The Reaggregation of Dissociated Embryonic Sea Urchin Cells

Studies carried out on reaggregating sea urchin embryonic cellsreveal that reaggregating cells can give rise to normal pluteuslarvae by three developmental pathways: (i) from clusters, (ii)from chains of beads, and (iii) from a tissue culture phase.Experiments carried out on a mixture of cells from two differentspecies, Arbacia punctulata and Lytechinus pictus, demonstratethat reaggregation is species specific and that the sortingout of cells according to species occurs. Movement of cellswithin an aggregate is non-random and unidirectional. Electronmicroscope analysis of mixed aggregates of cells of the twospecies indicates that cells of the same species make initialcontact and adhere to one another by means of numerous microvilliand with the formation of an intercellular hyaline-like material.Cells of the two different species adhere, but never by meansof microvilli and no hyaline-like material can be detected onthe cell surfaces. The results indicate a role in reaggregationof an intercellular material, possibly an intercellular cement.     

Ultrastructure of bovine parotid glands

Bovine parotid glands exhibit outstanding structural differences when compared with those of non-ruminant mammals. The acini are tortuous, branched and lined with cells of different heights, imparting a scalloped appearance to acinar lumina. Numerous microvilli, ca. 1.5 μ in length, extend into the lumina and intercellular canaliculi. Intercellular canaliculi measure ca. 3 μ in diameter and interweave in close association with intercellular tissue spaces. Intercellular tissue spaces are separated from the extraacinar spaces across a basal lamina only, whereas junctional complexes guard canaliculi from direct continuity with tissue spaces and/or extraacinar spaces. Flattened cytoplasmic lamellae extend from adjacent acinar cells and loosely interdigitate with one another across the tissue spaces. Acinar cells contain more mitochondria and less granular endoplasmic reticulum than parotid glands of non-ruminant mammals. Two types of secretory material, in the form of inclusions which vary in size and electron density, are present in the acinar cells. Intercalated ducts connect acini with striated ducts which in turn, empty into collecting ducts located between gland lobules. In terms of frequency of “basal infoldings” and numbers of mitochondria, striated ducts of calf parotid glands are not as well developed as those of certain other salivary glands. Myoepithelial cells are most often present at junctions of acini and intercalated ducts where they may attach to both acinar and ductal epithelium. Nerve “terminals” were not observed on the epithelial side of basement membranes in relation to the secretory cells.     

Contact-independent polarization of the cell surface and cortex of free sea urchin blastomeres

In a normal, intact sea urchin embryo blastomeres are structurally polarized so that all microvilli and cortical "pigment granules" are situated at the apical surfaces facing the hyaline layer and are absent from basolateral surfaces facing adjacent blastomeres and the internal embryonic cavity. To test the roles of intercellular contacts and the hyaline layer in the process of establishing this blastomere polarity, these two factors were experimentally eliminated; sea urchin eggs of four species were denuded of the nascent hyaline layer soon after fertilization and then cultured in calcium-free artificial seawater to prevent subsequent intercellular adhesion and contact. Such free blastomeres divided normally and still developed polarized distributions of microvilli and pigment granules resembling those of the corresponding blastomeres in intact embryos. These results indicate that the process of polarization is intrinsic to individual blastomeres (self-polarization) and that neither intercellular contacts nor adhesion of microvilli to the hyaline layer is necessary. The precise temporal and spatial coincidence of the patterns of polarization and the division cycles further suggests that a mechanistic link is maintained among cell division, blastomere polarization, and probably also a heritable component of the animal-vegetal axis.     

The fine structure of Comanthus japonica (Echinodermata: Crinoidea) from zygote through early gastrula

The fine structure of the early embryo of Comanthus has been described by scanning and transmission electron microscopy at approximately 20-min intervals from zygote (20 min) through early gastrula (260 min). In normally developing (and presumably monospermic) embryos, some non-fertilizing sperm were invariably trapped in the perivitelline space; this suggests that there is an effective block to polyspermy at the level of the plasma membrane. No trace of a hyaline layer is encountered in the pervitelline space. At first cleavage, which begins unilaterally at the animal pole, the contractile ring filaments are rather thick (50–150 Å) in comparison to those known for other marine invertebrates. From first cleavage through early gastrula, the lateral surfaces of the blastomeres are broadly adherent, and there is an intercellular material, presumably an adhesive, in the intercellular space. The blastocoel first appears during the four-cell stage. From the eight-cell stage through the start of gastrulation, only one opening, the vegetal pore, connects the blastocoel with the perivitelline space. Gastrulation begins at the 50–100-cell stage, while the vegetal pore is still open, and a clearly defined blastula stage is bypassed. Gastrulation is by a novel process, which I have called holoblastic involution. At gastrulation the eight most vegetal blastomeres, which encircle the vegetal pore, shoot out erect, unbranched filopodia for many microns through the blastocoel. The filopodia adhere to the blastocoelic surfaces of the animal blastomeres and contract, pulling the vegetal blastomeres into the blastocoel. The migrated vegetal blastomeres adhere to one another, forming the entoderm in the vegetal region of the embryo; the remaining blastomeres become the ectoderm. Soon after the completion of cell migration, the entodermal blastomeres appear to cast off their contractile microappendages and adhesive membranes into the blastocoel.     

Structural and functional polarity of starfish blastomeres

The cortex of the blastomeres of Asterina pectinifera are structurally polarized so that some kinds of granules in the cortex, which can be stained vitally with Nile blue (Nile blue-positive granules, NBGs), and microvilli were distributed mainly in the apical region. The blastomeres always faced the adjoining blastomeres and blastocoel with the NBG-free, smooth region during embryogenesis. To confirm whether such blastomeres are functionally polarized, we rotated one of the blastomeres in the 2-cell-stage embryo so that it faced the other with the NBG-containing region. As a result, all embryos developed into twin or partitioned blastulae. This shows that the blastomeres are functionally polarized and have to orient the basal cortex toward the inner side of the embryo in order to be integrated into a blastula together with the others. The cortical polarity was formed and maintained even in blastomeres of dissociated embryos. In such blastomeres the cleavage furrows were formed along the axis of polarity. When the blastomeres began to adhere closely to each other at the 256-cell stage, only the NBG-free (basal) region acquired adhesiveness. These facts make it possible to infer why the correct apicobasal orientation of blastomeres is necessary for embryonic integration, without considering intercellular communication during the cleavage stage.     

小鼠胚胎致密化起始的调控机制

植入前小鼠胚胎的发育事件包括第一次卵裂、胚胎基因组激活、桑椹胚致密、囊胚形成。小鼠受精卵胚胎的致密化发生在8-细胞阶段晚期, 致密过程中, 胚胎卵裂球本身以及卵裂球之间发生了一系列的变化。这些变化包括卵裂球微绒毛以及胞质成分的极性化分布, 卵裂球之间形成特殊的胞间连接。致密化是哺乳动物胚胎发育过程中的第一个细胞分化事件, 即导致了内细胞团以及滋养外胚层的产生。植入后, 内细胞团将发育成为胚体, 滋养外胚层将发育成为胎盘等胚外组织。细胞粘附分子E-cadherin介导的胞间粘附起始了致密化。卵裂球发生粘附所需的组分在致密前已经存在, 但是直至8-细胞阶段晚期连接复合体才表现出明显的粘附活性。敲除E-cadherin基因, 发现母源性的E-cadherin足以介导致密。E-cadherin介导的胞间粘附是细胞粘附的第一步。文章综述了E-cadherin介导胞间粘附的具体过程以及蛋白激酶C(Protein kinase C, PKC)调控该过程的相关 机制。     

Surface specializations of Fundulus cells and their relation to cell movements during gastrulation

Cell movements in Fundulus blastoderms during gastrulation were studied utilizing time-lapse cinemicrography and electron microscopy. Time-lapse films reveal that cells of the enveloping layer undulate and sometimes separate briefly but remain together in a cohesive layer. During epiboly, the marginal enveloping layer cells move over the periblast as it expands over the yolk sphere. Movement occurs as a result of ruffled membrane activity of the free borders of the marginal cells. Deep blastomeres become increasingly active during blastula and gastrula stages. Lobopodia project from the blastomeres in blastulae and adhere to other cells in gastrulae, giving the cells traction for movement. Contact specializations are formed by the lateral adjacent plasma membranes of enveloping layer cells. An apical junction is characterized by an intercellular gap of 60–75 A. Below this contact, the plasma membranes are separated by 120 A or more. In mid-gastrulae, cytoplasmic fibrils occur adjacent to some apical junctions, and small desmosomes appear below the apical junction. Septate desmosomes also appear at this time. A junction with an intercellular gap of 60 A occurs between marginal enveloping layer cells and periblast. Contacts between deep blastomeres become numerous in gastrulae and consist of contacts at the crests of surface undulations, short areas of contact in which the plasma membranes are 60 or 120 A apart, and long regions characterized by a 200-A intercellular gap. Lobopodia contact other blastomeres only in gastrulae. These junctions contain a 200-A intercellular space. Some deep blastomeres are in contact with the tips of periblast microvilli. The mechanism of epiboly in Fundulus is discussed and reevaluated in terms of these observations. The enveloping layer is adherent to the margin of the periblast and moves over it as a coherent cellular sheet. Periblast epiboly involves a controlled flow of cytoplasm from the thicker periblast into the thinner yolk cytoplasmic layer with which it is continuous. Deep cells move by adhering to each other, to the inner surface of the enveloping layer, and to the periblast.     

FGF9/16/20 and Wnt-5α signals are involved in specification of secondary muscle fate in embryos of the ascidian, <Emphasis Type="Italic">Halocynthia roretzi</Emphasis>

The tail muscle cells of the ascidian tadpole larva originate from two different lineages, the B- (primary) and A- and b- (secondary) line blastomeres of the eight-cell stage embryo. The primary muscle cells assume muscle fate cell-autonomously with the involvement of a localized muscle determinant, macho-1. On the other hand, fate determination of secondary muscle cells is a non-cell-autonomous process that depends on cellular interactions. In this paper, we investigated the mechanisms underlying fate specification of secondary muscle cells in Halocynthia roretzi. We found that FGF and Wnt5 signals were required. In contrast, the Nodal signal, which is required for specification of A-line muscle cells in another ascidian, Ciona intestinalis, was not necessary for the formation of any secondary muscle cells in Halocynthia embryo. Therefore, Halocynthia and Ciona show distinctly different mechanisms for generation of the secondary lineages, despite the fact that embryogenesis appears very similar between these species. We also found that the mechanisms involved in specification of A- and b-line muscle cells were distinct in that the required timing of the FGF signal for the A-line muscle cells preceded that for the b-line. Moreover, the inducer blastomeres for specification of these two lineages were different. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Morphology of gametes in sea urchins from Peter The Great Bay,Sea of Japan

The fine structure of the gametes in six sea urchin species of the Sea of Japan was studied. The sperm in Strongylocentrotus nudus, S. intermedius, Echinocardium cordatum, Scaphechinus mirabilis, Sc. griseus and Echinarachnius parma are species-specific. The conical head and symmetrically disposed ring-shape mitochondrion are common to regular sea urchin sperm cells. S. nudus is characterized by the bulb-shaped head of the sperm; S. intermedius, by a bullet-shaped one. The sperm spearhead and small amount of post-acrosome material are common to irregular sea urchins; the sperm width: length ratio varies for different species, with the highest for Sc. mirabilis. The sperm of Sc. griseus is characterized by two lipid drops in the middle part of sperm. Asymmetrical mitochondrion disposal is usual for E. parma. Actin filaments are found in the postacrosome material in the sperm of heart-shaped sea urchins. The differences in the fine structure of sperm in cosmopolitan species Ech. cordatum inhabiting the Sea of Japan and coastal areas of the Northeast Atlantic may bear record to the complex existence of species Ech. cordatum. The fine structure of sperm is unique for each of the studied families, Strongylocentrotidae, Scutellidae, and Loveniidae. The eggs of all the species are characterized by vitelline and jelly-like membranes. The vitelline membrane is formed by cytoplasm protrusions; the area between them is filled with fibrillar material. The jelly-like membrane is formed by fibrillar material associated with apical parts of microvilli of the vitelline membrane. The irregular sea urchins Sc. griseus, Sc. mirabilis and E. parma are characterized by chromatophores situated in the jelly-like membrane, with the highest abundance in Sc. mirabilis.     

Vascular Plants Facilitated Bryophytes in a Grassland Experiment

In grassland communities vascular plants and bryophytes form two distinct layers. In order to understand the factors responsible for plant community structure, more information about interactions between these plant groups is needed. Often negative correlations between vascular plant and bryophyte covers have been reported, suggesting competition. Here we tested experimentally whether different grassland vascular plant species (Trifolium pratense, Festuca pratensis, Prunella vulgaris) had different influences on the cover of two bryophyte species (Rhytidiadelphus squarrosus, Brachythecium rutabulum). In a two-year garden pot experiment one bryophyte species and one vascular plant species were planted per pot. Bryophytes were planted at a constant density, vascular plants in four densities. The cover of both bryophyte species increased with increasing vascular plant cover, showing the facilitative effect of vascular plants through creating better microclimate, e.g., optimising temperature. Bryophyte responses to vascular plant species were species-specific. Festuca had significantly positive effects on both bryophyte species in the second year, and Trifolium on Brachythecium in both years, whereas Prunella had no significant effect on bryophytes. The facilitative effect of vascular plants was stronger at the second experimental year. In summary, the biotic effects between bryophytes and grassland vascular plants are species-specific and positive interactions are prevailing at low vascular plant densities.     

CELL JUNCTIONS IN OMMATIDIA OF LIMULUS

The intercellular relationships in the ommatidia of the lateral eye of Limulus have been investigated. The distal process of the eccentric cell gives origin to microvilli which interdigitate with the microvilli of the retinular cells. Therefore, both types of visual cells contribute to form the rhabdom and may have an analogous photoreceptor function. Quintuple-layered junctions are found within the rhabdom at the lines of demarcation between adjoining microvilli, whether the microvilli originate from a single retinular cell, from two adjacent retinular cells, or from a retinular cell and the eccentric cell. Furthermore, quintuple-layered junctions between the eccentric cell and the tips of the microvilli of the retinular cells occur at the boundary between the distal process and the rhabdom. These findings are interpreted to indicate that the rhabdom provides an extensive electrotonic junction relating retinular cells to one another and to the eccentric cell. Quintuple-layered junctions between glial and visual cells, as well as other structural features of the ommatidial cells, are also described.     

An electron microscopic study of the development of amphioxus,Branchiostoma belcheri tsingtauense: Cleavage

Development of the Asian amphioxus, Branchiostoma belcheri tsingtauense, was investigated by scanning and transmission electron microscopy (SEM and TEM) from the fertilized egg through the blastula stage. The fertilized egg is spherical (mean diameter 115 μm after SEM preparation) and is covered with microvilli. Throughout cleavage, the second polar body remains attached to the animal pole. The cleavage type in this species is essentially radial, as revealed by SEM observations. At the third cleavage or 8-cell stage, and at later stages, a size difference between blastomeres in the animal and the vegetal halves is clearly discernible, but less marked than that reported for the European amphioxus, B. lanceolatum. During the period spanning the third to the fifth cleavage (8–32-cell) stages, blastomeres are arranged in tiers along the animal-vegetal axis. After the sixth cleavage, or 64-cell stage, the tiered arrangement of the blastomeres is no longer seen. At the 4-cell stage, the blastocoel or cleavage cavity is seen as an intercellular space, opening to the outside. The blastocoel remains open at the animal and the vegetal poles in later stages. Throughout early development, the cytoplasm of the blastomeres includes yolk granules, mitochondria, Golgi complexes, and rough and smooth endoplasmic reticulum. Chromatin in the interphase nucleus is not clearly demonstrated, and chromosomes in the mitotic phase are also extremely difficult to detect. As yet, regional differences have not been found in distribution and organization of cytoplasmic components with respect to prospective ectodermal, mesodermal, and endodermal areas in the fertilized egg and later cleaved embryos, although there are possibly fewer yolk granules in the region of the animal pole than in the vegetal polar zone.     

Ultrastructure of myocardial widened Z bands and endocardial cells in two teleostean species

Summary Widened myocardial Z bands and endocardial cells are described in two teleostean species Cichlasoma meeki and Corydoras aeneus. Widened Z bands containing mainly amorphous and electron-dense material were seen in a number of myocardial cells. Further, similar material may occur in large amounts beneath the sarcolemma and at intercellular junctions. Occasionally, we observed continuity between the latter material and that in expanded Z bands.In C. meeki the ventricular endocardial layer consists of two structurally different cell types, whereas in C. aeneus only one cell type was seen. The functional aspects of widened Z bands are discussed.     

Smelling like resin: terpenoids account for species-specific cuticular profiles in Southeast-Asian stingless bees

Insects may be unique in having a cuticle with a species-specific chemical profile. In social insects, colony survival depends not only on species-specific but also on colony-specific cuticular compounds with hydrocarbons playing an important role in the communication systems of ants, termites, wasps and bees. We investigated inter- and intraspecific differences in the composition of compounds found on the body surface of seven paleotropical stingless bee species (Apidae: Meliponini) at two different sites in Borneo (Sabah, Malaysia). Besides hydrocarbons, the body surface of all seven stingless bee species comprised terpenoid compounds, a substance class that has not been reported for chemical profiles of any social insect so far. Moreover, the chemical profile of some species differed fundamentally in the composition of terpenoids with one group (e.g. sesquiterpenes) being present in one species, but missing in another. Chemical profiles of different colonies from the same species showed the same hydrocarbon- and terpenoid compounds over different regions, as tested for Tetragonilla collina and Tetragonula melanocephala. However, chemical profiles differed quantitatively between the different colonies especially in T. melanocephala. It is likely that the terpenoids are derived from plant resins because stingless bees are known to collect and use large amounts of resins for nest construction and defence, suggesting an environmental origin of the terpenoids in the chemical profile of paleotropical stingless bees.     

A reevaluation of the fertilizin hypothesis of sperm agglutination and the description of a novel form of sperm adhesion

The classical isoagglutination of sea urchin sperm by egg jelly is not an agglutination of cells, as proposed by the fertilizin-antifertilizin hypothesis. Sperm motility is required to obtain the isoagglutination of Strongylocentrotus purpuratus sperm, and the sperm do not adhere to each other in the isoagglutination clusters, which cannot be fixed for microscopy and which disperse rapidly into individual cells when sperm motility is inhibited. These observations suggest that isoagglutination is the swarming of freely moving sperm to a common focus and is quite distinct from the agglutination of sperm by known crosslinking agents (antibodies or lectins).A previously unrecognized form of sperm agglutination is described which follows induction of an acrosome reaction by egg jelly, ammonia, or the ionophore A23187 in a suspension of sea urchin or sand dollar sperm. The sperm form rosettes of up to 100 cells in which the newly extended acrosomal processes adhere to each other. Rosettes can form containing sperm of different species, in which the acrosomal processes adhere without species preference.As observed by transmission electron microscopy, the acrosomal process of Lytechinus pictus sperm consists of an acrosomal tubule covered by a sheath of extracellular material. Rosette formation results from attachment between the extracellular materials of adjacent sperm.Less frequently, the acrosomal process of one sperm adheres to the midpiece of another by fusion of the acrosomal tubule and midpiece plasma membranes.     

STRUCTURAL AND FUNCTIONAL HETEROGENEITY OF THE SURFACE OF RAT LEUKEMIA CELLS

Rat leukemia cells IRC 741 in suspension culture form single cytoplasmic protrusions by which the cells preferentially adhere to one another. The induction and/or maintenance of these protrusions is sensitive to changes in intercellular contact, pH, temperature, and nutritional conditions. The protrusions are stable, rigid structures which take part in intercellular adhesion but not in adhesion to substrata. Movement on substrata occurs by means of ruffling membranes formed on the main cell body. This asymmetry in cellular form and function is associated with specialized cell surface regions. Ultrastructurally, the cell surface over the protrusions lacks microvilli, and is covered with a 3,000–4,000-Å thick cell coat consisting of 200–500-Å electron-dense particles in an amorphous matrix. In contrast, the surface over the main cell body has microvilli and a 200-Å wide cell coat which lacks particles. The extracellular particles overlying the protrusions have electron-lucent cores, are protease- and pepsin-resistant, and do not stain with colloidal iron, while the matrix in which they are embedded is sensitive to proteolytic enzymes and contains acidic moieties. The negative surface charge density over the protrusions is higher than that over the main cell body, as shown by the orientation of the cells in an electric field. The unexpected observation that a region of higher charge density is one of increased intercellular adhesiveness might be explained, in part, by the rigidity of the protrusions and by the very small radius of curvature of the overlying extracellular particles. The protrusions permit the observation of discrete regions, differing in charge density, on the surface of living leukemia cells.     

Organization of the surface and adhesive properties of cleavage furrows in loach (Misgurnus fossilis) eggs

The experiments with chimerous embryos of teleost loach (Misgurnus fossilis) have shown that before furrows of the 1st cleavage appeared, the eggs were completely nonadhesive. At the stages of cleavages II-IV whole eggs were able to adhere and then make extended junctions in the blastodisc region. Adhesive domains of blastomeres were discovered by using carmine dye particles which attached primarily in the region of blastomere cleavage furrows. Scanning electron microscopy (SEM) showed that the cells in the depth of the cleavage furrows have domains with a smoother relief than their outer surface with numerous folds. Moreover, most adhesive flat lamellar formations (ruffles) with microvilli at their ends were discovered in the furrow region, particularly in its apical part (in the sites of intercellular contact formation and carmine absorption). Colchicine (5 X 10(-4) M) treatment affects the reorganization of the cleavage furrow surface, and the eggs, one by one, lose their ability to adhere, and then to attach dye particles. Mechanisms of formation of an adhesive contact between divided cells are discussed.     

Nucleolar cycle and localization of NORs in early embryos of Parascaris univalens

During early embryogenesis of the nematode Parascaris univalens (2n=2) the processes of chromatin diminution and segregation of the germ and somatic cell lineages take place simultaneously. In this study we analyzed the nucleolar cycle in early embryos, both in germinal and somatic blastomeres, by means of silver staining and antibodies against the nucleolar protein fibrillarin. We observed an identical nucleolar cycle in both types of blastomeres, hence, the chromatin diminution process has no effect on the nucleolar cycle of somatic blastomeres. We report the existence of outstanding differences between this cycle and those previously reported during early embryogenesis of other species. There is a true nucleolar cycle in early embryos that shows a peculiar nucleolar disorganization at prophase, and a preferential localization of prenucleolar bodies only on the euchromatic regions during nucleologenesis. Moreover, fibrillarin does not form a perichromosomal sheath in metaphase or anaphase holocentric chromosomes, probably owing to their special centromeric organization. The number and location of nucleolus organizer regions (NORs) in the chromosomal complement have been determined using silver impregnation, chromomycin A₃/distamycin A staining, and fluorescent in situ hybridization using an rDNA probe. There are only two NORs, one per chromosome, and these are lost in blastomeres after chromatin diminution. Moreover, the constant presence of two nucleoli in somatic blastomeres suggests that NORs are not affected during the fragmentation of euchromatic regions when this process occurs.