Verne M. Chapman

The proto-oncogene c-kit encoding a transmembrane tyrosine kinase receptor maps to the mouse W locus

Mice carrying mutations at the W locus located on chromosome 5 are characterized by severe macrocytic anaemia, lack of hair pigmentation and sterility1. Mutations at this locus appear to affect the proliferation and/or migration of cells during early embryogenesis and result in an intrinsic defect in the haematopoietic stem cell hierarchy1,2. An understanding of the molecular basis of the complex and pleiotropic phenotype in W mutant mice would thus provide insights into the important developmental processes of gametogenesis, melanogenesis and haematopoiesis. Here we show that the mouse mutant W19H has a deletion of the c-kit proto-oncogene. Interspecific backcross analysis demonstrates that the W locus is very tightly linked to c-kit and that the two loci cannot be segregated at this level of analysis, c-kit is the cellular homologue of the oncogene v-kit of the HZ4 feline sarcoma virus3 and encodes a transmembrane protein tyrosine kinase receptor that is structurally similar to the receptors for colony-stimulating factor-1 (CSF-1) and platelet derived growth factor4,5. The co-localization of c-kit with W provides a molecular entry into this important region of the mouse genome. In addition, these observations provide the first example of a germ-line mutation in a mammalian proto-oncogene and implicate the c-kit gene as a candidate for the W locus.

Preferential expression of the maternally derived X chromosome in the mouse yolk sac.

Abstract We have studied the expression of the maternally derived X chromosome (X m ) and the paternally derived X chromosome (X p ) in female mouse conceptuses on the fourteenth day of gestation. We used an X-linked electrophoretic variant for phosphoglycerate kinase (PGK-1) to estimate the relative proportions of the expression of X m and X p in the fetus and in the yolk sac. Our results support the cytological observations of Takagi and Sasaki (1976) and suggest that X m is preferentially expressed in the mouse yolk sac. Further analysis strongly suggests that the paternally derived Pgk-1 allele (and therefore probably the whole of X p ) is not expressed in the mouse yolk sac endoderm. We have demonstrated that this effect is not caused by a selection pressure exerted by the phenotype of the maternal reproductive tract against cells which express X p . We therefore, conclude that the parental origin of X m and X p marks them as different from one another. Possible causes for the failure of the expression of X p in the yolk sac endoderm and the tissue specificity of the effect are discussed.

Biochemical diversity and evolution in the genus Mus

Thirteen biochemical groups of wild mice from Europe, Asia, and Africa belonging to the genus Mus are analyzed at 22–42 protein loci. Phylogenetic trees are proposed and patterns of biochemical evolution are discussed, as well as the possible contribution of wild mice to the genetic diversity of laboratory stocks.

Identification of an imprinted U2af binding protein related sequence on mouse chromosome 11 using the RLGS method

A new imprinted gene has been discovered in mice using the technique of restriction landmark genomic scanning (RGLS) with methylation sensitive enzymes. Eight out of 3,100 strain–specific Notl and BssHII spots were identified as imprinted in reciprocal F1 hybrids. Subsequently, we isolated a genomic clone for one locus on proximal chromosome 11 near the Glns locus, an imprinted region in uniparental disomic mice, and its corresponding cDNA clone. Expression of this transcript from the paternal allele was established using RT–PCR of reciprocal F1–hybrid mice. The amino–acid sequence deduced from the cDNA showed significant homology to the U2 small nuclear ribonucleoprotein auxiliary factor 35 kDa subunit.

Location of the mouse complement factor H gene (cfh) by FISH analysis and replication R-banding

A technique for replication R- and G-banding of mouse lymphocyte chromosomes was developed, and the replication R-banding pattern was analyzed. Optimal banding patterns were obtained with thymidine- and BrdU-treatment of lymphocytes in the same cell cycle. This produced replication R-band patterns that were the complete reverse of the G-band patterns on all chromosomes. Replication R-banding methods can be used in conjunction with nonisotopic, fluorescence in situ hybridization (FISH) to localize cloned probes to specific chromosomal bands on mouse chromosomes. with these methods the mouse complement factor H gene (cfh) was localized to the terminal portion of the F region of Chromosome 1. Q-banding patterns were also obtained by the replication R-banding method and may be useful for rapid identification of each chromosome.

The Mouse Zic Gene Family HOMOLOGUES OF THE DROSOPHILA PAIR-RULE GENE odd-paired

The mouse Zic gene, which encodes a zinc finger protein, is expressed in the developing or matured central nervous system in a highly restricted manner. We identified two novel Zic-related genes (Zic2, Zic3) through genomic and cDNA cloning. Both genes are highly similar to Zic(1), especially in their zinc finger motif. A comparison of genomic organization among the three Zic genes showed that they share common exon-intron boundaries and belong to the same gene family. Zic1, Zic2, and Zic3 were determined to mouse chromosome 9, 14, and X using an interspecific backcross panel. Northern blotting and ribonuclease protection showed that Zic2 and Zic3 are expressed in a restricted manner in the cerebellum at the adult stage. However, the temporal profile of the mRNA expression in the developing cerebella differ in the three Zic genes. Furthermore, we found that the Drosophila pair-rule gene, odd-paired is highly homologous to the Zic gene family. The similarity was not only the zinc finger motif, but also the exon-intron boundary was the same as those of mouse Zic gene family. These findings suggest that the Zic gene family and Drosophila odd-paired are derived from a common ancestral gene.

Effects of ENU dosage on mouse strains.

Abstract. The germline supermutagen, N-ethyl-N-nitrosourea (ENU), has a variety of effects on mice. ENU is a toxin and carcinogen as well as a mutagen, and strains differ in their susceptibility to its effects. Therefore, it is necessary to determine an appropriate mutagenic, non-toxic dose of ENU for strains that are to be used in experiments. In order to provide some guidance, we have compiled data from a number of laboratories that have exposed male mice from inbred and non-inbred strains or their F1 hybrids to ENU. The results show that most F1 hybrid animals tolerate ENU well, but that inbred strains of mice vary in their longevity and in their ability to recover fertility after treatment with ENU.

Differences in the DNA of the inactive X chromosomes of fetal and extraembryonic tissues of mice

We have examined the role of DNA modification in X chromosome inactivation of fetal tissues of the mouse using DNA-mediated gene transfer for the gene hypoxanthine phosphoribosyltransferase (HPRT). Two types of tissues have been examined with respect to randomness of inactivation in 14-day mouse conceptuses: 1) fetal tissue, which undergoes random inactivation of either the maternal or paternal X; and 2) yolk sac endoderm tissue, an extraembryonic membrane, which normally undergoes nonrandom inactivation of the paternal X. Exploiting an electrophoretic variant of HPRT as a means to mark the active and inactive HPRT alleles we provide evidence that: 1) inactive X DNA of the fetus at 14 days behaves like that of both adult tissue and cell lines in that the inactive X DNA is not efficient in gene transfer; and 2) in contrast, inactive X DNA from yolk sac endoderm is functional in gene transfer. Thus, despite the similarity in single active X chromosome expression in yolk sac endoderm and somatic tissues, there appears to be a difference at the level of DNA modification between these two tissues.

Undermethylation of structural gene sequences in extraembryonic lineages of the mouse

The first two lineages to differentiate in the mouse embryo are the trophectoderm and primitive endoderm, which give rise to various extraembryonic structures only. Previous work has shown that all derivatives of these two lineages share the property of undermethylation of repetitive DNA sequences, both satellite and dispersed. Here we show that this undermethylation is not a peculiarity of these repetitive elements but is also a feature of structural gene sequences within both lineages. alpha-Fetoprotein, albumin, and major urinary protein gene sequences all showed extensive undermethylation at MspI restriction sites in extraembryonic lineages, which did not correlate with their expression in these tissues. The same sequences were heavily methylated in embryonic tissues as early as 7.5 days of development. There are, therefore, major global differences in DNA methylation between the earliest cell lineages to be established in the mouse embryo. The significance of these differences for cellular commitment events remains to be elucidated.

Identification and characterization of Zic4, a new member of the mouse Zic gene family

The mouse Zic genes encode zinc-finger (Zf) proteins expressed only in the cerebellum of the adult brain. The genes are the vertebrate homologues of the Drosophila pair-rule gene, odd-paired (opa). We identified a novel gene, Zic4, which belongs to the Zic gene family, through a genomic and cDNA cloning study. Zic4 is highly similar to Zic1, Zic2 and Zic3, especially in its Zf motif. An analysis of the genomic organization of Zic4 showed that the gene shares a common exon-intron boundary with Zic1, Zic2, Zic3 and opa. The chromosomal location of Zic4 was determined to be mouse chromosome 9 in the vicinity of Zic1, using an interspecific backcross panel. An RNase protection study showed that Zic4 is expressed only in the cerebellum during the adult stage, as are the other Zic genes. The temporal profile of mRNA expression in the developing cerebellum is similar to that of Zic3 which has a peak on postnatal day 5. These findings suggest that Zic4 is a gene which works cooperatively with other Zic genes during cerebellar development.