Genetic ablation reveals that the roof plate is essential for dorsal interneuron specification

Rab23 is an essential negative regulator of the mouse Sonic hedgehog signalling pathway

The mouse open brain (opb) and Sonic hedgehog (Shh) genes have opposing roles in neural patterning: opb is required for dorsal cell types and Shh is required for ventral cell types in the spinal cord. Here we show that opb acts downstream of Shh. Ventral cell types that are absent in Shh mutants, including the floor plate, are present in Shh opb double mutants. The organization of ventral cell types in Shh opb double mutants reveals that Shh-independent mechanisms can pattern the neural tube along its dorsal-ventral axis. We cloned opb by a map-based approach and found that it encodes Rab23, a member of the Rab family of vesicle transport proteins. The data indicate that dorsalizing signals activate transcription of Rab23 in order to silence the Shh pathway in dorsal neural cells.

Signals from the ventral midline and isthmus regulate the development of Brn3.0-expressing neurons in the midbrain

The vertebrate midbrain consists of dorsal and ventral domains, the tectum and tegmentum, which execute remarkably different developmental programs. Tectal development is characterized by radial migration of differentiating neurons to form a laminar structure, while the tegmentum generates functionally diverse nuclei at characteristic positions along the neural axis. Here we show that neurons appearing early in the development of the tectum are characterized either by the expression of the POU-domain transcription factor Brn3.0, or by members of the Pax and LIM families. Early neurons of the rostral tegmentum co-express Brn3.0 and Lim1/2, and caudal tegmental neurons express Islet1/2. Notochord tissue or Shh-transfected epithelial cells, transplanted to the developing tectum, suppress the development of tectal neurons, and induce the differentiation of multiple tegmental cell types. The distance from the midbrain-hindbrain boundary (MHB) determines the specific markers expressed by the tegmental neurons induced in the tectum, and the transplantation of MHB tissue adjacent to the rostral tegmentum also induces caudal markers, demonstrating the role of MHB signals in determining the phenotype of these early midbrain neurons. Co-culture of isolated midbrain neuroepithelium with Shh-expressing cells demonstrates that Shh is sufficient to convert tectal neurons to a tegmental fate. In mice lacking Shh, Brn3.0- and Pax7-expressing neurons typical of the tectum develop throughout the ventral midbrain, and gene expression patterns characteristic of early tegmental development do not appear.

Combinatorial expression patterns of LIM-homeodomain and other regulatory genes parcellate developing thalamus

The anatomical and functional organization of dorsal thalamus (dTh) and ventral thalamus (vTh), two major regions of the diencephalon, is characterized by their parcellation into distinct cell groups, or nuclei, that can be histologically defined in postnatal animals. However, because of the complexity of dTh and vTh and difficulties in histologically defining nuclei at early developmental stages, our understanding of the mechanisms that control the parcellation of dTh and vTh and the differentiation of nuclei is limited. We have defined a set of regulatory genes, which include five LIM-homeodomain transcription factors (Isl1, Lhx1, Lhx2, Lhx5, and Lhx9) and three other genes (Gbx2, Ngn2, and Pax6), that are differentially expressed in dTh and vTh of early postnatal mice in distinct but overlapping patterns that mark nuclei or subsets of nuclei. These genes exhibit differential expression patterns in dTh and vTh as early as embryonic day 10.5, when neurogenesis begins; the expression of most of them is detected as progenitor cells exit the cell cycle. Soon thereafter, their expression patterns are very similar to those that we observe postnatally, indicating that unique combinations of these genes mark specific cell groups from the time they are generated to their later differentiation into nuclei. Our findings suggest that these genes act in a combinatorial manner to control the specification of nuclei-specific properties of thalamic cells and the differentiation of nuclei within dTh and vTh. These genes may also influence the pathfinding and targeting of thalamocortical axons through both cell-autonomous and non-autonomous mechanisms.

Proprioceptor pathway development is dependent on Math1

The proprioceptive system provides continuous positional information on the limbs and body to the thalamus, cortex, pontine nucleus, and cerebellum. We showed previously that the basic helix-loop-helix transcription factor Math1 is essential for the development of certain components of the proprioceptive pathway, including inner-ear hair cells, cerebellar granule neurons, and the pontine nuclei. Here, we demonstrate that Math1 null embryos lack the D1 interneurons and that these interneurons give rise to a subset of proprioceptor interneurons and the spinocerebellar and cuneocerebellar tracts. We also identify three downstream genes of Math1 (Lh2A, Lh2B, and Barhl1) and establish that Math1 governs the development of multiple components of the proprioceptive pathway.

Patterning of muscle acetylcholine receptor gene expression in the absence of motor innervation

The patterning of skeletal muscle is thought to depend upon signals provided by motor neurons. We show that AChR gene expression and AChR clusters are concentrated in the central region of embryonic skeletal muscle in the absence of innervation. Neurally derived Agrin is dispensable for this early phase of AChR expression, but MuSK, a receptor tyrosine kinase activated by Agrin, is required to establish this AChR prepattern. The zone of AChR expression in muscle lacking motor axons is wider than normal, indicating that neural signals refine this muscle-autonomous prepattern. Neuronal Neuregulin-1, however, is not involved in this refinement process, nor indeed in synapse-specific AChR gene expression. Our results demonstrate that AChR expression is patterned in the absence of innervation, raising the possibility that similarly prepatterned muscle-derived cues restrict axon growth and initiate synapse formation.

Detailed field pattern is intrinsic to the embryonic mouse hippocampus early in neurogenesis

There is accumulating evidence that the mammalian cerebral cortex is regionally specified early in neurogenesis. However, the degree and scale of the regional pattern that is intrinsic to different parts of the cortical primordium remains unclear. Here, we show that detailed patterning-the accurate positioning of several areas or fields-is intrinsic to the part of the primordium that generates the hippocampus. A caudomedial portion of the cortical primordium, the site from which the hippocampus arises, was isolated from potential extrinsic patterning cues by maintaining it in explant culture. Explants were prepared at embryonic day (E) 12.5, which is early in hippocampal neurogenesis in the mouse and 3 d before individual fields are seen by differential gene expression. Allowed to develop for 3 d in vitro, E12.5 explants upregulate field-specific patterns of gene expression with striking temporal and spatial accuracy. Possible sources of patterning signals intrinsic to the explants were evaluated by removing the cortical hem or presumptive extrahippocampal cortex from the explants. To expose cells to different local positional cues, explant fragments were grafted into ectopic positions in a larger explant. None of these manipulations altered the development of patterned, field-specific gene expression. Finally, explants harvested at E10.5 also upregulate field-specific gene expression, although less robustly. Some hippocampal patterning information is therefore intrinsic to the caudomedial cortical primordium at the time that the first hippocampal neurons are born at E10.5. By E12.5, hippocampal field patterning appears to be well established and resistant to the manipulation of several potential intrinsic cues.

Homeobox gene mutations and brain-stem developmental disorders: learning from knockout mice

Analysis of mice that carry targeted inactivations of Hox, Nkx and Phox2 homeobox genes revealed their involvement in regional patterning of brain-stem territories, in specification of neuronal identity, in establishment of appropriate patterns of connectivity and in control of neurotransmission. The specific abnormalities generated by such mutations may provide clues to the genetic basis and cellular mechanisms that are involved in human brain-stem developmental disorders.

Cre reporter strains produced by targeted insertion of EYFP and ECFP into the ROSA26 locus

BACKGROUND

Several Cre reporter strains of mice have been described, in which a lacZ gene is turned on in cells expressing Cre recombinase, as well as their daughter cells, following Cre-mediated excision of a loxP-flanked transcriptional "stop" sequence. These mice are useful for cell lineage tracing experiments as well as for monitoring the expression of Cre transgenes. The green fluorescent protein (GFP) and variants such as EYFP and ECFP offer an advantage over lacZ as a reporter, in that they can be easily visualized without recourse to the vital substrates required to visualize beta-gal in living tissue.

RESULTS

In view of the general utility of targeting the ubiquitously expressed ROSA26 locus, we constructed a generic ROSA26 targeting vector. We then generated two reporter lines of mice by inserting EYFP or ECFP cDNAs into the ROSA26 locus, preceded by a loxP-flanked stop sequence. These strains were tested by crossing them with transgenic strains expressing Cre in a ubiquitous (beta-actin-Cre) or a cell-specific (Isl1-Cre and En1-Cre) pattern. The resulting EYFP or ECFP expression patterns indicated that the reporter strains function as faithful monitors of Cre activity.

CONCLUSIONS

In contrast to existing lacZ reporter lines, where lacZ expression cannot easily be detected in living tissue, the EYFP and ECFP reporter strains are useful for monitoring the expression of Cre and tracing the lineage of these cells and their descendants in cultured embryos or organs. The non-overlapping emission spectra of EYFP and ECFP make them ideal for double labeling studies in living tissues.

The use of in ovo electroporation for the rapid analysis of neural-specific murine enhancers

The identification and characterization of DNA sequences necessary for proper gene expression have provided insights into gene regulation and generated tools useful for further experimentation. Studies of developmentally regulated genes have demonstrated how transcription factors interact at enhancers to generate restricted patterns of expression during embryogenesis. In vertebrates, the pursuit of such studies has relied on the generation of transgenic mice and thus has been limited by the time and expense required generating and characterizing these mice. The recently developed technique of in ovo electroporation allows the rapid introduction of exogenous DNA into developing chicken embryos. Here we have used this technique to introduce DNA containing murine enhancer/reporter constructs into cells of the chicken neural tube, resulting in appropriate expression of the reporter. This technique has the potential to greatly reduce the effort involved in the study of vertebrate enhancers. Furthermore, we have characterized factors such as timing of electroporation, concentration of DNA, and choice of basal promoters and found that they can influence the degree to which expression of enhancer constructs reflects endogenous gene expression.

LIM-homeodomain gene Lhx2 regulates the formation of the cortical hem

We are interested in the early mechanisms that initiate regional patterning in the dorsal telencephalon, which gives rise to cerebral cortex. Members of the LIM-homeodomain (LIM-HD) family of transcription factors are implicated in patterning and cell fate specification in several systems including the mammalian forebrain. Mice in which Lhx2 is disrupted were reported to have reduced telencephalic development, and the hippocampal primordium appeared to be missing, by morphological observation. We hypothesized that this may be due to a defect in the cortical hem, a Wnt- and Bmp-rich putative signaling center in the medial telencephalon, a source of regulatory signals for hippocampal development. We asked if the expression of any known hem-specific signaling molecule is deficient in Lhx2-/- mice. Our results reveal, unexpectedly, that at embryonic day (E)12.5, what appears to be some spared 'lateral' cortex is instead an expanded cortical hem. Normally restricted to the extreme medial edge of the telencephalon, the hem covers almost the entire dorsal telencephalon in the Lhx2-/- mice. This indicates a role for Lhx2 in the regulation of the extent of the cortical hem. In spite of an expanded, mislocated hem in the Lhx2-/- telencephalon, a potential source of ectopic dorsalizing cues, no hippocampal differentiation is detected in tissue adjacent to the mutant hem, nor does the overall dorsoventral patterning appear perturbed. We propose that Lhx2 is involved at a crucial early step in patterning the telencephalon, where the neuroepithelium is first divided into presumptive cortical tissue, and the cortical hem. The defect in the Lhx2-/- telencephalon appears to be at this step.

The Phox2b transcription factor coordinately regulates neuronal cell cycle exit and identity

In the vertebrate neural tube, cell cycle exit of neuronal progenitors is accompanied by the expression of transcription factors that define their generic and sub-type specific properties, but how the regulation of cell cycle withdrawal intersects with that of cell fate determination is poorly understood. Here we show by both loss- and gain-of-function experiments that the neuronal-subtype-specific homeodomain transcription factor Phox2b drives progenitor cells to become post-mitotic. In the absence of Phox2b, post-mitotic neuronal precursors are not generated in proper numbers. Conversely, forced expression of Phox2b in the embryonic chick spinal cord drives ventricular zone progenitors to become post-mitotic neurons and to relocate to the mantle layer. In the neurons thus generated, ectopic expression of Phox2b is sufficient to initiate a programme of motor neuronal differentiation characterised by expression of Islet1 and of the cholinergic transmitter phenotype, in line with our previous results showing that Phox2b is an essential determinant of cranial motor neurons. These results suggest that Phox2b coordinates quantitative and qualitative aspects of neurogenesis, thus ensuring that neurons of the correct phenotype are generated in proper numbers at the appropriate times and locations.

Dorsal and lateral fates in the mouse neural tube require the cell-autonomous activity of the open brain gene

The processes that specify early regional identity in dorsal and lateral regions of the mammalian neural tube are not well understood. The mouse open brain (opb) gene plays an essential role in dorsal neural patterning: in the caudal spinal cord of opb mutants, dorsal cell types are absent and markers of ventral fates, including Shh, expand into dorsal regions. Analysis of the opb mutant phenotype and of opb/opb <--> wild-type chimeric embryos reveals that early in neural development, the wild-type opb gene (opb(+)) is required cell autonomously for the expression of Pax7 in dorsal cells and Pax6 in lateral cells. Thus the opb(+) gene product acts intracellularly in the reception or interpretation of signals that determine cell types in the dorsal 80% of the neural tube. At later stages, the lack of opb(+) causes a non-cell-autonomous expansion of ventral cell types into dorsal regions of the neural tube, revealing that opb(+) controls the production of a diffusible molecule that defines the domain of Shh expression. The data indicate that opb(+) could act as either a novel component of a dorsalizing pathway or a novel intracellular negative regulator of the Shh signal transduction pathway.

Regulation of the neural patterning activity of sonic hedgehog by secreted BMP inhibitors expressed by notochord and somites

The secretion of Sonic hedgehog (Shh) from the notochord and floor plate appears to generate a ventral-to-dorsal gradient of Shh activity that directs progenitor cell identity and neuronal fate in the ventral neural tube. In principle, the establishment of this Shh activity gradient could be achieved through the graded distribution of the Shh protein itself, or could depend on additional cell surface or secreted proteins that modify the response of neural cells to Shh. Cells of the neural plate differentiate from a region of the ectoderm that has recently expressed high levels of BMPs, raising the possibility that prospective ventral neural cells are exposed to residual levels of BMP activity. We have examined whether modulation of the level of BMP signaling regulates neural cell responses to Shh, and thus might contribute to the patterning of cell types in the ventral neural tube. Using an in vitro assay of neural cell differentiation we show that BMP signaling markedly alters neural cell responses to Shh signals, eliciting a ventral-to-dorsal switch in progenitor cell identity and neuronal fate. BMP signaling is regulated by secreted inhibitory factors, including noggin and follistatin, both of which are expressed in or adjacent to the neural plate. Conversely, follistatin but not noggin produces a dorsal-to-ventral switch in progenitor cell identity and neuronal fate in response to Shh both in vitro and in vivo. These results suggest that the specification of ventral neural cell types depends on the integration of Shh and BMP signaling activities. The net level of BMP signaling within neural tissue may be regulated by follistatin and perhaps other BMP inhibitors secreted by mesodermal cell types that flank the ventral neural tube.

Sonic hedgehog signaling at gastrula stages specifies ventral telencephalic cells in the chick embryo

A secreted signaling factor, Sonic hedgehog (Shh), has a crucial role in the generation of ventral cell types along the entire rostrocaudal axis of the neural tube. At caudal levels of the neuraxis, Shh is secreted by the notochord and floor plate during the period that ventral cell fates are specified. At anterior prosencephalic levels that give rise to the telencephalon, however, neither the prechordal mesoderm nor the ventral neural tube expresses Shh at the time that the overt ventral character of the telencephalon becomes evident. Thus, the precise role and timing of Shh signaling relevant to the specification of ventral telencephalic identity remains unclear. By analysing neural cell differentiation in chick neural plate explants we provide evidence that neural cells acquire molecular properties characteristic of the ventral telencephalon in response to Shh signals derived from the anterior primitive streak/Hensen's node region at gastrula stages. Exposure of prospective anterior prosencephalic cells to Shh at this early stage is sufficient to initiate a temporal program of differentiation that parallels that of neurons generated normally in the medial ganglionic eminence subdivision of the ventral telencephalon.