Molecular analyses of the agouti allele in the Japanese house mouse identify a novel variant of the agouti gene

It has been thought that the Japanese house mouse carries the Aw allele at the agouti locus causing light-colored bellies, but they do not always show this coloration. Thus, the presence of the Aw allele seems to be doubtful in them. To ascertain whether the Aw allele is present, a two-pronged approach was used. First, we compared lengths of DNA fragments obtained from three PCRs conducted on them to the known fragment sizes generated from mouse strains exhibiting homozygosities of either a/a, A/A, or Aw/Aw. PCR I, PCR II, and PCR III amplify only in the A and Aw alleles, the a and Aw alleles, and the a allele, respectively, and we detected amplifications in strains with A/A and Aw/Aw by PCR I, in those with a/a and the Japanese house mouse by PCR II, and in those with a/a by PCR III. Second, we sequenced the exon 1A region of the agouti gene and obtained sequences corresponding to the above strains and the Japanese house mouse, but their sequences were similar to those of the a allele. We concluded that their agouti allele is not identical to the Aw allele and seems to be a novel type similar to the a allele.

Molecular and Phenotypic Analysis of 25 Recessive, Homozygous-Viable Alleles at the Mouse agouti Locus

Agouti is a paracrine-acting, transient antagonist of melanocortin 1 receptors that specifies the subapical band of yellow on otherwise black hairs of the wild-type coat. To better understand both agouti structure/function and the germline damage caused by chemicals and radiation, an allelic series of 25 recessive, homozygous-viable agouti mutations generated in specific-locus tests were characterized. Visual inspection of fur, augmented by quantifiable chemical analysis of hair melanins, suggested four phenotypic categories (mild, moderate, umbrous-like, severe) for the 18 hypomorphs and a single category for the 7 amorphs (null). Molecular analysis indicated protein-coding alterations in 8 hypomorphs and 6 amorphs, with mild-moderate phenotypes correlating with signal peptide or basic domain mutations, and more devastating phenotypes resulting from C-terminal lesions. Ten hypomorphs and one null demonstrated wild-type coding potential, suggesting that they contain mutations elsewhere in the ≥125-kb agouti locus that either reduce the level or alter the temporal/spatial distribution of agouti transcripts. Beyond the notable contributions to the field of mouse germ cell mutagenesis, analysis of this allelic series illustrates that complete abrogation of agouti function in vivo occurs most often through protein-coding lesions, whereas partial loss of function occurs slightly more frequently at the level of gene expression control.

Opposite Orientations of an Inverted Duplication and Allelic Variation at the Mouse agouti Locus

The mouse agouti protein is a paracrine signaling molecule that causes yellow pigment synthesis. A pale ventral coloration distinguishes the light-bellied agouti (AW) from the agouti (A) allele, and is caused by expression of ventral-specific mRNA isoforms with a unique 5′ untranslated exon. Molecular cloning demonstrates this ventral-specific exon lies within a 3.1-kb element that is duplicated in the opposite orientation 15-kb upstream to produce an interrupted palindrome and that similarity between the duplicated elements has been maintained by gene conversion. Orientation of the palindrome is reversed in A compared to AW, which suggests that mutation from one allele to the other is caused by intrachromosomal homologous recombination mediated by sequences within the duplicated elements. Analysis of 15 inbred strains of laboratory and wild-derived mice with Southern hybridization probes and closely linked microsatellite markers suggests six haplotype groups: one typical for most strains that carry AW (129/SvJ, LP/J, CE/J, CAST/Ei), one typical for most strains that carry A (Balb/cJ, CBA/J, FVB/N, PERA/Rk, RBB/Dn); and four that are atypical (MOLC/Rk, MOLG/Dn, PERA/Ei, PERC/Ei, SPRET/Ei, RBA/Dn). Our results suggest a model for molecular evolution of the agouti locus in which homologous recombination can produce a reversible switch in allelic identity.