Your search keyword '"Sally F Burn"' showing total 8 results

1. Postimplantation Mga expression and embryonic lethality of two gene-trap alleles

Author

Andrew J. Washkowitz, Virginia E. Papaioannou, Svetlana Gavrilov, and Sally F. Burn

Subjects

0301 basic medicine, Organogenesis, Embryonic Development, Biology, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Genetics, medicine, Basic Helix-Loop-Helix Transcription Factors, Inner cell mass, Animals, Blastocyst, Embryo Implantation, Progenitor cell, Molecular Biology, Transcription factor, Alleles, Cells, Cultured, Embryonic Stem Cells, Gene Expression Regulation, Developmental, Embryo, Embryo, Mammalian, Embryonic stem cell, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Epiblast, embryonic structures, Embryo Loss, Female, 030217 neurology & neurosurgery, Developmental Biology, Transcription Factors

Abstract

Background The dual-specificity T-box/basic helix-loop-helix leucine zipper transcription factor MGA is part of the MAX-interacting network of proteins. In the mouse, MGA is necessary for the survival of the pluripotent epiblast cells of the peri-implantation embryo and a null, gene-trap allele MgaGt results in embryonic lethality shortly after implantation. We have used this allele to document expression of Mga in postimplantation embryos and also investigated a second, hypomorphic gene-trap allele, MgaInv. Results Compound heterozygotes, MgaGt/MgaInv, die prior to midgestation. The extraembryonic portion of the embryos appears to develop relatively normally while the embryonic portion, including the pluripotent cells of the epiblast, is severely retarded by E7.5. Mga expression is initially limited to the pluripotent inner cell mass of the blastocyst and epiblast, but during organogenesis it is widely expressed, notably in the central nervous system and sensory organs, reproductive and excretory systems, heart, somites and limbs. Conclusions Widespread yet specific areas of expression of Mga during organogenesis raise the possibility that the transcription factor may play roles in controlling proliferation and potency in the progenitor cell populations of different organ systems. Documentation of these patterns sets the stage for the investigation of specific progenitor cell types.

Published

2017

2. Abstracts of papers presented at the 24th Genetics Society's Mammalian Genetics and Development Workshop held at the Institute of Child Health, University College London on 21st November 2013

Author

Michele J. Karolak, Sally F. Burn, Leif Oxburgh, Ron Smits, Elvira R M Bakker, Owen J. Sansom, Nils O. Lindstroem, Denis J. Headon, Jeanette Astorga, Jamie A. Davies, Peter Hohenstein, and Rachel A. Ridgway

Subjects

medicine.anatomical_structure, Beta-catenin, biology, Genetics, biology.protein, medicine, Cancer research, Notch signaling pathway, PTEN, General Medicine, Nephron

Published

2013

3. The dynamics of spleen morphogenesis

Author

Miguel Torres, Carlos G. Arques, Carlo De Angelis, Sally F. Burn, Roisin Doohan, Marit J. Boot, and Robert E. Hill

Subjects

Genetically modified mouse, Nkx2-5, Mesenchyme, Morphogenesis, Cre recombinase, Mice, Transgenic, Spleen, Biology, Organ culture, Mouse embryo, Mesoderm, Mice, Precursor cell, medicine, Animals, Molecular Biology, Homeodomain Proteins, Stomach, Cell Biology, Anatomy, Embryo, Mammalian, Cell biology, Haematopoiesis, medicine.anatomical_structure, Homeobox Protein Nkx-2.5, spleen, Transcription Factors, Bapx1, Gut culture, Developmental Biology

Abstract

The mammalian spleen has important functions in immunity and haematopoiesis but little is known about the events that occur during its early embryonic development. Here we analyse the origin of the cells that gives rise to the splenic mesenchyme and the process by which the precursors assume their position along the left lateral side of the stomach. We report a highly conserved regulatory element that regulates the Nkx2-5 gene throughout early spleen development. A transgenic mouse line carrying this element driving a reporter gene was used to show that morphogenesis of the spleen initiates bilaterally and posterior to the stomach, before the splenic precursors grow preferentially leftward. In addition the transgenic line was used in an organ culture system to track spleen precursor cells during development. Spleen cells were shown to move from the posterior mesenchyme and track along the left side of the stomach. Removal of tissue from the anterior stomach resulted in splenic cells randomly scattering suggesting a guidance role for the anterior stomach. Using a mouse line carrying a conditional Cre recombinase to mark early precursor cell populations, the spleen was found to derive from posterior mesenchyme distinct from the closely adjacent stomach mesenchyme.

Published

2008

4. Integrated β-catenin, BMP, PTEN, and Notch signalling patterns the nephron

Author

C-Hong Chang, Elvira R M Bakker, Denis J. Headon, Michele J. Karolak, Rachel A. Ridgway, Leif Oxburgh, Ron Smits, Nils O. Lindström, Owen J. Sansom, Jamie A. Davies, Sally F. Burn, Jeanette A. Johansson, Melanie L. Lawrence, Peter Hohenstein, and Gastroenterology & Hepatology

Subjects

Cellular differentiation, Kidney development, Nephron, Glomerulus (kidney), urologic and male genital diseases, PI3K, Mice, Phosphatidylinositol 3-Kinases, RNA, Small Interfering, Biology (General), beta Catenin, kidney development, patterning, Receptors, Notch, biology, General Neuroscience, Gene Expression Regulation, Developmental, Cell Differentiation, General Medicine, Cell biology, medicine.anatomical_structure, Bone Morphogenetic Proteins, Diffusion Chambers, Culture, Medicine, Signal Transduction, Research Article, Notch, QH301-705.5, Science, Notch signaling pathway, Mice, Transgenic, Bone morphogenetic protein, General Biochemistry, Genetics and Molecular Biology, Organ Culture Techniques, medicine, Animals, BMP, PTEN, mouse, PI3K/AKT/mTOR pathway, Body Patterning, General Immunology and Microbiology, urogenital system, PTEN Phosphohydrolase, Epithelial Cells, beta-catenin, Nephrons, Embryo, Mammalian, Developmental Biology and Stem Cells, biology.protein, Proto-Oncogene Proteins c-akt

Abstract

The different segments of the nephron and glomerulus in the kidney balance the processes of water homeostasis, solute recovery, blood filtration, and metabolite excretion. When segment function is disrupted, a range of pathological features are presented. Little is known about nephron patterning during embryogenesis. In this study, we demonstrate that the early nephron is patterned by a gradient in β-catenin activity along the axis of the nephron tubule. By modifying β-catenin activity, we force cells within nephrons to differentiate according to the imposed β-catenin activity level, thereby causing spatial shifts in nephron segments. The β-catenin signalling gradient interacts with the BMP pathway which, through PTEN/PI3K/AKT signalling, antagonises β-catenin activity and promotes segment identities associated with low β-catenin activity. β-catenin activity and PI3K signalling also integrate with Notch signalling to control segmentation: modulating β-catenin activity or PI3K rescues segment identities normally lost by inhibition of Notch. Our data therefore identifies a molecular network for nephron patterning. DOI: http://dx.doi.org/10.7554/eLife.04000.001, eLife digest The main function of the kidney is to filter blood to remove waste and regulate the amount of water and salt in the body. Structures in the kidney—called nephrons—do much of this work and blood is filtered in a part of each nephron called the glomerulus. The substances filtered out of the blood move into a series of ‘tubules’, another part of the nephrons, from where water and soluble substances are reabsorbed or excreted as the body requires. If the nephrons do not work correctly, it can lead to a wide range of health problems—from abnormal water and salt loss to dangerously high blood pressure. For organs and tissues to develop in an embryo, signalling pathways help cells to communicate with each other. These pathways control what type of cells the embryonic cells become and also help neighbouring cells work together to form specialised structures with particular functions. Much is unknown about how the nephron develops, including how its different structures coordinate their development with each other so that they form in the right position in the nephron. A protein called beta-catenin was already known to play an important role in the signalling pathways that trigger the earliest stages of nephron formation. Lindström et al. further investigated how this protein helps the nephron to develop by using a wide range of techniques, including growing genetically altered mouse kidneys in culture and capturing images of the developing nephrons with time-lapse microscopy. The combined results reveal that the levels of beta-catenin activity coordinate the development of the different structures in the nephron. The beta-catenin protein is not equally active in all parts of the nephron; instead, it forms a gradient of different activity levels. The highest levels of beta-catenin activity occur in the tubules at the furthest end of the developing nephron; this activity gradually decreases along the length of the nephron, and the glomerulus itself lacks beta-catenin activity altogether. Experimentally manipulating the levels of beta-catenin at different points along the nephron caused those cells to take on the wrong identity, causing parts of the nephron to form in the wrong place. Lindström et al. were also able to establish that the signalling pathway controlled by beta-catenin activity interacts with three other well-known signalling pathways as part of a network that controls nephron development. More research is required to find out which signal activates beta-catenin in the first place and from where in the kidney this signal comes. It also remains to be discovered how a particular cell in the tubule interprets the exact activities of the different signals to give the cell its specific identity for that place in the nephron. A better understanding of these sorts of processes will eventually help build new kidneys for people with kidney failure. DOI: http://dx.doi.org/10.7554/eLife.04000.002

Published

2015

5. Author response: Integrated β-catenin, BMP, PTEN, and Notch signalling patterns the nephron

Author

Ron Smits, Rachel A. Ridgway, Leif Oxburgh, Jamie A. Davies, Jeanette A. Johansson, Elvira R M Bakker, Melanie L. Lawrence, Nils O. Lindström, C-Hong Chang, Peter Hohenstein, Denis J. Headon, Michele J. Karolak, Owen J. Sansom, and Sally F. Burn

Subjects

medicine.anatomical_structure, Catenin, Notch signaling pathway, biology.protein, medicine, PTEN, Nephron, Biology, Cell biology

Published

2014

6. 13-P070 Wnt-Ca2+ signalling in kidney and embryonic development

Author

Nicholas D. Hastie, Sandra Chiwanza, Sally F. Burn, Anna Webb, and Peter Hohenstein

Subjects

Kidney, Embryology, medicine.anatomical_structure, Embryogenesis, medicine, Wnt signaling pathway, Ca2 signalling, Biology, Cell biology, Developmental Biology

Published

2009

7. A regulatory region upstream of Nkx2.5 drives spleen and pyloric sphincter expression

Author

Robert E. Hill and Sally F. Burn

Subjects

medicine.anatomical_structure, medicine, Spleen, Upstream (networking), Cell Biology, Anatomy, Pyloric sphincter, Biology, Molecular Biology, Regulatory region, Developmental Biology, Cell biology

Published

2006

8. A Wt1-Controlled Chromatin Switching Mechanism Underpins Tissue-Specific Wnt4 Activation and Repression

Author

Victor Velecela, Stefan G. E. Roberts, John H. Wiltshire, Ofelia M. Martínez-Estrada, Sally F. Burn, Rachel L. Berry, Abdelkader Essafi, Joan Slight, Peter Hohenstein, Anna Webb, David G. Brownstein, Jamie A. Davies, Nicholas D. Hastie, and Lee Spraggon

Subjects

Mesenchyme, Regulator, Biology, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, medicine, Transcriptional regulation, Molecular Biology, Psychological repression, 030304 developmental biology, Genetics, 0303 health sciences, Cohesin, urogenital system, fungi, Cell Biology, Cell biology, Chromatin, medicine.anatomical_structure, CTCF, 030220 oncology & carcinogenesis, Corepressor, Developmental Biology

Abstract

Summary Wt1 regulates the epithelial-mesenchymal transition (EMT) in the epicardium and the reverse process (MET) in kidney mesenchyme. The mechanisms underlying these reciprocal functions are unknown. Here, we show in both embryos and cultured cells that Wt1 regulates Wnt4 expression dichotomously. In kidney cells, Wt1 recruits Cbp and p300 as coactivators; in epicardial cells it enlists Basp1 as a corepressor. Surprisingly, in both tissues, Wt1 loss reciprocally switches the chromatin architecture of the entire Ctcf-bounded Wnt4 locus, but not the flanking regions; we term this mode of action "chromatin flip-flop." Ctcf and cohesin are dispensable for Wt1-mediated chromatin flip-flop but essential for maintaining the insulating boundaries. This work demonstrates that a developmental regulator coordinates chromatin boundaries with the transcriptional competence of the flanked region. These findings also have implications for hierarchical transcriptional regulation in development and disease.