Your search keyword '"Zelzer E"' showing total 65 results

1. Tendon-to-bone attachment cells are bi-fated are regulated by shared enhancers KLF transcription factors

Author

Kult, S, Olender, T, Osterwalder, M, Krief, S, Blecher-Gonen, R, Ben-Moshe, S, Farack, L, Keren-Shaul, H, Leshkowitz, D, Salame, TM, Capellini, TD, Itzkovitz, S, Amit, I, Visel, A, and Zelzer, E

Subjects

Genetics, Clinical Sciences, Genetics & Heredity, Clinical sciences

Published

2020

2. More than movement: the proprioceptive system as a new regulator of musculoskeletal biology

Author

Bornstein, B, Konstantin, N, Alessandro, C, Tresch, M, Zelzer, E, Bornstein B, Konstantin N, Alessandro C, Tresch MC, Zelzer E, Bornstein, B, Konstantin, N, Alessandro, C, Tresch, M, Zelzer, E, Bornstein B, Konstantin N, Alessandro C, Tresch MC, and Zelzer E

Abstract

The proprioceptive system is essential for the control of coordinated movement and posture. Thus, traditionally, the study of proprioception has focused on its role in motor control. In this review, we present more recent findings on other, non-traditional functions of this system. We focus on its involvement in musculoskeletal development, function and pathology, including the regulation of spinal alignment, bone fracture repair and joint morphogenesis. We present the hypothesis that the proprioceptive system plays a central role in musculoskeletal biology, and that understanding the underlying molecular mechanisms will promote both basic science and medical innovations. As an example, we discuss recent evidence indicating that Piezo2, a key mechanosensitive ion channel of proprioception, regulates spine alignment and joint development. The presented findings show that the proprioceptive system regulates a wide range of developmental and physiological processes and that its dysfunction may contribute to the etiology of various musculoskeletal pathologies.

Published

2021

3. Tendon-to-bone attachment cells are bi-fated < and > are regulated by shared enhancers < and > KLF transcription factors

Author

Kult, S, Olender, T, Osterwalder, M, Krief, S, Blecher-Gonen, R, Ben-Moshe, S, Farack, L, Keren-Shaul, H, Leshkowitz, D, Salame, TM, Capellini, TD, Itzkovitz, S, Amit, I, Visel, A, and Zelzer, E

Subjects

Genetics & Heredity, Clinical Sciences, Genetics

Published

2020

4. Deposition of collagen type I onto skeletal endothelium reveals a new role for blood vessels in regulating bone morphology

Author

Shoham, A.B., Rot, C., Stern, T., Krief, S., Akiva, A., Dadosh, T., Sabany, H., Lu, Yinhui, Kadler, K.E., Zelzer, E., and Materials and Interface Chemistry

Subjects

Basement membrane, Mineralization, Mouse, Bone and Bones/embryology, Mice, Transgenic, Collagen Type I/metabolism, Vascular patterning, Mice, Collagen type I, Endothelial cell, Vegfa, Osteoblasts/physiology, Pregnancy, Endochondral bone formation, Morphogenesis, Endothelium/blood supply, Animals, Osteoid, Calcification, Physiologic/physiology, Embryo, Mammalian, Bone Matrix/embryology, Bone Development/physiology, cardiovascular system, Female, Body Patterning/physiology, Morphogenesis/physiology, Blood Vessels/embryology

Abstract

Recently, blood vessels have been implicated in the morphogenesis of various organs. The vasculature is also known to be essential for endochondral bone development, yet the underlying mechanism has remained elusive. We show that a unique composition of blood vessels facilitates the role of the endothelium in bone mineralization and morphogenesis. Immunostaining and electron microscopy showed that the endothelium in developing bones lacks basement membrane, which normally isolates the blood vessel from its surroundings. Further analysis revealed the presence of collagen type I on the endothelial wall of these vessels. Because collagen type I is the main component of the osteoid, we hypothesized that the bone vasculature guides the formation of the collagenous template and consequently of the mature bone. Indeed, some of the bone vessels were found to undergo mineralization. Moreover, the vascular pattern at each embryonic stage prefigured the mineral distribution pattern observed one day later. Finally, perturbation of vascular patterning by overexpressing Vegf in osteoblasts resulted in abnormal bone morphology, supporting a role for blood vessels in bone morphogenesis. These data reveal the unique composition of the endothelium in developing bones and indicate that vascular patterning plays a role in determining bone shape by forming a template for deposition of bone matrix.

Published

2016

5. Insulin induces transcription of target genes through the hypoxia-inducible factor HIF-1alpha /ARNT

Author

Zelzer, E., primary

Published

1998

6. Tissue specific regulation of VEGF expression during bone development requires Cbfa1/Runx2

Author

Zelzer, E., Glotzer, D. J., Hartmann, C., Thomas, D., Fukai, N., Soker, S., and Olsen, B. R.

Published

2001

7. Interaction between the bHLH-PAS protein Trachealess and the POU-domain protein Drifter, specifies tracheal cell fates

Author

Zelzer, E. and Shilo, B. Z.

Published

2000

8. The PAS domain confers target gene specificity of Drosophila bHLH/PAS proteins.

Author

Zelzer, E, Wappner, P, and Shilo, B Z

Abstract

Trachealess (Trh) and Single-minded (Sim) are highly similar Drosophila bHLH/PAS transcription factors. They activate nonoverlapping target genes and induce diverse cell fates. A single Drosophila gene encoding a bHLH/PAS protein homologous to the vertebrate ARNT protein was isolated and may serve as a partner for both Trh and Sim. We show that Trh and Sim complexes recognize similar DNA-binding sites in the embryo. To examine the basis for their distinct target gene specificity, the activity of Trh-Sim chimeric proteins was monitored in embryos. Replacement of the Trh PAS domain by the analogous region of Sim was sufficient to convert it into a functional Sim protein. The PAS domain thus mediates all the features conferring specificity and the distinct recognition of target genes. The normal expression pattern of additional proteins essential for the activity of the Trh or Sim complexes can be inferred from the induction pattern of target genes and binding-site reporters, triggered by ubiquitous expression of Trh or Sim. We postulate that the capacity of bHLH/PAS heterodimers to associate, through the PAS domain, with additional distinct proteins that bind target-gene DNA, is essential to confer specificity.

Published

1997

9. More than movement: the proprioceptive system as a new regulator of musculoskeletal biology

Author

Bavat Bornstein, Nitzan Konstantin, Matthew C. Tresch, Elazar Zelzer, Cristiano Alessandro, Bornstein, B, Konstantin, N, Alessandro, C, Tresch, M, and Zelzer, E

Subjects

0301 basic medicine, Proprioception, Physiology, Basic science, joint loading, Regulator, Motor control, p'roprioception, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mechanosensitive ion channel, muscle coordination, Physiology (medical), motor control, Coordinated movement, Neuroscience, 030217 neurology & neurosurgery

Abstract

The proprioceptive system is essential for the control of coordinated movement and posture. Thus, traditionally, the study of proprioception has focused on its role in motor control. In this review, we present more recent findings on other, non-traditional functions of this system. We focus on its involvement in musculoskeletal development, function and pathology, including the regulation of spinal alignment, bone fracture repair and joint morphogenesis. We present the hypothesis that the proprioceptive system plays a central role in musculoskeletal biology, and that understanding the underlying molecular mechanisms will promote both basic science and medical innovations. As an example, we discuss recent evidence indicating that Piezo2, a key mechanosensitive ion channel of proprioception, regulates spine alignment and joint development. The presented findings show that the proprioceptive system regulates a wide range of developmental and physiological processes and that its dysfunction may contribute to the etiology of various musculoskeletal pathologies.

Published

2021

10. Limited column formation in the embryonic growth plate implies divergent growth mechanisms during pre- and postnatal bone development.

Author

Rubin S, Agrawal A, Seewald A, Lian MJ, Gottdenker O, Villoutreix P, Baule A, Stern T, and Zelzer E

Subjects

Animals, Mice, Imaging, Three-Dimensional, Growth Plate growth & development, Bone Development, Chondrocytes physiology, Chondrocytes cytology

Abstract

Chondrocyte columns, which are a hallmark of growth plate architecture, play a central role in bone elongation. Columns are formed by clonal expansion following rotation of the division plane, resulting in a stack of cells oriented parallel to the growth direction. In this work, we analyzed hundreds of Confetti multicolor clones in growth plates of mouse embryos using a pipeline comprising 3D imaging and algorithms for morphometric analysis. Surprisingly, analysis of the elevation angles between neighboring pairs of cells revealed that most cells did not display the typical stacking pattern associated with column formation, implying incomplete rotation of the division plane. Morphological analysis revealed that although embryonic clones were elongated, they formed clusters oriented perpendicular to the growth direction. Analysis of growth plates of postnatal mice revealed both complex columns, composed of ordered and disordered cell stacks, and small, disorganized clusters located in the outer edges. Finally, correlation between the temporal dynamics of the ratios between clusters and columns and between bone elongation and expansion suggests that clusters may promote expansion, whereas columns support elongation. Overall, our findings support the idea that modulations of division plane rotation of proliferating chondrocytes determines the formation of either clusters or columns, a multifunctional design that regulates morphogenesis throughout pre- and postnatal bone growth. Broadly, this work provides a new understanding of the cellular mechanisms underlying growth plate activity and bone elongation during development., Competing Interests: SR, AA, AS, ML, OG, PV, AB, TS, EZ No competing interests declared, (© 2024, Rubin, Agrawal et al.)

Published

2024

11. The mechanosensitive ion channel ASIC2 mediates both proprioceptive sensing and spinal alignment.

Author

Bornstein B, Watkins B, Passini FS, Blecher R, Assaraf E, Sui XM, Brumfeld V, Tsoory M, Kröger S, and Zelzer E

Subjects

Animals, Mice, Muscle Spindles physiology, Sensory Receptor Cells metabolism, Acid Sensing Ion Channels metabolism, Proprioception physiology

Abstract

By translating mechanical forces into molecular signals, proprioceptive neurons provide the CNS with information on muscle length and tension, which is necessary to control posture and movement. However, the identities of the molecular players that mediate proprioceptive sensing are largely unknown. Here, we confirm the expression of the mechanosensitive ion channel ASIC2 in proprioceptive sensory neurons. By combining in vivo proprioception-related functional tests with ex vivo electrophysiological analyses of muscle spindles, we showed that mice lacking Asic2 display impairments in muscle spindle responses to stretch and motor coordination tasks. Finally, analysis of skeletons of Asic2 loss-of-function mice revealed a specific effect on spinal alignment. Overall, we identify ASIC2 as a key component in proprioceptive sensing and a regulator of spine alignment., (© 2023 The Authors. Experimental Physiology published by John Wiley & Sons Ltd on behalf of The Physiological Society.)

Published

2024

12. A single-cell census of mouse limb development identifies complex spatiotemporal dynamics of skeleton formation.

Author

Markman S, Zada M, David E, Giladi A, Amit I, and Zelzer E

Subjects

Animals, Mice, Cell Differentiation, Organogenesis, Extremities growth & development, Skeleton growth & development

Abstract

Limb development has long served as a model system for coordinated spatial patterning of progenitor cells. Here, we identify a population of naive limb progenitors and show that they differentiate progressively to form the skeleton in a complex, non-consecutive, three-dimensional pattern. Single-cell RNA sequencing of the developing mouse forelimb identified three progenitor states: naive, proximal, and autopodial, as well as Msx1 as a marker for the naive progenitors. In vivo lineage tracing confirmed this role and localized the naive progenitors to the outer margin of the limb, along the anterior-posterior axis. Sequential pulse-chase experiments showed that the progressive transition of Msx1 + naive progenitors into proximal and autopodial progenitors coincides with their differentiation to Sox9 + chondroprogenitors, which occurs along all the forming skeletal segments. Indeed, tracking the spatiotemporal sequence of differentiation showed that the skeleton forms progressively in a complex pattern. These findings suggest an alternative model for limb skeleton development., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

13. Molecular characterization of the intact mouse muscle spindle using a multi-omics approach.

Author

Bornstein B, Heinemann-Yerushalmi L, Krief S, Adler R, Dassa B, Leshkowitz D, Kim M, Bewick G, Banks RW, and Zelzer E

Subjects

Mice, Animals, Proteomics, Muscle, Skeletal physiology, Proprioception physiology, Muscle Spindles physiology, Multiomics

Abstract

The proprioceptive system is essential for the control of coordinated movement, posture, and skeletal integrity. The sense of proprioception is produced in the brain using peripheral sensory input from receptors such as the muscle spindle, which detects changes in the length of skeletal muscles. Despite its importance, the molecular composition of the muscle spindle is largely unknown. In this study, we generated comprehensive transcriptomic and proteomic datasets of the entire muscle spindle isolated from the murine deep masseter muscle. We then associated differentially expressed genes with the various tissues composing the spindle using bioinformatic analysis. Immunostaining verified these predictions, thus establishing new markers for the different spindle tissues. Utilizing these markers, we identified the differentiation stages the spindle capsule cells undergo during development. Together, these findings provide comprehensive molecular characterization of the intact spindle as well as new tools to study its development and function in health and disease., Competing Interests: BB, LH, SK, RA, BD, DL, MK, GB, RB, EZ No competing interests declared, (© 2023, Bornstein, Heinemann-Yerushalmi et al.)

Published

2023

14. A mineralizing pool of Gli1-expressing progenitors builds the tendon enthesis and demonstrates therapeutic potential.

Author

Fang F, Xiao Y, Zelzer E, Leong KW, and Thomopoulos S

Subjects

Animals, Mice, Zinc Finger Protein GLI1, Chondrocytes, Transcription Factors, Tendons, Wound Healing

Abstract

The enthesis, a fibrocartilaginous transition between tendon and bone, is necessary for force transfer from muscle to bone to produce joint motion. The enthesis is prone to injury due to mechanical demands, and it cannot regenerate. A better understanding of how the enthesis develops will lead to more effective therapies to prevent pathology and promote regeneration. Here, we used single-cell RNA sequencing to define the developmental transcriptome of the mouse entheses over postnatal stages. Six resident cell types, including enthesis progenitors and mineralizing chondrocytes, were identified along with their transcription factor regulons and temporal regulation. Following the prior discovery of the necessity of Gli1-lineage cells for mouse enthesis development and healing, we then examined their transcriptomes at single-cell resolution and demonstrated clonogenicity and multipotency of the Gli1-expressing progenitors. Transplantation of Gli1-lineage cells to mouse enthesis injuries improved healing, demonstrating their therapeutic potential for enthesis regeneration., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

15. Neonatal Enthesis Healing Involves Noninflammatory Acellular Scar Formation through Extracellular Matrix Secretion by Resident Cells.

Author

Vinestock RC, Felsenthal N, Assaraf E, Katz E, Rubin S, Heinemann-Yerushalmi L, Krief S, Dezorella N, Levin-Zaidman S, Tsoory M, Thomopoulos S, and Zelzer E

Subjects

Animals, Extracellular Matrix, Inflammation, Mice, Tendons, Cicatrix, Wound Healing physiology

Abstract

Wound healing typically recruits the immune and vascular systems to restore tissue structure and function. However, injuries to the enthesis, a hypocellular and avascular tissue, often result in fibrotic scar formation and loss of mechanical properties, severely affecting musculoskeletal function and life quality. This raises questions about the healing capabilities of the enthesis. Herein, this study established an injury model to the Achilles entheses of neonatal mice to study the effectiveness of early-age enthesis healing. Histology and immunohistochemistry analyses revealed an atypical process that did not involve inflammation or angiogenesis. Instead, healing was mediated by secretion of collagen types I and II by resident cells, which formed a permanent hypocellular and avascular scar. Transmission electron microscopy showed that the cellular response to injury, including endoplasmic reticulum stress, autophagy, and cell death, varied between the tendon and cartilage ends of the enthesis. Single-molecule in situ hybridization, immunostaining, and terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assays verified these differences. Finally, gait analysis showed that these processes effectively restored function of the injured leg. These findings reveal a novel healing mechanism in neonatal entheses, whereby local extracellular matrix secretion by resident cells forms an acellular extracellular matrix deposit without inflammation, allowing gait restoration. These insights into the healing mechanism of a complex transitional tissue may lead to new therapeutic strategies for adult enthesis injuries., (Copyright © 2022 American Society for Investigative Pathology. Published by Elsevier Inc. All rights reserved.)

Published

2022

16. Application of 3D MAPs pipeline identifies the morphological sequence chondrocytes undergo and the regulatory role of GDF5 in this process.

Author

Rubin S, Agrawal A, Stegmaier J, Krief S, Felsenthal N, Svorai J, Addadi Y, Villoutreix P, Stern T, and Zelzer E

Subjects

Animals, Animals, Newborn, Cell Differentiation, Cell Proliferation, Embryo, Mammalian, Female, Growth Differentiation Factor 5 economics, Growth Plate cytology, Growth Plate diagnostic imaging, Imaging, Three-Dimensional, Intravital Microscopy, Mice, Knockout, Models, Animal, Tibia cytology, Tibia drug effects, Tibia growth & development, X-Ray Microtomography, Mice, Chondrocytes physiology, Growth Differentiation Factor 5 metabolism, Growth Plate growth & development

Abstract

The activity of epiphyseal growth plates, which drives long bone elongation, depends on extensive changes in chondrocyte size and shape during differentiation. Here, we develop a pipeline called 3D Morphometric Analysis for Phenotypic significance (3D MAPs), which combines light-sheet microscopy, segmentation algorithms and 3D morphometric analysis to characterize morphogenetic cellular behaviors while maintaining the spatial context of the growth plate. Using 3D MAPs, we create a 3D image database of hundreds of thousands of chondrocytes. Analysis reveals broad repertoire of morphological changes, growth strategies and cell organizations during differentiation. Moreover, identifying a reduction in Smad 1/5/9 activity together with multiple abnormalities in cell growth, shape and organization provides an explanation for the shortening of Gdf5 KO tibias. Overall, our findings provide insight into the morphological sequence that chondrocytes undergo during differentiation and highlight the ability of 3D MAPs to uncover cellular mechanisms that may regulate this process., (© 2021. The Author(s).)

Published

2021

17. BCKDK regulates the TCA cycle through PDC in the absence of PDK family during embryonic development.

Author

Heinemann-Yerushalmi L, Bentovim L, Felsenthal N, Vinestock RC, Michaeli N, Krief S, Silberman A, Cohen M, Ben-Dor S, Brenner O, Haffner-Krausz R, Itkin M, Malitsky S, Erez A, and Zelzer E

Subjects

Animals, Animals, Newborn, Embryo Loss enzymology, Embryo Loss pathology, Gene Deletion, Hypoglycemia complications, Hypoglycemia enzymology, Hypoglycemia pathology, Ketosis complications, Ketosis enzymology, Ketosis pathology, Mice, Knockout, Models, Biological, Phosphorylation, Pyruvic Acid metabolism, Mice, Citric Acid Cycle, Embryonic Development, Protein Kinases metabolism, Pyruvate Dehydrogenase Acetyl-Transferring Kinase metabolism, Pyruvate Dehydrogenase Complex metabolism

Abstract

Pyruvate dehydrogenase kinases (PDK1-4) inhibit the TCA cycle by phosphorylating pyruvate dehydrogenase complex (PDC). Here, we show that PDK family is dispensable for murine embryonic development and that BCKDK serves as a compensatory mechanism by inactivating PDC. First, we knocked out all four Pdk genes one by one. Surprisingly, Pdk total KO embryos developed and were born in expected ratios but died by postnatal day 4 because of hypoglycemia or ketoacidosis. Moreover, PDC was phosphorylated in these embryos, suggesting that another kinase compensates for PDK family. Bioinformatic analysis implicated branched-chain ketoacid dehydrogenase kinase (Bckdk), a key regulator of branched-chain amino acids (BCAAs) catabolism. Indeed, knockout of Bckdk and Pdk family led to the loss of PDC phosphorylation, an increase in PDC activity and pyruvate entry into the TCA cycle, and embryonic lethality. These findings reveal a regulatory crosstalk hardwiring BCAA and glucose catabolic pathways, which feed the TCA cycle., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

18. Bi-fated tendon-to-bone attachment cells are regulated by shared enhancers and KLF transcription factors.

Author

Kult S, Olender T, Osterwalder M, Markman S, Leshkowitz D, Krief S, Blecher-Gonen R, Ben-Moshe S, Farack L, Keren-Shaul H, Salame TM, Capellini TD, Itzkovitz S, Amit I, Visel A, and Zelzer E

Subjects

Animals, Bone and Bones, Female, Kruppel-Like Factor 4 genetics, Kruppel-Like Factor 4 metabolism, Kruppel-Like Transcription Factors metabolism, Mice, Regulatory Sequences, Nucleic Acid, Tendons, Chondrocytes metabolism, Kruppel-Like Transcription Factors genetics, Tenocytes metabolism, Transcriptome

Abstract

The mechanical challenge of attaching elastic tendons to stiff bones is solved by the formation of a unique transitional tissue. Here, we show that murine tendon-to-bone attachment cells are bi-fated, activating a mixture of chondrocyte and tenocyte transcriptomes, under regulation of shared regulatory elements and Krüppel-like factors (KLFs) transcription factors. High-throughput bulk and single-cell RNA sequencing of humeral attachment cells revealed expression of hundreds of chondrogenic and tenogenic genes, which was validated by in situ hybridization and single-molecule ISH. ATAC sequencing showed that attachment cells share accessible intergenic chromatin areas with either tenocytes or chondrocytes. Epigenomic analysis revealed enhancer signatures for most of these regions. Transgenic mouse enhancer reporter assays verified the shared activity of some of these enhancers. Finally, integrative chromatin and motif analyses and transcriptomic data implicated KLFs as regulators of attachment cells. Indeed, blocking expression of both Klf2 and Klf4 in developing limb mesenchyme impaired their differentiation., Competing Interests: SK, TO, MO, SM, DL, SK, RB, SB, LF, HK, TS, TC, SI, IA, AV, EZ No competing interests declared, (© 2021, Kult et al.)

Published

2021

19. Piezo2 expressed in proprioceptive neurons is essential for skeletal integrity.

Author

Assaraf E, Blecher R, Heinemann-Yerushalmi L, Krief S, Carmel Vinestock R, Biton IE, Brumfeld V, Rotkopf R, Avisar E, Agar G, and Zelzer E

Subjects

Abnormalities, Multiple, Animals, Bone Remodeling, Core Binding Factor Alpha 3 Subunit metabolism, Disease Models, Animal, Early Growth Response Protein 3 metabolism, Genetic Predisposition to Disease genetics, Hip Dislocation genetics, Hip Dislocation metabolism, Hip Dislocation pathology, Hip Joint anatomy & histology, Hip Joint metabolism, Hip Joint pathology, Ion Channels genetics, Mice, Mice, Inbred C57BL, Mice, Knockout, Musculoskeletal Abnormalities genetics, Musculoskeletal Abnormalities pathology, Musculoskeletal System pathology, Scoliosis, Ion Channels metabolism, Musculoskeletal Abnormalities metabolism, Musculoskeletal System metabolism, Neurons metabolism, Proprioception physiology

Abstract

In humans, mutations in the PIEZO2 gene, which encodes for a mechanosensitive ion channel, were found to result in skeletal abnormalities including scoliosis and hip dysplasia. Here, we show in mice that loss of Piezo2 expression in the proprioceptive system recapitulates several human skeletal abnormalities. While loss of Piezo2 in chondrogenic or osteogenic lineages does not lead to human-like skeletal abnormalities, its loss in proprioceptive neurons leads to spine malalignment and hip dysplasia. To validate the non-autonomous role of proprioception in hip joint morphogenesis, we studied this process in mice mutant for proprioceptive system regulators Runx3 or Egr3. Loss of Runx3 in the peripheral nervous system, but not in skeletal lineages, leads to similar joint abnormalities, as does Egr3 loss of function. These findings expand the range of known regulatory roles of the proprioception system on the skeleton and provide a central component of the underlying molecular mechanism, namely Piezo2.

Published

2020

20. Bone morphology is regulated modularly by global and regional genetic programs.

Author

Eyal S, Kult S, Rubin S, Krief S, Felsenthal N, Pineault KM, Leshkowitz D, Salame TM, Addadi Y, Wellik DM, and Zelzer E

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Bone Development genetics, Bone and Bones metabolism, Embryo, Mammalian, Female, Gene Expression Regulation, Developmental physiology, Homeodomain Proteins metabolism, Ligaments anatomy & histology, Ligaments embryology, Ligaments metabolism, Male, Mice, Mice, Transgenic, Organ Specificity genetics, Pre-B-Cell Leukemia Transcription Factor 1 genetics, Pre-B-Cell Leukemia Transcription Factor 1 metabolism, Pregnancy, SOX9 Transcription Factor genetics, SOX9 Transcription Factor metabolism, Tendons anatomy & histology, Tendons embryology, Tendons metabolism, Basic Helix-Loop-Helix Transcription Factors genetics, Bone and Bones anatomy & histology, Bone and Bones embryology, Genes, Developmental genetics, Homeodomain Proteins genetics

Abstract

Bone protrusions provide stable anchoring sites for ligaments and tendons and define the unique morphology of each long bone. Despite their importance, the mechanism by which superstructures are patterned is unknown. Here, we identify components of the genetic program that control the patterning of Sox9 + / Scx + superstructure progenitors in mouse and show that this program includes both global and regional regulatory modules. Using light-sheet fluorescence microscopy combined with genetic lineage labeling, we mapped the broad contribution of the Sox9 + / Scx + progenitors to the formation of bone superstructures. Then, by combining literature-based evidence, comparative transcriptomic analysis and genetic mouse models, we identified Gli3 as a global regulator of superstructure patterning, whereas Pbx1 , Pbx2 , Hoxa11 and Hoxd11 act as proximal and distal regulators, respectively. Moreover, by demonstrating a dose-dependent pattern regulation in Gli3 and Pbx1 compound mutations, we show that the global and regional regulatory modules work in a coordinated manner. Collectively, our results provide strong evidence for genetic regulation of superstructure patterning, which further supports the notion that long bone development is a modular process.This article has an associated 'The people behind the papers' interview., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

21. Common cellular origin and diverging developmental programs for different sesamoid bones.

Author

Eyal S, Rubin S, Krief S, Levin L, and Zelzer E

Subjects

Animals, Biological Evolution, Bone Morphogenetic Protein 2 metabolism, Bone Morphogenetic Protein 4 metabolism, Cartilage metabolism, Cell Lineage, Female, Femur metabolism, Fibrocartilage metabolism, Heterozygote, Male, Mice, Mice, Inbred C57BL, Muscles metabolism, Patella embryology, Patella growth & development, Sesamoid Bones cytology, Signal Transduction, Stress, Mechanical, Synovial Fluid metabolism, Basic Helix-Loop-Helix Transcription Factors genetics, Muscles embryology, SOX9 Transcription Factor genetics, Sesamoid Bones embryology, Sesamoid Bones growth & development, Transforming Growth Factor beta metabolism

Abstract

Sesamoid bones are small auxiliary bones that form near joints and contribute to their stability and function. Thus far, providing a comprehensive developmental model or classification system for this highly diverse group of bones has been challenging. Here, we compare our previously reported mechanisms of patella development in the mouse with those of two anatomically different sesamoids, namely lateral fabella and digit sesamoids. We show that all three types of sesamoid bones originate from Sox9 + / Scx + progenitors under the regulation of TGFβ and independently of mechanical stimuli from muscles. Whereas BMP2 regulates the growth of all examined sesamoids, the differentiation of lateral fabella or digit sesamoids is regulated redundantly by BMP4 and BMP2. Next, we show that whereas patella and digit sesamoids initially form in juxtaposition to long bones, lateral fabella forms independently and at a distance. Finally, our evidence suggests that, unlike the synovial joint that separates patella from femur, digit sesamoids detach from the phalanx by formation of a fibrocartilaginous joint. These findings highlight both common and divergent molecular and mechanical features of sesamoid bone development, which underscores their evolutionary plasticity., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

22. A novel nonosteocytic regulatory mechanism of bone modeling.

Author

Ofer L, Dean MN, Zaslansky P, Kult S, Shwartz Y, Zaretsky J, Griess-Fishheimer S, Monsonego-Ornan E, Zelzer E, and Shahar R

Subjects

Animals, Biomechanical Phenomena, Bone Remodeling genetics, Bone and Bones cytology, Bone and Bones metabolism, Chondrocytes cytology, Chondrocytes metabolism, Collagen Type I genetics, Collagen Type I metabolism, Fish Proteins metabolism, Gene Expression Regulation, Glycoproteins metabolism, Humans, Oryzias metabolism, Osteoblasts cytology, Osteoblasts metabolism, Osteocytes, Protein Isoforms genetics, Protein Isoforms metabolism, Species Specificity, Swimming physiology, Zebrafish genetics, Zebrafish metabolism, Zebrafish Proteins metabolism, Feedback, Physiological, Fish Proteins genetics, Glycoproteins genetics, Mechanotransduction, Cellular genetics, Oryzias genetics, Osteogenesis genetics, Zebrafish Proteins genetics

Abstract

Osteocytes, cells forming an elaborate network within the bones of most vertebrate taxa, are thought to be the master regulators of bone modeling, a process of coordinated, local bone-tissue deposition and removal that keeps bone strains at safe levels throughout life. Neoteleost fish, however, lack osteocytes and yet are known to be capable of bone modeling, although no osteocyte-independent modeling regulatory mechanism has so far been described. Here, we characterize a novel, to our knowledge, bone-modeling regulatory mechanism in a fish species (medaka), showing that although lacking osteocytes (i.e., internal mechanosensors), when loaded, medaka bones model in mechanically directed ways, successfully reducing high tissue strains. We establish that as in mammals, modeling in medaka is regulated by the SOST gene, demonstrating a mechanistic link between skeletal loading, SOST down-regulation, and intense bone deposition. However, whereas mammalian SOST is expressed almost exclusively by osteocytes, in both medaka and zebrafish (a species with osteocytic bones), SOST is expressed by a variety of nonosteocytic cells, none of which reside within the bone bulk. These findings argue that in fishes (and perhaps other vertebrates), nonosteocytic skeletal cells are both sensors and responders, shouldering duties believed exclusive to osteocytes. This previously unrecognized, SOST-dependent, osteocyte-independent mechanism challenges current paradigms of osteocyte exclusivity in bone-modeling regulation, suggesting the existence of multivariate feedback networks in bone modeling-perhaps also in mammalian bones-and thus arguing for the possibility of untapped potential for cell targets in bone therapeutics., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

23. Development of migrating tendon-bone attachments involves replacement of progenitor populations.

Author

Felsenthal N, Rubin S, Stern T, Krief S, Pal D, Pryce BA, Schweitzer R, and Zelzer E

Subjects

Animals, Animals, Newborn, Cell Compartmentation, Cell Death, Cell Lineage, Embryo, Mammalian cytology, Embryonic Development, Female, Hedgehog Proteins metabolism, Male, Mice, Inbred C57BL, Models, Biological, Osteoclasts cytology, Osteoclasts metabolism, Phagocytes cytology, Phagocytes metabolism, SOX9 Transcription Factor metabolism, Stem Cells metabolism, Zinc Finger Protein GLI1 metabolism, Bone and Bones physiology, Movement, Stem Cells cytology, Tendons physiology

Abstract

Tendon-bone attachment sites, called entheses, are essential for musculoskeletal function. They are formed embryonically by Sox9 + progenitors and continue to develop postnatally, utilizing Gli1 lineage cells. Despite their importance, we lack information on the transition from embryonic to mature enthesis and on the relation between Sox9 + progenitors and the Gli1 lineage. Here, by performing a series of lineage tracing experiments in mice, we identify the onset of Gli1 lineage contribution to different entheses. We show that Gli1 expression is regulated embryonically by SHH signaling, whereas postnatally it is maintained by IHH signaling. During bone elongation, some entheses migrate along the bone shaft, whereas others remain stationary. Interestingly, in stationary entheses Sox9 + cells differentiate into the Gli1 lineage, but in migrating entheses this lineage is replaced by Gli1 lineage. These Gli1 + progenitors are defined embryonically to occupy the different domains of the mature enthesis. Overall, these findings demonstrate a developmental strategy whereby one progenitor population establishes a simple embryonic tissue, whereas another population contributes to its maturation. Moreover, they suggest that different cell populations may be considered for cell-based therapy of enthesis injuries., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

24. New functions for the proprioceptive system in skeletal biology.

Author

Blecher R, Heinemann-Yerushalmi L, Assaraf E, Konstantin N, Chapman JR, Cope TC, Bewick GS, Banks RW, and Zelzer E

Subjects

Animals, Disease Models, Animal, Humans, Mice embryology, Muscle Spindles physiology, Scoliosis etiology, Scoliosis pathology, Mechanoreceptors physiology, Muscle, Skeletal physiology, Proprioception physiology, Spine embryology

Abstract

Muscle spindles and Golgi tendon organs (GTOs) are two types of sensory receptors that respond to changes in length or tension of skeletal muscles. These mechanosensors have long been known to participate in both proprioception and stretch reflex. Here, we present recent findings implicating these organs in maintenance of spine alignment as well as in realignment of fractured bones. These discoveries have been made in several mouse lines lacking functional mechanosensors in part or completely. In both studies, the absence of functional spindles and GTOs produced a more severe phenotype than that of spindles alone. Interestingly, the spinal curve phenotype, which appeared during peripubertal development, bears resemblance to the human condition adolescent idiopathic scoliosis. This similarity may contribute to the study of the disease by offering both an animal model and a clue as to its aetiology. Moreover, it raises the possibility that impaired proprioceptive signalling may be involved in the aetiology of other conditions. Overall, these new findings expand considerably the scope of involvement of proprioception in musculoskeletal development and function.This article is part of the Theo Murphy meeting issue 'Mechanics of development'., (© 2018 The Author(s).)

Published

2018

25. Mechanical regulation of musculoskeletal system development.

Author

Felsenthal N and Zelzer E

Subjects

Animals, Biomechanical Phenomena, Bone Development physiology, Chondrogenesis physiology, Humans, Mice, Models, Biological, Muscle Development physiology, Signal Transduction, Musculoskeletal Development physiology

Abstract

During embryogenesis, the musculoskeletal system develops while containing within itself a force generator in the form of the musculature. This generator becomes functional relatively early in development, exerting an increasing mechanical load on neighboring tissues as development proceeds. A growing body of evidence indicates that such mechanical forces can be translated into signals that combine with the genetic program of organogenesis. This unique situation presents both a major challenge and an opportunity to the other tissues of the musculoskeletal system, namely bones, joints, tendons, ligaments and the tissues connecting them. Here, we summarize the involvement of muscle-induced mechanical forces in the development of various vertebrate musculoskeletal components and their integration into one functional unit., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

26. The Proprioceptive System Regulates Morphologic Restoration of Fractured Bones.

Author

Blecher R, Krief S, Galili T, Assaraf E, Stern T, Anekstein Y, Agar G, and Zelzer E

Subjects

Animals, Fractures, Bone pathology, Humans, Mice, Proprioception, Bone and Bones pathology, Fractures, Bone etiology

Abstract

Successful fracture repair requires restoration of bone morphology and mechanical integrity. Recent evidence shows that fractured bones of neonatal mice undergo spontaneous realignment, dubbed "natural reduction." Here, we show that natural reduction is regulated by the proprioceptive system and improves with age. Comparison among mice of different ages revealed, surprisingly, that 3-month-old mice exhibited more rapid and effective natural reduction than newborns. Fractured bones of null mutants for transcription factor Runx3, lacking functional proprioceptors, failed to realign properly. Blocking Runx3 expression in the peripheral nervous system, but not in limb mesenchyme, recapitulated the null phenotype, as did inactivation of muscles flanking the fracture site. Egr3 knockout mice, which lack muscle spindles but not Golgi tendon organs, displayed a less severe phenotype, suggesting that both receptor types, as well as muscle contraction, are required for this regulatory mechanism. These findings uncover a physiological role for proprioception in non-autonomous regulation of skeletal integrity., (Copyright © 2017 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2017

27. The Proprioceptive System Masterminds Spinal Alignment: Insight into the Mechanism of Scoliosis.

Author

Blecher R, Krief S, Galili T, Biton IE, Stern T, Assaraf E, Levanon D, Appel E, Anekstein Y, Agar G, Groner Y, and Zelzer E

Subjects

Animals, Enhancer Elements, Genetic, Mechanoreceptors physiology, Mice, Mice, Inbred C57BL, Muscle, Skeletal growth & development, Muscle, Skeletal metabolism, Muscle, Skeletal physiology, Phenotype, Spinal Cord growth & development, Spinal Cord metabolism, Spinal Cord physiology, Core Binding Factor Alpha 3 Subunit genetics, Early Growth Response Protein 3 genetics, Mechanoreceptors metabolism, Proprioception, Scoliosis genetics

Abstract

Maintaining posture requires tight regulation of the position and orientation of numerous spinal components. Yet, surprisingly little is known about this regulatory mechanism, whose failure may result in spinal deformity as in adolescent idiopathic scoliosis. Here, we use genetic mouse models to demonstrate the involvement of proprioception in regulating spine alignment. Null mutants for Runx3 transcription factor, which lack TrkC neurons connecting between proprioceptive mechanoreceptors and spinal cord, developed peripubertal scoliosis not preceded by vertebral dysplasia or muscle asymmetry. Deletion of Runx3 in the peripheral nervous system or specifically in peripheral sensory neurons, or of enhancer elements driving Runx3 expression in proprioceptive neurons, induced a similar phenotype. Egr3 knockout mice, lacking muscle spindles, but not Golgi tendon organs, displayed a less severe phenotype, suggesting that both receptor types may be required for this regulatory mechanism. These findings uncover a central role for the proprioceptive system in maintaining spinal alignment., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

28. Development of a subset of forelimb muscles and their attachment sites requires the ulnar-mammary syndrome gene Tbx3.

Author

Colasanto MP, Eyal S, Mohassel P, Bamshad M, Bonnemann CG, Zelzer E, Moon AM, and Kardon G

Subjects

Animals, Cell Lineage, Female, Gene Expression Regulation, Developmental, Humans, Male, Mesoderm embryology, Mesoderm metabolism, Mice, Inbred C57BL, Muscle Fibers, Skeletal pathology, Olecranon Process pathology, T-Box Domain Proteins metabolism, Tendons pathology, Ulna pathology, Abnormalities, Multiple pathology, Breast Diseases pathology, Forelimb pathology, Muscles pathology, T-Box Domain Proteins genetics, Ulna abnormalities

Abstract

In the vertebrate limb over 40 muscles are arranged in a precise pattern of attachment via muscle connective tissue and tendon to bone and provide an extensive range of motion. How the development of somite-derived muscle is coordinated with the development of lateral plate-derived muscle connective tissue, tendon and bone to assemble a functional limb musculoskeletal system is a long-standing question. Mutations in the T-box transcription factor, TBX3, have previously been identified as the genetic cause of ulnar-mammary syndrome (UMS), characterized by distinctive defects in posterior forelimb bones. Using conditional mutagenesis in mice, we now show that TBX3 has a broader role in limb musculoskeletal development. TBX3 is not only required for development of posterior forelimb bones (ulna and digits 4 and 5), but also for a subset of posterior muscles (lateral triceps and brachialis) and their bone eminence attachment sites. TBX3 specification of origin and insertion sites appears to be tightly linked with whether these particular muscles develop and may represent a newly discovered mechanism for specification of anatomical muscles. Re-examination of an individual with UMS reveals similar previously unrecognized muscle and bone eminence defects and indicates a conserved role for TBX3 in regulating musculoskeletal development., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

29. Joint Development Involves a Continuous Influx of Gdf5-Positive Cells.

Author

Shwartz Y, Viukov S, Krief S, and Zelzer E

Subjects

Animals, Cell Lineage, Cell Proliferation, Gene Expression Regulation, Gene Knock-In Techniques, Integrases metabolism, Mice, Models, Animal, Models, Biological, Morphogenesis, SOX9 Transcription Factor metabolism, Stem Cells cytology, Growth Differentiation Factor 5 metabolism, Joints cytology, Joints metabolism

Abstract

Synovial joints comprise several tissue types, including articular cartilage, the capsule, and ligaments. All of these compartments are commonly assumed to originate from an early set of Gdf5-expressing progenitors populating the interzone domain. Here, we provide evidence that joints develop through a continuous influx of cells into the interzone, where they contribute differentially to forming joint tissues. Using a knockin Gdf5-CreER(T2) mouse, we show that early labeling of Gdf5-positive interzone cells failed to mark the entire organ. Conversely, multiple Cre activation steps indicated a contribution of these cells to various joint compartments later in development. Spatiotemporal differences between Gdf5 and tdTomato reporter expression support the notion of a continuous recruitment process. Finally, differential contribution of Gdf5-positive cells to various tissues suggests that the spatiotemporal dynamics of Gdf5 expression may instruct lineage divergence. This work supports the influx model of joint development, which may apply to other organogenic processes., (Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2016

30. PTH Induces Systemically Administered Mesenchymal Stem Cells to Migrate to and Regenerate Spine Injuries.

Author

Sheyn D, Shapiro G, Tawackoli W, Jun DS, Koh Y, Kang KB, Su S, Da X, Ben-David S, Bez M, Yalon E, Antebi B, Avalos P, Stern T, Zelzer E, Schwarz EM, Gazit Z, Pelled G, Bae HM, and Gazit D

Subjects

Animals, Cell Differentiation drug effects, Cell Movement drug effects, Combined Modality Therapy, Disease Models, Animal, Female, Humans, Mesenchymal Stem Cells cytology, Osteoporosis complications, Rats, Spinal Fractures etiology, Swine, Bone Regeneration drug effects, Mesenchymal Stem Cell Transplantation methods, Mesenchymal Stem Cells drug effects, Osteoporosis therapy, Parathyroid Hormone pharmacology, Spinal Fractures therapy

Abstract

Osteoporosis affects more than 200 million people worldwide leading to more than 2 million fractures in the United States alone. Unfortunately, surgical treatment is limited in patients with low bone mass. Parathyroid hormone (PTH) was shown to induce fracture repair in animals by activating mesenchymal stem cells (MSCs). However, it would be less effective in patients with fewer and/or dysfunctional MSCs due to aging and comorbidities. To address this, we evaluated the efficacy of combination i.v. MSC and PTH therapy versus monotherapy and untreated controls, in a rat model of osteoporotic vertebral bone defects. The results demonstrated that combination therapy significantly increased new bone formation versus monotherapies and no treatment by 2 weeks (P < 0.05). Mechanistically, we found that PTH significantly enhanced MSC migration to the lumbar region, where the MSCs differentiated into bone-forming cells. Finally, we used allogeneic porcine MSCs and observed similar findings in a clinically relevant minipig model of vertebral defects. Collectively, these results demonstrate that in addition to its anabolic effects, PTH functions as an adjuvant to i.v. MSC therapy by enhancing migration to heal bone loss. This systemic approach could be attractive for various fragility fractures, especially using allogeneic cells that do not require invasive tissue harvest.

Published

2016

31. Isometric Scaling in Developing Long Bones Is Achieved by an Optimal Epiphyseal Growth Balance.

Author

Stern T, Aviram R, Rot C, Galili T, Sharir A, Kalish Achrai N, Keller Y, Shahar R, and Zelzer E

Subjects

Animals, Arm Bones diagnostic imaging, Imaging, Three-Dimensional, Leg Bones diagnostic imaging, Male, Mice, Mice, Inbred C57BL, Models, Biological, Models, Statistical, X-Ray Microtomography, Arm Bones embryology, Arm Bones growth & development, Bone Development physiology, Leg Bones embryology, Leg Bones growth & development

Abstract

One of the major challenges that developing organs face is scaling, that is, the adjustment of physical proportions during the massive increase in size. Although organ scaling is fundamental for development and function, little is known about the mechanisms that regulate it. Bone superstructures are projections that typically serve for tendon and ligament insertion or articulation and, therefore, their position along the bone is crucial for musculoskeletal functionality. As bones are rigid structures that elongate only from their ends, it is unclear how superstructure positions are regulated during growth to end up in the right locations. Here, we document the process of longitudinal scaling in developing mouse long bones and uncover the mechanism that regulates it. To that end, we performed a computational analysis of hundreds of three-dimensional micro-CT images, using a newly developed method for recovering the morphogenetic sequence of developing bones. Strikingly, analysis revealed that the relative position of all superstructures along the bone is highly preserved during more than a 5-fold increase in length, indicating isometric scaling. It has been suggested that during development, bone superstructures are continuously reconstructed and relocated along the shaft, a process known as drift. Surprisingly, our results showed that most superstructures did not drift at all. Instead, we identified a novel mechanism for bone scaling, whereby each bone exhibits a specific and unique balance between proximal and distal growth rates, which accurately maintains the relative position of its superstructures. Moreover, we show mathematically that this mechanism minimizes the cumulative drift of all superstructures, thereby optimizing the scaling process. Our study reveals a general mechanism for the scaling of developing bones. More broadly, these findings suggest an evolutionary mechanism that facilitates variability in bone morphology by controlling the activity of individual epiphyseal plates.

Published

2015

32. On the development of the patella.

Author

Eyal S, Blitz E, Shwartz Y, Akiyama H, Schweitzer R, and Zelzer E

Subjects

Animals, Bone Morphogenetic Protein 4 metabolism, Cell Differentiation physiology, In Situ Hybridization, Joints cytology, Mice, Mice, Mutant Strains, Mice, Transgenic, Morphogenesis genetics, Morphogenesis physiology, Patella cytology, Real-Time Polymerase Chain Reaction, Sesamoid Bones cytology, Stem Cells cytology, Stem Cells metabolism, Joints embryology, Joints metabolism, Patella embryology, Patella metabolism, Sesamoid Bones embryology, Sesamoid Bones metabolism

Abstract

The current view of skeletal patterning fails to explain the formation of sesamoid bones. These small bones, which facilitate musculoskeletal function, are exceptionally embedded within tendons. Although their structural design has long puzzled researchers, only a limited model for sesamoid bone development has emerged. To date, sesamoids are thought to develop inside tendons in response to mechanical signals from the attaching muscles. However, this widely accepted model has lacked substantiation. Here, we show that, contrary to the current view, in the mouse embryo the patella initially develops as a bony process at the anteriodistal surface of the femur. Later, the patella is separated from the femur by a joint formation process that is regulated by mechanical load. Concurrently, the patella becomes superficially embedded within the quadriceps tendon. At the cellular level, we show that, similar to bone eminences, the patella is formed secondarily by a distinct pool of Sox9- and Scx-positive progenitor cells. Finally, we show that TGFβ signaling is necessary for the specification of patella progenitors, whereas the BMP4 pathway is required for their differentiation. These findings establish an alternative model for patella development and provide the mechanical and molecular mechanisms that underlie this process. More broadly, our finding that activation of a joint formation program can be used to switch between the formation of bony processes and of new auxiliary bones provides a new perspective on plasticity during skeletal patterning and evolution., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

33. A pathway to bone: signaling molecules and transcription factors involved in chondrocyte development and maturation.

Author

Kozhemyakina E, Lassar AB, and Zelzer E

Subjects

Animals, Chondrocytes physiology, Chondrogenesis genetics, Chondrogenesis physiology, Growth Plate cytology, Growth Plate metabolism, Growth Plate physiology, Humans, Transcription Factors genetics, Chondrocytes cytology, Chondrocytes metabolism, Transcription Factors metabolism

Abstract

Decades of work have identified the signaling pathways that regulate the differentiation of chondrocytes during bone formation, from their initial induction from mesenchymal progenitor cells to their terminal maturation into hypertrophic chondrocytes. Here, we review how multiple signaling molecules, mechanical signals and morphological cell features are integrated to activate a set of key transcription factors that determine and regulate the genetic program that induces chondrogenesis and chondrocyte differentiation. Moreover, we describe recent findings regarding the roles of several signaling pathways in modulating the proliferation and maturation of chondrocytes in the growth plate, which is the 'engine' of bone elongation., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

34. Vascular patterning regulates interdigital cell death by a ROS-mediated mechanism.

Author

Eshkar-Oren I, Krief S, Ferrara N, Elliott AM, and Zelzer E

Subjects

Animals, Extremities blood supply, Extremities embryology, Female, Gene Expression Regulation, Developmental physiology, Mice, Organ Culture Techniques, Pregnancy, Cell Death physiology, Reactive Oxygen Species metabolism

Abstract

Blood vessels serve as key regulators of organogenesis by providing oxygen, nutrients and molecular signals. During limb development, programmed cell death (PCD) contributes to separation of the digits. Interestingly, prior to the onset of PCD, the autopod vasculature undergoes extensive patterning that results in high interdigital vascularity. Here, we show that in mice, the limb vasculature positively regulates interdigital PCD. In vivo, reduction in interdigital vessel number inhibited PCD, resulting in syndactyly, whereas an increment in vessel number and distribution resulted in elevation and expansion of PCD. Production of reactive oxygen species (ROS), toxic compounds that have been implicated in PCD, also depended on interdigital vascular patterning. Finally, ex vivo incubation of limbs in gradually decreasing oxygen levels led to a correlated reduction in both ROS production and interdigital PCD. The results support a role for oxygen in these processes and provide a mechanistic explanation for the counterintuitive positive role of the vasculature in PCD. In conclusion, we suggest a new role for vascular patterning during limb development in regulating interdigital PCD by ROS production. More broadly, we propose a double safety mechanism that restricts PCD to interdigital areas, as the genetic program of PCD provides the first layer and vascular patterning serves as the second., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

35. A mechanical Jack-like Mechanism drives spontaneous fracture healing in neonatal mice.

Author

Rot C, Stern T, Blecher R, Friesem B, and Zelzer E

Subjects

Animals, Bony Callus metabolism, Cell Proliferation, Gene Expression Profiling, Growth Plate growth & development, Growth Plate physiology, Mice, Muscle Contraction physiology, Stress, Physiological, Bone Regeneration, Bony Callus growth & development, Fracture Healing, Fractures, Spontaneous therapy, Osteogenesis physiology

Abstract

Treatment of fractured bones involves correction of displacement or angulation, known as reduction. However, angulated long-bone fractures in infants often heal and regain proper morphology spontaneously, without reduction. To study the mechanism underlying spontaneous regeneration of fractured bones, we left humeral fractures induced in newborn mice unstabilized, and rapid realignment of initially angulated bones was seen. This realignment was surprisingly not mediated by bone remodeling, but instead involved substantial movement of the two fragments prior to callus ossification. Analysis of gene expression profiles, cell proliferation, and bone growth revealed the formation of a functional, bidirectional growth plate at the concave side of the fracture. This growth plate acts like a mechanical jack, generating opposing forces that straighten the two fragments. Finally, we show that muscle force is important in this process, as blocking muscle contraction disrupts growth plate formation, leading to premature callus ossification and failed reduction.

Published

2014

36. Endothelial cells regulate neural crest and second heart field morphogenesis.

Author

Milgrom-Hoffman M, Michailovici I, Ferrara N, Zelzer E, and Tzahor E

Abstract

Cardiac and craniofacial developmental programs are intricately linked during early embryogenesis, which is also reflected by a high frequency of birth defects affecting both regions. The molecular nature of the crosstalk between mesoderm and neural crest progenitors and the involvement of endothelial cells within the cardio-craniofacial field are largely unclear. Here we show in the mouse that genetic ablation of vascular endothelial growth factor receptor 2 (Flk1) in the mesoderm results in early embryonic lethality, severe deformation of the cardio-craniofacial field, lack of endothelial cells and a poorly formed vascular system. We provide evidence that endothelial cells are required for migration and survival of cranial neural crest cells and consequently for the deployment of second heart field progenitors into the cardiac outflow tract. Insights into the molecular mechanisms reveal marked reduction in Transforming growth factor beta 1 (Tgfb1) along with changes in the extracellular matrix (ECM) composition. Our collective findings in both mouse and avian models suggest that endothelial cells coordinate cardio-craniofacial morphogenesis, in part via a conserved signaling circuit regulating ECM remodeling by Tgfb1., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

37. Repositioning forelimb superficialis muscles: tendon attachment and muscle activity enable active relocation of functional myofibers.

Author

Huang AH, Riordan TJ, Wang L, Eyal S, Zelzer E, Brigande JV, and Schweitzer R

Subjects

Animals, Foot anatomy & histology, Foot physiology, Forelimb anatomy & histology, Hindlimb anatomy & histology, Hindlimb growth & development, Humans, Mice, Muscle Contraction physiology, Tendons anatomy & histology, Forelimb growth & development, Movement physiology, Muscles physiology, Tendons growth & development

Abstract

The muscles that govern hand motion are composed of extrinsic muscles that reside within the forearm and intrinsic muscles that reside within the hand. We find that the extrinsic muscles of the flexor digitorum superficialis (FDS) first differentiate as intrinsic muscles within the hand and then relocate as myofibers to their final position in the arm. This remarkable translocation of differentiated myofibers across a joint is dependent on muscle contraction and muscle-tendon attachment. Interestingly, the intrinsic flexor digitorum brevis (FDB) muscles of the foot are identical to the FDS in tendon pattern and delayed developmental timing but undergo limited muscle translocation, providing strong support for evolutionary homology between the FDS and FDB muscles. We propose that the intrinsic FDB pattern represents the original tetrapod limb and that translocation of the muscles to form the FDS is a mammalian evolutionary addition., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

38. Tendon-bone attachment unit is formed modularly by a distinct pool of Scx- and Sox9-positive progenitors.

Author

Blitz E, Sharir A, Akiyama H, and Zelzer E

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Bone Morphogenetic Protein 4 genetics, Bone Morphogenetic Protein 4 metabolism, Bone and Bones metabolism, Cartilage cytology, Cell Differentiation drug effects, Cell Differentiation physiology, Cells, Cultured, Chondrocytes cytology, Female, Gene Expression Regulation, Developmental, In Situ Hybridization, Mice, Mice, Knockout, Microscopy, Fluorescence, SOX9 Transcription Factor genetics, Stem Cells metabolism, Tamoxifen pharmacology, Tendons metabolism, Transforming Growth Factor beta metabolism, X-Ray Microtomography, Basic Helix-Loop-Helix Transcription Factors metabolism, Bone and Bones cytology, SOX9 Transcription Factor metabolism, Stem Cells cytology, Tendons cytology

Abstract

The assembly of the musculoskeletal system requires the formation of an attachment unit between a bone and a tendon. Tendons are often inserted into bone eminences, superstructures that improve the mechanical resilience of the attachment of muscles to the skeleton and facilitate movement. Despite their functional importance, little is known about the development of bone eminences and attachment units. Here, we show that bone eminence cells are descendants of a unique set of progenitors and that superstructures are added onto the developing long bone in a modular fashion. First, we show that bone eminences emerge only after the primary cartilage rudiments have formed. Cell lineage analyses revealed that eminence cells are not descendants of chondrocytes. Moreover, eminence progenitors were specified separately and after chondroprogenitors of the primary cartilage. Fields of Sox9-positive, Scx-positive, Col2a1-negative cells identified at presumable eminence sites confirm the identity and specificity of these progenitors. The loss of eminences in limbs in which Sox9 expression was blocked in Scx-positive cells supports the hypothesis that a distinct pool of Sox9- and Scx-positive progenitors forms these superstructures. We demonstrate that TGFβ signaling is necessary for the specification of bone eminence progenitors, whereas the SCX/BMP4 pathway is required for the differentiation of these progenitors to eminence-forming cells. Our findings suggest a modular model for bone development, involving a distinct pool of Sox9- and Scx-positive progenitor cells that form bone eminences under regulation of TGFβ and BMP4 signaling. This model offers a new perspective on bone morphogenesis and on attachment unit development during musculoskeletal assembly.

Published

2013

39. Fate mapping reveals origins and dynamics of monocytes and tissue macrophages under homeostasis.

Author

Yona S, Kim KW, Wolf Y, Mildner A, Varol D, Breker M, Strauss-Ayali D, Viukov S, Guilliams M, Misharin A, Hume DA, Perlman H, Malissen B, Zelzer E, and Jung S

Subjects

Animals, Antigens, Ly metabolism, CX3C Chemokine Receptor 1, Homeostasis immunology, Immunophenotyping, Macrophages immunology, Mice, Mice, Transgenic, Monocytes immunology, Myeloid Progenitor Cells metabolism, Receptors, Chemokine metabolism, Macrophages metabolism, Monocytes metabolism

Abstract

Mononuclear phagocytes, including monocytes, macrophages, and dendritic cells, contribute to tissue integrity as well as to innate and adaptive immune defense. Emerging evidence for labor division indicates that manipulation of these cells could bear therapeutic potential. However, specific ontogenies of individual populations and the overall functional organization of this cellular network are not well defined. Here we report a fate-mapping study of the murine monocyte and macrophage compartment taking advantage of constitutive and conditional CX(3)CR1 promoter-driven Cre recombinase expression. We have demonstrated that major tissue-resident macrophage populations, including liver Kupffer cells and lung alveolar, splenic, and peritoneal macrophages, are established prior to birth and maintain themselves subsequently during adulthood independent of replenishment by blood monocytes. Furthermore, we have established that short-lived Ly6C(+) monocytes constitute obligatory steady-state precursors of blood-resident Ly6C(-) cells and that the abundance of Ly6C(+) blood monocytes dynamically controls the circulation lifespan of their progeny., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

40. HIF1α is a central regulator of collagen hydroxylation and secretion under hypoxia during bone development.

Author

Bentovim L, Amarilio R, and Zelzer E

Subjects

Animals, Bone Development, Cells, Cultured, Citric Acid Cycle, Endoplasmic Reticulum, Growth Plate metabolism, Hydroxylation, Hypoxia-Inducible Factor 1, alpha Subunit genetics, Mice, Oxygen metabolism, Procollagen-Proline Dioxygenase biosynthesis, Procollagen-Proline Dioxygenase genetics, Procollagen-Proline Dioxygenase metabolism, Protein Folding, Protein Serine-Threonine Kinases biosynthesis, Pyruvate Dehydrogenase Acetyl-Transferring Kinase, Bone and Bones embryology, Cell Hypoxia, Chondrocytes metabolism, Collagen metabolism, Hypoxia-Inducible Factor 1, alpha Subunit metabolism

Abstract

Collagen production is fundamental for the ontogeny and the phylogeny of all multicellular organisms. It depends on hydroxylation of proline residues, a reaction that uses molecular oxygen as a substrate. This dependency is expected to limit collagen production to oxygenated cells. However, during embryogenesis, cells in different tissues that develop under low oxygen levels must produce this essential protein. In this study, using the growth plate of developing bones as a model system, we identify the transcription factor hypoxia-inducible factor 1 α (HIF1α) as a central component in a mechanism that underlies collagen hydroxylation and secretion by hypoxic cells. We show that Hif1a loss of function in growth plate chondrocytes arrests the secretion of extracellular matrix proteins, including collagen type II. Reduced collagen hydroxylation and endoplasmic reticulum stress induction in Hif1a-depleted cells suggests that HIF1α regulates collagen secretion by mediating its hydroxylation and consequently its folding. We demonstrate in vivo the ability of Hif1α to drive the transcription of collagen prolyl 4-hydroxylase, which catalyzes collagen hydroxylation. We also show that, concurrently, HIF1α maintains cellular levels of oxygen, most likely by controlling the expression of pyruvate dehydrogenase kinase 1, an inhibitor of the tricarboxylic acid cycle. Through this two-armed mechanism, HIF1α acts as a central regulator of collagen production that allows chondrocytes to maintain their function as professional secretory cells in the hypoxic growth plate. As hypoxic conditions occur also during pathological conditions such as cancer, our findings may promote the understanding not only of embryogenesis, but also of pathological processes.

Published

2012

41. Muscle contraction controls skeletal morphogenesis through regulation of chondrocyte convergent extension.

Author

Shwartz Y, Farkas Z, Stern T, Aszódi A, and Zelzer E

Subjects

Alcian Blue, Animals, Biomechanical Phenomena, Cartilage anatomy & histology, Cell Movement physiology, Cell Shape, Chondrocytes cytology, Immunohistochemistry, In Situ Hybridization, Mice, Models, Statistical, Neural Crest physiology, Phalloidine, Zebrafish, Bone and Bones embryology, Cartilage embryology, Chondrocytes physiology, Growth Plate embryology, Muscle Contraction physiology, Osteogenesis physiology

Abstract

Convergent extension driven by mediolateral intercalation of chondrocytes is a key process that contributes to skeletal growth and morphogenesis. While progress has been made in deciphering the molecular mechanism that underlies this process, the involvement of mechanical load exerted by muscle contraction in its regulation has not been studied. Using the zebrafish as a model system, we found abnormal pharyngeal cartilage morphology in both chemically and genetically paralyzed embryos, demonstrating the importance of muscle contraction for zebrafish skeletal development. The shortening of skeletal elements was accompanied by prominent changes in cell morphology and organization. While in control the cells were elongated, chondrocytes in paralyzed zebrafish were smaller and exhibited a more rounded shape, confirmed by a reduction in their length-to-width ratio. The typical columnar organization of cells was affected too, as chondrocytes in various skeletal elements exhibited abnormal stacking patterns, indicating aberrant intercalation. Finally, we demonstrate impaired chondrocyte intercalation in growth plates of muscle-less Sp(d) mouse embryos, implying the evolutionary conservation of muscle force regulation of this essential morphogenetic process.Our findings provide a new perspective on the regulatory interaction between muscle contraction and skeletal morphogenesis by uncovering the role of muscle-induced mechanical loads in regulating chondrocyte intercalation in two different vertebrate models., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

42. S1P1 inhibits sprouting angiogenesis during vascular development.

Author

Ben Shoham A, Malkinson G, Krief S, Shwartz Y, Ely Y, Ferrara N, Yaniv K, and Zelzer E

Subjects

Animals, Blood Vessels embryology, Blood Vessels growth & development, Embryo, Mammalian metabolism, Mice, Mice, Transgenic, Receptors, Lysosphingolipid genetics, Zebrafish, Endothelial Cells metabolism, Neovascularization, Physiologic, Receptors, Lysosphingolipid metabolism, Vascular Endothelial Growth Factor A metabolism

Abstract

Coordination between the vascular system and forming organs is essential for proper embryonic development. The vasculature expands by sprouting angiogenesis, during which tip cells form filopodia that incorporate into capillary loops. Although several molecules, such as vascular endothelial growth factor A (Vegfa), are known to induce sprouting, the mechanism that terminates this process to ensure neovessel stability is still unknown. Sphingosine-1-phosphate receptor 1 (S1P(1)) has been shown to mediate interaction between endothelial and mural cells during vascular maturation. In vitro studies have identified S1P(1) as a pro-angiogenic factor. Here, we show that S1P(1) acts as an endothelial cell (EC)-autonomous negative regulator of sprouting angiogenesis during vascular development. Severe aberrations in vessel size and excessive sprouting found in limbs of S1P(1)-null mouse embryos before vessel maturation imply a previously unknown, mural cell-independent role for S1P(1) as an anti-angiogenic factor. A similar phenotype observed when S1P(1) expression was blocked specifically in ECs indicates that the effect of S1P(1) on sprouting is EC-autonomous. Comparable vascular abnormalities in S1p(1) knockdown zebrafish embryos suggest cross-species evolutionary conservation of this mechanism. Finally, genetic interaction between S1P(1) and Vegfa suggests that these factors interplay to regulate vascular development, as Vegfa promotes sprouting whereas S1P(1) inhibits it to prevent excessive sprouting and fusion of neovessels. More broadly, because S1P, the ligand of S1P(1), is blood-borne, our findings suggest a new mode of regulation of angiogenesis, whereby blood flow closes a negative feedback loop that inhibits sprouting angiogenesis once the vascular bed is established and functional.

Published

2012

43. The heart endocardium is derived from vascular endothelial progenitors.

Author

Milgrom-Hoffman M, Harrelson Z, Ferrara N, Zelzer E, Evans SM, and Tzahor E

Subjects

Animals, Animals, Genetically Modified, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Biomarkers metabolism, Cell Lineage physiology, Chick Embryo, Chimera, Embryo, Nonmammalian anatomy & histology, Embryo, Nonmammalian physiology, Endocardium cytology, Endothelial Cells cytology, Gene Knockdown Techniques, LIM-Homeodomain Proteins genetics, LIM-Homeodomain Proteins metabolism, Mice, Myocardium cytology, Quail, Receptor, TIE-2 genetics, Receptor, TIE-2 metabolism, Stem Cells cytology, Transcription Factors genetics, Transcription Factors metabolism, Vascular Endothelial Growth Factor Receptor-2 genetics, Vascular Endothelial Growth Factor Receptor-2 metabolism, Endocardium embryology, Endothelial Cells physiology, Heart anatomy & histology, Heart embryology, Stem Cells physiology

Abstract

The embryonic heart is composed of two cell layers: the myocardium, which contributes to cardiac muscle tissue, and the endocardium, which covers the inner lumen of the heart. Whereas significant progress has been made toward elucidating the embryonic origins of the myocardium, the origins of the endocardium remain unclear. Here, we have identified an endocardium-forming field medial to the cardiac crescent, in a continuum with the endothelial plexus. In vivo live imaging of quail embryos revealed that endothelial progenitors, like second/anterior heart field progenitors, migrate to, and enter, the heart from the arterial pole. Furthermore, embryonic endothelial cells implanted into the cardiac crescent contribute to the endocardium, but not to the myocardium. In mouse, lineage analysis focusing on endocardial cells revealed an unexpected heterogeneity in the origins of the endocardium. To gain deeper insight into this heterogeneity, we conditionally ablated Flk1 in distinct cardiovascular progenitor populations; FLK1 is required in vivo for formation of the endocardium in the Mesp1 and Tie2 lineages, but not in the Isl1 lineage. Ablation of Flk1 coupled with lineage analysis in the Isl1 lineage revealed that endothelium-derived Isl1(-) endocardial cells were significantly increased, whereas Isl1(+) endocardial cells were reduced, suggesting that the endocardium is capable of undergoing regulative compensatory growth. Collectively, our findings demonstrate that the second heart field contains distinct myocardial and endocardial progenitor populations. We suggest that the endocardium derives, at least in part, from vascular endothelial cells.

Published

2011

44. Muscle force regulates bone shaping for optimal load-bearing capacity during embryogenesis.

Author

Sharir A, Stern T, Rot C, Shahar R, and Zelzer E

Subjects

Adaptation, Physiological physiology, Animals, Bone Density physiology, Female, Male, Mice, Mice, Inbred C57BL, Muscle Contraction physiology, Muscle, Smooth physiology, Periosteum cytology, Periosteum growth & development, Pregnancy, Stress, Mechanical, Uterus anatomy & histology, Uterus physiology, Bone and Bones anatomy & histology, Bone and Bones physiology, Embryo, Mammalian anatomy & histology, Embryo, Mammalian physiology, Embryonic Development physiology, Weight-Bearing physiology

Abstract

The vertebrate skeleton consists of over 200 individual bones, each with its own unique shape, size and function. We study the role of intrauterine muscle-induced mechanical loads in determining the three-dimensional morphology of developing bones. Analysis of the force-generating capacity of intrauterine muscles in mice revealed that developing bones are subjected to significant and progressively increasing mechanical challenges. To evaluate the effect of intrauterine loads on bone morphogenesis and the contribution of the emerging shape to the ability of bones to withstand these loads, we monitored structural and mineral changes during development. Using daily micro-CT scans of appendicular long bones we identify a developmental program, which we term preferential bone growth, that determines the specific circumferential shape of each bone by employing asymmetric mineral deposition and transient cortical thickening. Finite element analysis demonstrates that the resulting bone structure has optimal load-bearing capacity. To test the hypothesis that muscle forces regulate preferential bone growth in utero, we examine this process in a mouse strain (mdg) that lacks muscle contractions. In the absence of mechanical loads, the stereotypical circumferential outline of each bone is lost, leading to the development of mechanically inferior bones. This study identifies muscle force regulation of preferential bone growth as the module that shapes the circumferential outline of bones and, consequently, optimizes their load-bearing capacity during development. Our findings invoke a common mechanism that permits the formation of different circumferential outlines in different bones.

Published

2011

45. Tendon homeostasis: the right pull.

Author

Sharir A and Zelzer E

Subjects

Humans, Mechanotransduction, Cellular, Transforming Growth Factor beta physiology, Homeostasis, Tendons physiology

Abstract

Mechanotransduction, the conversion of a biophysical force into a cellular response, allows cells and tissues to respond to their mechanical milieu. How muscle force is translated through TGF-β signaling to regulate tendon homeostasis offers an interesting in vivo example of mechanotransduction., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

46. Connecting muscles to tendons: tendons and musculoskeletal development in flies and vertebrates.

Author

Schweitzer R, Zelzer E, and Volk T

Subjects

Animals, Drosophila embryology, Drosophila genetics, Drosophila physiology, Muscles embryology, Muscles physiology, Signal Transduction, Tendons physiology, Vertebrates embryology, Vertebrates genetics, Vertebrates physiology, Musculoskeletal Development genetics, Musculoskeletal Development physiology, Tendons embryology

Abstract

The formation of the musculoskeletal system represents an intricate process of tissue assembly involving heterotypic inductive interactions between tendons, muscles and cartilage. An essential component of all musculoskeletal systems is the anchoring of the force-generating muscles to the solid support of the organism: the skeleton in vertebrates and the exoskeleton in invertebrates. Here, we discuss recent findings that illuminate musculoskeletal assembly in the vertebrate embryo, findings that emphasize the reciprocal interactions between the forming tendons, muscle and cartilage tissues. We also compare these events with those of the corresponding system in the Drosophila embryo, highlighting distinct and common pathways that promote efficient locomotion while preserving the form of the organism.

Published

2010

47. Bone ridge patterning during musculoskeletal assembly is mediated through SCX regulation of Bmp4 at the tendon-skeleton junction.

Author

Blitz E, Viukov S, Sharir A, Shwartz Y, Galloway JL, Pryce BA, Johnson RL, Tabin CJ, Schweitzer R, and Zelzer E

Subjects

Animals, Embryo, Mammalian metabolism, Mice, Basic Helix-Loop-Helix Transcription Factors metabolism, Bone Morphogenetic Protein 4 metabolism, Gene Expression Regulation, Developmental, Osteogenesis, Tendons embryology

Abstract

During the assembly of the musculoskeletal system, bone ridges provide a stable anchoring point and stress dissipation for the attachment of muscles via tendons to the skeleton. In this study, we investigate the development of the deltoid tuberosity as a model for bone ridge formation. We show that the deltoid tuberosity develops through endochondral ossification in a two-phase process: initiation is regulated by a signal from the tendons, whereas the subsequent growth phase is muscle dependent. We then show that the transcription factor scleraxis (SCX) regulates Bmp4 in tendon cells at their insertion site. The inhibition of deltoid tuberosity formation and several other bone ridges in embryos in which Bmp4 expression was blocked specifically in Scx-expressing cells implicates BMP4 as a key mediator of tendon effects on bone ridge formation. This study establishes a mechanistic basis for tendon-skeleton regulatory interactions during musculoskeletal assembly and bone secondary patterning., (2009 Elsevier Inc. All rights reserved.)

Published

2009

48. Muscle contraction is necessary to maintain joint progenitor cell fate.

Author

Kahn J, Shwartz Y, Blitz E, Krief S, Sharir A, Breitel DA, Rattenbach R, Relaix F, Maire P, Rountree RB, Kingsley DM, and Zelzer E

Subjects

Animals, Cell Differentiation, Cell Proliferation, Chondrocytes metabolism, Extremities embryology, Extremities physiology, Homeodomain Proteins genetics, Mice, Muscle, Skeletal metabolism, Mutation, Myogenic Regulatory Factors genetics, beta Catenin metabolism, Joints cytology, Joints embryology, Muscle Contraction, Organogenesis, Stem Cells metabolism

Abstract

During embryogenesis, organ development is dependent upon maintaining appropriate progenitor cell commitment. Synovial joints develop from a pool of progenitor cells that differentiate into various cell types constituting the mature joint. The involvement of the musculature in joint formation has long been recognized. However, the mechanism by which the musculature regulates joint formation has remained elusive. In this study, we demonstrate, utilizing various murine models devoid of limb musculature or its contraction, that the contracting musculature is fundamental in maintaining joint progenitors committed to their fate, a requirement for correct joint cavitation and morphogenesis. Furthermore, contraction-dependent activation of beta-catenin, a key modulator of joint formation, provides a molecular mechanism for this regulation. In conclusion, our findings provide the missing link between progenitor cell fate determination and embryonic movement, two processes shown to be essential for correct organogenesis.

Published

2009

49. The forming limb skeleton serves as a signaling center for limb vasculature patterning via regulation of Vegf.

Author

Eshkar-Oren I, Viukov SV, Salameh S, Krief S, Oh CD, Akiyama H, Gerber HP, Ferrara N, and Zelzer E

Subjects

Animals, Bone and Bones embryology, Gene Expression Regulation, Developmental, Limb Buds embryology, Mesenchymal Stem Cells metabolism, Mice, Mice, Transgenic, SOX9 Transcription Factor genetics, SOX9 Transcription Factor metabolism, Vascular Endothelial Growth Factor A genetics, Body Patterning, Bone and Bones blood supply, Bone and Bones metabolism, Limb Buds blood supply, Limb Buds metabolism, Signal Transduction, Vascular Endothelial Growth Factor A metabolism

Abstract

Limb development constitutes a central model for the study of tissue and organ patterning; yet, the mechanisms that regulate the patterning of limb vasculature have been left understudied. Vascular patterning in the forming limb is tightly regulated in order to ensure sufficient gas exchange and nutrient supply to the developing organ. Once skeletogenesis is initiated, limb vasculature undergoes two seemingly opposing processes: vessel regression from regions that undergo mesenchymal condensation; and vessel morphogenesis. During the latter, vessels that surround the condensations undergo an extensive rearrangement, forming a stereotypical enriched network that is segregated from the skeleton. In this study, we provide evidence for the centrality of the condensing mesenchyme of the forming skeleton in regulating limb vascular patterning. Both Vegf loss- and gain-of-function experiments in limb bud mesenchyme firmly established VEGF as the signal by which the condensing mesenchyme regulates the vasculature. Normal vasculature observed in limbs where VEGF receptors Flt1, Flk1, Nrp1 and Nrp2 were blocked in limb bud mesenchyme suggested that VEGF, which is secreted by the condensing mesenchyme, regulates limb vasculature via a direct long-range mechanism. Finally, we provide evidence for the involvement of SOX9 in the regulation of Vegf expression in the condensing mesenchyme. This study establishes Vegf expression in the condensing mesenchyme as the mechanism by which the skeleton patterns limb vasculature.

Published

2009

50. Impaired skin and hair follicle development in Runx2 deficient mice.

Author

Glotzer DJ, Zelzer E, and Olsen BR

Subjects

Animals, Core Binding Factor Alpha 1 Subunit genetics, Core Binding Factor Alpha 1 Subunit physiology, Female, Gene Expression Regulation, Developmental, Hair Follicle abnormalities, Hair Follicle metabolism, Hedgehog Proteins deficiency, Hedgehog Proteins genetics, Hedgehog Proteins physiology, Keratin-14 metabolism, Lac Operon, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Mutant Strains, Mice, Transgenic, Patched Receptors, Patched-1 Receptor, Pregnancy, Receptors, Cell Surface genetics, Receptors, Cell Surface physiology, Signal Transduction physiology, Skin metabolism, Skin Abnormalities embryology, Skin Abnormalities genetics, Skin Abnormalities metabolism, Skin Transplantation, Transplantation, Homologous, Core Binding Factor Alpha 1 Subunit deficiency, Hair Follicle embryology, Skin embryology

Abstract

The transcription factor, Runx2, is known to play crucial roles in skeletal and tooth morphogenesis. Here we document that Runx2 has a regulatory role in skin and hair follicle development. The expression of Runx2 is restricted to hair follicles and is dynamic, pari passu with follicle development. Follicle maturation is delayed in the absence of Runx2 and overall skin and epidermal thickness of Runx2 null embryos is significantly reduced. The Runx2 null epidermis is hypoplastic, displaying reduced expression of Keratin 14, Keratin 1 and markers of proliferation. The expression pattern of Runx2 in the bulb epithelium of mature hair follicles is asymmetric and strikingly similar to that of Sonic hedgehog. This suggests that Runx2 may be a regulator of hedgehog signaling in skin as it is in bones and teeth. Supporting this possibility, we demonstrate that Sonic hedgehog, Patched1 and Gli1 transcripts are reduced in the skin of Runx2 null embryos. Moreover, we document Patched1 expression in epidermal basal cells and show that the skin of Sonic(+/-) embryos is thinner than that of wild-type littermates. These observations suggest that Runx2 and hedgehog signaling are involved in the well known, but unexplained, coupling of skin thickness to hair follicle development.

Published

2008