Reconstruction of Starfish Eggs by Electric Cell Fusion: A New Method of Detect the Cytoplasmic Determinant for Archenteron Formation

A method of detecting cytoplasm carrying the determinant for archenteron formation in starfish was established. Animal egg fragments (AEFs) which had been severed from the vegetal halves were fused electrically into pairs with fragments prepared from various regions of immature oocytes. It has been previously shown that the vegetal halves are exclusively endowed with the ability to form the archenteron; AEFs alone develop into so-called permanent blastulae. Eggs thus reconstructed were allowed to develop in order to assess the presence of the determinant in the added fragments. Only AEFs fused with fragments from near the vegetal pole of the oocytes formed the archenteron and developed into bipinnariae and juveniles.
Comparison between the inner and outer (including cortex) cytoplasm of small vegetal fragment showed that the outer cytoplasm gave the reconstructed egg a greater ability to form an archenteron than the inner cytoplasm.     

Changes in the Pattern of Intercellular Junctions during Early Embryogenesis of the Starfish, Asterias amurensis

Changes in the cellular adhesion pattern during the early embryogenesis of a starfish Asterias amurensis were examined using carboxyfluorescein (CF) dye as a probe. CF that was injected into one of the blastomeres at the 2- or 4-cell stage was in all cases restricted to the progeny cells of the CF-labelled blastomere. With the advancement of gastrulation, however, the injected dye was distributed not only to the progeny of the labelled blastomere, but also to cells that originated from non-injected blastomeres. At the beginning of mesenchyme cell release, the injected dye spread uniformly to most cells comprising the embryo. When one of the blastomeres situated in the vegetal hemisphere of an 8-cell embryo was labelled, the resulting embryo showed more intense fluorescence in the cells surrounding the archenteron than in the ectodermal layer, suggesting that the cells in ectodermal layer became associated more intimately or earlier than those surrounding the archenteron. Likewise, in double embryos formed by combining two denuded eggs, in which one egg had been labelled with CF, dye spread was observed when the ectodermal layer began to expand. The intercellular spread of CF dye in starfish embryo suggests that there is a dramatic change in the cellular adhesion pattern during the course of gastrulation.     

Effect of protein phosphatase inhibitors on cleavage furrow formation in newt eggs: Inhibition of normal furrow formation and concomitant induction of furrow-like dents

The effects of three protein phosphatase inhibitors, okadaic acid, calyculin A and tautomycin, on the formation of cleavage furrows and the induction of furrow-like dents in the egg of the newt, Cynops pyrrhogaster , were examined. Solutions of the individual compound were injected into the animal hemisphere of one of the two presumptive blastomere regions of the embryo during the first cleavage. Injection of a solution containing any of the chemicals often disturbed the formation of a normal furrow in the injected blastomere at second cleavage. Injection with okadaic acid or calyculin A often induced furrow-like dents on the surface of the injected blastomere at the same time as second cleavage in control embryos, while that with tautomycin usually did not induce them. In an injected blastomere, formation of dents started in the animal half and moved towards the vegetal half as the furrow in its counterpart blastomere extended from the animal half towards the vegetal. Dents gradually became slightly deeper and formed cytoplasmic projections that later degenerated, leaving a surface scar. Cytological observations on blastomeres injected with calyculin A revealed that nuclear division occurred normally.     

Archenteron-Forming Capacity in Blastomeres Isolated from Eight-Cell Stage Embryos of the Starfish, Asterina pectinifera

Starfish blastomeres are reported to be totipotent up to the 8-cell stage. We reinvestigated the development of blastomeres of 8-cell stage embryos with a regular cubic shape consisting of two tiers of 4 blastomeres. On dissociation of the embryo by disrupting the fertilization membrane at the 8-cell stage, each of the 4 blastomeres of the vegetal hemisphere gave rise to an embryo that gastrulated, whereas blastomeres from the animal hemisphere did not. By injection of a cell lineage tracer into blastomeres of 8-cell stage embryos, we found that only those of the vegetal hemisphere formed cells constituting the archenteron. Next, we compressed 4-cell stage embryos along the animal-vegetal axis so that all the blastomeres in the 8-cell stage were in a single layer. When these 8 blastomeres were then dissociated, an average of 7 of them developed into gastrulae. By cell lineage analysis, all the blastomeres in single-layered embryos at the 8-cell stage were shown to have the capacity to form cells constituting an archenteron. Taken together, these findings indicate that the fate to form the archenteron is specified by a cytoplasmic factor(s) localized at the vegetal hemisphere, and that isolated blastomeres that have inherited this factor develop into gastrulae.     

Animal-vegetal asymmetries influence the earliest steps in retina fate commitment in Xenopus.

An individual retina descends from a restricted and invariant group of nine animal blastomeres at the 32-cell stage. We tested which molecular signaling pathways are responsible for the competence of animal blastomeres to contribute to the retina. Inactivation of activin/Vg1 or fibroblast growth factor (FGF) signaling by expression of dominant-negative receptors does not prevent an animal blastomere from contributing to the retina. However, increasing bone morphogenetic protein (BMP) signaling in the retina-producing blastomeres significantly reduces their contribution. Conversely, reducing BMP signaling by expression of a dominant-negative BMP receptor or Noggin allows other animal blastomeres to contribute to the retina. Thus, the initial step in the retinal lineage is regulated by position within the BMP/Noggin field of epidermal versus neural induction. Vegetal tier blastomeres, in contrast, cannot contribute to the retina even when given access to the appropriate position and signaling fields by transplantation to the dorsal animal pole. We tested whether expression of molecules within the mesoderm inducing (activin, FGF), mesoderm-modifying (Wnt), or neural-inducing (BMP, Noggin) pathways impart a retinal fate on vegetal cell descendants. None of these, several of which induce secondary head structures, caused vegetal cells to contribute to retina. This was true even if the injected blastomeres were transplanted to the dorsal animal pole. Two pathways that specifically induce head tissues also were investigated. The simultaneous blockade of Wnt and BMP signaling, which results in the formation of a complete secondary axis with head and eyes, did not cause the vegetal clone to give rise to retina. However, Cerberus, a secreted protein that also induces an ectopic head with eyes, redirected vegetal progeny into the retina. These experiments indicate that vegetal blastomere incompetence to express a retinal fate is not due to a lack of components of known signaling pathways, but relies on a specific pathway of head induction.     

Cleavage and gastrulation in the shrimp Sicyonia ingentis: invagination is accompanied by oriented cell division.

Embryos of the penaeoidean shrimp Sicyonia ingentis were examined at intervals during cleavage and gastrulation using antibodies to beta-tubulin and DNA and laser scanning confocal microscopy. Cleavage occurred in a regular pattern within four domains corresponding to the 4-cell-stage blastomeres and resulted in two interlocking bands of cells, each with similar spindle orientations, around a central blastocoel. Right-left asymmetry was evident at the 32-cell-stage, and mirror-image embryos occurred in a 50:50 ratio. Gastrulation was initiated by invagination into the blastocoel at the 62-cell-stage of two mesendoderm cells, which arrested at the 32-cell-stage. Further invagination and expansion of the archenteron during gastrulation was accompanied by rapid and oriented cell division. The archenteron was composed of presumptive naupliar mesoderm and the blastopore was located at the site of the future anus of the nauplius larva. In order to trace cell lineages and determine axial relationships, single 2- and 4-cell-stage blastomeres were microinjected with rhodamine-dextran. The results showed that the mesendoderm cells which initiated gastrulation were derived from the vegetal 2-cell-stage blastomere, which could be distinguished by its slightly larger size and the location of the polar bodies. The mesendoderm cells descended from a single vegetal blastomere of the 4-cell-stage. This investigation provides the first evidence for oriented cell division during gastrulation in a simple invertebrate system. Oriented cell division has previously been discounted as a potential morphogenetic force, and may be a common mechanism of invagination in embryos that begin gastrulation with a relatively small number of cells.     

Ectopic mesodermal expression promoted by the eight-cell stage Bufo arenarum subequatorial cytoplasm

Mesodermal determinants were investigated by cytoplasmic transfer and blastomere isolation in the eight-cell stage of Bufo arenarum. Their existence was confirmed by assaying the subequatorial cytoplasm’s ability to respecify the developmental potency of animal quartets. The gray subequatorial cytoplasm, but not animal cytoplasm, is able to divert the ectodermal fate of animal quartets to several mesodermal components. The source of the transplanted cytoplasm was important in determining the category of the resulting structures. Ventral subequatorial cytoplasm from ventrovegetal blastomeres generated ventral derivatives, namely erythrocytes and mesenchyma. Dorsal subequatorial cytoplasm from dorsovegetal blastomeres produced dorsolateral derivatives, such as notochord, muscle, nephric tubules, and coelomic epithelium, including mesenchyma. On the other hand, transfer of vegetal pole cytoplasm to animal quartets resulted in the formation of groups of endoderm-like cells dispersed among epidermal cells. However, the presence of such cells did not cause any mesodermal induction. The present findings suggest the existence of cytoplasmic information responsible for mesodermal specification. The alternative hypothesis that animal blastomeres become mesoderm due to vegetal induction is questioned. Received: 9 October 1998 / Accepted: 10 March 1999     

Ultraviolet irradiation of eggs and blastomere isolation experiments suggest that gastrulation in the direct developing ascidian, Molgula pacifica, requires localized cytoplasmic determinants in the egg and cell signaling beginning at the two-cell stage

Gastrulation in the maximum direct developing ascidian Molgula pacifica is highly modified compared with commonly studied "model" ascidians in that endoderm cells situated in the vegetal pole region do not undergo typical invagination and due to the absence of a typical blastopore the involution of mesoderm cells is highly modified. At the gastrula stage, embryos are comprised of a central cluster of large yolky cells that are surrounded by a single layer of ectoderm cells in which there is only a slight indication of an inward movement of cells at the vegetal pole. As a consequence, these embryos do not form an archenteron. In the present study, ultraviolet (UV) irradiation of fertilized eggs tested the possibility that cortical cytoplasmic factors are required for gastrulation, and blastomere isolation experiments tested the possibility that cell signaling beginning at the two-cell stage may be required for the development of the gastrula. Irradiation of unoriented fertilized eggs with UV light resulted in late cleavage stage embryos that failed to undergo gastrulation. When blastomeres were isolated from two-cell embryos, they developed into late cleavage stage embryos; however, they did not undergo gastrulation and subsequently develop into juveniles. These results suggest that cytoplasmic factors required for gastrulation are localized in the egg cortex, but in contrast to previously studied indirect developers, these factors are not exclusively localized in the vegetal pole region at the first stage of ooplasmic segregation. Furthermore, the inability of embryos derived from blastomeres isolated at the two-cell stage to undergo gastrulation and develop into juveniles suggests that important cell signaling begins as early as the two-cell stage in M. pacifica. These results are discussed in terms of the evolution of maximum direct development in ascidians.     

SCN— Blocks Hardening of the Fertilization Envelope of Sea Urchin Eggs and Adhesion of Blastomeres

Sea urchin eggs kept in artificial sea water (ASW) containing 0.01–0.3 M NaSCN in place of NaCI from within 2 min after insemination formed thin, enlarged fertilization envelopes, which were broken on mild agitation of egg suspensions more easily than those formed in Ca²⁺-free ASW. The blastomeres of almost all embryos derived from eggs treated with 0.2M SCN^— for 1 hr dissociated spontaneously, and did not reassociate with other blastomeres appreciably. Thus SCN^— probably denaturated some compound(s) participating in blastomere binding and hardening of the fertilization envelope. Abnormal arrangements of blastomeres, probably due to incomplete blastomere dissociation, were observed in embryos derived from eggs treated with 0.1 M SCN^— for 1 hr. Treatment of fertilized or unfertilized eggs with 0.05–0.1 M SCN^— for a short period caused concentration-dependent block of morphogenic processes such as formation of the archenteron and pluteus arms in the post-hatching period. The effects of SCN^— on morphogenesis were not inhibited by furosemide or 4,4'-diisothiocyano 2,2'-disulfonic stilbene. Presumably, the denaturation of several compounds in the egg surface by SCN^— causes abnormal morphogenesis of embryos. The inhibitory effects of SCN^— on hardening of the fertilization envelope, blastomere binding and morphogenesis were greater in the absence of Ca²⁺.     

Melanophore lineage and clonal organization of the epidermis in Xenopus embryos as revealed by expression of a biogenic marker, GFP

Melanophore lineage during embryogenesis of Xenopus laevis was traced using the overexpression of a biogenic marker, green fluorescent protein (GFP). Two different approaches were applied after injection of GFP mRNA (hence a marker construct) into each blastomere at the 16-cell stage. In in vivo experiments, the embryos injected with a marker construct were grown until stage 45, in which melanophores were distributed over the whole body and were good enough for checking GFP expression at their migratory destination. In in vitro experiments, neural tubes of the embryos injected with a marker construct were isolated and cultured at stage 21 to examine by virtue of GFP expression how neural crest cells differentiate into melanophores. The results obtained from both in vivo and in vitro experiments indicated the following: 1) selected animal blastomeres vastly contribute to the development of melanophores, whereas other animal blastomeres do so slightly at a limited pace; and 2) vegetal blastomeres never contribute to melanophores in normal development, whereas certain vegetal blastomeres have a potential to give rise to melanophores in vitro. The analyses using GFP also disclosed that the dorsal and ventral epidermis derive from the restricted animal blastomeres in the normal development. Since the dorso-ventrality of the epidermis has been inseparably coupled with integumental pigmentation, the clonal organization of the epidermis observed in the present study is discussed in the light of pigment pattern formation attributed by melanophores.     

'METACHRONOUS' CLEAVAGE AND INITIATION OF GASTRULATION IN AMPHIBIAN EMBRYOS

The cleavage pattern in the egg of Xenopus laevis has been investigated with the aid of time-lapse cinematography. From the 5th cleavage onward, divisions of the surface blastomeres are not synchronous but metachronous. A few blastomeres in a very restricted region which is situated in most cases in the dorsal side of the animal hemisphere, slightly distant from the median line and near the equatorial junction of the animal and vegetal hemispheres, divide before the other blastomeres, and a wave-like propagation of the divisions travels along the surface from that region toward the animal and vegetal poles. The wave-like propagation ends in the vegetal pole region. In the animal hemisphere, this pattern of cleavage is continued until the 13th cleavage and thereafter the divisions of surface blastomeres become asynchronous. In the vegetal pole region, however, the 14th metachronous division of blastomeres is clearly observed in the film. Gastrulation begins after 14 cleavages.     

Pattern regulation in defect embryos of Xenopus laevis

Defect embryos of 24 series were prepared by removing increasing numbers of blastomeres from an 8-cell embryo of Xenopus laevis. They were cultured and their development was examined macroscopically when controls reached a tailbud stage or later. Results show that most of defect embryos of 12 series develop normally, and some of them become normal frogs. Each of these defect embryos contain at least two animal blastomeres, one dorsal, and one ventral blastomere of the vegetal hemisphere. This suggests that a set of these four blastomeres of the three types is essential for complete pattern regulation.     

Behavior and differentiation process of pigment cells in a tropical sea urchin Echinometra mathaei

The behavior and differentiation processes of pigment cells were studied in embryos of a tropical sea urchin Echinometra mathaei, whose egg volume was one half of those of well-known sea urchin species. Owing to earlier accumulation of pigments, pigment cells could be detected in the vegetal plate even before the onset of gastrulation, distributed dorsally in a hemi-circle near the center of the vegetal plate. Although some pigment cells left the archenteron during gastrulation, most of them remained at the archenteron tip. At the end of gastrulation, pigment cells left the archenteron and migrated into the blastocoele. Unlike pigment cells in typical sea urchins, however, they did not enter the ectoderm, and stayed in the blastocoele even at the pluteus stage. It is of interest that the majority of pigment cells were distributed in the vicinity of the larval skeleton. Aphidicolin treatment revealed that eight blastomeres were specific to pigment cell lineage after the eighth cleavage, one cell cycle earlier than that in well-known sea urchins. The pigment founder cells divided twice, and the number of pigment cells was around 32 at the pluteus stage. It was also found that the differentiation of pigment cells was blocked with Ni2+, whereas the treatment was effective only during the first division cycle of the founder cells.     

Polar asymmetry in the organization of the cortical cytokeratin system of Xenopus laevis oocytes and embryos

We have used whole-mount immunofluorescence microscopy of late-stage Xenopus laevis oocytes and early embryos to examine the organization of their cortical cytokeratin systems. In both mature oocytes and early embryos, there is a distinct animal-vegetal polarity in cytokeratin organization. In mature (stage-VI) oocytes, the cytokeratin filaments of the vegetal region form a unique, almost geodesic network; in the animal region, cytokeratin organization appears much more variable and irregular. In unfertilized, postgerminal vesicle breakdown eggs, the cortical cytokeratin system is disorganized throughout both animal and vegetal hemispheres. After fertilization, cytokeratin organization reappears first in a punctate pattern that is transformed into an array of oriented filaments. These cytokeratin filaments appear first in the vegetal hemisphere and are initially thin. Subsequently, they form bundles that grow thicker through the period of first to second cleavage, at which point large cytokeratin filament bundles form a loose, fishnet-like system that encompasses the vegetal portion of each blastomere. In the animal region, cytokeratin filaments do not appear to form large fibre networks, but rather appear to be organized into a system of fine filaments. The animal-vegetal polarity in cytokeratin organization persists until early blastula (stage 5); in later-stage embryos, both animal and vegetal blastomeres possess qualitatively similar cytokeratin filament systems. The entire process of cytokeratin reorganization in the egg is initiated by prick activation. These observations indicate that the cortical cytoskeleton of Xenopus oocytes and early embryos is both dynamic and asymmetric.     

Autonomous differentiation of dorsal axial structures from an animal cap cleavage stage blastomere in Xenopus

Dorsal or ventral blastomeres of the 16- and 32-cell stage animal hemisphere were labeled with a lineage dye and transplanted into the position of a ventral, vegetal midline blastomere. The donor blastomeres normally give rise to substantial amounts of head structures and central nervous system, whereas the blastomere which they replaced normally gives rise to trunk mesoderm and endoderm. The clones derived from the transplanted ventral blastomeres were found in tissues appropriate for their new position, whereas those derived from the transplanted dorsal blastomeres were found in tissues appropriate for their original position. The transplanted dorsal clones usually migrated into the host's primary axis (D1.1, 92%; D1.1.1, 69%; D1.1.2, 100%), and in many cases they also induced and populated a secondary axis (D1.1, 43%; D1.1.1, 67%; D1.1.2, 63%). Bilateral deletion of the dorsal blastomeres resulted in partial deficits of dorsal axial structures in the majority of cases, whereas deletions of ventral midline blastomeres did not. When the dorsal blastomeres were cultured as explants they elongated. Notochord and cement glands frequently differentiated in these explants. These studies show that the progeny of the dorsal, midline, animal blastomeres: (1) follow their normal lineage program to populate dorsal axial structures after the blastomere is transplanted to the opposite pole of the embryo; (2) induce and contribute to a secondary axis from their transplanted position in many embryos; (3) are important for the normal formation of the entire length of the dorsal axis; and (4) autonomously differentiate in the absence of exogenous growth factor signals. These data indicate that by the 16-cell stage, these blastomeres have received instructions regarding their fate, and they are intrinsically capable of carrying out some of their developmental program.     

Mesendoderm cells induce oriented cell division and invagination in the marine shrimp Sicyonia ingentis

The mesendoderm (ME) cells are the two most vegetal blastomeres in the early developing embryo of the marine shrimp Sicyonia ingentis. These two cells enter mitotic arrest for three cycles after the 5th cell cycle (32-cell stage) and ingress into the blastocoel at the 6th cycle (62-cell stage). Circumjacent to the ingressing ME cells are nine presumptive naupliar mesoderm (PNM) cells that exhibit a predictable pattern of spindle orientation into the blastopore, followed by invagination. We examined the role of ME cells and PNM cells in gastrulation using blastomere recombinations and confocal microscopy. Removal of ME progenitors prevented gastrulation. Removal of any other blastomeres, including PNM progenitors, did not interfere with normal invagination. Altered spindle orientations occurred in blastomeres that had direct contact with one of the ME cells; one spindle pole localized to the cytoplasmic region closest to ME cell contact. In recombined embryos, this resulted in an extension of the region of ME-embryo contact. Our results show that ME cells direct the spindle orientations of their adjacent cells and are consistent with a mechanism of oriented cell division being a responsible force for archenteron elongation.     

The role of animal-vegetal interaction with respect to the determination of dorsoventral polarity in the equal-cleaving spiralian,Lymnaea palustris

Summary Spirally cleaving embryos in which the first two cleavages generate four equal-sized blastomeres remain radially symmetrical along their animal-vegetal axis until the interval between third and fourth quartet formation. At this time animal micromeres and vegetal macromeres contact each other as they elongate and occlude the central, fluid-filled cleavage cavity. The overlying micromeres focus their contacts onto one of the four macromeres, the presumptive 3D macromere, as it elongates to a central position within the embryo. We tested the hypothesis that this animal-vegetal interaction was causally involved in the determination of the symmetry properties in both the animal and vegetal hemispheres by reversibly inhibiting animal-vegetal contact at the 24 cell stage with cytochalasin-B. Embryos remained hollow throughout the treatment period and animal-vegetal interaction did not occur. After treatment, blastomere elongation occurred but no D quadrant macromere appeared and the vegetal hemisphere remained radialized. On the basis of cleavage and ciliation patterns of first quartet derivatives, treated embryos remained fully or partially radialized, showing a strong tendancy to develop as ventral quadrants. These results show that the quadrants of this equal-cleaving spiralian are not definitively determined until after the 24 cell stage and that animal-vegetal interaction is required for D quadrant determination. The mechanisms of symmetrization in the animal and vegetal hemispheres of equal-cleaving spiralians is also discussed.     

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.     

Evolutionary implications of the mode of D quadrant specification in coelomates with spiral cleavage

In annelids, molluscs, echiurans and sipunculids the establishment of the dorsal-ventral axis of the embryo is associated with D quadrant specification during embryogenesis. This specification occurs in two ways in these phyla. One mechanism specifies the D quadrant via the shunting of a set of cytoplasmic determinants located at the vegetal pole of the egg to one blastomere of the four cell stage embryo. In this case, at the first two cleavages of embryogenesis there is an unequal distribution of cytoplasm, generating one macromere which is larger than the others at the four cell stage. The D quadrant can also be specified by a contact mediated inductive interaction between one of the macromeres at the vegetal pole with micromeres at the animal pole of the embryo. This mechanism operates at a later stage of development than the cytoplasmic localization mechanism and is associated with a pattern of cleavage in which the first two cleavages are equal. An analysis of the phylogenetic relationships within these phyla indicates that the taxa which determine the D quadrant at an early cleavage stage by cytoplasmic localization tend to be derived and lack a larval stage or have larvae with adult characters. Those taxa where the D quadrant is specified by induction include the ancestral groups although some derived groups also use this mechanism. The pulmonate mollusc Lymnaea uses an inductive mechanism for specifying the D quadrant. In these embryos each of the four vegetal macromeres has the potential of becoming the D macromere; however under normal circumstances one of the two vegetal crossfurrow macromeres almost invariably becomes the D quadrant. Experiments are described here in which the size of one of the blastomeres of the four cell stage Lymnaea embryo is increased; this macromere invariably becomes the D quadrant. These experiments suggest that developmental change in relative blastomere size during the first two cleavages in spiralian embryos that normally cleave equally may have provided a route that has led to the establishment of the cytoplasmic localization mechanism of D quadrant formation.