Altered BMP signaling disrupts chick diencephalic development

The diencephalon is the caudal part of the forebrain and is organized into easily identifiable clusters of neurons called nuclei. Neurons in different nuclei project to discrete brain regions. Thus precise organization of the nuclei during forebrain development is necessary to build accurate neural circuits. How diencephalic development is regulated is poorly understood. BMP signaling participates in central nervous system patterning and development at many levels along the neural axis. Based on their expression we hypothesized BMPs play a role in diencephalic development. To test this hypothesis, we electroporated constitutively active and dominant negative forms of type I BMP receptors (Bmpr1a and Bmpr1b) into the embryonic chick forebrain. Ectopic induction of BMP signaling through constitutively active forms of the type I BMP receptors perturbs the normal gene expression patterns in the diencephalon and increases apoptotic cell death. These defects lead to disorganization of the diencephalic nuclei, suggesting BMP signaling is sufficient to modify diencephalic development. Loss-of-function studies, using dominant negative forms of Bmpr1a and Bmpr1b, indicate type I BMP receptors are necessary for normal eye and craniofacial development. However, they do not appear to be required for normal diencephalic development. In summary, our data indicate that while not necessary, BMP signaling via Bmpr1a and Bmpr1b, is sufficient to modify nuclear organization in the chick diencephalon.     

Determining the fate of Shh-expressing cells in the diencephalon using a BAC transgenic reporter

The thalamus and prethalamus consist of multiple distinct nuclei and their boundary is demarcated by the zona limitans intrathalamica (ZLI). The development of the primordial thalamus and prethalamus proceed within the caudal diencephalon. Shh has been shown to be essential for diencephalic patterning and regionalization. To understand the role of Shh in the specification of distinct thalamic and prethalamic nuclei, we developed a lineage marker for diencephalic cells expressing Shh by using bacterial artificial chromosome (BAC) transgenesis. A genomic fragment containing ～210 kb of the mouse Shh locus was used to target enhanced green fluorescent protein (eGFP) in transgenic mice. This transgenic BAC reporter faithfully mimicked the pattern of endogenous Shh expression in the caudal diencephalon, including the ZLI. Fate mapping analysis at multiple developmental stages showed that descendents of Shh-expressing progenitor cells derived from ZLI contribute to a population of cells in the ventral lateral geniculate nucleus.     

Expression pattern of Wnt inhibitor factor 1(Wif1) during the development in mouse CNS

Wnt inhibitor factor-1 (WIF-1) is an extracellular antagonist of Wnts secreted proteins. Here we describe the expression pattern of Wif1 throughout the development of the mouse central nervous system (CNS). Wif1 mRNA can be detected as early as the developmental stage E11, and expression persists to adulthood. In embryonic stages, the level of Wif1 expression was very prominent in several areas including the cerebral cortex, the diencephalon and the midbrain, with the strongest level in the hippocampal plate and the diencephalon. However, after birth, the expression level of Wif1 decreased in the cortex and diencephalon. By adulthood, Wif1 is mainly expressed in the medial habenular nucleus (MHb) in the epithalamus, the mitral layer cells in the olfactory bulb and a few nuclei in the hypothalamus. Our data shows that the expression of Wif1 was very strong during embryonic development of the CNS and suggests that Wif1 may play an essential role in the spatial and temporal regulation of Wnt signals.     

Fate map of the diencephalon and the zona limitans at the 10-somites stage in chick embryos

The diencephalon is a central area of the vertebrate developing brain, where the thalamic nuclear complex, the pretectum and the anterior tegmental structures are generated. It has been subdivided into prosomeres, which are transversal domains defined by morphological and molecular criteria. The zona limitans intrathalamica is a central boundary in the diencephalon that separates the posterior diencephalon (prosomeres 1 and 2), from the anterior diencephalon (prosomere 3). This intrathalamic limit appears early on in neural tube development, and the molecular pattern that it reveals suggests an important role in the diencephalic histogenesis. We hereby present a fate map of the presumptive territories in the diencephalon of a chick embryo at the 10-11 somite stages (HH9-10), by homotopic and isochronic quail-chick grafts. The anatomical interpretation of chimeric brains was aided by correlative whole-mount in situ hybridization with RNA probes for chicken genes expressed in specific diencephalic territories. The resulting fate map describes the distribution of the presumptive diencephalic prosomeres in the neural tube, and demonstrates their topologically conserved relationships throughout the neural development. Moreover, we show that the presumptive epithelium of ZLI can be localized at early developmental stages in the diencephalic alar plate at the anterior limit of the Wnt8b gene expression domain.     

Embryogenesis and expression profiles of charon and nodal-pathway genes in sinistral (Paralichthys olivaceus) and dextral (Verasper variegatus) flounders

Although it is well known that flounder form external asymmetry by migration of one eye at metamorphosis, the control system that forms this asymmetry is unknown. To help elucidate this mechanism, we here describe the embryogenesis and expression profiles of the Nodal-pathway genes in the Japanese flounder, Paralichthys olivaceus. We also perform a comparative study of the laterality of the expression of these genes in sinistral (P. olivaceus) and dextral (Verasper variegatus) flounders. In P. olivaceus, Kupffer's vesicle forms at the 2-somite stage, after which left-sided expression of spaw starts at the 8-somite stage. Left-sided expression of pitx2 occurs in the gut field at the 15-somite to high-pec stages, in the heart field at the 21-somite stage, and in the dorsal diencephalon at the 27-somite to high-pec stages. In response to left-sided pitx2 expression, the heart, gut, and diencephalon begin asymmetric organogenesis at the pharyngula (heart) and the long-pec (gut and diencephalon) stages, whereas the eyes do not show signs of asymmetry at these stages. In both sinistral and dextral flounders, the Nodal-pathway genes are expressed at the left side of the dorsal diencephalon and left lateral-plate mesoderm. Considering these data together with our previous finding that reversal of eye laterality occurs to some extent in the P. olivaceus mutant reversed, in which embryonic pitx2 expression is randomized, we propose that although the Nodal pathway seems to function to fix eye laterality, embryonic expression of these genes does not act as a direct positional cue for eye laterality.     

Fgf8 controls regional identity in the developing thalamus

The vertebrate thalamus contains multiple sensory nuclei and serves as a relay station to receive sensory information and project to corresponding cortical areas. During development, the progenitor region of the diencephalon is divided into three parts, p1, p2 (presumptive thalamus) and p3, along its longitudinal axis. Besides the local expression of signaling molecules such as sonic hedgehog (Shh), Wnt proteins and Fgf8, the patterning mechanisms of the thalamic nuclei are largely unknown. Using mouse in utero electroporation to overexpress or inhibit endogenous Fgf8 at the diencephalic p2/p3 border, we revealed that it affected gene expression only in the p2 region without altering overall diencephalic size or the expression of other signaling molecules. We demonstrated that two distinctive populations in p2, which can be distinguished by Ngn2 and Mash1 in early embryonic diencephalon, are controlled by Fgf8 activity in complementary manner. Furthermore, we found that FGF activity shifts thalamic sensory nuclei on the A/P axis in postnatal brain. Moreover, gene expression analysis demonstrated that FGF signaling shifts prethalamic nuclei in complementary manner to the thalamic shift. These findings suggest conserved roles of FGF signaling in patterning along the A/P axis in CNS, and reveal mechanisms of nucleogenesis in the developing thalamus.