Identification and genetic mapping of 151 dispersed members of 16 ribosomal protein multigene families in the mouse

Discovery genetics: serendipity in basic research

The role of serendipity in science has no better example than the discovery of spontaneous mutations that leads to new mouse models for research. The approach of finding phenotypes and then carrying out genetic analysis is called forward genetics. Serendipity is a key component of discovering and developing mice with spontaneous mutations into animal models of human disease. In this article, the role of serendipity in discovering and developing mouse models is described within a program at The Jackson Laboratory that capitalizes on serendipitous discoveries in large breeding colonies. Also described is how any scientists working with mice can take advantage of serendipitous discoveries as a research strategy to develop new models. Spontaneous mutations cannot be planned but happen in all research mouse colonies and are discovered as unexpected phenotypes. The alert scientist or technician can rationally exploit such chance observations to create new research opportunities.

Identification of unique transcripts from a mouse full-length, subtracted inner ear cDNA library

A small-scale full-length library construction approach was developed to facilitate production of a mouse full-length cDNA encyclopedia representing approximately 250 enriched, normalized, and/or subtracted cDNA libraries. One library produced using this approach was a subtracted adult mouse inner ear cDNA library (sIEa). The average size of the inserts was approximately 2.5 kb, with the majority ranging from 0.5 to 7.0 kb. From this library 22,574 sequence reads were obtained from 15,958 independent clones. Sequencing and chromosomal localization established 5240 clusters, with 1302 clusters being unique and 359 representing new ESTs. Our sIEa library contributed 56.1% of the 7773 nonredundant Unigene clusters associated with the four mouse inner ear libraries in the NCBI dbEST. Based on homologous chromosomal regions between human and mouse, we identified 1018 UniGene clusters associated with the deafness locus critical regions. Of these, 59 clusters were found only in our sIEa library and represented approximately 50% of the identified critical regions.

A genetic test to determine the origin of maternal transmission ratio distortion. Meiotic drive at the mouse Om locus

We have shown previously that the progeny of crosses between heterozygous females and C57BL/6 males show transmission ratio distortion at the Om locus on mouse chromosome 11. This result has been replicated in several independent experiments. Here we show that the distortion maps to a single locus on chromosome 11, closely linked to Om, and that gene conversion is not implicated in the origin of this phenomenon. To further investigate the origin of the transmission ratio distortion we generated a test using the well-known effect of recombination on maternal meiotic drive. The genetic test presented here discriminates between unequal segregation of alleles during meiosis and lethality, based on the analysis of genotype at both the distorted locus and the centromere of the same chromosome. We used this test to determine the cause of the transmission ratio distortion observed at the Om locus. Our results indicate that transmission ratio distortion at Om is due to unequal segregation of alleles to the polar body at the second meiotic division. Because the presence of segregation distortion at Om also depends on the genotype of the sire, our results confirm that the sperm can influence segregation of maternal chromosomes to the second polar body.

Sex-of-offspring-specific transmission ratio distortion on mouse chromosome X

During our study of the DDK syndrome, we observed sex ratio distortion in favor of males among the offspring of F(1) backcrosses between the C57BL/6 and DDK strains. We also observed significant and reproducible transmission ratio distortion in favor of the inheritance of DDK alleles at loci on chromosome X among female offspring but not among male offspring in (C57BL/6 x DDK)F(1) x C57BL/6 and (C57BL/6-Pgk1(a) x DDK)F(1) x C57BL/6 backcrosses. The observed transmission ratio distortion is maximum at DXMit210 in the central region of chromosome X and decreases progressively at proximal and distal loci, in a manner consistent with the predictions of a single distorted locus model. DXMit210 is closely linked to two distortion-controlling loci (Dcsx1 and Dcsx2) described previously in interspecific backcrosses. Our analysis suggests that the female-offspring-specific transmission ratio distortion we observe is likely to be the result of the death of embryos of particular genotypic combinations. In addition, we confirm the previous suggestion that the transmission ratio distortion observed on chromosome X in interspecific backcrosses is also the result of loss of embryos.

The original shaker-with-syndactylism mutation (sy) is a contiguous gene deletion syndrome

Tests for allelism among mice with four different mutant alleles at the shaker-with-syndactylism locus on mouse Chromosome (Chr) 18 provide evidence that the original radiation-induced mutation, sy, is a deletion including at least two genes associated with distinct phenotypes. Mice homozygous for sy have syndactylous feet and other skeletal malformations, are deaf, and exhibit abnormal behavior characteristic of vestibular dysfunction. Two less severe spontaneous mutations, shown to be allelic with sy, cause syndactylism when homozygous (hence named fused phalanges, sy(fp) and sy(fp-2J)), but do not affect hearing and behavior. Here we describe a third spontaneous mutation allelic with sy that does not affect foot morphology (hence named no syndactylism, sy(ns)), but that does cause deafness and balance defects when homozygous. Complementation test results indicate that sy(fp) and sy(fp-2J) are alleles of the same gene, but that sy(ns) is an allele of a different gene. The original sy mutation, therefore, includes both of the genes defined by these three spontaneous mutations. Typing of DNA markers in sy/sy mice revealed a deletion of approximately 1 cM in the sy region of Chr 18, including D18Mit52, D18Mit124, D18Mit181, and D18Mit205. The genetic relationships described here will aid in positional cloning efforts to identify the genes responsible for the disparate phenotypes associated with the sy locus.

Characterization of the mouse Prox1 gene

Prox1, a vertebrate homologue of Drosophila prospero, encodes a divergent homeodomain protein. We have isolated and characterized full length mouse Prox1 cDNA and genomic clones. Mouse Prox1 gene mapped to position 106.3 cM from the centromere of Chromosome 1, which is very close to the retinal degeneration mutation, rd3. Although the coding sequence and exon-intron junctions of the Prox1 genes of wild type and rd3 mutant mice are identical, Northern blot analysis indicated that the ratio of the short (2.3 kb) and long (8 kb) forms of Prox1 mRNA is different in RNA isolated from wild type and rd3 retinas. Immunostaining of the eyes from wild type and rd3 animals also revealed differences in the distribution of Prox1 protein in the retina and lens. These data suggest that the rd3 mutation affects expression of the mouse Prox1 gene.

Neuronal ceroid lipofuscinosis (nclf), a new disorder of the mouse linked to chromosome 9

The neuronal ceroid lipofuscinoses (NCLs) comprise a set of at least 6 distinct human and an unknown number of animal diseases characterized by storage of proteolipids in lysosomes of many cell types. By unknown mechanisms, this accumulation leads to or is associated with severe neuronal and retinal degeneration. The genes for 3 human NCLs, infantile, late infantile, and juvenile, have been cloned. The first murine form of NCL, the motor neuron degeneration (mnd) mouse, has been described and mapped to proximal Chromosome 8. Here we describe a second genetic variant of NCL in the mouse, neuronal ceroid lipofuscinosis, nclf. These mice exhibited a phenotype that was almost exactly the same as that observed in mnd/mnd mice. Homozygous nclf mice developed progressive retinal atrophy early in life and become paralyzed at around 9 months of age. They accumulated luxol fast blue staining material in cytoplasm of neurons and many other cell types. Ultrastructurally, affected lysosomes had a "finger print pattern" with membranous material arranged in "pentalaminar" patterns. Affected mice developed severe cerebral gliosis in late stages of their disease. They also had severe Wallerian degeneration of long tracts in spinal cord and brain stem, lesions that accounted for the distinctive upper motor neuron signs displayed by both nclf/nclf and mnd/mnd mice. By crossing nclf/nclf mice with CAST/Ei mice, linkage analysis of nclf with respect to SSLP markers was performed, showing that nclf is located on Chromosome 9 between D9Mit164 and D9Mit165, in a region that is homologous with human Ch 15q21, where the gene for one variant of late infantile NCL, CLN6, recently has been mapped. The genes for two proteolipids known to be stored in lysosomes of animals and people with NCL were also mapped in this study and found not to map to the mnd or nclf loci nor to any mouse locus homologous to any known human NCL disease locus.

Characterization of the mouse Myoc/Tigr gene

Mutations in the myocilin (MYOC), also known as Trabecular meshwork-Inducible Glucocorticoid Response (TIGR) gene can lead to juvenile open-angle glaucoma in human and may be responsible for at least 3% of primary open-angle glaucoma. To develop a mouse model of primary open angle glaucoma, and to get deeper insight into the mechanisms of the MYOC/TIGR gene regulation and function, we have isolated and characterized full size mouse Myoc/Tigr cDNA and genomic clones. The mouse and human MYOC/TIGR genes have the same exon-intron structure and contain 3 exons, although the mouse gene is 6 kb shorter than the human gene (10 kb versus 16 kb) due to differences in the length of introns. The MYOC/TIGR gene encodes a moderately conserved protein, which is 82% identical between human and mouse. The encoded protein is 14 amino acids shorter at the N-terminus in the mouse than in the human (490 versus 504 amino acids). Mouse and human MYOC/TIGR genes show a similar pattern of expression in adult ocular and nonocular tissues. The mouse Myoc/Tigr gene was mapped to Chromosome 1 at position 82.8 cM from the centromere. All residues, which were identified in the human MYOC/TIGR protein as critical for glaucoma development, are conserved in the mouse Myoc/Tigr.

Mapping and characterization of a novel cochlear gene in human and in mouse: a positional candidate gene for a deafness disorder, DFNA9

Previously we identified a partial human cDNA for a novel cochlear transcript, hCoch-5B2 (HGMW-approved symbol D14S564E), using subtractive hybridization techniques. Herein we report isolation and characterization of both human and mouse (D12H14S564E) cDNAs for Coch-5B2. Full-length Coch5B2 deduced amino acid sequences reveal a very high degree of conservation in the coding region (89% nucleotide and 94% amino acid identity and a potential signal peptide and two regions of extensive homology to the collagen-binding type A domains of von Willebrand factor, also present in other secreted proteins, including extracellular matrix components. High levels of hCoch-5B2 expression are seen only in human fetal inner ear structures, cochlea, and vestibule, among a large panel of human fetal and adult tissues. Coch-5B2 expression in the mouse is more widespread than in the human, with message detected in mouse adult spleen, cerebrum, cerebellum/medulla, and thymus. In both species very low level expression is detected in total eye. More specifically, mouse retina shows a higher level of mCoch-5B2 message than sclera and choroid. We have mapped hCoch-5B2 to human 14q11.2-q13 by somatic cell hybrid analysis and FISH and, more precisely, using radiation hybrids to a region of markers linked to DFNA9, a nonsyndromic autosomal dominant sensorineural hearing loss with vestibular defects. Furthermore, we detect hCoch-5B2 on three overlapping YACs, two of which also contain one of the markers linked to DFNA9. mCoch-5B2 was genetically mapped in the mouse to chromosome 12, in a region of homologous synteny with human 14q11.2-q13, which contains the asp1 (audiogenic seizure prone) locus in the mouse.

A major gene affecting age-related hearing loss in C57BL/6J mice

A major gene responsible for age-related hearing loss (AHL) in C57BL/6J mice was mapped by analyses of a (C57BL/6J x CAST/Ei) x C57BL/6J backcross. AHL, as measured by elevated auditory-evoked brainstem response (ABR) thresholds, segregated among backcross mice as expected for a recessive, primarily single-gene trait. Both qualitative and quantitative linkage analyses gave the same genetic map position for the AHL gene (Ahl on chromosome 10, near D10Mit5. Marker assisted selection was then used to produce congenic lines of C57BL/6J that contain different CAST-derived segments of chromosome 10. ABR test results and cochlear histopathology of aged progenitors of these congenic lines are presented. Ahl is the first gene causing late-onset, non-syndromic hearing loss that has been reported in the mouse.

TRANCE is a novel ligand of the tumor necrosis factor receptor family that activates c-Jun N-terminal kinase in T cells

A novel member of the tumor necrosis factor (TNF) cytokine family, designated TRANCE, was cloned during a search for apoptosis-regulatory genes using a somatic cell genetic approach in T cell hybridomas. The TRANCE gene encodes a type II membrane protein of 316 amino acids with a predicted molecular mass of 35 kDa. Its extracellular domain is most closely related to TRAIL, FasL, and TNF. TRANCE is an immediate early gene up-regulated by TCR stimulation and is controlled by calcineurin-regulated transcription factors. TRANCE is most highly expressed in thymus and lymph nodes but not in nonlymphoid tissues and is abundantly expressed in T cells but not in B cells. Cross-hybridization of the mouse cDNA to a human thymus library yielded the human homolog, which encodes a protein 83% identical to the mouse ectodomain. Human TRANCE was mapped to chromosome 13q14 while mouse TRANCE was located to the portion of mouse chromosome 14 syntenic with human chromosome 13q14. A recombinant soluble form of TRANCE composed of the entire ectodomain induced c-Jun N-terminal kinase (JNK) activation in T cells but not in splenic B cells or in bone marrow-derived dendritic cells. These results suggest a role for this TNF-related ligand in the regulation of the T cell-dependent immune response.

Cloning, characterization, and mapping of a murine promiscuous chemokine receptor gene: homolog of the human Duffy gene

We report here the isolation and genomic organization of the orthologous mouse Duffy gene, named Dfy. It is a single copy gene located in chromosome 1 in a region homologous to the human Duffy gene (FY). Sequence analyses indicate that Dfy consists of two exons: exon 1 of 55 nucleotides, which encodes 7 amino acid residues; and exon 2 of 1038 nucleotides, which encodes 327 residues. The single intron consists of 462 nucleotides. The 5'-end promoter region contains motifs involved in vertebrate development in addition to potential binding sites of factors for globin transcription. The open reading frame (ORF) shows 60% homology with the human Duffy protein. However, mouse erythrocytes are serologically Duffy-negative and mouse erythrocyte membrane proteins do not cross-react with two Duffy-specific rabbit polyclonal antibodies. The deduced protein predicts a M(r) of 36,692 and carries three potential N-glycosylation sites to asparagine residues. Hydropathy analysis predicts an exocellular amino-terminal domain of 57 residues, seven transmembrane alpha-helices, and an endocellular carboxy-terminal domain of 29 residues. In bone marrow and spleen, Dfy expresses a major 1.4-kb and a minor 1.8-kb mRNA. Contrary to humans, Dfy is expressed in liver, synthesizing a 1.4-kb mRNA, and is repressed in kidney. Dfy is highly expressed in mouse brain and produces a major 8.5-kb and a minor 10.2-kb mRNA. The human erythroleukemia K562 cells, transfected with cDNA encoding the mouse Duffy-like protein and mouse erythrocytes, have the same chemokine binding profiles indicating that they contain the same protein.

Maid: a maternally transcribed novel gene encoding a potential negative regulator of bHLH proteins in the mouse egg and zygote

We isolated an abundant novel cDNA SSEC-8 from a subtraction cDNA library enriched for maternal transcripts that are still present in the mouse 2 cell stage embryo. This gene is evolutionarily conserved and maps to the distal region of mouse chromosome 2. The deduced polypeptide sequence of the encoded protein contains a conserved helix-loop-helix (HLH) motif without a basic DNA binding domain, suggesting that it functions as a negative regulator of basic (b) HLH transcription factors. Gel mobility shift assays show that in vitro translated protein prevents the E12/MyoD bHLH dimer from binding to DNA. Also, transient overexpression of this protein in C2C12 cells reduced the transcription of a CAT-reporter regulated by an E12/MyoD driven enhancer. The 3'-UTR contains consensus sequences of cytoplasmic polyadenylation elements (CPE's), and the length of its poly (A) tail changes during oocyte maturation, indicating that its expression is controlled by timely activation of translation. This new gene, Maid, models the translational and transcriptional regulation of gene expression during the transition from gamete to embryo.

Gene homologs on human chromosome 15q21-q26 and a chicken microchromosome identify a new conserved segment

The genes for insulin-like growth factor 1 receptor (IGF1R), aggrecan (AGC1), beta2-microglobulin (B2M), and an H6-related gene have been mapped to a single chicken microchromosome by genetic linkage analysis. In addition, a second H6-related gene was mapped to chicken macrochromosome 3. The Igf1r and Agc1 loci are syntenic on mouse Chr 7, together with Hmx3, an H6-like locus. This suggests that the H6-related locus, which maps to the chicken microchromosome in this study, is the homolog of mouse Hmx3. The IGF1R, AGC1, and B2M loci are located on human Chr 15, probably in the same order as found for this chicken microchromosome. This conserved segment, however, is not entirely conserved in the mouse and is split between Chr 7 (Igf1r-Agc) and 2 (B2m). This comparison also predicts that the HMX3 locus may map to the short arm of human Chr 15. The conserved segment defined by the IGF1R-AGC1-HMX3-B2M loci is approximately 21-35 Mb in length and probably covers the entire chicken microchromosome. These results suggest that a segment of human Chr 15 has been conserved as a chicken microchromosome. The significance of this result is discussed with reference to the evolution of the avian and mammalian genomes.

Megencephaly: a new mouse mutation on chromosome 6 that causes hypertrophy of the brain

Megencephaly, enlarged brain, occurs in several acquired and inherited human diseases including Sotos syndrome, Robinow syndrome, Canavan's disease, and Alexander disease. This defect can be distinguished from macrocephaly, an enlarged head, which usually occurs as a consequence of congenital hydrocephalus. The pathology of megencephaly in humans has not been well defined, nor has the defect been reported to occur spontaneously in any other species. In this report we describe a recessive mutation in the mouse that results in a 25% increase in brain size in the first 8 months of life. We have determined that the megencephaly is characterized by overall hypertrophy of the brain, and not by hyperplasia of particular cell types or by hypertrophy of a singular tissue compartment. Edema and hydrocephalus are absent. This mutation has been mapped to mid-distal mouse Chromosome (Chr) 6 in a region homologous with human Chr 12.

Somatic genetic events linked to the Apc locus in intestinal adenomas of the Min mouse

We have found previously that all spontaneous intestinal adenomas from Apc+/ApcMin mice lose the wild type Apc marker on two genetic backgrounds. On the (AKR x B6)F1 background, this event involves loss of the entire homolog of mouse chromosome 18 carrying Apc+. This chromosome carries both the Mcc and Dcc genes, which are homologs of genes that have been implicated in human colorectal cancer. To determine whether the loss of alleles of Mcc and/or Dcc is necessary for the formation of intestinal adenomas, subchromosomal somatic events were induced by gamma-irradiation. The observed spectrum of intrachromosomal somatic genetic losses rules out a requirement for loss of heterozygosity at either locus during adenoma formation. Subchromosomal allelic losses linked to Apc+ occur spontaneously on other genetic backgrounds. In the majority of these events, the Apc+ allele itself was somatically lost, as judged by the wild type marker at the Min site. However, on the [M. musculus castaneous (CAST) x B6-Min]F1 and (129/Sv x B6-Min)F1 backgrounds, spontaneous adenomas were observed in which the wild type marker at the Min site was retained. Further analysis will be required to determine whether these exceptions involve intra-Apc mutations. If not, then these events would illustrate routes to intestinal neoplasia that do not require complete inactivation of wild type Apc function.

A new mouse mutation causing male sterility and histoincompatibility

Male sterility and histoincompatibility, mshi, is an autosomal recessive mutation in BALB/cBy mice that causes reduced testis size and sterility in homozygous males. The testes of homozygous mutants are highly disorganized and appear to have a block in the regulation of male germ cell proliferation. No heterozygous effect is detectable. Reproduction is unaffected in females carrying the mutation. The mutation also affects histocompatibility; most homozygous males and females reject sex-matched skin grafts from BALB/cBy mice. We used an intercross between BALB/cBy and CAST/Ei to map the mshi mutation to the proximal end of Chromosome (Chr) 10. The most likely gene order places the mutation between D10Mit80 and D10Mit16, near the interferon gamma receptor locus, Ifgr, which may be a candidate gene for this mutation.

Strain distribution pattern for SSLP markers in the SWXJ recombinant inbred strain set: chromosomes 7 to X

The SWXJ recombinant inbred (RI) set was developed for genetic analysis of heritable ovarian tumors. In this report we present data for 223 simple sequence length polymorphisms spanning Chromosomes (Chrs) 7-X to complete the genetic marking of this RI set. The strain distribution patterns (SDP) for these loci were combined with data from 19 other polymorphic genes, resulting in densely marked maps for Chrs 7-X. Combined with the 165 loci for Chr 1-6 reported previously (Svenson et al., Mamm. Genome 6, 867, 1995), the SWXJ RI set represents a powerful tool for mapping genes in neoplastic as well as other heritable disorders.

Location of the 9257 and ataxia mutations on mouse chromosome 18

The location of three mutations on proximal Chromosome (Chr) 18 was determined by analysis of the offspring of several backcrosses. The results demonstrate that ataxia and the insertional mutation TgN9257Mm are separated by less than 1 cM and are located approximately 3 cM from the centromere, while the balding locus is 7 cM more distal. Previous data demonstrated that the twirler locus also maps within 1 cM of ataxia. The corrected locations will contribute to identification of appropriate candidate genes for these mutations. Two polymorphic microsatellite markers for proximal Chr 18 are described, D18Umi1 and D18Umi2. The Lama3 locus encoding the alpha 3 subunit of nicein was mapped distal to ataxia and did not recombine with Tg9257.

Structure and chromosomal location of the mouse medium-chain acyl-CoA dehydrogenase-encoding gene and its promoter

Medium-chain acyl-coenzyme A dehydrogenase (MCAD; mouse gene Acadm; human gene ACADM) catalyzes the initial step of fatty acid beta-oxidation in mitochondria. Inherited MCAD deficiency is an autosomal recessive disorder that occurs at high frequency in humans and is associated with considerable morbidity and mortality. We have cloned and characterized mouse Acadm which spans approximately 25 kb and contains 12 exons. The promoter region does not contain TATA or CAAT boxes and is G + C-rich (60%) within 200 bp of the cap site. A CpG island extends from 5' of the transcription start point into intron 1. The 5' regulatory region and a portion of intron 1 contain several Sp1 consensus sites and three regions containing hexamer DNA sequences that match the binding consensus for steroid/thyroid nuclear receptors. These putative nuclear receptor response elements (NRRE) share DNA sequence homology and electrophoretic mobility shift characteristics with known NRRE in the human ACADM promoter [Carter et al., J. Biol. Chem. 268 (1993) 13805-13810]. We have mapped mouse Acadm to the distal end of chromosome 3. Sequences previously localized to chromosome 8 are shown to be a pseudogene, and an additional pseudogene was identified on chromosome 11.

Mapping of the Hmg1 gene and of seven related sequences in the mouse

The High Mobility Group 1 protein (HMG1) is an abundant and highly conserved chromosomal protein. Mouse HMG1 is encoded by the Hmg1 gene, containing four introns, but the murine genome contains many related sequences that are mostly retrotransposed pseudogenes. By using an interspecific cross, we have mapped the functional Hmg1 gene on mouse Chromosome (Chr) 5 and seven Hmg1-related sequences on Chrs 6, 8, 17, 18, and X.

Homologs of genes and anonymous loci on human chromosome 13 map to mouse chromosomes 8 and 14

To enhance the comparative map for human Chromosome (Chr) 13, we identified clones for human genes and anonymous loci that cross-hybridized with their mouse homologs and then used linkage crosses for mapping. Of the clones for four genes and twelve anonymous loci tested, cross-hybridization was found for six, COL4A1, COL4A2, D13S26, D13S35, F10, and PCCA. Strong evidence for homology was found for COL4A1, COL4A2, D13S26, D13S35, and F10, but only circumstantial homology evidence was obtained for PCCA. To genetically map these mouse homologs (Cf10, Col4a1, Col4a2, D14H13S26, D8H13S35, and Pcca-rs), we used interspecific and intersubspecific mapping panels. D14H13S26 and Pcca-rs were located on the distal portion of mouse Chr 14 extending by approximately 30 cM the conserved linkage between human Chr 13 and mouse Chr 14, assuming that Pcca-rs is the mouse homolog of PCCA. By contrast, Cf10, Col4a1, Col4a2, and D8H13S35 mapped near the centromere of mouse Chr 8, defining a new conserved linkage. Finally, we identified either a closely linked sequence related to Col4a2, or a recombination hot-spot between Col4a1 and Col4a2 that has been conserved in humans and mice.