Altered retinoid distribution in the repeated epilation (Er) mutant mouse.

The repeated epilation (Er) mutation in mice causes successive loss and regrowth of hair in heterozygotes (Er/+), and blocks orofacial development and epidermal differentiation in lethal homozygotes (Er/Er). Because the mutation affects a systemic factor, because the Er phenotypes resemble exposure to excess retinoids and because retinoids are critical regulators of epithelial differentiation, we examined whether systemic retinoid levels are altered by the Er defect. Liver retinoic acid and retinol were elevated 1.5- and 3.5-fold, respectively, in adult heterozygotes (Er/+) compared to normal (+/+) animals. Retinyl palmitate was increased 2-fold in heterozygous skin and 3-fold in kidney, but the retinol level in plasma was only half that of normal animals. Newborn heterozygous liver also had nearly 2-fold increased retinoids compared to normal. In contrast, Er/Er newborns had reduced retinoid levels in liver, two-thirds the retinol and 15% the retinyl palmitate compared to normal, but greater than 4-fold elevated levels of retinyl palmitate in the extrahepatic body. Tissue contents of retinol binding protein (RBP), which transports vitamin A from the liver to the remainder of the body, were determined by immunoblotting with anti-mouse RBP. Newborn normal and mutant animals had similar liver microsomal RBP contents. RBP contents in plasma and in liver microsomes were also similar in normal and Er/+ adults despite different retinol contents in the Er/+ tissues. Hair follicles of the Er/+, but not the normal adult, were stained with this antiserum to RPB in the outer root sheath layer. These results strongly suggest that altered retinoid distribution is associated with, and may be responsible for, the altered epithelial differentiation in the Er mutant.     

Missense mutation in the tubulin-specific chaperone E (Tbce) gene in the mouse mutant progressive motor neuronopathy,a model of human motoneuron disease

Progressive motor neuronopathy (pmn) mutant mice have been widely used as a model for human motoneuron disease. Mice that are homozygous for the pmn gene defect appear healthy at birth but develop progressive motoneuron disease, resulting in severe skeletal muscle weakness and respiratory failure by postnatal week 3. The disease starts at the motor endplates, and then leads to axonal loss and finally to apoptosis of the corresponding cell bodies. We localized the genetic defect in pmn mice to a missense mutation in the tubulin-specific chaperone E (Tbce) gene on mouse chromosome 13. The human orthologue maps to chromosome 1q42.3. The Tbce gene encodes a protein (cofactor E) that is essential for the formation of primary alpha-tubulin and beta-tubulin heterodimeric complexes. Isolated motoneurons from pmn mutant mice exhibit shorter axons and axonal swelling with irregularly structured beta-tubulin and tau immunoreactivity. Thus, the pmn gene mutation provides the first genetic evidence that alterations in tubulin assembly lead to retrograde degeneration of motor axons, ultimately resulting in motoneuron cell death.     

Expression of the zinc finger gene Gli3 is affected in the morphogenetic mouse mutant extra-toes (Xt).

Genetic analysis and homology between the phenotypic alterations of the human Greig Cephalopolysyndactyly Syndrome (GCPS) and the mouse mutant extra-toes (Xt) have suggested a dominant mutation in the same gene of both species. Recently, the GLI3 gene, a member of the Krüppel-related zinc finger genes, has been proposed as a candidate gene for GCPS. We examined the expression of the mouse Gli3 gene in both Xt mutant animals and during normal mouse development. Northern and RNAase protection analysis of embryos revealed that Gli3 expression was reduced about 50% in heterozygous Xt/+ mice and completely absent in homozygous Xt/Xt mice. In addition, in situ analysis of wild-type mice documented Gli3 expression in the developing limb and brain, structures affected in Xt mutant mice. This pattern suggests an important function of the Gli3 gene during morphogenesis.     

A mouse model of Waardenburg syndrome type IV resulting from an ENU-induced mutation in endothelin 3

A line of mutant mice (114-CH19) exhibiting white spotting and preweaning lethality was identified during an N-ethyl-N-nitrosourea (ENU) mutagenesis screen. The trait segregated as a semidominant bellyspot with reduced penetrance. Homozygous mutant mice showed preweaning lethality, and exhibited white spotting over the majority of the body surface, with pigmented patches remaining around the pinnae, eyes and tail. Linkage analysis localized 114-CH19 on mouse chromosome 2, suggesting endothelin 3 (Edn3) as a candidate gene. Sequence analysis of Edn3 identified a G > A transversion that encodes an arginine to histidine substitution (R96H). This mutation is predicted to disrupt furin-mediated proteolytic cleavage of pro-endothelin that is necessary to form biologically active EDN3. This mutation is novel among human and mouse EDN3 mutants, is the first reported EDN3 ENU mutant, and is the second reported EDN3 point mutation. This study demonstrates the power of using ENU mutagenesis screens to generate new animal models of human disease, and expands the spectrum of EDN3 mutant alleles.     

Retinol-binding protein-deficient mice: biochemical basis for impaired vision

We reported previously that mice lacking plasma retinol-binding protein (RBP) are phenotypically normal except that they display impaired vision at the time of weaning. This visual defect is associated with greatly diminished eyecup levels of retinaldehyde and is reversible if the mutants are maintained for several months on a vitamin A-sufficient diet. Here we provide a biochemical basis for the visual phenotype of RBP-deficient mice. This phenotype does not result from inadequate milk total retinol levels since these are not different for RBP-deficient and wild-type mice. The eye, unlike all other tissues that have been examined, takes up dietary retinol very poorly. Moreover, compared to other tissues, the eye displays a strong preference for retinol uptake when retinol is delivered bound to RBP. The poor uptake of dietary retinol by the eye coupled with its marked ability to take up retinol from RBP, we propose, provides a basis for the impaired vision observed in weanling RBP-deficient mice. Further study of the mutants suggests that the impaired vision is reversible because the eyes of mutant mice slowly acquire sufficient retinol from the low levels of retinol present in their circulation either bound to albumin or present in lipoprotein fractions. Thus, the eye is unlike other tissues in the body in that it shows a very marked preference for acquiring retinol needed to support vision from the retinol-RBP complex and is unable to meet adequately its retinol need through uptake of recently absorbed dietary retinol. This provides an explanation for the impaired vision phenotype of RBP-deficient mice.     

A novel candidate gene for mouse and human preaxial polydactyly with altered expression in limbs of Hemimelic extra-toes mutant mice

Polydactyly is a common malformation of vertebrate limbs. In humans a major locus for nonsyndromic pre-axial polydactyly (PPD) has been mapped previously to 7q36. The mouse Hemimelic extra-toes (Hx) mutation maps to a homologous chromosome segment and has been proposed to affect a homologous gene. To understand the molecular changes underlying PPD, we used a positional cloning approach to identify the gene or genes disrupted by the Hx mutation and a closely linked limb mutation, Hammertoe (Hm). High resolution genetic mapping identified a small candidate interval for the mouse mutations located 1.2 cM distal to the Shh locus. The nonrecombinant interval was completely cloned in bacterial artificial chromosomes and searched for genes using a combination of exon trapping, sample sequencing, and mapping of known genes. Two novel genes, Lmbr1 and Lmbr2, are entirely within the candidate interval we defined genetically. The open reading frame of both genes is intact in mutant mice, but the expression of the Lmbr1 gene is dramatically altered in developing limbs of Hx mutant mice. The correspondence between the spatial and temporal changes in Lmbr1 expression and the embryonic onset of the Hx mutant phenotype suggests that the mouse Hx mutation may be a regulatory allele of Lmbr1. The human ortholog of Lmbr1 maps within the recently described interval for human PPD, strengthening the possibility that both mouse and human limb abnormalities are due to defects in the same highly conserved gene.     

Rescue of the neural tube defect of loop-tail mice by a BAC clone containing the Ltap gene

The mouse mutant loop-tail (Lp) is an accepted model for the study of neural tube defects (NTDs) in humans. Whereas Lp/+ heterozygotes show a mild tail defect (looped), homozygous Lp/Lp embryos show a very severe form of NTD, with a completely open neural tube from the hindbrain region to the caudal portion of the spinal cord (craniorachischisis). We have recently identified a positional candidate for Lp on chromosome 1, designated as Ltap. Here, we have used an in vivo complementation approach in transgenic mice to attempt to correct the looped-tail phenotype with a bacterial artificial chromosome clone (BAC280A23) that harbors a full-length copy of the Ltap gene. Genotype:phenotype correlations in Lp/+ heterozygotes carrying BAC280A23 show that this clone can rescue the looped-tail phenotype in two independent founder lines (P < 0.05 and P < 0.0001). Importantly, BAC280A23 is also observed to rescue the lethal NTD of Lp/Lp homozygotes, because several viable transgenic Lp/Lp mice could be identified and appeared normal (P < 0.05). Results from these gain-of-function transgenic animals strongly suggest that the positional candidate Ltap present in this BAC is indeed the gene that is defective in loop-tail.     

Missense mutation in the second RNA binding domain reveals a role for Prkra (PACT/RAX) during skull development

Random chemical mutagenesis of the mouse genome can causally connect genes to specific phenotypes. Using this approach, reduced pinna (rep) or microtia, a defect in ear development, was mapped to a small region of mouse chromosome 2. Sequencing of this region established co-segregation of the phenotype (rep) with a mutation in the Prkra gene, which encodes the protein PACT/RAX. Mice homozygous for the mutant Prkra allele had defects not only in ear development but also growth, craniofacial development and ovarian structure. The rep mutation was identified as a missense mutation (Serine 130 to Proline) that did not affect mRNA expression, however the steady state level of RAX protein was significantly lower in the brains of rep mice. The mutant protein, while normal in most biochemical functions, was unable to bind dsRNA. In addition, rep mice displayed altered morphology of the skull that was consistent with a targeted deletion of Prkra showing a contribution of the gene to craniofacial development. These observations identified a specific mutation that reduces steady-state levels of RAX protein and disrupts the dsRNA binding function of the protein, demonstrating the importance of the Prkra gene in various aspects of mouse development.     

Congenital hypothyroidism, dwarfism, and hearing impairment caused by a missense mutation in the mouse dual oxidase 2 gene, Duox2

Dual oxidases generate the hydrogen peroxide needed by thyroid peroxidase for the incorporation of iodine into thyroglobulin, an essential step in thyroid hormone synthesis. Mutations in the human dual oxidase 2 gene, DUOX2, have been shown to underlie several cases of congenital hypothyroidism. We report here the first mouse Duox2 mutation, which provides a new genetic model for studying the specific function of DUOX2 in the thyroid gland and in other organ systems where it is hypothesized to play a role. We mapped the new spontaneous mouse mutation to chromosome 2 and identified it as a T>G base pair change in exon 16 of Duox2. The mutation changes a highly conserved valine to glycine at amino acid position 674 (V674G) and was named "thyroid dyshormonogenesis" (symbol thyd) to signify a defect in thyroid hormone synthesis. Thyroid glands of mutant mice are goitrous and contain few normal follicles, and anterior pituitaries are dysplastic. Serum T(4) in homozygotes is about one-tenth the level of controls and is accompanied by a more than 100-fold increase in TSH. The weight of adult mutant mice is approximately half that of littermate controls, and serum IGF-I is reduced. The cochleae of mutant mice exhibit abnormalities characteristic of hypothyroidism, including a delayed formation of the inner sulcus and tunnel of Corti and an abnormally thickened tectorial membrane. Hearing thresholds of adult mutant mice are on average 50-60 decibels (dB) above those of controls.     

Chromosome mapping of the growth hormone receptor gene in man and mouse

Pituitary growth hormone (GH) is essential for normal growth and development in animals and GH deficiency leads to dwarfism. This hormone acts via specific high-affinity cell surface receptors found in liver and other tissues. The recent cloning and sequencing of cDNAs encoding human and rabbit GH receptors (GHR) has demonstrated that this receptor is unrelated to any previously described cell membrane receptor or growth factor receptor. We have used the cloned human GHR cDNA to map the GHR locus to the proximal short arm of human chromosome 5, region p13.1----p12, and to mouse chromosome 15 by Southern blot analysis and in situ hybridization. While human chromosome 5 carries several genes for hormone and growth factor receptors, GHR is the only growth-related gene so far mapped to the short arm. Inasmuch as GHR is the first gene with apparently homologous loci on human chromosome 5 and mouse chromosome 15, it identifies a new homologous conserved region. In humans, deficiency of GH receptor activity probably causes Laron-type dwarfism, an autosomal recessive disorder prevalent in Oriental Jews. In mice, the autosomal recessive mutation miniature (mn) is characterized by severe growth failure and early death and has been mapped to chromosome 15. Our assignment of Ghr to mouse chromosome 15 suggests this as a candidate gene for the mn mutation.     

Early transposable element insertion in intron 9 of the Hsf4 gene results in autosomal recessive cataracts in lop11 and ldis1 mice

Lens opacity 11 (lop11) is an autosomal recessive mouse cataract mutation that arose spontaneously in the RIIIS/J strain. At 3 weeks of age mice exhibit total cataracts with vacuoles. The lop11 locus was mapped to mouse chromosome 8. Analysis of the mouse genome for the lop11 critical region identified Hsf4 as a candidate gene. Molecular evaluation of Hsf4 revealed an early transposable element (ETn) in intron 9 inserted 61 bp upstream of the intron/exon junction. The same mutation was also identified in a previously mapped cataract mutant, ldis1. The ETn insertion altered splicing and expression of the Hsf4 gene, resulting in the truncated Hsf4 protein. In humans, mutations in HSF4 have been associated with both autosomal dominant and recessive cataracts. The lop11 mouse is an excellent resource for evaluating the role of Hsf4 in transparency of the lens.     

A loss-of-function mutation in natriuretic peptide receptor 2 (Npr2) gene is responsible for disproportionate dwarfism in cn/cn mouse

The achondroplastic mouse is a spontaneous mutant characterized by disproportionate dwarfism with short limbs and tail due to disturbed chondrogenesis during endochondral ossification. These abnormal phenotypes are controlled by an autosomal recessive gene (cn). In this study, linkage analysis using 115 affected mice of F2 progeny mapped the cn locus on an approximately 0.8-cM region of chromosome 4, and natriuretic peptide receptor 2 (Npr2) gene was identified as the most potent candidate for the cn mutant in this region. This gene encodes a receptor for C-type natriuretic peptide (CNP) that positively regulates longitudinal bone growth by producing cGMP in response to CNP binding to the extracellular domain. Sequence analyses of the Npr2 gene in cn/cn mice revealed a T to G transversion leading to the amino acid substitution of highly conserved Leu with Arg in the guanylyl cyclase domain. In cultured chondrocytes of cn/cn mice, stimulus with CNP did not significantly increase intracellular cGMP concentration, whereas it increased in +/+ mice. Transfection of the mutant Npr2 gene into COS-7 cells also showed similar results, indicating that the missense mutation of the Npr2 gene in cn/cn mice resulted in disruption of the guanylyl cyclase activity of the receptor. We therefore concluded that the dwarf phenotype of cn/cn mouse is caused by a loss-of-function mutation of the Npr2 gene, and cn/cn mouse will be a useful model to further study the molecular mechanism regulating endochondral ossification by CNP/natriuretic peptide receptor B signal.     

Mea2/Golga3 gene is disrupted in a line of transgenic mice with a reciprocal translocation between Chromosomes 5 and 19 and is responsible for a defective spermatogenesis in homozygotes

A line of transgenic mouse T604 transmitted a transgene to progeny together with a set of chromosomes with a reciprocal translocation. The transgene was integrated at a single site in the translocated chromosomes, as revealed by fluorescence in situ hybridization. The transgenic hemizygous males, also heterozygous for the translocation of chromosomes, showed apparently normal spermatogenesis, while the males homozygous for the transgene as well as for the translocated chromosomes showed a defect in spermatogenesis. Considering that the genetic rearrangement by either insertion of the transgene or the chromosome translocation in the T604 mouse line might have caused a recessive mutation in a gene indispensable for spermatogenesis, we have mapped the transgene integration site and the translocation breakpoints in mouse chromosomes. Linkage analysis with SSLP markers showed that the loci for the transgene and the translocation breakpoints were closely located to D5Mit24 on Chromosome (Chr) 5, and to a region between D19Mit19 and D19Jpk2 on Chr 19. Mea2 gene, mapped only 2 cM from D5Mit24 and known to show male-specific enhanced expression in the testis, was analyzed as a candidate for the gene disrupted in T604 transgenic mice. Southern blot analysis revealed that Mea2 gene was indeed disrupted in T604 mice, and Northern blot analysis of the testis RNA showed that the expression of Mea2 was annihilated in the testis of T604 transgenic homozygotes. Received: 8 July 1998 / Accepted: 23 September 1998     

Impaired retinol utilization in Adh4 alcohol dehydrogenase mutant mice

Adh4, a member of the mouse alcohol dehydrogenase (ADH) gene family, encodes an enzyme that functions in vitro as a retinol dehydrogenase in the conversion of retinol to retinoic acid, an important developmental signaling molecule. To explore the role of Adh4 in retinoid signaling in vivo, gene targeting was used to create a null mutation at the Adh4 locus. Homozygous Adh4 mutant mice were viable and fertile and demonstrated no obvious defects when maintained on a standard mouse diet. However, when subjected to vitamin A deficiency during gestation, Adh4 mutant mice demonstrated a higher number of stillbirths than did wild‐type mice. The proportion of liveborn second generation vitamin A‐deficient newborn mice was only 15% for Adh4 mutant mice but 49% for wild‐type mice. After retinol administration to vitamin A‐deficient dams in order to rescue embryonic development, Adh4 mutant mice demonstrated a higher resorption rate at stage E12.5 (69%), compared with wild‐type mice (30%). The relative ability of Adh4 mutant and wild‐type mice to metabolize retinol to retinoic acid was measured after administration of a 100‐mg/kg dose of retinol. Whereas kidney retinoic acid levels were below the level of detection in all vehicle‐treated mice (<1 pmol/g), retinol treatment resulted in very high kidney retinoic acid levels in wild‐type mice (273 pmol/g) but 8‐fold lower levels in Adh4 mutant mice (32 pmol/g), indicating a defect in metabolism of retinol to retinoic acid. These findings demonstrate that another retinol dehydrogenase can compensate for a lack of Adh4 when vitamin A is sufficient, but that Adh4 helps optimize retinol utilization under conditions of both retinol deficiency and excess. Dev. Genet. 25:1–10, 1999. © 1999 Wiley‐Liss, Inc.     

A mouse model of Waardenburg syndrome type IV resulting from an ENU‐induced mutation in endothelin 3

A line of mutant mice (114‐CH19) exhibiting white spotting and preweaning lethality was identified during an N‐ethyl‐N‐nitrosourea (ENU) mutagenesis screen. The trait segregated as a semidominant bellyspot with reduced penetrance. Homozygous mutant mice showed preweaning lethality, and exhibited white spotting over the majority of the body surface, with pigmented patches remaining around the pinnae, eyes and tail. Linkage analysis localized 114‐CH19 on mouse chromosome 2, suggesting endothelin 3 (Edn3) as a candidate gene. Sequence analysis of Edn3 identified a G > A transversion that encodes an arginine to histidine substitution (R96H). This mutation is predicted to disrupt furin‐mediated proteolytic cleavage of pro‐endothelin that is necessary to form biologically active EDN3. This mutation is novel among human and mouse EDN3 mutants, is the first reported EDN3 ENU mutant, and is the second reported EDN3 point mutation. This study demonstrates the power of using ENU mutagenesis screens to generate new animal models of human disease, and expands the spectrum of EDN3 mutant alleles.     

Muscle expression of human retinol-binding protein (RBP). Suppression of the visual defect of RBP knockout mice

Mice lacking retinol-binding protein (RBP) have low circulating retinol levels. They have severe visual defects due to a low content of retinol or retinyl esters in the eye. A transgenic mouse strain that expresses human RBP under the control of the muscle creatine kinase promoter in the null background was generated. The exogenous protein bound retinol and transthyretin in the circulation and effectively delivered retinol to the eye. Thus, RBP expressed from an ectopic source suppresses the visual phenotype, and retinoids accumulate in the eye. No human RBP was found in the retinal pigment epithelium of the transgenic mice, indicating that retinol uptake by the eye does not entail endocytosis of the carrier RBP.     

Retinoids and retinoid-metabolic gene expression in mouse adipose tissues

Vitamin A and its analogs (retinoids) regulate adipocyte differentiation. Recent investigations have demonstrated a relationship among retinoids, retinoid-binding-protein 4 (RBP4) synthesized in adipose tissues, and insulin-resistance status. In this study, we measured retinoid levels and analyzed the expression of retinoid homeostatic genes associated with retinol uptake, esterification, oxidation, and catabolism in subcutaneous (Sc) and visceral (Vis) mouse fat tissues. Both Sc and Vis depots were found to contain similar levels of all-trans retinol. A metabolite of retinol with characteristic ultraviolet absorption maxima for 9-cis retinol was observed in these 2 adipose depots, and its level was 2-fold higher in Sc than in Vis tissues. Vis adipose tissue expressed significantly higher levels of RBP4, CRBP1 (intracellular retinol-binding protein 1), RDH10 (retinol dehydrogenase), as well as CYP26A1 and B1 (retinoic acid (RA) hydroxylases). No differences in STRA6 (RBP4 receptor), LRAT (retinol esterification), CRABP1 and 2 (intracellular RA-binding proteins), and RALDH1 (retinal dehydrogenase) mRNA expressions were discerned in both fat depots. RALDH1 was identified as the only RALDH expressed in both Sc and Vis adipose tissues. These results indicate that Vis is more actively involved in retinoid metabolism than Sc adipose tissue.