Your search keyword '"McClay, David R."' showing total 410 results

201. Feedback circuits are numerous in embryonic gene regulatory networks and offer a stabilizing influence on evolution of those networks.

Author

Massri AJ, McDonald B, Wray GA, and McClay DR

Abstract

The developmental gene regulatory networks (dGRNs) of two sea urchin species, Lytechinus variegatus (Lv) and Strongylocentrotus purpuratus (Sp), have remained remarkably similar despite about 50 million years since a common ancestor. Hundreds of parallel experimental perturbations of transcription factors with similar outcomes support this conclusion. A recent scRNA-seq analysis suggested that the earliest expression of several genes within the dGRNs differs between Lv and Sp. Here, we present a careful reanalysis of the dGRNs in these two species, paying close attention to timing of first expression. We find that initial expression of genes critical for cell fate specification occurs during several compressed time periods in both species. Previously unrecognized feedback circuits are inferred from the temporally corrected dGRNs. Although many of these feedbacks differ in location within the respective GRNs, the overall number is similar between species. We identify several prominent differences in timing of first expression for key developmental regulatory genes; comparison with a third species indicates that these heterochronies likely originated in an unbiased manner with respect to embryonic cell lineage and evolutionary branch. Together, these results suggest that interactions can evolve even within highly conserved dGRNs and that feedback circuits may buffer the effects of heterochronies in the expression of key regulatory genes., (© 2023. The Author(s).)

Published

2023

202. Wound repair in sea urchin larvae involves pigment cells and blastocoelar cells.

Author

Allen RL, George AN, Miranda E, Phillips TM, Crawford JM, Kiehart DP, and McClay DR

Subjects

Animals, Epithelium, Larva, Metamorphosis, Biological, Calcium, Sea Urchins

Abstract

Sea urchin larvae spend weeks to months feeding on plankton prior to metamorphosis. When handled in the laboratory they are easily injured, suggesting that in the plankton they are injured with some frequency. Fortunately, larval wounds are repaired through an efficient wound response with mesenchymal pigment cells and blastocoelar cells assisting as the epithelium closes. An injury to the epithelium leads to an immediate calcium transient that rapidly spreads around the entire larva and is necessary for activating pigment cell migration toward the wound. If calcium transport is blocked, the pigment cells fail to activate and remain in place. When activated, pigment cells initiate directed migration to the wound site from distances of at least 85 ​μm. Upon arrival at the wound site they participate in an innate immune response. Blastocoelar cells are recruited to the injury site as well, though the calcium transient is unnecessary for activating these cells. At the wound site, blastocoelar cells participate in several functions including remodeling the skeleton if it protrudes through the epithelium., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

203. Development of a larval nervous system in the sea urchin.

Author

McClay DR

Subjects

Animals, Gene Regulatory Networks, Larva metabolism, Nervous System, Gene Expression Regulation, Developmental, Sea Urchins genetics, Sea Urchins metabolism

Abstract

This review reports recent findings on the specification and patterning of neurons that establish the larval nervous system of the sea urchin embryo. Neurons originate in three regions of the embryo. Perturbation analyses enabled construction of gene regulatory networks controlling the several neural cell types. Many of the mechanisms described reflect shared features of all metazoans and others are conserved among deuterostomes. This nervous system with a very small number of neurons supports the feeding and swimming behaviors of the larva until metamorphosis when an adult nervous system replaces that system., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

204. Reprint of: Conditional specification of endomesoderm.

Author

McClay DR, Croce JC, and Warner JF

Subjects

Animals, Endoderm, Mesoderm, Signal Transduction, Embryo, Nonmammalian, Sea Urchins

Abstract

Early in animal development many cells are conditionally specified based on observations that those cells can be directed toward alternate fates. The endomesoderm is so named because early specification produces cells that often have been observed to simultaneously express both early endoderm and mesoderm transcription factors. Experiments with these cells demonstrate that their progeny can directed entirely toward endoderm or mesoderm, whereas normally they establish both germ layers. This review examines the mechanisms that initiate the conditional endomesoderm state, its metastability, and the mechanisms that resolve that state into definitive endoderm and mesoderm., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

205. Developmental single-cell transcriptomics in the Lytechinus variegatus sea urchin embryo.

Author

Massri AJ, Greenstreet L, Afanassiev A, Berrio A, Wray GA, Schiebinger G, and McClay DR

Subjects

Animals, Cell Lineage, Endoderm cytology, Mesoderm cytology, Genomics methods, Lytechinus genetics, RNA-Seq methods, Single-Cell Analysis methods, Transcriptome

Abstract

Using scRNA-seq coupled with computational approaches, we studied transcriptional changes in cell states of sea urchin embryos during development to the larval stage. Eighteen closely spaced time points were taken during the first 24 h of development of Lytechinus variegatus (Lv). Developmental trajectories were constructed using Waddington-OT, a computational approach to 'stitch' together developmental time points. Skeletogenic and primordial germ cell trajectories diverged early in cleavage. Ectodermal progenitors were distinct from other lineages by the 6th cleavage, although a small percentage of ectoderm cells briefly co-expressed endoderm markers that indicated an early ecto-endoderm cell state, likely in cells originating from the equatorial region of the egg. Endomesoderm cells also originated at the 6th cleavage and this state persisted for more than two cleavages, then diverged into distinct endoderm and mesoderm fates asynchronously, with some cells retaining an intermediate specification status until gastrulation. Seventy-nine out of 80 genes (99%) examined, and included in published developmental gene regulatory networks (dGRNs), are present in the Lv-scRNA-seq dataset and are expressed in the correct lineages in which the dGRN circuits operate., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

206. Conditional specification of endomesoderm.

Author

McClay DR, Croce JC, and Warner JF

Subjects

Animals, Humans, Models, Biological, Sea Urchins embryology, Signal Transduction, Body Patterning, Endoderm embryology, Mesoderm embryology

Abstract

Early in animal development many cells are conditionally specified based on observations that those cells can be directed toward alternate fates. The endomesoderm is so named because early specification produces cells that often have been observed to simultaneously express both early endoderm and mesoderm transcription factors. Experiments with these cells demonstrate that their progeny can directed entirely toward endoderm or mesoderm, whereas normally they establish both germ layers. This review examines the mechanisms that initiate the conditional endomesoderm state, its metastability, and the mechanisms that resolve that state into definitive endoderm and mesoderm., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

207. Perspective on Epithelial-Mesenchymal Transitions in Embryos.

Author

McClay DR

Subjects

Animals, Cell Movement genetics, Cell Polarity genetics, Embryo, Nonmammalian, Epithelium metabolism, Epithelium pathology, Humans, Mesoderm metabolism, Cell Adhesion genetics, Epithelial-Mesenchymal Transition genetics, Gastrulation genetics, Mesoderm growth & development

Abstract

The epithelial-mesenchymal transition (EMT) is a key process required for building the early body plan of metazoa. It involves coordinated and precisely timed changes in multiple cell processes such as de-adhesion, motility, invasion, and cell polarity. While much has been learned about how embryos deploy epithelial-mesenchymal transitions since Betty Hay named the process decades ago, a number of things are still not well understood. Here I will discuss some of the big questions that remain, including how is all of this controlled, how does each of the cell biological events work, and how are they so nicely coordinated with one another?

Published

2021

208. Methodologies for Following EMT In Vivo at Single Cell Resolution.

Author

Massri AJ, Schiebinger GR, Berrio A, Wang L, Wray GA, and McClay DR

Subjects

Animals, Embryo, Nonmammalian cytology, Embryo, Nonmammalian metabolism, Sea Urchins, Computational Biology methods, Epithelial-Mesenchymal Transition, RNA-Seq methods, Single-Cell Analysis methods

Abstract

An epithelial-mesenchymal transition (EMT) occurs in almost every metazoan embryo at the time mesoderm begins to differentiate. Several embryos have a long record as models for studying an EMT given that a known population of cells enters the EMT at a known time thereby enabling a detailed study of the process. Often, however, it is difficult to learn the molecular details of these model EMT systems because the transitioning cells are a minority of the population of cells in the embryo and in most cases there is an inability to isolate that population. Here we provide a method that enables an examination of genes expressed before, during, and after the EMT with a focus on just the cells that undergo the transition. Single cell RNA-seq (scRNA-seq) has advanced as a technology making it feasible to study the trajectory of gene expression specifically in the cells of interest, in vivo, and without the background noise of other cell populations. The sea urchin skeletogenic cells constitute only 5% of the total number of cells in the embryo yet with scRNA-seq it is possible to study the genes expressed by these cells without background noise. This approach, though not perfect, adds a new tool for uncovering the mechanism of EMT in this cell type.

Published

2021

209. Chromosomal-Level Genome Assembly of the Sea Urchin Lytechinus variegatus Substantially Improves Functional Genomic Analyses.

Author

Davidson PL, Guo H, Wang L, Berrio A, Zhang H, Chang Y, Soborowski AL, McClay DR, Fan G, and Wray GA

Subjects

Animals, Chromosome Mapping, Molecular Sequence Annotation, Genome, Genomics methods, Lytechinus genetics

Abstract

Lytechinus variegatus is a camarodont sea urchin found widely throughout the western Atlantic Ocean in a variety of shallow-water marine habitats. Its distribution, abundance, and amenability to developmental perturbation make it a popular model for ecologists and developmental biologists. Here, we present a chromosomal-level genome assembly of L. variegatus generated from a combination of PacBio long reads, 10× Genomics sequencing, and HiC chromatin interaction sequencing. We show L. variegatus has 19 chromosomes with an assembly size of 870.4 Mb. The contiguity and completeness of this assembly are reflected by a scaffold length N50 of 45.5 Mb and BUSCO completeness score of 95.5%. Ab initio and transcript-informed gene modeling and annotation identified 27,232 genes with an average gene length of 12.6 kb, comprising an estimated 39.5% of the genome. Repetitive regions, on the other hand, make up 45.4% of the genome. Physical mapping of well-studied developmental genes onto each chromosome reveals nonrandom spatial distribution of distinct genes and gene families, which provides insight into how certain gene families may have evolved and are transcriptionally regulated in this species. Lastly, aligning RNA-seq and ATAC-seq data onto this assembly demonstrates the value of highly contiguous, complete genome assemblies for functional genomics analyses that is unattainable with fragmented, incomplete assemblies. This genome will be of great value to the scientific community as a resource for genome evolution, developmental, and ecological studies of this species and the Echinodermata., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2020

210. Developmental origin of peripheral ciliary band neurons in the sea urchin embryo.

Author

Slota LA, Miranda E, Peskin B, and McClay DR

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Butadienes pharmacology, Gene Expression Regulation, Developmental, Glycoproteins metabolism, Intercellular Signaling Peptides and Proteins metabolism, Larva growth & development, Mitogen-Activated Protein Kinases antagonists & inhibitors, Mitogen-Activated Protein Kinases metabolism, Nerve Tissue Proteins metabolism, Nitriles pharmacology, Nodal Protein metabolism, SOXC Transcription Factors metabolism, Signal Transduction genetics, Synaptotagmins metabolism, Body Patterning genetics, Ectoderm growth & development, Neurogenesis genetics, Neurons metabolism, Sea Urchins embryology

Abstract

In the sea urchin larva, most neurons lie within an ectodermal region called the ciliary band. Our understanding of the mechanisms of specification and patterning of these peripheral ciliary band neurons is incomplete. Here, we first examine the gene regulatory landscape from which this population of neural progenitors arise in the neuroectoderm. We show that ciliary band neural progenitors first appear in a bilaterally symmetric pattern on the lateral edges of chordin expression in the neuroectoderm. Later in development, these progenitors appear in a salt-and-pepper pattern in the ciliary band where they express soxC, and prox, which are markers of neural specification, and begin to express synaptotagminB, a marker of differentiated neurons. We show that the ciliary band expresses the acid sensing ion channel gene asicl, which suggests that ciliary band neurons control the larva's ability to discern touch sensitivity. Using a chemical inhibitor of MAPK signaling, we show that this signaling pathway is required for proper specification and patterning of ciliary band neurons. Using live imaging, we show that these neural progenitors undergo small distance migrations in the embryo. We then show that the normal swimming behavior of the larvae is compromised if the neurogenesis pathway is perturbed. The developmental sequence of ciliary band neurons is very similar to that of neural crest-derived sensory neurons in vertebrates and may provide insights into the evolution of sensory neurons in deuterostomes., Competing Interests: Declaration of competing interest The authors declare no competing interest or financial interests., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2020

211. Gastrulation in the sea urchin.

Author

McClay DR, Warner J, Martik M, Miranda E, and Slota L

Subjects

Animals, Cell Movement, Embryo, Nonmammalian cytology, Gastrula cytology, Gene Expression Regulation, Developmental, Germ Cells, Sea Urchins embryology, Transcription Factors genetics, Embryo, Nonmammalian physiology, Epithelial-Mesenchymal Transition, Gastrula physiology, Gastrulation, Morphogenesis, Sea Urchins physiology, Transcription Factors metabolism

Abstract

Gastrulation is arguably the most important evolutionary innovation in the animal kingdom. This process provides the basic embryonic architecture, an inner layer separated from an outer layer, from which all animal forms arise. An extraordinarily simple and elegant process of gastrulation is observed in the sea urchin embryo. The cells participating in sea urchin gastrulation are specified early during cleavage. One outcome of that specification is the expression of transcription factors that control each of the many subsequent morphogenetic changes. The first of these movements is an epithelial-mesenchymal transition (EMT) of skeletogenic mesenchyme cells, then EMT of pigment cell progenitors. Shortly thereafter, invagination of the archenteron occurs. At the end of archenteron extension, a second wave of EMT occurs to release immune cells into the blastocoel and primordial germ cells that will home to the coelomic pouches. The archenteron then remodels to establish the three parts of the gut, and at the anterior end, the gut fuses with the stomodaeum to form the through-gut. As part of the anterior remodeling, mesodermal coelomic pouches bud off the lateral sides of the archenteron tip. Multiple cell biological processes conduct each of these movements and in some cases the upstream transcription factors controlling this process have been identified. Remarkably, each event seamlessly occurs at the right time to orchestrate formation of the primitive body plan. This review covers progress toward understanding many of the molecular mechanisms underlying this sequence of morphogenetic events., (© 2020 Elsevier Inc. All rights reserved.)

Published

2020

212. Spatial and temporal patterns of gene expression during neurogenesis in the sea urchin Lytechinus variegatus .

Author

Slota LA, Miranda EM, and McClay DR

Abstract

Background: The sea urchin is a basal deuterostome that is more closely related to vertebrates than many organisms traditionally used to study neurogenesis. This phylogenetic position means that the sea urchin can provide insights into the evolution of the nervous system by helping resolve which developmental processes are deuterostome innovations, which are innovations in other clades, and which are ancestral. However, the nervous system of echinoderms is one of the least understood of all major metazoan phyla. To gain insights into echinoderm neurogenesis, spatial and temporal gene expression data are essential. Then, functional data will enable the building of a detailed gene regulatory network for neurogenesis in the sea urchin that can be compared across metazoans to resolve questions about how nervous systems evolved., Results: Here, we analyze spatiotemporal gene expression during sea urchin neurogenesis for genes that have been shown to be neurogenic in one or more species. We report the expression of 21 genes expressed in areas of neurogenesis in the sea urchin embryo from blastula stage (just before neural progenitors begin their specification sequence) through pluteus larval stage (when much of the nervous system has been patterned). Among those 21 gene expression patterns, we report expression of 11 transcription factors and 2 axon guidance genes, each expressed in discrete domains in the neuroectoderm or in the endoderm. Most of these genes are expressed in and around the ciliary band. Some including the transcription factors Lv - mbx, Lv - dmrt, Lv - islet, and Lv - atbf1, the nuclear protein Lv - prohibitin , and the guidance molecule Lv - semaa are expressed in the endoderm where they are presumably involved in neurogenesis in the gut., Conclusions: This study builds a foundation to study how neurons are specified and evolved by analyzing spatial and temporal gene expression during neurogenesis in a basal deuterostome. With these expression patterns, we will be able to understand what genes are required for neural development in the sea urchin. These data can be used as a starting point to (1) build a spatial gene regulatory network for sea urchin neurogenesis, (2) identify how subtypes of neurons are specified, (3) perform comparative studies with the sea urchin, protostome, and vertebrate organisms.

Published

2019

213. Methods for transplantation of sea urchin blastomeres.

Author

George AN and McClay DR

Subjects

Animals, Embryo, Nonmammalian cytology, Morphogenesis physiology, Blastomeres cytology, Cell Transplantation methods, Sea Urchins cytology

Abstract

The stereotypic cleavage pattern of sea urchin embryos provides a platform for dissection of early lineage decisions that lead to cell diversification. Cell transplantation provides a useful tool for understanding those decisions. The methods described in this paper provide a guide for how to produce embryonic mosaics in which either one cell is transplanted or an entire tier of cells are transplanted to a host embryo. Although the results of such a cut and paste experiment can be documented in many ways, one of the most useful approaches follows progeny of the transplanted cell as they go through morphogenesis using time-lapse imaging. Methods for mounting and imaging the embryos are provided., (© 2019 Elsevier Inc. All rights reserved.)

Published

2019

214. Neurogenesis in the sea urchin embryo is initiated uniquely in three domains.

Author

McClay DR, Miranda E, and Feinberg SL

Subjects

Animals, Body Patterning genetics, Bone Morphogenetic Proteins metabolism, Cell Lineage genetics, Fibroblast Growth Factors metabolism, Gene Expression Regulation, Developmental, Gene Regulatory Networks, Lytechinus genetics, Models, Biological, Nodal Protein metabolism, Signal Transduction, Transcription Factors metabolism, Embryo, Nonmammalian metabolism, Lytechinus embryology, Lytechinus metabolism, Neurogenesis genetics

Abstract

Many marine larvae begin feeding within a day of fertilization, thus requiring rapid development of a nervous system to coordinate feeding activities. Here, we examine the patterning and specification of early neurogenesis in sea urchin embryos. Lineage analysis indicates that neurons arise locally in three regions of the embryo. Perturbation analyses showed that when patterning is disrupted, neurogenesis in the three regions is differentially affected, indicating distinct patterning requirements for each neural domain. Six transcription factors that function during proneural specification were identified and studied in detail. Perturbations of these proneural transcription factors showed that specification occurs differently in each neural domain prior to the Delta-Notch restriction signal. Though gene regulatory network state changes beyond the proneural restriction are largely unresolved, the data here show that the three neural regions already differ from each other significantly early in specification. Future studies that define the larval nervous system in the sea urchin must therefore separately characterize the three populations of neurons that enable the larva to feed, to navigate, and to move food particles through the gut., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

215. Identification of neural transcription factors required for the differentiation of three neuronal subtypes in the sea urchin embryo.

Author

Slota LA and McClay DR

Subjects

Achaete-Scute Complex Genome Region physiology, Animals, Intracellular Signaling Peptides and Proteins physiology, Lytechinus cytology, Membrane Proteins physiology, Morpholinos pharmacology, Neurons classification, RNA, Antisense pharmacology, Receptors, Notch physiology, Ectoderm cytology, Gene Expression Regulation, Developmental, Gene Regulatory Networks genetics, Lytechinus embryology, Nerve Tissue Proteins physiology, Neurogenesis physiology, Neurons cytology, Transcription Factors physiology

Abstract

Correct patterning of the nervous system is essential for an organism's survival and complex behavior. Embryologists have used the sea urchin as a model for decades, but our understanding of sea urchin nervous system patterning is incomplete. Previous histochemical studies identified multiple neurotransmitters in the pluteus larvae of several sea urchin species. However, little is known about how, where and when neural subtypes are differentially specified during development. Here, we examine the molecular mechanisms of neuronal subtype specification in 3 distinct neural subtypes in the Lytechinus variegatus larva. We show that these subtypes are specified through Delta/Notch signaling and identify a different transcription factor required for the development of each neural subtype. Our results show achaete-scute and neurogenin are proneural for the serotonergic neurons of the apical organ and cholinergic neurons of the ciliary band, respectively. We also show that orthopedia is not proneural but is necessary for the differentiation of the cholinergic/catecholaminergic postoral neurons. Interestingly, these transcription factors are used similarly during vertebrate neurogenesis. We believe this study is a starting point for building a neural gene regulatory network in the sea urchin and for finding conserved deuterostome neurogenic mechanisms., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

216. New insights from a high-resolution look at gastrulation in the sea urchin, Lytechinus variegatus.

Author

Martik ML and McClay DR

Subjects

Animals, Cell Movement genetics, Endoderm growth & development, Endoderm ultrastructure, Gastrula ultrastructure, Sea Urchins genetics, Sea Urchins ultrastructure, Gastrula growth & development, Gastrulation physiology, Morphogenesis physiology, Sea Urchins embryology

Abstract

Background: Gastrulation is a complex orchestration of movements by cells that are specified early in development. Until now, classical convergent extension was considered to be the main contributor to sea urchin archenteron extension, and the relative contributions of cell divisions were unknown. Active migration of cells along the axis of extension was also not considered as a major factor in invagination., Results: Cell transplantations plus live imaging were used to examine endoderm cell morphogenesis during gastrulation at high-resolution in the optically clear sea urchin embryo. The invagination sequence was imaged throughout gastrulation. One of the eight macromeres was replaced by a fluorescently labeled macromere at the 32 cell stage. At gastrulation those patches of fluorescent endoderm cell progeny initially about 4 cells wide, released a column of cells about 2 cells wide early in gastrulation and then often this column narrowed to one cell wide by the end of archenteron lengthening. The primary movement of the column of cells was in the direction of elongation of the archenteron with the narrowing (convergence) occurring as one of the two cells moved ahead of its neighbor. As the column narrowed, the labeled endoderm cells generally remained as a contiguous population of cells, rarely separated by intrusion of a lateral unlabeled cell. This longitudinal cell migration mechanism was assessed quantitatively and accounted for almost 90% of the elongation process. Much of the extension was the contribution of Veg2 endoderm with a minor contribution late in gastrulation by Veg1 endoderm cells. We also analyzed the contribution of cell divisions to elongation. Endoderm cells in Lytechinus variagatus were determined to go through approximately one cell doubling during gastrulation. That doubling occurs without a net increase in cell mass, but the question remained as to whether oriented divisions might contribute to archenteron elongation. We learned that indeed there was a biased orientation of cell divisions along the plane of archenteron elongation, but when the impact of that bias was analyzed quantitatively, it contributed a maximum 15% to the total elongation of the gut., Conclusions: The major driver of archenteron elongation in the sea urchin, Lytechinus variagatus, is directed movement of Veg2 endoderm cells as a narrowing column along the plane of elongation. The narrowing occurs as cells in the column converge as they migrate, so that the combination of migration and the angular convergence provide the major component of the lengthening. A minor contributor to elongation is oriented cell divisions that contribute to the lengthening but no more than about 15%., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

217. Contribution of hedgehog signaling to the establishment of left-right asymmetry in the sea urchin.

Author

Warner JF, Miranda EL, and McClay DR

Subjects

Animals, Body Patterning, Cilia physiology, Embryo, Nonmammalian metabolism, Gene Expression Profiling, Gene Expression Regulation, Developmental, In Situ Hybridization, Kinesins chemistry, Mesoderm metabolism, Nodal Protein physiology, Oligonucleotides, Antisense genetics, Polymerase Chain Reaction, Signal Transduction, Transforming Growth Factor beta metabolism, Hedgehog Proteins physiology, Sea Urchins embryology, Sea Urchins physiology

Abstract

Most bilaterians exhibit a left-right asymmetric distribution of their internal organs. The sea urchin larva is notable in this regard since most adult structures are generated from left sided embryonic structures. The gene regulatory network governing this larval asymmetry is still a work in progress but involves several conserved signaling pathways including Nodal, and BMP. Here we provide a comprehensive analysis of Hedgehog signaling and it's contribution to left-right asymmetry. We report that Hh signaling plays a conserved role to regulate late asymmetric expression of Nodal and that this regulation occurs after Nodal breaks left-right symmetry in the mesoderm. Thus, while Hh functions to maintain late Nodal expression, the molecular asymmetry of the future coelomic pouches is locked in. Furthermore we report that cilia play a role only insofar as to transduce Hh signaling and do not have an independent effect on the asymmetry of the mesoderm. From this, we are able to construct a more complete regulatory network governing the establishment of left-right asymmetry in the sea urchin., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

218. Comparative Developmental Transcriptomics Reveals Rewiring of a Highly Conserved Gene Regulatory Network during a Major Life History Switch in the Sea Urchin Genus Heliocidaris.

Author

Israel JW, Martik ML, Byrne M, Raff EC, Raff RA, McClay DR, and Wray GA

Subjects

Animals, Cell Lineage, Evolution, Molecular, Feeding Behavior, Gastrointestinal Tract growth & development, Gene Expression Profiling, Larva growth & development, Nervous System growth & development, Phylogeny, Sea Urchins genetics, Sea Urchins metabolism, Selection, Genetic, Transcriptome, Gene Regulatory Networks, Sea Urchins growth & development

Abstract

The ecologically significant shift in developmental strategy from planktotrophic (feeding) to lecithotrophic (nonfeeding) development in the sea urchin genus Heliocidaris is one of the most comprehensively studied life history transitions in any animal. Although the evolution of lecithotrophy involved substantial changes to larval development and morphology, it is not known to what extent changes in gene expression underlie the developmental differences between species, nor do we understand how these changes evolved within the context of the well-defined gene regulatory network (GRN) underlying sea urchin development. To address these questions, we used RNA-seq to measure expression dynamics across development in three species: the lecithotroph Heliocidaris erythrogramma, the closely related planktotroph H. tuberculata, and an outgroup planktotroph Lytechinus variegatus. Using well-established statistical methods, we developed a novel framework for identifying, quantifying, and polarizing evolutionary changes in gene expression profiles across the transcriptome and within the GRN. We found that major changes in gene expression profiles were more numerous during the evolution of lecithotrophy than during the persistence of planktotrophy, and that genes with derived expression profiles in the lecithotroph displayed specific characteristics as a group that are consistent with the dramatically altered developmental program in this species. Compared to the transcriptome, changes in gene expression profiles within the GRN were even more pronounced in the lecithotroph. We found evidence for conservation and likely divergence of particular GRN regulatory interactions in the lecithotroph, as well as significant changes in the expression of genes with known roles in larval skeletogenesis. We further use coexpression analysis to identify genes of unknown function that may contribute to both conserved and derived developmental traits between species. Collectively, our results indicate that distinct evolutionary processes operate on gene expression during periods of life history conservation and periods of life history divergence, and that this contrast is even more pronounced within the GRN than across the transcriptome as a whole.

Published

2016

219. Developmental gene regulatory networks in sea urchins and what we can learn from them.

Author

Martik ML, Lyons DC, and McClay DR

Abstract

Sea urchin embryos begin zygotic transcription shortly after the egg is fertilized.  Throughout the cleavage stages a series of transcription factors are activated and, along with signaling through a number of pathways, at least 15 different cell types are specified by the beginning of gastrulation.  Experimentally, perturbation of contributing transcription factors, signals and receptors and their molecular consequences enabled the assembly of an extensive gene regulatory network model.  That effort, pioneered and led by Eric Davidson and his laboratory, with many additional insights provided by other laboratories, provided the sea urchin community with a valuable resource.  Here we describe the approaches used to enable the assembly of an advanced gene regulatory network model describing molecular diversification during early development.  We then provide examples to show how a relatively advanced authenticated network can be used as a tool for discovery of how diverse developmental mechanisms are controlled and work.

Published

2016

220. Sea Urchin Morphogenesis.

Author

McClay DR

Subjects

Animals, Gene Expression Regulation, Developmental, Gene Regulatory Networks, Morphogenesis physiology, Sea Urchins genetics, Sea Urchins growth & development

Abstract

In the sea urchin morphogenesis follows extensive molecular specification. The specification controls the many morphogenetic events and these, in turn, precede patterning steps that establish the larval body plan. To understand how the embryo is built it was necessary to understand those series of molecular steps. Here an example of the historical sequence of those discoveries is presented as it unfolded over the last 50 years, the years during which major progress in understanding development of many animals and plants was documented by CTDB. In sea urchin development a rich series of experimental studies first established many of the phenomenological components of skeletal morphogenesis and patterning without knowledge of the molecular components. The many discoveries of transcription factors, signals, and structural proteins that contribute to the shape of the endoskeleton of the sea urchin larva then followed as molecular tools became available. A number of transcription factors and signals were discovered that were necessary for specification, morphogenesis, and patterning. Perturbation of the transcription factors and signals provided the means for assembling models of the gene regulatory networks used for specification and controlled the subsequent morphogenetic events. The earlier experimental information informed perturbation experiments that asked how patterning worked. As a consequence it was learned that ectoderm provides a series of patterning signals to the skeletogenic cells and as a consequence the skeletogenic cells secrete a highly patterned skeleton based on their ability to genotypically decode the localized reception of several signals. We still do not understand the complexity of the signals received by the skeletogenic cells, nor do we understand in detail how the genotypic information shapes the secreted skeletal biomineral, but the current knowledge at least outlines the sequence of events and provides a useful template for future discoveries., (© 2016 Elsevier Inc. All rights reserved.)

Published

2016

221. Deployment of a retinal determination gene network drives directed cell migration in the sea urchin embryo.

Author

Martik ML and McClay DR

Subjects

Animals, Gene Expression Regulation, Developmental, Cell Movement, Gene Regulatory Networks, Sea Urchins embryology, Stem Cells physiology

Abstract

Gene regulatory networks (GRNs) provide a systems-level orchestration of an organism's genome encoded anatomy. As biological networks are revealed, they continue to answer many questions including knowledge of how GRNs control morphogenetic movements and how GRNs evolve. The migration of the small micromeres to the coelomic pouches in the sea urchin embryo provides an exceptional model for understanding the genomic regulatory control of morphogenesis. An assay using the robust homing potential of these cells reveals a 'coherent feed-forward' transcriptional subcircuit composed of Pax6, Six3, Six1/2, Eya, and Dach1 that is responsible for the directed homing mechanism of these multipotent progenitors. The linkages of that circuit are strikingly similar to a circuit involved in retinal specification in Drosophila suggesting that systems-level tasks can be highly conserved even though the tasks drive unrelated processes in different animals.

Published

2015

222. Specification to biomineralization: following a single cell type as it constructs a skeleton.

Author

Lyons DC, Martik ML, Saunders LR, and McClay DR

Subjects

Animals, Calcium Carbonate metabolism, Gene Expression Regulation, Developmental physiology, Larva, Cytoskeleton physiology, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells physiology, Minerals metabolism, Sea Urchins cytology

Abstract

The sea urchin larva is shaped by a calcite endoskeleton. That skeleton is built by 64 primary mesenchyme cells (PMCs) in Lytechinus variegatus. The PMCs originate as micromeres due to an unequal fourth cleavage in the embryo. Micromeres are specified in a well-described molecular sequence and enter the blastocoel at a precise time using a classic epithelial-mesenchymal transition. To make the skeleton, the PMCs receive signaling inputs from the overlying ectoderm, which provides positional information as well as control of the growth of initial skeletal tri-radiates. The patterning of the skeleton is the result both of autonomous inputs from PMCs, including production of proteins that are included in the skeletal matrix, and of non-autonomous dynamic information from the ectoderm. Here, we summarize the wealth of information known about how a PMC contributes to the skeletal structure. The larval skeleton is a model for understanding how information encoded in DNA is translated into a three-dimensional crystalline structure., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Integrative and Comparative Biology. All rights reserved. For permissions please email: journals.permissions@oup.com.)

Published

2014

223. Delayed transition to new cell fates during cellular reprogramming.

Author

Cheng X, Lyons DC, Socolar JE, and McClay DR

Subjects

Animals, Bone and Bones embryology, Cell Differentiation, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Gastrula, Mesoderm cytology, Mesoderm embryology, Signal Transduction, Bone Development physiology, Cellular Reprogramming, Gastrulation physiology, Gene Expression Regulation, Developmental, Lytechinus embryology

Abstract

In many embryos specification toward one cell fate can be diverted to a different cell fate through a reprogramming process. Understanding how that process works will reveal insights into the developmental regulatory logic that emerged from evolution. In the sea urchin embryo, cells at gastrulation were found to reprogram and replace missing cell types after surgical dissections of the embryo. Non-skeletogenic mesoderm (NSM) cells reprogrammed to replace missing skeletogenic mesoderm cells and animal caps reprogrammed to replace all endomesoderm. In both cases evidence of reprogramming onset was first observed at the early gastrula stage, even if the cells to be replaced were removed earlier in development. Once started however, the reprogramming occurred with compressed gene expression dynamics. The NSM did not require early contact with the skeletogenic cells to reprogram, but the animal cap cells gained the ability to reprogram early in gastrulation only after extended contact with the vegetal halves prior to that time. If the entire vegetal half was removed at early gastrula, the animal caps reprogrammed and replaced the vegetal half endomesoderm. If the animal caps carried morpholinos to either hox11/13b or foxA (endomesoderm specification genes), the isolated animal caps failed to reprogram. Together these data reveal that the emergence of a reprogramming capability occurs at early gastrulation in the sea urchin embryo and requires activation of early specification components of the target tissues., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

224. Sub-circuits of a gene regulatory network control a developmental epithelial-mesenchymal transition.

Author

Saunders LR and McClay DR

Subjects

Animals, Body Patterning genetics, Cell Adhesion genetics, Cell Movement genetics, Cell Polarity genetics, Embryo, Nonmammalian, Lytechinus genetics, Snail Family Transcription Factors, Transcription Factors physiology, Twist-Related Protein 1 physiology, Epithelial-Mesenchymal Transition genetics, Gene Regulatory Networks physiology, Lytechinus embryology

Abstract

Epithelial-mesenchymal transition (EMT) is a fundamental cell state change that transforms epithelial to mesenchymal cells during embryonic development, adult tissue repair and cancer metastasis. EMT includes a complex series of intermediate cell state changes including remodeling of the basement membrane, apical constriction, epithelial de-adhesion, directed motility, loss of apical-basal polarity, and acquisition of mesenchymal adhesion and polarity. Transcriptional regulatory state changes must ultimately coordinate the timing and execution of these cell biological processes. A well-characterized gene regulatory network (GRN) in the sea urchin embryo was used to identify the transcription factors that control five distinct cell changes during EMT. Single transcription factors were perturbed and the consequences followed with in vivo time-lapse imaging or immunostaining assays. The data show that five different sub-circuits of the GRN control five distinct cell biological activities, each part of the complex EMT process. Thirteen transcription factors (TFs) expressed specifically in pre-EMT cells were required for EMT. Three TFs highest in the GRN specified and activated EMT (alx1, ets1, tbr) and the 10 TFs downstream of those (tel, erg, hex, tgif, snail, twist, foxn2/3, dri, foxb, foxo) were also required for EMT. No single TF functioned in all five sub-circuits, indicating that there is no EMT master regulator. Instead, the resulting sub-circuit topologies suggest EMT requires multiple simultaneous regulatory mechanisms: forward cascades, parallel inputs and positive-feedback lock downs. The interconnected and overlapping nature of the sub-circuits provides one explanation for the seamless orchestration by the embryo of cell state changes leading to successful EMT.

Published

2014

225. Branching out: origins of the sea urchin larval skeleton in development and evolution.

Author

McIntyre DC, Lyons DC, Martik M, and McClay DR

Subjects

Animals, Calcium Carbonate metabolism, Cell Movement physiology, Ectoderm metabolism, Fibroblast Growth Factors metabolism, Larva anatomy & histology, Vascular Endothelial Growth Factor A metabolism, Wnt Proteins metabolism, Biological Evolution, Body Patterning physiology, Models, Biological, Sea Urchins anatomy & histology, Sea Urchins embryology, Signal Transduction physiology

Abstract

It is a challenge to understand how the information encoded in DNA is used to build a three-dimensional structure. To explore how this works the assembly of a relatively simple skeleton has been examined at multiple control levels. The skeleton of the sea urchin embryo consists of a number of calcite rods produced by 64 skeletogenic cells. The ectoderm supplies spatial cues for patterning, essentially telling the skeletogenic cells where to position themselves and providing the factors for skeletal growth. Here, we describe the information known about how this works. First the ectoderm must be patterned so that the signaling cues are released from precise positions. The skeletogenic cells respond by initiating skeletogenesis immediately beneath two regions (one on the right and the other on the left side). Growth of the skeletal rods requires additional signaling from defined ectodermal locations, and the skeletogenic cells respond to produce a membrane-bound template in which the calcite crystal grows. Important in this process are three signals, fibroblast growth factor, vascular endothelial growth factor, and Wnt5. Each is necessary for explicit tasks in skeleton production., (Copyright © 2014 Wiley Periodicals, Inc.)

Published

2014

226. Hedgehog signaling requires motile cilia in the sea urchin.

Author

Warner JF, McCarthy AM, Morris RL, and McClay DR

Subjects

Animals, Evolution, Molecular, Hedgehog Proteins genetics, Microscopy, Electron, Scanning, Receptors, G-Protein-Coupled genetics, Receptors, G-Protein-Coupled metabolism, Cilia metabolism, Hedgehog Proteins metabolism, Sea Urchins genetics, Signal Transduction

Abstract

A relatively small number of signaling pathways govern the early patterning processes of metazoan development. The architectural changes over time to these signaling pathways offer unique insights into their evolution. In the case of Hedgehog (Hh) signaling, two very divergent mechanisms of pathway transduction have evolved. In vertebrates, signaling relies on trafficking of Hh pathway components to nonmotile specialized primary cilia. In contrast, protostomes do not use cilia of any kind for Hh signal transduction. How these divergent lineages adapted such dramatically different ways of activating the signaling pathway is an unanswered question. Here, we present evidence that in the sea urchin, a basal deuterostome, motile cilia are required for embryonic Hh signal transduction, and the Hh receptor Smoothened (Smo) localizes to cilia during active Hh signaling. This is the first evidence that Hh signaling requires motile cilia and the first case of an organism requiring cilia outside of the vertebrate lineage.

Published

2014

227. Perturbations to the hedgehog pathway in sea urchin embryos.

Author

Warner JF and McClay DR

Subjects

Animals, Embryo, Nonmammalian metabolism, Gene Knockdown Techniques, Microinjections, Morpholinos genetics, RNA, Messenger genetics, Sea Urchins genetics, Tissue Culture Techniques, Hedgehog Proteins physiology, Sea Urchins metabolism, Signal Transduction

Abstract

The Hedgehog pathway has been shown to be an important developmental signaling pathway in many organisms (Ingham and McMahon. Genes Dev 15:3059-3087, 2001). Recently that work has been extended to developing echinoderm embryos (Walton et al. Dev Biol 331(1):26-37, 2009). Here we describe several methods to perturb the Hedgehog signaling pathway in the sea urchin. These include microinjection of Morpholinos and mRNA constructs as well as treatments with small molecule inhibitors. Finally we provide simple methods for assaying Hedgehog phenotypes in the sea urchin embryo.

Published

2014

228. Short-range Wnt5 signaling initiates specification of sea urchin posterior ectoderm.

Author

McIntyre DC, Seay NW, Croce JC, and McClay DR

Subjects

Animals, Body Patterning genetics, Ectoderm embryology, Embryo, Nonmammalian metabolism, Endoderm embryology, Gastrulation, Gene Expression Regulation, Developmental, LIM-Homeodomain Proteins genetics, LIM-Homeodomain Proteins metabolism, Sea Urchins metabolism, Transcription Factors genetics, Transcription Factors metabolism, Transforming Growth Factor beta metabolism, Wnt Signaling Pathway, Body Patterning physiology, Ectoderm metabolism, Endoderm metabolism, Sea Urchins embryology, Wnt Proteins metabolism

Abstract

The border between the posterior ectoderm and the endoderm is a location where two germ layers meet and establish an enduring relationship that also later serves, in deuterostomes, as the anatomical site of the anus. In the sea urchin, a prototypic deuterostome, the ectoderm-endoderm boundary is established before gastrulation, and ectodermal cells at the boundary are thought to provide patterning inputs to the underlying mesenchyme. Here we show that a short-range Wnt5 signal from the endoderm actively patterns the adjacent boundary ectoderm. This signal activates a unique subcircuit of the ectoderm gene regulatory network, including the transcription factors IrxA, Nk1, Pax2/5/8 and Lim1, which are ultimately restricted to subregions of the border ectoderm (BE). Surprisingly, Nodal and BMP2/4, previously shown to be activators of ectodermal specification and the secondary embryonic axis, instead restrict the expression of these genes to subregions of the BE. A detailed examination showed that endodermal Wnt5 functions as a short-range signal that activates only a narrow band of ectodermal cells, even though all ectoderm is competent to receive the signal. Thus, cells in the BE integrate positive and negative signals from both the primary and secondary embryonic axes to correctly locate and specify the border ectoderm.

Published

2013

229. Morphogenesis in sea urchin embryos: linking cellular events to gene regulatory network states.

Author

Lyons DC, Kaltenbach SL, and McClay DR

Subjects

Animals, Sea Urchins genetics, Sea Urchins metabolism, Stem Cells cytology, Stem Cells metabolism, Cell Lineage, Gene Regulatory Networks, Osteogenesis, Sea Urchins embryology

Abstract

Gastrulation in the sea urchin begins with ingression of the primary mesenchyme cells (PMCs) at the vegetal pole of the embryo. After entering the blastocoel the PMCs migrate, form a syncitium, and synthesize the skeleton of the embryo. Several hours after the PMCs ingress the vegetal plate buckles to initiate invagination of the archenteron. That morphogenetic process occurs in several steps. The nonskeletogenic cells produce the initial inbending of the vegetal plate. Endoderm cells then rearrange and extend the length of the gut across the blastocoel to a target near the animal pole. Finally, cells that will form part of the midgut and hindgut are added to complete gastrulation. Later, the stomodeum invaginates from the oral ectoderm and fuses with the foregut to complete the archenteron. In advance of, and during these morphogenetic events, an increasingly complex input of transcription factors controls the specification and the cell biological events that conduct the gastrulation movements., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2012

230. Frizzled1/2/7 signaling directs β-catenin nuclearisation and initiates endoderm specification in macromeres during sea urchin embryogenesis.

Author

Lhomond G, McClay DR, Gache C, and Croce JC

Subjects

Animals, Embryo, Nonmammalian cytology, Embryo, Nonmammalian physiology, Endoderm cytology, Frizzled Receptors genetics, Gene Expression Regulation, Developmental, Paracentrotus metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, Stem Cells cytology, Stem Cells physiology, beta Catenin genetics, Embryonic Development physiology, Endoderm physiology, Frizzled Receptors metabolism, Paracentrotus cytology, Paracentrotus embryology, Signal Transduction physiology, beta Catenin metabolism

Abstract

In sea urchins, the nuclear accumulation of β-catenin in micromeres and macromeres at 4th and 5th cleavage activates the developmental gene regulatory circuits that specify all of the vegetal tissues (i.e. skeletogenic mesoderm, endoderm and non-skeletogenic mesoderm). Here, through the analysis of maternal Frizzled receptors as potential contributors to these processes, we found that, in Paracentrotus lividus, the receptor Frizzled1/2/7 is required by 5th cleavage for β-catenin nuclearisation selectively in macromere daughter cells. Perturbation analyses established further that Frizzled1/2/7 signaling is required subsequently for the specification of the endomesoderm and then the endoderm but not for that of the non-skeletogenic mesoderm, even though this cell type also originates from the endomesoderm lineage. Complementary analyses on Wnt6 showed that this maternal ligand is similarly required at 5th cleavage for the nuclear accumulation of β-catenin exclusively in the macromeres and for endoderm but not for non-skeletogenic mesoderm specification. In addition, Wnt6 misexpression reverses Frizzled1/2/7 downregulation-induced phenotypes. Thus, the results indicate that Wnt6 and Frizzled1/2/7 are likely to behave as the ligand-receptor pair responsible for initiating β-catenin nuclearisation in macromeres at 5th cleavage and that event is necessary for endoderm specification. They show also that β-catenin nuclearisation in micromeres and macromeres takes place through a different mechanism, and that non-skeletogenic mesoderm specification occurs independently of the nuclear accumulation of β-catenin in macromeres at the 5th cleavage. Evolutionarily, this analysis outlines further the conserved involvement of the Frizzled1/2/7 subfamily, but not of specific Wnts, in the activation of canonical Wnt signaling during early animal development.

Published

2012

231. Left-right asymmetry in the sea urchin embryo: BMP and the asymmetrical origins of the adult.

Author

Warner JF, Lyons DC, and McClay DR

Subjects

Animals, Sea Urchins metabolism, Body Patterning physiology, Bone Morphogenetic Proteins metabolism, Embryo, Nonmammalian metabolism, Sea Urchins embryology

Abstract

Bilateral animals, including humans and most metazoans, are not perfectly symmetrical. Some internal structures are distributed asymmetrically to the right or left side. A conserved Nodal and BMP signaling system directs molecular pathways that impart the sidedness to those asymmetric structures. In the sea urchin embryo, one such asymmetrical structure, oddly enough, is the entire adult, which grows out of left sided structures produced in the larva. In a paper just published in PLOS Biology, BMP signaling is shown to be necessary early in larval development to initiate the asymmetric specification of one of those left-sided structures, called the left coelomic pouch. This study reports that BMP signaling activates a group of transcription factors asymmetrically in the left coelomic pouch only, which launch the pathway that eventually leads to the formation of the adult that emerges from the larva at metamorphosis., Competing Interests: The authors have declared that no competing interests exist.

Published

2012

232. Wnt6 activates endoderm in the sea urchin gene regulatory network.

Author

Croce J, Range R, Wu SY, Miranda E, Lhomond G, Peng JC, Lepage T, and McClay DR

Subjects

Animals, Embryo, Nonmammalian physiology, Embryonic Induction, Gene Knockdown Techniques, Oocytes cytology, Oocytes physiology, Sea Urchins physiology, Signal Transduction physiology, Wnt Proteins genetics, Endoderm physiology, Gene Expression Regulation, Developmental, Gene Regulatory Networks, Sea Urchins anatomy & histology, Sea Urchins embryology, Sea Urchins genetics, Wnt Proteins metabolism

Abstract

In the sea urchin, entry of β-catenin into the nuclei of the vegetal cells at 4th and 5th cleavages is necessary for activation of the endomesoderm gene regulatory network. Beyond that, little is known about how the embryo uses maternal information to initiate specification. Here, experiments establish that of the three maternal Wnts in the egg, Wnt6 is necessary for activation of endodermal genes in the endomesoderm GRN. A small region of the vegetal cortex is shown to be necessary for activation of the endomesoderm GRN. If that cortical region of the egg is removed, addition of Wnt6 rescues endoderm. At a molecular level, the vegetal cortex region contains a localized concentration of Dishevelled (Dsh) protein, a transducer of the canonical Wnt pathway; however, Wnt6 mRNA is not similarly localized. Ectopic activation of the Wnt pathway, through the expression of an activated form of β-catenin, of a dominant-negative variant of GSK-3β or of Dsh itself, rescues endomesoderm specification in eggs depleted of the vegetal cortex. Knockdown experiments in whole embryos show that absence of Wnt6 produces embryos that lack endoderm, but those embryos continue to express a number of mesoderm markers. Thus, maternal Wnt6 plus a localized vegetal cortical molecule, possibly Dsh, is necessary for endoderm specification; this has been verified in two species of sea urchin. The data also show that Wnt6 is only one of what are likely to be multiple components that are necessary for activation of the entire endomesoderm gene regulatory network.

Published

2011

233. Evolutionary crossroads in developmental biology: sea urchins.

Author

McClay DR

Subjects

Animals, Gene Regulatory Networks, Sea Urchins genetics, Sea Urchins growth & development, Biological Evolution, Developmental Biology methods

Abstract

Embryos of the echinoderms, especially those of sea urchins and sea stars, have been studied as model organisms for over 100 years. The simplicity of their early development, and the ease of experimentally perturbing this development, provides an excellent platform for mechanistic studies of cell specification and morphogenesis. As a result, echinoderms have contributed significantly to our understanding of many developmental mechanisms, including those that govern the structure and design of gene regulatory networks, those that direct cell lineage specification, and those that regulate the dynamic morphogenetic events that shape the early embryo.

Published

2011

234. The control of foxN2/3 expression in sea urchin embryos and its function in the skeletogenic gene regulatory network.

Author

Rho HK and McClay DR

Subjects

Animals, Blastula, Embryo, Nonmammalian, Endoderm, Extracellular Matrix genetics, Giant Cells, Mesoderm, RNA, Messenger analysis, Sea Urchins, Calcification, Physiologic genetics, Gene Regulatory Networks physiology, Transcription Factors genetics

Abstract

Early development requires well-organized temporal and spatial regulation of transcription factors that are assembled into gene regulatory networks (GRNs). In the sea urchin, an endomesoderm GRN model explains much of the specification in the endoderm and mesoderm prior to gastrulation, yet some GRN connections remain incomplete. Here, we characterize FoxN2/3 in the primary mesenchyme cell (PMC) GRN state. Expression of foxN2/3 mRNA begins in micromeres at the hatched blastula stage and then is lost from micromeres at the mesenchyme blastula stage. foxN2/3 expression then shifts to the non-skeletogenic mesoderm and, later, to the endoderm. Here, we show that Pmar1, Ets1 and Tbr are necessary for activation of foxN2/3 in micromeres. The later endomesoderm expression of foxN2/3 is independent of the earlier expression of foxN2/3 in micromeres and is independent of signals from PMCs. FoxN2/3 is necessary for several steps in the formation of the larval skeleton. Early expression of genes for the skeletal matrix is dependent on FoxN2/3, but only until the mesenchyme blastula stage as foxN2/3 mRNA disappears from PMCs at that time and we assume that the protein is not abnormally long-lived. Knockdown of FoxN2/3 inhibits normal PMC ingression and foxN2/3 morphant PMCs do not organize in the blastocoel and fail to join the PMC syncytium. In addition, without FoxN2/3, the PMCs fail to repress the transfating of other mesodermal cells into the skeletogenic lineage. Thus, FoxN2/3 is necessary for normal ingression, for expression of several skeletal matrix genes, for preventing transfating and for fusion of the PMC syncytium.

Published

2011

235. Dynamics of Delta/Notch signaling on endomesoderm segregation in the sea urchin embryo.

Author

Croce JC and McClay DR

Subjects

Animals, Embryo, Nonmammalian, Endoderm metabolism, Intracellular Signaling Peptides and Proteins, Membrane Proteins genetics, Mesoderm metabolism, Microscopy, Fluorescence, Oligonucleotides, Antisense, Receptors, Notch genetics, Sea Urchins genetics, Signal Transduction genetics, Transcription Factors genetics, Transcription Factors physiology, Endoderm embryology, Membrane Proteins physiology, Mesoderm embryology, Receptors, Notch physiology, Sea Urchins embryology, Sea Urchins metabolism, Signal Transduction physiology

Abstract

Endomesoderm is the common progenitor of endoderm and mesoderm early in the development of many animals. In the sea urchin embryo, the Delta/Notch pathway is necessary for the diversification of this tissue, as are two early transcription factors, Gcm and FoxA, which are expressed in mesoderm and endoderm, respectively. Here, we provide a detailed lineage analysis of the cleavages leading to endomesoderm segregation, and examine the expression patterns and the regulatory relationships of three known regulators of this cell fate dichotomy in the context of the lineages. We observed that endomesoderm segregation first occurs at hatched blastula stage. Prior to this stage, Gcm and FoxA are co-expressed in the same cells, whereas at hatching these genes are detected in two distinct cell populations. Gcm remains expressed in the most vegetal endomesoderm descendant cells, while FoxA is downregulated in those cells and activated in the above neighboring cells. Initially, Delta is expressed exclusively in the micromeres, where it is necessary for the most vegetal endomesoderm cell descendants to express Gcm and become mesoderm. Our experiments show a requirement for a continuous Delta input for more than two cleavages (or about 2.5 hours) before Gcm expression continues in those cells independently of further Delta input. Thus, this study provides new insights into the timing mechanisms and the molecular dynamics of endomesoderm segregation during sea urchin embryogenesis and into the mode of action of the Delta/Notch pathway in mediating mesoderm fate.

Published

2010

236. Hedgehog signaling patterns mesoderm in the sea urchin.

Author

Walton KD, Warner J, Hertzler PH, and McClay DR

Subjects

Animals, Drosophila growth & development, Drosophila physiology, Drosophila Proteins physiology, Embryo, Nonmammalian physiology, Fetal Proteins genetics, Gene Amplification, Gene Expression Regulation, Hedgehog Proteins genetics, Mutagenesis, Nucleic Acid Hybridization, Polymerase Chain Reaction, RNA genetics, RNA isolation & purification, Recombination, Genetic, Sea Urchins genetics, Sea Urchins growth & development, Signal Transduction, T-Box Domain Proteins genetics, Fetal Proteins physiology, Hedgehog Proteins physiology, Mesoderm physiology, Sea Urchins embryology, T-Box Domain Proteins physiology

Abstract

The Hedgehog (Hh) signaling pathway is essential for patterning many structures in vertebrates including the nervous system, chordamesoderm, limb and endodermal organs. In the sea urchin, a basal deuterostome, Hh signaling is shown to participate in organizing the mesoderm. At gastrulation the Hh ligand is expressed by the endoderm downstream of the Brachyury and FoxA transcription factors in the endomesoderm gene regulatory network. The co-receptors Patched (Ptc) and Smoothened (Smo) are expressed by the neighboring skeletogenic and non-skeletogenic mesoderm. Perturbations of Hh, Ptc and Smo cause embryos to develop with skeletal defects and inappropriate non-skeletogenic mesoderm patterning, although initial specification of mesoderm occurs without detectable abnormalities. Perturbations of the pathway caused late defects in skeletogenesis and in the non-skeletogenic mesoderm, including altered numbers of pigment and blastocoelar cells, randomized left-right asymmetry of coelomic pouches, and disorganized circumesophageal muscle causing an inability to swallow. Together the data support the requirement of Hh signaling in patterning each of the mesoderm subtypes in the sea urchin embryo.

Published

2009

237. Blocking Dishevelled signaling in the noncanonical Wnt pathway in sea urchins disrupts endoderm formation and spiculogenesis, but not secondary mesoderm formation.

Author

Byrum CA, Xu R, Bince JM, McClay DR, and Wikramanayake AH

Subjects

Adaptor Proteins, Signal Transducing metabolism, Animals, Body Patterning genetics, Dishevelled Proteins, Embryo, Nonmammalian, Endoderm metabolism, Gene Deletion, Mesoderm metabolism, Models, Biological, Phosphoproteins metabolism, Pigmentation genetics, Signal Transduction genetics, Signal Transduction physiology, Adaptor Proteins, Signal Transducing genetics, Endoderm embryology, Mesoderm embryology, Phosphoproteins genetics, Sea Urchins embryology, Sea Urchins genetics, Wnt Proteins physiology

Abstract

Dishevelled (Dsh) is a phosphoprotein key to beta-catenin dependent (canonical) and beta-catenin independent (noncanonical) Wnt signaling. Whereas canonical Wnt signaling has been intensively studied in sea urchin development, little is known about other Wnt pathways. To examine roles of these beta-catenin independent pathways in embryogenesis, we used Dsh-DEP, a deletion construct blocking planar cell polarity (PCP) and Wnt/Ca(2+) signaling. Embryos overexpressing Dsh-DEP failed to gastrulate or undergo skeletogenesis, but produced pigment cells. Although early mesodermal gene expression was largely unperturbed, embryos exhibited reduced expression of genes regulating endoderm specification and differentiation. Overexpressing activated beta-catenin failed to rescue Dsh-DEP embryos, indicating that Dsh-DEP blocks endoderm formation downstream of initial canonical Wnt signaling. Because Dsh-DEP-like constructs block PCP signaling in other metazoans, and disrupting RhoA or Fz 5/8 in echinoids blocks subsets of the Dsh-DEP phenotypes, our data suggest that noncanonical Wnt signaling is crucial for sea urchin endoderm formation and skeletogenesis., ((c) 2009 Wiley-Liss, Inc.)

Published

2009

238. Twist is an essential regulator of the skeletogenic gene regulatory network in the sea urchin embryo.

Author

Wu SY, Yang YP, and McClay DR

Subjects

Animals, Cell Transplantation methods, Cloning, Molecular, In Situ Hybridization, Oligodeoxyribonucleotides, Antisense pharmacology, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Embryo, Nonmammalian physiology, Gene Expression Regulation, Developmental, Sea Urchins embryology, Sea Urchins genetics, Twist-Related Protein 1 genetics

Abstract

Recent work on the sea urchin endomesoderm gene regulatory network (GRN) offers many opportunities to study the specification and differentiation of each cell type during early development at a mechanistic level. The mesoderm lineages consist of two cell populations, primary and secondary mesenchyme cells (PMCs and SMCs). The micromere-PMC GRN governs the development of the larval skeleton, which is the exclusive fate of PMCs, and SMCs diverge into four lineages, each with its own GRN state. Here we identify a sea urchin ortholog of the Twist transcription factor, and show that it plays an essential role in the PMC GRN and later is involved in SMC formation. Perturbations of Twist either by morpholino knockdown or by overexpression result in defects in progressive phases of PMC development, including specification, ingression/EMT, differentiation and skeletogenesis. Evidence is presented that Twist expression is required for the maintenance of the PMC specification state, and a reciprocal regulation between Alx1 and Twist offers stability for the subsequent processes, such as PMC differentiation and skeletogenesis. These data illustrate the significance of regulatory state maintenance and continuous progression during cell specification, and the dynamics of the sequential events that depend on those earlier regulatory states.

Published

2008

239. Evolution of the Wnt pathways.

Author

Croce JC and McClay DR

Subjects

Animals, Evolution, Molecular, Humans, Phylogeny, Wnt Proteins genetics, Signal Transduction physiology, Wnt Proteins metabolism

Abstract

Wnt proteins mediate the transduction of at least three major signaling pathways that play central roles in many early and late developmental decisions. They control diverse cellular behaviors, such as cell fate decisions, proliferation, and migration, and are involved in many important embryological events, including axis specification, gastrulation, and limb, heart, or neural development. The three major Wnt pathways are activated by ligands, the Wnts, which clearly belong to the same gene family. However, their signal is then mediated by three separate sets of extracellular, cytoplasmic, and nuclear components that are pathway-specific and that distinguish each of them. Homologs of the Wnt genes and of the Wnt pathways components have been discovered in many eukaryotic model systems and functional investigations have been carried out for most of them. This review extracts available data on the Wnt pathways, from the protist Dictyostelium discoideum to humans, and provides from an evolutionary prospective the overall molecular and functional conservation of the three Wnt pathways and their activators throughout the eukaryotic superkingdom.

Published

2008

240. Genomics and expression profiles of the Hedgehog and Notch signaling pathways in sea urchin development.

Author

Walton KD, Croce JC, Glenn TD, Wu SY, and McClay DR

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cloning, Molecular, DNA Primers, Evolution, Molecular, Gene Expression Regulation, Developmental, Hedgehog Proteins physiology, Molecular Sequence Data, Polymerase Chain Reaction, Receptors, Notch physiology, Sea Urchins embryology, Sea Urchins growth & development, Sequence Alignment, Sequence Homology, Amino Acid, Signal Transduction genetics, Embryo, Nonmammalian physiology, Gene Expression Profiling, Genomics, Hedgehog Proteins genetics, Receptors, Notch genetics, Sea Urchins genetics

Abstract

The Hedgehog (Hh) and Notch signal transduction pathways control a variety of developmental processes including cell fate choice, differentiation, proliferation, patterning and boundary formation. Because many components of these pathways are conserved, it was predicted and confirmed that pathway components are largely intact in the sea urchin genome. Spatial and temporal location of these pathways in the embryo, and their function in development offer added insight into their mechanistic contributions. Accordingly, all major components of both pathways were identified and annotated in the sea urchin Strongylocentrotus purpuratus genome and the embryonic expression of key components was explored. Relationships of the pathway components, and modifiers predicted from the annotation of S. purpuratus, were compared against cnidarians, arthropods, urochordates, and vertebrates. These analyses support the prediction that the pathways are highly conserved through metazoan evolution. Further, the location of these two pathways appears to be conserved among deuterostomes, and in the case of Notch at least, display similar capacities in endomesoderm gene regulatory networks. RNA expression profiles by quantitative PCR and RNA in situ hybridization reveal that Hedgehog is produced by the endoderm beginning just prior to invagination, and signals to the secondary mesenchyme-derived tissues at least until the pluteus larva stage. RNA in situ hybridization of Notch pathway members confirms that Notch functions sequentially in the vegetal-most secondary mesenchyme cells and later in the endoderm. Functional analyses in future studies will embed these pathways into the growing knowledge of gene regulatory networks that govern early specification and morphogenesis.

Published

2006

241. The genomic underpinnings of apoptosis in Strongylocentrotus purpuratus.

Author

Robertson AJ, Croce J, Carbonneau S, Voronina E, Miranda E, McClay DR, and Coffman JA

Subjects

Amino Acid Sequence, Animals, Caspases genetics, Cell Death, Consensus Sequence, Models, Biological, Molecular Sequence Data, Phylogeny, Sea Urchins classification, Sea Urchins cytology, Sea Urchins physiology, Sequence Alignment, Sequence Homology, Amino Acid, Apoptosis genetics, Genome, Sea Urchins genetics

Abstract

Programmed cell death through apoptosis is a pan-metazoan character involving intermolecular signaling networks that have undergone substantial lineage-specific evolution. A survey of apoptosis-related proteins encoded in the sea urchin genome provides insight into this evolution while revealing some interesting novelties, which we highlight here. First, in addition to a typical CARD-carrying Apaf-1 homologue, sea urchins have at least two novel Apaf-1-like proteins that are each linked to a death domain, suggesting that echinoderms have evolved unique apoptotic signaling pathways. Second, sea urchins have an unusually large number of caspases. While the set of effector caspases (caspases-3/7 and caspase-6) in sea urchins is similar to that found in other basal deuterostomes, signal-responsive initiator caspase subfamilies (caspases-8/10 and 9, which are respectively linked to DED and CARD adaptor domains) have undergone echinoderm-specific expansions. In addition, there are two groups of divergent caspases, one distantly related to the vertebrate interleukin converting enzyme (ICE)-like subfamily, and a large clan that does not cluster with any of the vertebrate caspases. Third, the complexity of proteins containing an anti-apoptotic BIR domain and of Bcl-2 family members approaches that of vertebrates, and is greater than that found in protostome model systems such as Drosophila or Caenorhabditis elegans. Finally, the presence of Death receptor homologues, previously known only in vertebrates, in both Strongylocentrotus purpuratus and Nematostella vectensis suggests that this family of apoptotic signaling proteins evolved early in animals and was subsequently lost in the nematode and arthropod lineage(s). Our results suggest that cell survival is contingent upon a diverse array of signals in sea urchins, more comparable in complexity to vertebrates than to arthropods or nematodes, but also with unique features that may relate to specific requirements imposed by the biphasic life cycle and/or immunological idiosyncrasies of this organism.

Published

2006

242. A genome-wide survey of the evolutionarily conserved Wnt pathways in the sea urchin Strongylocentrotus purpuratus.

Author

Croce JC, Wu SY, Byrum C, Xu R, Duloquin L, Wikramanayake AH, Gache C, and McClay DR

Subjects

Amino Acid Sequence, Animals, Conserved Sequence, Embryo, Nonmammalian physiology, Gene Expression Regulation, Developmental, Molecular Sequence Data, Phylogeny, Reverse Transcriptase Polymerase Chain Reaction, Sea Urchins classification, Sea Urchins embryology, Sequence Homology, Amino Acid, Genome, Sea Urchins genetics, Wnt Proteins genetics

Abstract

The Wnt pathways are evolutionarily well-conserved signal transduction pathways that are known to play important roles in all Metazoans investigated to date. Here, we examine the Wnt pathway genes and target genes present in the genome of the echinoderm Strongylocentrotus purpuratus. Analysis of the Wnt genes revealed that eleven of the thirteen reported Wnt subfamilies are represented in sea urchin, with the intriguing identification of a Wnt-A ortholog thought to be absent in deuterostomes. A phylogenetic study of the Frizzled proteins, the Wnt receptors, performed throughout the animal kingdom showed that not all Frizzled subfamilies were present in the metazoan common ancestor, e.g. Fz3/6 emerged later during evolution. Using sequence analysis, orthologs of the vast majority of the cellular machinery involved in transducing the three types of Wnt pathways were found in the sea urchin genome. Furthermore, of about one hundred target genes identified in other organisms, more than half have clear echinoderm orthologs. Thus, these analyses produce new inputs in the evolutionary history of the Wnt genes in an animal occupying a position that offers great insights into the basal properties of deuterostomes.

Published

2006

243. Lineage-specific expansions provide genomic complexity among sea urchin GTPases.

Author

Beane WS, Voronina E, Wessel GM, and McClay DR

Subjects

Animals, GTP Phosphohydrolases metabolism, Humans, Isoenzymes genetics, Isoenzymes metabolism, Multigene Family, Phylogeny, Protein Biosynthesis, Sea Urchins classification, GTP Phosphohydrolases genetics, Genome, Sea Urchins enzymology

Abstract

In every organism, GTP-binding proteins control many aspects of cell signaling. Here, we examine in silico several GTPase families from the Strongylocentrotus purpuratus genome: the monomeric Ras superfamily, the heterotrimeric G proteins, the dynamin superfamily, the SRP/SR family, and the "protein biosynthesis" translational GTPases. Identified were 174 GTPases, of which over 90% are expressed in the embryo as shown by tiling array and expressed sequence tag data. Phylogenomic comparisons restricted to Drosophila, Ciona, and humans (protostomes, urochordates, and vertebrates, respectively) revealed both common and unique elements in the expected composition of these families. Galpha and dynamin families contain vertebrate expansions, consistent with whole genome duplications, whereas SRP/SR and translational GTPases are highly conserved. Unexpectedly, Ras superfamily analyses revealed several large (5+) lineage-specific expansions in the sea urchin. For Rho, Rab, Arf, and Ras subfamilies, comparing total human gene numbers to the number of sea urchin genes with vertebrate orthologs suggests reduced genomic complexity in the sea urchin. However, gene duplications in the sea urchin increase overall numbers such that total sea urchin gene numbers approximate vertebrate gene numbers for each monomeric GTPase family. These findings suggest that lineage-specific expansions may be an important component of genomic evolution in signal transduction.

Published

2006

244. RhoA regulates initiation of invagination, but not convergent extension, during sea urchin gastrulation.

Author

Beane WS, Gross JM, and McClay DR

Subjects

Animals, Cloning, Molecular, Cytoskeleton metabolism, Extracellular Matrix metabolism, Fetal Proteins antagonists & inhibitors, Fetal Proteins physiology, Lytechinus genetics, Lytechinus physiology, Molecular Sequence Data, Sequence Analysis, Protein, T-Box Domain Proteins antagonists & inhibitors, T-Box Domain Proteins physiology, rhoA GTP-Binding Protein genetics, Gastrula physiology, Lytechinus embryology, rhoA GTP-Binding Protein physiology

Abstract

During gastrulation, the archenteron is formed using cell shape changes, cell rearrangements, filopodial extensions, and convergent extension movements to elongate and shape the nascent gut tube. How these events are coordinated remains unknown, although much has been learned from careful morphological examinations and molecular perturbations. This study reports that RhoA is necessary to trigger archenteron invagination in the sea urchin embryo. Inhibition of RhoA results in a failure to initiate invagination movements, while constitutively active RhoA induces precocious invagination of the archenteron, complete with the actin rearrangements and extracellular matrix secretions that normally accompany the onset of invagination. Although RhoA activity has been reported to control convergent extension movements in vertebrate embryos, experiments herein show that RhoA activity does not regulate convergent extension movements during sea urchin gastrulation. Instead, the results support the hypothesis that RhoA serves as a trigger to initiate invagination, and once initiation occurs, RhoA activity is no longer involved in subsequent gastrulation movements.

Published

2006

245. A Fringe-modified Notch signal affects specification of mesoderm and endoderm in the sea urchin embryo.

Author

Peterson RE and McClay DR

Subjects

Animals, Blotting, Northern, Blotting, Western, Cloning, Molecular, Computational Biology, Gene Expression Regulation, Developmental physiology, Membrane Proteins metabolism, N-Acetylglucosaminyltransferases genetics, Oligonucleotides, Antisense, Phylogeny, Receptors, Notch, Sequence Analysis, DNA, Cell Differentiation physiology, Endoderm physiology, Membrane Proteins physiology, Mesoderm physiology, N-Acetylglucosaminyltransferases metabolism, Sea Urchins embryology, Signal Transduction physiology

Abstract

Fringe proteins are O-fucose-specific beta-1,3 N-acetylglucosaminyltransferases that glycosylate the extracellular EGF repeats of Notch and enable Notch to be activated by the ligand Delta. In the sea urchin, signaling between Delta and Notch is known to be necessary for specification of secondary mesenchyme cells (SMCs). The Lytechinus variegatus Fringe homologue is expressed in both the signaling and receiving cells during this first Delta-Notch signal. Perturbation of Fringe expression through morpholino antisense oligonucleotide (MO) injection results in fewer SMCs but also causes decreased and delayed archenteron invagination. Partial endoderm specification occurs but expression of some endoderm genes is compromised. The data are consistent with a Fringe-requiring Notch signal as one upstream component of archenteron morphogenesis. Finally, Fringe perturbations result in more severe phenotypes than those previously reported for Notch dominant-negative (LvN(neg)) injections or reported here for Notch MO (NMO) injections. Injecting a combination of LvN(neg) and NMO results in a more severe phenotype than either treatment alone, and this combination phenocopies the fringe MO embryos. Taken together, the results show that Fringe is necessary both for maternal and zygotic Notch signals, and these Notch signals affect specification of mesoderm and endoderm.

Published

2005

246. LvGroucho and nuclear beta-catenin functionally compete for Tcf binding to influence activation of the endomesoderm gene regulatory network in the sea urchin embryo.

Author

Range RC, Venuti JM, and McClay DR

Subjects

Amino Acid Sequence, Animals, Basic Helix-Loop-Helix Transcription Factors, Conserved Sequence, DNA-Binding Proteins genetics, Drosophila classification, Drosophila genetics, Drosophila Proteins, Histone Deacetylase 1, Histone Deacetylases, Humans, Molecular Sequence Data, Phylogeny, Polymerase Chain Reaction, RNA, Messenger genetics, Repressor Proteins genetics, Sea Urchins classification, Sequence Alignment, Sequence Homology, Amino Acid, Transcription Factors metabolism, beta Catenin, Cytoskeletal Proteins physiology, DNA-Binding Proteins physiology, Embryo, Nonmammalian physiology, Endoderm physiology, Gene Expression Regulation, Developmental physiology, Mesoderm physiology, Repressor Proteins physiology, Sea Urchins embryology, Trans-Activators physiology

Abstract

In the sea urchin embryo, specification of the endomesoderm is accomplished by the activity of a network of regulatory genes in the vegetal hemisphere, called the endomesoderm gene regulatory network (GRN). The activation of this network is mediated primarily through the activity of the Wnt pathway, though details of pathway activation remain unclear. To gain further insight into control of endomesoderm GRN activation, we have identified a sea urchin homologue of the co-repressor Groucho (LvGroucho) that has been shown to antagonize beta-catenin/Tcf activation complexes during Wnt signaling in other systems. Groucho functions by recruiting the histone deacetylase Rpd3 to the DNA template via interaction with site-specific transcription factors, resulting in localized chromatin condensation and transcriptional silencing. Our results show that the LvGroucho protein localizes to all nuclei throughout embryonic development. Interaction assays demonstrate that LvGroucho interacts with Tcf via both the Q and the WD domains of the protein. LvGroucho interacts with Tcf to antagonize the expression of key endomesoderm regulatory genes. Assays demonstrate that LvGroucho and n beta-catenin functionally compete for binding to Tcf as a major mechanism by which the Tcf-control switch is regulated. Functional analysis of the N-terminal AES197 domain of LvGroucho shows that it is sufficient to recapitulate the function of full-length LvGroucho. This finding strongly supports the conclusion that the effects of LvGro overexpression are due primarily to its interactions with Tcf and not other Groucho interacting partners, since Tcf is the only protein present in the sea urchin known to interact with AES197. Because the Q domain is unable to bind Rpd3, it was expected to behave as a dominant negative LvGroucho. Unexpectedly, overexpression of the Q domain gave functional results similar to LvGroucho and the AES197 domain. This is the first evidence for an inherent repressive function for the Q domain alone. Together, our results indicate that LvGroucho functionally competes with beta-catenin for Tcf binding, and this competitive mechanism regulates one of the earliest steps in the initiation of the sea urchin endomesoderm GRN.

Published

2005

247. SpHnf6, a transcription factor that executes multiple functions in sea urchin embryogenesis.

Author

Otim O, Amore G, Minokawa T, McClay DR, and Davidson EH

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cell Differentiation, Cloning, Molecular, DNA, Complementary genetics, Gene Expression Regulation, Developmental, Gene Targeting, Mesoderm cytology, Models, Biological, Molecular Sequence Data, Oligonucleotides, Antisense genetics, Phenotype, RNA, Messenger genetics, RNA, Messenger metabolism, Sea Urchins genetics, Transcription Factors genetics, Sea Urchins embryology, Sea Urchins metabolism, Transcription Factors metabolism

Abstract

The Strongylocentrotus purpuratus hnf6 (Sphnf6) gene encodes a new member of the ONECUT family of transcription factors. The expression of hnf6 in the developing embryo is triphasic, and loss-of-function analysis shows that the Hnf6 protein is a transcription factor that has multiple distinct roles in sea urchin development. hnf6 is expressed maternally, and before gastrulation its transcripts are distributed globally. Early in development, its expression is required for the activation of PMC differentiation genes such as sm50, pm27, and msp130, but not for the activation of any known PMC regulatory genes, for example, alx, ets1, pmar1, or tbrain. Micromere transplantation experiments show that the gene is not involved in early micromere signaling. Early hnf6 expression is also required for expression of the mesodermal regulator gatac. The second known role of hnf6 is its participation after gastrulation in the oral ectoderm gene regulatory network (GRN), in which its expression is essential for the maintenance of the state of oral ectoderm specification. The third role is in the neurogenic ciliated band, which is foreshadowed exactly by a trapezoidal band of hnf6 expression at the border of the oral ectoderm and where it continues to be expressed through the end of embryogenesis. Neither oral ectoderm regulatory functions nor ciliated band formation occur normally in the absence of hnf6 expression.

Published

2004

248. Nuclear beta-catenin-dependent Wnt8 signaling in vegetal cells of the early sea urchin embryo regulates gastrulation and differentiation of endoderm and mesodermal cell lineages.

Author

Wikramanayake AH, Peterson R, Chen J, Huang L, Bince JM, McClay DR, and Klein WH

Subjects

Animals, Blotting, Northern, Cell Differentiation physiology, Cell Lineage physiology, Cell Nucleus metabolism, DNA Primers, Endoderm physiology, Fluorescent Antibody Technique, Gastrula metabolism, Gene Expression Profiling, In Situ Hybridization, Mesoderm physiology, Microinjections, Oligonucleotides, Antisense, Plasmids genetics, Reverse Transcriptase Polymerase Chain Reaction, Wnt Proteins, Zebrafish Proteins, beta Catenin, Cytoskeletal Proteins metabolism, Gene Expression Regulation, Developmental, Proteins metabolism, Sea Urchins embryology, Sea Urchins metabolism, Signal Transduction physiology, Trans-Activators metabolism

Abstract

The entry of beta-catenin into vegetal cell nuclei beginning at the 16-cell stage is one of the earliest known molecular asymmetries seen along the animal-vegetal axis in the sea urchin embryo. Nuclear beta-catenin activates a vegetal signaling cascade that mediates micromere specification and specification of the endomesoderm in the remaining cells of the vegetal half of the embryo. Only a few potential target genes of nuclear beta-catenin have been functionally analyzed in the sea urchin embryo. Here, we show that SpWnt8, a Wnt8 homolog from Strongylocentrotus purpuratus, is zygotically activated specifically in 16-cell-stage micromeres in a nuclear beta-catenin-dependent manner, and its expression remains restricted to the micromeres until the 60-cell stage. At the late 60-cell stage nuclear beta-catenin-dependent SpWnt8 expression expands to the veg2 cell tier. SpWnt8 is the only signaling molecule thus far identified with expression localized to the 16-60-cell stage micromeres and the veg2 tier. Overexpression of SpWnt8 by mRNA microinjection produced embryos with multiple invagination sites and showed that, consistent with its localization, SpWnt8 is a strong inducer of endoderm. Blocking SpWnt8 function using SpWnt8 morpholino antisense oligonucleotides produced embryos that formed micromeres that could transmit the early endomesoderm-inducing signal, but these cells failed to differentiate as primary mesenchyme cells. SpWnt8-morpholino embryos also did not form endoderm, or secondary mesenchyme-derived pigment and muscle cells, indicating a role for SpWnt8 in gastrulation and in the differentiation of endomesodermal lineages. These results establish SpWnt8 as a critical component of the endomesoderm regulatory network in the sea urchin embryo., (Copyright 2004 Wiley-Liss, Inc.)

Published

2004

249. Methods for embryo dissociation and analysis of cell adhesion.

Author

McClay DR

Subjects

Animals, Biological Assay instrumentation, Biological Assay methods, Cell Adhesion physiology, Cell Separation instrumentation, Embryo, Nonmammalian cytology, Female, Microdissection instrumentation, Microdissection methods, Models, Animal, Ovum cytology, Ovum growth & development, Sea Urchins cytology, Cell Separation methods, Embryo, Nonmammalian embryology, Sea Urchins embryology

Published

2004

250. Blastomere isolation and transplantation.

Author

Sweet H, Amemiya S, Ransick A, Minokawa T, McClay DR, Wikramanayake A, Kuraishi R, Kiyomoto M, Nishida H, and Henry J

Subjects

Animals, Blastomeres cytology, Blastomeres physiology, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Cell Separation instrumentation, Chordata, Nonvertebrate growth & development, Echinodermata growth & development, Embryo, Nonmammalian cytology, Female, Male, Microdissection instrumentation, Microdissection methods, Sea Urchins embryology, Sea Urchins growth & development, Tissue Transplantation instrumentation, Blastomeres transplantation, Cell Separation methods, Chordata, Nonvertebrate embryology, Echinodermata embryology, Embryo, Nonmammalian embryology, Tissue Transplantation methods

Published

2004