The Cortical response to RhoA is regulated during mitosis. Annotation of cytoskeletal and motility proteins in the sea urchin genome assembly

Hoffman, Matthew P.

January 2008

Thesis advisor: David Burgess / This doctoral thesis addresses two central topics divided into separate chapters. In Chapter 1: The cortical response to RhoA is regulated during mitosis, experimental findings using sea urchin embryos are presented that demonstrate that the small GTPase RhoA participates in positive signaling for cell division and that this activity is negatively regulated prior to anaphase. In a second series of experiments, myosin phosphatase is shown to be a central negative regulator of myosin activity during the cell cycle through metaphase of mitosis and experimental findings support the conclusion that myosin phosphatase opposes RhoA signaling until anaphase onset. These experiments also reveal that myosin activation alone is insufficient to stimulate cortical contractions during S phase and during metaphase arrest following activation of the spindle checkpoint. In Chapter 2: Annotation of cytoskeletal and motility proteins in the sea urchin genome assembly, as part of a collaborative project, homologs of cytoskeletal genes and gene families were derived and annotated from the sea urchin genome assembly. In addition, phylogenetic analysis of multiple gene families is presented based on these findings. / Thesis (PhD) — Boston College, 2008. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

RhoA

Cytokinesis

Sea urchin

Cytoskeleton

Cell cycle

Annotation

Identification and Spatiotemporal Control of the Asymmetrical Membrane Cortex in Cleavage Stage Sea Urchin Embryos

Alford, Lea Marie

January 2009

Thesis advisor: David R. Burgess / Polarity established by the first cleavages in sea urchin embryos was investigated in this thesis revealing precocious embryonic polarity. Studies of embryonic polarity have focused on protostomes such as <italics>C. elegans</italics>, and those on deuterostomes have focused on later developmental stages. I find asymmetries in the sea urchin membrane cell cortex as early as the first division after fertilization as a result of new membrane addition in the cleavage furrow. Membrane domains and the polarity determinants Par6, aPKC, and Cdc42 are polarized to the apical, or free, cell surface, while the cell-cell contact site remains distinct. Using immunofluorescence, fluorescence recovery after photobleaching (FRAP), and specific inhibitor treatments, myosin filaments were identified as the major regulator of membrane cortex polarity. However, membrane domains and cortical polarity determinants are differentially regulated with respect to blastomere dissociation. These asymmetries are required for proper spindle alignment and cleavage plane determination and are responsible for polarized fluid phase endocytosis. The work in this thesis and future studies addressing the connection between the membrane cortex and myosin filaments has and will lead to a greater understanding of the maintenance of embryonic polarity in cleavage stage sea urchin embryos. / Thesis (PhD) — Boston College, 2009. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

cell polarity

membrane domain

myosin II

PAR proteins

sea urchin

The Newfoundland and Labrador sea urchin fishery : popular knowledge, identity and occupational attitudes within the new fishery /

Walsh, Kieran,

January 2004

Thesis (M.A.)--Memorial University of Newfoundland, 2005. / Bibliography: leaves 144-152.

The distance chemosensory behavior of the sea urchin Lytechinus variegatus / The distance chemosensory foraging behavior of the sea urchin Lytechinus variegatus

Pisut, Daniel P. (Daniel Peter)

09 January 2004

Many organisms that lack vision rely on chemical signals to glean information from their environment. Little is known, however, about the ability of sea urchins to detect and respond to such signals. This lack of understanding is especially surprising given the ecological impact of urchins in their respective communities. Regardless of geography, urchins exert strong top down control of plants, algae, and sedentary invertebrates, and these effects are especially evident when urchins, or urchin predators, are removed from an ecosystem. Facultative omnivorous species such as Lytechinus variegatus may greatly alter the abundances of other invertebrates in seagrass communities by preying on juvenile and adult bivalves as well as gastropod egg masses. These potential food resources, however, are patchily distributed within seagrass beds. To find such resources before other organisms can exploit them may require acute abilities to detect signals emanating from these patches. Experiments performed in this study demonstrated a consistent ability of L. variegatus to detect and orient to chemicals emanating from potential food resources over a distance of 1 m. Unlike what has been found in some other marine organisms, turbulent flow conditions did not negatively affect the ability of L. variegatus to find the source of this chemical cue. In fact, only the slowest flows hindered this ability; the bluff shape of the urchin formed a relatively large boundary layer at slow flows, preventing the delivery of chemical signals to the sensors. The relatively high success rates of L. variegatus in turbulent flows may allow it to effectively forage in areas where other organisms cannot. Thus, turbulence may provide a selective advantage for this animal, based on its comparative ability to detect and respond to signals in its environment.

Sensory biology

Behavior

Sea urchin

Lytechinus variegatus

Sea urchins Behavior

Iodine Uptake in Larvae of the Purple Sea Urchin (Strogylocentrotus purpuratus Stimpson 1857): Evidence for Peroxide Dependent Diffusion of Iodine in an Animal

Miller, Ashley E. M.

15 May 2013

Echinoids (sea urchins and sand dollars) undergo thyroid hormone (TH) regulated larval development and several species can endogenously synthesize these hormones. Although iodine is the essential component for TH synthesis, nothing is known about iodine uptake mechanisms in echinoids. This thesis primarily aimed to characterize integumental iodine uptake in larvae (echinoplutei) of the purple sea urchin Strongylocentrotus purpuratus. The two mechanisms considered were: iodine uptake via sodium dependent transport utilizing orthologs of vertebrate sodium iodide symporter (NIS) and apical iodide transporter (AIT) versus hydrogen peroxide dependent diffusion (PDD) of iodine. Pharmacology and radioiodine (125I) experiments characterized the effects of various compounds on echinoid iodine uptake. The results demonstrate that purple sea urchin echinoplutei acquire iodine from feeding on microalgae and through integumental transfer. Integumental transfer of iodine is inhibited by cyanide and is temperature dependent. Echinoplutei are not affected by perchlorate exposure demonstrating that NIS/AIT is not involved in S. purpuratus iodine uptake. NIS and AIT are both members of the Sodium Solute Carrier 5 (SSF5) transporter family and phylogenetic analysis of various vertebrate and invertebrate SLC5 members (obtained through BLAST searches) indicated that NIS-like transporters might be a vertebrate synapomorphy. Hydrogen peroxide exposure and oxidative stress induced an increase in iodine influx, whereas reducing agents and peroxidase inhibitors disrupted iodine uptake supporting a PDD-based iodine uptake model. In situ hybridization, immunohistochemistry and real time-PCR analysis demonstrate that the sea urchin dual oxidase 1 (Udx1) (an NADPH oxidase that produced hydrogen peroxide) is expressed throughout all stages of larval development in both S. purpuratus and Lytechinus variegatus specifically occurring in epithelial cells. These findings are the first data to demonstrate Udx1 presence and potential activity outside of fertilization and embryogenesis in echinoplutei. The expression patterns and pharmacological results make Udx1 an attractive candidate for involvement in integumental iodine transfer through PDD. These data provide the first evidence for PDD in an animal. The results also suggest that NIS/AIT may be a vertebrate synapomorphy and PDD of iodine across the integument may be widespread across organisms. Future characterization of iodine uptake mechanism in diverse taxa will address this issue. / Studies were funded by the Natural Sciences and Engineering REsearch Council (NSERC) to A.H. [grant number 400230], Equipment purchased with funding from the Caiadian Foundation for Innovation CFI and NSERC [grant number 400587] to A.H.

iodine

echinoids

dual oxidase

radio-iodine

sea urchin

integumental transfer

Short-Range Inter-Blastomere Signaling Specifies Ectodermal Fate and is Required for Skeletal Patterning in the Sea Urchin

McIntyre, Daniel Clifton

January 2012

<p>Sea urchin larvae possess a beautiful, intricately patterned, calcium-carbonate skeleton. Formation of this complex structure results from two independent processes within the developing embryo: specification of the mesenchymal cells that produce the skeletal rods, and patterning inputs from the ectoderm, which secretes signals directing the growth and shape of the skeleton. To understand patterning of the skeleton therefore, the specification events behind these two processes must be understood separately, and then connected in order to understand how ectoderm signaling directs skeletal growth. While the former processes of mesenchyme specification and mineralization are under study elsewhere, the means by which ectodermal cues directing skeletal growth are activated and localized is not known. Using molecular genetics, including gene knock downs and mis-expression, as well as microsurgical manipulations of early cleavage embryos, I show how a previously undescribed territory within the ectoderm, the border ectoderm (BE) is specified with short range signaling inputs. Then, experiments show that the BE provides signals that initiate, and contribute to the propagation of skeletogenesis. From this dataset, and from biological experiments I outline a model for how the BE patterns and contributes to the directed growth of the skeleton. I also discuss challenges to this model that need to be addressed in future research. In principle, the mechanism proposed herein depends on the integration of information from both the primary and secondary embryonic axes. It requires both short-range signaling by Wnt5 from the endoderm to establish the BE fate, and TGFß signaling from the oral and aboral ectoderm which subdivides the BE into four territories. These findings demonstrate that the short-range signaling cascade that subdivides the embryo into first mesoderm and then endoderm also specifies ectodermal fates. Ultimately, this research paves the way for understanding how the larval skeleton is patterned during embryogenesis and may provide a paradigm for understanding other, more complex, developmental problems.</p> / Dissertation

Developmental biology

Genetics

patterning

sea urchin

signaling

skeleton

Calcification in echinoderms: regeneration of the test of the sea urchin Strongylocentrotus droebachiensis.

Vocisano, Rinaldo Antonio.

January 1971

No description available.

Calcification.

Sea urchins.

Green sea urchin.

Echinodermata.

Regeneration (Biology)

Management of the red sea urchin fishery : a biological approach /

Ubeda, Armando J.

January 1900

Thesis (M.S.)--Oregon State University, 2004. / Typescript (photocopy). Includes bibliographical references (leaves 53-57). Also available online.

A viability study in terms of business opportunities for echinoderms (sea urchins) in South Africa.

Cilliers, Johannes S.

21 August 2012

M.Comm. / Du Plessis (1993:649) states that the most common reasons for business failure are the lack of understanding of the market and inferior products. The first point in Timmons' criteria list focuses on the industry and market. This is of utmost importance as no correct analysis of a new venture's viability can be done if there is not a full understanding by the potential investor of the exact market that he/she intends to venture into. Timmons does not highlight the importance of the product as such in his criteria list although inferior products are one of the most common reasons for failure. Timmons' fatal flaw aspect, point six, is however very important as it is an "abort checkpoint". If the venture has a fatal flaw, regardless of everything else being perfect, it could cancel the potential venture. This fatal flaw aspect is in line with Cartland's "subjective determination" criteria. Various probabilities are difficult or impossible to quantify accurately. If the entrepreneur is not totally convinced of the probability of success, it should be seen as a fatal flaw and the venture abandoned. Timmons' list of eight criteria is seen to incorporate the broadest and most appropriate checklist. Chapter three will concentrate on the industry, market and product in more detail, thus ensuring a thorough understanding of the market and product, avoiding one of the weaknesses in Timmons' criteria. In chapter four the business opportunity for echinoderms in South Africa will be evaluated against the eight factors as outlined especially by Timmons in this chapter.

Sea urchins -- South Africa

Sea urchin industry -- South Africa

Three-dimensional skeletal patterning during sea urchin embryogenesis

Piacentino, Michael Louis

13 February 2016

Multi-tissue pattern formation during development is a complex process in which extracellular communication events specify distinct cell types and regulate exquisite embryonic morphogenesis. The sea urchin embryo provides an excellent model for studying pattern formation due to relative genetic and morphological simplicity. The larval skeleton is secreted via biomineralization by the skeletogenic primary mesenchyme cells (PMCs). The PMCs undergo an epithelial-mesenchymal transition and migrate as individual cells within the blastocoel into stereotypic positions; this regulated PMC migration and positioning is required for normal skeletal patterning. Elegant PMC transplant experiments have demonstrated that PMC positioning, and thus skeletal patterning, is directed by ectodermal cues, and not by cues internal to the PMCs. In recent years, new efforts have been made to identify the ectodermal gene products that regulate skeletal development. The transcription factors Otp, Pax2/5/8 and Strim1, signaling by FGF, VEGF, and Wnt5a ligands have all been implicated in skeletal development in the sea urchin embryo; however, loss-of-function analysis for most of these gene products results in inhibition of skeletogenesis, suggesting that they regulate biomineralization and not PMC positioning and patterning. Notably, no skeletal patterning genes have previously been identified that pattern specific parts of the larval skeleton. This dissertation takes candidate-based and systems-level approaches to identify novel skeletal patterning genes that pattern distinct parts of the larval skeleton. We find that activation of the Alk4/5/7 receptor is required during gastrulation for anterior PMC positioning and skeletal patterning. We next test the function of the TGF-ß ligand Univin and find that it is necessary and sufficient for secondary skeletal patterning, indicating that Univin is a likely signaling ligand in anterior skeletal patterning. We also report a ventral accumulation of sulfated proteoglycans that requires function of the sulfate transporter, SLC26a2/7. This SLC-dependent sulfated proteoglycan accumulation is necessary and sufficient to attract PMCs to the ventral territory, and thereby pattern the ventral transverse skeletal elements. Finally, BMP5-8 function is required for left-side skeletal and serotonergic neuron development. Together, these studies reveal novel ectodermal genes that specifically regulate skeletal patterning across the anterior-posterior, dorsal-ventral, and left-right axes in Lytechinus variegatus embryos. / 2017-01-01T00:00:00Z

Developmental biology

Development

Embryology

Patterning

Sea urchin

Skeleton