The secreted protein Sonic hedgehog (Shh) exerts many of its patterning effects through a combination of short- and long-range signalling. Three distinct mechanisms, which are not necessarily mutually exclusive, have been proposed to account for the long-range effects of Shh: simple diffusion of Shh, a relay mechanism in which Shh activates secondary signals, and direct delivery of Shh through cytoplasmic extensions, termed cytonemes. Although there is much data (using soluble recombinant Shh (ShhN)) to support the simple diffusion model of long-range Shh signalling, there has been little evidence to date for a native form of Shh that is freely diffusible and not membrane-associated. Here we provide evidence for a freely diffusible form of Shh (s-ShhNp) that is cholesterol modified, multimeric and biologically potent. We further demonstrate that the availability of s-ShhNp is regulated by two functional antagonists of the Shh pathway, Patched (Ptc) and Hedgehog-interacting protein (Hip). Finally, we show a gradient of s-ShhNp across the anterior-posterior axis of the chick limb, demonstrating the physiological relevance of s-ShhNp.
Herein, we demonstrate that Lrp6-mediated R-spondin 2 signaling through the canonical Wnt pathway is required for normal morphogenesis of the respiratory tract and limbs. We show that the footless insertional mutation creates a severe hypomorphic R-spondin 2 allele (Rspo2 Tg ). The predicted protein encoded by Rspo2Tg neither bound the cell surface nor activated the canonical Wnt signaling reporter TOPFLASH. Rspo2 activation of TOPFLASH was dependent upon the second EGF-like repeat of Lrp6. Rspo2Tg/Tg mice had severe malformations of laryngeal-tracheal cartilages, limbs and palate, and lung hypoplasia consistent with sites of Rspo2 expression. Rspo2Tg/Tg lung defects were associated with reduced branching, a reduction in TOPGAL reporter activity, and reduced expression of the downstream Wnt target Irx3. Interbreeding the Rspo2Tg and Lrp6 -alleles resulted in more severe defects consisting of marked lung hypoplasia and absence of tracheal-bronchial rings, laryngeal structures and all limb skeletal elements.
In most cells, the ubiquitously expressed Na+/H+exchanger isoform 1 (NHE1) is thought to be a primary regulator of pH homeostasis, cell volume regulation, and the proliferative response to growth factor stimulation. To study the function of NHE1 during embryogenesis when these cellular processes are very active, we targeted the Nhe1 gene by replacing the sequence encoding transmembrane domains 6 and 7 with the neomycin resistance gene. NHE activity assays on isolated acinar cells indicated that the targeted allele is functionally null. Although the absence of NHE1 is compatible with embryogenesis, Nhe1 homozygous mutants (−/−) exhibit a decreased rate of postnatal growth that is first evident at 2 wk of age. At this time, Nhe1 −/− animals also begin to exhibit ataxia and epileptic-like seizures. Approximately 67% of the −/− mutants die before weaning. Postmortem examinations frequently revealed an accumulation of a waxy particulate material inside the ears, around the eyes and chin, and on the ventral surface of the paws. Histological analysis of adult tissues revealed a thickening of the lamina propria and a slightly atrophic glandular mucosa in the stomach.
In this report we describe the developmental expression and function of Sp8, a member of the Sp family of zinc finger transcription factors, and provide evidence that the legless transgene insertional mutant is a hypomorphic allele of the Sp8 gene. Sp8 is expressed during embryogenesis in the forming apical ectodermal ridge (AER), restricted regions of the central nervous system, and tail bud. Targeted deletion of the Sp8 gene gives a striking phenotype, with severe truncation of both forelimbs and hindlimbs, absent tail, as well as defects in anterior and posterior neuropore closure leading to exencephaly and spina bifida. Outgrowth of the limb depends on formation of the AER, a signaling center that forms at the limb bud apex. In Sp8 mutants, the AER precursor cells are induced and initially express multiple appropriate marker genes, but expression of these genes is not maintained and progression to a mature AER is blocked. These observations indicate that Sp8 functions downstream of Wnt3, Fgf10, and Bmpr1a in the signaling cascade that mediates AER formation.apical ectodermal ridge ͉ exencephaly ͉ spina bifida ͉ zinc finger ͉ legless
We present an initial characterization of the murine Gsh‐4 gene which is shown to encode a LIM‐type homeodomain. Genes in this category are known to control late developmental cell‐type specification events in simpler organisms. Whole mount and serial section in situ hybridizations show transient Gsh‐4 expression in ventrolateral regions of the developing neural tube and hindbrain. Mice homozygous for a targeted mutation in Gsh‐4 suffer early postnatal death resulting from immature lungs which do not inflate. Prenatal administration of progesterone and glucocorticoid, to extend gestational term and accelerate maturation, resulted in lung inflation at birth. Nevertheless, the hormonally treated mutants generally failed to survive beyond an hour after birth, due to ineffective breathing efforts. It is concluded that Gsh‐4 plays a critical role in the development of respiratory control mechanisms and in the normal growth and maturation of the lung.
Six to eight copies of a transgene integrated into mouse chromosome 15 resulting in a new transgene insertional mutant, Footless, presenting with malformations of the limbs, kidney, and soft palate. Homozygotes possess a unique asymmetric pattern of limb truncations. Posterior structures from the autopod and zeugopod of the hindlimbs are missing with left usually more severely affected than right. In contrast, anterior structures are missing from the right forelimbs. The left forelimb is usually normal except for the absence of the distal telephalanges and nails. These structures are absent on all formed digits. In situ hybridization assays examined the expression of Shh, dHand, Msx2, Fgf8, En1, and Lmx1b in mutant limb buds and indicated normal establishment of the anterior/posterior and dorsal/ventral axes of the developing limbs. However, dysmorphology of the apical ectodermal ridge was observed in the mutant limb buds.
A steady ionic current is driven out of both developing and regenerating amphibian limbs. In the developing limbs of anurans and urodeles, focal outwardly directed current (0.5-2 A/cm 2 ) predicts the location of mesenchyme accumulations producing the early bud. Here, we report measurements of a similar outwardly directed ionic current associated with the development of the limb bud in the mouse and chick embryo by using a noninvasive, self-referencing electrode for the measurement of extracellular current. In both the mouse and chick embryo, flank currents were usually inwardly directedthe direction of Na ؉ uptake by ectoderm. Outward currents associated with the mouse limb bud ranged from 0.04 -10.8 A/cm 2 . Mouse limb bud and flank currents were similar to those measured in amphibian larvae, because they were reversibly collapsed and/or reversed by application of 30 M amiloride, a Na ؉ channel blocker. Unlike the amphibian embryos, flank ectoderm adjacent to the mouse limb bud in the anterior/posterior axis was usually associated with outwardly directed ionic current. This raises the possibility of a different, or changing, gradient of extracellular voltage experienced by mesenchyme cells in this plane of development than that observed in other regions of the limb bud. In the chick flank caudal to the somites, a striking reversal of the inwardly directed flank currents to very large (ϳ100 A/cm 2 ) outwardly directed currents occurred three developmental stages before limb bud formation. We tested the relevance of this outwardly directed ionic current to limb formation in the chick embryo by reversing it by using an artificially applied "countercurrent" pulled through a microelectrode inserted just beneath the caudal ectoderm of the embryo. This application was performed for approximately 6 hr 2.5-3 developmental stages before hindlimb bud formation. This method resulted in abnormal limb formation by the tenth day of gestation in some embryos, whereas all control embryos developed normally. These data suggest an early physiological control of limb development.
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