Manipulation of blastodermal cells

Blastodermal cells isolated from newly laid, unincubated eggs are virtually uncommitted cells that exhibit many of the properties of pluripotential stem cells. They can be transferred from donor to recipient embryos and contribute to both somatic tissues and the germline. Blastodermal cells that have been maintained in culture for 7 d express the epitopes ECMA-7 and SSEA-1, which are also expressed by mouse embryonic stem cells. After culture for up to at least 7 d, blastodermal cells retain the ability to differentiate into somatic tissues and the germline both in vivo and in vitro. Proliferation in the absence of differentiation of blastodermal cells is stimulated by the presence of Leukemia Inhibitory Factor (LIF) and other ligands that interact with the gp130 receptor, and differentiation is stimulated by exposure to retinoic acid. Blastodermal cells also possess high levels of telomerase activity, which is shared by immortalized cells and cells within the germline. Blastodermal cells can be transfected and will express foreign genes both in vivo and in vitro. Transfected cells can be isolated by fluorescence activated cell sorting and can be cryopreserved without losing their ability to contribute to either somatic tissues or the germline. These properties of blastodermal cells make them ideal vectors for introducing genetic modifications to the germline.

Epithelial differentiation in Drosophila

Our understanding of epithelial development in Drosophila has been greatly improved in recent years. Two key regulators of epithelial polarity, Crumbs and DE-cadherin, have been studied at the genetic and molecular levels and a number of additional genes are being analyzed that contribute to the differentiation of epithelial cell structure. Epithelial architecture has a profound influence on morphogenetic movements, patterning and cell-type determination. The combination of embryological and genetic/molecular tools in Drosophila will help us to elucidate the complex events that determine epithelial cell structure and how they relate to morphogenesis and other developmental processes.

Cellularization in locust embryos occurs before blastoderm formation

In Drosophila intracellular gradients establish the pattern of segmentation by controlling gene expression during a critical syncytial stage, prior to cellularization. To investigate whether a similar mechanism may be exploited by other insects, we examined the timing of cellularization with respect to blastoderm formation in an insect with extreme short-germ development, the African desert locust, Schistocerca gregaria. Using light and electron microscopic techniques, we show that the islands of cytoplasm surrounding cleavage nuclei are largely isolated from their neighbours, allowing cleavage to proceed asynchronously. Within a short time of their arrival at the surface and prior to blastoderm formation, nuclei become surrounded by complete cell membranes that block the free uptake of dye (10,000 kDa) from the yolk. Our results imply that the formation of the blastoderm disc involves the aggregation of cells at the posterior pole of the egg and not the migration of nuclei within a syncytial cytoplasm. These findings suggest that the primary cleavage syncytium does not play the same role in patterning the locust embryo as it does in Drosophila. However, we do identify a syncytial nuclear layer that underlies the forming blastoderm and remains in continuity with the yolk.

Centriole and centrosome dynamics during the embryonic cell cycles that follow the formation of the cellular blastoderm in Drosophila

We have used immunofluorescence and electron microscopy to examine centrosome dynamics during the first postblastodermic mitoses in the Drosophila embryo. The centrosomal material, as recognized by antibodies against CP190 and gamma-tubulin, does not show the typical shape changes observed in syncytial embryos, but remains compact throughout mitosis. Centrioles, however, behave as during the syncytial mitoses, with each daughter cell inheriting two separated centrioles at the end of telophase. During interphase in epithelial cells that have a distinct G1 phase, two isolated centrioles are found, suggesting that the separation of sister centrioles is tightly coupled to a mitotic oscillator in both the "abbreviated" and the "complete" embryonic division cycles. The centrioles of the Drosophila embryo sharply differed from the sperm basal body, having a cartwheel structure with nine microtubular doublets and a central tubule. This "immature" centriolar morphology was shown to persist throughout embryonic development, clearly demonstrating that these centrioles are able to replicate despite their apparently neotenic structure.

Distribution of blastodermal cells transferred to chick embryos for chimera production using windowed eggs

1. To improve the production of chimeras, the distribution of donor blastodermal cells after transferring into recipient embryos was examined morphologically. 2. Donor blastodermal cells were distributed near the site of injection in the epiblast and in the subgerminal cavity and yolk. Some filled the hole made by the micropipette and were distributed outside the epiblast. Many were buried in yolk. In some cases, more donor blastodermal cells were located in the yolk than in the subgerminal cavity and some were located 800 microm below the under-surface of the epiblast. 3. It is recommended that injection should be as shallow as possible to increase the proportion of chimeras produced, and that some means is needed to prevent blastodermal cells from escaping from the hole produced by injection.

Production of chicken chimeras from injection of frozen-thawed blastodermal cells

To execute a strategy for reconstituting genetic resources from cryopreserved blastodermal cells, experiments were conducted to optimize conditions for producing chimeric chickens from frozen-thawed blastodermal cells. Stage X blastodermal cells were collected from Barred Plymouth Rock embryos and dispersed. Cells were resuspended in 10% dimethyl sulfoxide in Dulbecco's modified Eagle's medium (DMEM) containing 20% fetal bovine serum, and distributed into plastic ampules. Cell suspensions were seeded to induce ice formation at -7 C, cooled from -7 to -35 C at 1 C/min and then ampules were plunged into liquid nitrogen. Thawing was done by plunging the ampules into warm water (37 C) for 3 min. After centrifugation, the supernatant was replaced with DMEM, and dead or broken cells were removed by density gradient centrifugation. Approximately 500 cells were injected into irradiated Stage X White Leghorn recipient embryos. Following incubation, several somatic chimeras were produced. The frequency of somatic chimerism when fresh (unfrozen) cells, or cells that were frozen and selected by density gradient centrifugation on Percoll or Nycoprep were injected into recipient embryos was 84, 79, and 85%, respectively. The percentage of donor-derived pigmentation in the down of these chimeric chickens was 79, 50, and 58%, respectively. Germline chimerism was determined by mating the chimeras that survived to sexual maturity to Barred Plymouth Rocks. Nine of 16 birds (56.2%) injected with fresh cells, 2 of 26 birds (7.7%) injected with cells that were frozen and selected by density gradient centrifugation on a Percoll gradient, and 3 of 26 birds (11.5%) injected with cells that were frozen and selected on a Nycoprep gradient showed germline transmission; the percentage of donor-derived progeny in these chimeras were 29.5, 5.2, and 6.8%, respectively. The Barred Plymouth Rock donor stock was "reconstituted" by inter se mating of germline male and female chimeras. These data demonstrate that the strategy described here for reconstituting genetic resources from cryopreserved blastodermal cells via chimeric intermediates can be performed successfully.

Spatial relationship between endophyll, primordial germ cells, sickle endoblast and upper layer in cultured avian blastoderms

By isotopic quail-chicken chimera experiments of the Rauber's sickle or by radioactive labelling and isotopically replacing of the caudal endophyllic sheet in unincubated avian blastoderms, followed by culture, we demonstrated that the displacement of the endophyll by the cranially extending sickle endoblast is not exclusively a mechanical phenomenon, as suggested by earlier studies (Vakaet, 1962 a, b). Indeed, our study suggests that the sickle endoblast also migrates centripetally very soon (already after 5 h) in and through the caudal endophyll before ingression of upper layer cells takes place. We also describe the early spatial relationship between the three elementary tissues (endophyll, Rauber's sickle, upper layer) (Callebaut et al, 1996a) and the induction phenomena between quail sickle endoblast and chicken upper layer (UL) during the formation of the primitive groove. The latter already develops before ingression occurs. We found no evidence for an endophyllic origin of avian primordial germ cells.

Adepithelial cells in Drosophila melanogaster: origin and cell lineage

We have analysed the cell lineage relationships between larval and imaginal mesodermal primordia at the blastoderm stage by homotopic single cell transplantations. The primordia of adepithelial cells, the precursors of adult thoracic muscles, are restricted to the region from 50 to 65% egg length within the ventrally located mesodermal anlage. Clones of adepithelial cells always show a common cell lineage with larval muscles and in some cases additionally with larval fat body. This proves that at the blastoderm stage the determination of larval vs. imaginal mesodermal primordia has not yet taken place. Larval somatic muscle clones, in contrast to clones in the ectoderm, can overlap several segments, whereas clones of adepithelial cells are always restricted to imaginal discs of one segment.

Comparative development of the turkey and chicken embryo from cleavage through hypoblast formation

The development of the turkey and chicken embryo from the first cleavage division through hypoblast formation is described. The early development of the chicken embryo has been categorized into 14 stages. A similar staging sequence for the turkey was not proposed until 1993, when we described the early development of the turkey embryo, which was divided into 11 stages. Comparatively, differences in the temporal and spatial development of the turkey and chicken blastoderm were evident. Of significance is the observation that at oviposition the turkey is in Stage VII and characterized by the first signs of area pellucida formation. In contrast, the chicken embryo at oviposition is in Stage X and area pellucida formation is completed. Similarly, the hypoblast, which is already apparent in the Stage X chicken embryo, does not appear in the turkey embryo until the egg is incubated. Furthermore, the anterior-posterior (head-tail) axis in the early embryo is achieved prior to oviposition in the chicken but after the onset of incubation in the turkey. It is apparent that the turkey embryo is less mature than the chicken embryo at oviposition. Whether this distinction is related to differences between the hatchability of turkey and chicken eggs is not yet known.

Map of the Anlage fields in the avian unincubated blastoderm

By excision at different sites of rectangular fragments from unincubated chicken blastoderms and replacement by isotopic fragments from unincubated quail blastoderms, we could make the first complete map of the Anlage fields in the freshly laid avian blastoderm. All the Anlage fields (Fig. 11) are found in the upper layer (UL) of the caudal half of the area centralis (bordered by the Rauber-Koller's sickle). In the UL of the area marginalis, peripheral to Rauber-Koller's sickle, neither gastrulation nor neurulation phenomena could be observed. Similar heterotopic replacement experiments indicate that before incubation, the different parts of the UL of the area centralis are still uncommitted or reversibly committed. The Anlage fields of chordamesoblast and definitive endoderm (gut endoderm) in unincubated avian blastoderms appeared to be disposed caudally in the caudal half of the area centralis. As far as we know we are the first to demonstrate that the Anlage field of the definitive gut endoderm (which is derived from the upper layer: Hunt, 1937; Vakaet, 1962b) is localized in the most caudal upper layer part of the area centralis just centrally to the Rauber-Koller's sickle. The Anlage field of the neural plate is localized in the upper layer over the more cranial endophyll. The Anlage of the brain is shield-shaped, whilst the other Anlage fields are sickle-shaped, parallel with the Rauber-Koller's sickle. Their general hemicircular disposition and form still seem to reflect (together with the Rauber-Koller's sickle) the original ooplasmic radial symmetry (Callebaut, 1972) combined with the eccentricity of the deep layer components, which was observed during early symmetrization by gravitational orientation of the egg yolk (Callebaut, 1993a,b). The Rauber-Koller's sickle might be homologous with the vegetal dorsalizing cells or centre of Nieuwkoop (1973) in amphibian blastulas.

A cluster of noninvoluting endocytic cells at the margin of the zebrafish blastoderm marks the site of embryonic shield formation

In zebrafish embryos, the nascent embryonic shield first appears as a thickening in the germ ring of the mid-epiboly blastoderm. This site defines the dorsal side of the developing embryo. In this paper, we report that the site of embryonic axis formation is marked earlier at the late-blastula stage by the appearance of a cluster of cells with unique endocytic activities. This cluster of cells is composed of enveloping layer epithelial cells and one to two layers of underlying deep cells. Unlike other marginal blastomeres, cells in this cluster do not participate in involution as the blastoderm undergoes epiboly. These noninvoluting endocytic marginal (NEM) cells can be selectively labeled by applying membrane impermeant fluorescent probes to pre-epiboly and mid-epiboly embryos. During embryonic shield formation, deep cells in the NEM cell cluster rearrange and are displaced forward to the leading edge of the blastoderm. As deep NEM cells move into this location, they become a group of cells known as "forerunner cells." Between 60%- and 80%-epiboly, the forerunner cells coalesce into a coherent cell cluster that forms a wedge-shaped cap at the leading edge of the blastoderm. During embryonic axis formation, deep cells migrate and converge toward the embryonic midline, which is defined by the center of the forerunner cell cluster. At approximately 90% epiboly, the forerunner cell cluster becomes overlapped by the constricting germ ring. At tailbud stage, forerunner cells form the dorsal roof of Kupffer's vesicle, which is located ventral to the nascent chordoneural hinge. On the basis of previous grafting studies and known dorsal gene expression patterns, we discuss possible roles that the NEM/forerunner cell cluster may play in teleost axis formation.

The nonreceptor protein tyrosine phosphatase corkscrew functions in multiple receptor tyrosine kinase pathways in Drosophila

Corkscrew (csw) encodes a nonreceptor protein tyrosine phosphatase (PTPase) that has been implicated in signaling from the Torso receptor tyrosine kinase (RTK). csw mutations, unlike tor mutations, are associated with zygotic lethality, indicating that Csw plays additional roles during development. We have conducted a detailed phenotypic analysis of csw mutations to identify these additional functions of Csw. Our results indicate that Csw operates positively downstream of other Drosophila RTKs such as the Drosophila epidermal growth factor receptor (DER), the fibroblast growth factor receptor (Breathless), and likely other RTKs. This model is substantiated by specific dosage interactions between csw and DER. It is proposed that Csw is part of the evolutionarily conserved "signaling cassette" that operates downstream of all RTKs. In support of this hypothesis, we demonstrate that SHP-2, a vertebrate PTPase similar to Csw and previously implicated in RTK signaling, encodes the functional vertebrate homologue of Csw.

Contributions to somatic and germline lineages of chicken blastodermal cells maintained in culture

Chicken blastodermal cells were cultured for 48 hr as explanted intact embryos, as dispersed cells in a monolayer, or with a confluent layer of mouse fibroblasts. The cells were then dispersed and injected into stage X (E-G&K) recipient embryos that were exposed to 600 rads of irradiation from a 60Co source. Regardless of the conditions in which the cells were cultured, chimeras with contributions to both somatic tissues and the germline were observed. When blastodermal cells were co-cultured with mouse embryonic fibroblasts, significantly more somatic chimeras were observed and the proportion of feather follicles derived from donor cells was increased relative to that observed following the injection of cells derived from explanted embryos or monolayer cultures. Culture of blastodermal cells in any of the systems, however, yielded fewer chimeras that exhibited reduced contributions to somatic tissues in comparison to the frequency and extent of somatic chimerism observed following injection of freshly prepared cells. Contributions to the germline were observed at an equal frequency regardless of the conditions of culture, but were significantly reduced in comparison to the frequency and rate of germline transmission following injection of cells obtained directly from stage X (E-G&K) embryos. These data demonstrate that some cells retain the ability to contribute to germline and somatic tissues after 48 hr in culture and that the ability to contribute to the somatic and germline lineages is not retained equally.

Long-term in vitro culture and characterisation of avian embryonic stem cells with multiple morphogenetic potentialities

Petitte, J.N., Clarck, M.E., Verrinder Gibbins, A. M. and R. J. Etches (1990; Development 108, 185–189) demonstrated that chicken early blastoderm contains cells able to contribute to both somatic and germinal tissue when injected into a recipient embryo. However, these cells were neither identified nor maintained in vitro. Here, we show that chicken early blastoderm contains cells characterised as putative avian embryonic stem (ES) cells that can be maintained in vitro for long-term culture. These cells exhibit features similar to those of murine ES cells such as typical morphology, strong reactivity toward specific antibodies, cytokine-dependent extended proliferation and high telomerase activity. These cells also present high capacities to differentiate in vitro into various cell types including cells from ectodermic, mesodermic and endodermic lineages. Production of chimeras after injection of the cultivated cells reinforced the view that our culture system maintains in vitro some avian putative ES cells.

Magnetic resonance microscopy and spectroscopy reveal kinetics of cryoprotectant permeation in a multicompartmental biological system

Successful cryopreservation of most multicompartmental biological systems has not been achieved. One prerequisite for success is quantitative information on cryoprotectant permeation into and amongst the compartments. This report describes direct measurements of cryoprotectant permeation into a multicompartmental system using chemical shift selective magnetic resonance (MR) microscopy and MR spectroscopy. We used the developing zebrafish embryo as a model for studying these complex systems because these embryos are composed of two membrane-limited compartments: (i) a large yolk (surrounded by the yolk syncytial layer) and (ii) differentiating blastoderm cells (each surrounded by a plasma membrane). MR images of the spatial distribution of three cryoprotectants (dimethyl sulfoxide, propylene glycol, and methanol) demonstrated that methanol permeated the entire embryo within 15 min. In contrast, the other cryoprotectants exhibited little or no permeation over 2.5 h. MR spectroscopy and microinjections of cryoprotectants into the yolk inferred that the yolk syncytial layer plays a critical role in limiting the permeation of some cryoprotectants throughout the embryo. This study demonstrates the power of MR technology combined with micromanipulation for elucidating key physiological factors in cryobiology.

Ingression during early gastrulation of fundulus

This study demonstrates that involution does not occur during early gastrulation of Fundulus heteroclitus, prior to and during germ ring formation. This conclusion has been reached by following the motile behavior of large numbers of individual cells. Instead of involution, superficial deep cells of the marginal region of the blastoderm undergo ingression. They do not leave the surface as members of a flowing cohesive sheet, but sink beneath rather haphazardly as individuals. Indeed, during much of ingression, many marginal cells are so loosely arranged that they move about freely on the yolk syncytial layer. A small proportion of the cells initially at the blastoderm margin undergo ingression there, but most recede from the margin and ingress supramarginally one to three cell diameters from the margin. Cells that are initially supramarginal ingress mainly there, sometimes quite far from the margin. Only a small number moves to the margin and ingresses there. Interestingly, although most ingression takes place supramarginally, much occurs close to the margin-up to one to four cells away. Ingression begins immediately after the onset of epiboly and is most active before appearance of the germ ring; it ceases quite soon thereafter. It is also more active dorsally than ventrally, correlating with the earlier formation of the germ ring dorsally. Ingression constitutes the first invasive cellular activity of development. Significantly, it proceeds by blebbing locomotion, a noncontact inhibiting mode of cell movement. The possible broader import of these discoveries is given appropriate attention.

armadillo, bazooka, and stardust are critical for early stages in formation of the zonula adherens and maintenance of the polarized blastoderm epithelium in Drosophila

Cellularization of the Drosophila embryo results in the formation of a cell monolayer with many characteristics of a polarized epithelium. We have used antibodies specific to cellular junctions and nascent plasma membranes to study the formation of the zonula adherens (ZA) in relation to the establishment of basolateral membrane polarity. The same approach was then used as a test system to identify X-linked zygotically active genes required for ZA formation. We show that ZA formation begins during cellularization and that the basolateral membrane domain is established at mid-gastrulation. By creating deficiencies for defined regions of the X chromosome, we have identified genes that are required for the formation of the ZA and the generation of basolateral membrane polarity. We show that embryos mutant for both stardust (sdt) and bazooka (baz) fail to form a ZA. In addition to the failure to establish the ZA, the formation of the monolayered epithelium is disrupted after cellularization, resulting in formation of a multilayered cell sheet by mid-gastrulation. SEM analysis of mutant embryos revealed a conversion of cells exhibiting epithelial characteristics into cells exhibiting mesenchymal characteristics. To investigate how mutations that affect an integral component of the ZA itself influence ZA formation, we examined embryos with reduced maternal and zygotic supply of wild-type Arm protein. These embryos, like embryos mutant for both sdt and baz, exhibit an early disruption of ZA formation. These results suggest that early stages in the assembly of the ZA are critical for the stability of the polarized blastoderm epithelium.

Regulation and function of the terminal gap gene huckebein in the Drosophila blastoderm

Pattern formation in Drosophila involves a cascade of maternal and zygotic factors which are spatially restricted in the blastoderm embryo. Here we show that the Drosophila gene huckebein (hkb), a member of the gap gene class of segmentation genes, is not only required for suppression of segmentation in the terminal regions of the embryo but also to spatially restrict germ layer formation at the beginning of gastrulation. hkb encodes a Sp1/egr-like zinc finger protein, likely to be a transcription factor. Its absence in hkb mutants causes the ectodermal and mesodermal primordia to expand at the expense of endoderm anlagen, which are completely absent in null alleles of hkb. Conversely, ectopic expression of hkb inhibits the formation of the major gastrulation fold which gives rise to the mesoderm and prevents normal segmentation in the ectoderm of the trunk region.

Primordial germ cell migration in the Ceratitis capitata embryo

In this study we followed the behavior of germ cell precursors in the early embryo of the dipteran Ceratitis capitata using conventional fluorescence, laser scanning confocal and transmissiom electron microscopies. During cellularization the pole cells formed a cluster which lodged in a roundish break in the blastoderm at the posterior pole of the embryo. When gastrulation began, the pole cells shifted dorsally and during elongation of the germ band moved into the posterior midgut primordium. Pole cell morphology suggested that these cells were motile until the early stages of development.

Larval and imaginal pathways in early development of Drosophila

In holometabolous development, higher insects have two different life forms, the larva and the imago. Both larval and imaginal cells are derived from cells of the blastoderm stage. After the final embryonic wave of mitosis, however, only the imaginal cells remain diploid, proliferate massively and do not differentiate until metamorphosis. The separation of these two pathways was described by many authors as a fundamental process that must take place at a very early stage of development, most probably the blastoderm stage. Mainly by using single cell transplantations at the blastoderm or early gastrula stages, respectively, we found common cell lineages between larval and imaginal structures by clones overlapping in the ectoderm (i.e. larval epidermal cells and imaginal discs within a segment, or larval and imaginal salivary gland cells), the mesoderm (i.e. larval somatic muscles and adepithelial cells), and the endoderm (i.e. larval and imaginal midgut cells). From these findings we conclude that it seems to be a principle in Drosophila embryogenesis that the separation of larval and imaginal pathways is postponed to a later developmental stage.

Tyrosine phosphorylation accompanying the cellularization of the syncytial blastoderm of Drosophila

At an early stage in embryogenesis, the Drosophila blastoderm is a syncytium in which approximately 6000 nuclei align under the plasma membrane. During the interphase of nuclear cycle 14, a wave of membrane formation descends from the blastoderm surface to enclose each nucleus in an intact cell membrane. We show by immunofluorescence microscopy that the membrane-formation process is closely accompanied in space and time by a wave of tyrosine phosphorylation, suggesting that one or more tyrosine kinases and phosphatases are active in the process.

The 95F unconventional myosin is required for proper organization of the Drosophila syncytial blastoderm

The 95F myosin, a class VI unconventional myosin, associates with particles in the cytoplasm of the Drosophila syncytial blastoderm and is required for the ATP- and F-actin-dependent translocation of these particles. The particles undergo a cell cycle-dependent redistribution from domains that surround each nucleus in interphase to transient membrane invaginations that provide a barrier between adjacent spindles during mitosis. When 95F myosin function is inhibited by antibody injection, profound defects in syncytial blastoderm organization occur. This disorganization is seen as aberrant nuclear morphology and position and is suggestive of failures in cytoskeletal function. Nuclear defects correlate with gross defects in the actin cytoskeleton, including indistinct actin caps and furrows, missing actin structures, abnormal spacing of caps, and abnormally spaced furrows. Three-dimensional examination of embryos injected with anti-95F myosin antibody reveals that actin furrows do not invaginate as deeply into the embryo as do normal furrows. These furrows do not separate adjacent mitoses, since microtubules cross over them. These inappropriate microtubule interactions lead to aberrant nuclear divisions and to the nuclear defects observed. We propose that 95F myosin function is required to generate normal actin-based transient membrane furrows. The motor activity of 95F myosin itself and/or components within the particles transported to the furrows by 95F myosin may be required for normal furrows to form.

A sex-specific number of germ cells in embryonic gonads of Drosophila

Male first instar larvae possess more germ cells in their gonads than female larvae of the same stage. To determine the earliest time point of sexual dimorphism in germ cell number, we have counted the germ cells of sexed embryos at different developmental stages. We found no difference in germ cell number of male and female embryos at the blastoderm and early gastrulation stage, or when germ cells are about to exit the midgut pocket. We find, however, that males have significantly more germ cells than females as soon as the germ cells are near the places where the gonads are formed and in all later stages. Our results show that germ cells are subject to a sex-specific control mechanism that regulates the number of germ cells already in embryos.

Mesodermal patterning during avian gastrulation and neurulation: experimental induction of notochord from non-notochordal precursor cells

The cells that are normally fated to form notochord occupy a region at the rostral tip of the primitive streak at late gastrula/early neurula stages of avian and mammalian development. If these cells are surgically removed from avian embryos in culture, a notochord will nonetheless form in the majority of cases. The origin of this reconstituted notochord previously had not been investigated and was the objective of this study. Chick embryos at late gastrulal early neurula stages were cultured, and the rostral tip of the primitive streak including Hensen's node was removed and replaced with non-node cells from quail epiblast to ensure that the cells normally fated to be notochord would be absent and that healing of the blastoderm would occur. Embryos were allowed to develop for 24 hr, and the presence and origin (host or graft) of the notochord were assessed using antibodies against notochord or quail cells. Two notochords typically developed; both were almost exclusively of host origin. The primitive streak, and in some cases adjacent tissues, was removed from another group of embryos in an attempt to estimate the mediolateral position and extent of the cells required to form reconstituted notochord. Additional experimental embryos with and without grafts were transected at various rostrocaudal levels in an attempt to estimate the rostrocaudal extent of the cells required to form reconstituted notochord. Finally, various levels of the primitive streak either were placed in a neutral environment (the germ cell crescent) or were grafted in place of the node. Collective results from all experiments indicate that the areas lateral to the rostral portion of the primitive streak, estimated to have a rostrocaudal span of less than 500 microns and a mediolateral extent of less than 250 microns, are critical for formation of the reconstituted notochord. Fate mapping and histological examination of this region identify 4 possible precursor cell populations. Further studies are underway to determine which of the 4 possible precursor cell types forms or induces the reconstituted notochord, and which tissue interactions underlie this change in cell fate.

Mitotic delay dependent survival identifies components of cell cycle control in the Drosophila blastoderm

The Drosophila body pattern is laid down by maternal and zygotic factors which act during the early phase of embryonic development. During this period, nascent zygotic transcripts longer than about 6 kilobases are aborted between the rapid mitotic cycles. Resurrector1 (Res1) and Godzilla1 (God1), two newly identified dominant zygotic suppressor mutations, and a heterozygous maternal deficiency of the cyclin B locus, complement the partial loss of function of the segmentation gene knirps (kni) by extending the length of mitotic cycles at blastoderm. The mitotic delay caused by Res1 and God1 zygotically and by the deficiency of the cyclin B locus maternally allows the expression of a much longer transcript of a kni cognate gene normally aborted between the short mitotic cycles and consequently allows survival of kni mutant progeny. In addition to the practical benefits of identifying mutations in Drosophila cell cycle regulatory genes as suppressors of kni, our results have evolutionary implications regarding the flexibility of the genome to meet sudden selective pressures by recruiting cognate genes to function.