A three-dimensional study of brain string vessels using celloidin sections stained with anti-collagen antibodies.

The purpose of this study was to explain the morphology and significance of string vessels in human brains. Brain slices (1.5 cm thick) were embedded in celloidin, sections cut at 100 microm and stained with antibody to collagen IV. A second component of the study was a 3-D rotational study for which we used sections stained with propidium iodide for cell nuclei and anti-collagen stain for blood vessel basement membranes. The materials consisted of brain from two infants at 28 and 35 weeks gestation, two term infants at 20 days and 3 months, one 5 years old, and 3 adults aged 25, 57, and 84 years. String vessels were counted in at least six fields of deep white matter using a 10x objective and the counts averaged and expressed as string vessels per cubic mm. The 3-D rotational study using confocal microscopy was designed to find nuclei in string vessels. The least number of string vessels were present in the premature infant. All others had comparably similar numbers of string vessels except the two term-born infants in whom there was a 3-5-fold increase. However, the two brains had other pathologic lesions, which could affect the counts. In normal brains, string vessels appear as a singe line of stain and usually connect two arterioles or capillaries. They can form loops and occasionally a string vessel may continue into a normal capillary. String vessels have rare nuclei. Our study indicates that string vessels are present in utero, increase in number and are present throughout life. Their exact nature remains unexplained. They apparently do not represent age-related acquired atrophy of capillaries because they are present at all ages and do not progressively increase with normal aging. This technique appears suitable for the study of large number of string vessels.

Microfilaments, cell shape changes, and the formation of primary mesenchyme in sea urchin embryos.

Primary mesenchyme formation in sea urchin embryos occurs when a subset of epithelial cells of the blastula move from the epithelial layer into the blastocoel. The role of microfilaments in producing the cell shape changes that characterize this process, referred to as ingression, was investigated in this study. f-Actin was localized by confocal microscopy using labeled phalloidin. The distribution of f-actin was observed before, during, and after ingression and was correlated with cellular movements. Prior to the onset of ingression, staining became intense in the apical region of putative primary mesenchyme and disappeared following the completion of mesenchyme formation. The apical end of these cells constricted coincidentally with the appearance of the intensified staining, indicating that f-actin may be involved in this constriction. In addition, papaverine, a smooth muscle cell relaxant that interferes with microfilament-based contraction, and that was shown in this study to inhibit cytokinesis, diminished apical constriction and delayed ingression. Despite this interference with apical constriction, the basal surface of ingressing cells protruded into the blastocoel. It is suggested that apical constriction, while not necessary for ingression, does contribute to the efficient production of mesenchyme and that protrusion of the basal surface results from changes that occur independent of apical constriction.

Organization of the ciliary basal apparatus in embryonic cells of the sea urchin, Lytechinus pictus.

The basal apparatus of embryonic cells of the sea urchin Lytechinus pictus was examined by transmission electron microscopy and compared with the basal apparatus of other metazoan cells. The basal apparatus in these cells is associated with a specialized region of the apical cell surface that is encircled by a ring of microvilli. The basal apparatus includes several features that are common to all ciliated cells, including a basal body, basal foot, basal foot cap, and striated rootlet. However, a component not seen in the basal apparatus of other species has been observed in these cells. This structure is continuous with the striated rootlet, and its ultrastructure indicates that it is composed of the same components as the rootlet. This structure extends from the junction of the basal body and striated rootlet to the cortical region that surrounds the basal body. Based on its morphology and position, this structure is referred to as a striated side-arm. The striated side-arm is always aligned in the plane of the basal foot. Thus, both of these structures extend from the basal body in the plane of the effective stroke. It is suggested that the striated side-arm serves to stabilize the basal apparatus against force exerted by the cilium.

Sea urchin primary mesenchyme cells: ingression occurs independent of microtubules.

The formation of primary mesenchyme cells in euechinoid sea urchin embryos involves the transformation of 32 epithelial cells into mesenchymal cells in a process referred to as ingression. The mechanism that drives this epithelial-mesenchymal transformation has yet to be identified. Previous studies (J. R. Gibbins, L. G. Tilney, and K. R. Porter, 1969, J. Cell Biol. 41, 201-226; L. G. Tilney and J. R. Gibbins, 1969, J. Cell Biol. 41, 227-250) implicated that microtubules are essential components for the normal development, including ingression, of the mesenchymal cells. In the present study I have reinvestigated the role of microtubules in ingression by using the microtubule-disrupting drugs colchicine and nocodazole, and the microtubule-stabilizing drug taxol. The effect of these drugs on microtubules was monitored by indirect immunofluorescence using monoclonal antibodies specific for alpha- and beta-tubulins. The microtubule array seen in control embryos disappeared in colchicine- and nocodazole-treated embryos, while it was enhanced in taxol-treated embryos. When premesenchyme blastulae of Strongylocentrotus purpuratus were treated with any of these reagents the primary mesenchyme cells ingressed on schedule and appeared to undergo cell-shape changes identical to those observed in untreated embryos. The conclusion of this study is that the mechanism of primary mesenchyme cell ingression does not include an essential role for microtubules; ingression occurs regardless of the presence or absence of microtubules.

Sea urchin primary mesenchyme cells: relation of cell polarity to the epithelial-mesenchymal transformation.

In euechinoid sea urchin embryos, a subset of epithelial cells in the wall of the blastula become pulsatile, elongate, lose connections with their neighboring cells, and move into the blastocoel to form the primary mesenchyme cells. The Golgi apparatus and microtubule organizing center (MTOC) are located at the apical end of these epithelial cells. We show that as primary mesenchyme cells begin to move into the blastocoel, the Golgi apparatus and MTOC move to a new position adjacent to the apical side of the nucleus. They do not move to a position between the nucleus and the leading (i.e., basal) end of the cell as they do in cultured fibroblasts undergoing directed migration. In addition, we have inhibited the movement of membranous vesicles to the cell surface by incubating embryos in the ionophore monensin. We have used antibodies to msp130, a primary mesenchyme cell surface-specific glycoprotein, to demonstrate that monensin inhibits the movement of msp130-containing vesicles to the cell surface. Despite the inhibition of membrane shuttling by monensin, primary mesenchyme cells ingress on schedule and display normal cell-shape changes. We draw two conclusions from our data. First, the cellular elongation that characterizes ingression is not due to the local insertion of membrane at the leading (basal) end of the cell. Second, ingression does not depend upon establishment of the same cell polarity required for fibroblasts to carry out directed cell migration.

Immunocytochemical evidence suggesting heterogeneity in the population of sea urchin egg cortical granules.

Unfertilized eggs of many species of animals contain cortical granules, which are specialized secretory granules that upon fertilization release their contents from the egg. The unfertilized eggs of the sea urchin, Strongylocentrotus purpuratus, contain cortical granules that all display an identical and elaborate internal morphology. It has been assumed that they all contain identical components. In this report we present immunocytochemical data which indicate that the cortical granule population of S. purpuratus eggs is heterogeneous. Two monoclonal antibodies are shown to react to the spiral lamellae region of approximately 20% of the cortical granules, implying that the contents of the reactive granules differ from the contents of the majority of the population. An egg protein of greater than 320 kDa is recognized by the antibody. These antibodies also stain a 130-kDa protein expressed on the surface of primary mesenchyme cells in later development. Both antibodies recognize a post-translational modification of this protein. This suggests that an antigenically similar epitope is present both on the 130-kDa primary mesenchyme cell-specific protein and in the cortical granules. To determine if the primary mesenchyme and cortical granule proteins are related, a fusion protein antibody specific for a region of the 130-kDa protein was used to stain unfertilized eggs. This antibody did not stain cortical granules. Thus, 20% of the cortical granules contain a molecule that has an epitope antigenically similar to the post-translational modification recognized in primary mesenchyme cells by the monoclonal antibodies.

Localization and expression of msp130, a primary mesenchyme lineage-specific cell surface protein in the sea urchin embryo.

In this report, we use a monoclonal antibody (B2C2) and antibodies against a fusion protein (Leaf et al. 1987) to characterize msp130, a cell surface protein specific to the primary mesenchyme cells of the sea urchin embryo. This protein first appears on the surface of these cells upon ingression into the blastocoel. Immunoelectronmicroscopy shows that msp130 is present in the trans side of the Golgi apparatus and on the extracellular surface of primary mesenchyme cells. Four precursor proteins to msp130 are identified and we show that B2C2 recognizes only the mature form of msp130. We demonstrate that msp130 contains N-linked carbohydrate groups and that the B2C2 epitope is sensitive to endoglycosidase F digestion. Evidence that msp130 is apparently a sulphated glycoprotein is presented. The recognition of the B2C2 epitope of msp130 is disrupted when embryos are cultured in sulphate-free sea water. In addition, two-dimensional immunoblots show that msp130 is an acidic protein that becomes substantially less acidic in the absence of sulphate. We also show that two other independently derived monoclonal antibodies, IG8 (McClay et al. 1983; McClay, Matranga & Wessel, 1985) and 1223 (Carson et al. 1985), recognize msp130, and suggest this protein to be a major cell surface antigen of primary mesenchyme cells.

Antibodies to a fusion protein identify a cDNA clone encoding msp130, a primary mesenchyme-specific cell surface protein of the sea urchin embryo.

In this report we identify a 130-kDa protein encoded by a sea urchin primary mesenchyme-specific cDNA clone, 18C6. The cDNA clone has been partially sequenced, and an open reading frame has been identified. A portion of this open reading frame has been expressed as a beta-galactosidase fusion protein in Escherichia coli, and antibodies to the fusion protein have been generated. These antibodies recognize a 130-kDa protein localized at the surface of primary mesenchyme cells and designated msp130. This is demonstrated to be the same 130-kDa protein recognized by the primary mesenchyme-specific monoclonal antibody B2C2, which recognizes a post-translational modification of the protein. RNA gel blots show that the transcript encoding msp130 is undetectable in egg RNA or 16-cell RNA but can be first detected in premesenchyme blastula embryos. The transcript accumulates significantly after primary mesenchyme cell ingression. Analysis of the expression of msp130 by indirect immunofluorescence staining of embryos and by immunoblots using fusion protein antibodies shows that the msp130 protein is first detectable soon after primary mesenchyme cell ingression.

Translation of maternal histone mRNAs in sea urchin embryos: a test of control by 5' cap methylation.

Recent results have demonstrated the occurrence of mRNA cap methylation in the sea urchin embryo following fertilization. It has been suggested that this methylation event is responsible for the translational activation of maternal histone mRNAs in these embryos. We have used aphidicolin, an effective inhibitor of both DNA synthesis and cap methylation in cleavage stage sea urchin embryos, to examine the relationship between cap methylation and translation. At 5 micrograms/ml, a dose which rapidly abolishes DNA replication and blocks cleavage, we note no effect on recruitment or translation of maternal alpha-subtype histone mRNAs. This suggests that a postfertilization cap methylation event is not critical to the process of regulation of the translation of stored alpha-subtype histone mRNAs.

Origin of a gene regulatory mechanism in the evolution of echinoderms.

A rich diversity of ancient sea urchin lineages survives to the present. These include several advanced orders as well as the cidaroids, which represent the group ancestral to all other sea urchins. Here we show that all advanced groups of sea urchins examined possess in their eggs a class of maternal messenger RNA (mRNA) encoded by the evolutionarily highly conserved alpha-subtype histone genes. The maternal histone mRNAs are unique in their time of accumulation in oogenesis, their localization in the egg nucleus and their delayed timing of translation after fertilization. Cidaroid sea urchins as well as other echinoderm classes, such as starfish and sea cucumbers, possess the genes but do not have maternal alpha-subtype histone mRNAs in their eggs. Thus, although all the echinoderms examined transcribe alpha-subtype histone genes during embryogenesis, the expression of these genes as maternal mRNAs is confined to advanced sea urchins. The fossil record allows us to pinpoint the evolution of this mode of expression of alpha-histone genes to the time of the splitting of advanced sea urchin lineages from the ancestral cidaroids in a radiation which occurred in a relatively brief interval of time approximately 190-200 Myr ago. The origin of a unique gene regulatory mechanism can thus be correlated with a set of macroevolutionary events.