Cell signaling pathways controlling an axis organizing center in the zebrafish

Protein-O-fucosylation of coreceptors may be required for Nodal signaling in Xenopus

Nodal-related ligands of TGF-β family play pivotal roles for mesoderm induction and body axis formation during vertebrate early embryogenesis. Nodal ligands are distinct from most other TGF-β ligands family as they require EGF-CFC factors as coreceptors for signaling, in addition to their cognate type I and type II TGF-β receptors. In amphibian Xenopus laevis embryos, 5 Nodal-related genes (Xnr1/2/4/5/6) and 2 EGF-CFC genes (XCR1, XCR3) play roles in mesoderm induction and the accumulation of phosphorylated Smad2, while in mammalian embryos, 1 Nodal gene and 1 EGF-CFC gene (Cripto) play roles during mesoderm induction. Mammalian EGF-CFC factors are reported to be O-fucosylated at a conserved threonine residue of the EGF-like motif by protein-O-fucosyltransferase 1 (Pofut1), but this O-fucose modification is shown to be dispensable for Nodal signaling in mammalian embryos. In this study, we investigated the developmental roles of Xenopus laevis Pofut1 (XPofut1) and its potential function in Nodal signaling. We found that morpholino antisense-mediated knockdown of XPofut1 causes reduction of Smad2 phosphorylation in late blastula and axial truncation in neurula. We also found that the O-fucosyltransferase activity of XPofut1 is important in the marginal zone, but not in the vegetal pole region, of blastula. Interestingly, XPofut1 is necessary for Smad2 phosphorylation induced by Xnr1 or Xnr2, but not by Xnr5 or Xnr6. Among the Nodal signaling components, only EGF-CFC factors are known to be modified by Pofut1. Therefore, based on our current observation, we propose that XPofut1 regulates signaling of a subset of nodal ligands in pregastrulation embryos possibly through modulating the function of EGF-CFC factors.

Maternal control of embryonic dorsal organizer in vertebrates

The establishment of the body axis and developmental blueprint in embryos has remained to be a central question in developmental biology, captivating scientists for centuries. A milestone in this field was achieved in 1924 when Hans Spemann and Hilde Mangold discovered the dorsal organizer for embryonic body axis formation in amphibians. Since then, extensive studies have demonstrated that the dorsal organizer is evolutionarily conserved in vertebrates. This organizer functions as a signaling center, directing adjacent cells toward specific fates and orchestrating pattern formation to establish the embryonic axis. After 70 years since the discovery of the organizer, studies in different model animal species had revealed that locally activated β-catenin signaling during blastulation plays an indispensable role in organizer induction. Then, efforts have been made to identify initiators of β-catenin activation in blastulas. Now, it appears that maternal Huluwa, a transmembrane protein, is a bona fide organizer inducer at least in teleost fish and frog, which can activate downstream signaling pathways, including but probably not limited to β-catenin pathway. More studies are needed to decode the complete molecular network controlling organizer induction.

The temporal control and activity of maternal zsquildlike-A/hnrnpaba during zebrafish embryogenesis indicate a role in early pattern formation

During embryogenesis in Danio rerio (zebrafish), the earliest morphological patterning events are dependent on the precise temporal translation and/or localization of specific maternal mRNAs/proteins. Dorsoventral patterning in particular requires the translocation of maternal factors that are present in the Balbiani Body from the vegetal region of the unfertilized egg to the future dorsal side of the embryo (Fuentes et al., 2020), leading to the localized activation of the β-catenin pathway in the cells in that region. Since zebrafish are chordates, this dorsoventral patterning then leads to the formation of neural tissue on the dorsal side of the embryo. What is not yet clear is the identity of all maternal and zygotic factors that first establish dorsoventral patterning, and which factors lead to the establishment of neural versus non-neural tissue. Taking an evolutionary approach to this question, we investigated a gene in zebrafish, zsquidlike-A (hnrnpaba), that is homologous to a key dorsoventral patterning gene in fruit flies (Drosophila melanogaster) called squid (Kelley, 1993). While dorsoventral patterning in flies and fish looks quite different both morphologically and at the molecular level, we demonstrate that not only has a key dorsoventral patterning gene in flies been conserved in fish, maternal fish zsquidlike-A protein is synthesized precisely as dorsoventral patterning is unfolding in fish embryos, and in its absence, dorsoventral patterning is severely disrupted.

Quantitative Staging of Mid-blastula Zebrafish Embryos by Nuclei Counting

Precise developmental staging of embryos is critical for experimental methods that compare different groups of embryos in developmental biology. During development, gene and protein expression levels change dynamically as cells acquire sequentially more restricted cell fates, from pluri- or multipotent cells to germ layers and to differentiated cells. In particular, zebrafish embryos experience rapid transcriptional changes at the mid-blastula transition, when zygotic transcription is activated in specific domains along the dorsoventral and anteroposterior axes and maternal transcripts are degraded. During these rapid and widespread transcriptional changes, precise staging is needed to accurately compare one group of experimental embryos to another that differ in some experimental variable, such as mutant versus wild-type embryos, or embryos receiving two different experimental treatments. Precise staging ensures that an observed change in gene or protein expression between the experimental groups is due to the experimental variable and not to a difference in developmental stage caused by asynchrony in early development. However, zebrafish embryos exhibit rapid cell divisions and subtle morphological changes during the mid-blastula period, making it difficult to accurately stage embryos using morphology or timing alone. Here, we present a method to quantitatively stage zebrafish embryos based on cell count during the mid-blastula period. Our method can be applied to any zebrafish experiment performed during the mid-blastula period, by counting nuclei in sibling embryos of the experimental ones. After staining with a nuclear marker, nuclei are imaged with a confocal microscope and then quickly identified and counted with standard imaging software. Overall, this quantitative staging method can increase experimental rigor and decrease variability in experiments during the mid-blastula period.

Canonical and Non-Canonical Wnt Signaling Generates Molecular and Cellular Asymmetries to Establish Embryonic Axes

The formation of embryonic axes is a critical step during animal development, which contributes to establishing the basic body plan in each particular organism. Wnt signaling pathways play pivotal roles in this fundamental process. Canonical Wnt signaling that is dependent on β-catenin regulates the patterning of dorsoventral, anteroposterior, and left-right axes. Non-canonical Wnt signaling that is independent of β-catenin modulates cytoskeletal organization to coordinate cell polarity changes and asymmetric cell movements. It is now well documented that components of these Wnt pathways biochemically and functionally interact to mediate cell-cell communications and instruct cellular polarization in breaking the embryonic symmetry. The dysfunction of Wnt signaling disrupts embryonic axis specification and proper tissue morphogenesis, and mutations of Wnt pathway genes are associated with birth defects in humans. This review discusses the regulatory roles of Wnt pathway components in embryonic axis formation by focusing on vertebrate models. It highlights current progress in decoding conserved mechanisms underlying the establishment of asymmetry along the three primary body axes. By providing an in-depth analysis of canonical and non-canonical pathways in regulating cell fates and cellular behaviors, this work offers insights into the intricate processes that contribute to setting up the basic body plan in vertebrate embryos.

Organizing activities of axial mesoderm

For almost a century, developmental biologists have appreciated that the ability of the embryonic organizer to induce and pattern the body plan is intertwined with its differentiation into axial mesoderm. Despite this, we still have a relatively poor understanding of the contribution of axial mesoderm to induction and patterning of different body regions, and the manner in which axial mesoderm-derived information is interpreted in tissues of changing competence. Here, with a particular focus on the nervous system, we review the evidence that axial mesoderm notochord and prechordal mesoderm/mesendoderm act as organizers, discuss how their influence extends through the different axes of the developing organism, and describe how the ability of axial mesoderm to direct morphogenesis impacts on its role as a local organizer.

Emergence of a left-right symmetric body plan in vertebrate embryos

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.

When You Come to a Fork in the Road, Take It: Wnt Signaling Activates Multiple Pathways through the APC/Axin/GSK-3 Complex

The Wnt signaling pathway is a highly conserved regulator of metazoan development and stem cell maintenance. Activation of Wnt signaling is an early step in diverse malignancies. Work over the past four decades has defined a "canonical" Wnt pathway that is initiated by Wnt proteins, secreted glycoproteins that bind to a surface receptor complex and activate intracellular signal transduction by inhibiting a catalytic complex composed of the classical tumor suppressor Adenomatous Polyposis Coli (APC), Axin, and Glycogen Synthase Kinase-3 (GSK-3). The best characterized effector of this complex is β-catenin, which is stabilized by inhibition of GSK-3, allowing β-catenin entrance to the nucleus and activation of Wnt target gene transcription, leading to multiple cancers when inappropriately activated. However, canonical Wnt signaling through the APC/Axin/GSK-3 complex impinges on other effectors, independently of β-catenin, including the mechanistic Target of Rapamycin (mTOR), regulators of protein stability, mitotic spindle orientation, and Hippo signaling. This review focuses on these alternative effectors of the canonical Wnt pathway and how they may contribute to cancers.

Dynamic BMP signaling mediates notochord segmentation in zebrafish

The vertebrate spine is a metameric structure composed of alternating vertebral bodies (centra) and intervertebral discs.1 Recent studies in zebrafish have shown that the epithelial sheath surrounding the notochord differentiates into alternating cartilage-like (col2a1/col9a2+) and mineralizing (entpd5a+) segments which serve as a blueprint for centra formation.2,3,4,5 This process also defines the trajectories of migrating sclerotomal cells that form the mature vertebral bodies.4 Previous work demonstrated that notochord segmentation is typically sequential and involves the segmented activation of Notch signaling.2 However, it is unclear how Notch is activated in an alternating and sequential fashion. Furthermore, the molecular components that define segment size, regulate segment growth, and produce sharp segment boundaries have not been identified. In this study, we uncover that a BMP signaling wave acts upstream of Notch during zebrafish notochord segmentation. Using genetically encoded reporters of BMP activity and signaling pathway components, we show that BMP signaling is dynamic as axial patterning progresses, leading to the sequential formation of mineralizing domains in the notochord sheath. Genetic manipulations reveal that type I BMP receptor activation is sufficient to ectopically trigger Notch signaling. Moreover, loss of Bmpr1ba and Bmpr1aa or Bmp3 function disrupts ordered segment formation and growth, which is recapitulated by notochord-specific overexpression of the BMP antagonist, Noggin3. Our data suggest that BMP signaling in the notochord sheath precedes Notch activation and instructs segment growth, facilitating proper spine morphogenesis.

The role of fibroblast growth factor 7 in cartilage development and diseases

Fibroblast growth factor 7 (FGF7), also known as keratinocyte growth factor (KGF), shows a crucial biological significance in tissue development, wound repair, tumorigenesis, and immune reconstruction. In the skeletal system, FGF7 directs the cellular synaptic extension of individual cells and facilities functional gap junction intercellular communication of a collective of cells. Moreover, it promotes the osteogenic differentiation of stem cells via a cytoplasmic signaling network. For cartilage, reports have indicated the potential role of FGF7 on the regulation of key molecules Cx43 in cartilage and Runx2 in hypertrophic cartilage. However, the molecular mechanism of FGF7 in chondrocyte behaviors and cartilage pathological process remains largely unknown. In this review, we systematically summarize the recent biological function of FGF7 and its regulatory role on chondrocytes and cartilage diseases, especially through the hot focus of two key molecules, Runx2 and Cx43. The current knowledge of FGF7 on the physiological and pathological processes of chondrocytes and cartilage provides us new cues for wound repair of cartilage defect and therapy of cartilage diseases.

Proprotein Convertase Subtilisin/Kexin 6 in Cardiovascular Biology and Disease

Proprotein convertase subtilisin/kexin 6 (PCSK6) is a secreted serine protease expressed in most major organs, where it cleaves a wide range of growth factors, signaling molecules, peptide hormones, proteolytic enzymes, and adhesion proteins. Studies in Pcsk6-deficient mice have demonstrated the importance of Pcsk6 in embryonic development, body axis specification, ovarian function, and extracellular matrix remodeling in articular cartilage. In the cardiovascular system, PCSK6 acts as a key modulator in heart formation, lipoprotein metabolism, body fluid homeostasis, cardiac repair, and vascular remodeling. To date, dysregulated PCSK6 expression or function has been implicated in major cardiovascular diseases, including atrial septal defects, hypertension, atherosclerosis, myocardial infarction, and cardiac aging. In this review, we describe biochemical characteristics and posttranslational modifications of PCSK6. Moreover, we discuss the role of PCSK6 and related molecular mechanisms in cardiovascular biology and disease.