A gene with sequence similarity to Drosophila engrailed is expressed during the development of the neural tube and vertebrae in the mouse

The mouse genes En-1 and En-2 display sequence similarity, in and around the homeobox region, to the engrailed family in Drosophila. This paper describes their pattern of expression in the 12.5-day mouse embryo as determined by in situ hybridization. En-2 is expressed in a subset of cells expressing En-1. Both genes are expressed in the developing midbrain and its junction with the hindbrain. In addition, En-1 is expressed in the floor of the hindbrain, a restricted ventrolateral segment of the neural tube throughout the trunk and anterior part of the tail, the dermatome of tail somites, the centrum and costal processes in developing vertebrae, a restricted region of facial mesenchyme and the limb-bud ectoderm. Supplementary studies of 9.5-day and 10.5-day embryos showed that the same pattern of expression pertained in the neural tube, but that expression in the somites is at first confined to the dermatome and later found at a low level in restricted sclerotomal regions. Both genes are expressed in restricted domains which do not cross tissue-type boundaries. In several instances, however, boundaries of expression lie within morphologically undifferentiated tissue. These results suggest that En-1 and En-2 may be involved in the establishment or maintenance of the spatial integrity of specific domains within developing tissues.     

Crossregulation between En-2 and Wnt-1 in chick tectal development

En-1, En-2 and Wnt-1 are proposed to be essential signals for the development of the optic tectum in chick embryos. Drosophila engrailed and wingless , homologs of En ( En-1 and En-2 ) and Wnt-1 , respectively, have been shown to crossregulate each other. In the present paper, it is reported that crossregulation between En-2 and Wnt-1 is preserved in the development of the chick optic tectum. When En-2 is overexpressed by the replication competent retroviral vector, Wnt-1 is expressed ectopically at the dorsal midline of the diencephalon. When Wnt-1 is introduced extrinsically either by ectopic transplantation of mesencephalon, or by implantation of Wnt-1 producing cells, En-2 is induced ectopically at the dorsal midline of the tel-diencephalic border. Thus, ectopic expression of En-2 and Wnt-1 leads to crossregulation of each other in the chick brain. As diencephalon transdifferentiates into the optic tectum by an appropriate signal, the crossregulation of En-2 and Wnt-1 in the diencephalon may mimic the relationship required for early development in the tectum.     

The cellular environment controls the expression of engrailed-like protein in the cranial neuroepithelium of quail-chick chimeric embryos.

We have previously shown that one of two chicken engrailed-like genes, chick En-2, is expressed in a restricted region of the early chick embryo brain: the mes/metencephalon (Gardner et al. 1988). In this study, we examine the role of the cellular environment in regulation of engrailed-like (En) protein expression in quail-chick chimeric embryos. Two types of transplant surgery were performed at the 9-15 somite stage to produce chimeric embryos. In the first, the mid-mesencephalic vesicle or caudal mesencephalic vesicle alar plate (which is En protein-positive) was transplanted from a quail embryo into an En protein-negative region of chick neuroepithelium, the prosencephalon (mMP and cMP grafts, respectively). In the second reciprocal surgery, prosencephalic alar plate which is En protein-negative, was transplanted into the En protein-positive mesencephalic vesicle (PM grafts). A polyclonal antiserum, alpha Enhb-1, which recognizes chick En proteins (Davis et al. 1991) was used to identify En-positive cells 48 h after surgery. In mMP embryos, 71% of integrated grafts had lost En expression (n = 17). In contrast, in cMP grafts, 93% of integrated grafts continued to stain with the antiserum (n = 14). In addition, in 86% of these embryos, the graft induced adjacent chick host diencephalic cells to become En protein-positive as well. All PM grafts contained aEnhb-1-positive cells; such cells never expressed this protein in their normal environment. These early changes in En protein expression correlate well with the morphological changes observed in similar graft surgeries assayed later in development. Thus, our results are consistent with the hypothesis that En genes play a role in the regionalization of the early cranial neuroepithelium.     

The dynamic expression pattern of frzb-1 suggests multiple roles in chick development

The Wnt family of secreted proteins has been shown to have multiple roles in embryonic development. Wnt signals are thought to be propagated by binding to the cysteine-rich extracellular domain (CRD) of Frizzled, a seven-transmembrane-domain cell surface receptor. Secreted Frizzled-related proteins (generally denoted Frzb or Sfrp) possess a domain with a high degree of sequence identity and structural similarity with the CRD of Frizzled. Current data indicate that the cysteine-rich domain of secreted Frzb proteins can bind Wnt proteins, suggesting the possibility that Frzbs compete with membrane-bound Frizzled for Wnt binding and consequently act as competitive inhibitors of Wnt signaling. In order to gain a better understanding of the potential roles of Frzb-1 in chick development, we utilized the polymerase chain reaction to isolate a partial cDNA of the chick orthologue of frzb-1, cfrzb-1, and compared its expression pattern to that of Wnt-1, Wnt-3a, Wnt-5a, Wnt-7a, and Wnt-8c. Whole-mount in situ hybridizations have revealed three major phases of expression for cfrzb-1 in the developing chick. The earliest expression of cfrzb-1 is in cells fated to become neural ectoderm in streak-stage embryos. Expression of cfrzb-1 in the neural ectoderm continues up through stage 8. After stage 8, cfrzb-1 expression is gradually attenuated in the closing neural tube of the trunk and is concomitantly up-regulated in neural crest cells. Finally, cfrzb-1 appears in the condensing mesenchyme of the bones in both the limb and the trunk in stage 25+ embryos. Comparative analysis of the cfrzb-1 and the Wnt gene expression patterns suggests possible interactions between cFrzb-1 and all of the Wnt family members examined.     

Developmental Plasticity of the Prospective Dermatome and the Prospective Sclerotome Region of an Avian Somite

The ventro-medial wall of a somite gives rise to the sclerotome and then to cartilaginous axial skeleton, while the dorso-lateral wall differentiates into the dermomyotome to form dermal mesenchyme and muscle. Although previous studies suggested pluri-potency of somite cell differentiation, apparent pluri-potency may be the result of migration of predetermined cells. To investigate whether the developmental fate of any region is determined, I isolated fragments of a region of a quail somite and transplanted them into chick embryos. When a fragment of the ventral wall of a quail somite, the prospective sclerotome, was transplanted into a chick embryo between the ectoderm and a newly formed somite, the transplanted quail cells were shown to form myotome and mesenchyme in 4-day chimera embryos and to form muscle and dermal tissue in 9-day chimeras. On the other hand, when a fragment of the dorsal wall of a quail somite, the prospective dermomyotome, was transplanted into a chick embryo between the neural tube and a newly formed somite, the graft gave rise to mesenchyme around the neural tube and notochord and then to vertebral cartilage. Thus the developmental fate of a region of a somite was shown not to be determined at the time of somite segmentation, confirming previous observations.     

Engrailed defines the position of dorsal di-mesencephalic boundary by repressing diencephalic fate.

Regionalization of a simple neural tube is a fundamental event during the development of central nervous system. To analyze in vivo the molecular mechanisms underlying the development of mesencephalon, we ectopically expressed Engrailed, which is expressed in developing mesencephalon, in the brain of chick embryos by in ovo electroporation. Misexpression of Engrailed caused a rostral shift of the di-mesencephalic boundary, and caused transformation of dorsal diencephalon into tectum, a derivative of dorsal mesencephalon. Ectopic Engrailed rapidly repressed Pax-6, a marker for diencephalon, which preceded the induction of mesencephalon-related genes such as Pax-2, Pax-5, Fgf8, Wnt-1 and EphrinA2. In contrast, a mutant Engrailed, En-2(F51rE), bearing mutation in EH1 domain, which has been shown to interact with a co-repressor, Groucho, did not show the phenotype induced by wild-type Engrailed. Furthermore, VP16-Engrailed chimeric protein, the dominant positive form of Engrailed, caused caudal shift of di-mesencephalic boundary and ectopic Pax-6 expression in mesencephalon. These data suggest that (1) Engrailed defines the position of dorsal di-mesencephalic boundary by directly repressing diencephalic fate, and (2) Engrailed positively regulates the expression of mesencephalon-related genes by repressing the expression of their negative regulator(s).     

Initiation of dorso-ventral axis during chick limb development

We analysed spatio-temporal expression of dorso-ventral genes - Wnt-7a, En-1, Lmx-1 and Fgf-8 - during both normal and ectopic limb formation following fibroblast growth factor (FGF) application to the flank. We confirm that Wnt-7a is the first of these genes to be expressed in dorsal ectoderm in limb-forming regions. We also noticed patterns and kinetics of gene expression specific to chick that could account for differences observed in ridge formation between chick and mouse. We find that Wnt-7a expression, in dorsal ectoderm, is rapidly and locally induced by FGF application. In contrast, ectopic induction of Lmx-1 expression, in dorsal mesoderm, is much slower, occurs first at a distance from the FGF-2 bead and seems initially independent of direct Wnt-7a signalling during FGF-2 limb induction. Finally, we show that there is no contribution to extra-limb mesoderm from normal limb mesoderm and confirm that flank cells give rise to the extra limb. Furthermore, we suggest that an inhibitor present in the flank normally prevents Lmx-1 expression in this region and restricts its expression to limb-forming regions.     

WNT signals control FGF-dependent limb initiation and AER induction in the chick embryo

A regulatory loop between the fibroblast growth factors FGF-8 and FGF-10 plays a key role in limb initiation and AER induction in vertebrate embryos. Here, we show that three WNT factors signaling through beta-catenin act as key regulators of the FGF-8/FGF-10 loop. The Wnt-2b gene is expressed in the intermediate mesoderm and the lateral plate mesoderm in the presumptive chick forelimb region. Cells expressing Wnt-2b are able to induce Fgf-10 and generate an extra limb when implanted into the flank. In the presumptive hindlimb region, another Wnt gene, Wnt-8c, controls Fgf-10 expression, and is also capable of inducing ectopic limb formation in the flank. Finally, we also show that the induction of Fgf-8 in the limb ectoderm by FGF-10 is mediated by the induction of Wnt-3a. Thus, three WNT signals mediated by beta-catenin control both limb initiation and AER induction in the vertebrate embryo.     

Mitogenic effect of muscle on the neuroepithelium of the developing spinal cord

A previous study revealed that segments of bowel grafted between the neural tube and somites of a younger chick host embryo would induce a unilateral increase in cellularity of the host's neural tube. The current experiments were done to test the hypotheses that muscle tissue in the wall of the gut is responsible for this growth-promoting effect and that the spinal cord enlargement is the result of a mitogenic action on the neuroepithelium. Fragments of skeletal (E8-15) or cardiac muscle (E4-14) were removed from quail embryos and grafted between the neural tube and somites of chick host embryos (E2). Both skeletal and cardiac muscle grafts mimicked the effect of bowel and induced an increase in cell number as well as a unilateral enlargement of the region of the host's neural tube immediately adjacent to the grafts. The growth-promoting effect of muscle-containing grafts was restricted to the neural tube itself and was not seen in proximate dorsal root or sympathetic ganglia. The action of the grafts of muscle was neither species- nor class-specific, since enlargement of the neural tube was observed following implantation of fetal mouse skeletal muscle into quail hosts. Grafts of skeletal muscle or gut increased the number of cells taking up [3H]thymidine in the host's neuroepithelium as early as 9 h following implantation of a graft. The increase in the number of cells entering the S phase of the cell cycle preceded the increase in cell number. These observations demonstrate that muscle-containing tissues can increase the rate of proliferation of neuroepithelial cells when these tissues are experimentally placed together.     

Dorsal dermis development depends on a signal from the dorsal neural tube, which can be substituted by Wnt-1

To investigate the origin and nature of the signals responsible for specification of the dermatomal lineage, excised axial organs in 2-day-old chick embryos were replaced by grafts of the dorsal neural tube, or the ventral neural tube plus the notochord, or aggregates of cells engineered to produce Sonic hedgehog (Shh), Noggin, BMP-2, Wnt-1, or Wnt-3a. By E10, grafts of the ventral neural tube plus notochord or of cells producing Shh led to differentiation of cartilage and muscles, and an impaired dermis derived from already segmented somites. In contrast, grafts of the dorsal neural tube, or of cells producing Wnt-1, triggered the formation of a feather-inducing dermis. These results show that the dermatome inducer is produced by the dorsal neural tube. The signal can be Wnt-1 itself, or can be mediated, or at least mimicked by Wnt-1.     

Mouse-chick neural chimeras

Embryonic chimera production was used to study the developmental processes of the mouse nervous system. The difficulty of performing in situ transplantation experiments of neural primordium of mouse embryo was overcome by isotopic and isochronic grafting of mouse neural tube fragments into chick embryo. Mouse neural tube cells differentiated perfectly in ovo and neural crest cells associated with the grafted neural tube were able to migrate and reach the normal arrest sites of host neural crests. Cranial neural crest cells penetrated into chick facial areas and entered into the development of dental bud structures, participating in vibrissa formation. Depending on graft level, in ovo implanted mouse neural crest cells formed different components of the peripheral nervous system. At trunk level, they located in spinal ganglia and orthosympathetic chains and gave rise to Schwann cells lining the nerves. When implanted into the lumbosacral region, they penetrated into the enteric nervous system. At the precise 18-24 somite level, they colonized host adrenal gland. Mouse neural tube was involved in the mechanisms required to maintain myogenesis in host somites. Furthermore in ovo grafts of mouse cells from genetically modified embryos, in which many mutations induce early death, are particularly useful to investigate cellular events involved in the development of the nervous system and to identify molecular events of embryogenesis.     

Monoclonal antibodies specific to quail embryo tissues: their epitopes in the developing quail embryo and their application to identification of quail cells in quail-chick chimeras.

Quail-chick chimeras have been used extensively in the field of developmental biology. To detect quail cells more easily and to detect cellular processes of quail cells in quail-chick chimeras, we generated four monoclonal antibodies (MAb) specific to some quail tissues. MAb QCR1 recognizes blood vessels, blood cells, and cartilage cells, MAb QB1 recognizes quail blood vessels and blood cells, and MAb QB2 recognizes quail blood vessels, blood cells, and mesenchymal tissues. These antibodies bound to those tissues in 3-9-day quail embryos and did not bind to any tissues of 3-9-day chick embryos. MAb QSC1 is specific to the ventral half of spinal cord and thymus in 9-day quail embryo. No tissue in 9-day chick embryo reacted with this MAb. This antibody binds transiently to a small number of brain vesicle cells in developing chick embryo as well as in quail embryo. A preliminary application of two of these MAb, QCR1 and QSC1, on quail-chick chimeras of neural tube and somites is reported here.     

Examining pattern formation in mouse, chicken and frog embryos with an En-specific antiserum.

We have raised an antiserum, designated alpha Enhb-1, to a portion of the mouse En-2 protein containing the homeodomain. The antiserum detects both the En-1 and En-2 proteins in mouse, chick and Xenopus embryos by Western blot analysis. Using whole-mount immunohistochemistry, combined in some cases with scanning electron microscopy, we have examined the distribution of the proteins in the early embryos of these species. The major features of expression were similar. The initial production of En protein occurred, just before or during the formation of the first somites, in a band of the anterior neural plate in the prospective mid/hindbrain region. Later in development En-1 protein accumulated in the ventral ectoderm of the developing mouse and chick limb buds, indicating that a dorsal-ventral polarity is present as soon as any limb bud swelling is apparent and that, at least in the mouse, this polarity is established independently of the apical ectodermal ridge. In all three species, alpha Enhb-1 bound to a subset of ventro-lateral differentiating neurons in the spinal cord and hindbrain and their pattern of birth in the mouse reflected the division of the hindbrain into rhombomeres. En-1 protein also accumulated in a lateral stripe of dermatome in the mouse and chick, indicating a dorsal-ventral subdivision of this tissue. The results show that En expression is a good marker for pattern formation in a variety of tissues and will be useful in experimental studies designed to characterize further these processes.     

Acceleration of early chick embryo morphogenesis by insulin is associated with altered expression of embryonic genes

In the present study, we show that insulin accelerates early morphogenesis in gastrulating chick embryo explants cultured in vitro, whereas antiserum to insulin adversely affects this process. Comparison between length of body axis of control and treated embryos clearly brings out the significant acceleration of development by excess insulin (0.175 to 17.5 nM). In embryos treated with 87.5 and 175 nM insulin, a high occurrence of abnormalities is observed. Treatment of embryos with antiserum to porcine insulin results in a high percentage of abnormalities, particularly in the forming neural tube. In situ hybridization of whole embryos using digoxigenin-labeled riboprobes showed that insulin modifies the expression of crucial developmental genes within 2 hours. While Brachyury, a pan-mesodermal marker gene, ERNI, the earliest known marker for neural induction in chick, and noggin, important in neural tube patterning, are upregulated, expression of goosecoid, necessary for gastrulation movements, does not appear to be significantly altered. During the same time, insulin does not exert any mitogenic effect on chick embryonic cells as assessed by nuclear counts. These findings demonstrate that insulin plays an important role in the early morphogenesis of the chick embryo. The function of insulin appears to be mediated by specific genes which orchestrate pattern formation during early development.     

Formation of the boundary between the midbrain and the hindbrain: involvement of Otx2 and Gbx2 genes

We have studied the neuromeric organisation of the mesencephalic-metencephalic (mes-met) territory of the avian neural tube using chick/quail transplantation experiments and analysing the expression of various regulatory genes in chimeric and normal embryos. Homotopic grafts demonstrate the presence of an interneuromeric boundary separating the mesencephalic and cerebellar territories (the mes-met or midbrain/hindbrain boundary). This boundary is characterised from HH10 onwards by the confrontation of the Otx2-Wnt1 and Gbx2-Fgf8 expressing domains, while En2 and Pax2 genes are expressed at both sides of the mes-met boundary. The evolution of the position of the Otx2/Gbx2 boundary with respect to the vesicles and constriction observed within the mes-met domain between stages HH10 and HH20, allows us to redefine the fate map of this region and to propose a new nomenclature for HH10. Transplantation between the prosencephalic neuroepithelium and the mes-met domain shows the possibility of inducing a mes-met phenotype within the two caudal-most prosomeres, preceded by its characteristic genetic cascade. The induction selectively takes place along the boundary between the graft (Otx2 positive) and the host cerebellar territory (expressing high levels of Gbx2); this includes the induction inside the graft of a new Otx2/Gbx2 boundary. Conversely, no induction is ever observed when the graft is confronted to the host Otx2 expressing domain. Although Fgf8 may be involved in the inductive events, our data strongly suggest that confrontation between Otx2 and Gbx2 is essential as an organiser of the mes-met domain.     

Cell lineage analysis of neural induction: origins of cells forming the induced nervous system

Horseradish peroxidase (HRP) was used as an intracellular lineage tracer in two experiments designed to reveal the sites of origin of cells that formed the duplicate embryo which developed in relation to an organizer grafted in the ventral marginal zone (VMZ) of Xenopus laevis embryos. In the first experiment a dorsal blastoporal lip fully labeled with HRP was grafted in the VMZ of an unlabeled embryo at the beginning of gastrulation. This resulted in development of a second embryo in which labeled cells, of graft origin, formed the notochord, and parts of the somites, endoderm, and neural tube. The second experiment was designed to show the sites of origin of the host's cells that formed parts of the induced embryo. HRP was injected into individual blastomeres in a series of Xenopus embryos at the 32-cell stage and each embryo received an unlabeled organizer graft in the VMZ at the beginning of gastrulation. In these embryos the lineages that contributed to the host's primary neural tube did not contribute any cells to the induced neural tube. All the cells in the induced neural tube which originated from the host were descendants of ventral blastomeres that did not contribute to the neural tube normally. This shows that the second neural tube is formed as a result of the action of the organizer on cells in its immediate vicinity which would not normally have entered neural pathways of differentiation.     

Functional analysis of chick ONT1 reveals distinguishable activities among olfactomedin-related signaling factors

The Olfactomedin family is a relatively new class of extracellular proteins. Two family members have been shown to play roles in the early development of ectodermal tissues: Noelin enhances neural crest generation in chick and Tiarin promotes dorsal neural specification in Xenopus. In this study, we introduce a novel member of the Olfactomedin family, ONT1. In the early chick embryo, ONT1 expression first appears at Hensen's node and subsequently in the axial and paraxial mesoderm. When the neural tube closes, strong expression of ONT1 is transiently found in the roof plate region from the rostral midbrain to the hindbrain. Overexpression of ONT1 in these regions prolongs the generation of neural crest cells in a manner similar to that of Noelin. Interestingly, ONT1 and Noelin have opposing effects on the expression of the migrating neural crest marker HNK-1 in the chick: they, respectively, cause suppression and ectopic induction of this marker. Differential activities among Olfactomedin-related factors are further examined in Xenopus. Microinjection of ONT1 mRNA into the Xenopus embryo expands the expression domain of the neural crest marker FoxD3 at the neurula stage whereas overexpression of Tiarin or Noelin suppresses FoxD3. ONT1 exhibits no dorsalizing effects on the Xenopus neural tube, which contrasts with the strong dorsalizing activity seen for Tiarin. Thus, distinct Olfactomedin-related factors evoke qualitatively different phenotypes even in the same experimental systems, suggesting that Olfactomedin family uses multiple response systems to mediate its signals in embryogenesis.     

Apical ectodermal ridge induction by the transplantation of En-1-overexpressing ectoderm in chick limb bud

In the early chick embryo, the dorsal–ventral (DV) boundary organizes the apical ectodermal ridge (AER) structure in the limb bud field. Here it is reported that Engrailed-1 ( En-1 ), a homolog of the Drosophila segment polarity gene engrailed expressed in the ventral limb ectoderm, participates in AER formation at the DV boundary of the limb bud. Restricted ectopic expression of En-1 in the dorsal side of the limb bud by transplantation of En-1 -overexpressing ectoderm induces ectopic AER at the boundary of En-1 -positive and -negative cells. The results suggest that En-1 is involved in AER formation at the DV boundary of the limb bud.