Coordinated development of the limb musculoskeletal system: Tendon and muscle patterning and integration with the skeleton

Huang, Alice H.

doi:10.1016/j.ydbio.2017.03.028

Cited by 40 publications

(39 citation statements)

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“…60–62 This section will discuss tendon development in the context of mechanical regulation; however, an in-depth discussion of cell and molecular regulators of tendon development can be found in several recent reviews. 63–65 …”

Section: The Role Of Mechanical Forces In Musculoskeletal Developmentmentioning

confidence: 99%

“…[60][61][62] This section will discuss tendon development in the context of mechanical regulation; however, an in-depth discussion of cell and molecular regulators of tendon development can be found in several recent reviews. [63][64][65] In the limb bud, Scx is first expressed by limb mesoderm at E10.5, following induction of Sox9expressing prechondrogenic progenitors at E10.0. 61 At early stages (E10.5-11.5), the domains of Scx expression are closely associated with those of muscle, although Scx + and PAX3 + progenitors are completely distinct throughout all developmental stages.…”

Section: Bone Enthesis Developmentmentioning

confidence: 99%

“…61 At early stages (E10.5-11.5), the domains of Scx expression are closely associated with those of muscle, although Scx + and PAX3 + progenitors are completely distinct throughout all developmental stages. 65 Despite early induction of Scx, a characteristic tendon pattern is not apparent until E12.5, 61,62 when aligned progenitors can be observed within all segments of the limb, connecting muscle to the skeleton. [65][66][67] Generally, the stages of limb tendon development can be defined as induction (E10.5-E12.5), differentiation (E13.5), and growth (E14.5 onward).…”

Section: Bone Enthesis Developmentmentioning

confidence: 99%

“…65 Despite early induction of Scx, a characteristic tendon pattern is not apparent until E12.5, 61,62 when aligned progenitors can be observed within all segments of the limb, connecting muscle to the skeleton. [65][66][67] Generally, the stages of limb tendon development can be defined as induction (E10.5-E12.5), differentiation (E13.5), and growth (E14.5 onward). Recent studies established a new understanding of limb tendon development, in which tendons in the autopod are regulated by a separate developmental program relative to tendons in the zeugopod or styolopod.…”

Section: Bone Enthesis Developmentmentioning

confidence: 99%

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Mechanobiology of limb musculoskeletal development

Arvind

Huang

2017

Annals of the New York Academy of Sciences

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While there has been considerable progress in identifying molecular regulators of musculoskeletal development, the role of physical forces in regulating induction, differentiation, and patterning events is less well understood. Here, we highlight recent findings in this area, focusing primarily on model systems that test the mechanical regulation of skeletal and tendon development in the limb. We also discuss a few of the key signaling pathways and mechanisms that have been implicated in mechanotransduction and highlight current gaps in knowledge and opportunities for further research in the field.

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Section: The Role Of Mechanical Forces In Musculoskeletal Developmentmentioning

confidence: 99%

Section: Bone Enthesis Developmentmentioning

confidence: 99%

Section: Bone Enthesis Developmentmentioning

confidence: 99%

Section: Bone Enthesis Developmentmentioning

confidence: 99%

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Mechanobiology of limb musculoskeletal development

Arvind

Huang

2017

Annals of the New York Academy of Sciences

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“…These cellular based osteological functions can produce gross shape change of bone processes through micro anatomical bone surface modeling and remodeling modulated by the loading vector (Huang, ). The osteogenic topologies observed in this study in part conformed to the proposed tension/compression loading model illustrated in Figure .…”

Section: Discussionmentioning

confidence: 99%

Bone Surface Micro‐Topography at Craniofacial Entheses: Insights on Osteogenic Adaptation at Muscle Insertions

Walters

Crew

Fyfe

2019

The Anatomical Record

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Macroscopic details of the bone–muscle interface are represented by a mosaic of calcified features inclusive of fossae, tuberosities, crests, and ridges. These features are in part of an adaptive osteogenic response to dissipate forces of localized mechanical loading. In an osteoarchaeological or paleontological context, these features are interpreted as “musculoskeletal stress markers” to infer habitual behaviors. Microscopic surveys of bone surface topography of the enthesis can reveal localized osteogenic topologies. These features illustrate the developmental mechanisms that produce these bony forms and contribute to an evidential basis to read these structures. Microscopic osteogenic topographies at sites of gnathic muscle attachments located in the craniofacial skeleton were explored in reference to extrapolated loading vectors in an ontogenetic series of craniofacial skeletons of the primate (Procolobus verus). Epoxy resin replicas of bone surfaces were made, and micro‐topographical detail viewed with Scanning Electron Microscope. Osteoclastic bone remodeling was found at entheses associated with presumptive net tensile loading. Mineralized fibrocartilage was present at entheses, associated with presumptive net compressive loading. Collectively, these outcomes suggest that entheses develop through adaptive osteogenic activity in response to differential vectors of local mechanical loading. However, the presence of mineralized fibrocartilage also suggests that proliferative cartilage has a role in the development of bone eminences providing functional processes. This study concludes that the vector of muscle loading at entheses as well as proliferative fibrocartilage is influencing the form of bony eminences in the primate craniofacial skeleton defining functional and species defining morphologies. Anat Rec, 302:2140–2155, 2019. © 2019 American Association for Anatomy

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Comparative development of limb musculature in phylogenetically and ecologically divergent lizards

Díaz

Taylor-Diaz

Trainor

et al. 2021

Developmental Dynamics

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Background Squamate reptiles (lizards, snakes, and amphisbaenians) exhibit incredible diversity in their locomotion, behavior, morphology, and ecological breadth. Although they often are used as models of locomotor diversity, surprisingly little attention has been given to muscle development in squamate reptiles. In fact, the most detailed examination was conducted almost 80 years ago and solely focused on the proximal limb regions. Herein, we present forelimb and hindlimb muscle morphogenesis data for three lizard species with different locomotion and feeding strategies: the desert grassland whiptail lizard, the central bearded dragon, and the veiled chameleon. This study fills critical gaps in our understanding of muscle morphogenesis in squamate reptiles and presents a comparative and temporospatial analysis of muscle development. Results Our results reveal a conserved pattern of early muscle development among lizards with different adult morphologies and ecologies. The variations that exist are concentrated in distal regions, particularly the specialized autopodia of chameleons, where differentiation of muscles associated with the digits is delayed. Conclusions The chameleon autopod provides an example of major evolutionary modifications to the skeleton with only minor disruption of the conserved order and pattern of limb muscle development. This robustness of muscle patterning facilitates the evolution of extreme yet functional phenotypes.

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Coordinated development of the limb musculoskeletal system: Tendon and muscle patterning and integration with the skeleton

Cited by 40 publications

References 85 publications

Mechanobiology of limb musculoskeletal development

Mechanobiology of limb musculoskeletal development

Bone Surface Micro‐Topography at Craniofacial Entheses: Insights on Osteogenic Adaptation at Muscle Insertions

Comparative development of limb musculature in phylogenetically and ecologically divergent lizards

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