine). Methods and Results—We show the optimization of this method to obtain ex vivo micro-CT images of embryonic and neonatal mice with excellent soft-tissue contrast. We demonstrate the utility of this method to visualize key structures during cardiovascular development at various stages of embryogenesis. Our method benefits from the ease of sample preparation, low toxicity, and low cost. Furthermore, we show how multiple cardiac defects can be demonstrated by micro-CT in a single specimen with a known genetic lesion. Indeed, a previously undescribed cardiac venous abnormality is revealed in a PlexinD1 mutant mouse. Conclusions—Micro-CT of iodine-stained tissue is a valuable technique for the characterization of cardiovascular development and defects in mouse models of congenital heart disease.

Plasticity of Hopx+ Type I alveolar cells to regenerate Type II cells in the lung

The plasticity of differentiated cells in adult tissues undergoing repair is an area of intense research. Pulmonary alveolar Type II cells produce surfactant and function as progenitors in the adult, demonstrating both self-renewal and differentiation into gas exchanging Type I cells. In vivo, Type I cells are thought to be terminally differentiated and their ability to give rise to alternate lineages has not been reported. Here, we show that Hopx becomes restricted to Type I cells during development. However, unexpectedly, lineage-labeled Hopx+ cells both proliferate and generate Type II cells during adult alveolar regrowth following partial pneumonectomy. In clonal 3D culture, single Hopx+ Type I cells generate organoids composed of Type I and Type II cells, a process modulated by TGFβ signaling. These findings demonstrate unanticipated plasticity of Type I cells and a bi-directional lineage relationship between distinct differentiated alveolar epithelial cell types in vivo and in single cell culture.

Evaluation and application of modularly assembled zinc-finger nucleases in zebrafish.

Zinc-finger nucleases (ZFNs) allow targeted gene inactivation in a wide range of model organisms. However, construction of target-specific ZFNs is technically challenging. Here, we evaluate a straightforward modular assembly-based approach for ZFN construction and gene inactivation in zebrafish. From an archive of 27 different zinc-finger modules, we assembled more than 70 different zinc-finger cassettes and evaluated their specificity using a bacterial one-hybrid assay. In parallel, we constructed ZFNs from these cassettes and tested their ability to induce lesions in zebrafish embryos. We found that the majority of zinc-finger proteins assembled from these modules have favorable specificities and nearly one-third of modular ZFNs generated lesions at their targets in the zebrafish genome. To facilitate the application of ZFNs within the zebrafish community we constructed a public database of sites in the zebrafish genome that can be targeted using this archive. Importantly, we generated new germline mutations in eight different genes, confirming that this is a viable platform for heritable gene inactivation in vertebrates. Characterization of one of these mutants, gata2a, revealed an unexpected role for this transcription factor in vascular development. This work provides a resource to allow targeted germline gene inactivation in zebrafish and highlights the benefit of a definitive reverse genetic strategy to reveal gene function.

Integration of Bmp and Wnt signaling by Hopx specifies commitment of cardiomyoblasts

Making cardiomyocytes In the heart, multiple cell types work together. Cardiac progenitor cells give rise to cardiomyocyte, endothelial, or smooth muscle lineages. However, the identity of a marker specific to cardiomyocyte formation has been elusive. Jain et al. now identify a specialized progenitor population that is committed exclusively to forming cardiomyocytes. They also identify the niche signals that promote lineage commitment and the mechanisms involved in making cardiomyocytes. The findings may help in the development of future cell-based regenerative therapeutics for heart disease. Science, this issue 10.1126/science.aaa6071 Identification of the committed cardiomyoblast that retains proliferative potential may inform cardiac regenerative therapeutics. INTRODUCTION Cardiac progenitor cells are multipotent, and lineage analyses of murine and chick cardiac development have demonstrated that these cells give rise to the cardiac endothelium, smooth muscle, and cardiomyocytes. However, the mechanisms governing commitment to the myocyte lineage in vivo remain largely unknown. Further understanding of these mechanisms, and of the identity of progenitors committed to the myocyte lineage, may advance cardiac regenerative therapies. RATIONALE Hopx is an atypical homeodomain expressed in cardiac mesoderm shortly after cardiac progenitor cells are first evident. Previous studies have demonstrated that Hopx functions as a nuclear transcription co-repressor and is expressed in adult, +4 intestinal stem cells and hair follicle bulge stem cells. We compare lineage tracing of multipotent cardiac progenitor cells marked by Islet1 and Nkx2-5 expression with lineage tracing of Hopx+ cells. We also perform functional studies of Hopx from endogenous tissue and differentiated embryoid bodies to identify mechanisms promoting commitment and myogenesis. RESULTS We define and characterize a Hopx-expressing cardiomyoblast intermediate that is committed to the cardiomyocyte fate. Hopx+ is initially expressed in a subset of cardiac progenitor cells residing in the precardiac mesoderm prior to the expression of troponin T, a component of the contractile sarcomere apparatus of myocytes. Lineage-tracing experiments demonstrate that Hopx+ cells give rise to cardiac myocytes exclusively. Early Hopx+ cardiomyoblasts expand during cardiogenesis. Overexpression of Hopx in cardiac progenitor cells leads to an increase in myocytes, whereas Hopx deficiency compromises myogenesis. Whole-genome analysis reveals that Hopx occupies regulatory regions of multiple Wnt-related genes, and Hopx–/– cardiac tissues are characterized by an expansion of Wnt signaling. Restoration of Wnt levels during differentiation of Hopx–/– embryoid bodies partially rescues myogenesis. Wnt signaling is a potent regulator of stemness of cardiac progenitor cells, and our data suggest that Hopx promotes myogenesis by repressing Wnt signaling. Cardiac progenitor cells down-regulate Wnt signaling as they enter the cardiac outflow tract, coincident with the expression of Hopx. The outflow tract is also enriched for bone morphogenetic protein (Bmp) signaling, known to influence differentiation of myocytes. Hopx physically interacts with activated Smad complexes in vitro and in vivo. Exogenous Bmp4 represses Wnt signaling in cardiac explants, and Bmp4-mediated Wnt repression requires Hopx. Thus, Hopx functions to couple Bmp signaling to repression of Wnt. CONCLUSION Our work defines an intermediate cardiac progenitor that expresses Hopx and is committed exclusively to the myocyte fate. Therefore, akin to an erythroblast in hematopoietic differentiation, we have termed these committed cardiac progenitor cells “cardiomyoblasts.” The ability to identify committed, but undifferentiated, cardiomyocyte precursors may facilitate development of cardiac regenerative therapies, including those using embryonic stem cells and induced pluripotent stem cells. Hopx functions to promote myogenesis by physically interacting with Smad proteins to repress Wnt signaling. Our findings raise the possibility that Hopx-mediated integration of Bmp signaling to repress Wnt may be active in other progenitor populations and may potentially underlie the tumor suppressor function of Hopx. Lineage tracing of Hopx+ cells. Images depicting lineage tracing of early Hopx+ cardiomyoblasts that give rise to myocytes in the left ventricle and atria. Some images are duplicated and pseudocolored. Cardiac progenitor cells are multipotent and give rise to cardiac endothelium, smooth muscle, and cardiomyocytes. Here, we define and characterize the cardiomyoblast intermediate that is committed to the cardiomyocyte fate, and we characterize the niche signals that regulate commitment. Cardiomyoblasts express Hopx, which functions to coordinate local Bmp signals to inhibit the Wnt pathway, thus promoting cardiomyogenesis. Hopx integrates Bmp and Wnt signaling by physically interacting with activated Smads and repressing Wnt genes. The identification of the committed cardiomyoblast that retains proliferative potential will inform cardiac regenerative therapeutics. In addition, Bmp signals characterize adult stem cell niches in other tissues where Hopx-mediated inhibition of Wnt is likely to contribute to stem cell quiescence and to explain the role of Hopx as a tumor suppressor.

Hopx expression defines a subset of multipotent hair follicle stem cells and a progenitor population primed to give rise to K6 + niche cells

The mammalian hair follicle relies on adult resident stem cells and their progeny to fuel and maintain hair growth throughout the life of an organism. The cyclical and initially synchronous nature of hair growth makes the hair follicle an ideal system with which to define homeostatic mechanisms of an adult stem cell population. Recently, we demonstrated that Hopx is a specific marker of intestinal stem cells. Here, we show that Hopx specifically labels long-lived hair follicle stem cells residing in the telogen basal bulge. Hopx+ cells contribute to all lineages of the mature hair follicle and to the interfollicular epidermis upon epidermal wounding. Unexpectedly, our analysis identifies a previously unappreciated progenitor population that resides in the lower hair bulb of anagen-phase follicles and expresses Hopx. These cells co-express Lgr5, do not express Shh and escape catagen-induced apoptosis. They ultimately differentiate into the cytokeratin 6-positive (K6) inner bulge cells in telogen, which regulate the quiescence of adjacent hair follicle stem cells. Although previous studies have suggested that K6+ cells arise from Lgr5-expressing lower outer root sheath cells in anagen, our studies indicate an alternative origin, and a novel role for Hopx-expressing lower hair bulb progenitor cells in contributing to stem cell homeostasis.

Distinct enhancers at the Pax3 locus can function redundantly to regulate neural tube and neural crest expressions.

Pax3 is a transcription factor expressed in somitic mesoderm, dorsal neural tube and pre-migratory neural crest during embryonic development. We have previously identified cis-acting enhancer elements within the proximal upstream genomic region of Pax3 that are sufficient to direct functional expression of Pax3 in neural crest. These elements direct expression of a reporter gene to pre-migratory neural crest in transgenic mice, and transgenic expression of a Pax3 cDNA using these elements is sufficient to rescue neural crest development in mice otherwise lacking endogenous Pax3. We show here that deletion of these enhancer sequences by homologous recombination is insufficient to abrogate neural crest expression of Pax3 and results in viable mice. We identify a distinct enhancer in the fourth intron that is also capable of mediating neural crest expression in transgenic mice and zebrafish. Our analysis suggests the existence of functionally redundant neural crest enhancer modules for Pax3.

Zebrafish neurofibromatosis type 1 genes have redundant functions in tumorigenesis and embryonic development

SUMMARY Neurofibromatosis type 1 (NF1) is a common, dominantly inherited genetic disorder that results from mutations in the neurofibromin 1 (NF1) gene. Affected individuals demonstrate abnormalities in neural-crest-derived tissues that include hyperpigmented skin lesions and benign peripheral nerve sheath tumors. NF1 patients also have a predisposition to malignancies including juvenile myelomonocytic leukemia (JMML), optic glioma, glioblastoma, schwannoma and malignant peripheral nerve sheath tumors (MPNSTs). In an effort to better define the molecular and cellular determinants of NF1 disease pathogenesis in vivo, we employed targeted mutagenesis strategies to generate zebrafish harboring stable germline mutations in nf1a and nf1b, orthologues of NF1. Animals homozygous for loss-of-function alleles of nf1a or nf1b alone are phenotypically normal and viable. Homozygous loss of both alleles in combination generates larval phenotypes that resemble aspects of the human disease and results in larval lethality between 7 and 10 days post fertilization. nf1-null larvae demonstrate significant central and peripheral nervous system defects. These include aberrant proliferation and differentiation of oligodendrocyte progenitor cells (OPCs), dysmorphic myelin sheaths and hyperplasia of Schwann cells. Loss of nf1 contributes to tumorigenesis as demonstrated by an accelerated onset and increased penetrance of high-grade gliomas and MPNSTs in adult nf1a+/−; nf1b−/−; p53e7/e7 animals. nf1-null larvae also demonstrate significant motor and learning defects. Importantly, we identify and quantitatively analyze a novel melanophore phenotype in nf1-null larvae, providing the first animal model of the pathognomonic pigmentation lesions of NF1. Together, these findings support a role for nf1a and nf1b as potent tumor suppressor genes that also function in the development of both central and peripheral glial cells as well as melanophores in zebrafish.

Oligodendrocyte progenitor cell numbers and migration are regulated by the zebrafish orthologs of the NF1 tumor suppressor gene

Neurofibromatosis type 1 is the most commonly inherited human cancer predisposition syndrome. Neurofibromin (NF1) gene mutations lead to increased risk of neurofibromas, schwannomas, low grade, pilocytic optic pathway gliomas, as well as malignant peripheral nerve sheath tumors and glioblastomas. Despite the evidence for NF1 tumor suppressor function in glial cell tumors, the mechanisms underlying transformation remain poorly understood. In this report, we used morpholinos to knockdown the two nf1 orthologs in zebrafish and show that oligodendrocyte progenitor cell (OPC) numbers are increased in the developing spinal cord, whereas neurons are unaffected. The increased OPC numbers in nf1 morphants resulted from increased proliferation, as detected by increased BrdU labeling, whereas TUNEL staining for apoptotic cells was unaffected. This phenotype could be rescued by the forced expression of the GTPase-activating protein (GAP)-related domain of human NF1. In addition, the in vivo analysis of OPC migration following nf1 loss using time-lapse microscopy demonstrated that olig2-EGFP(+) OPCs exhibit enhanced cell migration within the developing spinal cord. OPCs pause intermittently as they migrate, and in nf1 knockdown animals, they covered greater distances due to a decrease in average pause duration, rather than an increase in velocity while in motion. Interestingly, nf1 knockdown also leads to an increase in ERK signaling, principally in the neurons of the spinal cord. Together, these results show that negative regulation of the Ras pathway through the GAP activity of NF1 limits OPC proliferation and motility during development, providing insight into the oncogenic mechanisms through which NF1 loss contributes to human glial tumors.

Cardiac and vascular functions of the zebrafish orthologues of the type I neurofibromatosis gene NFI

Von Recklinghausen neurofibromatosis is a common autosomal dominant genetic disorder characterized by benign and malignant tumors of neural crest origin. Significant progress in understanding the pathophysiology of this disease has occurred in recent years, largely aided by the development of relevant animal models. Von Recklinghausen neurofibromatosis is caused by mutations in the NF1 gene, which encodes neurofibromin, a large protein that modulates the activity of Ras. Here, we describe the identification and characterization of zebrafish nf1a and nf1b, orthologues of NF1, and show neural crest and cardiovascular defects resulting from morpholino knockdown, including vascular and cardiac valvular abnormalities. Development of a zebrafish model of von Recklinghausen neurofibromatosis will allow for structure-function analysis and genetic screens in this tractable vertebrate system.