Robert G. Summers

An ultrastructural immunocytochemical localization of hyalin in the sea urchin egg

The fertilized sea urchin egg is invested by the hyaline layer, a thick extracellular coat which is necessary for normal development. On the basis of ultrastructural studies and the fact that hyalin is released during the time of the cortical reaction, it has been generally accepted that hyalin is derived from the cortical granules. However, this has never been proven definitely, and recently, it has been reported that hyalin is a membrane and/or cell surface protein. To determine where hyalin is stored, we carried out an ultrastructural immunocytochemical localization of hyalin in the unfertilized egg. Hyalin purified from isolated hyaline layers was used to immunize rabbits. Antisera so obtained were shown to be hyalin specific following absorption with a combination of sea urchin proteins. Immunocytochemical localizations were carried out on sections of Epon-embedded material using protein A-coated gold particles as an antibody marker. Our results demonstrate that, prior to fertilization, hyalin is stored in the homogeneous component of the cortical granule in Strongylocentrotus droebachiensis and Strongylocentrotus purpuratus. Labeling of small cortical vesicles in both unfertilized and fertilized eggs, suggests that these vesicles may contain a secondary reservoir of hyalin.

The effect of local anesthetics and ammonia on cortical granule-plasma membrane attachment in the sea urchin egg

Abstract The normal attachment of sea urchin egg cortical granules to the overlying plasma membrane can be disrupted by urethane, the tertiary amines procaine and tetracaine, and ammonia. Following such treatment, and contrary to the normal situation in mature eggs, the cortical granules can be dislodged from the egg cortex by centrifugal force. In some experiments, procaine treatment alone can disrupt cortical granule attachment enough to prevent exocytosis at fertilization. In such eggs, cortical granules can then be seen in the blastomeres. These observations suggest that a special attachment exists between the cortical granules and the plasma membrane and that if this attachment is sufficiently disrupted, cortical granule exocytosis is prevented. A new technique for the isolation of cortical granules has been developed based on the urethane sensitivity of their attachment to the plasma membrane.

CELLS ARE ADDED TO THE ARCHENTERON DURING AND FOLLOWING SECONDARY INVAGINATION IN THE SEA URCHIN LYTECHINUS VARIEGATUS

In the present investigation, nuclei of endodermal cells, primary and secondary mesenchyme cells (PMCs and SMCs), and small micromere descendants (SMDs) of the sea urchin Lytechinus variegatus were counted and mapped at five developmental stages, ranging from primary invagination to pluteus larva. The archenteron and its derivatives were measured three dimensionally with STERECON analytical software. For the first time SMC production is included in the kinetic analysis of archenteron formation. While the archenteron lumen doubled in length during secondary invagination, the number of archenteron cells increased by at least 38% (over 50% when SMCs that emigrated from the tip of the archenteron were included). The volume of the archenteron epithelial wall plus the volume of 17 new SMCs increased by 40% over the equivalent volumes at the end of primary invagination. Because secondary invagination involves the addition of archenteron cells and an increase in volume of the archenteron epithelium, we conclude that secondary invagination is not accomplished simply by the rearrangement and reshaping of the primary archenteron cells. Both archenteron cell number and wall volume continued to increase at the same rates from the end of secondary invagination until the 27-h prism stage, although the lumen lengthened more slowly. SMCs were also produced at a constant rate from primary invagination until the prism stage. Because the production of both endodermal and mesodermal cells continues until the late prism stage, we conclude that gastrulation (defined as the establishment of the germ layers) also extends into the late prism stage.

A Stereometric Analysis of Karyokinesis, Cytokinesis and Cell Arrangements during and following Fourth Cleavage Period in the Sea Urchin, Lytechinus variegatus

Fourth cleavage of the sea urchin embryo produces 16 blastomeres that are the starting point for analyses of cell lineages and bilateral symmetry. We used optical sectioning, scanning electron microscopy and analytical 3‐D reconstructions to obtain stereo images of patterns of karyokinesis and cell arrangements between 4th and 6th cleavage. At 4th cleavage, 8 mesomeres result from a variant, oblique cleavage of the animal quartet with the mesomeres arranged in a staggered, offset pattern and not a planar ring. This oblique, non‐radial cleavage pattern and polygonal packing of cells persists in the animal hemisphere throughout the cleavage period. Contrarily, at 4th cleavage, the 4 vegetal quartet nuclei migrate toward the vegetal pole during interphase; mitosis and cytokinesis are latitudinal and subequatorial. The 4 macromeres and 4 micromeres form before the animal quartet divides to produce a 12‐cell stage. Subsequently, macromeres and their derivatives divide synchronously and radially through 8th cleavage according to the Sachs‐Hertwig rule. At 5th cleavage, mesomeres and macromeres divide first; then the micromeres divide latitudinally and unequally to form the small and large micromeres. This temporal sequence produces 28‐and 32‐cell stages. At 6th cleavage, macromere and mesomere descendants divide synchronously before the 4 large micromeres divide parasynchronously to produce 56‐ and 60‐cell stages.

Characterization of Involution during Sea Urchin Gastrulation Using Two-Photon Excited Photorelease and Confocal Microscopy.

: Sea urchin embryos have served as a model system for the investigation of many concepts in developmental biology. Their gastrulation consists of two stages; primary invagination, where part of the epithelium invaginates into the blastocoel, and secondary invagination, where the archenteron elongates to completely traverse the blastocoel. Primary invagination involves proliferation of cells within the vegetal plate during primary invagination, but until recently, it was assumed that the larval gastrointestinal (GI) tract developed without further involution of epithelial cells. To investigate rigorously the contribution of epithelial cell involution during archenteron and GI tract development in the sea urchin, Lytechinus variegatus, we developed a new method for cell tracking based on two-photon excited photorelease of caged fluorophores. Single-cell embryos were injected with caged dye and two-photon excitation uncaging was employed to mark small groups of cells throughout gastrulation. Two-photon excitation allowed for noninvasive, three-dimensionally resolved uncaging inside living cells with minimal biological damage. Cellular involution into the archenteron was observed throughout primary and secondary invagination, and the larval intestine was formed by further involution of cells following secondary invagination, which is inconsistent with the traditional model of sea urchin gastrulation. Further, as two-photon excitation microscopy becomes accessible to many researchers, the novel techniques described here will be broadly applicable to development of other invertebrate and vertebrate embryos.

Applications of Confocal Microscopy to Studies of Sea Urchin Embryogenesis

The principles, advantages, and some of the general applications of confocal microscopy are presented by Wright et al. ([I] in this volume). The primary benefit of the confocal microscope derives from its ability to obtain optical sections from which out-of-focus information has been removed by the confocal aperture. The background rejection of the confocal aperture is only one consideration, however. Specimen preparation is an equally important factor that determines whether or not sections of sufficient resolution and contrast can be successfully obtained from deep within a thick specimen (see Cheng and Summers, 1990). Once confocal images of adequate quality are collected from the interior of an entire specimen or from a limited area of interest within that sample, the optical sections are stored individually in a digital form on the host computer. Subsequently, these data sets can be transformed into three-dimensional, stereoscopic, or extended-focus views that allow an entire specimen to be viewed in focus (Boyde, 1990).

Premature sperm incorporation into the primary oocyte of the polychaete Pectinaria: Male pronuclear formation and oocyte maturation

Abstract Immature oocytes of the annelid Pectinaria were prematurely fertilized while in the germinal vesicle stage. Fertilization was morphologically normal except for the formation of an enlarged fertilization cone which persisted even after sperm incorporation. However, at 30 min postinsemination, no signs of male pronuclear morphogenesis were detected. Ultrastructural data show that in the cytoplasm of a GV-stage oocyte the sperm nuclear envelope remains intact and the enclosed chromatin remains condensed. Prematurely fertilized eggs were then induced to undergo germinal vesicle breakdown (GVBD). Subsequently male pronuclear development occurred. Thus, the factors in the Pectinaria oocyte which are necessary for sperm transformation develop in the maturing cytoplasm and are dependent upon GVBD. Such prematurely fertilized oocytes fail to display the normal arrest of meiosis at Metaphase I, but instead progress directly to formation of the female pronucleus. Occurrences of normal first cleavage were observed suggesting that prematurely incorporated sperm can be recruited for participation in development.

Dynamics of Ubiquitin Pools in Developing Sea Urchin Embryos

The sea urchin embryo is a closed metabolic system in which embryogenesis is accompanied by significant protein degradation. We report results which are consistent with a function for the ubiquitinmediated proteolytic pathway in selective protein degradation during embryogenesis in this system. Quantitative solid‐ and solution‐phase immunochemical assays, employing anti‐ubiquitin antibodies, showed that unfertilized eggs of Strongylocentrotus purpuratus have a high content of unconjugated ubiquitin (ca. 8 × 108 molecules), and also contain abundant conjugates involving ubiquitin and maternal proteins. The absolute content of ubiquitin in the conjugated form increases about 13‐fold between fertilization and the pluteus larva stage; 90% or more of embryonic ubiquitin molecules are conjugated to embryonic proteins in hatched blastulae and later‐stage embryos. Qualitatively similar results were obtained with embryos of Lytechinus variegatus. The results of pulse‐labeling and immunoprecipitation experiments indicate that synthesis of ubiquitin in S. purpuratus is developmentally regulated, with an overall increase in synthetic rate of 12‐fold between fertilization and hatching. Regulation is likely to occur at the level of translation, since others have shown that levels of ubiquitin‐encoding mRNA remain virtually constant in echinoid embryos during this developmental interval. The sea urchin embryo should be a useful system for characterizing the role of ubiquitination in embryogenesis.

FORMATION OF THE CORTICAL CONCAVITY AT FERTILIZATION IN THE SEA URCHIN EGG

During the initial stages of fertilization envelope elevation in eggs of Strongylocentrotus pur puratus and S. droebachiensis a large concavity of the egg cortex was observed in the light microscope. This concavity corresponded in shape and size with the elevating fertilization envelope. However, after the vitelline layers of eggs were disrupted and the eggs inseminated, the concavity failed to develop although the eggs were fertilized and developed normally. We propose that the concavity is formed owing to increased hydrostatic pressure within the perivitelline space. To further support this hypothesis we measured total egg protein secreted during fertilization, and found that 98% was retained within the perivitelline space. Furthermore, 80% of the total protein was contributed by the hyaline layer. Presumably, colloidal osmotic pressure and/or hydration of fertilization product, trapped beneath the fertilization envelope, is responsible for increased hydrostatic pressure within the perivitelline space, and therefore promotes not only fertilization envelope elevation, but the cortical concavity as well.

Analysis of sea urchin egg cortical transformation in the absence of cortical granule exocytosis

A burst of endocytosis accompanying microvillar elongation follows cortical granule exocytosis in normal sea urchin development. By 5 min postfertilization the burst is over and a lower level of endocytosis ensues (constitutive phase). To determine whether microvillar elongation and initiation of endocytosis are necessary concommitants of cortical granule exocytosis we utilized Chases (1967, Ph.D. thesis, University of Washington, Seattle) high-hydrostatic pressure technique to block the latter and then examined developing eggs for endocytosis and microvillar elongation. To accomplish this, eggs were fertilized, after which hydrostatic pressure was quickly raised to 6000-7000 psi at the start of cortical granule exocytosis and maintained for 5 min. Only the cortical granules immediately surrounding the sperm penetration site were secreted (about 3% or less of the eggs total number of cortical granules). Blockage of major cortical granule exocytosis had the following consequences on surface events during first division: (1) The endocytosis burst normally associated with cortical granule exocytosis was effectively eliminated as was early microvillar elongation and elevation. Both occurred to a limited extent around the sperm penetration site which resulted in a highly localized surface transformation. (2) By 20 min after fertilization endocytosis began over the rest of the egg surface in the absence of any further cortical granule exocytosis. (3) Subsequently, during a 30-min period starting midway between fertilization and first cleavage microvilli more than doubled in length and endocytosis levels increased severalfold. These events brought about a complete surface transformation similar to that which normally occurs in early development but in the absence of cortical granule exocytosis. By first cleavage surfaces and cortices of high-pressure-treated and control eggs were nearly indistinguishable except for the presence of cortical granules in cortices of the former. Pressure-treated eggs cleaved normally and developed to larval forms overnight. The period of late surface transformation in high-pressure-treated Strongylocentrotus purpuratus eggs corresponds in timing and some of its characteristics to second phase microvillar elongation observed in normal development in this species and also in S. droebachiensis development. These observations suggest, therefore, that microvillar elongation and endocytosis are necessary membrane remodelling events which must occur for normal development even in the absence of membrane addition from the cortical granules.