Role of Dlx6 in regulation of an endothelin-1-dependent, dHAND branchial arch enhancer.

Neural crest cells play a key role in craniofacial development. The endothelin family of secreted polypeptides regulates development of several neural crest sublineages, including the branchial arch neural crest. The basic helix-loop-helix transcription factor dHAND is also required for craniofacial development, and in endothelin-1 (ET-1) mutant embryos, dHAND expression in the branchial arches is down-regulated, implicating it as a transcriptional effector of ET-1 action. To determine the mechanism that links ET-1 signaling to dHAND transcription, we analyzed the dHAND gene for cis-regulatory elements that control transcription in the branchial arches. We describe an evolutionarily conserved dHAND enhancer that requires ET-1 signaling for activity. This enhancer contains four homeodomain binding sites that are required for branchial arch expression. By comparing protein binding to these sites in branchial arch extracts from endothelin receptor A (EdnrA) mutant and wild-type mouse embryos, we identified Dlx6, a member of the Distal-less family of homeodomain proteins, as an ET-1-dependent binding factor. Consistent with this conclusion, Dlx6 was down-regulated in branchial arches from EdnrA mutant mice. These results suggest that Dlx6 acts as an intermediary between ET-1 signaling and dHAND transcription during craniofacial morphogenesis.

Disruption of ECE-1 and ECE-2 reveals a role for endothelin-converting enzyme-2 in murine cardiac development.

Endothelin-converting enzyme-1 and -2 (ECE-1 and -2) are membrane-bound metalloproteases that can cleave biologically the inactive endothelin-1 (ET-1) precursor to form active ET-1 in vitro. We previously reported developmental defects in specific subsets of neural crest-derived tissues, including branchial arch-derived craniofacial structures, aortic arch arteries, and the cardiac outflow tract in ECE-1 knockout mice. To examine the role of ECE-2 in cardiovascular development, we have now generated a null mutation in ECE-2 by homologous recombination. ECE-2 null mice develop normally, are healthy into adulthood, are fertile in both sexes, and live a normal life span. However, when they are bred into an ECE-1-null background, defects in cardiac outflow structures become more severe than those in ECE-1 single knockout embryos. In addition, ECE-1(-/-); ECE-2(-/-) double null embryos exhibited abnormal atrioventricular valve formation, a phenotype never seen in ECE-1 single knockout embryos. In the developing mouse heart, ECE-2 mRNA is expressed in the endocardial cushion mesenchyme from embyronic day (E) 12.5, in contrast to the endocardial expression of ECE-1. Levels of mature ET-1 and ET-2 in whole ECE-1(-/-); ECE-2(-/-) embryos at E12.5 do not differ appreciably from those of ECE-1(-/-) embryos. The significant residual ET-1/ET-2 in the ECE-1(-/-); ECE-2(-/-) embryos indicates that proteases distinct from ECE-1 and ECE-2 can carry out ET-1 activation in vivo.

Signaling pathways crucial for craniofacial development revealed by endothelin-A receptor-deficient mice.

Most of the bone and cartilage in the craniofacial region is derived from cephalic neural crest cells, which undergo three primary developmental events: migration from the rhombomeric neuroectoderm to the pharyngeal arches, proliferation as the ectomesenchyme within the arches, and differentiation into terminal structures. Interactions between the ectomesenchymal cells and surrounding cells are required in these processes, in which defects can lead to craniofacial malformation. We have previously shown that the G-protein-coupled endothelin-A receptor (ET(A)) is expressed in the neural crest-derived ectomesenchyme, whereas the cognate ligand for ET(A), endothelin-1 (ET-1), is expressed in arch epithelium and the paraxial mesoderm-derived arch core; absence of either ET(A) or ET-1 results in numerous craniofacial defects. In this study we have attempted to define the point at which cephalic neural crest development is disrupted in ET(A)-deficient embryos. We find that, while neural crest cell migration in the head of ET(A)(-/-) embryos appears normal, expression of a number of transcription factors in the arch ectomesenchymal cells is either absent or significantly reduced. These ET(A)-dependent factors include the transcription factors goosecoid, Dlx-2, Dlx-3, dHAND, eHAND, and Barx1, but not MHox, Hoxa-2, CRABP1, or Ufd1. In addition, the size of the arches in E10.5 to E11.5 ET(A)(-/-) embryos is smaller and an increase in ectomesenchymal apoptosis is observed. Thus, ET(A) signaling in ectomesenchymal cells appears to coordinate specific aspects of arch development by inducing expression of transcription factors in the postmigratory ectomesenchyme. Absence of these signals results in retarded arch growth, defects in proper differentiation, and, in some mesenchymal cells, apoptosis. In particular, this developmental pathway appears distinct from the pathway that includes UFD1L, implicated as a causative gene in CATCH 22 patients, and suggests parallel complementary pathways mediating craniofacial development.

Adipose expression of the phosphoenolpyruvate carboxykinase promoter requires peroxisome proliferator-activated receptor gamma and 9-cis-retinoic acid receptor binding to an adipocyte-specific enhancer in vivo.

A putative adipocyte-specific enhancer has been mapped to approximately 1 kilobase pair upstream of the cytosolic phosphoenolpyruvate carboxykinase (PEPCK) gene. In the present study, we used transgenic mice to identify and characterize the 413-base pair (bp) region between -1242 and -828 bp as a bona fide adipocyte-specific enhancer in vivo. This enhancer functioned most efficiently in the context of the PEPCK promoter. The nuclear receptors peroxisome proliferator-activated receptor gamma (PPARgamma) and 9-cis-retinoic acid receptor (RXR) are required for enhancer function in vivo because: 1) a 3-bp mutation in the PPARgamma-/RXR-binding element centered at -992 bp, PCK2, completely abolished transgene expression in adipose tissue; and 2) electrophoretic mobility supershift experiments with specific antibodies indicated that PPARgamma and RXR are the only factors in adipocyte nuclear extracts which bind PCK2. In contrast, a second PPARgamma/RXR-binding element centered at -446 bp, PCK1, is not involved in adipocyte specificity because inactivation of this site did not affect transgene expression. Moreover, electrophoretic mobility shift experiments indicated that, unlike PCK2, PCK1 is not selective for PPARgamma/RXR binding. To characterize the enhancer further, the rat and human PEPCK 5'-flanking DNA sequences were compared by computer and found to have significant similarities in the enhancer region. This high level of conservation suggests that additional transcription factors are probably involved in enhancer function. A putative human PCK2 element was identified by this sequence comparison. The human and rat PCK2 elements bound PPARgamma/RXR with the same affinities. This work provides the first in vivo evidence that the binding of PPARgamma to its target sequences is absolutely required for adipocyte-specific gene expression.

Role of Endothelin-1/Endothelin-A receptor-mediated signaling pathway in the aortic arch patterning in mice.

The intercellular signaling mediated by endothelins and their G protein-coupled receptors has recently been shown to be essential for the normal embryonic development of subsets of neural crest cell derivatives. Endothelin-1 (ET-1) is proteolytically generated from its inactive precursor by endothelin-converting enzyme-1 (ECE-1) and acts on the endothelin-A (ETA) receptor. Genetic disruption of this ET-1/ECE-1/ETA pathway results in defects in branchial arch- derived craniofacial tissues, as well as defects in cardiac outflow and great vessel structures, which are derived from cephalic (cardiac) neural crest. In this study, in situ hybridization of ETA-/- and ECE-1(-)/- embryos with a cardiac neural crest marker, cellular retinoic acid-binding protein-1, shows that the migration of neural crest cells from the neural tube to cardiac outflow tract is not affected in these embryos. Immunostaining of an endothelial marker, platelet endothelial cell adhesion molecule CD-31, shows that the initial formation of the branchial arch arteries is not disturbed in ETA-/- or ECE-1(-)/- embryos. To visualize the subsequent patterning of arch vessels in detail, we generated ETA-/- or ECE-1(-)/- embryos that expressed an SM22alpha-lacZ marker transgene in arterial smooth muscle cells. Wholemount X-gal staining of these mutant embryos reveals that the abnormal regression and persistence of specific arch arteries results in disturbance of asymmetrical remodeling of the arch arteries. These defects include abnormal regression of arch arteries 4 and 6, enlargement of arch artery 3, and abnormal persistence of the bilateral ductus caroticus and right dorsal aorta. These abnormalities eventually lead to various types of great vessel malformations highly similar to those seen in neural crest-ablated chick embryos and human congenital cardiac defects. This study demonstrates that ET-1/ETA-mediated signaling plays an essential role in a complex process of aortic arch patterning by affecting the postmigratory cardiac neural crest cell development.

Cranial and cardiac neural crest defects in endothelin-A receptor-deficient mice.

Neural crest cells arise in the dorsal aspect of the neural tube and migrate extensively to differentiate into a variety of neural and non-neural tissues. While interactions between neural crest cells and their local environments are required for the proper development of these tissues, little information is available about the molecular nature of the cell-cell interactions in cephalic neural crest development. Here we demonstrate that mice deficient for one type of endothelin receptor, ETA, mimic the human conditions collectively termed CATCH 22 or velocardiofacial syndrome, which include severe craniofacial deformities and defects in the cardiovascular outflow tract. We show that ETA receptor mRNA is expressed by the neural crest-derived ectomesenchymal cells of pharyngeal arches and cardiac outflow tissues, whereas ET-1 ligand mRNA is expressed by arch epithelium, paraxial mesoderm-derived arch core and the arch vessel endothelium. This suggests that paracrine interaction between neural crest-derived cells and both ectoderm and mesoderm is essential in forming the skeleton and connective tissue of the head. Further, we find that pharyngeal arch expression of goosecoid is absent in ETA receptor-deficient mice, placing the transcription factor as one of the possible downstream signals triggered by activation of the ETA receptor. These observations define a novel genetic pathway for inductive communication between cephalic neural crest cells and their environmental counterparts.

Dual genetic pathways of endothelin-mediated intercellular signaling revealed by targeted disruption of endothelin converting enzyme-1 gene.

Recent gene targeting studies have revealed unexpected roles for endothelins in the development of neural crest-derived tissues. Endothelin converting enzyme-1 (ECE-1) catalyzes the proteolytic activation of big endothelin-1 to endothelin-1(ET-1) in vitro. However, the importance of ECE-1 cleavage in the multiple endothelin pathways in vivo is unknown. Here we generated a targeted null mutation in the mouse ECE-1 gene. ECE-1-/- term embryos exhibited craniofacial and cardiac abnormalities virtually identical to the defects seen in ET-1 and endothelin A receptor (ETA)-deficient embryos. Epidermal melanocytes as well as enteric neurons of the distal gut were also absent in ECE-1-/- embryos, reproducing the developmental phenotype seen in ET-3-/- and endothelin B receptor (ETB)-/- mice. Surprisingly, large amounts of mature ET-1 peptide are found in ECE-1-/- embryos, indicating that non-ECE-1 protease(s) can activate ET-1 at certain sites. However, these enzymes cannot produce sufficient mature endothelin at the locations crucial for normal embryonic development. These findings reveal that ECE-1 is a bona fide activating protease for both big ET-1 and big ET-3 in vivo, and that the cell-cell communication pathways represented by the ET-1/ECE-1/ETA axis and the ET-3/ECE-1/ETB axis are each involved in the development of distinct subsets of neural crest cell lineages. Mutations in ECE-1 may cause developmental defects in humans, such as Hirschsprung disease, velocardiofacial syndrome and related neurocristopathies.

Hepatic fibrosis, glomerulosclerosis, and a lipodystrophy-like syndrome in PEPCK-TGF-beta1 transgenic mice.

Transgenic mice overexpressing a constitutively active human TGF-beta1 under control of the rat phosphoenolpyruvate carboxykinase regulatory sequences developed fibrosis of the liver, kidney, and adipose tissue, and exhibited a severe reduction in body fat. Expression of the transgene in hepatocytes resulted in increased collagen deposition, altered lobular organization, increased hepatocyte turnover, and in extreme cases, hemorrhage and thrombosis. Renal expression of the transgene was localized to the proximal tubule epithelium, and was associated with tubulointerstitial fibrosis, characterized by excessive collagen deposition and increased fibronectin and plasminogen activator inhibitor-1 immunoreactivity. Pronounced glomerulosclerosis was evident, and hydronephrosis developed with low penetrance. Expression of TGF-beta1 in white and brown adipose tissue resulted in a lipodystrophy-like syndrome. All white fat depots and brown fat pads were severely reduced in size, and exhibited prominent fibroplasia. This reduction in WAT was due to impaired adipose accretion. Introduction of the transgene into the ob/ob background suppressed the obesity characteristic of this mutation; however, transgenic mutant mice developed severe hepato- and splenomegaly. These studies strengthen the link between TGF-beta1 expression and fibrotic disease, and demonstrate the potency of TGF-beta1 in modulating mesenchymal cell differentiation in vivo.

Rat spermatogenesis in mouse testis.

Recently, transplantation of mouse donor spermatogonial stem cells from a fertile testis to an infertile recipient mouse testis was described. The donor cells established spermatogenesis in the seminiferous tubules of the host, and normal spermatozoa were produced. In the most successful transplants, the recipient mice were fertile and sired up to 80 per cent of progeny from donor cells. Here we examine the feasibility of transplanting spermatogonial stem cells from other species to the mouse seminiferous tubule to generate spermatogenesis. Marked testis cells from transgenic rats were transplanted to the testes of immunodeficient mice, and in all of 10 recipient mice (in 19 of 20 testes), rat spermatogenesis occurred. Epididymides of eight mice were examined, and the three from mice with the longest transplants (> or = 110 days) contained rat spermatozoa with normal morphology. The generation of rat spermatogenesis in mouse testes suggests that spermatogonial stem cells of many species could be transplanted, and opens the possibility of xenogeneic spermatogenesis for other species.

Cell-specific expression of cytosolic phosphoenolpyruvate carboxykinase in transgenic mice.

The gene encoding cytosolic phosphoenolpyruvate carboxykinase (PEPCK) is expressed in multiple cell types in diverse tissues including liver, kidney, intestine, and white and brown adipose tissues. It can thus be considered a model system for examining the regulation of cell-specific transcription. The PEPCK gene is transcribed from a single start site, but studies of transgenic mice have revealed that distinct cis-acting elements (and thus different trans-acting factors) regulate PEPCK expression in hepatocytes, renal proximal tubule epithelial cells, and adipocytes. Hepatocytes require elements between -457 and +69 bp; renal proximal tubule epithelia require elements between -363 and +69 bp; and adipocytes require elements between -2086 and -888 bp. An additional element downstream of +69 bp is required to either attenuate PEPCK mRNA levels in liver and fat or increase renal PEPCK mRNA. We hypothesize that the transcription factors C/EBP and DBP are the principal tissue-specific regulators in liver, and that HNF-1 and perhaps C/EBP are important for kidney-specific PEPCK expression. We propose that the putative downstream element is involved in regulating PEPCK mRNA turnover in liver and fat. Finally, we suggest that the fat-specific element is an enhancer that requires a novel adipogenic regulatory factor, ARF6, to function. The long-term objective will be to fine map the cis-acting elements and identify the cognate trans-acting factors that regulate PEPCK in liver, kidney and fat. This information will help elucidate the combinatorial mechanisms that control the cell-specific expression of this complex gene.

LDL receptor-related protein internalizes and degrades uPA-PAI-1 complexes and is essential for embryo implantation.

The low density lipoprotein receptor-related protein (LRP) is a large multifunctional clearance receptor that has been implicated in the hepatic uptake of chylomicron remnants and in the removal of protease-inhibitor complexes from the circulation and from the extracellular space. Disruption of the LRP gene in mice blocks development of LRP-/- embryos around the implantation stage. The expression pattern of LRP in the postimplantation stage embryo is identical to that of urokinase, a plasminogen activator that confers invasive properties to migrating cells. We demonstrate that LRP mediates uptake and degradation of urokinase-type plasminogen activator-plasminogen activator inhibitor 1 complexes and propose that the inability of the giant cells to remove the inactive protease complexes from their surfaces interferes with implantation of the embryo.

Tissue-specific, developmental, hormonal, and dietary regulation of rat phosphoenolpyruvate carboxykinase-human growth hormone fusion genes in transgenic mice.

The cytosolic phosphoenolpyruvate carboxykinase (PEPCK) gene is expressed in multiple tissues and is regulated in a complex tissue-specific manner. To map the cis-acting DNA elements that direct this tissue-specific expression, we made transgenic mice containing truncated PEPCK-human growth hormone (hGH) fusion genes. The transgenes contained PEPCK promoter fragments with 5' endpoints at -2088, -888, -600, -402, and -207 bp, while the 3' endpoint was at +69 bp. Immunohistochemical analysis showed that the -2088 transgene was expressed in the correct cell types (hepatocytes, proximal tubular epithelium of the kidney, villar epithelium of the small intestine, epithelium of the colon, smooth muscle of the vagina and lungs, ductal epithelium of the sublingual gland, and white and brown adipocytes). Solution hybridization of hGH mRNA expressed from the transgenes indicated that white and brown fat-specific elements are located distally (-2088 to -888 bp) and that liver-, gut-, and kidney-specific elements are located proximally (-600 to +69 bp). However, elements outside of the region tested are necessary for the correct developmental pattern and level of PEPCK expression in kidney. Both the -2088 and -402 transgenes responded in a tissue-specific manner to dietary stimuli, and the -2088 transgene responded to glucocorticoid stimuli. Thus, different tissues utilize distinct cell-specific cis-acting elements to direct and regulate the PEPCK gene.