Shiri Kult scite author profile

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.

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A novel nonosteocytic regulatory mechanism of bone modeling

Ofer

Dean

Zaslansky

et al. 2019

PLoS Biol

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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.

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Bone morphology is regulated modularly by global and regional genetic programs

Eyal

Kult

Rubin

et al. 2019

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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 dosedependent 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.

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Bone Morphology is Regulated Modularly by Global and Regional Genetic Programs

Eyal

Kult

Rubin

et al. 2018

Preprint

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During skeletogenesis, a variety of protrusions of different shapes and sizes develop on the surfaces of long bones. These superstructures provide stable anchoring sites for ligaments and tendons during the assembly of the musculoskeletal system. Despite their importance, the mechanism by which superstructures are patterned and ultimately give rise to the unique morphology of each long bone is far from understood. In this work, we provide further evidence that long bones form modularly from Sox9 + cells, which contribute to their substructure, and from Sox9 + /Scx + progenitors that give rise to superstructures. Moreover, we identify components of the genetic program that controls the patterning of Sox9 + /Scx + progenitors 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. Additionally, by combining literature-based evidence and comparative transcriptomic analysis of different Sox9 + /Scx + progenitor populations, we identified genes potentially involved in patterning of bone superstructures. We present evidence indicating that Gli3 is 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 coordinately.Collectively, our results provide strong evidence for genetic regulation of superstructure patterning that further supports the notion that long bone development is a modular process.

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Fluorescent Cell Staining Methods for Living Hypsibius exemplaris Embryos

McGreevy

Heikes

Kult

et al. 2018

Cold Spring Harb Protoc

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The tardigrade Hypsibius exemplaris was chosen as a model system in part because animals and embryos are optically clear at all stages, facilitating the visualization of events in living material. Here we report new methods for introducing fluorescent dyes into developing H. exemplaris embryos, including methods for fluorescently marking mitochondria, lysosomes, membranes, and nuclei. The development of these techniques suggests approaches for attempting to introduce other molecules into embryos. LysoTracker Green DND-26 staining solution (75 nM) (for lysosomes) This is a green fluorescent dye that stains acidic compartments in live cells (excitation peak, 504 nm; emission peak, 511 nm).

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Shiri Kult

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

A novel nonosteocytic regulatory mechanism of bone modeling

Bone morphology is regulated modularly by global and regional genetic programs

Bone Morphology is Regulated Modularly by Global and Regional Genetic Programs

Fluorescent Cell Staining Methods for Living Hypsibius exemplaris Embryos

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