Your search keyword '"Danielle Rux"' showing total 13 results

1. SOX9 keeps growth plates and articular cartilage healthy by inhibiting chondrocyte dedifferentiation/osteoblastic redifferentiation

Author

Lutian Yao, Danielle Rux, Ling Qin, Marco Angelozzi, Ranjan Kc, Renata Pellegrino da Silva, Abdul Haseeb, Véronique Lefebvre, Robert J. Tower, Maurizio Pacifici, and Charles de Charleroy

Subjects

Cartilage, Articular, Articular cartilage, Osteoarthritis, SOX9, Biology, Chondrocyte, Mice, Chondrocytes, Osteogenesis, Conditional gene knockout, medicine, Animals, Cell Lineage, Growth Plate, Mice, Knockout, Osteoblasts, Multidisciplinary, Chemistry, Cartilage, Cell Differentiation, SOX9 Transcription Factor, Osteoblast, Chondrogenesis, medicine.disease, Cell biology, Mice, Inbred C57BL, RUNX2, medicine.anatomical_structure, Growth plates

Abstract

Cartilage is essential throughout vertebrate life. It starts developing in embryos when osteochondroprogenitor cells commit to chondrogenesis, activate a pancartilaginous program to form cartilaginous skeletal primordia, and also embrace a growth-plate program to drive skeletal growth or an articular program to build permanent joint cartilage. Various forms of cartilage malformation and degeneration diseases afflict humans, but underlying mechanisms are still incompletely understood and treatment options suboptimal. The transcription factor SOX9 is required for embryonic chondrogenesis, but its postnatal roles remain unclear, despite evidence that it is down-regulated in osteoarthritis and heterozygously inactivated in campomelic dysplasia, a severe skeletal dysplasia characterized postnatally by small stature and kyphoscoliosis. Using conditional knockout mice and high-throughput sequencing assays, we show here that SOX9 is required postnatally to prevent growth-plate closure and preosteoarthritic deterioration of articular cartilage. Its deficiency prompts growth-plate chondrocytes at all stages to swiftly reach a terminal/dedifferentiated stage marked by expression of chondrocyte-specific (Mgp) and progenitor-specific (Nt5e and Sox4) genes. Up-regulation of osteogenic genes (Runx2, Sp7, and Postn) and overt osteoblastogenesis quickly ensue. SOX9 deficiency does not perturb the articular program, except in load-bearing regions, where it also provokes chondrocyte-to-osteoblast conversion via a progenitor stage. Pathway analyses support roles for SOX9 in controlling TGFβ and BMP signaling activities during this cell lineage transition. Altogether, these findings deepen our current understanding of the cellular and molecular mechanisms that specifically ensure lifelong growth-plate and articular cartilage vigor by identifying osteogenic plasticity of growth-plate and articular chondrocytes and a SOX9-countered chondrocyte dedifferentiation/osteoblast redifferentiation process.

Published

2021

2. Primary cilia drive postnatal tidemark patterning in articular cartilage by coordinating responses to Indian Hedgehog and mechanical load

Author

Courtney Cortese, Danielle Rux, Biao Han, Maurizio Pacifici, Lin Han, Eiki Koyama, and Kimberly Helbig

Subjects

Extracellular matrix, medicine.anatomical_structure, Indian hedgehog, Cilium, medicine, Morphogenesis, Body movement, Biology, biology.organism_classification, Aggrecan, Chondrocyte, Hedgehog signaling pathway, Cell biology

Abstract

Articular cartilage (AC) is essential for body movement, but is highly susceptible to degenerative diseases and has poor self-repair capacity. To improve current subpar regenerative treatment, developmental mechanisms of AC should be clarified and, specifically, how postnatal multi-zone organization is acquired. Primary cilia are cell surface organelles crucial for mammalian tissue morphogenesis and while the importance of chondrocyte primary cilia is well appreciated their specific roles in postnatal AC morphogenesis remain unclear. To explore these mechanisms, we used a murine conditional loss-of-function approach (Ift88-flox) targeting joint-lineage progenitors (Gdf5Cre) and monitored postnatal knee AC development. Joint formation and growth up to juvenile stages were largely unaffected, however mature AC (aged 2 months) exhibited disorganized extracellular matrix, decreased aggrecan and collagen II due to reduced gene expression (not increased catabolism), and marked reduction of AC modulus by 30-50%. In addition, we discovered the surprising findings that tidemark patterning was severely disrupted and accompanied alterations in hedgehog signaling that were also dependent on regional load-bearing functions of AC. Interestingly, Prg4 expression was also increased in those loaded sites. Together, our data provide evidence that primary cilia orchestrate postnatal AC morphogenesis, dictating tidemark topography, zonal matrix composition and mechanical load responses.

Published

2021

3. Premature growth plate closure caused by a hedgehog cancer drug is preventable by co-administration of a retinoid antagonist in mice

Author

Juliet Chung, Christina Mundy, Danielle Rux, Maurizio Pacifici, Masahiro Iwamoto, Sarah E. Catheline, Eiki Koyama, and Cheri Saunders

Subjects

0301 basic medicine, medicine.medical_specialty, Indian hedgehog, medicine.drug_class, Endocrinology, Diabetes and Metabolism, 030209 endocrinology & metabolism, Antineoplastic Agents, Chondrocyte, Article, 03 medical and health sciences, Mice, Retinoids, 0302 clinical medicine, Chondrocytes, Internal medicine, Neoplasms, medicine, Animals, Humans, Orthopedics and Sports Medicine, Hedgehog Proteins, Retinoid, Growth Plate, Progenitor cell, Receptor, Child, Hedgehog, biology, Chemistry, Antagonist, Cell Differentiation, biology.organism_classification, Chondrogenesis, 030104 developmental biology, Endocrinology, medicine.anatomical_structure

Abstract

The growth plates are key engines of skeletal development and growth and contain a top reserve zone followed by maturation zones of proliferating, prehypertrophic, and hypertrophic/mineralizing chondrocytes. Trauma or drug treatment of certain disorders can derange the growth plates and cause accelerated maturation and premature closure, one example being anti-hedgehog drugs such as LDE225 (Sonidegib) used against pediatric brain malignancies. Here we tested whether such acceleration and closure in LDE225-treated mice could be prevented by co-administration of a selective retinoid antagonist, based on previous studies showing that retinoid antagonists can slow down chondrocyte maturation rates. Treatment of juvenile mice with an experimental dose of LDE225 for 2 days (100 mg/kg by gavage) initially caused a significant shortening of long bone growth plates, with concomitant decreases in chondrocyte proliferation; expression of Indian hedgehog, Sox9, and other key genes; and surprisingly, the number of reserve progenitors. Growth plate involution followed with time, leading to impaired long bone lengthening. Mechanistically, LDE225 treatment markedly decreased the expression of retinoid catabolic enzyme Cyp26b1 within growth plate, whereas it increased and broadened the expression of retinoid synthesizing enzyme Raldh3, thus subverting normal homeostatic retinoid circuitries and in turn accelerating maturation and closure. All such severe skeletal and molecular changes were prevented when LDE-treated mice were co-administered the selective retinoid antagonist CD2665 (1.5 mg/kg/d), a drug targeting retinoid acid receptor γ, which is most abundantly expressed in growth plate. When given alone, CD2665 elicited the expected maturation delay and growth plate expansion. In vitro data showed that LDE225 acted directly to dampen chondrogenic phenotypic expression, a response fully reversed by CD2665 co-treatment. In sum, our proof-of-principle data indicate that drug-induced premature growth plate closures can be prevented or delayed by targeting a separate phenotypic regulatory mechanism in chondrocytes. The translation applicability of the findings remains to be studied. © 2021 American Society for Bone and Mineral Research (ASBMR).

Published

2021

4. Activin A promotes the development of acquired heterotopic ossification and is an effective target for disease attenuation in mice

Author

Lutian Yao, Juliet Chung, Sayantani Sinha, Danielle Rux, Sarah E. Catheline, Ling Qin, Maurizio Pacifici, Christina Mundy, and Eiki Koyama

Subjects

animal structures, Endogeny, Inflammation, SOX9, Biochemistry, 03 medical and health sciences, Mice, 0302 clinical medicine, In vivo, Osteogenesis, medicine, Animals, Progenitor cell, Neutralizing antibody, Molecular Biology, 030304 developmental biology, 0303 health sciences, biology, business.industry, Ossification, Heterotopic, Cell Biology, medicine.disease, Chondrogenesis, Activins, Myositis Ossificans, 030220 oncology & carcinogenesis, Cancer research, biology.protein, Heterotopic ossification, medicine.symptom, business

Abstract

Heterotopic ossification (HO) is a common, potentially debilitating pathology that is instigated by inflammation caused by tissue damage or other insults, which is followed by chondrogenesis, osteogenesis, and extraskeletal bone accumulation. Current remedies are not very effective and have side effects, including the risk of triggering additional HO. The TGF-β family member activin A is produced by activated macrophages and other inflammatory cells and stimulates the intracellular effectors SMAD2 and SMAD3 (SMAD2/3). Because HO starts with inflammation and because SMAD2/3 activation is chondrogenic, we tested whether activin A stimulated HO development. Using mouse models of acquired intramuscular and subdermal HO, we found that blockage of endogenous activin A by a systemically administered neutralizing antibody reduced HO development and bone accumulation. Single-cell RNA-seq analysis and developmental trajectories showed that the antibody treatment reduced the recruitment of Sox9+ skeletal progenitors, many of which also expressed the gene encoding activin A (Inhba), to HO sites. Gain-of-function assays showed that activin A enhanced the chondrogenic differentiation of progenitor cells through SMAD2/3 signaling, and inclusion of activin A in HO-inducing implants enhanced HO development in vivo. Together, our data reveal that activin A is a critical upstream signaling stimulator of acquired HO in mice and could represent an effective therapeutic target against forms of this pathology in patients.

Published

2021

5. Hox11 expression characterizes developing zeugopod synovial joints and is coupled to postnatal articular cartilage morphogenesis into functional zones in mice

Author

Eiki Koyama, Danielle Rux, Maurizio Pacifici, and Kimberly Helbig

Subjects

musculoskeletal diseases, Cartilage, Articular, Green Fluorescent Proteins, Morphogenesis, Biology, Wrist, GDF5, Chondrocyte, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Genes, Reporter, Synovial joint, medicine, Limb development, Animals, Molecular Biology, 030304 developmental biology, 0303 health sciences, Mesenchymal stem cell, Synovial Membrane, Genes, Homeobox, Gene Expression Regulation, Developmental, Extremities, Cell Biology, Embryonic stem cell, Cell biology, medicine.anatomical_structure, Chondrogenesis, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Previous studies on mouse embryo limbs have established that interzone mesenchymal progenitor cells emerging at each prescribed joint site give rise to joint tissues over fetal time. These incipient tissues undergo structural maturation and morphogenesis postnatally, but underlying mechanisms of regulation remain unknown. Hox11 genes dictate overall zeugopod musculoskeletal patterning and skeletal element identities during development. Here we asked where these master regulators are expressed in developing limb joints and whether they are maintained during postnatal zeugopod joint morphogenesis. We found that Hoxa11 was predominantly expressed and restricted to incipient wrist and ankle joints in E13.5 mouse embryos, and became apparent in medial and central regions of knees by E14.5, though remaining continuously dormant in elbow joints. Closer examination revealed that Hoxa11 initially characterized interzone and neighboring cells and was then restricted to nascent articular cartilage, intra joint ligaments and structures such as meniscal horns over prenatal time. Postnatally, articular cartilage progresses from a nondescript cell-rich, matrix-poor tissue to a highly structured, thick, zonal and mechanically competent tissue with chondrocyte columns over time, most evident at sites such as the tibial plateau. Indeed, Hox11 expression (primarily Hoxa11) was intimately coupled to such morphogenetic processes and, in particular, to the topographical rearrangement of chondrocytes into columns within the intermediate and deep zones of tibial plateau that normally endures maximal mechanical loads. Revealingly, these expression patterns were maintained even at 6 months of age. In sum, our data indicate that Hox11 genes remain engaged well beyond embryonic synovial joint patterning and are specifically tied to postnatal articular cartilage morphogenesis into a zonal and resilient tissue. The data demonstrate that Hox11 genes characterize adult, terminally differentiated, articular chondrocytes and maintain region-specificity established in the embryo.

Published

2020

6. DNMT3A and TET1 cooperate to regulate promoter epigenetic landscapes in mouse embryonic stem cells

Author

Anna Guzman, Margaret A. Goodell, Wei Li, Jianjun Shen, Min Luo, Taiping Chen, Jianzhong Su, Deqiang Sun, Yun Huang, Danielle Rux, Sean M Cullen, Tianpeng Gu, Marcos R. Estecio, Mira Jeong, Michael Kyba, Jia Jia Chen, Swanand Hardikar, Xueqiu Lin, Lei Stanley Qi, and Minjung Lee

Subjects

Epigenomics, 0301 basic medicine, Embryonic stem cells, lcsh:QH426-470, H3K27me3, Cell Line, DNA Methyltransferase 3A, Dioxygenases, Epigenesis, Genetic, Mice, 03 medical and health sciences, Proto-Oncogene Proteins, Animals, DNA (Cytosine-5-)-Methyltransferases, Epigenetics, Promoter Regions, Genetic, lcsh:QH301-705.5, DNA methylation, biology, Research, Mouse Embryonic Stem Cells, Epigenome, Methylation, PRC2, Chromatin, TET1, Cell biology, DNA-Binding Proteins, lcsh:Genetics, 030104 developmental biology, Histone, DNA demethylation, lcsh:Biology (General), 5-Methylcytosine, biology.protein, DNMT3A

Abstract

Background DNA methylation is a heritable epigenetic mark, enabling stable but reversible gene repression. In mammalian cells, DNA methyltransferases (DNMTs) are responsible for modifying cytosine to 5-methylcytosine (5mC), which can be further oxidized by the TET dioxygenases to ultimately cause DNA demethylation. However, the genome-wide cooperation and functions of these two families of proteins, especially at large under-methylated regions, called canyons, remain largely unknown. Results Here we demonstrate that DNMT3A and TET1 function in a complementary and competitive manner in mouse embryonic stem cells to mediate proper epigenetic landscapes and gene expression. The longer isoform of DNMT3A, DNMT3A1, exhibits significant enrichment at distal promoters and canyon edges, but is excluded from proximal promoters and canyons where TET1 shows prominent binding. Deletion of Tet1 increases DNMT3A1 binding capacity at and around genes with wild-type TET1 binding. However, deletion of Dnmt3a has a minor effect on TET1 binding on chromatin, indicating that TET1 may limit DNA methylation partially by protecting its targets from DNMT3A and establishing boundaries for DNA methylation. Local CpG density may determine their complementary binding patterns and therefore that the methylation landscape is encoded in the DNA sequence. Furthermore, DNMT3A and TET1 impact histone modifications which in turn regulate gene expression. In particular, they regulate Polycomb Repressive Complex 2 (PRC2)-mediated H3K27me3 enrichment to constrain gene expression from bivalent promoters. Conclusions We conclude that DNMT3A and TET1 regulate the epigenome and gene expression at specific targets via their functional interplay. Electronic supplementary material The online version of this article (10.1186/s13059-018-1464-7) contains supplementary material, which is available to authorized users.

Published

2018

7. Hox11Function Is Required for Region-Specific Fracture Repair

Author

Kenneth M. Kozloff, S. A. Goldstein, Danielle Rux, Deneen M. Wellik, Jane Y. Song, Kyriel M. Pineault, Ilea T. Swinehart, Kayla N. Garthus, Aleesa J. Schlientz, and Gurjit S. Mandair

Subjects

0301 basic medicine, Endocrinology, Diabetes and Metabolism, Cartilage, Mesenchymal stem cell, Anatomy, Biology, Skeleton (computer programming), Bone remodeling, Cell biology, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, medicine, Limb development, Orthopedics and Sports Medicine, Tibia, Hox gene, Endochondral ossification

Abstract

The processes that govern fracture repair rely on many mechanisms that recapitulate embryonic skeletal development. Hox genes are transcription factors that perform critical patterning functions in regional domains along the axial and limb skeleton during development. Much less is known about roles for these genes in the adult skeleton. We recently reported that Hox11 genes, which function in zeugopod development (radius/ulna and tibia/fibula), are also expressed in the adult zeugopod skeleton exclusively in PDGFRα + /CD51 + /LepR+ mesenchymal stem/stromal cells (MSCs). In this study, we use a Hoxa11eGFP reporter allele and loss-of-function Hox11 alleles, and we show that Hox11 expression expands after zeugopod fracture injury, and that loss of Hox11 function results in defects in endochondral ossification and in the bone remodeling phase of repair. In Hox11 compound mutant fractures, early chondrocytes are specified but show defects in differentiation, leading to an overall deficit in the cartilage production. In the later stages of the repair process, the hard callus remains incompletely remodeled in mutants due, at least in part, to abnormal bone matrix organization. Overall, our data supports multiple roles for Hox11 genes following fracture injury in the adult skeleton.This article is protected by copyright. All rights reserved

Published

2017

8. Hoxgenes in the adult skeleton: Novel functions beyond embryonic development

Author

Danielle Rux and Deneen M. Wellik

Subjects

0301 basic medicine, Genetics, animal structures, Stromal cell, Embryogenesis, Mesenchymal stem cell, Embryo, Biology, Skeleton (computer programming), Cell biology, 03 medical and health sciences, 030104 developmental biology, embryonic structures, Hox gene, Transcription factor, Function (biology), Developmental Biology

Abstract

Hox genes encode evolutionarily conserved transcription factors that control skeletal patterning in the developing embryo. They are expressed in regionally restricted domains and function to regulate the morphology of specific vertebral and long bone elements. Recent work has provided evidence that Hox genes continue to be regionally expressed in adult tissues. Fibroblasts cultured from adult tissues show broadly maintained Hox gene expression patterns. In the adult skeleton, Hox genes are expressed in progenitor-enriched populations of mesenchymal stem/stromal cells (MSCs), and genetic loss-of-function analyses have provided evidence that Hox genes function during the fracture healing process. This review will highlight our current understanding of Hox expression in the adult animal and its function in skeletal regeneration. Developmental Dynamics 246:310-317, 2017. © 2016 Wiley Periodicals, Inc.

Published

2017

9. Joints in the appendicular skeleton: Developmental mechanisms and evolutionary influences

Author

Rebekah S. Decker, Maurizio Pacifici, Eiki Koyama, and Danielle Rux

Subjects

musculoskeletal diseases, Cartilage, Articular, 0303 health sciences, Appendicular skeleton, Morphogenesis, Context (language use), Skeletal structures, Articular cartilage, Fibrous tissue, Biology, Chick embryos, Biological Evolution, Bone and Bones, Article, 03 medical and health sciences, medicine.anatomical_structure, medicine, Animals, Humans, Cell Lineage, Joints, Neuroscience, Developmental biology, 030304 developmental biology

Abstract

The joints are a diverse group of skeletal structures, and their genesis, morphogenesis, and acquisition of specialized tissues have intrigued biologists for decades. Here we review past and recent studies on important aspects of joint development, including the roles of the interzone and morphogenesis of articular cartilage. Studies have documented the requirement of interzone cells in limb joint initiation and formation of most, if not all, joint tissues. We highlight these studies and also report more detailed interzone dissection experiments in chick embryos. Articular cartilage has always received special attention owing to its complex architecture and phenotype and its importance in long-term joint function. We pay particular attention to mechanisms by which neonatal articular cartilage grows and thickens over time and eventually acquires its multi-zone structure and becomes mechanically fit in adults. These and other studies are placed in the context of evolutionary biology, specifically regarding the dramatic changes in limb joint organization during transition from aquatic to land life. We describe previous studies, and include new data, on the knee joints of aquatic axolotls that unlike those in higher vertebrates, are not cavitated, are filled with rigid fibrous tissues and resemble amphiarthroses. We show that when axolotls metamorph to life on land, their intra-knee fibrous tissue becomes sparse and seemingly more flexible and the articular cartilage becomes distinct and acquires a tidemark. In sum, there have been considerable advances toward a better understanding of limb joint development, biological responsiveness, and evolutionary influences, though much remains unclear. Future progress in these fields should also lead to creation of new developmental biology-based tools to repair and regenerate joint tissues in acute and chronic conditions.

Published

2019

10. Regionally Restricted Hox Function in Adult Bone Marrow Multipotent Mesenchymal Stem/Stromal Cells

Author

Danielle Rux, Ilea T. Swinehart, Deneen M. Wellik, Daniel Lucas, S. A. Goldstein, Jane Y. Song, Kenneth M. Kozloff, Kyriel M. Pineault, Kelsey Trulik, and Aleesa J. Schlientz

Subjects

0301 basic medicine, Aging, animal structures, Stromal cell, Green Fluorescent Proteins, Bone Marrow Cells, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, medicine, Animals, Limb development, Tibia, Hox gene, Molecular Biology, Fracture Healing, Homeodomain Proteins, Mesenchymal stem cell, Embryogenesis, Cell Differentiation, Mesenchymal Stem Cells, Cell Biology, Anatomy, Chondrogenesis, Cell biology, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Animals, Newborn, Bone marrow, Developmental Biology

Abstract

Posterior Hox genes (Hox9-13) are critical for patterning the limb skeleton along the proximodistal axis during embryonic development. Here we show that Hox11 paralogous genes, which developmentally pattern the zeugopod (radius/ulna and tibia/fibula), remain regionally expressed in the adult skeleton. Using Hoxa11EGFP reporter mice, we demonstrate expression exclusively in multipotent mesenchymal stromal cells (MSCs) in the bone marrow of the adult zeugopod. Hox-positive cells express PDGFRα and CD51, are marked by LepR-Cre, and exhibit colony-forming unit fibroblast activity and tri-lineage differentiation in vitro. Loss of Hox11 function leads to fracture repair defects, including reduced cartilage formation and delayed ossification. Hox mutant cells are defective in osteoblastic and chondrogenic differentiation in tri-lineage differentiation experiments, and these defects are zeugopod specific. In the stylopod (humerus and femur) and sternum, bone marrow MSCs express other regionally restricted Hox genes, and femur fractures heal normally in Hox11 mutants. Together, our data support regional Hox expression and function in skeletal MSCs.

Published

2016

11. HoxA3 is an apical regulator of haemogenic endothelium

Author

Lynn M. Hartweck, Ondine Cleaver, Diana C. Chong, Arianna Caprioli, Danielle Rux, Michelina Iacovino, Michael Kyba, and Istvan Szatmari

Subjects

Time Factors, Cellular differentiation, Sequence Homology, Medical and Health Sciences, Mesoderm, Hox genes, Mice, chemistry.chemical_compound, 0302 clinical medicine, Aorta-gonad-mesonephros, Developmental, In Situ Hybridization, Yolk Sac, Oligonucleotide Array Sequence Analysis, Mice, Knockout, 0303 health sciences, Reverse Transcriptase Polymerase Chain Reaction, Gene Expression Regulation, Developmental, Cell Differentiation, Biological Sciences, Flow Cytometry, Cell biology, Haematopoiesis, medicine.anatomical_structure, RUNX1, Embryo, 030220 oncology & carcinogenesis, Core Binding Factor Alpha 2 Subunit, embryonic structures, Hemangioblast, Stem cell, dorsal aorta, HoxA3, Endothelium, Hemangioblasts, Knockout, Molecular Sequence Data, Biology, Article, 03 medical and health sciences, Vasculogenesis, Sequence Homology, Nucleic Acid, medicine, Animals, Cell Lineage, hemogenic endothelium, 030304 developmental biology, Homeodomain Proteins, Base Sequence, Nucleic Acid, Gene Expression Profiling, Mammalian, Cell Biology, hemangioblast, Embryo, Mammalian, hematopoiesis, Hematopoiesis, Gene Expression Regulation, chemistry, Developmental Biology

Abstract

During development, haemogenesis occurs invariably at sites of vasculogenesis. Between embryonic day (E) 9.5 and E10.5 in mice, endothelial cells in the caudal part of the dorsal aorta generate haematopoietic stem cells and are referred to as haemogenic endothelium. The mechanisms by which haematopoiesis is restricted to this domain, and how the morphological transformation from endothelial to haematopoietic is controlled are unknown. We show here that HoxA3, a gene uniquely expressed in the embryonic but not yolk sac vasculature, restrains haematopoietic differentiation of the earliest endothelial progenitors, and induces reversion of the earliest haematopoietic progenitors into CD41-negative endothelial cells. This reversible modulation of endothelial-haematopoietic state is accomplished by targeting key haematopoietic transcription factors for downregulation, including Runx1, Gata1, Gfi1B, Ikaros, and PU.1. Through loss-of-function, and gain-of-function epistasis experiments, and the identification of antipodally regulated targets, we show that among these factors, Runx1 is uniquely able to erase the endothelial program set up by HoxA3. These results suggest both why a frank endothelium does not precede haematopoiesis in the yolk sac, and why haematopoietic stem cell generation requires Runx1 expression only in endothelial cells.

Published

2010

12. Inducible cassette exchange: a rapid and efficient system enabling conditional gene expression in embryonic stem and primary cells

Author

Gagan Bajwa, Michelina Iacovino, Elisabeth Mahen, Danielle Rux, Darko Bosnakovski, Holger Fey, Ana Mitanoska, Michael Kyba, and Zhaohui Xu

Subjects

Male, Cellular differentiation, Transgene, Gene Expression, Biology, Cell fate determination, Muscle Development, Transfection, Article, Mice, Directed differentiation, Animals, Humans, Transgenes, Alleles, Embryonic Stem Cells, MyoD Protein, HEK 293 cells, Lentivirus, Cell Differentiation, Cell Biology, Fibroblasts, Embryonic stem cell, Molecular biology, Cell biology, Mutagenesis, Insertional, Electroporation, HEK293 Cells, Genetic Loci, Doxycycline, Molecular Medicine, MYF5, Myogenin, Myogenic Regulatory Factor 5, Reprogramming, Developmental Biology, Plasmids

Abstract

Genetic modification is critically enabling for studies addressing specification and maintenance of cell fate; however, methods for engineering modifications are inefficient. We demonstrate a rapid and efficient recombination system in which an inducible, floxed cre allele replaces itself with an incoming transgene. We target this inducible cassette exchange (ICE) allele to the (HPRT) locus and demonstrate recombination in murine embryonic stem cells (ESCs) and primary cells from derivative ICE mice. Using lentivectors, we demonstrate recombination at a randomly integrated ICE locus in human ESCs. To illustrate the utility of this system, we insert the myogenic regulator, Myf5, into the ICE locus in each platform. This enables efficient directed differentiation of mouse and human ESCs into skeletal muscle and conditional myogenic transdetermination of primary cells cultured in vitro. This versatile tool is thus well suited to gain-of-function studies probing gene function in the specification and reprogramming of cell fate.

Published

2011

13. HoxA3 Controls Notch Pathway to Repress Blood Development

Author

Michael Kyba, Danielle Rux, Valentina Sanghez, Michael B. Elowitz, Joe Markson, Mitsujiro Osawa, Steven Beuder, Michelina Iacovino, and Dustin Kee

Subjects

Hemogenic endothelium, JAG1, Immunology, Notch signaling pathway, Cell Biology, Hematology, Biology, Biochemistry, Cell biology, LFNG, Haematopoiesis, chemistry.chemical_compound, Downregulation and upregulation, RUNX1, chemistry, Stem cell

Abstract

Hematopoietic stem cells (HSC) are generated from a specialized subset of endothelial cells, hemogenic endothelium. Previous studies performed by our group showed that HoxA3 restrains the cell at the hemogenic endothelium stage, inhibiting further differentiation toward blood by direct repression of Runx1. Building on our previous work, we show here that overexpression of HoxA3 affects the Notch pathway. Upon HoxA3 upregulation in endothelial cells, Jag1 is induced, Mfng (Manic) and Lfng (Lunatic) fringes are downregulated, and there is a trend towards Notch target gene repression. These data suggest that in the presence of HoxA3, endothelial cells are blocked from receiving Notch signal through ligand cis-inhibition with resulting blood inhibition. In order to test this hypothesis, we evaluated the effect of activation or inhibition of the Notch pathway during blood development. We show here that the number of blood progenitors originating from the hemogenic endothelium is decreased when the Notch pathway is inhibited. Conversely, induction of the pathway by upregulation of NICD (Notch1 Intra Cellular Domain) promotes an increase in the number of blood progenitors originating from hemogenic endothelium. Furthermore, inhibition of the pathway when HoxA3 is upregulated has little or no effect in blood while induction of the pathway in HoxA3 presence in part promotes blood development. Taken together, these results demonstrate that Notch pathway is both sufficient and essential for blood development. Specifically HoxA3 inhibits Notch signal reception in two ways: 1) HoxA3 increases Jag1 ligand expression that acts in cis-inhibition; 2) represses Manic and Lunatic fringes both necessary to increase the affinity of Notch receptors for the Delta ligands. When this blockage is bypassed by NICD upregulation, blood is formed, demonstrating that HoxA3-dependent Notch inhibition results in blood suppression. Disclosures No relevant conflicts of interest to declare.

Published

2014