The lungs are generated by branching morphogenesis as a result of reciprocal signalling interactions between the epithelium and mesenchyme during development. Mutations that disrupt formation of either the correct number or shape of epithelial branches affect lung function. This, in turn, can lead to congenital abnormalities such as cystadenomatoid malformations, pulmonary hypertension or lung hypoplasia. Defects in lung architecture are also associated with adult lung disease, particularly in cases of idiopathic lung fibrosis. Identifying the signalling pathways which drive epithelial tube formation will likely shed light on both congenital and adult lung disease. Here we show that mutations in the planar cell polarity (PCP) genes Celsr1 and Vangl2 lead to disrupted lung development and defects in lung architecture. Lungs from Celsr1Crsh and Vangl2Lp mouse mutants are small and misshapen with fewer branches, and by late gestation exhibit thickened interstitial mesenchyme and defective saccular formation. We observe a recapitulation of these branching defects following inhibition of Rho kinase, an important downstream effector of the PCP signalling pathway. Moreover, epithelial integrity is disrupted, cytoskeletal remodelling perturbed and mutant endoderm does not branch normally in response to the chemoattractant FGF10. We further show that Celsr1 and Vangl2 proteins are present in restricted spatial domains within lung epithelium. Our data show that the PCP genes Celsr1 and Vangl2 are required for foetal lung development thereby revealing a novel signalling pathway critical for this process that will enhance our understanding of congenital and adult lung diseases and may in future lead to novel therapeutic strategies.
Little is known of the molecular processes that lead to the growth of stereocilia on the surface of hair cells in the inner ear. The PDZ protein whirlin is known, by virtue of the whirler mutation, to be involved in the process of stereocilia elongation and actin polymerization in the sensory hair cells of mammals. We have investigated the function of whirlin and its putative interacting partner, myosin XVa, in the stereocilium using relevant mice mutants. We raised an antibody that detects the short isoform of the whirlin protein which has been demonstrated to rescue the stereocilia growth defect in the whirler mutant. We show that whirlin localizes at the tips of stereocilia. Expression of whirlin is dynamic during stereocilia growth, demonstrating an ordered appearance and fade-out across the stereocilia rows and revealing a novel molecular gradation of process traversing the stereocilia bundle. Fade-out of whirlin in inner hair cells precedes that of outer hair cells, consistent with the earlier maturation of inner hair cell stereocilia. In myosin XVa mutants in which stereocilia are shortened, whirlin expression in the stereocilia tips is stalled and fade-out is accelerated. In whirlin mutants, myosin XVa is still expressed in stereocilia, but its appearance at the stereocilia tip is delayed. The data indicate that whirlin expression is a critical and dynamic organizer for stereocilia elongation and actin polymerization.
Mutations in a number of genes have been linked to inherited dilated cardiomyopathy (DCM). However, such mutations account for only a small proportion of the clinical cases emphasising the need for alternative discovery approaches to uncovering novel pathogenic mutations in hitherto unidentified pathways. Accordingly, as part of a large-scale N-ethyl-N-nitrosourea mutagenesis screen, we identified a mouse mutant, Python, which develops DCM. We demonstrate that the Python phenotype is attributable to a dominant fully penetrant mutation in the dynamin-1-like (Dnm1l) gene, which has been shown to be critical for mitochondrial fission. The C452F mutation is in a highly conserved region of the M domain of Dnm1l that alters protein interactions in a yeast two-hybrid system, suggesting that the mutation might alter intramolecular interactions within the Dnm1l monomer. Heterozygous Python fibroblasts exhibit abnormal mitochondria and peroxisomes. Homozygosity for the mutation results in the death of embryos midway though gestation. Heterozygous Python hearts show reduced levels of mitochondria enzyme complexes and suffer from cardiac ATP depletion. The resulting energy deficiency may contribute to cardiomyopathy. This is the first demonstration that a defect in a gene involved in mitochondrial remodelling can result in cardiomyopathy, showing that the function of this gene is needed for the maintenance of normal cellular function in a relatively tissue-specific manner. This disease model attests to the importance of mitochondrial remodelling in the heart; similar defects might underlie human heart muscle disease.
The human XRCC2 gene was recently identified by its ability to complement a hamster cell line, irs1, which is sensitive to DNA-damaging agents and shows genetic instability. The XRCC2 protein is highly conserved in mammalian species and has structural features, including a putative ATP-binding domain (P-loop), consistent with membership of the RecA/RAD51 family of recombination-repair proteins. We show that a hybrid XRCC2-green fluorescent protein, which was found to be functional by complementation, localizes to the nucleus. We have established a functional link between XRCC2 and RAD51 by looking at damage-dependent RAD51 focus formation in the irs1 cell line. Little or no formation of RAD51 foci occurred in irs1. This effect was specific to the loss of XRCC2 because transfection of the gene into irs1 restored normal levels of focus formation. Surprisingly, XRCC2 genes carrying site-specific mutations in P-loop residues were found to be able to complement the XRCC2-deficient irs1 line for a number of different end points. We conclude that XRCC2 is important in the early stages of homologous recombination in mammalian cells to facilitate RAD51-dependent recombination repair but that it does not make use of ATP binding to promote this function.The repair of DNA damage by homologous recombination has an important function in maintaining genetic stability in cells. In bacteria, the RecA protein has a central role in the recombination process, and in the last decade RecA-like proteins have been discovered in eukaryotes. In particular the RAD51 protein is highly conserved from yeast to humans and has been shown to have similar attributes to RecA (1, 2). Mutations in both RecA and RAD51 cause severe defects in recombination and extreme sensitivity to DNA-damaging agents. RecA acts directly in recombination processes in which, in the presence of ATP, it forms a polymer on single-stranded DNA and promotes strand exchange with a homologous sequence (3). Using molecular recombination assays, yeast (Saccharomyces cerevisiae) and human RAD51 proteins have been shown to promote strand exchange similarly, although some of the biochemical properties of RAD51 differ from those of RecA.For example, purified RecA preferentially binds to singlestranded DNA and hydrolyzes ATP at a relatively high rate, whereas the yeast and human RAD51 proteins bind equally to single-and double-stranded DNA and show a much lower rate of ATP hydrolysis (1). All members of this family have a highly conserved sequence motif, first described by Walker et al. (4), that has been linked to ATP binding. The flexible loop of this motif (Walker box A) interacts with the phosphates of ATP and is therefore sometimes called the P-loop.In S. cerevisiae, two further members of the RecA/ RAD51family of proteins facilitate homologous recombination in mitotic cells; Rad55p and Rad57p form a heterodimer and stimulate RAD51-mediated recombination (5). Yeast mutants that lack these recombination proteins are also extremely sensitive to agents causing severe forms of da...
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