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.

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.

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.

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.

Linkage analysis of systemic lupus erythematosus induced in diabetes-prone nonobese diabetic mice by Mycobacterium bovis.

Systemic lupus erythematosus induced by Mycobacterium bovis in diabetes-prone nonobese diabetic mice was mapped in a backcross to the BALB/c strain. The subphenotypes-hemolytic anemia, antinuclear autoantibodies, and glomerular immune complex deposition-did not cosegregate, and linkage analysis for each trait was performed independently. Hemolytic anemia mapped to two loci: Bah1 at the MHC on chromosome 17 and Bah2 on distal chromosome 16. Antinuclear autoantibodies mapped to three loci: Bana1 at the MHC on chromosome 17, Bana2 on chromosome 10, and Bana3 on distal chromosome 1. Glomerular immune complex deposition did not show significant linkage to any genomic region. Mapping of autoantibodies (Coombs' or antinuclear autoantibodies) identified two loci: Babs1 at the MHC and Babs2 on distal chromosome 1. It has previously been reported that genes conferring susceptibility to different autoimmune diseases map nonrandomly to defined regions of the genome. One possible explanation for this clustering is that some alleles at loci within these regions confer susceptibility to multiple autoimmune diseases-the "common gene" hypothesis. With the exception of the H2, this study failed to provide direct support for the common gene hypothesis, because the loci identified as conferring susceptibility to systemic lupus erythematosus did not colocalize with those previously implicated in diabetes. However, three of the four regions identified had been previously implicated in other autoimmune diseases.

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.

Exogenous FGF-4 can suppress anterior development in the mouse embryo during neurulation and early organogenesis.

Members of the fibroblast growth factor (FGF) family of peptide growth factors are widely expressed in the germ layer derivatives during gastrulation and early organogenesis of the mouse. We have investigated the effect of administering recombinant FGF-4 in the late-primitive streak stage embryo to test if the patterning of the body plan may be influenced by this growth factor. Shortly after FGF treatment the embryonic tissues up-regulated the expression of Brachyury and the RTK signaling regulator Spry2, suggesting that FGF signaling was activated as an immediate response to exogenous FGF. Concomitantly, Hesx1 expression was suppressed in the prospective anterior region of the embryo. After 24 h of in vitro development, embryos displayed a dosage-related suppression of forebrain morphogenesis, disruption of the midbrain-hindbrain partition, and inhibition of the differentiation of the embryonic mesoderm. Overall, development of the anterior-posterior axis in the late gastrula is sensitive to the delivery of exogenous FGF-4. The early response associated with the expression of Spry2 suggests that the later phenotype observed could be primarily related to an inhibition of the FGF signaling pathway.

Experimental analysis of the emergence of left-right asymmetry of the body axis in early postimplantation mouse embryos.

The lateral asymmetry of the body axis of mouse embryo is revealed first by the asymmetric expression of genes such as nodal, lefty2 and Pitx2 in the lateral plate mesoderm of the neurulating embryo and subsequently by the looping of the heart tube, the rotation of the body axis and situ solitus of specific visceral organs. Analysis of gene expression in the early gastrula shows that there is a transient asymmetric localization of the transcripts of Cerrl, Fgf8, Hesx1 and Hnf3beta gene in the anterior visceral endoderm, Otx2 and Sox2 in the epiblast and Lim1 in the nascent mesoderm. However, the asymmetric expression is not consistent and varies among the embryos, which may be reflecting the lability of the mechanism for specifying the laterality of the body axis during gastrulation. The plasticity of the process that determines laterality is further manifested by the ability to randomise the expression of the Pitx2 gene in the lateral plate mesoderm in embryos that are grown in vitro. The expression of laterality requires the presence of the node and its axial mesodermal derivatives. In mutant embryos that lack the node and in node-ablated embryos, the loss of the axial notochord is associated with isomerism of the body axis, which is revealed either by the expression of the Pitx2 gene in the lateral plate mesoderm of both sides of the body or the complete absence of expression. Our results are therefore consistent with the concept that the specification of the laterality of the body axis goes through a dynamic phase during gastrulation and the activity of the node and its derivatives is instrumental in the conferment of left-right identity of the embryonic tissues.

The orderly allocation of mesodermal cells to the extraembryonic structures and the anteroposterior axis during gastrulation of the mouse embryo.

The prospective fate of cells in the primitive streak was examined at early, mid and late stages of mouse gastrula development to determine the order of allocation of primitive streak cells to the mesoderm of the extraembryonic membranes and to the fetal tissues. At the early-streak stage, primitive streak cells contribute predominantly to tissues of the extraembryonic mesoderm as previously found. However, a surprising observation is that the erythropoietic precursors of the yolk sac emerge earlier than the bulk of the vitelline endothelium, which is formed continuously throughout gastrula development. This may suggest that the erythropoietic and the endothelial cell lineages may arise independently of one another. Furthermore, the extraembryonic mesoderm that is localized to the anterior and chorionic side of the yolk sac is recruited ahead of that destined for the posterior and amnionic side. For the mesodermal derivatives in the embryo, those destined for the rostral structures such as heart and forebrain mesoderm ingress through the primitive streak early during a narrow window of development. They are then followed by those for the rest of the cranial mesoderm and lastly the paraxial and lateral mesoderm of the trunk. Results of this study, which represent snapshots of the types of precursor cells in the primitive streak, have provided a better delineation of the timing of allocation of the various mesodermal lineages to specific compartments in the extraembryonic membranes and different locations in the embryonic anteroposterior axis.

Impact of node ablation on the morphogenesis of the body axis and the lateral asymmetry of the mouse embryo during early organogenesis.

The node of the mouse gastrula is the major source of the progenitor cells of the notochord, the floor plate, and the gut endoderm. The node may also play a morphogenetic role since it can induce a partial body axis following heterotopic transplantation. The impact of losing these progenitor cells and the morphogenetic activity on the development of the body axes was studied by the ablation of the node at late gastrulation. In the ablated embryo, an apparently intact anterior-posterior body axis with morphologically normal head folds, neural tube, and primitive streak developed during early organogenesis. Cell fate analysis revealed that the loss of the node elicits de novo recruitment of neural ectoderm and somitic mesoderm from the surrounding germ-layer tissues. This leads to the restoration of the neural tube and the paraxial mesoderm. However, the body axis of the embryo was foreshortened and somite formation was retarded. Histological and gene expression studies reveal that in most of the node-ablated embryos, the notochord in the trunk was either absent or interrupted, and the floor plate was absent in the ventral region of the reconstituted neural tube. The loss of the node did not affect the differentiation of the gut endoderm or the formation of the mid- and hindgut. In the node-ablated embryo, expression of the Pitx2 gene in the lateral plate mesoderm was no longer restricted to the left side but was found on both sides of the body or was completely absent from the lateral plate mesoderm. Therefore, the loss of the node results in the failure to delineate the laterality of the body axis. The node and its derivatives therefore play a critical role in the patterning of the ventral neural tube and lateral body axis but not of the anterior-posterior axis during early organogenesis.

Flow cytometric study of T cell development in NOD mice reveals a deficiency in alphabetaTCR+CDR-CD8- thymocytes.

As a result of failed induction of T cell tolerance to pancreatic B cells, non-obese diabetic (NOD) mice develop spontaneous autoimmune insulin-dependent diabetes mellitus (IDDM). The thymic stroma, which plays a crucial role in thymic T cell maturation, undergoes extensive premature disorganization in NOD mice, so it is of interest to examine NOD T cell development. In this study, both major and minor developmental populations of thymocytes of NOD/Lt mice were studied and compared to those of BALB/c, C57BL/6 and CBA mice by multiparameter flow cytometry (FACS). These results are described in detail and reveal that most thymocyte subsets were normally represented, including alphaTcR-CD4-CD8- (triple negative; TN), alphabetaTcR-CD4+CD8- and alphabetaTcR-CD4-CD8+ (immature single positive; ISP), alphabetaTcR-/lowCD4+CD8+ (double positive; DP) and alphabetaTcR+CD4+CD8- and alphabetaTcR+CD4-CD8+ (mature single positive; SP) as well as gammadelta T cells. However, NOD mice exhibited a marked deficiency of thymic alphabetaTcR+CD4-CD8- (alphabeta+DN) T cells. alphabeta+DN T cells, which are included among NK1+ T cells in C57BL/6 mice, produce large amounts of IL-4 on primary stimulation. Given the potential significance of NKT cells in immunoregulation, it is possible that the scarcity of these cells in NOD mice plays a role in the pathogenesis of IDDM.

The allocation of epiblast cells to the embryonic heart and other mesodermal lineages: the role of ingression and tissue movement during gastrulation.

The cardiogenic potency of cells in the epiblast of the early primitive-streak stage (early PS) embryo was tested by heterotopic transplantation. The results of this study show that cells in the anterior and posterior epiblast of the early PS-stage embryos have similar cardiogenic potency, and that they differentiated to heart cells after they were transplanted directly to the heart field of the late PS embryo. That the epiblast cells can acquire a cardiac fate without any prior act of ingression through the primitive streak or movement within the mesoderm suggests that neither morphogenetic event is critical for the specification of the cardiogenic fate. The mesodermal cells that have recently ingressed through the primitive streak can express a broad cell fate that is characteristic of the pre-ingressed cells in the host when they were returned to the epiblast. However, mesoderm cells that have ingressed through the primitive streak did not contribute to the lateral plate mesoderm after transplantation back to the epiblast, implying that some restriction of lineage potency may have occurred during ingression. Early PS stage epiblast cells that were transplanted to the epiblast of the mid PS host embryos colonised the embryonic mesoderm but not the extraembryonic mesoderm. This departure from the normal cell fate indicates that the allocation of epiblast cells to the mesodermal lineages is dependent on the timing of their recruitment to the primitive streak and the morphogenetic options that are available to the ingressing cells at that instance.

Association between alphabetaTCR+CD4-CD8- T-cell deficiency and IDDM in NOD/Lt mice.

NOD mice develop spontaneous IDDM as a result of T-cell-mediated autoimmune destruction of pancreatic beta-cells. It is not known why these T-cells become autoreactive, nor is it clear whether the breakdown in self-tolerance reflects a general problem in T-cell development or a selective defect in an as yet undefined regulatory cell population. In this study, we showed that NOD mice, although relatively normal with regard to most thymocyte subsets, exhibit a marked deficiency in alphabetaTCR+CD4-CD8- (alphabeta+DN) T-cells in the thymus and, to a lesser extent, in the periphery. These T-cells have been termed NKT cells (NK1.1+-like T-cells) because they share some cell surface markers with conventional natural killer (NK) cells. To examine the role of these cells in the pathogenesis of IDDM, semiallogeneic or syngeneic double-negative (DN) thymocytes, enriched for NKT cells, were transferred into intact 4-week-old NOD recipients; the onset of diabetes was then monitored over the ensuing 30 weeks. Mice receiving NKT-enriched thymocytes did not develop diabetes, whereas mice receiving unfractionated thymocytes or phosphate-buffered saline developed diabetes at the normal rate. NKT cells represent a distinct T-cell lineage that has been shown to play a role in immunoregulation in vivo. The deficiency of these cells observed in NOD mice may therefore contribute to destruction of pancreatic islet cells by conventional T-cells.