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1.
Cell ; 2024 Oct 23.
Artigo em Inglês | MEDLINE | ID: mdl-39454574

RESUMO

Elucidating organismal developmental processes requires a comprehensive understanding of cellular lineages in the spatial, temporal, and molecular domains. In this study, we introduce Zebrahub, a dynamic atlas of zebrafish embryonic development that integrates single-cell sequencing time course data with lineage reconstructions facilitated by light-sheet microscopy. This atlas offers high-resolution and in-depth molecular insights into zebrafish development, achieved through the sequencing of individual embryos across ten developmental stages, complemented by reconstructions of cellular trajectories. Zebrahub also incorporates an interactive tool to navigate the complex cellular flows and lineages derived from light-sheet microscopy data, enabling in silico fate-mapping experiments. To demonstrate the versatility of our multimodal resource, we utilize Zebrahub to provide fresh insights into the pluripotency of neuro-mesodermal progenitors (NMPs) and the origins of a joint kidney-hemangioblast progenitor population.

2.
Nat Rev Mol Cell Biol ; 25(7): 517-533, 2024 Jul.
Artigo em Inglês | MEDLINE | ID: mdl-38418851

RESUMO

Segmentation is a fundamental feature of the vertebrate body plan. This metameric organization is first implemented by somitogenesis in the early embryo, when paired epithelial blocks called somites are rhythmically formed to flank the neural tube. Recent advances in in vitro models have offered new opportunities to elucidate the mechanisms that underlie somitogenesis. Notably, models derived from human pluripotent stem cells introduced an efficient proxy for studying this process during human development. In this Review, we summarize the current understanding of somitogenesis gained from both in vivo studies and in vitro studies. We deconstruct the spatiotemporal dynamics of somitogenesis into four distinct modules: dynamic events in the presomitic mesoderm, segmental determination, somite anteroposterior polarity patterning, and epithelial morphogenesis. We first focus on the segmentation clock, as well as signalling and metabolic gradients along the tissue, before discussing the clock and wavefront and other models that account for segmental determination. We then detail the molecular and cellular mechanisms of anteroposterior polarity patterning and somite epithelialization.


Assuntos
Padronização Corporal , Somitos , Somitos/embriologia , Somitos/metabolismo , Animais , Humanos , Padronização Corporal/genética , Vertebrados/embriologia , Regulação da Expressão Gênica no Desenvolvimento , Desenvolvimento Embrionário/genética , Mesoderma/metabolismo , Mesoderma/embriologia , Transdução de Sinais , Morfogênese
3.
Annu Rev Cell Dev Biol ; 35: 259-283, 2019 10 06.
Artigo em Inglês | MEDLINE | ID: mdl-31412208

RESUMO

The vertebrate anteroposterior axis forms through elongation of multiple tissues during embryogenesis. This process is based on tissue-autonomous mechanisms of force generation and intertissue mechanical coupling whose failure leads to severe developmental anomalies such as body truncation and spina bifida. Similar to other morphogenetic modules, anteroposterior body extension requires both the rearrangement of existing materials-such as cells and extracellular matrix-and the local addition of new materials, i.e., anisotropic growth, through cell proliferation, cell growth, and matrix deposition. Numerous signaling pathways coordinate body axis formation via regulation of cell behavior during tissue rearrangements and/or volumetric growth. From a physical perspective, morphogenesis depends on both cell-generated forces and tissue material properties. As the spatiotemporal variation of these mechanical parameters has recently been explored in the context of vertebrate body elongation, the study of this process is likely to shed light on the cross talk between signaling and mechanics during morphogenesis.


Assuntos
Padronização Corporal , Desenvolvimento Embrionário , Vertebrados/embriologia , Animais , Movimento Celular , Embrião de Mamíferos/citologia , Embrião de Mamíferos/metabolismo , Embrião não Mamífero/citologia , Embrião não Mamífero/metabolismo , Humanos , Transdução de Sinais , Vertebrados/metabolismo
4.
Cell ; 171(3): 668-682.e11, 2017 Oct 19.
Artigo em Inglês | MEDLINE | ID: mdl-28942924

RESUMO

The periodic segmentation of the vertebrate body axis into somites, and later vertebrae, relies on a genetic oscillator (the segmentation clock) driving the rhythmic activity of signaling pathways in the presomitic mesoderm (PSM). To understand whether oscillations are an intrinsic property of individual cells or represent a population-level phenomenon, we established culture conditions for stable oscillations at the cellular level. This system was used to demonstrate that oscillations are a collective property of PSM cells that can be actively triggered in vitro by a dynamical quorum sensing signal involving Yap and Notch signaling. Manipulation of Yap-dependent mechanical cues is sufficient to predictably switch isolated PSM cells from a quiescent to an oscillatory state in vitro, a behavior reminiscent of excitability in other systems. Together, our work argues that the segmentation clock behaves as an excitable system, introducing a broader paradigm to study such dynamics in vertebrate morphogenesis.


Assuntos
Relógios Biológicos , Transdução de Sinais , Proteínas Adaptadoras de Transdução de Sinal/metabolismo , Animais , Proteínas de Ciclo Celular , Embrião de Galinha , Embrião de Mamíferos/metabolismo , Embrião não Mamífero/metabolismo , Mesoderma/metabolismo , Camundongos , Morfogênese , Fosfoproteínas/metabolismo , Percepção de Quorum , Somitos/metabolismo , Proteínas de Sinalização YAP
5.
Annu Rev Genet ; 57: 117-134, 2023 11 27.
Artigo em Inglês | MEDLINE | ID: mdl-38012023

RESUMO

Organismal development requires the reproducible unfolding of an ordered sequence of discrete steps (cell fate determination, migration, tissue folding, etc.) in both time and space. Here, we review the mechanisms that grant temporal specificity to developmental steps, including molecular clocks and timers. Individual timing mechanisms must be coordinated with each other to maintain the overall developmental sequence. However, phenotypic novelties can also arise through the modification of temporal patterns over the course of evolution. Two main types of variation in temporal patterning characterize interspecies differences in developmental time: allochrony, where the overall developmental sequence is either accelerated or slowed down while maintaining the relative duration of individual steps, and heterochrony, where the duration of specific developmental steps is altered relative to the rest. New advances in in vitro modeling of mammalian development using stem cells have recently enabled the revival of mechanistic studies of allochrony and heterochrony. In both cases, differences in the rate of basic cellular functions such as splicing, translation, protein degradation, and metabolism seem to underlie differences in developmental time. In the coming years, these studies should identify the genetic differences that drive divergence in developmental time between species.


Assuntos
Evolução Biológica , Mamíferos , Animais , Embrião de Mamíferos , Diferenciação Celular/genética
6.
Cell ; 164(1-2): 9-10, 2016 Jan 14.
Artigo em Inglês | MEDLINE | ID: mdl-26771479

RESUMO

The morphology of the vertebrate skeleton exhibits tremendous plasticity in evolution, allowing adaptation to a wide variety of ecological niches and lifestyles. Indjeian et al. now uncover how the cis regulation of a gene controls skeletal variation in fish and might have contributed to the evolution of bipedalism in humans.


Assuntos
Evolução Biológica , Evolução Molecular , Fator 6 de Diferenciação de Crescimento/genética , Esqueleto/fisiologia , Vertebrados/genética , Animais , Humanos
7.
Nature ; 613(7944): 550-557, 2023 01.
Artigo em Inglês | MEDLINE | ID: mdl-36599986

RESUMO

Animals display substantial inter-species variation in the rate of embryonic development despite a broad conservation of the overall sequence of developmental events. Differences in biochemical reaction rates, including the rates of protein production and degradation, are thought to be responsible for species-specific rates of development1-3. However, the cause of differential biochemical reaction rates between species remains unknown. Here, using pluripotent stem cells, we have established an in vitro system that recapitulates the twofold difference in developmental rate between mouse and human embryos. This system provides a quantitative measure of developmental speed as revealed by the period of the segmentation clock, a molecular oscillator associated with the rhythmic production of vertebral precursors. Using this system, we show that mass-specific metabolic rates scale with the developmental rate and are therefore higher in mouse cells than in human cells. Reducing these metabolic rates by inhibiting the electron transport chain slowed down the segmentation clock by impairing the cellular NAD+/NADH redox balance and, further downstream, lowering the global rate of protein synthesis. Conversely, increasing the NAD+/NADH ratio in human cells by overexpression of the Lactobacillus brevis NADH oxidase LbNOX increased the translation rate and accelerated the segmentation clock. These findings represent a starting point for the manipulation of developmental rate, with multiple translational applications including accelerating the differentiation of human pluripotent stem cells for disease modelling and cell-based therapies.


Assuntos
Embrião de Mamíferos , Desenvolvimento Embrionário , Animais , Humanos , Camundongos , Diferenciação Celular , Desenvolvimento Embrionário/fisiologia , NAD/metabolismo , Oxirredução , Células-Tronco Pluripotentes/citologia , Células-Tronco Pluripotentes/metabolismo , Especificidade da Espécie , Técnicas In Vitro , Transporte de Elétrons , Relógios Biológicos , Fatores de Tempo , Embrião de Mamíferos/citologia , Embrião de Mamíferos/embriologia , Embrião de Mamíferos/metabolismo , Levilactobacillus brevis
8.
Nature ; 614(7948): 500-508, 2023 02.
Artigo em Inglês | MEDLINE | ID: mdl-36543321

RESUMO

The vertebrate body displays a segmental organization that is most conspicuous in the periodic organization of the vertebral column and peripheral nerves. This metameric organization is first implemented when somites, which contain the precursors of skeletal muscles and vertebrae, are rhythmically generated from the presomitic mesoderm. Somites then become subdivided into anterior and posterior compartments that are essential for vertebral formation and segmental patterning of the peripheral nervous system1-4. How this key somitic subdivision is established remains poorly understood. Here we introduce three-dimensional culture systems of human pluripotent stem cells called somitoids and segmentoids, which recapitulate the formation of somite-like structures with anteroposterior identity. We identify a key function of the segmentation clock in converting temporal rhythmicity into the spatial regularity of anterior and posterior somitic compartments. We show that an initial 'salt and pepper' expression of the segmentation gene MESP2 in the newly formed segment is transformed into compartments of anterior and posterior identity through an active cell-sorting mechanism. Our research demonstrates that the major patterning modules that are involved in somitogenesis, including the clock and wavefront, anteroposterior polarity patterning and somite epithelialization, can be dissociated and operate independently in our in vitro systems. Together, we define a framework for the symmetry-breaking process that initiates somite polarity patterning. Our work provides a platform for decoding general principles of somitogenesis and advancing knowledge of human development.


Assuntos
Padronização Corporal , Técnicas de Cultura de Células em Três Dimensões , Somitos , Humanos , Técnicas In Vitro , Somitos/citologia , Somitos/embriologia , Somitos/metabolismo , Coluna Vertebral/citologia , Coluna Vertebral/embriologia , Relógios Biológicos , Epitélio/embriologia
9.
Annu Rev Cell Dev Biol ; 29: 1-26, 2013.
Artigo em Inglês | MEDLINE | ID: mdl-23808844

RESUMO

Body axis elongation and segmentation are major morphogenetic events that take place concomitantly during vertebrate embryonic development. Establishment of the final body plan requires tight coordination between these two key processes. In this review, we detail the cellular and molecular as well as the physical processes underlying body axis formation and patterning. We discuss how formation of the anterior region of the body axis differs from that of the posterior region. We describe the developmental mechanism of segmentation and the regulation of body length and segment numbers. We focus mainly on the chicken embryo as a model system. Its accessibility and relatively flat structure allow high-quality time-lapse imaging experiments, which makes it one of the reference models used to study morphogenesis. Additionally, we illustrate conservation and divergence of specific developmental mechanisms by discussing findings in other major embryonic model systems, such as mice, frogs, and zebrafish.


Assuntos
Padronização Corporal , Vertebrados/embriologia , Animais , Desenvolvimento Embrionário , Humanos , Morfogênese , Linha Primitiva , Transdução de Sinais , Vertebrados/metabolismo
10.
Development ; 150(9)2023 05 01.
Artigo em Inglês | MEDLINE | ID: mdl-37070753

RESUMO

Developmental morphogenesis is driven by tissue stresses acting on tissue rheology. Direct measurements of forces in small tissues (100 µm-1 mm) in situ, such as in early embryos, require high spatial precision and minimal invasiveness. Here, we introduce a control-based approach, tissue force microscopy (TiFM), that integrates a mechanical cantilever probe and live imaging with closed-loop feedback control of mechanical loading in early chicken embryos. By testing previously qualitatively characterized force-producing tissues in the elongating body axis, we show that TiFM quantitatively captures stress dynamics with high sensitivity. TiFM also provides the means to apply stable, minimally invasive and physiologically relevant loads to drive tissue deformation and to follow the resulting morphogenetic progression associated with large-scale cell movements. Together, TiFM allows us to control tissue force measurement and manipulation in small developing embryos, and promises to contribute to the quantitative understanding of complex multi-tissue mechanics during development.


Assuntos
Galinhas , Fenômenos Mecânicos , Animais , Embrião de Galinha , Morfogênese/fisiologia
11.
Nat Rev Mol Cell Biol ; 15(11): 709-21, 2014 Nov.
Artigo em Inglês | MEDLINE | ID: mdl-25335437

RESUMO

Segmentation of the paraxial mesoderm is a major event of vertebrate development that establishes the metameric patterning of the body axis. This process involves the periodic formation of sequential units, termed somites, from the presomitic mesoderm. Somite formation relies on a molecular oscillator, the segmentation clock, which controls the rhythmic activation of several signalling pathways and leads to the oscillatory expression of a subset of genes in the presomitic mesoderm. The response to the periodic signal of the clock, leading to the establishment of the segmental pre-pattern, is gated by a system of travelling signalling gradients, often referred to as the wavefront. Recent studies have advanced our understanding of the molecular mechanisms involved in the generation of oscillations and how they interact and are coordinated to activate the segmental gene expression programme.


Assuntos
Desenvolvimento Embrionário/genética , Regulação da Expressão Gênica no Desenvolvimento , Mesoderma/metabolismo , Transdução de Sinais , Vertebrados/metabolismo , Animais , Relógios Biológicos/genética , Padronização Corporal , Proteínas CLOCK/genética , Proteínas CLOCK/metabolismo , Humanos , Mesoderma/citologia , Mesoderma/embriologia , Modelos Biológicos , Receptores Notch/genética , Receptores Notch/metabolismo , Vertebrados/embriologia , Vertebrados/genética , Proteínas Wnt/genética , Proteínas Wnt/metabolismo
12.
Cell ; 145(5): 650-63, 2011 May 27.
Artigo em Inglês | MEDLINE | ID: mdl-21620133

RESUMO

One of the most striking features of the human vertebral column is its periodic organization along the anterior-posterior axis. This pattern is established when segments of vertebrates, called somites, bud off at a defined pace from the anterior tip of the embryo's presomitic mesoderm (PSM). To trigger this rhythmic production of somites, three major signaling pathways--Notch, Wnt/ß-catenin, and fibroblast growth factor (FGF)--integrate into a molecular network that generates a traveling wave of gene expression along the embryonic axis, called the "segmentation clock." Recent systems approaches have begun identifying specific signaling circuits within the network that set the pace of the oscillations, synchronize gene expression cycles in neighboring cells, and contribute to the robustness and bilateral symmetry of somite formation. These findings establish a new model for vertebrate segmentation and provide a conceptual framework to explain human diseases of the spine, such as congenital scoliosis.


Assuntos
Redes Reguladoras de Genes , Escoliose/genética , Vertebrados/embriologia , Animais , Humanos , Mesoderma/metabolismo , Coluna Vertebral/embriologia , Vertebrados/genética
13.
Nature ; 584(7819): 98-101, 2020 08.
Artigo em Inglês | MEDLINE | ID: mdl-32581357

RESUMO

Formation of the body of vertebrate embryos proceeds sequentially by posterior addition of tissues from the tail bud. Cells of the tail bud and the posterior presomitic mesoderm, which control posterior elongation1, exhibit a high level of aerobic glycolysis that is reminiscent of the metabolic status of cancer cells experiencing the Warburg effect2,3. Glycolytic activity downstream of fibroblast growth factor controls WNT signalling in the tail bud3. In the neuromesodermal precursors of the tail bud4, WNT signalling promotes the mesodermal fate that is required for sustained axial elongation, at the expense of the neural fate3,5. How glycolysis regulates WNT signalling in the tail bud is currently unknown. Here we used chicken embryos and human tail bud-like cells differentiated in vitro from induced pluripotent stem cells to show that these cells exhibit an inverted pH gradient, with the extracellular pH lower than the intracellular pH, as observed in cancer cells6. Our data suggest that glycolysis increases extrusion of lactate coupled to protons via the monocarboxylate symporters. This contributes to elevating the intracellular pH in these cells, which creates a favourable chemical environment for non-enzymatic ß-catenin acetylation downstream of WNT signalling. As acetylated ß-catenin promotes mesodermal rather than neural fate7, this ultimately leads to activation of mesodermal transcriptional WNT targets and specification of the paraxial mesoderm in tail bud precursors. Our work supports the notion that some tumour cells reactivate a developmental metabolic programme.


Assuntos
Âmnio/embriologia , Glicólise , Proteínas Wnt/metabolismo , Acetilação , Animais , Padronização Corporal , Embrião de Galinha , Humanos , Concentração de Íons de Hidrogênio , Ácido Láctico/metabolismo , Mesoderma/metabolismo , beta Catenina/metabolismo
14.
Nature ; 580(7801): 113-118, 2020 04.
Artigo em Inglês | MEDLINE | ID: mdl-31915384

RESUMO

The segmental organization of the vertebral column is established early in embryogenesis, when pairs of somites are rhythmically produced by the presomitic mesoderm (PSM). The tempo of somite formation is controlled by a molecular oscillator known as the segmentation clock1,2. Although this oscillator has been well-characterized in model organisms1,2, whether a similar oscillator exists in humans remains unknown. Genetic analyses of patients with severe spine segmentation defects have implicated several human orthologues of cyclic genes that are associated with the mouse segmentation clock, suggesting that this oscillator might be conserved in humans3. Here we show that human PSM cells derived in vitro-as well as those of the mouse4-recapitulate the oscillations of the segmentation clock. Human PSM cells oscillate with a period two times longer than that of mouse cells (5 h versus 2.5 h), but are similarly regulated by FGF, WNT, Notch and YAP signalling5. Single-cell RNA sequencing reveals that mouse and human PSM cells in vitro follow a developmental trajectory similar to that of mouse PSM in vivo. Furthermore, we demonstrate that FGF signalling controls the phase and period of oscillations, expanding the role of this pathway beyond its classical interpretation in 'clock and wavefront' models1. Our work identifying the human segmentation clock represents an important milestone in understanding human developmental biology.


Assuntos
Relógios Biológicos/fisiologia , Desenvolvimento Embrionário/fisiologia , Somitos/metabolismo , Animais , Diferenciação Celular , Células Cultivadas , Feminino , Fatores de Crescimento de Fibroblastos/metabolismo , Humanos , Técnicas In Vitro , Masculino , Camundongos , Células-Tronco Pluripotentes/citologia , RNA-Seq , Transdução de Sinais , Análise de Célula Única , Somitos/citologia
15.
Development ; 149(6)2022 03 15.
Artigo em Inglês | MEDLINE | ID: mdl-35344041

RESUMO

The body of vertebrate embryos forms by posterior elongation from a terminal growth zone called the tail bud. The tail bud is a source of highly motile cells that eventually constitute the presomitic mesoderm (PSM), a tissue that plays an important role in elongation movements. PSM cells establish an anterior-posterior cell motility gradient that parallels a gradient associated with the degradation of a specific cellular signal (FGF) known to be implicated in cell motility. Here, we combine the electroporation of fluorescent reporters in the PSM with time-lapse imaging in the chicken embryo to quantify cell diffusive movements along the motility gradient. We show that a simple microscopic model for random cell motility induced by FGF activity along with geometric confinement leads to rectified tissue elongation consistent with our observations. A continuum analog of the microscopic model leads to a macroscopic mechano-chemical model for tissue extension that couples FGF activity-induced cell motility and tissue rheology, and is consistent with the experimentally observed speed and extent of elongation. Together, our experimental observations and theoretical models explain how the continuous addition of cells at the tail bud combined with lateral confinement can be converted into oriented movement and drive body elongation.


Assuntos
Embrião de Mamíferos , Mesoderma , Animais , Movimento Celular , Embrião de Galinha , Mesoderma/metabolismo , Transdução de Sinais , Vertebrados
16.
Mol Psychiatry ; 2024 Aug 06.
Artigo em Inglês | MEDLINE | ID: mdl-39107583

RESUMO

Hemispheric brain asymmetry is a basic organizational principle of the human brain and has been implicated in various psychiatric conditions, including autism spectrum disorder. Brain asymmetry is not a uniquely human feature and is observed in other species such as the mouse. Yet, asymmetry patterns are generally nuanced, and substantial sample sizes are required to detect these patterns. In this pre-registered study, we use a mouse dataset from the Province of Ontario Neurodevelopmental Network, which comprises structural MRI data from over 2000 mice, including genetic models for autism spectrum disorder, to reveal the scope and magnitude of hemispheric asymmetry in the mouse. Our findings demonstrate the presence of robust hemispheric asymmetry in the mouse brain, such as larger right hemispheric volumes towards the anterior pole and larger left hemispheric volumes toward the posterior pole, opposite to what has been shown in humans. This suggests the existence of species-specific traits. Further clustering analysis identified distinct asymmetry patterns in autism spectrum disorder models, a phenomenon that is also seen in atypically developing participants. Our study shows potential for the use of mouse models to understand the biological bases of typical and atypical brain asymmetry but also warrants caution as asymmetry patterns seem to differ between humans and mice.

17.
Adv Funct Mater ; 34(3)2024 Jan 15.
Artigo em Inglês | MEDLINE | ID: mdl-38707790

RESUMO

Skeletal muscle connective tissue (MCT) surrounds myofiber bundles to provide structural support, produce force transduction from tendons, and regulate satellite cell differentiation during muscle regeneration. Engineered muscle tissue composed of myofibers layered within MCT has not yet been developed. Herein, a bioengineering strategy to create MCT-layered myofibers through the development of stem cell fate-controlling biomaterials that achieve both myogenesis and fibroblast differentiation in a locally controlled manner at the single construct is introduced. The reciprocal role of transforming growth factor-beta 1 (TGF-ß1) and its inhibitor as well as 3D matrix stiffness to achieve co-differentiation of MCT fibroblasts and myofibers from a human-induced pluripotent stem cell (hiPSC)-derived paraxial mesoderm is studied. To avoid myogenic inhibition, TGF-ß1 is conjugated on the gelatin-based hydrogel to control the fibroblasts' populations locally; the TGF-ß1 degrades after 2 weeks, resulting in increased MCT-specific extracellular matrix (ECM) production. The locations of myofibers and fibroblasts are precisely controlled by using photolithography and co-axial wet spinning techniques, which results in the formation of MCT-layered functional myofibers in 3D constructs. This advanced engineering strategy is envisioned as a possible method for obtaining biomimetic human muscle grafts for various biomedical applications.

19.
PLoS Genet ; 17(10): e1009812, 2021 10.
Artigo em Inglês | MEDLINE | ID: mdl-34648490

RESUMO

Oscillatory and sequential processes have been implicated in the spatial patterning of many embryonic tissues. For example, molecular clocks delimit segmental boundaries in vertebrates and insects and mediate lateral root formation in plants, whereas sequential gene activities are involved in the specification of regional identities of insect neuroblasts, vertebrate neural tube, vertebrate limb, and insect and vertebrate body axes. These processes take place in various tissues and organisms, and, hence, raise the question of what common themes and strategies they share. In this article, we review 2 processes that rely on the spatial regulation of periodic and sequential gene activities: segmentation and regionalization of the anterior-posterior (AP) axis of animal body plans. We study these processes in species that belong to 2 different phyla: vertebrates and insects. By contrasting 2 different processes (segmentation and regionalization) in species that belong to 2 distantly related phyla (arthropods and vertebrates), we elucidate the deep logic of patterning by oscillatory and sequential gene activities. Furthermore, in some of these organisms (e.g., the fruit fly Drosophila), a mode of AP patterning has evolved that seems not to overtly rely on oscillations or sequential gene activities, providing an opportunity to study the evolution of pattern formation mechanisms.


Assuntos
Padronização Corporal/genética , Insetos/genética , Vertebrados/genética , Animais , Desenvolvimento Embrionário/genética , Regulação da Expressão Gênica no Desenvolvimento/genética , Humanos
20.
Proc Natl Acad Sci U S A ; 118(28)2021 07 13.
Artigo em Inglês | MEDLINE | ID: mdl-34260377

RESUMO

Duchenne muscular dystrophy (DMD) is a devastating genetic disease leading to degeneration of skeletal muscles and premature death. How dystrophin absence leads to muscle wasting remains unclear. Here, we describe an optimized protocol to differentiate human induced pluripotent stem cells (iPSC) to a late myogenic stage. This allows us to recapitulate classical DMD phenotypes (mislocalization of proteins of the dystrophin-associated glycoprotein complex, increased fusion, myofiber branching, force contraction defects, and calcium hyperactivation) in isogenic DMD-mutant iPSC lines in vitro. Treatment of the myogenic cultures with prednisolone (the standard of care for DMD) can dramatically rescue force contraction, fusion, and branching defects in DMD iPSC lines. This argues that prednisolone acts directly on myofibers, challenging the largely prevalent view that its beneficial effects are caused by antiinflammatory properties. Our work introduces a human in vitro model to study the onset of DMD pathology and test novel therapeutic approaches.


Assuntos
Células-Tronco Pluripotentes Induzidas/patologia , Músculo Esquelético/patologia , Distrofia Muscular de Duchenne/patologia , Prednisolona/farmacologia , Fenômenos Biomecânicos , Cálcio/metabolismo , Diferenciação Celular/efeitos dos fármacos , Linhagem Celular , Distrofina/deficiência , Distrofina/metabolismo , Glicoproteínas/metabolismo , Humanos , Células-Tronco Pluripotentes Induzidas/efeitos dos fármacos , Fibras Musculares Esqueléticas/efeitos dos fármacos , Fibras Musculares Esqueléticas/patologia , Músculo Esquelético/efeitos dos fármacos , Distrofia Muscular de Duchenne/genética , Mutação/genética , Optogenética , Fenótipo
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