Developmental autonomy of muscle fine structure in muscle lineage cells of ascidian embryos

We have observed ultrastructural features of muscle differentiation in the muscle lineage cells of cleavage-arrested whole embryos and partial embryos of ascidians. Whole embryos of Ciona intestinalis and Ascidia ceratodes were cleavage-arrested with cytochalasin B at the 8-cell stage and reared to an age equivalent to several hours after hatching; these embryos formed extensive myofilaments which were often further organized into myofibrils of different sizes and densities in the peripheral cytoplasm of the two muscle lineage blastomeres (B4.1 pair). Developing myofibrils in cleavage-arrested embryos resembled the muscle elements observed in normal hatched larvae, but were less uniformly organized. A similar development of myofilaments and myofibrils occurred in the muscle lineage cells of multicellular partial embryos reared to "hatching" age. These partial embryos resulted from the isolated muscle lineage pair (B4.1) of blastomeres of the 8-cell stage (Ciona and Ascidia), and from a muscle lineage blastomere pair (B5.2) isolated at the 16-cell stage (Ascidia). Muscle lineage cells in the partial embryos were readily identified by the dense aggregates of mitochondria in their cytoplasm. Taken together, these results from the two kinds of partial embryo effectively eliminate inductive interactions with embryonic tissues other than mesodermal as a necessary factor in the onset of self-differentiation in muscle lineage cells. The relative complexity of muscle phenotype expressed in cleavage-arrested and partial embryos attests to an unusually strong developmental autonomy in the ascidian muscle lineages. This autonomy lends further support to the theory that a localized and segregated egg cytoplasmic determinant is responsible for larval muscle development in ascidian embryos.     

Expression of an antigen specific for trunk lateral cells in quarter embryos of the ascidian, Halocynthia roretzi

Cell-lineage analysis has demonstrated that a pair of the right and left A7.6 cells of a 64-cell embryo of the ascidian Halocynthia roretzi, descendants of A4.1 cells of an 8-cell embryo, give rise to trunk lateral cells (TLCs). In this study, in order to investigate cellular mechanisms involved in the specification of TLCs, we have examined the expression of a TLC-specific antigen in cleavage-arrested embryos and in quarter partial embryos. Although cleavage arrest of embryos by treatment with cytochalasin B at early stages, prior to and including the 16-cell stage, inhibited expression of the TLC-specific antigen, embryos arrested at the 32-cell stage and at later stages developed the antigen. The only blastomeres exhibiting expression of the antigen were the presumptive TLCs, as predicted by cell-lineage assignments. When the developmental potential of quarter embryos that originated from four isolated blastomere-pairs (a4.2, b4.2, A4.1, and B4.1 pairs) of an 8-cell embryo was examined, the A4.1 quarter embryos, which are developmentally fated to give rise to TLCs, rarely showed evidence of expression of the antigen. Expression of the antigen was not observed in a4.2 and b4.2 quarter embryos, which are not associated with the TLC fate. By contrast, expression of the antigen was detected in about a half of the B4.1 quarter embryos which are also not associated with the TLC fate. These results are discussed with reference to the relationship between TLCs and mesenchyme cells.     

The ascidian embryo as a prototype of vertebrate neurogenesis

Ascidian tadpole larvae, composed of only about 2500 cells, have a primitive nervous system which is derived from the neural plate. The stereotyped cell cleavage pattern and well characterized cell lineage in these animals allow the isolation and culture of identified blastomeres in variable combinations. Ascidian embryos express cell-type-specific markers corresponding to their cell fates, even when cultured under cleavage-arrest by cytochalasin B. This system provides us with a unique opportunity to study the roles of cell lineage and cell contact in early neuronal differentiation in the absence of events associated with complex morphogenesis. In addition, the isolated, cleavage-arrested blastomeres are ideally suited to electrical recording, permitting the use of ionic channels as specific markers for differentiation. In the cleavage-arrested embryos, suppression of one type of K+ channel, and induction of two types of Na+ channels, occur following cell contact with the vegetal blastomere. The combination of molecular and electrophysiological analyses on this simple animal system may provide insights into the nature of the cell interactions important in early neurogenesis, both in ascidians and in vertebrates.     

Differentiation of 2-cell and 8-cell mouse embryos arrested by cytoskeletal inhibitors

Mouse embryos at the 2-cell stage were cultured in the presence of cytochalasin B (CB), cytochalasin D (CD), colchicine (COL) or colcemid (COM) for up to 72 h. Cleavage was arrested in the 2-cell and 8-cell embryos cultured in CB or CD but the blastomeres continued to differentiate, since chromosome replication occurred in the blastomeres at approximately the same time as control embryos underwent cleavage; an increase in the incorporation of [³H]uridine into RNA was also detected. Furthermore, the cleavage-arrested embryos acquired the necessary information to undergo morphogenesis; these embryos when explanted to fresh medium after 48 h culture in CB or CD underwent compaction within 15–60 min and started to cavitate to produce trophoblastic vesicles within 5–6 h at the same time as when the control embryos were undergoing compaction and beginning to form blastocoelic cavities. In contrast, the embryos arrested in the presence of COM or COL showed none of these differentiative, biochemical or morphogenetic changes. Hence, differentiation of blastomeres and morphogenesis is apparently coupled with nuclear divisions and the information does not reside within the blastomeres at the 2-cell or 8-cell stage. The trophoblastic vesicles produced after cleavage arrest subsequently gave rise to only trophoblast giant cells and no embryonic derivatives were detected.     

Isolation of cDNA Clones for Epidermis-Specific Genes of the Ascidian Embryo

The present investigation was conducted to isolate cDNA clones that correspond to epidermis-specific genes of the ascidian embryo. When cleavage of fertilized eggs of Halocynthia roretzi is blocked by treatment with cytochalasin B and the arrested eggs are reared as one-celled embryos for about 30 hr, they develop features of differentiation of the epidermis only. Translation in vitro of poly(A)⁺ RNA from cleavage-arrested embryos and analysis of the products by two-dimensional gel electrophoresis revealed several predominant polypeptides that were not detected in a similar analysis of fertilized eggs, suggesting the appearance of epidermis-specific mRNAs in cleavage-arrested embryos. A cDNA library was constructed from arrested one-celled embryos. Differential screening of the library with a total cDNA probe from cleavage-arrested embryos and with a similar probe from fertilized eggs yielded eight different cDNA clones specific for the cleavage-arrested embryos. Northern blot analysis revealed that the mRNAs that corresponded to these cDNAs were present in normal tailbud embryos. In addition, in situ hybridization of whole-mount specimens showed that the mRNAs were restricted to the epidermal cells of tailbud embryos.     

Requirement of cell division for muscle actin expression in the primary muscle cell lineage of ascidian embryos

The role of cell division in the expression of muscle actin and its relationship to acetylcholinesterase (AChE) development was examined in cleavage-arrested embryos of the ascidian Styela. Muscle actin expression was detected by two-dimensional gel electrophoresis of radioactively labelled proteins and by in situ hybridization with a cDNA probe, whereas AChE activity was assayed by enzyme histochemistry. In the majority of cases, muscle actin expression was first detected in embryos arrested after the 16-cell stage. Some embryos showed muscle actin expression after arrest at the 8-cell stage, however, muscle actin mRNA did not accumulate in embryos arrested at earlier cleavages. The cells that expressed muscle actin in 8- to 64-cell cleavage-arrested embryos belonged to the primary muscle lineage; secondary muscle cell precursors did not express muscle actin. Zygotic muscle actin mRNA appeared to accumulate with myoplasmic pigment granules in the perinuclear region of cleavage-arrested embryos, suggesting that the myoplasm may have a role in the organization of muscle cells. In contrast to muscle actin, AChE was detected in a small proportion of embryos treated with cytochalasin as early as the 1- or 2-cell stage, and most embryos treated with cytochalasin at later cleavages expressed this enzyme in some of their cells. Most primary muscle lineage cells expressed both muscle actin mRNA and AChE, however, some cells expressed only muscle actin mRNA or AChE. The results suggest that at least three cleavages are required for muscle actin expression and that muscle actin and AChE expression can be uncoupled in cleavage-arrested embryos.     

Differentiation Expression in Blastomeres of Cleavage-Arrested Embryos of the Ascidian Halocynthia roretzi

The question whether two or more different genetic programs are expressed in the common cytoplasm of single blastomeres or the expression of one genetic program somehow excludes expression of the other, was analyzed by assessing the occurrence of a muscle-specific and two epidermis-specific antigens in cleavage-arrested blastomeres in early embryos of the ascidian Halocynthia roretzi . Blastomeres which had been arrested in 1- to 4-cell stages expressed only the epidermis markers. Arrested 8-cell to 32-cell embryos produced both epidermis and muscle markers, but each cell expressed only one program of differentiation, even though some possessed the potential to express both. The differentiation expressions followed their cell lineages. These results indicate that at least in this experimental system differentiation markers of the two different cell-types are expressed exclusively.
A distinct order was noticed in expression of the two epidermis markers in a single blastomeres; a marker is always superiorly expressed, whereas the other appears only when the superior marker is expressed.     

Determinative properties of muscle lineages in ascidian embryos

Blastomeres removed from early cleavage stage ascidian embryos and reared to 'maturity' as partial embryos often elaborate tissue-specific features typical of their constituent cell lineages. We used this property to study recent corrections of the ascidian larval muscle lineage and to compare the ways in which different lineages give rise to muscle. Our evaluation of muscle differentiation was based on histochemical localization and quantitative radiometric measurement of a muscle-specific acetylcholinesterase activity, and the development of myofilaments and myofibrils as observed by electron microscopy. Although the posterior-vegetal blastomeres (B4.1 pair) of the 8-cell embryo have long been believed to be the sole precursors of larval muscle, recent studies using horseradish peroxidase to mark cell lineages have shown that small numbers of muscle cells originate from the anterior-vegetal (A4.1) and posterior-animal (b4.2) blastomeres of this stage. Fully differentiated muscle expression in isolated partial embryos of A4.1-derived cells requires an association with cells from other lineages whereas muscle from B4.1 blastomeres develops autonomously. Clear differences also occurred in the time acetylcholinesterase activity was first detected in partial embryos from these two sources. Isolated b4.2 cells failed to show any muscle development even in combination with anterior-animal cells (a4.2) and are presumably even more dependent on normal cell interactions and associations. Others have noted an additional distinction between the different sources of muscle: muscle cells from non-B4.1 lineages occur exclusively in the distal part of the tail, while the B4.1 descendants contribute those cells in the proximal and middle regions. During the course of ascidian larval evolution tail muscle probably had two origins: the primary lineage (B4.1) whose fate was set rigidly at early cleavage stages and secondarily evolved lineages which arose later by recruitment of cells from other tissues resulting in increased tail length. In contrast to the B4.1 lineage, muscle development in the secondary lineages is controlled less rigidly by processes that depend on cell interactions.     

Cytological effects of the microinjection of antibody to ras p21 in early cleavage Xenopus embryos

The presence of two ras-related proteins (22 and 23 kDa) was demonstrated in Xenopus embryonic extracts by selective immunoprecipitation using anti-ras monoclonal antibodies 142-24E05 and Y13-259. We further describe the cytological effects of the microinjection of anti-ras monoclonal antibody Y13-259 into early cleavage blastomeres of Xenopus embryos. Injection of the antibody into a blastomere at the two-, four-, or eight-cell stage caused cleavage arrest in the descendants of the injected blastomere. Light microscopy (LM) of cleavage-arrested cells revealed extensive deformation of the cells as well as heterogeneity of distribution of yolk platelets and pigment granules. LM analysis of serial sections of cleavage-arrested cells revealed the presence of multiple nuclei. Although the nuclei expressed similar morphological properties, indicating that they were probably in the same stage of the nuclear cycle, they revealed highly variable chromatin densities. Electron microscope (EM) analysis of the cytoplasm of cleavage-arrested cells revealed the accumulation of vesicles and large membranous elements coincident with cleavage arrest. Furthermore, endoplasmic reticulum (ER) existed in two forms, as closed, circular profiles and as long, linear arrays. Mitochondria were characteristically aligned in single file on both sides of the two types of ER cisternae. EM analysis of nuclei confirmed variations in chromatin organization and suggested the occurrence of unique nuclear envelope fusion among micronuclei in cleavage-arrested cells. Cleavage arrest and changes in cytological features were not observed in the cytoplasm of cells microinjected with normal rat IgG. Thus the immunochemical data and microinjection experiments suggest that ras-like or ras antigenicity exists within rapidly replicating Xenopus blastomeres and may be involved in the organization of a number of its cytoplasmic elements.     

Autonomous muscle cell differentiation in partial ascidian embryos according to the newly verified cell lineages

Recent analysis of cell lineages in ascidian embryos by the intracellular injection of a tracer enzyme has clearly demonstrated that muscle cells are derived not only from the B4.1-cell pair of the eight-cell stage embryo, as has hitherto been believed, but also from both the b4.2- and A4.1-cell pairs (H. Nishida and N. Satoh, 1983, Dev. Biol.99, 382–394). In order to reexamine the developmental autonomy in muscle lineage cells, the B4.1 pair was isolated from the eight-cell stage embryo. The progeny cells of the B4.1 pair, as well as those of the six other blastomeres, were then allowed to develop in isolation into partial embryos. Autonomous muscle cell differentiation not only in partial embryos originating from the B4.1 cells but also in those from the six other blastomeres was substantiated by (a) occurrence of localized histospecific muscle acetylcholinesterase and (b) development of myofibrils. These results support the validity of the recent cell lineage study and confirmed the self-differentiation potency of muscle lineage cells in ascidian embryos according to the newly verified cell lineages.     

Mapping the distribution of differentiation potential for intestine, muscle, and hypodermis during early development in Caenorhabditis elegans

We have analyzed the differentiation potential of cells in early embryos of Caenorhabditis elegans by assessing the production of markers for intestinal, muscle, and hypodermal cell differentiation in cleavage-arrested blastomeres. Our results show that differentiation potential does not always segregate during cleavage in a linear fashion, i.e., a blastomere can express a differentiation potential that is absent in its parent blastomere and vice versa. Furthermore, the expression of a particular differentiation program by certain cleavage-arrested blastomeres is an exclusive event in that each cell will express only one program of differentiation, even though it may have the potential to express several.     

An evolutionary change in the muscle lineage of an anural ascidian embryo is restored by interspecific hybridization with a urodele ascidian

Anural ascidians do not develop into a conventional tailed larva with differentiated muscle cells, however, embryos of some anural ascidian species retain the ability to express acetylcholinesterase (AChE) in a vestigial muscle cell lineage. This study examines the number of AChE-positive cells that develop in the anural ascidian Molgula occulta relative to that in the closely related urodele (tailed) species, Molgula oculata. Histochemical assays showed that M. oculata embryos develop 36 to 38 AChE-positive cells, consistent with the number of tail muscle cells expressed in other urodele ascidians. In contrast, M. occulta embryos develop a mean of only 20 AChE-positive cells in their vestigial muscle lineage. Cleavage-arrested embryos of the anural species express AChE only in B-line blastomeres, showing that the vestigial muscle lineage cells are derived from the primary muscle lineage. Less than the expected number of AChE-positive B-line cells develop in cleavage-arrested anural embryos, however, implying that the allocation of primary muscle lineage cells is decreased. Eggs of the anural species can be fertilized with sperm of the urodele species resulting in the development of some larvae that contain a short tail and/or a brain melanocyte, specific features of urodele larvae. The typical urodele number of AChE-positive cells is restored in some of these hybrid embryos. Both primary and secondary muscle lineages are restored because cleavage-arrested hybrid embryos develop more AChE-positive cells in the B-line blastomeres and supernumerary AChE-positive cells in the A-line blastomeres. Hybrid embryos that develop the urodele complement of AChE-positive cells also form a tail and/or a brain melanocyte showing that restoration of muscle lineage cells is coupled to the development of other urodele features. AChE expression occurred in anural embryos with disorganized or dissociated blastomeres, indicating that AChE expression is determined autonomously. It is concluded that an evolutionary change in the allocation of larval muscle lineage cells occurs during development of the anural ascidian M. occulta which can be restored by interspecific hybridization with the urodele ascidian M. oculata.     

Developmental autonomy of presumptive notochord cells in partial embryos of an ascidian

Summary

Ultrastructural features of larval notochord cell differentiation, sheath (membrane leaflets and filaments) and vacuoles of intracellular colloid, were found in some cells of certain partial embryos of the ascidian, Ciona intestinalis. As expected from established lineage fate maps, mature quarter-embryos developing from microsurgically isolated anterior-vegetal blastomeres (A4.1 pair) at the 8-cell stage had some cells with the notochord features. Such cells, however, also occurred in quarter-embryos resulting from the posterior-vegetal blastomere pair (B4.1) and in partial embryos derived from the B5.1 cell pair isolated at the next cleavage of the B4.1 blastomeres. These findings confirm a prediction of additional notochord cell fates from a recent revision of the ascidian lineage map based on cell marking with microinjected horseradish peroxidase. Partial embryos obtained from other lineages of the 8- and 16-cell stages did not develop notochord cells.     

Differentiation without cleavage: multiple cytospecific ultrastructural expressions in individual one-celled ascidian embryos

Multiple states of differentiation developed within the same undivided egg cytoplasm of ascidian zygotes cleavage-arrested with cytochalasin B. Complex ultrastructural traits of up to four quite diverse cell lineage components were observed in regions of the common cytoplasm in such multinucleate homokaryons of Ciona intestinalis: epidermal, muscle, notochordal, and neural. Almost all specimens among those selected as showing differentiation contained two such features, half of them had at least three, and a few expressed all four. The histospecific morphological characteristics noted were the extracellular test material of epidermal cell origin, muscle myofilaments and myofibrils, sheath components (leaflets and filaments) associated with notochordal cells, and the particular localized combinations of microtubules, filamentous structures, and cilia indicative of neural tissues. Cleavage-arrested one-celled embryos of Ascidia ceratodes served to demonstrate that those which were found cytochemically to contain muscle acetylcholinesterase always had myofibrils and myofilaments. Other arrested zygotes of Ascidia (unstained specimens) also had quite fully formed test material as well as myofilaments and myofibrils. The occurrence within the same cell of so many specific markers of diverse pathways of development is consistent with a theory about a primary level of regulation based on autonomous gene activation factors already present in the fertilized egg. If further investigation substantiates a real cytoplasmic continuity within these cleavage-arrested embryos, other theories that invoke cell interactions, temporal sequences of metabolically distinct microenvironments, and gradients of substances as causes of determinative change seem inadequate to account for the coexisting expressions of differentiation described here.     

Muscle cell differentiation in ascidian embryos analysed with a tissue-specific monoclonal antibody

Utilizing a muscle-specific monoclonal antibody (Mu-2) as a probe, we analysed developmental mechanisms involved in muscle cell differentiation in ascidian embryos. The antigen recognized by Mu-2 was a single polypeptide with a relative molecular mass of about 220 X 10(3). It first appeared at the early tailbud stage and continued to be expressed until the swimming larva stage. There were distinct and separate puromycin and actinomycin D sensitivity periods during the occurrence of the antigen, suggesting the new synthesis of the polypeptide by developing muscle cells. Embryos that had been permanently arrested with aphidicolin in the early cleavage stages up to the 32-cell stage did not express the antigen. DNA replications may be required for the antigen expression. Embryos that had been arrested with cytochalasin B in the 8-cell and later stages developed the antigen, and the number and position of the arrested blastomeres exhibiting the differentiation marker almost corresponded to those of the B4.1-line muscle lineage. Furthermore, in quarter embryos developed from each blastomere pair isolated from the 8-cell embryo, all the B4.1 as well as a part of b4.2 partial embryos expressed the antigen, while the a4.2 and A4.1 partial embryos did not show the antigen expression. These results may provide further support for the existence of cytoplasmic determinants for muscle cell differentiation in this mosaic egg.     

Segregation during cleavage of a factor determining endodermal alkaline phosphatase development in ascidian embryos.

Localized alkaline phosphatase activity (EC 3.1.3.1) develops progressively in endodermal tissues of the presumptive digestive system in Ciona intestinalis embryos. It was first detected histochemically at late gastrulation, and a puromycin sensitivity period coincident with this time suggests that new alkaline phosphatase is synthesized. Embryos in which cell division was blocked with cytochalasin B at early cleavage stages up to the 64-cell stage, eventually differentiated strong alkaline phosphatase activity in certain cells at each cleavage-arrested stage. The maximum cell numbers and their positions were identical to those of the previously known endodermal cell lineage. Actinomycin D did not prevent development of endodermal alkaline phosphatase when administered from fertilization onwards, nor did other inhibitors of RNA synthesis (chromomycin A3, cordycepin, and daunomycin). There is probably a preformed maternal mRNA for endodermal alkaline phosphatase present in the unfertilizec Ciona egg. Either this RNA itself, or some related translation factor, is localized in the egg cytoplasm and segregated during early cleavages into the endodermal cell lineage of the embryo.     

Differentiation of histospecific ultrastructural features in cells of cleavage-arrested early ascidian embryos

Summary Ultrastructural features of histospecific differentiation were found in early cleavage stage ascidian embryos treated with cytochalasin B and held thereby in cleavagearrest until hatching time. Markers characteristic of tissue differentiation during normal embryonic and larval stages ofCiona intestinalis were expressed in muscle and two brain cell lineages of cleavage-arrested whole embryos and in epidermal and notochordal cell lineages of cleavage-arrested partial embryos. These features were muscle myofilaments and myofibrils, melanosomes of the brain pigment cells, cilium-derived structures present in a proprioceptive brain cell, extracellular test material of epidermal cell origin, and the sheath filaments, membrane leaflets, and vacuolar colloid associated with notochord cells. All of these ultrastructural markers of differentiation were blocked in their development by treatment of gastrula stage embryos with actinomycin D, an inhibitor of RNA synthesis, and presumably result from the expression of new gene activity. At the time of cleavage-arrest the five cell lineages studies still contained two or more unsegregated lineage pathways. Subsequent developmental autonomy within the lineages is consistent with the hypothesis of segregation during early development of functionally independent gene regulatory factors.     

Gap-junctional permeability in early and cleavage-arrested ascidian embryos.

Using the whole-cell voltage clamp technique, we have studied junctional conductance (Gj), and Lucifer Yellow (LY) coupling in 2-cell and 32-cell ascidian embryos. Gj ranges from 17.5 to 35.3 nS in the 2-cell embryo where there is no passage of LY, and from 3.5 to 12.2 nS in the later embryo where LY dye spread is extensive. In both cases, Gj is independent of the transjunctional potential (Vj). Manually apposed 2-cell or 32-cell embryos established a junctional conductance of up to 10 nS within 30 min of contact. Furthermore, since we did not observe any significant number of cytoplasmic bridges at the EM and Gj is sensitive to octanol, it is probable that blastomeres in the 2-cell and 32-cell embryos are in communication by gap junctions. In order to compare Gj in the two stages and to circumvent problems of cell size, movement and spatial location, we used cytochalasin B to arrest cleavage. Gj in cleavage-arrested 2-cell embryos ranged from 25.0 to 38.0 nS and remained constant over a period of 2.5 h. LY injected into a blastomere of these arrested embryos did not spread to the neighbour cell until they attained the developmental age of a 32- to 64-cell control embryo. Our experiments indicate a change in selectivity of gap junctions at the 32-cell stage that is not reflected by a macroscopic change in ionic permeability.     

Quantitative control of end products in the melanocyte lineage of the ascidian embryo.

Terminal amounts of tyrosinase (EC 1.10.3.1) activity and melanin pigment in the giant melanocytes of cleavage-arrestedCiona intestinalis (L.) embryos are regulated independently of cell size and number of nuclei in the cells. Embryos were cleavage-arrested in cytochalasin B at a time before the last two divisions of the melanocyte lineage took place. The resulting two giant melanocytes, one from each of the two bilateral melanocyte lineages, developed tyrosinase and melanin. The cells were about three times larger in volume than the normal larval melanocytes and each contained four nuclei instead of just one. Quantitative measurements of melanin synthesized and tyrosinase activity in embryos with the giant melanocytes revealed amounts identical to those found in normal embryos. This specification of exact quantities differs markedly from the situation in mammalian melanocytes where cell volume and gene dosage influence the extent of melanotic differentiation. Quantitative control of differentiation in ascidian melanocytes appears to be mediated by a cytoplasmic determinant segregated through the melanocyte lineage and inherited by one daughter at each division of the lineages.