Development of Loach Eggs after Experimental Increase of Cell Mass in the Dorsal and Ventral Areas of Blastoderm

The fertilized loach eggs were injected, before the beginning of cleavage, with the nuclear dye Hoechst 33258 and left to develop until the late blastula stage. Some cells of the dorsal area of stained blastoderm were transplanted in the analogous area of intact embryos of the same age, which led to an earlier and more pronounced development of head and trunk structures in recipients. A relationship was established between specific features of the development of recipients and localization of descendants of the transplanted cells. Transplantation of cells of the dorsal area of stained blastoderm in the ventral area of embryos of the same age led to the formation of two axial complexes, both at the same level of development, but behind the control, and stained cells were located predominantly in one of twin embryos.     

Neurite extension by peripheral and central nervous system neurons in response to substratum-bound fibronectin and laminin

Small groups of blastoderm cells were transplanted from wild-type donor embryos into genetically marked host embryos of the same age. Donor cells were injected either into an homologous or an ectopic region of the recipient, and both donor and recipient embryos were allowed to develop. Donor flies were examined for defects in external structures. Recipients were scored for patches of donor-type marked tissue derived from the injected cells. After ectopic transfer, the donor cells recovered in chimaeric recipients differentiated structures consistent with the donor site of cell removal. No apparent fate change was observed. In the rare cases when both individuals of a donor/host pair survived, a direct correspondence could be made between the deleted region in the donor and the chimaeric patch in the host. The results show that blastoderm cells are stably determined to within a segment.     

A morphological and developmental study of Drosophila embryos ligated during nuclear multiplication

In the Drosophila embryo, determination is established at the cellular blastoderm and a mosaic type development is observed after this time. Before the blastoderm stage, however, development is not of the mosaic type, as ligation during the nuclear multiplication stage causes a change in the spatial organization of the larval pattern. An aberration in determination leads to an increase in segment size, an increase in the number of cells per segment, and a decrease in segment number. This abnormal determination of blastoderm cells has also been demonstrated experimentally by marking corresponding regions of the blastoderm in ligated (posterior fragments only) and nonligated embryos. When the blastoderms of nonligated and ligated embryos are punctured at the same site, ligated embryos produce larvae with damage in segments posterior to the segments damaged in larvae from nonligated embryos. Ultrastructurally, no abnormalities were observed in the plasma membrane at the time of ligation or later in blastoderm cells which formed in the ligation area of these embryos. Evidence from this study, as well as other sources, indicates that determination of segmentation is under maternal control.     

Acquisition of developmental autonomy in the equatorial region of the Xenopus embryo

This paper describes a continuing effort to define the location and mode of action of morphogenetic determinants which direct the development of dorsal body axis structures in embryos of the frog Xenopus laevis. Earlier results demonstrated that presumptive endodermal cells in one vegetal quadrant of the 64-cell embryo can, under certain experimental conditions, induce partial or complete body axis formation by progeny of adjacent equatorial cells. (R.L. Gimlich and J.C. Gerhart, 1984, Dev. Biol. 104, 117-130). I have now assessed the importance of other blastomeres for embryonic axis formation in a series of transplantation experiments using cells from the equatorial level of the 32-cell embryo. The transplant recipients were embryos which had been irradiated with ultraviolet light before first cleavage. Without transplantation, embryos failed to develop the dorsal structures of the embryonic body axis. However, cells of these recipients were competent to respond to inductive signals from transplanted tissue and to participate in normal embryogenesis. Dorsal equatorial cells, but not their lateral or ventral counterparts, often caused partial or complete body axis development in irradiated recipients, and themselves formed much of the notochord and some prechordal and somitic mesoderm. These are the same structures that they would have formed in the normal donor. Thus, the dorsal equatorial blastomeres were often at least partially autonomous in developing according to their prospective fates. In addition, they induced progeny of neighboring host cells to contribute to the axial mesoderm and to form most of the central nervous system. The frequency with which such transplants caused complete axis formation in irradiated hosts increased when they were made at later and later cleavage stages. In contrast, the inductive activity of vegetal cells remained the same or declined during the cleavage period. These and other results suggest that the egg cytoplasmic region containing "axial determinants" is distributed to both endodermal and mesodermal precursors in the dorsal-most quadrant of the early blastula.     

Developmental analysis of fs(1)gastrulation defective,a dorsal-group gene of Drosophila melanogaster

Summary The gastrulation defective (gd) locus is a maternally expressed gene in Drosophila required for normal differentiation of structures along the embryonic dorso-ventral axis. Cuticular defects of the offspring from females with different combinations of gd alleles comprised a phenotypic continuum. Complementation among several alleles produced normal offspring while progressively more severe mutations produced a graded loss of structures from ventral, and then lateral, blastoderm cells. The most severely affected embryos consisted entirely of structures derived from dorsal blastoderm cells. Histological examination of staged siblings from selected allelic combinations showed that internal tissues were similarly affected. The tissues observed in amorphic embryos support new, more dorsal, assignments of fate map positions for blastoderm precursors of the cephalopharyngeal apparatus, hindgut and ventral nerve cord. The loss of ventral and lateral structures did not occur through cell death and appeared to involve a change in blastoderm cell fate. A direct effect of the mutations on blastoderm cell determination, however, was insufficient to explain the development of the dorsalized embryos. Intermediate phenotypes suggested that cell interactions or movements associated with morphogenesis are required for the determination of some cell fates in the dorsoventral axis. Thus, the developmental fate of all blastoderm cells may not be fixed at the time of blastoderm formation.     

BEHAVIOR OF INTERPHASE EMBRYONIC NUCLEI TRANSPLANTED IN NUCLEAR MULTIPLICATION STAGE EMBRYOS OF DROSOPHILA MELANOGASTER

Interphase nuclei were transplanted from syncytial blastoderm into early cleavage embryos of Drosophila melanogaster. The transplanted nuclei, when exposed to host cytoplasm, were initiated to mitosis. During the period from 10 to 50 min after transplantation, the implanted nuclei and host nuclei were found not synchronous in their mitotic cycles. Synchrony was restored usually by the blastoderm stage.
About 5% of eggs with transplanted nuclei developed significantly faster than control eggs, resulting in premature blastoderm formation. This finding is discussed in relation to chimera formation and to embryonic development of grandchildless mutants.     

A Cell Marker System and Mosaic Patterns during Early Embryonic Development in Drosophila melanogaster

An embryonic cell marker system has been developed in Drosophila melanogaster that has enabled us to identify the genotype of cells as early as the cellular blastoderm stage of development. This system allows unambiguous detection of embryos homozygous for most X-linked lethal mutations at stages prior to when their first defects become obvious. By examining gynandromorphs at this stage, we have observed that the number of nuclei per unit area in male regions is about half that in female regions. An examination of early cleavage stage embryos whose DNA has been stained with Hoechst 33258 and whose actin has been stained with phalloidin suggests that this difference is due to a cell cycle delay in cells losing the ring-X. These experiments also demonstrate the existence of a mechanism which controls the timing of nuclear divisions in cycle 10-14 embryos.     

Variability of quantitative morphogenetic parameters during early morphogenesis of the loach, <Emphasis Type="Italic">Misgurnus fossilis</Emphasis> L.

Analysis of normal variation in quantitative morphological characters during the early embryonic development of the loach, based on observations on individual developmental trajectories of living embryos, shows that the dorsoventral differentiation of the blastoderm proceeds in two stages. Initially, at the onset of epiboly, the sagittal (short) and transverse (long) blastoderm meridians are marked off, and only then, upon germ ring (GR) formation, differentiation between the opposite poles of the sagittal meridian takes place. The embryonic shield (ES) usually appears in the segment of the blastoderm where the radius of its external curvature reaches a maximum and, therefore, the active surface tension at the blastoderm boundary with the YSL periblast) and yolk is the highest. In this case, the convergence of inner cells toward the future dorsal segment (leading to ES formation) is a mechanical consequence of surface tension anisotropy. The normal course of epiboly is associated with periodic changes in the curvature of the blastoderm external surface, with new structures (the dorsal segment, GR, and ES) are marked off only when the surface curvature becomes maximally uniform. Although the ES in most embryos appears within the initial dorsal segment, individual developmental trajectories have been traced where the GR starts to form at the dorsal pole of the blastoderm but the ES develops on its opposite site, at the point of GR closure. In both cases, GR formation is initiated at the point of convergence of centrifugal cell migration flows that arise in the marginal zone of the blastoderm upon GR initiation or closure.     

Pathfinding during spinal tract formation in the chick-quail chimera analysed by species-specific monoclonal antibodies.

In order to analyse the spinal tract formation at early stages of development in avian embryos, chick-quail spinal cord chimeras were prepared and species-specific monoclonal antibodies (MAb) were developed. MAbs CN, QN and CQN uniquely stained chick, quail, and both chick and quail nervous tissues, respectively. All three antibodies appeared to bind to the same membrane molecule, but to different epitopes. Cord reversal revealed the features of axonal growth of both cord interneurons and dorsal root ganglion cells. Quail cord interneurons grew along an originally ventral marginal layer in the quail cord transplanted in a reversed position, then turned toward the ventral side at the boundary between the graft and the host, and grew along the host chick ventral marginal layer. Central axons of dorsal root ganglia were restricted to the ventrolateral region of the cord which originally formed the dorsal funiculus. These results suggest that cord interneurons and dorsal root ganglion cells actively select to grow along specific regions of the cord and that spinal tract formation appears to be determined by cord cells, and not by sclerotome cells.     

The Blood Island is a Site of Formation of the Primary Embryo Thrombocyte in the Chick Blastoderm

Using the immunohistological technique we inquired at what developmental stage and in which site of chick blastoderm does the embryo thrombocyte (ET) begin to differentiate. An anti-ET antibody was raised against rabbits by injecting ETs isolated from blood of 10 day chick embryos. By applying the indirect staining method to smear preparations of blood collected from developing embryos it was confirmed that cytoplasm of the ET showed more intense staining than that of the erythroid cell and that the ET population could be distinguished from the erythrocyte population by this antibody. Cells showing the intense staining could be detected first in blood islands of the area opaca vasculosa of stage 9+ blastoderms. These embryo thromboblasts were found singly or in groups of a small number at dorsal periphery of cell clusters in the blood island. The electron microscopy revealed that embryo thromboblasts appeared in the same position in the stage 9+ blastoderm. At stage 10+ or later embryo thromboblasts were also present adhering to the vascular endothelium or free in the vessel lumen. We conclude that ETs start differentiating from primitive mesenchymal cells localized in the blood island of the area opaca vasculosa at stage 9 or earlier, migrate thereafter to vessel lumen, and enter the blood stream.     

Dorsal specification in blastoderm at the blastula stage in the goldfish, Carassius auratus

The teleost dorsoventral axis cannot be morphologically distinguished before gastrulation. Previous studies by the current authors have shown that localized dorsalizing activity in the yolk cell (YC) induces the dorsal tissues in the overlying blastoderm. In order to examine whether or not dorsal blastomeres are committed to their dorsal fate before the gastrula stage, a variety of transplant operations were performed in goldfish blastoderms at the mid- to late-blastula stages. When the blastoderm was cut from the YC, rotated horizontally at 180°, and recombined with the YC, the blastoderm frequently developed two axes, indicating that dorsal blastomeres of the blastula had already acquired the ability to differentiate into the organizer in the absence of dorsalizing signals from the YC. This result was further confirmed by experiments using ventralized embryos in which no dorsal structures formed: the axis formation was frequently observed in the normal blastoderm combined with the ventralized YC at the blastula stage. However, the axes formed in the absence of dorsal information from the YC exhibited a lower dorso-anterior index. Furthermore, the dorsal specification was not stably maintained when the dorsal cells were located far from the YC. These results suggest that the inductive and permissive influence of the YC may be required for the blastoderm to undergo full dorsal differentiation.     

Demonstration of neural induction using nuclear markers inXenopus

Summary Two nuclear markers were used to investigate the origin of cells in secondary embryos ofXenopus induced by dorsal lip transplants, and to determine the ability of the chordomesoderm to direct cells to change their fates.³H-thymidine was used to label cells transplanted between individualX. laevis embryos, and nuclear quinacrine fluorescence was used to distinguishX. borealis tissues transplanted toX. laevis hosts. In the first set of experiments, dorsal lip tissue (also known as the dorsal marginal zone; DMZ) was transplanted to the ventral marginal zone (VMZ) of host embryos. The marginal zone is the toroid of presumptive mesodermal cells which involutes during gastrulation. Examination of the secondary embryos resulting from these grafts revealed that their notochords were derived almost exclusively from transplanted cells whereas their nervous systems and somites were composed almost entirely of host cells. Next, the nuclear markers were used to show the normal fates of the tissue of the ventral equatorial region immediately above the VMZ by orthotopic grafting. This tissue was found to give rise to structures in the ventral posterior portions of the tailbud embryo. Finally, the same ventral tissue was labeled and transplanted to the dorsal equatorial region above the DMZ. As a result, it was induced to change its fate and become neural. These results lend unequivocal support to Spemann's theory of neural induction which has recently been questioned.     

Prospective Neural Areas and Their Morphogenetic Movements during Neural Plate Formation of Xenopus Embryos. I. Development of Vegetal Half Embryos and Chimera Embryos

Development of animal cap-less Xenopus gastrulae was examined. In vegetal halves from which the animal cap was removed 0.6 mm above the blastopore, an apparently normal array of craniocaudal structures developed. Histological examination showed differentiation of central nervous system (CNS) structures in the cap-less embryos, but differentiation of sensory organs, such as a lens and ear vesicle in only a few embryos. Only the dorsal midline of the embryos was covered with epidermis, and its lateral-ventral areas consisted of bare endoderm and mesoderm. The development of animal cap was also investigated by exchanging the animal cap of X. laevis embryos with that of X. borealis embryos, which can be distinguished by quinacrine fluorescence staining. The central nervous system of chimera embryos consisted mainly of X. laevis cells stained homogeneously with quinacrine but a small number of punctately-stained X. borealis cells was in the anterior tip of the forebrain. Cells of the lens and ear vesicle were punctately stained. More than two-thirds of the epidermal area consisted of punctately-stained cells and only the dorsal midline of the posterior head- and trunk-epidermis consisted of homogeneously-stained cells.
Areas of the prospective central nervous system and their movement during embryogenesis of Xenopus are discussed.     

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster

Summary We describe the results of cell transplantation experiments performed to investigate mesodermal lineages in Drosophila melanogaster, particularly the lineages of the somatic muscles, the visceral muscles and the fat body. Cells to be transplanted were labelled by injecting a mixture of horseradish peroxidase (HRP) and fluorescein-dextran (FITC) in wild-type embryos at the syncytial blastoderm stage. For transplantation cells were removed from the ventral furrow, 8–12 min after the start of gastrulation, and individually transplanted into homotopic or heterotopic locations of unlabelled wild-type hosts of the same age. HRP labelling in the resulting cell clones was demonstrated histochemically in the fully developed embryo; histotypes could be distinguished without ambiguity. Mesodermal cells were already found to be committed to mesodermal fates at the time of transplantation. They developed only into mesodermal derivatives and did not integrate in non-mesodermal organs upon heterotopical transplantation. No evidence was found for commitment to any particular mesodermal organ at the time of transplantation. The majority of somatic muscle clones contributed cells to only one segment. However, clones were not infrequently distributed through two or even three segments. Clones of fat body cells were generally restricted to a small region. However, cells of clones of visceral musculature were widely distributed. With respect to the proliferative abilities of transplanted cells the clones were difficult to interpret due to the syncytial character of the somatic musculature and the fact that the organization of the other organs is poorly understood. Evidence from histological observations of developing normal embryos indicates only three mitoses for mesodermal cells. Clones larger than seven cells were not found when embryos were fixed previous to germ-band shortening; larger clones were found in the fat body and visceral musculature after fixing the embryos at the end of organogenesis. Quantitative considerations suggest that a few mesodermal cells might perform more than three mitoses.     

Early cellular interactions promote embryonic axis formation in Xenopus laevis

We have attempted to define the location and mode of action of axial determinants in the egg of Xenopus laevis. To this end, we transplanted small numbers of blastomeres from normal 64-cell stage embryos into synchronous recipient embryos which had been irradiated with ultraviolet light prior to first cleavage. Without transplantation, such embryos fail to develop dorsal structures of the embryonic body axis. We found that one to three blastomeres transplanted from the vegetal-most octet of cells can effect complete or partial rescue of of axis development in a recipient, provided that the donor cells derive from the quadrant just under the prospective dorsal marginal region. These same cells, when transplanted into the ventral vegetal quadrant of a normal 64-cell embryo, cause the formation of a complete second body axis. In contrast, other cells from the vegetal octet of normal donors fail to cause axis formation. When the rescuing donor cells are labeled with a lineage-restricted fluorescent marker, we find that their progeny do not contribute to the axial structures of the recipient. Progeny of the transplanted cells are found below the level of the blastopore in the early gastrula and eventually give rise to portions of the gut, as is their fate in normal development. These results, in agreement with those of Nieuwkoop (P.D. Nieuwkoop, 1977, Curr. Top. Dev. Biol. 11, 115-132), imply that the dorsal-most vegetal cells of the 64-cell embryo receive from the egg cytoplasm a set of determinants enabling them to induce neighboring cells to undertake axis formation. We discuss the relationship between axis induction in rescued irradiated embryos and axis determining processes in normal embryogenesis.     

Survival capacity of haploid-diploid goldfish chimeras

In teleosts, haploidy has been considered to be inviable due to the expression of abnormalities during embryogenesis, but the recent report of live haploid-diploid mosaic fish suggests the probable improvement of survival capacity by adding diploid cells or tissues to haploid embryos. In order to examine such possibilities, two types of haploid-diploid goldfish chimeric embryos were produced by transplantation of blastoderm between the normally fertilized diploid and the artificially induced gynogenetic haploid: the haploid-base chimera with the diploid upper half on the haploid lower half blastoderm and the diploid-base chimera with the haploid upper half on the diploid lower half blastoderm. Fluorescent detection of FITC-labeled cells, subsequent histochemical detection of biotin-labeled haploid cells and flow-cytometrical detection of both haploid and diploid cells proved successful induction of the haploid-diploid chimera. Both types of chimeric embryos demonstrated much better survival capacity than pure haploid individuals, but all the haploid-base chimeras died before 10 days after fertilization due to the expression of edema, whereas several diploid-base chimeras survived until 16 months after fertilization when the experiment was ended. This concluded diploid-base chimeras became viable by adding diploid cells to haploid embryos. However, the proportion of transplanted haploid cells was reduced and the distribution of these cells was limited to certain organs because survivors exhibited haploid cells only in brain, eye and/or skin. These results suggest possible elimination of haploid cells from the organs originated from ectoderm.     

Normal Female Germ Cell Differentiation Requires the Female X Chromosome to Autosome Ratio and Expression of Sex-Lethal in DROSOPHILA MELANOGASTER

In somatic cells of Drosophila, the ratio of X chromosomes to autosomes (X:A ratio) determines sex and dosage compensation. The present paper addresses the question of whether germ cells also use the X:A ratio for sex determination and dosage compensation. Triploid female embryos were generated which, through the loss of an unstable ring-X chromosome, contained some germ cells of 2X;3A constitution in their ovaries. Such germ cells were shown to differentiate along one of two alternative pathways: a minority developed into normal female oocytes and eggs; the majority developed into abnormal multicellular cysts. An X:A ratio of 1 is, therefore, required in female germ cell development, at least in the mature ovary after stem cell division. Abnormal development of female germ cells was also observed when 2X;2A germ cells which were homozygous or trans-heterozygous for mutant alleles at the Sex-lethal locus were transplanted into normal female host embryos at the blastoderm stage. Germ cells homozygous for amorphic alleles failed to give rise to normal eggs. Instead, they formed multicellular cysts, very similar to those formed by 2X;3A cells. Zygotic Sxl+ activity is, therefore, also necessary for the development of normal female germ cells. No abnormalities were detected in transplanted germ cells from female embryos whose mothers had been homozygous for the mutation daughterless. When normal XY germ cells were transplanted into female embryos, no traces of such cells could be found in the adult ovary. XY germ cells seem, therefore, not to develop as far as 2X;3A or Sxl homozygous cells in a female gonad. This indicates that neither 2X;3A nor Sxl homozygous germ cells are equivalent to normal XY germ cells.     

Germ-line chimera by lower-part blastoderm transplantation between diploid goldfish and triploid crucian carp

Germ-line chimerism was successfully induced by blastoderm transplantation from donor triploid crucian carp, which reproduces gynogenetically, to recipient diploid goldfish, which reproduces bisexually. Lower part of donor blastoderm including primordial germ cells (PGCs) was sandwiched between recipient blastoderm at the mid- to late-blastula stage. When donor grafts were prepared from intact embryos or ventralized ones by removing vegetal yolk hemisphere at the 1- to 2-cell stage, malformations including double axes were observed in the resultant chimeras transplanted with grafts from intact embryos at the hatching stage, while a few malformations in those from ventralized embryos. PGCs originated from donor grafts were observed around the gonadal anlage at 10 days post-fertilization in chimeras. When ploidy of erythrocytes and epidermal cells in chimeric fish was examined by flow-cytometry, no triploid cells were detected at 1- and 5-year-old chimeras. Three-year-old chimeric fish (n=5) laid eggs originated from the donor together with those from the recipient. The frequency of eggs from the donor crucian carp blastoderm varied from 3.1 to 89.3% between chimeras.     

Prebursal stem cells in the intraembryonic mesenchyme of the chick embryo at 7 days of incubation.

Cyclophosphamide-treated 18-day-old chick embryos were transplanted with cells from 7-day intraembryonic mesenchyme; the recipients and donors were identical at the major histocompatibility locus. At the age of 35 days, the cell recipients were studied to determine the reconstitution capacity of the transplanted cells. The transplantation resulted in a complete restoration of IgM and IgG class antibody production against human gammaglobulin and Brucella abortus, and of microscopic morphology of the bursa of Fabricius and of the germinal center formation in the spleen. These findings demonstrate that 7-day intraembryonic mesenchyme of the chick embryo harbor prebursal stem cells. These findings confirm our previous observations in the yolk sac-embryo chimeras indicating that lymphoid stem cells originate in the intraembryonic hematopoietic sites.     

Analysis of the Drosophila maternal effect mutant MAT(3)1 by pole cell transplantation experiments

Summary Pole cell transplantations were used to construct germ line mosaics of the Drosophila melanogaster maternal effect mutant mat(3)1. The mutant is of particular interest since the development of embryos derived from homozygous mat(3)1 females is arrested at the pole cell stage. Such embryos form exclusively pole cells and no blastoderm cells. By means of germ line mosaics we could demonstrate the primary target tissue of mutant gene expression. For normal development the mat(3)1 ⁺gene has to be expressed in the germ line. Pole cells formed in defective embryos derived from homozygous mutant mothers were transplanted into normal recipient embryos to test their developmental potential. Heterozygous mat(3)1 pole cells were found to form fertile gametes in both sexes whereas homozygous mat(3)1 pole cells form fertile gametes only in males. The lack of progeny derived from homozygous mat(3)1 donor pole cells in recipient females further demonstrates the germ line autonomy of the mat(3)1 mutation. Pole cells from defective embryos that are transplanted into normal hosts colonize the gonads with the same frequency as donor pole cells derived from normal embryos. This indicates that mat(3)1 derived pole cells are normal with respect to their function as germ cells and that the mat(3)1 mutant might therefore offer a convenient source for the mass isolation of functional pole cells.