The isthmic organizer and brain regionalization

Distinct neural identities are acquired through progressive restriction of developmental potential under the influence of local environmental signals. Evidence for the localization of such morphogenetic signals at specific locations of the developing neural primordium has suggested the concept of "secondary organizer regions", which regulate the identity and regional polarity of neighboring neuroepithelial areas one step further. In recent years, the most studied secondary organizer has been the isthmic organizer, which is localized at the hind-midbrain transition and controls anterior hindbrain and midbrain regionalization. Otx2 and Gbx2 expression is fundamental for positioning the organizer and for the establishment of molecular interactions that induce Fgf8 expression and then, stabilize the autoregulative loop of En1, Wnt1 and Pax2 expression. Temporospatial patterns of such gene expressions are necessary for the correct development of the organizer which, by a planar mechanism of induction, controls the normal development of the rostral hindbrain from r2 to the midbrain-diencephalic boundary. Fgf8 appears as the active diffusible molecule for isthmic morphogenetic activity and has been suggested to be the morphogenetic effector in other inductive activities revealed in other neuroepithelial regions.     

Timing and cell interactions underlying neural induction in the chick embryo

Previous studies on neural induction have identified regionally localized inducing activities, signaling molecules, potential competence factors and various other features of this important, early differentiation event. In this paper, we have developed an improved model system for analyzing neural induction and patterning using transverse blastoderm isolates obtained from gastrulating chick embryos. We use this model to establish the timing of neural specification and the spatial distribution of perinodal cells having organizer activity. We show that a tissue that acts either as an organizer or as an inducer of an organizer is spatially co-localized with the prospective neuroectoderm immediately rostral to the primitive streak in the early gastrula. As the primitive streak elongates, this tissue with organizing activity and the prospective neuroectoderm rostral to the streak separate. Furthermore, we show that up to and through the mid-primitive streak stage (i.e., stage 3c/3+), the prospective neuroectoderm cannot self-differentiate (i.e. , express neural markers and acquire neural plate morphology) in isolation from tissue with organizer activity. Signals from the organizer and from other more caudal regions of the primitive streak act on the rostral prospective neuroectoderm and the latter gains potency (i.e., is specified) by the fully elongated primitive streak stage (i.e., stage 3d). Transverse blastoderm isolates containing non-specified, prospective neuroectoderm provide an improved model system for analyzing early signaling events involved in neuraxis initiation and patterning.     

Endoderm induction by the organizer-secreted factors chordin and noggin in Xenopus animal caps.

Spemann's organizer has potent neural inducing and mesoderm dorsalizing activities in the Xenopus gastrula. A third activity, the organizer's ability to induce a secondary gut, has been difficult to analyze experimentally due to the lack of early gene markers. Here we introduce endodermin, a pan-endodermal gene marker, and use it to demonstrate that chordin (Chd), a protein secreted by the organizer region, is able to induce endodermal differentiation in Xenopus. The ability of chd, as well as that of noggin, to induce endoderm in animal cap explants is repressed by the ventralizing factor BMP-4. When FGF signaling is blocked by a dominant-negative FGF receptor in chd-injected animal caps, neural induction is inhibited and most of the explant is induced to become endoderm. The results suggest that proteins secreted by the organizer, acting together with known peptide growth factors, regulate differentiation of the endodermal germ layer.     

Neural induction and patterning in the mouse in the absence of the node and its derivatives

The signals which induce vertebrate neural tissue and pattern it along the anterior-posterior (A-P) axis have been proposed to emanate from Spemann's organizer, which in mammals is a structure termed the node. However, mouse embryos mutant for HNF3 beta lack a morphological node and node derivatives yet undergo neural induction. Gene expression domains occur at their normal A-P axial positions along the mutant neural tubes in an apparently normal temporal manner, including the most anterior and posterior markers. This neural patterning occurs in the absence of expression of known organizer genes, including the neural inducers chordin and noggin. Other potential signaling centers in gastrulating mutant embryos appear to express their normal constellation of putative secreted factors, consistent with the possibility that neural-inducing and -patterning signals emanate from elsewhere or at an earlier time. Nevertheless, we find that the node and the anterior primitive streak, from which the node derives, are direct sources of neural-inducing signals, as judged by expression of the early midbrain marker Engrailed, in explant-recombination experiments. Similar experiments showed the neural-inducing activity in HNF3 beta mutants to be diffusely distributed. Our results indicate that the mammalian organizer is capable of neural induction and patterning of the neural plate, but that maintenance of an organizer-like signaling center is not necessary for either process.     

Response of plant development to environment: control of flowering by daylength and temperature

The transition from vegetative growth to flowering is often controlled by environmental conditions and influenced by the age of the plant. Intensive genetic analysis has identified pathways that regulate flowering time of Arabidopsis in response to daylength or low temperature (vernalization). These pathways are proposed to converge to regulate the expression of genes that act within the floral primordium and promote floral development. In the past year, genes that confer the responses to daylength or vernalization have been cloned and have enabled aspects of the genetic models to be tested at the molecular level.     

The sex determination gene doublesex regulates the A/P organizer to direct sex-specific patterns of growth in the Drosophila genital imaginal disc.

Each Drosophila genital imaginal disc contains primordia for both male and female genitalia and analia. The sexually dimorphic development of this disc is governed by the sex-specific expression of doublesex (dsx). We present data that substantially revises our understanding of how dsx controls growth and differentiation in the genital disc. The classical view of genital disc development is that in each sex, dsx autonomously "represses" the development of the inappropriate genital primordium while allowing the development of the appropriate primordium. Instead, we show that dsx regulates the A/P organizer to control growth of each genital primordium, and then directs each genital primordium to differentiate defined adult structures in both sexes.     

Follistatin possesses trunk and tail organizer activity and lacks head organizer activity.

In this report the organizer activity of follistatin was examined by transplantation of pieces of the animal cap, isolated from embryos injected with follistatin mRNA, into the blastocoele of an early host blastula (Einsteck explants). Host embryos developed a secondary axis consisting of myotomes, notochord and neural tube of the trunk or tail character. Secondary structures that are characteristic of a head, such as cement glands or brain and eyes, did not develop in these experiments. These findings suggested that follistatin may have the trunk and tail organizer activity, while it was not possible to reconstitute its head organizer activity.     

Physiological Analysis of Flower Formation in Wedgwood Iris

A series of experiments is described in which buds and scalesof iris bulbs were implanted in nutrient media and subjectedto varying temperature treatments, in an attempt to analysethe effect of different endogenous growth factors and of gibberellicacid on flower formation. In isolated scales incubated at 13°C for one to three weeks much of a heat-stable flower-inducingcompound and a small quantity of a second growth factor is produced.At 25.5° C no such substances are formed. It is shown thatat different times during a prolonged lowtemperature treatmentof iris bulbs, different growth factors are formed which activatesuccessive stages in the differentiation of the flower primordium.At 25.5° C the production and activity of the factor responsiblefor the transition to the reproductive stage are inhibited.Probably not inhibited at this temperature are differentiationprocesses in the reproductive primordium controlled by otherfactors with gibberellin-like characters.     

The Spemann-Mangold organizer: the control of fate specification and morphogenetic rearrangements during gastrulation in Xenopus

Vertebrate embryonic development is controlled by sequentially operating signalling centres that organize spatial pattern by inductive interactions. The embryonic body plan is established during gastrulation through the action of the Spemann-Mangold or gastrula organizer, a signalling source discovered 75 years ago by Hans Spemann and Hilde Mangold. Transplantation of the organizer to a heterotopic location in a recipient embryo results in the formation of a secondary embryonic body axis, in which several tissue types, most notably somites and the neural tube, are derived from ventral host cells. Because of these non-cell autonomous recruiting or inducing activities the organizer has become a paradigm for studying intercellular communication in the vertebrate embryo. Here, I review some of the recent advances in understanding 1) the initiation of the Spemann-Mangold organizer, 2) its function in pattern formation along the dorsal-ventral and anterior-posterior axes and 3) the integration of cell fate specification events and downstream execution of morphogenetic movements during gastrulation in Xenopus laevis.     

The organizer of the mouse gastrula is composed of a dynamic population of progenitor cells for the axial mesoderm

An organizer population has been identified in the anterior end of the primitive streak of the mid-streak stage embryo, by the expression of Hnf3beta, Gsc(lacZ) and Chrd, and the ability of these cells to induce a second neural axis in the host embryo. This cell population can therefore be regarded as the mid-gastrula organizer and, together with the early-gastrula organizer and the node, constitute the organizer of the mouse embryo at successive stages of development. The profile of genetic activity and the tissue contribution by cells in the organizer change during gastrulation, suggesting that the organizer may be populated by a succession of cell populations with different fates. Fine mapping of the epiblast in the posterior region of the early-streak stage embryo reveals that although the early-gastrula organizer contains cells that give rise to the axial mesoderm, the bulk of the progenitors of the head process and the notochord are localized outside the early gastrula organizer. In the mid-gastrula organizer, early gastrula organizer derived cells that are fated for the prechordal mesoderm are joined by the progenitors of the head process that are recruited from the epiblast previously anterior to the early gastrula organizer. Cells that are fated for the head process move anteriorly from the mid-gastrula organizer in a tight column along the midline of the embryo. Other mid-gastrula organizer cells join the expanding mesodermal layer and colonize the cranial and heart mesoderm. Progenitors of the trunk notochord that are localized in the anterior primitive streak of the mid-streak stage embryo are later incorporated into the node. The gastrula organizer is therefore composed of a constantly changing population of cells that are allocated to different parts of the axial mesoderm.     

Depletion of Bmp2, Bmp4, Bmp7 and Spemann organizer signals induces massive brain formation in Xenopus embryos

To address the patterning function of the Bmp2, Bmp4 and Bmp7 growth factors, we designed antisense morpholino oligomers (MO) that block their activity in Xenopus laevis. Bmp4 knockdown was sufficient to rescue the ventralizing effects caused by loss of Chordin activity. Double Bmp4 and Bmp7 knockdown inhibited tail development. Triple Bmp2/Bmp4/Bmp7 depletion further compromised trunk development but did not eliminate dorsoventral patterning. Unexpectedly, we found that blocking Spemann organizer formation by UV treatment or beta-Catenin depletion caused BMP inhibition to have much more potent effects, abolishing all ventral development and resulting in embryos having radial central nervous system (CNS) structures. Surprisingly, dorsal signaling molecules such as Chordin, Noggin, Xnr6 and Cerberus were not re-expressed in these embryos. We conclude that BMP inhibition is sufficient for neural induction in vivo, and that in the absence of ventral BMPs, Spemann organizer signals are not required for brain formation.