Mutation of BSND causes Bartter syndrome with sensorineural deafness and kidney failure.

Antenatal Bartter syndrome (aBS) comprises a heterogeneous group of autosomal recessive salt-losing nephropathies. Identification of three genes that code for renal transporters and channels as responsible for aBS has resulted in new insights into renal salt handling, diuretic action and blood-pressure regulation. A gene locus of a fourth variant of aBS called BSND, which in contrast to the other forms is associated with sensorineural deafness (SND) and renal failure, has been mapped to chromosome 1p. We report here the identification by positional cloning, in a region not covered by the human genome sequencing projects, of a new gene, BSND, as the cause of BSND. We examined ten families with BSND and detected seven different mutations in BSND that probably result in loss of function. In accordance with the phenotype, BSND is expressed in the thin limb and the thick ascending limb of the loop of Henle in the kidney and in the dark cells of the inner ear. The gene encodes a hitherto unknown protein with two putative transmembrane alpha-helices and thus might function as a regulator for ion-transport proteins involved in aBS, or else as a new transporter or channel itself.

Regulation of neurotrophin-3 expression by epithelial-mesenchymal interactions: the role of Wnt factors.

Neurotrophins regulate survival, axonal growth, and target innervation of sensory and other neurons. Neurotrophin-3 (NT-3) is expressed specifically in cells adjacent to extending axons of dorsal root ganglia neurons, and its absence results in loss of most of these neurons before their axons reach their targets. However, axons are not required for NT-3 expression in limbs; instead, local signals from ectoderm induce NT-3 expression in adjacent mesenchyme. Wnt factors expressed in limb ectoderm induce NT-3 in the underlying mesenchyme. Thus, epithelial-mesenchymal interactions mediated by Wnt factors control NT-3 expression and may regulate axonal growth and guidance.

The T genes in embryogenesis.

Since its identification in 1927, the mouse T (Brachyury) locus has been implicated in mesoderm formation and notochord differentiation. Recent work has demonstrated that this gene encodes a putative transcription factor expressed specifically in nascent mesoderm and in the differentiating notochord. Homologous genes have been cloned from the frog Xenopus laevis, the zebrafish Brachydanio rerio and the ascidian Halocynthia roretzi. The T gene is an important tool for elucidating mesoderman and embryonic pattern formation.

T-Box Genes in the Kidney and Urinary Tract.

T-box (Tbx) genes encode an ancient group of transcription factors that play important roles in patterning, specification, proliferation, and differentiation programs in vertebrate organogenesis. This is testified by severe organ malformation syndromes in mice homozygous for engineered null alleles of specific T-box genes and by the large number of human inherited organ-specific diseases that have been linked to mutations in these genes. One of the organ systems that has not been associated with loss of specific T-box gene function in human disease for long is the excretory system. However, this has changed with the finding that mutations in TBX18, a member of a vertebrate-specific subgroup within the Tbx1-subfamily of T-box transcription factor genes, cause congenital anomalies of the kidney and urinary tract, predominantly hydroureter and ureteropelvic junction obstruction. Gene expression analyses, loss-of-function studies, and lineage tracing in the mouse suggest a primary role for this transcription factor in specifying the ureteric mesenchyme in the common anlage of the kidney, the ureter, and the bladder. We review the function of Tbx18 in ureterogenesis and discuss the body of evidence that Tbx18 and other members of the T-box gene family, namely, Tbx1, Tbx2, Tbx3, and Tbx20, play additional roles in development and homeostasis of other components of the excretory system in vertebrates.

Tetrodotoxin-sensitive α-subunits of voltage-gated sodium channels are relevant for inhibition of cardiac sodium currents by local anesthetics.

The sodium channel α-subunit (Nav) Nav1.5 is regarded as the most prevalent cardiac sodium channel required for generation of action potentials in cardiomyocytes. Accordingly, Nav1.5 seems to be the main target molecule for local anesthetic (LA)-induced cardiotoxicity. However, recent reports demonstrated functional expression of several "neuronal" Nav's in cardiomyocytes being involved in cardiac contractility and rhythmogenesis. In this study, we examined the relevance of neuronal tetrodotoxin (TTX)-sensitive Nav's for inhibition of cardiac sodium channels by the cardiotoxic LAs ropivacaine and bupivacaine. Effects of LAs on recombinant Nav1.2, 1.3, 1.4, and 1.5 expressed in human embryonic kidney cell line 293 (HEK-293) cells, and on sodium currents in murine, cardiomyocytes were investigated by whole-cell patch clamp recordings. Expression analyses were performed by reverse transcription PCR (RT-PCR). Cultured cardiomyocytes from neonatal mice express messenger RNA (mRNA) for Nav1.2, 1.3, 1.5, 1.8, and 1.9 and generate TTX-sensitive sodium currents. Tonic and use-dependent block of sodium currents in cardiomyocytes by ropivacaine and bupivacaine were enhanced by 200 nM TTX. Inhibition of recombinant Nav1.5 channels was similar to that of TTX-resistant currents in cardiomyocytes but stronger as compared to inhibition of total sodium current in cardiomyocytes. Recombinant Nav1.2, 1.3, 1.4, and 1.5 channels displayed significant differences in regard to use-dependent block by ropivacaine. Finally, bupivacaine blocked sodium currents in cardiomyocytes as well as recombinant Nav1.5 currents significantly stronger in comparison to ropivacaine. Our data demonstrate for the first time that cardiac TTX-sensitive sodium channels are relevant for inhibition of cardiac sodium currents by LAs.

Wnts differentially regulate colony growth and differentiation of chondrogenic rat calvaria cells.

The wingless- and int-related proteins (Wnts) have an important role during embryonic development and limb patterning. To investigate their function during chondrocyte differentiation, we used NIH3T3 cells producing seven members of the Wnt family and secreted frizzled-related protein (sFRP-2) for co-culture experiments with the rat chondrogenic cell line pColl(II)-EGFP-5. Pilot experiments showed a negative effect of Wnt-7a on the proliferation of three rodent chondrogenic cell lines, RCJ3.1(C5.18), CFK-2, and C1. To establish a reporter system for chondrogenic differentiation we then produced a stably transfected chondrogenic cell line based on RCJ3.1(C5.18) for further experiments, which expresses green fluorescence protein (EGFP) under the collagen type II promoter (pColl(II)-EGFP-5). This cell line permits convenient observation of green fluorescence as a marker for differentiation in life cultures. The colony size of this cell line in agarose suspension cultures was reduced to 20-40% of control, when exposed to Wnt-1, 3a, 4, 7a, and 7b for 14 days. Similarly, reporter gene expression and the synthesis of cartilage-specific proteoglycans were inhibited by this group of Wnts. In contrast, pColl(II)-EGFP-5 cells exposed to Wnt-5a and Wnt-11 reached 140% of control, and reporter gene expression and proteoglycan synthesis were stimulated. The effects of Wnt-7a and Wnt-5a were additive in pColl(II)-EGFP-5 cells and some but not all Wnt effects were antagonized by the inhibition of proteoglycan sulfation with chlorate, by sFRP-2, which may modulate Wnt receptor binding, or by inhibitors of protein kinase C. These results suggest two functional Wnt subclasses that differentially regulate proliferation and chondrogenic differentiation in vitro which may have implications for cartilage differentiation in vivo. Since some, but not all Wnt effects were sensitive to inhibitors of proteoglycan synthesis or protein kinase C, multiple modes of signal transduction may be involved.

Embryonic expression of the murine homologue of SALL1, the gene mutated in Townes--Brocks syndrome.

SALL1 is one of three human homologues of the Drosophila region-specific homeotic gene spalt (sal). Mutations of SALL1 on chromosome 16q12.1 cause Townes--Brocks syndrome (TBS) which is characterized by defects in multiple organ systems including limbs, ears, kidneys and anus. Here, we have analyzed the expression of the mouse homologue of SALL1 (Sall1) during early embryogenesis. Sall1 expression is very prominent in the developing brain and the limbs. Other sites of expression include the meso- and metanephros, lens, olfactory bulbs, heart, primitive streak and the genital tubercle. Hence, Sall1 expression to a large degree reflects the structures affected in human TBS.

Cloning and expression analysis of the mouse T-box gene Tbx18.

T-box genes encode transcription factors that regulate a variety of developmental processes. In this report, we describe the cloning and expression analysis of the novel mouse T-box gene Tbx18. During development expression is most prominent in the proepicardial organ and in the epicardium of the heart. Other sites of expression include the cranial paraxial mesoderm, the presomitic mesoderm, the anterior somite half, the genital ridge, and the developing limb buds.

Cloning and expression analysis of the mouse T-box gene tbx20.

T-box genes constitute a conserved multi-gene family with important roles in many developmental processes. In this report, we describe the cloning and expression analysis of a novel mouse T-box gene, Tbx20. Expression is prominent in the extraembryonic mesoderm, in the developing heart, the eye anlage and motor neurons of hindbrain and spinal cord.

Expression patterns of Wnt genes in mouse gut development.

Wnt signaling regulates cell fate decisions and cell proliferation during development and in adult tissues in both invertebrates and vertebrates. Here we describe the identification of Wnt genes, Wnt2a, 4, 5a, 5b, 6 and 11, expressed in mouse embryonic gut development. Each of these genes exhibits a characteristic and regional-specific expression pattern along the anterior-posterior axis of the digestive tube between embryonic day (E) 12.5 and 16.5 of embryonic development. The expression of Wnt5a is confined to the mesenchymal compartment, while expression of Wnt4 is found both in the intestinal epithelium and the mesenteric anlage. Wnt11 is expressed in the epithelium of esophagus and colon, but also in mesenchymal cells of the stomach. Wnt5b and Wnt6 exhibit restricted expression in the epithelium of the esophagus. A characteristic regionalized expression pattern is observed in the developing stomach. Wnt5a is expressed in the mesenchymal layer of the prospective gland region but becomes restricted to the tip of the gland region by E14.5. Wnt11 is highly expressed at the gastro-esophageal junctions, while Wnt4 is found in the epithelium lining the pyloric region of the stomach but not in the epithelium of the prospective gland region.

Brachyury is a target gene of the Wnt/beta-catenin signaling pathway.

To identify target genes of the Wnt/beta-catenin signaling pathway in early mouse embryonic development we have established a co-culture system consisting of NIH3T3 fibroblasts expressing different Wnts as feeder layer cells and embryonic stem (ES) cells expressing a green fluorescent protein (GFP) reporter gene transcriptionally regulated by the TCF/beta-catenin complex. ES cells specifically respond to Wnt signal as monitored by GFP expression. In GFP-positive ES cells we observe expression of Brachyury. Two TCF binding sites located in a 500 bp Brachyury promoter fragment bind the LEF-1/beta-catenin complex and respond specifically to beta-catenin-dependent transactivation. From these results we conclude that Brachyury is a target gene for Wnt/beta-catenin signaling.

Identification of a Wnt/beta-catenin signaling pathway in human thyroid cells.

beta-Catenin is a structural component of the adherens junctions. Outside the adherens junctions a complex consisting of glycogen synthase kinase 3beta, the tumor suppressor adenomatous polyposis coli, and axin constantly targets beta-Catenin for degradation to keep levels of free beta-Catenin low. Free beta-Catenin is able to bind to transcription factors of the T cell factor/lymphoid-enhancing factor family and to stimulate transcription of target genes. This signaling function of beta-Catenin is activated by extracellular Wnt factors that bind to Frizzled receptors and induce inhibition of beta-Catenin degradation. By RT-PCR and subcloning, we observed the expression of five Wnt factors, three members of the Frizzled receptor family, and all known Disheveled isoforms in thyroid cells. Immunoprecipitation studies demonstrated the formation of the complex targeting beta-Catenin for degradation. Introduction of a degradation resistant beta-Catenin into the thyroid carcinoma cell line WRO induced appearance of monomeric beta-Catenin as shown by size fractionation and nuclear beta-Catenin immunostaining. Reporter gene assays demonstrated a stimulation of T cell factor/lymphoid-enhancing factor-mediated transcription in these cells. In ARO cells, a thyroid carcinoma cell line carrying a mutated adenomatous polyposis coli gene, monomeric beta-Catenin and nuclear immunostaining were observed. In summary, our data indicate that elements of the Wnt signaling pathway are expressed in thyroid cells and that this pathway is functionally active.

Pax-2 regulatory sequences that direct transgene expression in the developing neural plate and external granule cell layer of the cerebellum.

Expression of Pax-2 in the mouse gastrula is the first marker of the midbrain-hindbrain region. To address roles played by transcription factors in the process of neural plate pattern formation and to facilitate gain-of-function approaches in the study of midbrain-hindbrain and cerebellar development, we characterized regulatory sequences at the Pax-2 locus using an in vivo transgenic mouse reporter assay. An 8.5 kb fragment of genomic DNA located upstream of Pax-2 directed lacZ expression prior to neurulation (7.5 days post-coitum, dpc) in a region fated to become midbrain and hindbrain, and subsequently in developing neuroepithelium. While similar to the pattern of Pax-2 expression, reporter gene activity extended beyond the boundaries of Pax-2 expression, most probably reflecting purdurance of beta-galactosidase activity and an absence of DNA sequences that restrict Pax-2 expression to rhombomere 1 by 9. 5 dpc. In the fetal and neonatal brain, Pax-2-lacZ activity was confined largely to Purkinje cells and the external granule cell layer (EGL) of the cerebellum. A 4 kb regulatory element, in contrast, initiated neural expression at 8.25 dpc in the anterior hindbrain, but recapitulated all later aspects of Pax-2-lacZ activity observed with the larger transgene. These results indicate the presence of regulatory sequences upstream of the Pax-2 locus capable of directing gene expression in the developing midbrain, first rhombomere of the hindbrain, and its principal derivative, the cerebellum. Successful misexpression of Sonic hedgehog demonstrates that Pax-2 regulatory sequences should prove generally useful for transgenic gain-of-function approaches in mice.

Down the tube of obstructive nephropathies: the importance of tissue interactions during ureter development.

Congenital obstructive malformations of the ureter are amongst the most common human birth defects. To date, the etiology of these diseases has remained largely unexplored, which has preempted any rational approach for therapeutic intervention. Here, we describe that obstructive ureter defects can arise from genetic insults affecting various subprograms of ureter development including formation and patterning of the ureteric bud, differentiation of tissue compartments of the ureter, and junction formation with the bladder and pelvis. New experimental findings have highlighted the importance of epithelial-mesenchymal tissue interactions in all of these subprograms and provided unique insights into the molecular nature of the transcriptional regulators and signaling pathways involved.

Immunohistochemical analysis of the Brachyury protein in wild-type and mutant mouse embryos.

The murine Brachyury (T) gene is required in posterior mesoderm formation and axial development. Mutant embryos lacking T gene function are deficient in notochord differentiation and posterior mesoderm formation, but make anterior mesoderm. Posterior axial development requires increasing T activity along the rostrocaudal axis. The T gene is transiently transcribed in nascent and migrating mesoderm and continuously in the notochord. The maintenance of T expression in the notochord depends, directly or indirectly, on wild-type T activity. In Xenopus it has been shown that the onset of T expression occurs in response to mesoderm-inducing growth factors. The T protein is binding to DNA and is probably involved in the control of gene expression. Here we show that the T protein is located in the nucleus. We have analyzed the expression pattern of T protein in wild-type and mutant embryos from early primitive streak formation to the end of the tail bud stage. Throughout all stages of mesoderm formation T protein is transiently present in nascent and migrating mesoderm. In the notochord T protein persists to the end of the tail bud stage. It is also transiently detectable in the forming gut endoderm and in prospective neuroectoderm of later embryos. This shows that T expression is not strictly correlated with a commitment of cells to mesoderm. The analysis of the tail development of TWis/+ mutant embryos demonstrated that the formation of the neural tube, gut, and somites from the tail bud proceeds in the absence of a notochord. The maintenance and differentiation of these structures, however, seems to depend on signals from the notochord.

The Brachyury gene encodes a novel DNA binding protein.

Brachyury (T) mutant embryos are deficient in mesoderm formation and do not complete axial development. The notochord is most strongly affected. The T gene is expressed transiently in primitive streak-derived nascent and migrating mesoderm cells and continuously in the notochord. Ectopic expression of T protein in the animal cap of Xenopus embryos results in ectopic mesoderm formation. The T protein is located in the nucleus. These and other data suggested that the T gene might be involved in the control of transcriptional regulation. In an attempt to demonstrate specific DNA binding of the T protein we have identified a consensus sequence among DNA fragments selected from a mixture of random oligomers. Under our experimental conditions T protein binds as a monomer to DNA. This property resides in the N-terminal domain of 229 amino acid residues which is strongly conserved between the mouse protein, and its Xenopus and zebrafish homologues. The latter proteins also recognize the consensus DNA binding site. We suggest that the T protein is involved in the control of genes required for mesoderm formation, and for the differentiation and function of chorda mesoderm.

sFRP-2 is a target of the Wnt-4 signaling pathway in the developing metanephric kidney.

Members of the Wnt family of secreted glycoproteins act as short-range signaling molecules in vertebrate embryogenesis. Previous work has shown that Wnt-4 is required for kidney development. Mice lacking functional Wnt-4 fail to form pretubular cell aggregates. Wnt-4 acts as an autoinducer of the mesenchymal to epithelial transition underlying nephron development. We have identified a member of the gene family encoding secreted frizzled related proteins (sFRP), putative Wnt antagonists, that shows overlapping expression with Wnt-4 in aggregating mesenchyme and simple epithelial bodies during metanephric development. sFRP-2 expression is absent in metanephric mesenchyme of kidneys mutant for Wnt-4 and is coinduced with Wnt-4 in isolated metanephric mesenchyme by cells expressing Wnt-4. The cysteine-rich domain of sFRP-2 binds to Wnt-4 as shown by coimmunoprecipitation experiments. Hence, sFRP-2 is a target of the Wnt-4 signaling pathway in the metanephric kidney and may modulate Wnt-4 signaling. sFRP-2 expression is highly dynamic and specific during other aspects of embryogenesis. sFRP-2 is expressed in subpopulations of ependymal cells in spinal cord and brain, in the developing eye, in limb bud mesenchyme, in the heart, and strongly in skeletogenic condensations of facial bones, suggesting widespread interaction with other members of the Wnt gene family during embryogenesis.

Homologs of the mouse Brachyury gene are involved in the specification of posterior terminal structures in Drosophila, Tribolium, and Locusta.

The Brachyury (T) gene is required for notochord differentiation in vertebrates. We have identified a Drosophila gene, the T-related gene (Trg), with high similarity to T within a stretch of approximately 200 amino acids, the DNA-binding domain of T. Trg is expressed throughout embryogenesis, first at the blastoderm stage in the hindgut primordium under the control of the terminal gap genes tll and hkb, and then until the end of embryogenesis in the differentiating hindgut. Drosophila embryos deficient for Trg do not form the hindgut, a phenotype that can be rescued by a Trg transgene. Thus, a common feature of T and Trg is their requirement in specifying the development of a single embryonic structure. Homologs of Trg are also expressed in the developing hindgut of Tribolium and Locusta embryos suggesting a highly conserved function of Trg in insects. This conservation and the high similarity of T and Trg raise the question of a common evolutionary origin of the hindgut of insects and the notochord of chordates.

Rescue of the tail defect of Brachyury mice.

The mouse Brachyury (T) gene is required for normal development of axial structures. Embryos homozygous for the T mutation show severe deficiencies in mesoderm formation. They lack the notochord and allantois, have abnormal somites, and die at approximately 10 days postcoitum probably as a result of the allantois defect. Mice heterozygous for the T mutation exhibit a variable short-tailed phenotype. The T gene has been cloned and shown to be expressed in the tissues most strongly affected by the mutation. In this paper, we show that a single-copy transgene representing the wild-type T allele is able to rescue the T-associated tail phenotype. In addition, we show that increasing dosage of the T gene in Tc/+ mice causes an increased extension of the axis. These data show the correlation of the level of T product with the extension of the anteroposterior axis, directly demonstrating the involvement of the T product in this process.

The T protein encoded by Brachyury is a tissue-specific transcription factor.

The mouse Brachyury (T) gene is required for differentiation of the notochord and formation of mesoderm during posterior development. Homozygous embryos lacking T activity do not develop a trunk and tail and die in utero. The T gene is specifically expressed in notochord and early mesoderm cells in the embryo. recent data have demonstrated that the T protein is localized in the cell nucleus and specifically binds to a palindrome of 20 bp (the T site) in vitro. We show that the T protein activates expression of a reporter gene in HeLa cells through binding to the T site. Thus T is a novel tissue-specific transcription factor. It consists of a large N-terminal DNA binding domain (amino acids 1-229) and two pairs of transactivation and repression domains in the C-terminal protein half. T can also transactivate transcription through variously oriented and spaced T sites, a fact that may be relevant in the search for genes controlled by T protein and important in mesoderm development.