Mitochondrial dysfunction in the skeletal muscle of a mouse model of Rett syndrome (RTT): implications for the disease phenotype.

Rett syndrome (RTT) is a severe neurodevelopmental disorder, predominantly caused by mutations in the X-linked Methyl-CpG-binding protein 2 (MECP2) gene. Patients present with numerous functional deficits including intellectual disability and abnormalities of movement. Clinical and biochemical features may overlap with those seen in patients with primary mitochondrial respiratory chain disorders. In the late stages of the disorder, patients suffer from motor deterioration and usually require assisted mobility. Using a mouse model of RTT (Mecp2(tm1Tam)), we studied the mitochondrial function in the hind-limb skeletal muscle of these mice. We identified a reduction in cytochrome c oxidase subunit I (MTCO1) at both the transcript and protein level, in accordance with our previous findings in RTT patient brain studies. Mitochondrial respiratory chain (MRC) enzyme activity of complexes II+III (COII+III) and complex IV (COIV), and glutathione (GSH) levels were significantly reduced in symptomatic mice, but not in the pre-symptomatic mice. Our findings suggest that mitochondrial abnormalities in the skeletal muscle may contribute to the progressive deterioration in mobility in RTT through the accumulation of free radicals, as evidenced by the decrease in reduced glutathione (GSH). We hypothesise that a diminution in GSH leads to an accumulation of free radicals and an increase in oxidative stress. This may impact on respiratory chain function and contribute in part to the progressive neurological and motor deterioration seen in the Mecp2-mutant mouse. Treatment strategies aimed at restoring cellular GSH levels may prove to be a novel target area to consider in future approaches to RTT therapies.

Expression and functional analysis of Dkk1 during early gonadal development.

WNT signalling plays a central role in mammalian sex determination by promoting ovarian development and repressing aspects of testis development in the early gonad. Dickkopf homolog 1 (DKK1) is a WNT signalling antagonist that plays critical roles in multiple developmental systems by modulating WNT activity. Here, we examined the role of DKK1 in mouse sex determination and early gonadal development. Dkk1 mRNA was upregulated sex-specifically during testis differentiation, suggesting that DKK1 could repress WNT signalling in the developing testis. However, we observed overtly normal testis development in Dkk1-null XY gonads, and found no significant upregulation of Axin2 or Sp5 that would indicate increased canonical WNT signalling. Nor did we find significant differences in expression of key markers of testis and ovarian development. We propose that DKK1 may play a protective role that is not unmasked by loss-of-function in the absence of other stressors.

Fate-Mapping Technique: Targeted Whole-Embryo Electroporation of DNA Constructs into the Germ Layers of Mouse Embryos 7-7.5 Days Post-coitum.

INTRODUCTIONFate maps reveal body plan organization and presage the expression of molecular characteristics of cell lineages and formation of body parts. This protocol targets DNA expression constructs into the germ layers of gastrula-stage mouse embryos by focal electroporation. Plasmids utilizing a promoter that drives widespread, non-lineage-restricted expression of transgenes are introduced to cells in defined germ layer regions by whole-embryo electroporation. Germ-layer cells are exposed to the DNA by microinjecting the plasmids into the proamniotic cavity (ectoderm) or directly into the intercellular space of the mesenchyme (mesoderm), or by incubating the embryo in the DNA solution (endoderm). Electroporation is performed on whole embryos in vitro by electric current-mediated permeation of the cell membrane, which allows DNA adsorbed to cell surfaces to enter the cells. A point electrode is used to focus the electric field to the intended site of electroporation and a plate electrode is used to generate the current at an effective voltage low enough to minimize damage to the embryonic tissue. Expression of the transgene can be used to track the fate and movement of cells and the cDNA to study the functional consequences of overexpression of genes during embryonic development in vitro.

Allocation and early differentiation of cardiovascular progenitors in the mouse embryo.

During gastrulation of the mouse embryo, progenitor cells of the endothelium of blood vessels are allocated to different compartments of the extraembryonic and embryonic tissues in accordance to the timing and the site of recruitment to the mesodermal layer. In the yolk sac, the endothelium and the erythropoietic progenitors are populated by different groups of mesodermal cells, suggesting that they may not be derived from a common pool of progenitors. An orderly pattern of movement of mesodermal cells and the provision of proper intercellular transforming growth factor beta (TGF beta) and vascular endothelial growth factor (VEGF) signaling by neighboring germ layer tissues are essential for normal morphogenesis of the vasculature.

Impact of mutations of cartilage matrix genes on matrix structure, gene activity and chondrogenesis.

OBJECTIVE: Chondrocytes in the growth plate at different stages of differentiation synthesize characteristic extracellular matrix (ECM) components. Mutations in some ECM genes result in chondrodysplasia in humans and mice. We aimed to evaluate the impact of loss- and gain-of-function mutations of ECM genes on matrix structure, gene expression and formation of the growth plate. DESIGN: We review information on the impact of deficiencies in proteoglycans, and types X and II collagens on skeletal development. Additionally, we compare the impact of a glycine904 to cysteine (G904C) mutation in the triple helical coding domain of mouse Col2a1 with two previously reported Col2a1 mutations (exon7 deletion (Del1) and G85C). The G904C Col2a1 gene was introduced as a transgene into mice. Transgenic newborn mice were examined for skeletal development. The histology of the epiphyseal cartilage and the growth plate, and the ultrastructure of chondrocytes and collagen fibrillar morphology in the ECM were studied in 18.5-day transgenic and wild-type fetuses. The distribution of the mRNAs for Col2a1, Col11a1, Col9a1, Matn1, Agc and Ihh in the growth plate of 18.5-day G904C/G904C and wild type fetuses were compared by in situ hybridization. RESULTS: Heterozygous transgenic mice harbouring five copies of the G904C Col2a1 transgene developed skeletal abnormalities and dwarfism. Homozygous G904C/G904C mice died at birth, showing cleft palate, disrupted zonation of chondrocytes and reduction of the zone of hypertrophic chondrocytes. Fewer collagen fibrils were found in ECM of the cartilage. Rough endoplasmic reticulum of the chondrocytes of G904C/+ and G904C/G904C mice was distended. In G904C/G904C mutant mice, Agc gene activity was extended to the hypertrophic zone. Expression of the other genes studied was unchanged. Calcified materials that were not found normally in the maturing and only at low abundance in the hypertrophic zones of the wild type growth plate, were present in these zones in G904C/G904C mice. Despite phenotypic similarities for the G904C and Del1 mice, reduced expression of types I, II, IX, X collagens and aggrecan were reported for the latter mutation. Changes in gene activity and matrix organization in the growth plate also accompanied deficiencies in aggrecan, perlecan and collagen II. CONCLUSIONS: The data suggest that a single amino acid alteration in collagen II could lead to skeletal abnormalities through multiple secondary effects on the synthesis and assembly of ECM components. The functional impact of mutations of ECM genes reveals that chondrodysplasia is caused not just by the formation of abnormal matrix molecules, but that the alteration of one ECM component may lead to a cascade of disruption of other gene activities in chondrocytes which collectively contribute to the pathological changes in the architecture of the growth plate.

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.

Cell lineage determination in the mouse.

During the peri-implantation development of the mouse embryo from the blastocyst through gastrulation, Pou5f1 (OCT-4) down-regulation is closely linked to the initial step of lineage allocation to extraembryonic and embryonic somatic tissues. Subsequently, differentiation of the lineage precursors is subject to inductive tissue interactions and intercellular signalling that regulate cell proliferation and the acquisition of lineage-specific morphological and molecular characteristics. A notable variation of this process of lineage specification is the persistence of Pou5f1 activity throughout the differentiation of the primordial germ cells, which may underpin their ability to produce pluripotent progeny either as stem cells (embryonic germ cells) in vitro or as gametes in vivo. Nevertheless, intercellular signalling still plays a critical role in the specification of the primordial germ cells. The findings that primordial germ cells can be induced from any epiblast cells and that they share common progenitors with other somatic cells provide compelling evidence for the absence of a pre-determined germ line in the mouse embryo.

Mechanisms for the development of esophageal atresia.

BACKGROUND: There is no universally accepted theory to explain esophageal embryology and the abnormal development that produces esophageal atresia. METHODS: The impact of Adriamycin administration on the pathogenesis of esophageal atresia was studied in the rat model of VATER association, from embryonic day (ED) 10 to ED 13. RESULTS: Tissues in the ED10 Adriamycin-exposed embryos displayed less cell proliferation as shown by the reduced population of MIB-5-labelled cells. Cell apoptosis that is characteristic of the normal ED 12 lateral epithelial folds of the foregut (the prospective site of tracheoesophageal septation) was absent in the foregut of the Adriamycin-exposed embryo. Histologic examination of the ED 11-exposed embryo showed the presence of abnormal notochord that was stretched, split, or tethered to the foregut. This contrasts with the normal embryo in which the notochord was localized in close vicinity of the ventral part of the neural tube and separated from the foregut by ample amount of mesenchyme. The abnormal localization of the notochord was accompanied by the lack of down-regulation of the sonic hedgehog (Shh) activity in the prospective site of future tracheoesophageal separation in the exposed ED 12 embryo. CONCLUSION: The authors proposed that the ectopic location of the notochord leads to the disruption in Shh signalling that may underpin the development of esophageal atresia.

Morphogenetic tissue movement and the establishment of body plan during development from blastocyst to gastrula in the mouse.

In many animal species, the early development of the embryo follows a stereotypic pattern of cell cleavage, lineage allocation and generation of tissue asymmetry leading to delineation of the body plan with three primary embryonic axes. The mammalian embryo has been regarded as an exception and primary body axes of the mouse embryo were thought to develop after implantation. However, recent findings have challenged this view. Asymmetry in the fertilised oocyte, as defined by the position of the second polar body and the sperm entry point, can be correlated with the orientation of the animal-vegetal and the embryonic-abembryonic axes in the preimplantation blastocyst. Studies of the pattern of morphogenetic movement of cells and genetic activity in the peri-implantation embryo suggest that the animal-vegetal axis of the blastocyst might presage the orientation of the anterior-posterior axis of the gastrula. This suggests that the asymmetry of the zygote that is established at fertilisation and early cleavage has a lasting impact on the delineation of body axes during embryogenesis.

Desrt, an AT-rich interaction domain family transcription factor gene, is an early marker for nephrogenic mesoderm and is expressed dynamically during mouse limb development.

Desrt is a mouse gene of the AT-rich interaction domain family of transcription factors. Here we describe the temporal and spatial pattern of expression of Desrt during mouse organogenesis. Desrt expression is first detected in the intermediate plate mesoderm, providing an early embryonic marker for this tissue, and subsequently in the nephrogenic cords of the urogenital ridges. A highly dynamic expression pattern is observed in the developing limb, implicating Desrt in limb patterning. Desrt is also detected in the myotome of the somites, the oro-naso-pharyngeal ectoderm and underlying mesenchyme, otic vesicles, the gut and its derivatives, and transiently in the liver.

The allocation and differentiation of mouse primordial germ cells.

Analysis of the lineage potency of epiblast cells of the early-streak stage mouse embryo reveals that the developmental fate of the cells is determined by their position in the germ layer. Epiblast cells that are fated to become neuroectoderm can give rise to primordial germ cells (PGCs) and other types of somatic cells when they were transplanted to the proximal region of the epiblast. On the contrary, proximal epiblast cells transplanted to the distal region of the embryo do not form PGCs. Therefore, the germ line in the mouse is unlikely to be derived from a predetermined progenitor population, but may be specified as a result of tissue interactions that take place in the proximal epiblast of the mouse gastrula. The initial phase of the establishment of the PGC population requires, in addition to BMP activity emanating from the extraembryonic ectoderm, normal Lim1 and Hnf3beta activity in the germ layers. The entire PGC population is derived from a finite number of progenitor cells and there is no further cellular recruitment to the germ line after gastrulation. The XX PGCs undergo X-inactivation at the onset of migration from the gut endoderm and re-activate the silenced X-chromosome when they enter the urogenital ridge. Germ cells that are localised ectopically in extragonadal sites do not re-activate the X-chromosome, even when nearly all germ cells in the fetal ovary have restored full activity of both X-chromosomes. XXSxr germ cells can re-activate the X-chromosome in the sex-reversed testis, suggesting that the regulation of X-chromosome activity is independent of ovarian morphogenesis.

Defects of the body plan of mutant embryos lacking Lim1, Otx2 or Hnf3beta activity.

The orientation of the anterior-posterior (A-P) axis was examined in gastrula-stage Hnf3beta, Otx2 and Lim1 null mutant embryos that display defective axis development. In situ hybridization analysis of the expression pattern of genes associated with the posterior germ layer tissues and the primitive streak (T, Wnt3 and Fgf8) and anterior endoderm (Cer1 and Sox17) revealed that the A-P axis of mutant embryos remains aligned with the proximo-distal plane of the gastrula. Further analysis revealed that cells which express Chrd activity are either absent in Hnf3beta mutant embryos or localised in heterotopic sites in Lim1 and Otx2 null mutants. Lim1-expressing cells are present in the Hnf3beta mutant embryo albeit in heterotopic sites. In all three mutants, Gsc-expressing cells are missing from the anterior mesendoderm. These findings suggest that although some cells with organizer activity may be present in the mutant embryo, they are not properly localised and fail to contribute to the axial mesoderm of the head. By contrast, in T/T mutant embryos that display normal head fold development, the expression domains of organizer, primitive streak and anterior endoderm genes are regionalised correctly in the gastrula.

An X-linked GFP transgene reveals unexpected paternal X-chromosome activity in trophoblastic giant cells of the mouse placenta.

A GFP transgene has been integrated on the proximal part of the mouse X chromosome just distal of Timp and Syn1. During development, this X-linked GFP transgene exhibits widespread green fluorescence throughout the embryonic and adult life of male mice but displays mosaic expression in tissues as a result of X-inactivation in females. In living female embryos, inactivation of the transgene is imprinted in extraembryonic regions and random in the embryo proper, demonstrating that this reporter is behaving in a similar fashion to the majority of X-linked loci, and so provides a vital readout of X chromosome activity. This is observation is further supported in T16H/X female mice harboring the GFP transgene on the normal X chromosome where reporter inactivation is observed in somatic cells. The differential expression of GFP activity facilitates fluorescence activated cell sorting for the purification of GFP+ vs. GFP- cells from female embryonic tissues, thereby allowing access to populations of cells that have kept active a particular X chromosome. By tracking the activity of this X-linked GFP transgene, we discovered that the primary and secondary giant cells of the X/X placenta maintain an active paternal copy of this transgene on the presumed silenced paternal X-chromosome. This finding implies that the imprint on the paternal X chromosome may be relaxed in these trophectodermal derivatives.

Lineage allocation during early embryogenesis. Mapping of the neural primordia and application to the analysis of mouse mutants.

The methods outlined in this chapter discuss a range of techniques that have been employed for lineage analysis studies of the neural primordia from the onset of gastrulation and during neurulation. As the mouse has been extensively mapped, lineage analysis during normal morphogenesis is well understood. Attention is now focused on the tissue interactions that are essential for gastrulation and neurulation to proceed normally. The key to understanding these tissue interactions lies in the study of mutant embryos where abnormal development of specific tissue types affects the processes of gastrulation and neurulation. Lineage analysis and tissue potency experiments on particular mutant embryos will provide insight into these essential tissue interactions. As the first step toward undertaking such analysis of the neural derivatives, we have outlined the mutant strains available and detailed a protocol for the introgression of the lacZ transgene onto the mutant background.

The mouse Pdgfc gene: dynamic expression in embryonic tissues during organogenesis.

The signaling activity of Platelet-derived growth factors A and B (PDGF-A and PDGF-B) that is mediated through the two receptor kinases, PDGFR-alpha and PDGFR-beta has been shown to be critical for the development of the cardiovascular organs, the kidney, the lung and the central nervous system. During the cloning of genes for VEGF related proteins, we isolated a mouse cDNA that can encode for a protein of 345 amino acids. A comparison of the amino acid sequence reveals that this predicted gene product displays 95% identity to human PDGF-C. The mouse Pdgfc gene maps to a region of chromosome 17 that is syntenic to human chromosome 6p21.3 In E9. 5-E15.5 mouse embryo, Pdgfc is widely expressed in the surface ectoderm and later in the germinal layer of the skin, the olfactory and otic placode and their derivatives and the lining of the oral cavity. In the gut and visceral organs, such as the lung and the kidney, Pdgfc mRNA is first expressed in the endodermal epithelium and later in mesenchymal tissues associated with the endodermal structures. Similar to other PDGFs, Pdgfc is widely expressed in mesenchymal precursors and the myoblast of the smooth and skeletal muscles. Contrary to PDGF-A, Pdgfc is not expressed in the central nervous system, except in the cerebellum, and neurogenic derivatives of the neural crest cells. Pdgfc is also absent from the heart and the vascular endothelium

Lim1 activity is required for intermediate mesoderm differentiation in the mouse embryo.

During gastrulation and early organogenesis, Lim1 is expressed in the visceral endoderm, the anterior mesendoderm, and the lateral mesoderm that comprises the lateral plate and intermediate mesoderm. A previous study has reported that kidneys and gonads are missing in the Lim1 null mutants (W. Shawlot and R. R. Behringer, 1995, Nature 374, 425-430). Results of the present study show that in the early organogenesis stage mutant embryo, the intermediate mesoderm that contains the urogenital precursor tissues is disorganized and displays diminished expression of PAX2 and the Hoxb6-lacZ transgene. When posterior epiblast cells of the Lim1 null mutant embryo were transplanted to the primitive streak of wild-type host embryos, they were able to colonize the lateral plate and intermediate mesoderm of the host, suggesting that Lim1 activity is not essential for the allocation of epiblast cells to these mesodermal lineages. However, most of the mutant cells that colonized the lateral and intermediate mesoderm of the host embryo did not express the Hoxb6-lacZ transgene, except for some cells that were derived from the distal part of the posterior epiblast. Lim1 activity may therefore be required for the full expression of this transgene that normally marks the differentiation of the lateral plate and intermediate mesoderm.