RESUMEN
Animal body plans are established during embryonic development by the Hox genes. This patterning process relies on the differential expression of Hox genes along the head-to-tail axis. Hox spatial collinearity refers to the relationship between the organization of Hox genes in clusters and the differential Hox expression, whereby the relative order of the Hox genes within a cluster mirrors the spatial sequence of expression in the developing embryo. In vertebrates, the cluster organization is also associated with the timing of Hox activation, which harmonizes Hox expression with the progressive emergence of axial tissues. Thereby, in vertebrates, Hox temporal collinearity is intimately linked to Hox spatial collinearity. Understanding the mechanisms contributing to Hox temporal and spatial collinearity is thus key to the comprehension of vertebrate patterning. Here, we provide an overview of the main discoveries pertaining to the mechanisms of Hox spatial-temporal collinearity.
Asunto(s)
Tipificación del Cuerpo , Regulación del Desarrollo de la Expresión Génica , Proteínas de Homeodominio , Vertebrados , Humanos , Animales , Vertebrados/embriología , Vertebrados/genética , Vertebrados/metabolismo , Análisis Espacial , Genes Homeobox , Familia de Multigenes , Proteínas de Homeodominio/genética , Proteínas de Homeodominio/metabolismo , Silenciador del GenRESUMEN
Vertebrate calcitonin-producing cells (C-cells) are neuroendocrine cells that secrete the small peptide hormone calcitonin in response to elevated blood calcium levels. Whereas mouse C-cells reside within the thyroid gland and derive from pharyngeal endoderm, avian C-cells are located within ultimobranchial glands and have been reported to derive from the neural crest. We use a comparative cell lineage tracing approach in a range of vertebrate model systems to resolve the ancestral embryonic origin of vertebrate C-cells. We find, contrary to previous studies, that chick C-cells derive from pharyngeal endoderm, with neural crest-derived cells instead contributing to connective tissue intimately associated with C-cells in the ultimobranchial gland. This endodermal origin of C-cells is conserved in a ray-finned bony fish (zebrafish) and a cartilaginous fish (the little skate, Leucoraja erinacea). Furthermore, we discover putative C-cell homologs within the endodermally-derived pharyngeal epithelium of the ascidian Ciona intestinalis and the amphioxus Branchiostoma lanceolatum, two invertebrate chordates that lack neural crest cells. Our findings point to a conserved endodermal origin of C-cells across vertebrates and to a pre-vertebrate origin of this cell type along the chordate stem.
Asunto(s)
Calcitonina , Linaje de la Célula , Ciona intestinalis , Endodermo , Cresta Neural , Células Neuroendocrinas , Animales , Endodermo/metabolismo , Endodermo/citología , Calcitonina/metabolismo , Células Neuroendocrinas/metabolismo , Células Neuroendocrinas/citología , Ciona intestinalis/metabolismo , Ciona intestinalis/embriología , Cresta Neural/metabolismo , Cresta Neural/citología , Embrión de Pollo , Ratones , Vertebrados/embriología , Vertebrados/metabolismo , Pez Cebra/embriología , Anfioxos/embriología , Anfioxos/metabolismo , Anfioxos/genética , Cuerpo Ultimobranquial/metabolismoRESUMEN
Morphogenesis is a physical process that sculpts the final functional forms of tissues and organs. Remarkably, the lungs of terrestrial vertebrates vary dramatically in form across species, despite providing the same function of transporting oxygen and carbon dioxide. These divergent forms arise from distinct physical processes through which the epithelium of the embryonic lung responds to the mechanical properties of its surrounding mesenchymal microenvironment. Here we compare the physical processes that guide folding of the lung epithelium in mammals, birds, and reptiles, and suggest a conceptual framework that reconciles how conserved molecular signaling generates divergent mechanical forces across these species.
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Pulmón , Morfogénesis , Vertebrados , Animales , Pulmón/embriología , Pulmón/crecimiento & desarrollo , Vertebrados/embriología , HumanosRESUMEN
The emergence of new structures can often be linked to the evolution of novel cell types that follows the rewiring of developmental gene regulatory subnetworks. Vertebrates are characterized by a complex body plan compared to the other chordate clades and the question remains of whether and how the emergence of vertebrate morphological innovations can be related to the appearance of new embryonic cell populations. We previously proposed, by studying mesoderm development in the cephalochordate amphioxus, a scenario for the evolution of the vertebrate head mesoderm. To further test this scenario at the cell population level, we used scRNA-seq to construct a cell atlas of the amphioxus neurula, stage at which the main mesodermal compartments are specified. Our data allowed us to validate the presence of a prechordal-plate like territory in amphioxus. Additionally, the transcriptomic profile of somite cell populations supports the homology between specific territories of amphioxus somites and vertebrate cranial/pharyngeal and lateral plate mesoderm. Finally, our work provides evidence that the appearance of the specific mesodermal structures of the vertebrate head was associated to both segregation of pre-existing cell populations, and co-option of new genes for the control of myogenesis.
Asunto(s)
Regulación del Desarrollo de la Expresión Génica , Cabeza , Anfioxos , Mesodermo , Vertebrados , Animales , Mesodermo/citología , Mesodermo/embriología , Anfioxos/embriología , Anfioxos/genética , Cabeza/embriología , Vertebrados/embriología , Vertebrados/genética , Somitos/embriología , Somitos/citología , Somitos/metabolismo , Evolución Biológica , TranscriptomaRESUMEN
The primary senses-touch, taste, sight, smell, and hearing-connect animals with their environments and with one another. Aside from the eyes, the primary sense organs of vertebrates and the peripheral sensory pathways that relay their inputs arise from two transient stem cell populations: the neural crest and the cranial placodes. In this chapter we consider the senses from historical and cultural perspectives, and discuss the senses as biological faculties. We begin with the embryonic origin of the neural crest and cranial placodes from within the neural plate border of the ectodermal germ layer. Then, we describe the major chemical (i.e. olfactory and gustatory) and mechanical (i.e. vestibulo-auditory and somatosensory) senses, with an emphasis on the developmental interactions between neural crest and cranial placodes that shape their structures and functions.
Asunto(s)
Cresta Neural , Animales , Cresta Neural/citología , Cresta Neural/embriología , Cresta Neural/fisiología , Humanos , Sensación/fisiología , Órganos de los Sentidos/embriología , Órganos de los Sentidos/fisiología , Órganos de los Sentidos/citología , Vertebrados/embriología , Vertebrados/fisiologíaRESUMEN
Although vertebrates display a large variety of forms and sizes, the mechanisms controlling the layout of the basic body plan are substantially conserved throughout the clade. Following gastrulation, head, trunk, and tail are sequentially generated through the continuous addition of tissue at the caudal embryonic end. Development of each of these major embryonic regions is regulated by a distinct genetic network. The transitions from head-to-trunk and from trunk-to-tail development thus involve major changes in regulatory mechanisms, requiring proper coordination to guarantee smooth progression of embryonic development. In this review, we will discuss the key cellular and embryological events associated with those transitions giving particular attention to their regulation, aiming to provide a cohesive outlook of this important component of vertebrate development.
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Tipificación del Cuerpo , Regulación del Desarrollo de la Expresión Génica , Animales , Humanos , Desarrollo Embrionario , Gastrulación , Vertebrados/embriologíaRESUMEN
The diversity of vertebrate body plans is dizzying, yet stunning for the many things they have in common. Vertebrates have inhabited virtually every part of the earth from its coldest to warmest climates. They locomote by swimming, flying, walking, slithering, or climbing, or combinations of these behaviors. And they exist in many different sizes, from the smallest of frogs, fish and lizards to giraffes, elephants, and blue whales. Despite these differences, vertebrates follow a remarkably similar blueprint for the establishment of their body plan. Within the relatively small amount of time required to complete gastrulation, the process through which the three germ layers, ectoderm, mesoderm, and endoderm are created, the embryo also generates its body axis and is simultaneously patterned. For the length of this axis, the genes that distinguish the neck from the rib cage or the trunk from the sacrum are the Hox genes. In vertebrates, there was evolutionary pressure to maintain this set of genes in the organism. Over the past decades, much has been learned regarding the regulatory mechanisms that ensure the appropriate expression of these genes along the main body axes. Genetic functions continue to be explored though much has been learned. Much less has been discerned on the identity of co-factors used by Hox proteins for the specificity of transcriptional regulation or what downstream targets and pathways are critical for patterning events, though there are notable exceptions. Current work in the field is demonstrating that Hox genes continue to function in many organs long after directing early patterning events. It is hopeful continued research will shed light on remaining questions regarding mechanisms used by this important and conserved set of transcriptional regulators.
Asunto(s)
Tipificación del Cuerpo , Regulación del Desarrollo de la Expresión Génica , Genes Homeobox , Vertebrados , Animales , Tipificación del Cuerpo/genética , Vertebrados/genética , Vertebrados/embriología , Genes Homeobox/genéticaRESUMEN
External bilateral symmetry is a prevalent feature in vertebrates, which emerges during early embryonic development. To begin with, vertebrate embryos are largely radially symmetric before transitioning to bilaterally symmetry, after which, morphogenesis of various bilateral tissues (e.g somites, otic vesicle, limb bud), and structures (e.g palate, jaw) ensue. While a significant amount of work has probed the mechanisms behind symmetry breaking in the left-right axis leading to asymmetric positioning of internal organs, little is known about how bilateral tissues emerge at the same time with the same shape and size and at the same position on the two sides of the embryo. By discussing emergence of symmetry in many bilateral tissues and structures across vertebrate model systems, we highlight that understanding symmetry establishment is largely an open field, which will provide deep insights into fundamental problems in developmental biology for decades to come.
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Tipificación del Cuerpo , Vertebrados , Animales , Vertebrados/embriología , Desarrollo Embrionario , Regulación del Desarrollo de la Expresión Génica , Morfogénesis , Somitos/embriologíaRESUMEN
Morphogenesis from cells to tissue gives rise to the complex architectures that make our organs. How cells and their dynamic behavior are translated into functional spatial patterns is only starting to be understood. Recent advances in quantitative imaging revealed that, although highly heterogeneous, cellular behaviors make reproducible tissue patterns. Emerging evidence suggests that mechanisms of cellular coordination, intrinsic variability and plasticity are critical for robust pattern formation. While pattern development shows a high level of fidelity, tissue organization has undergone drastic changes throughout the course of evolution. In addition, alterations in cell behavior, if unregulated, can cause developmental malformations that disrupt function. Therefore, comparative studies of different species and of disease models offer a powerful approach for understanding how novel spatial configurations arise from variations in cell behavior and the fundamentals of successful pattern formation. In this chapter, I dive into the development of the vertebrate nervous system to explore efforts to dissect pattern formation beyond molecules, the emerging core principles and open questions.
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Sistema Nervioso , Vertebrados , Animales , Vertebrados/fisiología , Vertebrados/embriología , Sistema Nervioso/crecimiento & desarrollo , Sistema Nervioso/embriología , Tipificación del Cuerpo , Humanos , MorfogénesisRESUMEN
Neural-crest cells and neuromesodermal progenitors (NMPs) are multipotent cells that are important for development of vertebrate embryos. In embryos of ascidians, which are the closest invertebrate relatives of vertebrates, several cells located at the border between the neural plate and the epidermal region have neural-crest-like properties; hence, the last common ancestor of ascidians and vertebrates may have had ancestral cells similar to neural-crest cells. However, these ascidian neural-crest-like cells do not produce cells that are commonly of mesodermal origin. Here we showed that a cell population located in the lateral region of the neural plate has properties resembling those of vertebrate neural-crest cells and NMPs. Among them, cells with Tbx6-related expression contribute to muscle near the tip of the tail region and cells with Sox1/2/3 expression give rise to the nerve cord. These observations and cross-species transcriptome comparisons indicate that these cells have properties similar to those of NMPs. Meanwhile, transcription factor genes Dlx.b, Zic-r.b and Snai, which are reminiscent of a gene circuit in vertebrate neural-crest cells, are involved in activation of Tbx6-related.b. Thus, the last common ancestor of ascidians and vertebrates may have had cells with properties of neural-crest cells and NMPs and such ancestral cells may have produced cells commonly of ectodermal and mesodermal origins.
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Cresta Neural , Vertebrados , Animales , Vertebrados/embriología , Cresta Neural/citología , Cresta Neural/embriología , Urocordados/embriología , Urocordados/citología , Embrión no Mamífero/citología , Ciona intestinalis/embriología , Ciona intestinalis/genética , Ciona intestinalis/citologíaRESUMEN
The neural crest is an embryonic stem cell population unique to vertebrates1 whose expansion and diversification are thought to have promoted vertebrate evolution by enabling emergence of new cell types and structures such as jaws and peripheral ganglia2. Although jawless vertebrates have sensory ganglia, convention has it that trunk sympathetic chain ganglia arose only in jawed vertebrates3-8. Here, by contrast, we report the presence of trunk sympathetic neurons in the sea lamprey, Petromyzon marinus, an extant jawless vertebrate. These neurons arise from sympathoblasts near the dorsal aorta that undergo noradrenergic specification through a transcriptional program homologous to that described in gnathostomes. Lamprey sympathoblasts populate the extracardiac space and extend along the length of the trunk in bilateral streams, expressing the catecholamine biosynthetic pathway enzymes tyrosine hydroxylase and dopamine ß-hydroxylase. CM-DiI lineage tracing analysis further confirmed that these cells derive from the trunk neural crest. RNA sequencing of isolated ammocoete trunk sympathoblasts revealed gene profiles characteristic of sympathetic neuron function. Our findings challenge the prevailing dogma that posits that sympathetic ganglia are a gnathostome innovation, instead suggesting that a late-developing rudimentary sympathetic nervous system may have been characteristic of the earliest vertebrates.
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Evolución Biológica , Linaje de la Célula , Cresta Neural , Neuronas , Sistema Nervioso Simpático , Vertebrados , Animales , Dopamina beta-Hidroxilasa/metabolismo , Dopamina beta-Hidroxilasa/genética , Ganglios Simpáticos/citología , Ganglios Simpáticos/metabolismo , Cresta Neural/citología , Cresta Neural/metabolismo , Neuronas/citología , Neuronas/metabolismo , Petromyzon/anatomía & histología , Petromyzon/embriología , Petromyzon/genética , Sistema Nervioso Simpático/citología , Sistema Nervioso Simpático/fisiología , Tirosina 3-Monooxigenasa/metabolismo , Tirosina 3-Monooxigenasa/genética , Vertebrados/anatomía & histología , Vertebrados/embriología , Vertebrados/genética , Células Madre Embrionarias/citología , Células Madre Embrionarias/metabolismo , Aorta/anatomía & histología , Aorta/embriología , Catecolaminas/biosíntesis , Catecolaminas/metabolismo , Vías BiosintéticasRESUMEN
The chronologically ordered generation of distinct cell types is essential for the establishment of neuronal diversity and the formation of neuronal circuits. Recently, single-cell transcriptomic analyses of various areas of the developing vertebrate nervous system have provided evidence for the existence of a shared temporal patterning program that partitions neurons based on the timing of neurogenesis. In this review, I summarize the findings that lead to the proposal of this shared temporal program before focusing on the developing spinal cord to discuss how temporal patterning in general and this program specifically contributes to the ordered formation of neuronal circuits.
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Tipificación del Cuerpo , Regulación del Desarrollo de la Expresión Génica , Tubo Neural , Neurogénesis , Médula Espinal , Vertebrados , Animales , Tubo Neural/crecimiento & desarrollo , Neurogénesis/genética , Vertebrados/crecimiento & desarrollo , Vertebrados/genética , Vertebrados/embriología , Tipificación del Cuerpo/genética , Regulación del Desarrollo de la Expresión Génica/genética , Médula Espinal/crecimiento & desarrollo , Médula Espinal/embriología , Neuronas/citología , Neuronas/metabolismo , HumanosRESUMEN
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.
Asunto(s)
Tipificación del Cuerpo , Somitos , Somitos/embriología , Somitos/metabolismo , Animales , Humanos , Tipificación del Cuerpo/genética , Vertebrados/embriología , Regulación del Desarrollo de la Expresión Génica , Desarrollo Embrionario/genética , Mesodermo/metabolismo , Mesodermo/embriología , Transducción de Señal , MorfogénesisRESUMEN
BACKGROUND: The phylotypic or intermediate stages are thought to be the most evolutionary conserved stages throughout embryonic development. The contrast with divergent early and later stages derived from the concept of the evo-devo hourglass model. Nonetheless, this developmental constraint has been studied as a whole embryo process, not at organ level. In this review, we explore brain development to assess the existence of an equivalent brain developmental hourglass. In the specific case of vertebrates, we propose to split the brain developmental stages into: (1) Early: Neurulation, when the neural tube arises after gastrulation. (2) Intermediate: Brain patterning and segmentation, when the neuromere identities are established. (3) Late: Neurogenesis and maturation, the stages when the neurons acquire their functionality. Moreover, we extend this analysis to other chordates brain development to unravel the evolutionary origin of this evo-devo constraint. SUMMARY: Based on the existing literature, we hypothesise that a major conservation of the phylotypic brain might be due to the pleiotropy of the inductive regulatory networks, which are predominantly expressed at this stage. In turn, earlier stages such as neurulation are rather mechanical processes, whose regulatory networks seem to adapt to environment or maternal geometries. The later stages are also controlled by inductive regulatory networks, but their effector genes are mostly tissue-specific and functional, allowing diverse developmental programs to generate current brain diversity. Nonetheless, all stages of the hourglass are highly interconnected: divergent neurulation must have a vertebrate shared end product to reproduce the vertebrate phylotypic brain, and the boundaries and transcription factor code established during the highly conserved patterning will set the bauplan for the specialised and diversified adult brain. KEY MESSAGES: The vertebrate brain is conserved at phylotypic stages, but the highly conserved mechanisms that occur during these brain mid-development stages (Inducing Regulatory Networks) are also present during other stages. Oppositely, other processes as cell interactions and functional neuronal genes are more diverse and majoritarian in early and late stages of development, respectively. These phenomena create an hourglass of transcriptomic diversity during embryonic development and evolution, with a really conserved bottleneck that set the bauplan for the adult brain around the phylotypic stage.
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Evolución Biológica , Encéfalo , Tubo Neural , Vertebrados , Animales , Vertebrados/embriología , Vertebrados/crecimiento & desarrollo , Encéfalo/embriología , Encéfalo/crecimiento & desarrollo , Tubo Neural/embriología , Neurogénesis/fisiología , Neurulación/fisiologíaRESUMEN
Vertebrate paired appendages are one of the most important evolutionary novelties in vertebrates. During embryogenesis, the skeletal elements of paired appendages differentiate from the somatic mesoderm, which is a layer of lateral plate mesoderm. However, the presence of the somatic mesoderm in the common ancestor of vertebrates has been controversial. To address this problem, it is necessary but insufficient to understand the developmental process of lateral plate mesoderm formation in lamprey (jawless vertebrates) embryos. Here, I show the presence of the somatic mesoderm in lamprey (Lethenteron camtschaticum) embryos using plastic sectioning and transmission electron microscopy analysis. During the early pharyngeal stages, the somatic mesoderm transforms from the lateral plate mesoderm in the trunk region. Soon after, when the cardiac structures were morphologically distinct, the somatic mesoderm was recognized through the cardiac to more caudal regions. These findings indicated that the somatic mesoderm evolved before the emergence of paired appendages. I also discuss the developmental changes in the body wall organization in the common ancestor of vertebrates, which is likely related to the evolution of the paired appendages.
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Evolución Biológica , Lampreas , Mesodermo , Animales , Desarrollo Embrionario , Lampreas/anatomía & histología , Lampreas/embriología , Mesodermo/embriología , Mesodermo/ultraestructura , Vertebrados/anatomía & histología , Vertebrados/embriología , Embrión no Mamífero/embriología , Embrión no Mamífero/ultraestructuraRESUMEN
The vertebrate inner ear arises from a pool of progenitors with the potential to contribute to all the sense organs and cranial ganglia in the head. Here, we explore the molecular mechanisms that control ear specification from these precursors. Using a multiomics approach combined with loss-of-function experiments, we identify a core transcriptional circuit that imparts ear identity, along with a genome-wide characterization of noncoding elements that integrate this information. This analysis places the transcription factor Sox8 at the top of the ear determination network. Introducing Sox8 into the cranial ectoderm not only converts non-ear cells into ear progenitors but also activates the cellular programs for ear morphogenesis and neurogenesis. Thus, Sox8 has the unique ability to remodel transcriptional networks in the cranial ectoderm toward ear identity.
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Oído Interno , Ectodermo , Regulación del Desarrollo de la Expresión Génica , Factores de Transcripción SOXE , Animales , Oído Interno/embriología , Ectodermo/embriología , Factores de Transcripción SOXE/fisiología , Cráneo , Vertebrados/embriologíaRESUMEN
The primitive streak, a transient embryonic structure, marks bilateral symmetry in mammalian and avian embryos and helps confer anterior-posterior and dorsal-ventral spatial information to early differentiating cells during gastrulation. Its recapitulation in vitro may facilitate derivation of tissues and organs with in vivolike complexity. Proper understanding of the primitive streak and what it entails in human development is key to achieving such research objectives. Here we provide an overview of the primitive streak and conclude that this structure is neither conserved nor necessary for gastrulation or early lineage diversification. We offer a model in which the primitive streak is viewed as part of a morphologically diverse yet molecularly conserved process of spatial coordinate acquisition. We predict that recapitulation of the primitive streak is dispensable for development in vitro.
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Embrión de Mamíferos/fisiología , Embrión no Mamífero/fisiología , Gastrulación , Línea Primitiva/fisiología , Vertebrados/embriología , Animales , Evolución Biológica , Embrión de Mamíferos/anatomía & histología , Embrión de Mamíferos/citología , Embrión no Mamífero/anatomía & histología , Embrión no Mamífero/citología , Regulación del Desarrollo de la Expresión Génica , Humanos , Morfogénesis , FilogeniaRESUMEN
Zygotic genome activation (ZGA) initiates regionalized transcription underlying distinct cellular identities. ZGA is dependent upon dynamic chromatin architecture sculpted by conserved DNA-binding proteins. However, the direct mechanistic link between the onset of ZGA and the tissue-specific transcription remains unclear. Here, we have addressed the involvement of chromatin organizer Satb2 in orchestrating both processes during zebrafish embryogenesis. Integrative analysis of transcriptome, genome-wide occupancy and chromatin accessibility reveals contrasting molecular activities of maternally deposited and zygotically synthesized Satb2. Maternal Satb2 prevents premature transcription of zygotic genes by influencing the interplay between the pluripotency factors. By contrast, zygotic Satb2 activates transcription of the same group of genes during neural crest development and organogenesis. Thus, our comparative analysis of maternal versus zygotic function of Satb2 underscores how these antithetical activities are temporally coordinated and functionally implemented highlighting the evolutionary implications of the biphasic and bimodal regulation of landmark developmental transitions by a single determinant.
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Proteínas de Unión a la Región de Fijación a la Matriz/metabolismo , Factores de Transcripción/metabolismo , Vertebrados/embriología , Proteínas de Pez Cebra/metabolismo , Pez Cebra/embriología , Pez Cebra/metabolismo , Animales , Cromatina/genética , Cromatina/metabolismo , Desarrollo Embrionario , Femenino , Regulación del Desarrollo de la Expresión Génica , Masculino , Proteínas de Unión a la Región de Fijación a la Matriz/genética , Factores de Transcripción/genética , Transcriptoma , Vertebrados/genética , Vertebrados/metabolismo , Pez Cebra/genética , Proteínas de Pez Cebra/genética , Cigoto/metabolismoRESUMEN
Fibroblast growth factors (FGFs) comprise a large family of growth factors, regulating diverse biological processes including cell proliferation, migration, and differentiation. Each FGF binds to a set of FGF receptors to initiate certain intracellular signaling molecules. Accumulated evidence suggests that in early development and adult state of vertebrates, FGFs also play exclusive and context dependent roles. Although FGFs have been the focus of research for therapeutic approaches in cancer, cardiovascular disease, and metabolic syndrome, in this review, we mainly focused on their role in germ layer specification and axis patterning during early vertebrate embryogenesis. We discussed the functional roles of FGFs and their interacting partners as part of the gene regulatory network for germ layer specification, dorsal-ventral (DV), and anterior-posterior (AP) patterning. Finally, we briefly reviewed the regulatory molecules and pharmacological agents discovered that may allow modulation of FGF signaling in research.
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Factores de Crecimiento de Fibroblastos/metabolismo , Estratos Germinativos/metabolismo , Receptores de Factores de Crecimiento de Fibroblastos/metabolismo , Transducción de Señal , Vertebrados/metabolismo , Animales , Factores de Crecimiento de Fibroblastos/genética , Regulación del Desarrollo de la Expresión Génica , Estratos Germinativos/embriología , Humanos , Modelos Biológicos , Unión Proteica , Receptores de Factores de Crecimiento de Fibroblastos/genética , Vertebrados/embriología , Vertebrados/genéticaRESUMEN
The vertebrate retina contains an array of neural circuits that detect distinct features in visual space. Direction-selective (DS) circuits are an evolutionarily conserved retinal circuit motif - from zebrafish to rodents to primates - specialized for motion detection. During retinal development, neuronal subtypes that wire DS circuits form exquisitely precise connections with each other to shape the output of retinal ganglion cells tuned for specific speeds and directions of motion. In this review, we follow the chronology of DS circuit development in the vertebrate retina, including the cellular, molecular, and activity-dependent mechanisms that regulate the formation of DS circuits, from cell birth and migration to synapse formation and refinement. We highlight recent findings that identify genetic programs critical for specifying neuronal subtypes within DS circuits and molecular interactions essential for responses along the cardinal axes of motion. Finally, we discuss the roles of DS circuits in visual behavior and in certain human visual disease conditions. As one of the best-characterized circuits in the vertebrate retina, DS circuits represent an ideal model system for studying the development of neural connectivity at the level of individual genes, cells, and behavior.