Implementation of a large-scale ENU mutagenesis program: towards increasing the mouse mutant resource

Systematic approaches to mouse mutagenesis will be vital for future studies of gene function. We have begun a major ENU mutagenesis program incorporating a large genome-wide screen for dominant mutations. Progeny of ENU-mutagenized mice are screened for visible defects at birth and weaning, and at 5 weeks of age by using a systematic and semi-quantitative screening protocol—SHIRPA. Following this, mice are screened for abnormal locomotor activity and for deficits in prepulse inhibition of the acoustic startle response. Moreover, in the primary screen, blood is collected from mice and subjected to a comprehensive clinical biochemical analysis. Subsequently, secondary and tertiary screens of increasing complexity can be used on animals demonstrating deficits in the primary screen. Frozen sperm is archived from all the male mice passing through the screen. In addition, tail tips are stored for DNA. Overall, the program will provide an extensive new resource of mutant and phenotype data to the mouse and human genetics communities at large. The challenge now is to employ the expanding mouse mutant resource to improve the mutant map of the mouse. An improved mutant map of the mouse will be an important asset in exploiting the growing gene map of the mouse and assisting with the identification of genes underlying novel mutations—with consequent benefits for the analysis of gene function and the identification of novel pathways. Received: 16 December 1999 / Accepted: 16 December 1999     

A high-resolution radiation hybrid map of the proximal region of rat Chromosome 4

Radiation hybrid (RH) mapping has been used to produce genome maps in the human and mouse, but as yet the technique has been applied little to other species. We describe the use of RH mapping in the rat, using a newly available rat/hamster RH panel, to construct an RH map of the proximal part of rat Chromosome (Chr) 4. This region is of interest because quantitative trait loci (QTLs) for defective insulin and catecholamine action, hypertension, and dyslipidemia map to this region. The RH map includes 23 rat genes or microsatellites previously mapped to this part of Chr 4, one rat gene not previously mapped in the rat, and markers for four new genes, homologs of which map to the syntenic region of the mouse genome. The RH map integrates genetic markers previously mapped on several rat crosses, increases the resolution of existing maps, and may provide a suitable basis for physical map construction and gene identification in this chromosomal region. Our results demonstrate the utility of RH mapping in the rat genome and show that RH mapping can be used to localize, in the rat genome, the homologs of genes from other species such as the mouse. This will facilitate identification of candidate genes underlying QTLs on this chromosomal segment. Received: 4 December 1998 / Accepted: 19 January 1999     

Cryoconservation—archiving for the future

Mouse genetics is set to play a pivotal role in the key post-genome challenge—the study of mammalian gene function. Addressing this challenge will involve the development and application of systematic mutagenesis approaches. The expanding mouse mutant resource that will result threatens to overwhelm the currently available animal facility space. Cryopreservation of both mouse embryos and spermatozoa is currently widely employed for the efficient archiving of mouse stocks. Distribution and dissemination of new and existing mouse strains is simplified by the availability of extensive frozen archives. Also, the availability of archives of frozen spermatozoa provides a potential powerful route for the production of backcross progeny for rapid genetic mapping. Moreover, frozen oocytes and ovaries may offer a valuable addition to the current cryopreservation approaches. Comprehensive mouse mutant archives will provide an essential resource for mammalian genetics throughout the 21^st century. Received: 16 December 1999 / Accepted: 17 December 1999     

Mutagenesis strategies for identifying novel loci associated with disease phenotypes

The systematic identification of the function of all the genes in the mammalian genome is one of the major scientific challenges for the 21st century. A comprehensive insight into mammalian gene function will illuminate our understanding of the genetic bases of disease. Mouse mutagenesis is a powerful tool for the study of mammalian gene function. Most recently, a number of approaches employing the chemical mutagen ethylnitrosourea (ENU) have been utilised by mouse geneticists to deliver a substantial new collection of mouse disease models. The growing mouse mutant archive provides a powerful resource for the identification of novel genes involved with human genetic disease.     

A human genome map of comparative anchor tagged sequences.

Effective comparative mapping inference utilizing developing gene maps of animal species requires the inclusion of anchored reference loci that are homologous to genes mapped in the more "gene-dense" mouse and human maps. Nominated anchor loci, termed comparative anchor tagged sequences (CATS), have been ordered in the mouse linkage map, but due to the dearth of common polymorphisms among human coding genes have not been well represented in human linkage maps. We present here an ordered framework map of 314 comparative anchor markers in humans based on mapping analysis in the Genebridge 4 panel of radiation hybrid cell lines, plus empirically optimized CATS PCR primers which detect these markers. The ordering of these homologous gene markers in human and mouse maps provides a framework for comparative gene mapping of representative mammalian species.     

Mouse models of human single gene disorders. I: Nontransgenic mice.

Mouse models of human genetic disorders provide a valuable resource for investigating the pathogenesis of genetic disease and for testing potential therapies. The high degree of resolution of linkage mapping in the mouse allows mutant phenotypes to be mapped precisely which, combined with the accurate definition of areas of homology between the mouse and human genomes, greatly facilitates the identification of mouse models. We describe here mouse models of human single gene disorders dividing them into three categories depending on the information available; phenotypic similarities, comparative mapping and identification of the underlying genetic lesion.     

Physical and transcriptional map of a 3-Mb region of mouse chromosome 1 containing the gene for the neural tube defect mutant loop-tail (Lp)

The Lp mouse mutant provides a model for the severe human neural tube defect (NTD), cranio-rachischisis. To identify the Lp gene, a positional cloning approach has been adopted. Previously, linkage analysis in a large intraspecific backcross was used to map the Lp locus to distal mouse chromosome 1. Here we report a detailed physical map of this region. The interval surrounding Lp has been cloned in a yeast artificial chromosome (YAC) contig consisting of 63 clones spanning approximately 3.2 Mb. Fifty sequence tagged sites (STSs) have been used to construct the contig and establish marker order across the interval. Based on the high level of conserved synteny between distal mouse chromosome 1 and human 1q21-q24, many of these STSs were designed from expressed sequences identified by cross-screening human and mouse databases of expressed sequence tags. Added to other known genes in the region, a total of 29 genes were located and ordered within the contig. Seven novel polymorphisms were identified within the region, allowing refinement of the genetic map and a reduction in the size of the physical interval containing the Lp gene. The Lp interval, between D1Mit113 and Tagln2, can be spanned by two nonchimeric overlapping YACs that define a physical distance of approximately 1 Mb. Within this region, 10 potential candidate genes have been mapped. The materials and genes described here will provide a resource for the identification and further study of the mutated Lp gene that causes this severe neural tube defect and will provide candidates for other defects known to map to the homologous region on human chromosome 1q.     

Location of mouse and human genes corresponding to conserved canine olfactory receptor gene subfamilies

Olfactory receptors are G protein-coupled, seven-transmembrane-domain proteins that are responsible for binding odorants in the nasal epithelium. They are encoded by a large gene family, members of which are organized in several clusters scattered throughout the genomes of mammalian species. Here we describe the mapping of mouse sequences corresponding to four conserved olfactory receptor genes, each representing separate, recently identified canine gene subfamilies. Three of the four canine genes detected related gene clusters in regions of mouse Chromosomes (Chrs) 2, 9, and 10, near previously mapped mouse olfactory genes, while one detected a formerly unidentified gene cluster located on mouse Chr 6. In addition, we have localized two human gene clusters with homology to the canine gene, CfOLF4, within the established physical map of Chr 19p. Combined with recently published studies, these data link the four conserved olfactory gene subfamilies to homologous regions of the human, dog, and mouse genomes. Received: 10 September 1997 / Accepted: 29 December 1997     

Comparative mapping using somatic cell hybrids

Summary Comparative mapping, or ascertaining the gene linkage relationships between different species, is rapidly developing. This is possible because new techniques in chromosome identification and somatic cell hybridization, such as the generation of hybrids preferentially segregating chromosomes of any desired species including rodents, and the development of gene transfer techniques have yielded new information about the human and rodent gene maps. In addition, the discovery and characterization of mouse subspecies has generated new mouse sexual genetic linkage data. The following picture is emerging. Several X-linked genes in man are X-linked in all mammalian species tested. The linkage relationships of several tightly linked genes, less than 1 map unit apart, are also conserved in all mammalian species tested. Ape autosomal genes are assigned to ape chromosomes homologous to their human counterparts indicating extensive conservation in the 12 million years (MYR) of evolution from apes to man. Similarly, mouse and rat, 10 MYR apart in evolution, have several large autosomal synteny groups conserved. In comparing the mouse and human gene maps we find that human genes assigned to different arms of the same human chromosome are unlinked in the mouse; mouse genes large map distances (20 to 45 cM) apart are very likely to be unlinked in the human. However, several autosomal synteny groups 10 to 20 cM apart, including thePgd, Eno-1, Pgm-1 group on human chromosome arm lp, are conserved in mice and man. This suggests that homology mapping, the superimposition of one species gene map on the homologous conserved portion of another species genome may be possible, and that ancestral autosomal synteny groups should be detectable. Presented in the formal symposium on Somatic Cell Genetics at the 27th Annual Meeting of the Tissue Culture Association, Philadelphia, Pennsylvania, June 7–10, 1976.     

Mouse-based phenogenomics for modelling human disease

The powerful and wide-ranging genetic tools available in the laboratory mouse make it the major experimental model for studying mammalian gene function in vivo and modelling human disease traits. Large-scale random mutagenesis approaches, either gene-driven or phenotype-driven, promise to identify new clinically relevant phenotypes and their associated genes. Development of appropriate tools for assessing clinical phenotypes in mice is a crucial component of these endeavours, as is the establishment of the infrastructure for archiving and distribution of the growing mutant resource to the community. Integrated, multidisciplinary programs will be needed to fully exploit the power of the mouse in molecular medicine.     

Comparative genetic analysis: the utility of mouse genetic systems for studying human monogenic disease

One of the long-term goals of mutagenesis programs in the mouse has been to generate mutant lines to facilitate the functional study of every mammalian gene. With a combination of complementary genetic approaches and advances in technology, this aim is slowly becoming a reality. One of the most important features of this strategy is the ability to identify and compare a number of mutations in the same gene, an allelic series. With the advent of gene-driven screening of mutant archives, the search for a specific series of interest is now a practical option. This review focuses on the analysis of multiple mutations from chemical mutagenesis projects in a wide variety of genes and the valuable functional information that has been obtained from these studies. Although gene knockouts and transgenics will continue to be an important resource to ascertain gene function, with a significant proportion of human diseases caused by point mutations, identifying an allelic series is becoming an equally efficient route to generating clinically relevant and functionally important mouse models.     

Characterization and radiation hybrid mapping of expressed sequence tags from the canine brain

Abstract Maps of the canine genome are now developing rapidly. Most of the markers on the current integrated canine radiation hybrid/genetic linkage/cytogenetic map are highly polymorphic microsatellite (type II) markers that are very useful for mapping disease loci. However, there is still an urgent need for the mapping of gene-based (type I) markers that are required for comparative mapping, as well as identifying candidate genes for disease loci that have been genetically mapped. We constructed an adult brain cDNA library as a resource to increase the number of gene-based markers on the canine genome map. Eighty-one percent of the 2700 sequenced expressed sequence tags (ESTs) represented unique sequences. The canine brain ESTs were compared with sequences in public databases to identify putative canine orthologs of human genes. One hundred nine of the canine ESTs were mapped on the latest canine radiation hybrid (RH) panel to determine the location of the respective canine gene. The addition of these new gene-based markers revealed three conserved segments (CS) between human and canine genomes previously detected by fluorescence in situ hybridization (FISH), but not by RH mapping. In addition, five new CS between dog and human were identified that had not been detected previously by RH mapping or FISH. This work has increased the number of gene-based markers on the canine RH map by approximately 30% and indicates the benefit to be gained by increasing the gene content of the current canine comparative map.     

Comprehensive analysis of photoreceptor gene expression and the identification of candidate retinal disease genes.

To identify the full set of genes expressed by mammalian rods, we conducted serial analysis of gene expression (SAGE) by using libraries generated from mature and developing mouse retina. We identified 264 uncharacterized genes that were specific to or highly enriched in rods. Nearly half of all cloned human retinal disease genes are selectively expressed in rod photoreceptors. In silico mapping of the human orthologs of genes identified in our screen revealed that 86 map within intervals containing uncloned retinal disease genes, representing 37 different loci. We expect these data will allow identification of many disease genes, and that this approach may be useful for cloning genes involved in classes of disease where cell type-specific expression of disease genes is observed.     

Genetic Models in Applied Physiology. Functional genomics in the mouse: powerful techniques for unraveling the basis of human development and disease.

Now that near-complete DNA sequences of both the mouse and human genomes are available, the next major challenge will be to determine how each of these genes functions, both alone and in combination with other genes in the genome. The mouse has a long and rich history in biological research, and many consider it a model organism for the study of human development and disease. Over the past few years, exciting progress has been made in developing techniques for chromosome engineering, mutagenesis, mapping and maintenance of mutations, and identification of mutant genes in the mouse. In this mini-review, many of these powerful techniques will be presented along with their application to the study of development, physiology, and disease.     

Comparative mapping of human chromosome 10 to pig chromosomes 10 and 14

Identification of predictive markers in QTL regions that impact production traits in commercial populations of swine is dependent on construction of dense comparative maps with human and mouse genomes. Chromosomal painting in swine suggests that large genomic blocks are conserved between pig and human, while mapping of individual genes reveals that gene order can be quite divergent. High-resolution comparative maps in regions affecting traits of interest are necessary for selection of positional candidate genes to evaluate nucleotide variation causing phenotypic differences. The objective of this study was to construct an ordered comparative map of human chromosome 10 and pig chromosomes 10 and 14. As a large portion of both pig chromosomes are represented by HSA10, genes at regularly spaced intervals along this chromosome were targeted for placement in the porcine genome. A total of 29 genes from human chromosome 10 were mapped to porcine chromosomes 10 (SSC10) and 14 (SSC14) averaging about 5 Mb distance of human DNA per marker. Eighteen genes were assigned by linkage in the MARC mapping population, five genes were physically assigned with the IMpRH mapping panel and seven genes were assigned on both maps. Seventeen genes from human 10p mapped to SSC10, and 12 genes from human 10q mapped to SSC14. Comparative maps of mammalian species indicate that chromosomal segments are conserved across several species and represent syntenic blocks with distinct breakpoints. Development of comparative maps containing several species should reveal conserved syntenic blocks that will allow us to better define QTL regions in livestock.     

Chromosomal assignments for porcine genes encoding enzymes in hepatic metabolic pathways

Increasing the number of mapped genes will facilitate (1) the identification of potential candidate genes for a trait of interest within quantitative trait loci regions and (2) comparative mapping. The metabolic activities of the liver are essential for providing fuel to peripheral organs, for regulation of amino acid, carbohydrate and lipid metabolism and for homoeostasis of vitamins, minerals and electrolytes. We aimed to identify and map genes coding for enzymes active in the liver by somatic cell genetics in order to contribute to the improvement of the porcine gene map. We mapped 28 genes of hepatic metabolic pathways including six genes whose locations could be confirmed and 22 new assignments. Localization information in human was available for all but one gene. In total 24 genes were assigned to in the expected chromosomal regions on the basis of the currently available information on the comparative human and pig map while for four genes our results suggest a new correspondence or extended regions of conservation between porcine and human chromosomes.     

Use of comparative physical and sequence mapping to annotate mouse chromosome 16 and human chromosome 21

Distal mouse chromosome 16 (MMU16) shares conserved linkage with human chromosome 21 (HSA21), trisomy for which causes Down syndrome (DS). A 4.5-Mb physical map extending from Cbr1 to Tmprss2 on MMU16 provides a minimal tiling path of P1 artificial chromosomes (PACs) for comparative mapping and genomic sequencing. Thirty-four expressed sequences were positioned on the mouse map, including 19 that were not physically mapped previously. This region of the mouse:human comparative map shows a high degree of evolutionary conservation of gene order and content, which differs only by insertion of one gene (in mouse) and a small inversion involving two adjacent genes. "Low-pass" (2.2x) mouse sequence from a portion of the contig was ordered and oriented along 510 kb of finished HSA21 sequence. In combination with 68 kb of unique PAC end sequence, the comparison provided confirmation of genes predicted by comparative mapping, indicated gene predictions that are likely to be incorrect, and identified three candidate genes in mouse and human that were not observed in the initial HSA21 sequence annotation. This comparative map and sequence derived from it are powerful tools for identifying genes and regulatory regions, information that will in turn provide insights into the genetic mechanisms by which trisomy 21 results in DS.     

A gene map of the rat derived from linkage analysis and related regions in the mouse and human genomes

We report the localization by linkage analysis in the rat genome of 148 new markers derived from 128 distinct known gene sequences, ESTs, and anonymous sequences selected in GenBank database on the basis of the presence of a repeated element. The composite linkage map of the rat contributed by our group integrates mapping information on a total of 370 different known genes, ESTs, and anonymous mouse or human sequences, and provides a valuable tool for comparative genome analysis. 206 and 254 homologous loci were identified in the mouse and human genomes respectively. Our linkage map, which combines both anonymous markers and gene markers, should facilitate the advancement of genetic studies for a wide variety of rat models characterized for complete phenotypes. The comparative genome mapping should define genetic regions in human likely to be homologous to susceptibility loci identified in rat and provide useful information for the identification of new potential candidates for genetic disorders. Received: 2 January 1999 / Accepted: 7 March 1999     

Analysis of the unassembled part of the dog genome sequence: chromosomal localization of 115 genes inferred from multispecies comparative genomics

The identification of dog genes and their accurate localization to chromosomes remain a major challenge in the postgenomics era. The 132 annotated canine genes with human orthologs remaining in the unassembled part (chrUnknown) of the dog sequence assembly (CanFam1) are of limited use for candidate gene approaches or comparative mapping studies. We used a two-step comparative analysis to infer a canine chromosomal interval for localization of the chrUn genes. We first constructed a human-dog synteny map, using 14,456 gene-based comparative anchors. We then mapped the 132 chrUn genes onto the reference (human) synteny map and identified the corresponding, orthologous segment on the canine map, based on conserved gene order. Our results show that 110 chrUn genes could be localized to short intervals on 18 dog chromosomes, whereas 22 genes remained assigned to 2 possible intervals. We extended this comparative analysis to multiple species, using the chimpanzee, mouse, and rat genome sequences. This made it possible to narrow down the intervals concerned and to increase the number of canine chrUn genes with an inferred chromosome location to 115. This study demonstrates that dog chromosomal intervals for chrUn genes can be rapidly inferred, using a reference species, and indicates that comparative strategies based on larger numbers of species may be even more effective.