A Transgene-Induced Mitotic Arrest Mutation in the Mouse Allelic with Oligosyndactylism

Oligosyndactylism (Os) is a radiation-induced mutation on mouse chromosome 8 associated with early postimplantation lethality in homozygotes and abnormal development of the limbs and kidneys in heterozygotes. The recessive lethal effect of Os is due to a mitotic block of the embryonic cells that becomes apparent at the blastocyst stage, but it is not known if the heterozygous effect of Os is due to haploinsufficiency of the gene responsible for the mitotic arrest, or is due to mutation(s) of other gene(s). We have recently described a transgene-induced recessive mutation, 94-A/K, that results in early postimplantation death of the embryos, and we have mapped this mutation to the same region of chromosome 8 where Os has been assigned. On the basis of complementation tests between transgenic and Os/+ mice, in vitro growth characteristics and increased mitotic index of 94-A/K embryos, and molecular structural analysis of 94-A and 94-K transgenic and Os/+ mice, we conclude that the 94-A/K mutation represents a new allele of Os. This insertional mutation should facilitate the isolation of a mammalian gene essential for normal progression of the cell cycle beyond metaphase.     

Enhanced susceptibility of mouse embryos heterozygous for oligosyndactyly (Os/+) to mitomycin C-induced skeletal abnormalities

The mouse mutation, oligosyndactyly (Os), results in syndactyly, muscle anomalies, and deficiency of nephrons in heterozygous animals and early embryonic lethality in homozygotes. Since the homozygous lethality results from mitotic arrest with intact spindles at the time of implantation, we have hypothesized that the heterozygous manifestations may result from impairment of cell proliferation in regions with high proliferative rates. To test this hypothesis, Os/+ and +/+ mouse embryos at 6.5 days of gestation were exposed to mitomycin C (MMC), an agent that causes a high degree of embryonic cell death which is "compensated" for by a period of rapid cell proliferation. 17.9% of MMC-treated +/+ fetuses had fused vertebrae, a significant increase over untreated fetuses, and this frequency was further increased to 33.6% in MMC-treated Os/+ fetuses. Saline treated Os/+ and +/+ fetuses showed the same low rate (0-3%) of vertebral fusion. These results indicate that Os/+ embryos have an increased sensitivity to the vertebral fusion-inducing effect of MMC at 6.5 days of gestation, a finding compatible with the hypothesis that rapid cell proliferation may be impaired in Os/+ embryos and fetuses.     

Molecular Genetics of the Brown (B)-Locus Region of Mouse Chromosome 4. I. Origin and Molecular Mapping of Radiation- and Chemical-Induced Lethal Brown Deletions

Over a period of many years, germ-cell mutagenesis experiments using the mouse specific-locus test have generated numerous radiation- and chemical-induced alleles of the brown (b; Tyrp1) locus in mouse chromosome 4. We describe here the origin, maintenance and initial molecular characterization of 28 b mutations that are prenatally lethal when homozygous. Each of these mutations is deleted for Tyrp1 sequences, and each of 25 mutations tested further is deleted for at least one other locus defined by molecular clones previously found to be closely linked to b by interspecific backcross analysis. A panel of DNAs from mice carrying a lethal b mutation and a Mus spretus chromosome 4 was used in the fine structure mapping of these molecularly defined loci. The deletional nature of each of these prenatally lethal mutations is consistent with the hypothesis that the null phenotype at b has an effect only on the quality (color) of eumelanin produced in melanocytes. The resulting deletion map provides a framework on which to build future molecular-genetic and biological analyses of this region of mouse chromosome 4.     

Analysis of mitochondrial DNA somatic mutations in OXYS and Wistar strain rats

Rats of the OXYS strain are sensitive to oxidative stress and serve as a biological model of premature aging. We have compared spectra of somatic mutations in a control region of mtDNA from the liver of the OXYS rat strain and of Wistar rats as a control. The majority of nucleotide substitutions in the mutation spectra were represented by transitions: 94 and 97% in the OXYS and Wistar rats, respectively. It was shown that 40% of somatic mutations in the control region of mtDNA from Wistar rats were significantly consistent with the model of dislocation mutagenesis. No statistical support for this model was found for mutations in the control region of mtDNA from OXYS rats. The mutation frequency in the ETAS section was higher in the OXYS strain rats than in Wistar rats. These results suggest different mechanisms of mutagenesis in the two rat strains under study.     

Genomic organization and chromosomal localization of the mouse IKBKAP gene.

The autosomal recessive disorder familial dysautonomia (FD) has recently been demonstrated to be caused by mutations in the IKBKAP gene, so named because an initial report suggested that it encoded an IkappaB kinase complex associated protein (IKAP). Two mutations in IKBKAP have been reported to cause FD. The major mutation is a T-->C transition in the donor splice site of intron 20 and the minor mutation is a missense mutation in exon 19 that disrupts a consensus serine/threonine kinase phosphorylation site. We have characterized the cDNA sequences of the mouse, rat and rabbit IKBKAP-encoded mRNAs and determined the genomic organization and chromosomal location of mouse IKBKAP. There is significant homology in the amino acid sequence of IKAP across species and the serine/threonine kinase phosphorylation site altered in the minor FD mutation of IKAP is conserved. The mouse and human IKBKAP genes exhibit significant conservation of their genomic organization and the intron 20 donor splice site sequence, altered in the major FD mutation, is conserved in the human and mouse genes. Mouse IKBKAP is located on the central portion of chromosome 4 and maps to a region in which there is conserved linkage homology between the human and mouse genomes. The homologies observed in the human and mouse sequences should allow, through the process of homologous recombination, for the generation of mice that bear the IKBKAP mutations present in individuals with FD. The characterization of such mice should provide significant information regarding the pathophysiology of FD.     

The ubiquinone-binding site of the Saccharomyces cerevisiae succinate-ubiquinone oxidoreductase is a source of superoxide

The mitochondrial succinate dehydrogenase (SDH) is a tetrameric iron-sulfur flavoprotein of the Krebs cycle and of the respiratory chain. A number of mutations in human SDH genes are responsible for the development of paragangliomas, cancers of the head and neck region. The mev-1 mutation in the Caenorhabditis elegans gene encoding the homolog of the SDHC subunit results in premature aging and hypersensitivity to oxidative stress. It also increases the production of superoxide radicals by the enzyme. In this work, we used the yeast succinate dehydrogenase to investigate the molecular and catalytic effects of paraganglioma- and mev-1-like mutations. We mutated Pro-190 of the yeast Sdh2p subunit to Gln (P190Q) and recreated the C. elegans mev-1 mutation by converting Ser-94 in the Sdh3p subunit into a glutamate residue (S94E). The P190Q and S94E mutants have reduced succinate-ubiquinone oxidoreductase activities and are hypersensitive to oxygen and paraquat. Although the mutant enzymes have lower turnover numbers for ubiquinol reduction, larger fractions of the remaining activities are diverted toward superoxide production. The P190Q and S94E mutations are located near the proximal ubiquinone-binding site, suggesting that the superoxide radicals may originate from a ubisemiquinone intermediate formed at this site during the catalytic cycle. We suggest that certain mutations in SDH can make it a significant source of superoxide production in mitochondria, which may contribute directly to disease progression. Our data also challenge the dogma that superoxide production by SDH is a flavin-mediated event rather than a quinone-mediated one.     

Disease-related mutations in cytochrome c oxidase studied in yeast and bacterial models.

Mitochondrial cytochrome c oxidase is a key protonmotive component of the respiratory chain. Mutations in the mitochondrially-encoded subunits of the complex have been reported in association with a range of diseases. In this work we used yeast and bacterial mutants to assess the effect of human mutations in subunit 1 (L196I) and subunit 3 (G78S, A200T, Delta F94-F98, F251L and W249Stop). While the stop mutation at the C-terminus of subunit 3 and the short deletion were highly deleterious and abolished the assembly of the mitochondrial enzyme, the four missense mutations caused little or no effect on the respiratory function. Detailed analysis of G78S, A200T and Delta F94-F98 in Rhodobacter sphaeroides confirmed and extended these observations. We show in this study that the combination of yeast and bacterial models is a useful tool to elucidate the effect of mutations in the catalytic core of cytochrome oxidase. The yeast enzyme is highly similar to the human enzyme and provides a good model to assess the deleterious effect of reported mutations. The bacterial system allows detailed biochemical analysis of the effect of the mutations on the function and assembly of the catalytic core of the enzyme.     

Molecular Genetic Analysis of the DILUTE-SHORT EAR ( d-se) Region of the Mouse

Genes of the dilute-short ear (d-se) region of mouse chromosome 9 comprise an array of loci important to the normal development of the animal. Over 200 spontaneous, chemically induced and radiation-induced mutations at these loci have been identified, making it one of the most genetically well-characterized regions of the mouse. Molecular analysis of this region has recently become feasible by the identification of a dilute mutation that was induced by integration of an ecotropic murine leukemia virus genome. Several unique sequence cellular DNA probes flanking this provirus have now been identified and used to investigate the organization of wild-type chromosomes and chromosomes with radiation-induced d-se region mutations. As expected, several of these mutations are associated with deletions, and, in general, the molecular and genetic complementation maps of these mutants are concordant. Furthermore, a deletion breakpoint fusion fragment has been identified and has been used to orient the physical map of the d-se region with respect to the genetic complementation map. These experiments provide important initial steps for analyzing this developmentally important region at the molecular level, as well as for studying in detail how a diverse group of mutagens acts on the mammalian germline.     

Spindle-pole organization during early mouse development

Spindle-pole organization during early mouse development was examined using a variety of immunological reagents that recognize centrosomal components. Spindle poles of unfertilized eggs and blastocysts were found to react positively with two antisera (centrin and NRS-01), whereas poles of activated eggs and early cleavage-stage embryos were negative when treated with the same sera. In contrast, a third antiserum (5051) showed positive spindle-pole staining throughout the preimplantation stages of development. Two monoclonal antibodies (MPM-1 and MPM-2) that are known to react with mitotic phosphoproteins were also used in this study. Both antibodies stained the cytoplasm of mitotic cells with extremely high intensity. In addition, MPM-2 was found to stain spindle poles. These results suggest that organizational changes in the spindle pole are occurring during early mouse development. Embryos homozygous for a recessive lethal mutation known as oligosyndactyly (Os) were also treated with the reagents described above. This mutation results in a metaphase arrest at the blastocyst stage with intact spindles being present. Spindle poles were observed in Os homozygous mutants stained with centrin, NRS-01, and 5051. However, when Os mutants were stained with the MPM monoclonal antibodies, about half of the mitotic cells completely lacked the dramatic cytoplasmic staining. This observation is in contrast to that observed for wild-type embryos, where greater than 95% of mitotic cells showed positive cytoplasmic staining.     

Drastic Ca2+ sensitization of myofilament associated with a small structural change in troponin I in inherited restrictive cardiomyopathy

Six missense mutations in human cardiac troponin I (cTnI) were recently found to cause restrictive cardiomyopathy (RCM). We have bacterially expressed and purified these human cTnI mutants and examined their functional and structural consequences. Inserting the human cTnI into skinned cardiac muscle fibers showed that these mutations had much greater Ca2+-sensitizing effects on force generation than the cTnI mutations in hypertrophic cardiomyopathy (HCM). The mutation K178E in the second actin-tropomyosin (Tm) binding region showed a particularly potent Ca2+-sensitizing effect among the six RCM-causing mutations. Circular dichroism and nuclear magnetic resonance spectroscopy revealed that this mutation does not extensively affect the structure of the whole cTnI molecule, but induces an unexpectedly subtle change in the structure of a region around the mutated residue. The results indicate that the K178E mutation has a localized effect on a structure that is critical to the regulatory function of the second actin-Tm binding region of cTnI. The present study also suggests that both HCM and RCM involving cTnI mutations share a common feature of increased Ca2+ sensitivity of cardiac myofilament, but more severe change in Ca2+ sensitivity is associated with the clinical phenotype of RCM.     

水稻窄叶突变体zy17的遗传分析和候选基因鉴定

器官大小调控是一个基本的发育生物学过程,受细胞分裂和细胞扩展的影响。然而,植物器官大小调控的遗传和分子机理仍不清楚。为了进一步了解器官大小调控的分子机制,文章分离了一系列水稻叶子宽窄改变的突变体。其中,窄叶突变体zy17叶变窄,同时伴有植株矮化、穗子变小、枝梗数和穗粒数降低的表型。遗传分析表明该窄叶性状受1个隐性基因控制;细胞学分析表明该突变体叶子的细胞数目和维管束数目显著降低,表明ZY17影响了细胞分裂。基因组重测序进一步筛选出ZY17的3个候选基因：Os02g22390基因突变发生在内含子区,编码蛋白为逆转座蛋白;Os02g28280和Os02g29530基因突变都发生在外显子区,其中Os02g28280编码一个功能未知蛋白,该基因突变后,发生碱基置换,产生非同义突变;Os02g29530编码一个含糖基转移酶相关的PFAM结构域的蛋白,该基因突变后,出现两个碱基的缺失,从而导致其蛋白翻译提前终止。对候选基因的深入研究,将揭示水稻叶子大小调控的机制。     

Estimating the number of coding mutations in genotypic- and phenotypic-driven N-ethyl-N-nitrosourea (ENU) screens

N-ethyl-N-nitrosourea (ENU) is a widely used mutagen in genotypic and phenotypic screens aimed at elucidating gene function. The high rate at which ENU induces point mutations raises the possibility that an observed phenotype may be to the result of another unidentified linked mutation. This article presents methods for estimating the probability of additional linked coding mutations (1) in a given region of DNA using both Poisson and Bayesian models and in (2) an F(1) animal exposed to ENU that has undergone b number of backcrosses. Applying these methods to the mouse data set of Quwailid et al., we estimate that the probability that a confounding mutation is linked to a cloned mutation when the candidate region is 5 Mb is very slim (p < 0.002). Where mutants are identified by genotypic methods, we show that backcrossing in the absence of marker-assisted selection is an inefficient means of eliminating linked confounding mutations.