Your search keyword '"Gridley, Thomas"' showing total 42 results

1. Notch2 and Proteomic Signatures in Mouse Neointimal Lesion Formation

Author

Peterson, Sarah M., Turner, Jacqueline E., Harrington, Anne, Davis-Knowlton, Jessica, Lindner, Volkhard, Gridley, Thomas, Vary, Calvin P.H., and Liaw, Lucy

Abstract

Supplemental Digital Content is available in the text.

Published

2018

2. DLL4/Notch1 and BMP9 Interdependent Signaling Induces Human Endothelial Cell Quiescence via P27KIP1and Thrombospondin-1

Author

Rostama, Bahman, Turner, Jacqueline E., Seavey, Guy T., Norton, Christine R., Gridley, Thomas, Vary, Calvin P.H., and Liaw, Lucy

Abstract

Supplemental Digital Content is available in the text.

Published

2015

3. Specific Notch receptor–ligand interactions control human TCR-αβ/γδ development by inducing differential Notch signal strength

Author

Van de Walle, Inge, Waegemans, Els, De Medts, Jelle, De Smet, Greet, De Smedt, Magda, Snauwaert, Sylvia, Vandekerckhove, Bart, Kerre, Tessa, Leclercq, Georges, Plum, Jean, Gridley, Thomas, Wang, Tao, Koch, Ute, Radtke, Freddy, and Taghon, Tom

Abstract

In humans, high Notch activation promotes γδ T cell development, whereas lower levels promote αβ-lineage differentiation. How these different Notch signals are generated has remained unclear. We show that differential Notch receptor–ligand interactions mediate this process. Whereas Delta-like 4 supports both TCR-αβ and -γδ development, Jagged1 induces mainly αβ-lineage differentiation. In contrast, Jagged2-mediated Notch activation primarily results in γδ T cell development and represses αβ-lineage differentiation by inhibiting TCR-β formation. Consistently, TCR-αβ T cell development is rescued through transduction of a TCR-β transgene. Jagged2 induces the strongest Notch signal through interactions with both Notch1 and Notch3, whereas Delta-like 4 primarily binds Notch1. In agreement, Notch3 is a stronger Notch activator and only supports γδ T cell development, whereas Notch1 is a weaker activator supporting both TCR-αβ and -γδ development. Fetal thymus organ cultures in JAG2-deficient thymic lobes or with Notch3-blocking antibodies confirm the importance of Jagged2/Notch3 signaling in human TCR-γδ differentiation. Our findings reveal that differential Notch receptor–ligand interactions mediate human TCR-αβ and -γδ T cell differentiation and provide a mechanistic insight into the high Notch dependency of human γδ T cell development.

Published

2013

4. Oncogenic activation of the Notch1gene by deletion of its promoter in Ikaros-deficient T-ALL

Author

Jeannet, Robin, Mastio, Jérôme, Macias-Garcia, Alejandra, Oravecz, Attila, Ashworth, Todd, Geimer Le Lay, Anne-Solen, Jost, Bernard, Le Gras, Stéphanie, Ghysdael, Jacques, Gridley, Thomas, Honjo, Tasuku, Radtke, Freddy, Aster, Jon C., Chan, Susan, and Kastner, Philippe

Abstract

The Notch pathway is frequently activated in T-cell acute lymphoblastic leukemias (T-ALLs). Of the Notch receptors, Notch1 is a recurrent target of gain-of-function mutations and Notch3 is expressed in all T-ALLs, but it is currently unclear how these receptors contribute to T-cell transformation in vivo. We investigated the role of Notch1 and Notch3 in T-ALL progression by a genetic approach, in mice bearing a knockdown mutation in the Ikaros gene that spontaneously develop Notch-dependent T-ALL. While deletion of Notch3has little effect, T cell–specific deletion of floxed Notch1 promoter/exon 1 sequences significantly accelerates leukemogenesis. Notch1-deleted tumors lack surface Notch1 but express γ-secretase–cleaved intracellular Notch1 proteins. In addition, these tumors accumulate high levels of truncated Notch1 transcripts that are caused by aberrant transcription from cryptic initiation sites in the 3′ part of the gene. Deletion of the floxed sequences directly reprograms the Notch1locus to begin transcription from these 3′ promoters and is accompanied by an epigenetic reorganization of the Notch1locus that is consistent with transcriptional activation. Further, spontaneous deletion of 5′ Notch1 sequences occurs in approximately 75% of Ikaros-deficient T-ALLs. These results reveal a novel mechanism for the oncogenic activation of the Notch1gene after deletion of its main promoter.

Published

2010

5. Oncogenic activation of the Notch1 gene by deletion of its promoter in Ikaros-deficient T-ALL

Author

Jeannet, Robin, Mastio, Jérôme, Macias-Garcia, Alejandra, Oravecz, Attila, Ashworth, Todd, Geimer Le Lay, Anne-Solen, Jost, Bernard, Le Gras, Stéphanie, Ghysdael, Jacques, Gridley, Thomas, Honjo, Tasuku, Radtke, Freddy, Aster, Jon C., Chan, Susan, and Kastner, Philippe

Abstract

The Notch pathway is frequently activated in T-cell acute lymphoblastic leukemias (T-ALLs). Of the Notch receptors, Notch1 is a recurrent target of gain-of-function mutations and Notch3 is expressed in all T-ALLs, but it is currently unclear how these receptors contribute to T-cell transformation in vivo. We investigated the role of Notch1 and Notch3 in T-ALL progression by a genetic approach, in mice bearing a knockdown mutation in the Ikaros gene that spontaneously develop Notch-dependent T-ALL. While deletion of Notch3 has little effect, T cell–specific deletion of floxed Notch1 promoter/exon 1 sequences significantly accelerates leukemogenesis. Notch1-deleted tumors lack surface Notch1 but express γ-secretase–cleaved intracellular Notch1 proteins. In addition, these tumors accumulate high levels of truncated Notch1 transcripts that are caused by aberrant transcription from cryptic initiation sites in the 3′ part of the gene. Deletion of the floxed sequences directly reprograms the Notch1 locus to begin transcription from these 3′ promoters and is accompanied by an epigenetic reorganization of the Notch1 locus that is consistent with transcriptional activation. Further, spontaneous deletion of 5′ Notch1 sequences occurs in approximately 75% of Ikaros-deficient T-ALLs. These results reveal a novel mechanism for the oncogenic activation of the Notch1 gene after deletion of its main promoter.

Published

2010

6. Snail1 Gene Function During Early Embryo Patterning in Mice

Author

Murray, Stephen A and Gridley, Thomas

Abstract

Originally identified as one of two zygotically expressed genes required for gastrulation in Drosophila, the Snail gene and other family members play critical roles in vertebrate development. Functionally, these genes are thought to drive epithelial-mesenchymal transitions at several points during development, and also during the metastatic progression of cancer. Although the Snai2-null mouse is viable and fertile, the early embryonic lethality of Snai1-null mice has precluded the detailed analysis of Snai1 function after gastrulation. We have recently generated a conditional allele of the Snai1 gene and examined its function during the formation of the neural crest and establishment of the left-right axis. We uncovered new details regarding Snai1 function during gastrulation and left-right asymmetry determination, while surprisingly showing that neither the Snai1 nor Snai2 genes are essential for neural crest cell delamination. These results shed new light on the role of Snail family genes in early mouse development, and raise interesting questions concerning the diversity of gene function among vertebrate species.

Published

2006

7. The long and short of it: Somite formation in mice

Author

Gridley, Thomas

Abstract

A fundamental characteristic of the vertebrate body plan is its segmentation along the anterior–posterior axis. This segmental pattern is established during embryogenesis by the formation of somites, the transient epithelial blocks of cells that derive from the unsegmented presomitic mesoderm. Somite formation involves a molecular oscillator, termed the segmentation clock, in combination with gradients of signaling molecules such as fibroblast growth factor 8, WNT3A, and retinoic acid. Disruption of somitogenesis in humans can result in disorders such as spondylocostal dysostosis, which is characterized by vertebral malformations. This review summarizes recent findings concerning the role of Notch signaling in the segmentation clock, the complex regulatory network that governs somitogenesis, the genes that cause inherited spondylocostal dysostosis, and the mechanisms that regulate bilaterally symmetric somite formation. Developmental Dynamics 235:2330–2336, 2006. © 2006 Wiley‐Liss, Inc.

Published

2006

8. Jag2‐Notch1 signaling regulates oral epithelial differentiation and palate development

Author

Casey, Liam M., Lan, Yu, Cho, Eui‐Sic, Maltby, Kathleen M., Gridley, Thomas, and Jiang, Rulang

Abstract

During mammalian palatogenesis, palatal shelves initially grow vertically from the medial sides of the paired maxillary processes flanking the developing tongue and subsequently elevate and fuse with each other above the tongue to form the intact secondary palate. Pathological palate–mandible or palate–tongue fusions have been reported in humans and other mammals, but the molecular and cellular mechanisms that prevent such aberrant adhesions during normal palate development are unknown. We previously reported that mice deficient in Jag2, which encodes a cell surface ligand for the Notch family receptors, have cleft palate associated with palate–tongue fusions. In this report, we show that Jag2 is expressed throughout the oral epithelium and is required for Notch1 activation during oral epithelial differentiation. We show that Notch1 is normally highly activated in the differentiating oral periderm cells covering the developing tongue and the lateral oral surfaces of the mandibular and maxillary processes during palate development. Oral periderm activation of Notch1 is significantly attenuated during palate development in the Jag2 mutants. Further molecular and ultrastructural analyses indicate that oral epithelial organization and periderm differentiation are disrupted in the Jag2 mutants. Moreover, we show that the Jag2 mutant tongue fused to wild‐type palatal shelves in recombinant explant cultures. These data indicate that Jag2‐Notch1 signaling is spatiotemporally regulated in the oral epithelia during palate development to prevent premature palatal shelf adhesion to other oral tissues and to facilitate normal adhesion between the elevated palatal shelves. Developmental Dynamics 235:1830–1844, 2006. © 2006 Wiley‐Liss, Inc.

Published

2006

9. A requirement for Notch1 distinguishes 2 phases of definitive hematopoiesis during development

Author

Hadland, Brandon K., Huppert, Stacey S., Kanungo, Jyotshnabala, Xue, Yingzi, Jiang, Rulang, Gridley, Thomas, Conlon, Ronald A., Cheng, Alec M., Kopan, Raphael, and Longmore, Gregory D.

Abstract

Notch1 is known to play a critical role in regulating fates in numerous cell types, including those of the hematopoietic lineage. Multiple defects exhibited by Notch1-deficient embryos confound the determination of Notch1 function in early hematopoietic development in vivo. To overcome this limitation, we examined the developmental potential of Notch1–/– embryonic stem (ES) cells by in vitro differentiation and by in vivo chimera analysis. Notch1 was found to affect primitive erythropoiesis differentially during ES cell differentiation and in vivo, and this result reflected an important difference in the regulation of Notch1 expression during ES cell differentiation relative to the developing mouse embryo. Notch1 was dispensable for the onset of definitive hematopoiesis both in vitro and in vivo in that Notch1–/– definitive progenitors could be detected in differentiating ES cells as well as in the yolk sac and early fetal liver of chimeric mice. Despite the fact that Notch1–/– cells can give rise to multiple types of definitive progenitors in early development, Notch1–/– cells failed to contribute to long-term definitive hematopoiesis past the early fetal liver stage in the context of a wild-type environment in chimeric mice. Thus, Notch1 is required, in a cell-autonomous manner, for the establishment of long-term, definitive hematopoietic stem cells (HSCs).

Published

2004

10. A requirement for Notch1 distinguishes 2 phases of definitive hematopoiesis during development

Author

Hadland, Brandon K., Huppert, Stacey S., Kanungo, Jyotshnabala, Xue, Yingzi, Jiang, Rulang, Gridley, Thomas, Conlon, Ronald A., Cheng, Alec M., Kopan, Raphael, and Longmore, Gregory D.

Abstract

Notch1 is known to play a critical role in regulating fates in numerous cell types, including those of the hematopoietic lineage. Multiple defects exhibited by Notch1-deficient embryos confound the determination of Notch1 function in early hematopoietic development in vivo. To overcome this limitation, we examined the developmental potential of Notch1–/–embryonic stem (ES) cells by in vitro differentiation and by in vivo chimera analysis. Notch1 was found to affect primitive erythropoiesis differentially during ES cell differentiation and in vivo, and this result reflected an important difference in the regulation of Notch1 expression during ES cell differentiation relative to the developing mouse embryo. Notch1 was dispensable for the onset of definitive hematopoiesis both in vitro and in vivo in that Notch1–/–definitive progenitors could be detected in differentiating ES cells as well as in the yolk sac and early fetal liver of chimeric mice. Despite the fact that Notch1–/–cells can give rise to multiple types of definitive progenitors in early development, Notch1–/–cells failed to contribute to long-term definitive hematopoiesis past the early fetal liver stage in the context of a wild-type environment in chimeric mice. Thus, Notch1 is required, in a cell-autonomous manner, for the establishment of long-term, definitive hematopoietic stem cells (HSCs).

Published

2004

11. Slug Is a Novel Downstream Target of MyoD

Author

Zhao, Po, Iezzi, Simona, Carver, Ethan, Dressman, Devin, Gridley, Thomas, Sartorelli, Vittorio, and Hoffman, Eric P.

Abstract

Temporal expression profiling was utilized to define transcriptional regulatory pathways in vivoin a mouse muscle regeneration model. Potential downstream targets of MyoD were identified by temporal expression, promoter data base mining, and gel shift assays; Slugand calpain 6were identified as novel MyoD targets. Slug, a member of the snail/slug family of zinc finger transcriptional repressors critical for mesoderm/ectoderm development, was further shown to be a downstream target by using promoter/reporter constructs and demonstration of defective muscle regeneration in Slugnull mice.

Published

2002

12. Epithelial-Mesenchymal Transitions and Cancer

Author

Carver, Ethan A. and Gridley, Thomas

Abstract

More than 90% of malignant tumors arising in humans are of epithelial origin. The loss of epithelial morphology and the acquisition of mesenchymal characteristics are important early events in tumor progression. This type of morphological transformation is termed an epithelial-mesenchymal transition. These transitions occur normally during embryonic development, as well as pathologically during tumor progression. This review will encapsulate our understanding of the role that epithelial-mesenchymal transitions play during tumor progression and metastasis, and we also summarize recent results describing the roles played by such genes as E-cadherin, Snail, and TGFβ in regulating epithelial-mesenchymal transitions and metastasis.

Published

2002

13. Growth defect in <TOGGLE>Grg5</TOGGLE> null mice is associated with reduced Ihh signaling in growth plates

Author

Wang, Wen-Fang, Wang, You-Gan, Reginato, Anthony M., Plotkina, Sofiya, Gridley, Thomas, and Olsen, Bjorn R.

Abstract

Gene-targeted disruption of Grg5, a mouse homologue of Drosophila groucho (gro), results in postnatal growth retardation in mice. The growth defect, most striking in approximately half of the Grg5 null mice, occurs during the first 4–5 weeks of age, but most mice recover retarded growth later. We used the nonlinear mixed-effects model to fit the growth data of wild-type, heterozygous, and Grg5 null mice. On the basis of preliminary evidence suggesting an interaction between Grg5 and the transcription factor Cbfa1/Runx2, critical for skeletal development, we further investigated the skeleton in the mice. A long bone growth plate defect was identified, which included shorter zones of proliferative and hypertrophic chondrocytes and decreased trabecular bone formation. This decreased trabecular bone formation is likely caused by a reduced recruitment of osteoblasts into the growth plate region of Grg5 null mice. Like the growth defect, the growth plate and trabecular bone abnormality improved as the mice grew older. The growth plate defect was associated with reduced Indian hedgehog expression and signaling. We suggest that Grg5, a transcriptional coregulator, modulates the activities of transcription factors, such as Cbfa1/Runx2 in vivo to affect Ihh expression and the function of long bone growth plates. © 2002 Wiley-Liss, Inc.

Published

2002

14. A mouse model of Alagille syndrome: Notch2 as a genetic modifier of Jag1 haploinsufficiency

Author

McCright, Brent, Lozier, Julie, and Gridley, Thomas

Abstract

Alagille syndrome is a human autosomal dominant developmental disorder characterized by liver, heart, eye, skeletal, craniofacial and kidney abnormalities. Alagille syndrome is caused by mutations in the Jagged 1 (JAG1) gene, which encodes a ligand for Notch family receptors. The majority of JAG1 mutations seen in Alagille syndrome patients are null alleles, suggesting JAG1 haploinsufficiency as a primary cause of this disorder. Mice homozygous for a Jag1 null mutation die during embryogenesis and Jag1/+ heterozygous mice exhibit eye defects but do not exhibit other phenotypes characteristic of Alagille syndrome patients (Xue, Y., Gao, X., Lindsell, C. E., Norton, C. R., Chang, B., Hicks, C., Gendron-Maguire, M., Rand, E. B., Weinmaster, G. and Gridley, T. (1999) Hum. Mol. Genet.8, 723-730). Here we report that mice doubly heterozygous for the Jag1 null allele and a Notch2 hypomorphic allele exhibit developmental abnormalities characteristic of Alagille syndrome. Double heterozygous mice exhibit jaundice, growth retardation, impaired differentiation of intrahepatic bile ducts and defects in heart, eye and kidney development. The defects in bile duct epithelial cell differentiation and morphogenesis in the double heterozygous mice are similar to defects in epithelial morphogenesis of Notch pathway mutants in Drosophila, suggesting that a role for the Notch signaling pathway in regulating epithelial morphogenesis has been conserved between insects and mammals. This work also demonstrates that the Notch2 and Jag1 mutations interact to create a more representative mouse model of Alagille syndrome and provides a possible explanation of the variable phenotypic expression observed in Alagille syndrome patients.

Published

2002

15. The Mouse Snail Gene Encodes a Key Regulator of the Epithelial-Mesenchymal Transition

Author

Carver, Ethan A., Jiang, Rulang, Lan, Yu, Oram, Kathleen F., and Gridley, Thomas

Abstract

Snail family genes encode DNA binding zinc finger proteins that act as transcriptional repressors. Mouse embryos deficient for the Snail (Sna) gene exhibit defects in the formation of the mesoderm germ layer. In Sna−/−mutant embryos, a mesoderm layer forms and mesodermal marker genes are induced but the mutant mesoderm is morphologically abnormal. Lacunae form within the mesoderm layer of the mutant embryos, and cells lining these lacunae retain epithelial characteristics. These cells resemble a columnar epithelium and have apical-basal polarity, with microvilli along the apical surface and intercellular electron-dense adhesive junctions that resemble adherens junctions. E-cadherin expression is retained in the mesoderm of the Sna−/−embryos. These defects are strikingly similar to the gastrulation defects observed in snail-deficient Drosophilaembryos, suggesting that the mechanism of repression of E-cadherin transcription by Snail family proteins may have been present in the metazoan ancestor of the arthropod and mammalian lineages.

Published

2001

16. The Mouse Snail Gene Encodes a Key Regulator of the Epithelial-Mesenchymal Transition

Author

Carver, Ethan A., Jiang, Rulang, Lan, Yu, Oram, Kathleen F., and Gridley, Thomas

Abstract

ABSTRACTSnail family genes encode DNA binding zinc finger proteins that act as transcriptional repressors. Mouse embryos deficient for the Snail (Sna) gene exhibit defects in the formation of the mesoderm germ layer. In Sna−/−mutant embryos, a mesoderm layer forms and mesodermal marker genes are induced but the mutant mesoderm is morphologically abnormal. Lacunae form within the mesoderm layer of the mutant embryos, and cells lining these lacunae retain epithelial characteristics. These cells resemble a columnar epithelium and have apical-basal polarity, with microvilli along the apical surface and intercellular electron-dense adhesive junctions that resemble adherens junctions. E-cadherin expression is retained in the mesoderm of the Sna−/−embryos. These defects are strikingly similar to the gastrulation defects observed insnail-deficient Drosophilaembryos, suggesting that the mechanism of repression of E-cadherin transcription by Snail family proteins may have been present in the metazoan ancestor of the arthropod and mammalian lineages.

Published

2001

17. The NrarpGene Encodes an Ankyrin-Repeat Protein That Is Transcriptionally Regulated by the Notch Signaling Pathway

Author

Krebs, Luke T., Deftos, Michael L., Bevan, Michael J., and Gridley, Thomas

Abstract

We have identified a gene encoding a novel protein that is transcriptionally regulated by the Notch signaling pathway in mammals. This gene, named Nrarp(for Notch-regulated ankyrin-repeat protein), encodes a 114 amino acid protein that has a unique amino-terminus and a carboxy-terminal domain containing two ankyrin-repeat motifs. A Xenopushomolog of the Nrarpgene was previously identified in a large-scale in situhybridization screen of randomly isolated cDNA clones. We demonstrate that in T-cell and myoblast cell lines expression of the Nrarpgene is induced by the intracellular domain of the Notch1 protein, and that this induction is mediated by a CBF1/Su(H)/Lag-1 (CSL)-dependent pathway. During mouse embryogenesis, the Nrarpgene is expressed in several tissues in which cellular differentiation is regulated by the Notch signaling pathway. Expression of the Nrarpgene is downregulated in Notch1null mutant mouse embryos, indicating that expression of the Nrarpgene is regulated by the Notch pathway in vivo.Thus, Nrarptranscript levels are regulated by the level of Notch1signaling in both cultured cell lines and mouse embryos. During somitogenesis, the Nrarpgene is expressed in a pattern that suggests that Nrarpexpression may play a role in the formation of somites, and Nrarpexpression in the paraxial mesoderm is altered in several Notch pathway mutants that exhibit defects in somite formation. These observations demonstrate that the Nrarpgene is an evolutionarily conserved transcriptional target of the Notch signaling pathway.

Published

2001

18. Defects in development of the kidney, heart and eye vasculature in mice homozygous for a hypomorphic Notch2 mutation

Author

McCright, Brent, Gao, Xiang, Shen, Liya, Lozier, Julie, Lan, Yu, Maguire, Maureen, Herzlinger, Doris, Weinmaster, Gerry, Jiang, Rulang, and Gridley, Thomas

Abstract

The Notch gene family encodes large transmembrane receptors that are components of an evolutionarily conserved intercellular signaling mechanism. To assess the in vivo role of the Notch2 gene, we constructed a targeted mutation, Notch2del1. Unexpectedly, we found that alternative splicing of the Notch2del1mutant allele leads to the production of two different in-frame transcripts that delete either one or two EGF repeats of the Notch2 protein, suggesting that this allele is a hypomorphic Notch2 mutation. Mice homozygous for the Notch2del1 mutation died perinatally from defects in glomerular development in the kidney. Notch2del1/Notch2del1 mutant kidneys were hypoplastic and mutant glomeruli lacked a normal capillary tuft. The Notch ligand encoded by the Jag1 gene was expressed in developing glomeruli in cells adjacent to Notch2-expressing cells. We show that mice heterozygous for both the Notch2del1 and Jag1dDSL mutations exhibit a glomerular defect similar to, but less severe than, that of Notch2del1/Notch2del1 homozygotes. The co-localization and genetic interaction of Jag1 and Notch2 imply that this ligand and receptor physically interact, forming part of the signal transduction pathway required for glomerular differentiation and patterning. Notch2del1/Notch2del1 homozygotes also display myocardial hypoplasia, edema and hyperplasia of cells associated with the hyaloid vasculature of the eye. These data identify novel developmental roles for Notch2 in kidney, heart and eye development.

Published

2001

19. The Type II Activin Receptors Are Essential for Egg Cylinder Growth, Gastrulation, and Rostral Head Development in Mice

Author

Song, Jihwan, Oh, Suk P., Schrewe, Heinrich, Nomura, Masatoshi, Lei, Hong, Okano, Makiko, Gridley, Thomas, and Li, En

Abstract

The type II activin receptors, ActRIIA and ActRIIB, have been shown to play critical roles in axial patterning and organ development in mice. To investigate whether their function is required for mesoderm formation and gastrulation as implicated in Xenopusstudies, we generated mice carrying both receptor mutations by interbreeding the ActRIIAand ActRIIBknockout mutants. We found that embryos homozygous for both receptor mutations were growth arrested at the egg cylinder stage and did not form mesoderm. Further analyses revealed that ActRIIA−/−ActRIIB+/−and about 15% of the ActRIIA−/−embryos failed to form an elongated primitive streak, resulting in severe disruption of mesoderm formation in the embryo proper. Interestingly, we observed similar gastrulation defects in ActRIIA−/−nodal+/−double mutants, which, if they developed beyond the gastrulation stage, displayed rostral head defects and cyclopia. These results provide genetic evidence that type II activin receptors are required for egg cylinder growth, primitive streak formation, and rostral head development in mice.

Published

1999

20. Genomic Organization, Alternative Polyadenylation, and Chromosomal Localization of Grg, a Mouse Gene Related to the groucho Transcript of the Drosophila Enhancer of split Complex

Author

Mallo, Moisés, Steingrímsson, Eiríkur, Copeland, Neal G., Jenkins, Nancy A., and Gridley, Thomas

Abstract

The Grg gene encodes a 197-amino-acid protein homologous to the amino-terminal domain of the product of the groucho gene of the Drosophila Enhancer of split complex. We describe here the genomic organization of the mouse Grg gene. It spans approximately 7 kb on chromosome 10 and consists of seven exons. The 3' region of the Grg gene contains two functional polyadenylation sites that give rise to two transcripts that are differentially expressed among adult mouse tissues. The promoter region is very GC rich and lacks TATA box and "initiator" sequences. Primer extension analysis and ribonuclease protection assays show that Grg has a major transcription start site situated downstream of putative binding motifs for the transcription factors Sp1, E2A, and PuF. Copyright 1994, 1999 Academic Press

Published

1994

21. Cloning, Analysis, and Chromosomal Localization of Notch-1, a Mouse Homolog of Drosophila Notch

Author

Amo, Francisco Franco del, Gendron-Maguire, Maureen, Swiatek, Pamela J., Jenkins, Nancy A., Copeland, Neal G., and Gridley, Thomas

Abstract

The Notch gene of Drosophila encodes a large transmembrane protein involved in cell-cell interactions and cell fate decisions in the Drosophila embryo. We report here the isolation of cDNA clones encompassing the full-length coding sequence of Notch-1, a mouse homolog of Drosophila Notch. The predicted amino acid sequence of the Notch-1 protein retains all of the conserved amino acid motifs of Notch and the other vertebrate Notch homologs. The cDNA sequence predicts a 2531-amino-acid protein containing a signal peptide, 36 epidermal growth factor-like repeats, 3 Notch/lin-12 repeats, a transmembrane domain, and 6 cdc10/ankyrin repeats. The Notch-1 gene was localized to the proximal portion of mouse chromosome 2 by mapping with an interspecific backcross panel. Copyright 1993, 1999 Academic Press

Published

1993

22. Isolation of Sna, a mouse gene homologous to the Drosophila genes snail and escargot: its expression pattern suggests multiple roles during postimplantation development

Author

Smith, David E., Amo, Francisco Franco Del, and Gridley, Thomas

Abstract

The Drosophila gene snail encodes a zinc-finger protein that is required zygotically for mesoderm formation. Snail acts as a transcriptional repressor during the period of mesoderm formation by preventing expression of mesectodermal and ectodermal genes in the mesoderm anlage. A Xenopus homolog (xsnail) of snail has been cloned and it too is expressed early in the meso-dermal germ layer. We have isolated cDNA clones of a mouse gene (termed Sna) closely related to snail and xsnail and another Drosophila gene termed escargot that also encodes a zinc-finger protein. Sna encodes a 264 amino acid protein that contains four zinc fingers. Developmental RNA blot analysis showed that Sna transcripts are expressed throughout postimplantation development. Analysis of the spatial and temporal localization of Sna transcripts by in situ hybridization to both whole-mount and sectioned embryos revealed that, in the gastrulating embryo, Sna is expressed through-out the primitive streak and in the entire mesodermal germ layer. By 9.5 days post coitum (dpc) Sna is expressed at high levels in cephalic neural crest and limb bud mesenchyme. In fact, by 10.5 dpc Sna expression is observed in most mesenchymal cells, whether of neural crest or mesodermal origin. Later in gestation, high levels of Sna expression are observed in condensing cartilage and in the mesenchymal component of several tissues (lung, kidney, teeth and vibrissae) that undergo epithelial-mesenchymal inductive interactions during development. These results suggest multiple roles for the Sna gene in gastrulation and organogenesis during murine development.

Published

1992

23. The Slug Gene Is Not Essential for Mesoderm or Neural Crest Development in Mice

Author

Jiang, Rulang, Lan, Yu, Norton, Christine R., Sundberg, John P., and Gridley, Thomas

Abstract

The Slug gene encodes a zinc finger protein, homologous to the product of theDrosophilaSnail gene, that is implicated in the generation and migration of both mesoderm and neural crest cells in several vertebrate species. We describe here the cloning and genetic analysis of the mouse Slug (Slugh) gene.Slughencodes a 269-amino-acid protein that shares 92% amino acid identity with the product of the chicken Slug gene. We have characterizedSlughgene expression during early mouse embryogenesis by whole mountin situhybridization ofSlughmRNA and through detection of β-galactosidase expression from an in-frameSlughlacZallele generated through homologous recombination.Slughexpression is first detected in extraembryonic mesoderm and is later detected in many mesodermal subsets, although it is not detected in the primitive streak. In contrast to many other vertebrates, the mouse Slug gene is not expressed in premigratory neural crest cells but is expressed in migratory neural crest cells. Analysis of a targeted null mutation that deleted allSlughcoding sequences revealed thatSlughis not required for mesoderm formation or for neural crest generation, migration, or development in mice. These results indicate that neither the expression pattern nor the biological function of the Slug gene is conserved among all vertebrates. These data also raise interesting questions about the regulation of neural crest generation, which is one of the distinguishing characteristics of the vertebrate subphylum.

Published

1998

24. Differential screening of a PCR-generated mouse embryo cDNA library: glucose transporters are differentially expressed in early postimplantation mouse embryos

Author

Smith, David E. and Gridley, Thomas

Abstract

Differential screening of a cDNA library constructed using PCR amplification techniques from RNA isolated from the distal portion (embryonic ectoderm, mesoderm and visceral endoderm) of 7.5 days post coitum (dpc) mouse embryos led to the isolation of two cDNA clones expressed at higher levels in 7.5 dpc embryos than 12.5 dpc embryos. Nucleotide sequence analysis revealed that each of these clones was a different member of the family of facilitative glucose transporters (Glut genes). The differentially expressed cDNA clones represent mouse Glut-1 and Glut-3. Levels of the Glut-3 mRNA declined 14-fold between days 7.5 and 12.5 of gestation, and were under our limits of detetction by 14.5 dpc. The levels of the Glut-1 mRNA declined about 3-fold between days 7.5 and 12.5 of gestation. Analysis of the expression of these genes by in situ hybridization revealed striking differences in transcript localization in early postimplantation mouse embryos. At 7.5 dpc, both transporters were expressed more strongly in extraembryonic tissues than in the embryo proper. While both transporters were expressed in the amnion and chorion, only Glut-1 was expressed in the ectoplacental cone. In the yolk sac, Glut-3 appeared to be expressed only in the endoderm while Glut-1, although expressed in both layers, was expressed more strongly in the mesoderm layer. Thus, the two transporters have relatively reciprocal sites of expression in the developing extraembryonic membranes. Expression of Glut-1 was fairly widespread in the embryo at 8.5 dpc, but by 10.5 dpc expression was down-regulated and was observed in the eye and the spinal cord. Expression of Glut-3 was largely confined to non-neural surface ectoderm and was also substantially down-regulated by 10.5 dpc. These results prompted an examination of the RNA expression pattern of two other glucose transporter isoforms, Glut-2 and Glut-4. We did not detect Glut-4 expression, while Glut-2 expression was largely confined to extraembryonic visceral yolk sac endoderm. These data suggest differential roles for these glucose transporter family members during early postimplantation development of mice.

Published

1992

25. Mouse TCOF1 Is Expressed Widely, Has Motifs Conserved in Nucleolar Phosphoproteins, and Maps to Chromosome 18

Author

Paznekas, William A., Zhang, Nian, Gridley, Thomas, and Jabs, Ethylin Wang

Abstract

Mutations in the humanTCOF1gene have been identified in patients with Treacher Collins syndrome (Mandibulofacial Dysostosis), an autosomal dominant condition affecting the craniofacial region. We report the isolation of the entire mouseTcof1coding sequence (3960 bp) by performing a computer-based search for mouse cDNA clones homologous toTCOF1and generating overlapping RT-PCR products from mouse RNA. Tcof1 is a 1320 amino acid protein of 135 kd with 61.4% identity to TCOF1 and displays repeating motifs enriched for serine- and acidic amino acid-rich regions with potential phosphorylation sites and putative nuclear localization signals.Tcof1maps to the mouse chromosome 18 region syntenic with human chromosome 5q32→q33 which contains theTCOF1locus. Northern blot hybridization indicatesTcof1expression is ubiquitous in adult tissues and in the embryonic stage, is elevated at 11 dpc when the branchial arches and facial swellings are present in mouse. Our results are consistent with TCOF1 mutations leading to the Treacher Collins syndrome phenotype.

Published

1997

26. Expression pattern of Motch, a mouse homolog of Drosophila Notch, suggests an important role in early postimplantation mouse development

Author

Amo, Francisco Franco Del, Smith, David E., Swiatek, Pamela J., Gendron-Maguire, Maureen, Greenspan, Ralph J., Mcmahon, Andrew P., and Gridley, Thomas

Abstract

The Notch gene of Drosophila encodes a large transmembrane protein involved in cell-cell interactions and cell fate decisions in the Drosophila embryo. To determine if a gene homologous to Drosophila Notch plays a role in early mouse development, we screened a mouse embryo cDNA library with probes from the Xenopus Notch homolog, Xotch. A partial cDNA clone encoding the mouse Notch homolog, which we have termed Motch, was used to analyze expression of the Motch gene. Motch transcripts were detected in a wide variety of adult tissues, which included derivatives of all three germ layers. Differentiation of P19 embryonal carcinoma cells into neuronal cell types resulted in increased expression of Motch RNA. In the postimplantation mouse embryo Motch transcripts were first detected in mesoderm at 7.5 days post coitum (dpc). By 8.5 dpc, transcript levels were highest in presomitic mesoderm, mesenchyme and endothelial cells, while much lower levels were detected in neuroepithelium. In contrast, at 9.5 dpc, neuroepithelium was a major site of Motch expression. Transcripts were also abundant in cell types derived from neural crest. These data suggest that the Motch gene plays multiple roles in patterning and differentiation of the early postimplantation mouse embryo.

Published

1992

27. goosecoid is not an essential component of the mouse gastrula organizer but is required for craniofacial and rib development

Author

Rivera-Pérez, Jaime A., Mallo, Moisés, Gendron-Maguire, Maureen, Gridley, Thomas, and Behringer, Richard R.

Abstract

goosecoid (gsc) is an evolutionarily conserved homeobox gene expressed in the gastrula organizer region of a variety of vertebrate embryos, including zebrafish, Xenopus, chicken and mouse. To understand the role of gsc during mouse embryogenesis, we generated gsc-null mice by gene targeting in embryonic stem cells. Surprisingly, gsc-null embryos gastrulated and formed the primary body axes; gsc-null mice were born alive but died soon after birth with numerous craniofacial defects. In addition, rib fusions and sternum abnormalities were detected that varied depending upon the genetic background. Transplantation experiments suggest that the ovary does not provide gsc function to rescue gastrulation defects. These results demonstrate that gsc is not essential for organizer activity in the mouse but is required later during embryogenesis for craniofacial and rib cage development.

Published

1995

28. Ectopic Hoxa-1 induces rhombomere transformation in mouse hindbrain

Author

Zhang, Maobin, Kim, Hee-Joong, Marshall, Heather, Gendron-Maguire, Maureen, Lucas, Debra A., Baron, Agnès, Gudas, Lorraine J., Gridley, Thomas, Krumlauf, Robb, and Grippo, Joseph F.

Abstract

Homeobox genes are expressed with a specific spatial and temporal order, which is essential for pattern formation during the early development of both invertebrates and vertebrates. Here we show that widespread ectopic expression of the Hoxa-1 (Hox 1.6) gene directed by a human β-actin promoter in transgenic mice is embry-olethal and produces abnormal phenotypes in a subset of domains primarily located in anterior regions. Interestingly, this abnormal development in the Hoxa-1 transgenic mice is associated with ectopic expression of the Hoxb-1 (Hox 2.9) gene in select hindbrain regions. At gestation day 9.5, two domains of strong Hoxb-1 expression are found in the anterior region of the hindbrains of Hoxa-1 transgenic embryos. One region represents the normal pattern of Hoxb-1 expression in rhombomere 4 and its associated migrating neural crest cells, while another major domain of Hoxb-1 expression consistently appears in rhombomere 2. Similar ectopic domains of β-galactosidase activity are detected in dual transgenic embryos containing both β-actin/Hoxa-1 transgene and a Hoxb-1/lacZ reporter construct. Expression of another lacZ reporter gene that directs β-galactosidase activity predominately in rhombomere 2 is suppressed in the Hoxa-1 transgenic embryos. We have also detected weaker and variable ectopic Hoxb-1 expression in rhombomeres 1, 3 and 6. No ectopic Hoxb-1 expression is detected in rhombomere 5 and the expression of Hoxa-3 and Krox-20 in this region is unchanged in the Hoxa-1 transgenic embryos. While no obvious change in the morphology of the trigeminal or facial-acoustic ganglia is evident, phenotypic changes do occur in neurons that emanate from rhombomeres 2 and 3 in the Hoxa-1 transgenic embryos. Additionally, alterations in the pattern of Hoxa-2 and Hoxb-1 expression in a sub-population of neural crest cells migrating from the rhombomere 2 region are detected in these transgenics. Taken together, these data suggest that ectopic Hoxa-1 expression can reorganize select regions of the developing hindbrain by inducing partial transformations of several rhombomeres into a rhombomere-4-like identity.

Published

1994

29. Notch Signaling in Vertebrate Development and Disease

Author

Gridley, Thomas

Published

1997

30. Development of the mammalian ear: coordinate regulation of formation of the tympanic ring and the external acoustic meatus

Author

Mallo, Moisés and Gridley, Thomas

Abstract

The tympanic membrane in mammals is a trilaminar structure formed by the apposition of two epithelial cell layers, along with an intervening layer of cells derived from pharyngeal arch mesenchyme. One epithelial layer is contributed by the external acoustic meatus, a derivative of the first pharyngeal cleft. The other epithelial layer is contributed by the tubotympanic recess, a derivative of the first pharyngeal pouch. We demonstrate here an absolute correlation between formation of the external acoustic meatus and formation of the tympanic ring, a first archderived membrane bone that anchors the tympanic membrane. Experimental loss of the tympanic ring by retinoic acid treatment, or duplication of the ring in Hoxa-2 null mutant embryos, resulted in corresponding alterations in formation of the external acoustic meatus. We suggest that the tympanic ring primordium induces formation and morphogenesis of the external acoustic meatus, and that expression of the Hoxa-2 and goosecoid genes may be involved in regulating the formation and morphogenesis of these structures.

Published

1996

31. Molecular analysis of the Mov 34 mutation: transcript disrupted by proviral integration in mice is conserved in Drosophila

Author

Gridley, Thomas, Gray, Douglas A., Orr-Weaver, Terry, Soriano, Philippe, Barton, David E., Francke, Uta, and Jaenisch, Rudolf

Abstract

The Mov 34 mutation is a recessive embryonic lethal mutation caused by retroviral integration in the murine germline. This integration disrupts a transcription unit that appears to encode a novel protein. The Mov 34 proviral integration is located on mouse chromosome 8 and the human homolog of this gene has been mapped to chromosome region 16q23-q24. An evolutionarily conserved syntenic relationship exists between this region of human chromosome 16 and a region of mouse chromosome 8 that also contains oligosyndactyly (Os), another recessive lethal mutation. Genetic studies have ruled out Os as residing at the same locus as the Mov 34 integration. The Mov 34 transcript is conserved in evolution, and a Drosophila homolog appears to encode a protein with 62 % amino acid identity to the murine protein. In situ hybridization to Drosophila polytene chromosomes localizes the Drosophila homolog to 60B,C on chromosome 2. Several Drosophila lethal mutations also map to this region.

Published

1990

32. <TOGGLE>Slug</TOGGLE> expression during organogenesis in mice

Author

Oram, Kathleen F., Carver, Ethan A., and Gridley, Thomas

Abstract

The vertebrate Slug gene encodes a zinc finger-containing transcriptional repressor. Here we report expression of the mouse Slug gene during organogenesis and late fetal development using histochemical detection of β-galactosidase expressed from a targeted Slug^lacZ knock-in allele. The Slug gene is highly expressed in the mesenchymal or stromal component of numerous organs. It is also highly expressed in craniofacial mesenchyme, in bone of both mesodermal and neural crest origin, and in the outflow tract and the endocardial cushions of the heart. Anat Rec Part A 271A:189–191, 2003. © 2003 Wiley-Liss, Inc.

Published

2003

33. Slugexpression during organogenesis in mice

Author

Oram, Kathleen F., Carver, Ethan A., and Gridley, Thomas

Abstract

The vertebrate Sluggene encodes a zinc finger-containing transcriptional repressor. Here we report expression of the mouse Sluggene during organogenesis and late fetal development using histochemical detection of ß-galactosidase expressed from a targeted SluglacZknock-in allele. The Sluggene is highly expressed in the mesenchymal or stromal component of numerous organs. It is also highly expressed in craniofacial mesenchyme, in bone of both mesodermal and neural crest origin, and in the outflow tract and the endocardial cushions of the heart. Anat Rec Part A 271A:189–191, 2003. © 2003 Wiley-Liss, Inc.

Published

2003

34. Craniosynostosis in <TOGGLE>Twist</TOGGLE> heterozygous mice: A model for Saethre-Chotzen syndrome

Author

Carver, Ethan A., Oram, Kathleen F., and Gridley, Thomas

Abstract

Saethre-Chotzen syndrome is a common autosomal dominant form of craniosynostosis, the premature fusion of the sutures of the calvarial bones of the skull. Most Saethre-Chotzen syndrome cases are caused by haploinsufficiency for the TWIST gene. Mice heterozygous for a null mutation of the Twist gene replicate certain features of Saethre-Chotzen syndrome, but have not been reported to exhibit craniosynostosis. We demonstrate that Twist heterozygous mice exhibit fusions of the coronal suture and other cranial suture abnormalities, indicating that Twist heterozygous mice constitute a better animal model for Saethre-Chotzen syndrome than was previously appreciated. Anat Rec 268:90–92, 2002. © 2002 Wiley-Liss, Inc.

Published

2002

35. Craniosynostosis in Twistheterozygous mice: A model for Saethre‐Chotzen syndrome

Author

Carver, Ethan A., Oram, Kathleen F., and Gridley, Thomas

Abstract

Saethre‐Chotzen syndrome is a common autosomal dominant form of craniosynostosis, the premature fusion of the sutures of the calvarial bones of the skull. Most Saethre‐Chotzen syndrome cases are caused by haploinsufficiency for the TWISTgene. Mice heterozygous for a null mutation of the Twistgene replicate certain features of Saethre‐Chotzen syndrome, but have not been reported to exhibit craniosynostosis. We demonstrate that Twistheterozygous mice exhibit fusions of the coronal suture and other cranial suture abnormalities, indicating that Twistheterozygous mice constitute a better animal model for Saethre‐Chotzen syndrome than was previously appreciated. Anat Rec 268:90–92, 2002. © 2002 Wiley‐Liss, Inc.

Published

2002

36. Cloning, Expression, and Chromosomal Localization of a Mouse Gene Homologous to the Germ Cell Migration Regulator wunen and to Type 2 Phosphatidic Acid Phosphatases

Author

Zhang, Nian, Copeland, Neal G., Gilbert, Debra J., Jenkins, Nancy A., and Gridley, Thomas

Abstract

The wunen gene of Drosophila melanogasterencodes a multipass membrane-spanning protein that negatively regulates primordial germ cell migration. Here we describe the cloning of a mouse gene that encodes a protein homologous to wunen and to the Type 2 phosphatidic acid phosphatases. This gene encodes a 251-amino-acid protein that most closely resembles the human Type 2 phosphatidic acid phosphatase PAP-2c. Northern blot analysis revealed the presence of a single 1.9-kb Ppap2ctranscript. The Ppap2cgene was localized to the central portion of mouse Chromosome 10 by interspecific backcross analysis.

Published

2000

37. Genomic organization and chromosomal localization of the mouse snail (Sna) gene

Author

Jiang, Rulang, Copeland, Neal G., Gilbert, Debra J., Jenkins, Nancy A., and Gridley, Thomas

Published

1997

38. Assignment of the MurineNotch2andNotch3Genes to Chromosomes 3 and 17

Author

Gao, Xiang, Copeland, Neal G., Gilbert, Debra J., Jenkins, Nancy A., and Gridley, Thomas

Published

1998

39. Exclusion of Jagged2 as a candidate for the legless gene

Author

Bell, Sheila M., Lan, Yu, Jiang, Rulang, and Gridley, Thomas

Published

1998

40. The Jagged2 gene maps to Chromosome 12 and is a candidate for the lgland smmutations

Author

Lan, Yu, Jiang, Rulang, Shawber, Carrie, Weinmaster, Gerry, and Gridley, Thomas

Published

1997

41. Notch2Regulates Early Folliculogenesis in Mice.

Author

Xu, Jingxia and Gridley, Thomas

Abstract

In mammals, development of the ovarian follicle (folliculogenesis) involves oocyte-somatic cell communication. The bidirectional communication between the oocyte and surrounding somatic cells, termed granulosa cells, is essential for development of an egg competent for fertilization and embryogenesis. Little is known about the molecular mechanisms that govern the early events in folliculogenesis. The Notch signaling pathway plays an essential role during oocyte development in Drosophila. In the mouse ovary, Notch pathway receptors are expressed in granulosa cells, while Notch ligands are expressed in the oocytes. Furthermore, expression of a ligand, Jag2, in granulosa cells in mice resembles expression of the ligand Deltain follicle cells in Drosophila, suggesting that there also may be an important role for Notch signaling in oogenesis and folliculogenesis in mice. Here, we use the cre/loxPsystem to delete the Notch2gene specifically in the granulosa cells of the postnatal ovary using Amhr2-Cretransgenic mice, and show that the Notch2gene is required for early stages of folliculogenesis. Notch2gene deletion in granulosa cells (Notch2null/flox, Amhr2-Cre/+) resulted in reduced fertility in female mice, and histological examination revealed that the mutant mice had follicles containing multiple oocytes (>=4, multiple oocyte follicle, MOF). At postnatal day 18 (PND18) mutant mice had significantly reduced numbers of normal primordial follicles, but contained extremely large numbers of MOFs. At 7 weeks old, mutants exhibited hemorrhagic cysts in their ovaries. Analysis of early folliculogenesis showed that at PND2, mutants had more oocytes and fewer normal primordial follicles than the littermate controls. We observed no abnormal proliferation of oocytes after E16.5, nor have we observed a defect in granulosa cell proliferation. The endowment of primordial follicles in mammalian ovaries is finite. When follicles are depleted, infertility occurs. Our data show that Notch2deletion in granulosa cells is important in germ cell cyst breakdown and the endowment of primordial follicles. Furthermore, the Notch signaling pathway plays an important role in oocyte-granulosa cell communication, and is required for normal follicle development and fertility in mice.(platform)

Published

2009

42. Letter from California. SAN FRANCISCO, June 23, 1849.

Author

GRIDLEY, THOMAS M.

Published

1849