Early events in sea urchin metamorphosis,description and analysis

The larval epithelium of the sea urchin, Lytechinus pictus, consists of squamous cells and bands of columnar epithelial cells bearing cilia. During metamorphosis this tissue undergoes a series of rapid, complex changes. Through the scanning and transmission electron microscope, we describe and analyse these changes. The changes can be divided into three steps. (1) The larval arms bend away from the left side of the larva, exposing the urchin rudiment. Cells which are identical to smooth muscle cells are in a position to bring about this bending. (2) The squamous epithelial cells assume a cuboidal shape. This change in shape results in the collapse of the larval epithelium onto the presumptive aboral surface. These cells possess a subapical band of microfilaments. The cellular shape change but not the bending of the arms is reversibly inhibited by Cytochalasin B. These observations suggest a mechanism for this change. (3) The former lining of the vestibule of the urchin rudiment comes to lie over the collapsed larval tissue and forms the adult epithelium. At this point, after only one hour, the larva has assumed the external shape of an adult sea urchin.     

Physiological and induced apoptosis in sea urchin larvae undergoing metamorphosis

Paracentrotus lividus embryos at the early pluteus stage undergo spontaneous apoptosis. Using a TUNEL (TdT-mediated dUTP Nick-End Labelling) assay on whole mount embryos, we showed that there was a different distribution of the apoptotic cells in different optical sections. Not more than 20% of cells in plutei were spontaneously apoptotic, as confirmed by the counts of dissociated ectoderm and intestine cells. Observation of larva stages closer to metamorphosis confirmed that apoptosis is a physiological event for the development of the adult. In particular, larvae at different developmental stages showed apoptotic cells in the oral and aboral arms, intestine, ciliary band and both apical and oral ganglia. Moreover, we found that the number of apoptotic cells decreased in later larva stages, possibly because in the organism approaching metamorphosis, a smaller number of cells needs to be eliminated. Furthermore, combined phorbol ester (TPA) and heat shock treatment enhanced apoptosis by increasing the number of cells involved in the phenomenon.     

Complete regulation of development throughout metamorphosis of sea urchin embryos devoid of macromeres

The developmental potential of the animal cap (consisting of eight mesomeres) recombined with micromeres or of micromere progeny was examined in sea urchin embryos. The embryos derived from the animal cap recombined with a quartet of micromeres or their descendants developed into four-armed plutei. After feeding, the larvae developed into eight-armed plutei. The left-right polarity of the larvae, recognized by the location of the echinus rudiment, was essentially normal, regardless of the orientation of animal-vegetal polarity in micromeres combining with the animal cap. The larvae had sufficient potential to metamorphose into complete juvenile sea urchins with five-fold radial symmetry. Cell lineage tracing experiments showed that: (i) macromere progeny were not required for formation of the typical pattern of primary mesenchyme cells derived exclusively from large micromeres; (ii) the progeny of large micromeres did not contribute to cells in the endodermal gut with three compartments of normal function; (iii) the presumptive ectoderm had the potential to differentiate into endodermal gut and mesodermal secondary mesenchyme cells, from which pigment cells likely differentiated; and (iv) behavior of the progeny of small micromeres was the same as that in normal embryos through the gastrula stage. These results indicate that the mesomeres respecify their fate under the inductive influence of micromeres so perfectly that complete juvenile sea urchins are produced.     

Cellular factor stimulating DNA synthesis in nuclei isolated from sea urchin embryos

DNA synthesis in isolated nuclei of morula-stage embryos of sea urchin was studied. Embryonic extracts of cleaving embryos (but not unfertilized eggs) stimulated DNA synthesis in the in vitro system. A stimulatory factor was identified which eluted at 0.52 M KCl during chromatography on DEAE-cellulose column. This factor was inactivated by heat treatment and trypsin digestion, and was resolved into three active peaks by gel filtration (Stokes radii of 6.3, 4.6, and 4.1 nm, respectively).     

Cellular and molecular mechanisms of negligible senescence: insight from the sea urchin

Sea urchins exhibit a very different life history from humans and short-lived model animals and therefore provide the opportunity to gain new insight into the complex process of aging. Sea urchins grow indeterminately, regenerate damaged appendages, and reproduce throughout their lifespan. Some species show no increase in mortality rate at advanced ages. Nevertheless, different species of sea urchins have very different reported lifespans ranging from 4 to more than 100?years, thus providing a unique model to investigate the molecular, cellular, and physiological mechanisms underlying both lifespan determination and negligible senescence. Studies to date have demonstrated maintenance of telomeres, maintenance of antioxidant and proteasome enzyme activities, and little accumulation of oxidative cellular damage with age in tissues of sea urchin species with different lifespans. Gene expression studies indicate that key cellular pathways involved in energy metabolism, protein homeostasis, and tissue regeneration are maintained with age. Taken together, these studies suggest that long-term maintenance of mechanisms that sustain tissue homeostasis and regenerative capacity is essential for indeterminate growth and negligible senescence, and a better understanding of these processes may suggest effective strategies to mitigate the degenerative decline in human tissues with age.     

Cellular biomarkers to elucidate global warming effects on Antarctic sea urchin Sterechinus neumayeri

Global warming is a reality and its effects have been widely studied. However, the consequences for marine invertebrates remain poorly understood. Thus, the present study proposed to evaluate the effect of elevated temperature on the innate immune system of Antarctic sea urchin Sterechinus neumayeri. Sea urchins were collected nearby Brazilian Antarctic Station ??Comandante Ferraz?? and exposed to 0 (control), 2 and 4°C for periods of 48?h, 2, 7 and 14?days. After the experimental periods, coelomic fluid was collected in order to perform the following analyses: coelomocytes differential counting, phagocytic response, adhesion and spreading coelomocytes assay, intranuclear iron crystalloid and ultra structural analysis of coelomocytes. The red sphere cell was considered a biomarker for heat stress, as they increased in acute stress. Besides that, a significant increase in phagocytic indexes was observed at 2°C coinciding with a significant increase of intranuclear iron crystalloid at the same temperature and same time period. Furthermore, significant alterations in cell adhesion and spreading were observed in elevated temperatures. The ultra structural analysis of coelomocytes showed no significant difference across treatments. This was the first time that innate immune response alterations were observed in response to elevated temperature in a Polar echinoid.     

Cellular control over spicule formation in sea urchin embryos: A structural approach

The spicules of the sea urchin embryo form in intracellular membrane-delineated compartments. Each spicule is composed of a single crystal of calcite and amorphous calcium carbonate. The latter transforms with time into calcite by overgrowth of the preexisting crystal. Relationships between the membrane surrounding the spiculogenic compartment and the spicule mineral phase were studied in the transmission electron microscope (TEM) using freeze-fracture. In all the replicas observed the spicules were tightly surrounded by the membrane. Furthermore, a variety of structures that are related to the material exchange process across the membrane were observed. The spiculogenic cells were separated from other cell types of the embryo, frozen, and freeze-dried on the TEM grids. The contents of electron-dense granules in the spiculogenic cells were shown by electron diffraction to be composed of amorphous calcium carbonate. These observations are consistent with the notion that the amorphous calcium carbonate-containing granules contain the precursor mineral phase for spicule formation and that the membrane surrounding the forming spicule is involved both in transport of material and in controlling spicule mineralization.     

Larval arm resorption proceeds concomitantly with programmed cell death during metamorphosis of the sea urchin Hemicentrotus pulcherrimus

Sea urchins are excellent models to elucidate metamorphic phenomena of echinoderms. However, little attention has been paid to the way that their organ resorption is accomplished by programmed cell death (PCD) and related cellular processes. We have used cytohistochemistry and transmission electron microscopy to study arm resorption in competent larvae of metamorphosing sea urchins, Hemicentrotus pulcherrimus, induced to metamorphose by L-glutamine treatment. The results show that: (1) columnar epithelial cells, which are constituents of the ciliary band, undergo PCD in an overlapping fashion with apoptosis and autophagic cell death; (2) squamous epithelial cells, which are distributed between the two arrays of the ciliary band, display a type of PCD distinct from that of columnar epithelial cells, i.e., a cytoplasmic type of non-lysosomal vacuolated cell death; (3) epithelial integrity is preserved even when PCD occurs in constituent cells of the epithelium; (4) secondary mesenchyme cells, probably blastocoelar cells, contribute to the elimination of dying epithelial cells; (5) nerve cells have a delayed initiation of PCD. Taken together, our data indicate that arm resorption in sea urchins proceeds concomitantly with various types of PCD followed by heterophagic elimination, but that epithelial organization is preserved during metamorphosis.This investigation was supported in part by a Keio University special grant-in-aid for innovative collaborative research projects.     

Cellular and biochemical responses to environmental and experimentally induced stress in sea urchin coelomocytes

Coelomocytes are considered to be immune effectors of sea urchins. Subpopulations of coelomocytes can be purified from a total cell suspension. The proportion of each cell type can vary not only among species, but also between individuals of the same species, according to their size and physiological conditions. We tested the hypothesis that coelomocytes play a role in defense mechanisms activated by adverse external conditions. Total coelomocytes from control and stressed (temperature, pollution, and injuries) sea urchins were analyzed for their expression of the 70 kDa heat shock protein (hsp70), a well recognized stress marker. Further analysis was performed by separation of coelomocytes into subpopulations by step gradients. We demonstrated that sea urchin coelomocytes respond to temperature shock and to polluted seawater by the upregulation of hsp70. Among coelomocytes certain cells, known as red spherula cells, showed a great increase in number in animals collected from polluted seawaters or subjected to "accidental" injury. The present study confirms the immunological function of sea urchin coelomocytes, as indicated by the upregulation of the hsp70 molecular marker, and suggests that sea urchin coelomocytes can be utilized as sensitive bio-indicators of environmental stress.     

NO/cGMP signaling and HSP90 activity represses metamorphosis in the sea urchin Lytechinus pictus.

Nitric oxide (NO) signaling repressively regulates metamorphosis in two solitary ascidians and a gastropod. We present evidence for a similar role in the sea urchin Lytechinus pictus. NO commonly signals via soluble guanylyl cyclase (sGC). Nitric oxide synthase (NOS) activity in some mammalian cells, including neurons, depends on the molecular chaperone heat shock protein 90 (HSP90); this may be so in echinoid larvae as well. Pluteus larvae containing juvenile rudiments were treated with either radicicol L- or D-nitroarginine-methyl-ester (L-NAME and D-NAME), or IH-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (ODQ), inhibitors of HSP90, NOS, and sGC, respectively. In all instances, drug treatment significantly increased the frequency of metamorphosis. SNAP, a NO donor, suppressed the inductive properties of L-NAME and biofilm, a natural inducer of metamorphosis. NADPH diaphorase histochemistry indicated NOS activity in cells in the lower lip of the larval mouth, the preoral hood, the gut, and in the tube feet of the echinus rudiment. Histochemical staining coincided with NOS immunostaining. Microsurgical removal of the oral hood or the pre-oral hood did not induce metamorphosis, but larvae lacking these structures retained the capacity to metamorphose in response to ODQ. We propose that the production of NO repressively regulates the initiation of metamorphosis and that a sensory response to environmental cues reduces the production of NO, and consequently cGMP, to initiate metamorphosis.     

Induction of metamorphosis in the sea urchin Holopneustes purpurascens by a metabolite complex from the algal host Delisea pulchra

Most benthic invertebrates have complex life cycles with planktonic larvae that return to the substratum to settle and metamorphose into a benthic stage. Although naturally produced chemical cues have long been thought to be important for the settlement or metamorphosis of invertebrate larvae, few ecologically relevant chemical cues have been clearly identified. The marine echinoid Holopneustes purpurascens has a complex life cycle, with a planktonic, nonfeeding dispersive larva that metamorphoses into a benthic stage that lives in the canopy of subtidal benthic algae such as the red alga Delisea pulchra and the kelp Ecklonia radiata. Recently recruited juveniles are found primarily on D. pulchra, and we hypothesized that this was in response to a chemical cue produced by this alga. Competent larvae metamorphosed in the presence of D. pulchra, or seawater surrounding this alga, but not in response to the presence of E. radiata or its extracts. A cue for metamorphosis was isolated and characterized from D. pulchra and found to be a water-soluble complex of the sugar floridoside and isethionic acid in a 1:1 molar ratio. The floridoside-isethionic acid complex also triggered settlement in H. purpurascens; however, this response was less specific than metamorphosis and was reversible. Larvae of H. purpurascens also metamorphosed in the presence of several other species of red, but not brown or green, algae from their habitat. Floridoside is found only in red algae, suggesting that the floridoside-isethionic acid complex may be acting as a cue for metamorphosis in other red algae as well as in D. pulchra.     

Acetylcholinesterase in sea urchin spermatozoa

Flagella contain the bulk of spermatozoan acetylcholinesterase. Brief sonication of sea urchin sperm suspended in Tris-buffered (pH 8.0), Ca, Mg-free artificial sea water (F-ASW) containing 10 mM ethylene diaminetetracetic acid, (EDTA) doubled the specific activity over that of the intact spermatozoa. Lipids were removed from the solubilized supernatant of the tail membrane fraction by ether extraction. Hydrolysis of acetylthiocholine in the presence of dithiobisnitrobenzoic acid (DTNB) was monitored spectrophotometrically at 412 nm by the Ellman procedure. The enzyme was purified by affinity chromatography on a Sepharose cyanogen bromide gel to which the cholinesterase inhibitor trimethyl (para-aminophenyl) ammonium chloride was coupled. The enzyme was eluted from the column with a discontinous NaCl gradient (0.1–0.5 M). The active fraction recovered at 0.35 M NaCl contained 0.007% of the initial total sperm cell protein with a 500-fold increase in specific activity. Twenty-four hr centrifugation on a 5–20% sucrose density gradient at 50,000g in a Beckman L5-75 centrifuge yielded peaks at 14.7 S and 9.1 S. In the presence of 1% Triton X-100, three peaks appeared: 23.3 S, 13.7 S, and 9.1 S. These sedimentation coefficients resemble those of the electroplax acetylcholinesterase (AChE) forms A₈ and A₄. Eserine completely inhibited the activity of the purified enzyme, which exhibits a substrate optimum at 4 mM acetylcholine. The activity is depressed by 75% at 10 mM ACh and by 90% at 25 mM. The Km was 2.1 × 10^?4 M. In the sperm cell the enzyme that terminates the action of intracellularly synthesized ACh may be involved in controlling ionophoric channels that regulate transmembrane transport of calcium.     

Laboratory on sea urchin fertilization

Since about 1880, the eggs and sperm of sea urchins have been used for the study of fertilization, the metabolic activation of development and gene regulatory mechanisms governing embryogenesis. Sea urchin gametes are a favorite material for observations of the process of fertilization in advanced high school, community college, and university biology laboratory courses. This article is a laboratory handout, designed for the student to follow in learning about fertilization. In addition to observations of sperm-egg interaction, simple experiments are described that demonstrate some mechanisms involved in the process. The hope is that by making simple observations of fertilization, the student will gain an appreciation for the fact that successive generations of higher organisms are bridged by the fusion of egg and sperm, two very different single cells.     

Relative importance of parental and larval nutrition on larval development and metamorphosis of the sea urchin Strongylocentrotus droebachiensis

We examined the relative importance of parental nutritional condition and larval food ration on the rates of development, growth and metamorphosis of larvae of Strongylocentrotus droebachiensis (Müller) in a laboratory experiment. Parents were reared for 22 months on either a high ration of kelp (Laminaria spp., 6 days week⁻¹) supplemented with mussel flesh (Mytilus spp., 1 day week⁻¹) (KM), or a low ration of kelp (1 day week⁻¹) (KL). Larvae were fed either a high ration (5000 cells ml⁻¹) or a low ration (500 cells ml⁻¹) of microalgae (Dunaliella tertiolecta). Larval food ration had a strong effect on the rates of development, growth, and metamorphosis, which were all significantly greater in larvae fed the high ration. Test diameter of settlers also was significantly greater in the high than the low ration. Parental nutritional condition had little or no effect on the rates of development and growth, and no effect on settler size. The rate of metamorphosis was significantly higher in larvae from the KM than the KL treatment in the high but not the low ration (where rates of metamorphosis were similar). Although parental condition generally had a small effect on larval development, our results suggest that when planktonic food is abundant, larvae of adults from nutritionally rich habitats (such as kelp beds) may metamorphose sooner than those of adults from nutritionally poor habitats (such as barrens).     

Ribosomal proteins of sea urchin eggs

Summary Ribosomal proteins from unfertilized eggs of three sea urchin species, Pseudocentrotus depressus, Hemicentrotus pulcherrimus, and Anthocidaris crassispina, were analyzed. Species-specific differences were observed in the profiles of large subunit proteins on two-dimensional slab gels, though the number of ribosomal proteins and the molecular weights of their counterparts were the same. The small subunit proteins revealed similarities in the electrophoretic profiles and in the phosphorylation patterns among these three species.