Charles A. Ettensohn

Cell lineage conversion in the sea urchin embryo

The mesoderm of the sea urchin embryo conventionally is divided into two populations of cells; the primary mesenchyme cells (PMCs), which produce the larval skeleton, and the secondary mesenchyme cells (SMCs), which differentiate into a variety of cell types but do not participate in skeletogenesis. In this study we examine the morphogenesis of embryos from which the PMCs have been removed microsurgically. We confirm the observation of Fukushi (1962) that embryos lacking PMCs form a complete skeleton, although in a delayed fashion. We demonstrate by microsurgical and cell marking experiments that the appearance of skeletogenic cells in such PMC-deficient embryos is due exclusively to the conversion of other cells to the PMC phenotype. Time-lapse video recordings of PMC-deficient embryos indicate that the converting cells are a subpopulation of late-ingressing SMCs. The conversion of these cells to the skeletogenic phenotype is accompanied by their de novo expression of cell surface determinants normally unique to PMCs, as shown by binding of wheat germ agglutinin and a PMC-specific monoclonal antibody. Cell transplantation and cell marking experiments have been carried out to determine the number of SMCs that convert when intermediate numbers of PMCs are present in the embryo. These experiments indicate that the number of converting SMCs is inversely proportional to the number of PMCs in the blastocoel. In addition, they show that PMCs and converted SMCs cooperate to produce a skeleton that is correct in both size and configuration. This regulatory system should shed light on the nature of cell-cell interactions that control cell differentiation and on the way in which evolutionary processes modify developmental programs.

Gastrulation in the sea urchin embryo is accompanied by the rearrangement of invaginating epithelial cells

The second phase of gastrulation in the sea urchin embryo, secondary invagination, involves a dramatic elongation of the tube-like gut rudiment. The cells in the wall of the rudiment, which are organized as a monolayered epithelium, change their arrangement during this process. The number of cells in the wall of the gut rudiment at any given level along its long axis decreases markedly as determined by light microscopy of serial cross sections and by scanning electron microscopy, an observation that can be accounted for only if some of the cells exchange nearest neighbors during secondary invagination. Transmission electron microscopy reveals that cell rearrangement takes place despite the continued presence of typical intercellular junctional complexes. In addition to undergoing rearrangement, the cells in the wall of the gut rudiment change their shape during secondary invagination, becoming more flattened. These data raise the possibility that mechanisms other than the contraction of the filopodia of the presumptive secondary mesenchyme cells contribute to the second phase of invagination in the sea urchin embryo. In addition, the observation that cells in the wall of the gut rudiment undergo rearrangement during secondary invagination provides additional evidence that epithelial sheets can exhibit fluid-like properties during morphogenesis.

Alx1, a member of the Cart1/Alx3/Alx4 subfamily of Paired-class homeodomain proteins, is an essential component of the gene network controlling skeletogenic fate specification in the sea urchin embryo

In the sea urchin embryo, the large micromeres and their progeny function as a critical signaling center and execute a complex morphogenetic program. We have identified a new and essential component of the gene network that controls large micromere specification, the homeodomain protein Alx1. Alx1 is expressed exclusively by cells of the large micromere lineage beginning in the first interphase after the large micromeres are born. Morpholino studies demonstrate that Alx1 is essential at an early stage of specification and controls downstream genes required for epithelial-mesenchymal transition and biomineralization. Expression of Alx1 is cell autonomous and regulated maternally through β-catenin and its downstream effector, Pmar1. Alx1 expression can be activated in other cell lineages at much later stages of development, however, through a regulative pathway of skeletogenesis that is responsive to cell signaling. The Alx1 protein is highly conserved among euechinoid sea urchins and is closely related to the Cart1/Alx3/Alx4 family of vertebrate homeodomain proteins. In vertebrates, these proteins regulate the formation of skeletal elements of the limbs, face and neck. Our findings suggest that the ancestral deuterostome had a population of biomineral-forming mesenchyme cells that expressed an Alx1-like protein.

MECHANISMS OF EPITHELIAL INVAGINATION

This review is concerned with the mechanical forces that cause epithelial sheets to invaginate during morphogenesis. Interest in this problem is currently increasing and a variety of models, each with a different emphasis, have been formulated to explain mechanical aspects of epithelial folding. A critical evaluation of the experimental evidence bearing on this problem leads to the following conclusions. (1) The most popular model of invagination, one based on microfilament-mediated cell shape change, should be re-examined, given the limitations of the experimental evidence usually offered in its support. Recent experiments with permeabilized epithelia offer a promising approach for confirming the validity of this model. (2) Current hypotheses based on disparities in the adhesive properties of epithelial cells are consistent with available data, but appear to be impossible to test directly at this time. (3) There is evidence that suggests that cell growth and division are involved in invagination during the branching morphogenesis of some epithelio-mesenchymal organs, but it has been shown that these processes are not involved in other cases. (4) Recent studies demonstrate that some epithelial invaginations are accompanied by movements of cells, both in the form of rearrangement (exchange of nearest neighbors) and involution (flow of surrounding cells into the invaginating region). (5) A general conclusion that may be drawn from the data now available is that several different mechanisms of epithelial folding operate during morphogenesis.

Differential stability of β-catenin along the animal-vegetal axis of the sea urchin embryo mediated by dishevelled

β-Catenin has a central role in the early axial patterning of metazoan embryos. In the sea urchin, β-catenin accumulates in the nuclei of vegetal blastomeres and controls endomesoderm specification. Here, we use in-vivo measurements of the half-life of fluorescently tagged β-catenin in specific blastomeres to demonstrate a gradient in β-catenin stability along the animal-vegetal axis during early cleavage. This gradient is dependent on GSK3β-mediated phosphorylation of β-catenin. Calculations show that the difference in β-catenin half-life at the animal and vegetal poles of the early embryo is sufficient to produce a difference of more than 100-fold in levels of the protein in less than 2 hours. We show that dishevelled (Dsh), a key signaling protein, is required for the stabilization of β-catenin in vegetal cells and provide evidence that Dsh undergoes a local activation in the vegetal region of the embryo. Finally, we report that GFP-tagged Dsh is targeted specifically to the vegetal cortex of the fertilized egg. During cleavage, Dsh-GFP is partitioned predominantly into vegetal blastomeres. An extensive mutational analysis of Dsh identifies several regions of the protein that are required for vegetal cortical targeting, including a phospholipid-binding motif near the N-terminus.

The regulation of primary mesenchyme cell patterning

The primary mesenchyme cells (PMCs) of the sea urchin embryo undergo a dramatic sequence of morphogenetic behaviors that includes migration, localization at specific sites within the embryo, and synthesis of the larval skeleton. To gain information about how these processes are regulated, PMC migration and patterning were analyzed in embryos with experimentally altered numbers of PMCs. PMC movements were followed by labeling the cells with a fluorescent dye, rhodamine B isothiocyanate, or with the PMC-specific monoclonal antibody 6a9. These methods show that individual PMCs have the capacity to join any position in the pattern, and rule out the possibility that PMC morphogenesis involves a sorting out of discrete subpopulations of cells to predetermined sites. All sites in the PMC pattern have the capacity to accept more cells than they normally do, and PMCs do not appear to compete with one another for preferred sites in the pattern. Even in embryos with 2-3 times the normal complement of PMCs, all these cells take part in spiculogenesis and the resultant skeleton is normal in size and configuration. Two special sites along the basal lamina (those corresponding to the positions of the PMC ventrolateral clusters) promote spicule elongation, an effect that is independent of the numbers of PMCs at these sites. These observations emphasize the role of the basal lamina, blastocoel matrix, and embryonic epithelium in regulating key aspects of PMC morphogenesis. The PMCs remain highly flexible in their ability to respond to patterning cues in the blastocoel, since postmigratory PMCs will repeat their patterning process if microinjected into the blastocoel of young recipient embryos.

Identification and developmental expression of new biomineralization proteins in the sea urchin Strongylocentrotus purpuratus.

Abstract. The endoskeleton of the sea urchin larva is a network of calcareous rods secreted by primary mesenchyme cells (PMCs). In this study, we identified seven new biomineralization-related proteins through an analysis of a large database of gene products expressed by PMCs. The proteins include three new spicule matrix proteins (SpSM29, SpSM32, and SpC-lectin), two proteins related to the PMC-specific cell surface glycoprotein MSP130 (MSP130-related-1 and -2), and two novel proteins (SpP16 and SpP19). The genes encoding these proteins are expressed specifically by cells of the large micromere-PMC lineage and are activated zygotically beginning at the blastula stage, prior to PMC ingression. Several of the mRNAs show regulated patterns of expression within the PMC syncytium that correlate with the pattern of skeletal rod growth. This work identifies new proteins that may regulate the process of biomineralization in this tractable model system.

Lessons from a gene regulatory network: echinoderm skeletogenesis provides insights into evolution, plasticity and morphogenesis.

Significant new insights have emerged from the analysis of a gene regulatory network (GRN) that underlies the development of the endoskeleton of the sea urchin embryo. Comparative studies have revealed ways in which this GRN has been modified (and conserved) during echinoderm evolution, and point to mechanisms associated with the evolution of a new cell lineage. The skeletogenic GRN has also recently been used to study the long-standing problem of developmental plasticity. Other recent findings have linked this transcriptional GRN to morphoregulatory proteins that control skeletal anatomy. These new studies highlight powerful new ways in which GRNs can be used to dissect development and the evolution of morphogenesis.

The genomic regulatory control of skeletal morphogenesis in the sea urchin.

A central challenge of developmental and evolutionary biology is to understand how anatomy is encoded in the genome. Elucidating the genetic mechanisms that control the development of specific anatomical features will require the analysis of model morphogenetic processes and an integration of biological information at genomic, cellular and tissue levels. The formation of the endoskeleton of the sea urchin embryo is a powerful experimental system for developing such an integrated view of the genomic regulatory control of morphogenesis. The dynamic cellular behaviors that underlie skeletogenesis are well understood and a complex transcriptional gene regulatory network (GRN) that underlies the specification of embryonic skeletogenic cells (primary mesenchyme cells, PMCs) has recently been elucidated. Here, we link the PMC specification GRN to genes that directly control skeletal morphogenesis. We identify new gene products that play a proximate role in skeletal morphogenesis and uncover transcriptional regulatory inputs into many of these genes. Our work extends the importance of the PMC GRN as a model developmental GRN and establishes a unique picture of the genomic regulatory control of a major morphogenetic process. Furthermore, because echinoderms exhibit diverse programs of skeletal development, the newly expanded sea urchin skeletogenic GRN will provide a foundation for comparative studies that explore the relationship between GRN evolution and morphological evolution.

Patterning the early sea urchin embryo.

Publisher Summary This chapter discusses the current understanding of mechanisms that underlie the patterning of the early sea urchin embryo. Its focus is on the partitioning of the cleavage and blastula stage embryo into distinct domains of gene expression and cell fate. Although many questions remain unanswered, recent studies have advanced the understanding of the early patterning of this embryo, and so a re-evaluation of the problem is warranted. The sea urchin embryo has a long and rich history as a model system for the analysis of patterning. The classical fate map of the cleavage stage embryo (Horstadius, 1973) has been modified in important ways by recent studies. Improved methods of cell labeling have been used to generate higher resolution fate maps and have made it possible to examine more advanced developmental stages. The most extensive fate mapping studies have been carried out with embryos of Lytechinus variegatus and Strongylocentrotus purpuratus.