Interaction of the mutant aphakia, fidget and ocular retardation genes in mice

The phenogenetic analysis of the effects of aphakia (ak) gene and its interaction with the ocular retardation (or) and fidget (fi) genes suggests that the ak gene acts in the lens cells with the result of arresting lens fibre differentiation. In mice homozygous for ak, the lens failure leads to secondary retina defects, in particular, to formation of retinal folds. In ak/ak or/or mice, the lens and retina morphogenesis stops at the optic cup stage, the eye is strongly reduced in size and more affected, compared to the corresponding single homozygotes. Unlike ak/ak or/or, in the ak/ak fi/fi mice the eyes are more regular in shape than those in the ak/ak +/+ condition. The fi gene inhibition of the retina anlage growth leads to some improvement of the eye development in double ak/ak fi/fi homozygotes, due to the absence of extensive retina folding.     

Site of fidget gene action and its interaction with the ocular retardation gene in cultured mouse embryo retinas

The eye rudiments of 10 and 11 days old mouse embryos of the genotypes +/+ +/+, fi/fi +/+, +/+ or/or, fi/fi or/or and 11 days old embryos of the genotype fi/+ or/+ were cultivated in vitro during 24, 48 and 72 hrs. The expression of the fi gene was shown in the cells of the cultivated fi/fi +/+ retina: its proliferative activity was inhibited. The fi gene was not active in the cells of the developing lens and the anomalies of the latter in homozygotes arose secondarily, due to the inhibition of growth of the retinal rudiment. The fi and or genes interacted synergically in the cultivated fi/fi or/or retina, thus resulting in the marked inhibition of its mitotic activity. This suggests that both the genes act in the retinal cells and, apparently, affect different links of the biochemical chain of events in the preparation of DNA replication.     

Mapping of genetic modifiers affecting the eye phenotype of ocular retardation (Chx10 or-J ) mice

Ocular retardation is a recessive murine mutation whose phenotypic expression is greatly affected by genetic background effects. Mice of the inbred 129/SvJ background that are homozygous for the Chx10^or-J mutation are blind and have a thin, poorly differentiated retina and no optic nerve. A backcross between 129/SvJ and Mus musculus castaneus (CASA/Rk) produced animals that were homozygous for the Chx10^or-J mutation, yet showed a much milder phenotype. Such animals, when brother-sister mated and selected for mild phenotype for several generations, resulted in partial recovery of visual function, including presence of an optic nerve and pupillary response. In this article we report a genome scan of phenotypic extremes of the backcross to identify the genetic loci affecting this phenotype modification. Our scan revealed significant loci on Chromosomes 6 and 14 where the CASA/Rk alleles are maintained selectively. Markers were developed near candidate genes, but no candidate gene could be identified unequivocally. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users.     

Penetrance and expressivity of the gene for double podding in chickpea

The double-pod per peduncle trait is known to contribute to increased seed yield in chickpea (Cicer arietinum L.). A cross was made between the single-podded variety ICCV 2 and the double-podded variety JG 62 in 1993. Penetrance and expressivity of the gene for double podding was studied in an F2 population and F10 recombinant inbred lines (RILs) of this cross. Homozygous recessive allele of this gene (ss) governs the production of double flowers and pods per peduncle. Results indicated that the s allele has unstable penetrance and variable expressivity. The penetrance of this allele was 53% for the F2 and 84.5% for the RILs. The ranges for the expression of this trait among the penetrant F2 individuals and the penetrant RILs were 1.1-14.8% and 0.1-33.0%. These were 8.3-30.8% for early sown and 17.1-68.7% for the late sown double-podded parent JG 62. Thus it appears that the allele shows greater penetrance and enhanced expressivity under soil moisture stress. In the F2 the seed yield advantage of the double-podded over the single-podded plants was 18%, whereas among the RILs it was 7%. The increased number of pods and seeds contributed to the higher yield. However, there was a slight decrease in seed size of the double-podded genotypes. An increase in the size of seed may have a role in the decreased penetrance and expressivity of this allele among the double-podded segregants of the ICCV 2 x JG 62 chickpea cross.     

Deletion of the MBII-85 snoRNA gene cluster in mice results in postnatal growth retardation

Prader-Willi syndrome (PWS [MIM 176270]) is a neurogenetic disorder characterized by decreased fetal activity, muscular hypotonia, failure to thrive, short stature, obesity, mental retardation, and hypogonadotropic hypogonadism. It is caused by the loss of function of one or more imprinted, paternally expressed genes on the proximal long arm of chromosome 15. Several potential PWS mouse models involving the orthologous region on chromosome 7C exist. Based on the analysis of deletions in the mouse and gene expression in PWS patients with chromosomal translocations, a critical region (PWScr) for neonatal lethality, failure to thrive, and growth retardation was narrowed to the locus containing a cluster of neuronally expressed MBII-85 small nucleolar RNA (snoRNA) genes. Here, we report the deletion of PWScr. Mice carrying the maternally inherited allele (PWScr^m−/p+) are indistinguishable from wild-type littermates. All those with the paternally inherited allele (PWScr^m+/p−) consistently display postnatal growth retardation, with about 15% postnatal lethality in C57BL/6, but not FVB/N crosses. This is the first example in a multicellular organism of genetic deletion of a C/D box snoRNA gene resulting in a pronounced phenotype.     

Growth retardation and hair loss in transgenic mice overexpressing human H-ferritin gene

H-ferritin (HF) is a core subunit of the iron storage protein ferritin, and plays a central role in the regulation of cellular iron homeostasis. Recent studies revealed that ferritin and HF are involved in a wide variety of iron-independent functions, including regulating biological processes during physiological and pathological conditions, and can be overexpressed in some human diseases. To investigate the in vivo function of HF, we generated transgenic (tg) mice overexpressing the human HF gene (hHF-tg). We established two independent hHF-tg mouse lines. Although both lines of hHF-tg mice were viable, they showed reduced body size compared to wild-type (WT) mice at 4–12 weeks of age. Serum iron concentration and blood parameters of hHF-tg mice such as hemoglobin and red blood cell counts were comparable to those of WT mice. At 3–5 weeks of age, hHF-tg mice exhibited temporary loss of coat hair on the trunk, but not on the head or face. Histological analyses revealed that although initial hair development was normal, hHF-tg mice had epidermal hyperplasia with hyperkeratosis, dilated hair follicles, bended hair shafts and keratinous debris during the hairless period. In conclusion, we showed that hHF-tg mice exhibited mild growth retardation and temporary hairless phenotype. Our findings highlight the physiological roles of HF and demonstrate that hHF-tg mice are useful for understanding the in vivo functions of HF.     

Codon usage in bacteria: correlation with gene expressivity

The nucleic acid sequence bank now contains over 600 protein coding genes of which 107 are from prokaryotic organisms. Codon frequencies in each new prokaryotic gene are given. Analysis of genetic code usage in the 83 sequenced genes of the Escherichia coli genome (chromosome, transposons and plasmids) is presented, taking into account new data on gene expressivity and regulation as well as iso-tRNA specificity and cellular concentration. The codon composition of each gene is summarized using two indexes: one is based on the differential usage of iso-tRNA species during gene translation, the other on choice between Cytosine and Uracil for third base. A strong relationship between codon composition and mRNA expressivity is confirmed, even for genes transcribed in the same operon. The influence of codon use of peptide elongation rate and protein yield is discussed. Finally, the evolutionary aspect of codon selection in mRNA sequences is studied.     

Mutant gene expression in murine aggregation chimeras. 5. The ocular retardation and fidget genes

Analysis of ocular retardation (or) and fidget (fi) genes expression in 18 day old embryos, 10 and 20 day old or/or C/C----+/+ c/c and fi/fi or/or C/C----+/+ +/+ c/c mice has shown that genes or and fi are active in developing retina and suppress cell proliferation. Structural defects of retina and decrease in the eye size in the chimaeras, compared to the normal embryos, were observed already in the presence of 13-16% of mutant cells. As the fraction of mutant cells increased, the degree of eye disturbances increased as well. In the fi/fi or/or----+/+ +/+ chimaeras structural defects of retina and decrease in the eye size are more pronounced than in the or/or----+/+ chimaeras, due to the synergetical effect of both mutant genes in the fi/fi or/or cell clones. In the ontogenesis of the or/or----+/+ chimaeras the development of the retinal photoreceptor layer is normalized due to the substitution of mutant cells for actively proliferating normal cells. No metabolic cooperation between the mutant and normal cells was observed in the developing retina of chimaeras.     

Partial rescue of the ocular retardation phenotype by genetic modifiers

The or(J) allele of the murine ocular retardation mutation is caused by a premature stop codon in the homeodomain of the Chx10 gene. When expressed on an inbred 129/Sv strain, the or(J) phenotype is characterized by microphthalmia and a thin, poorly differentiated retina in which the peripheral portion is affected to a greater extent than the central portion. Such mutant retinae lack differentiated bipolar cells and the optic nerve typically fails to form, leading to blindness. Here, we show that progeny from an outcrossed backcross between 129/Sv-or(J) /or(J) and Mus musculus castaneus produce animals that are homozygous for the or(J) mutation and exhibit a much ameliorated eye phenotype. Although not of normal size, such modified or(J) eyes are significantly larger than those in 129/Sv-or(J) /or(J) mice, and contain a better organized retina which includes bipolar cells. Furthermore, optic nerves are frequently present, and the eyes show a degree of function as reflected by electroretinogram and pupillary response. As in 129/Sv-or(J) /or(J) mice, however, modified or(J) eyes show incomplete growth and a lack of cell differentiation in the periphery of the retina. The selective, and apparently nonmodifiable, effect of the ocular retardation phenotype on the periphery of the retina indicates that Chx10 plays an important role in the central-to-peripheral gradient of retinal development. These findings demonstrate that the ocular retardation phenotype can be greatly modified by the genetic background, and help to define a role for Chx10 in ocular development.     

Variation in gene expression and aberrantly regulated chromosome regions in cloned mice

DNA microarray analysis was used to determine the precise genome-wide gene expression profiles of somatic cloned mice derived from Sertoli and cumulus cells. It demonstrated unexpectedly large epigenetic diversity in neonatal cloned mice, despite their normal appearance and genetic identity. In three neonatal tissues of the cloned mice, the expression of 9-40% of the genes examined was more than two times higher or lower in donor cell-dependent or -independent manners compared with normal controls. Relatively few (0.4-4%) of the genes exhibited up- or downregulation in the same manner in both types of clone. A cluster analysis of the variation in gene expression led to the identification of several chromosome regions in which gene expression was aberrantly controlled in the somatic clones. These results provide a more complete understanding of how somatic clones differ from each other and from normal individuals produced by sexual reproduction and indicate the significant difficulties that face the application of somatic cloning in regenerative medicine.