In this study we show in mice that Ftm (Rpgrip1l) is located at the ciliary basal body. Our data reveal that Ftm is necessary for developmental processes such as the establishment of left-right asymmetry and patterning of the neural tube and the limbs. The loss of Ftm affects the ratio of Gli3 activator to Gli3 repressor, suggesting an involvement of Ftm in Shh signalling. As Ftm is not essential for cilia assembly but for full Shh response, Ftm can be considered as a novel component for cilium-related Hh signalling. Furthermore, the absence of Ftm in arthropods underlines the divergence between vertebrate and Drosophila Hh pathways.
While somatic antibody mutants are rare in the preimmune repertoire and in primary immune responses, they dominate secondary and hyperimmune responses. We present evidence that somatic hypermutation is restricted to a particular pathway of B-cell differentiation in which distinct sets of B-cell clones are driven into the memory compartment. In accord with earlier results of McKean et al. (1984) and Rudikoff et al. (1984), somatic mutation occurs stepwise in the course of clonal expansion, before and after isotype switch, presumably at a rate close to 1 X 10(-3) per base pair per generation. At this rate, both selectable and unselectable mutations accumulate in the rearranged V region genes. The distribution of replacement mutations in the V regions shows that a fraction of the mutations in CDRs is positively selected whereas replacement mutations are counterselected in the FRs. By constructing an antibody mutant through site-specific mutagenesis we show that a point mutation in CDR1 of the heavy chain, found in most secondary anti-NP antibodies, is sufficient to increase NP binding affinity to the level typical for the secondary response. Somatic mutation may contribute to the immune repertoire in a more general sense than merely the diversification of a specific response. We have evidence that clones producing antibodies which no longer bind the immunizing antigen can be kept in the system and remain available for stimulation by a different antigen. Somatic mutations are 10 times less frequent in DJH loci than in either expressed or non-expressed rearranged VDJH or VJ loci. We therefore conclude that a V gene has to be brought into the proximity of the DJH segment in order to fully activate the hypermutational mechanism in these loci.
Mammalian homologues of the Drosophila Iroquois homeobox gene complex, involved in patterning and regionalization of differentiation, have recently been identified (Mech. Dev., 69 (1997) 169; Dev. Biol., 217 (2000) 266; Dev. Dyn., 218 (2000) 160; Mech. Dev., 91 (2000) 317; Dev. Biol., 224 (2000) 263; Genome Res., 10 (2000) 1453; Mech. Dev., 103 (2001) 193). The six members of the murine family were found to be organized in two cognate clusters of three genes each, Irx1, -2, -4 and Irx3, -5, -6, respectively (Peters et al., 2000). As a basis for further study of their regulation and function we performed a comparative analysis of the genomic organization and of the expression patterns of all six Irx genes. The genes are expressed in highly specific and regionalized patterns of ectoderm, mesoderm and endoderm derived tissues. In most tissues the pattern of expression of the clustered genes, especially of Irx1 and -2 and of Irx3 and -5, respectively, closely resembled each other while those of Irx4 and -6 were very divergent. Interestingly, the expression of cognate genes was found to be mutually exclusive in adjacent and interacting tissues of limb, heart and the laryncho-pharyncheal region. The results indicate that the Irx genes are coordinately regulated at the level of the cluster.
As a result of transgenic insertional mutagenesis, heterozygous Fused toes (Ft) mice display a syndactyly of forelimbs and a thymic hyperplasia. Homozygous Ft/Ft embryos die in midgestation, exhibiting a deformation of craniofacial structures, a syndactyly and a polydactyly of fore- and hindlimbs, a disorganization of the ventral spinal cord, and defects in left-right axis formation. Here we report on our structural analyses of the Ft mutation. We established a physical as well as a gene map of the Ft locus, showing that the transgene integration resulted in a deletion of 1.6 Mb of genomic sequences on mouse Chromosome 8. Owing to this deletion, six genes, including the entire IroquoisB (IrxB) gene cluster, are directly affected by the Ft mutation.
We have generated transgenic mouse lines that carry one of three different constructs in which the murine N‐myc gene is expressed under the control of the immunoglobulin heavy chain transcriptional enhancer element (E mu‐N‐myc genes). High‐level expression of the E mu‐N‐myc transgenes occurred in lymphoid tissues; correspondingly, many of these E mu‐N‐myc lines reproducibly developed pre‐B‐ and B‐lymphoid malignancies. The E mu‐N‐myc transgene also appeared to participate in the generation of a T cell malignancy that developed in one E mu‐N‐myc mouse. These tumors and cell lines adapted from them expressed exceptionally high levels of the E mu‐N‐myc transgene; the levels were comparable to those observed in human neuroblastomas with highly amplified N‐myc genes. In contrast, all of the E mu‐N‐myc cell lines had exceptionally low or undetectable levels of the c‐myc RNA sequences, consistent with the possibility that high‐level N‐myc expression can participate in the negative ‘cross‐regulation’ of c‐myc gene expression. Our findings demonstrate that deregulated expression of the N‐myc gene has potent oncogenic potential within the B‐lymphoid lineage despite the fact that the N‐myc gene has never been implicated in naturally occurring B‐lymphoid malignancies. Our results also are discussed in the context of differential myc gene activity in normal and transformed cells.
Ciliopathies are life‐threatening human diseases caused by defective cilia. They can often be traced back to mutations of genes encoding transition zone (TZ) proteins demonstrating that the understanding of TZ organisation is of paramount importance. The TZ consists of multimeric protein modules that are subject to a stringent assembly hierarchy. Previous reports place Rpgrip1l at the top of the TZ assembly hierarchy in Caenorhabditis elegans. By performing quantitative immunofluorescence studies in RPGRIP1L−/− mouse embryos and human embryonic cells, we recognise a different situation in vertebrates in which Rpgrip1l deficiency affects TZ assembly in a cell type‐specific manner. In cell types in which the loss of Rpgrip1l alone does not affect all modules, additional truncation or removal of vertebrate‐specific Rpgrip1 results in an impairment of all modules. Consequently, Rpgrip1l and Rpgrip1 synergistically ensure the TZ composition in several vertebrate cell types, revealing a higher complexity of TZ assembly in vertebrates than in invertebrates.
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