Interallelic complementation at the mouse Mitf locus.

Mutations at the mouse microphthalmia locus (Mitf) affect the development of different cell types, including melanocytes, retinal pigment epithelial cells of the eye, and osteoclasts. The MITF protein is a member of the MYC supergene family of basic-helix-loop-helix-leucine-zipper (bHLHZip) transcription factors and is known to regulate the expression of cell-specific target genes by binding DNA as homodimer or as heterodimer with related proteins. The many mutations isolated at the locus have different effects on the phenotype and can be arranged in an allelic series in which the phenotypes range from near normal to white microphthalmic animals with osteopetrosis. Previous investigations have shown that certain combinations of Mitf alleles complement each other, resulting in a phenotype more normal than that of each homozygote alone. Here we analyze this interallelic complementation in detail and show that it is limited to one particular allele, Mitf(Mi-white) (Mitf(Mi-wh)), a mutation affecting the DNA-binding domain. Both loss- and gain-of-function mutations are complemented, as are other Mitf mutations affecting the DNA-binding domain. Furthermore, this behavior is not restricted to particular cell types: Both eye development and coat color phenotypes are complemented. Our analysis suggests that Mitf(Mi-wh)-associated interallelic complementation is due to the unique biochemical nature of this mutation.

[1]  A. Ferré-D’Amaré,et al.  Molecular basis of mouse microphthalmia (mi) mutations helps explain their developmental and phenotypic consequences , 1994, Nature Genetics.

[2]  N. Copeland,et al.  Genomic, transcriptional and mutational analysis of the mouse microphthalmia locus. , 2000, Genetics.

[3]  C. Goding,et al.  Melanocyte-specific expression of the human tyrosinase promoter: activation by the microphthalmia gene product and role of the initiator , 1994, Molecular and cellular biology.

[4]  V. Pirrotta Transvection and chromosomal trans-interaction effects. , 1999, Biochimica et biophysica acta.

[5]  R. Boissy,et al.  A mouse model for vitiligo. , 1986, The Journal of investigative dermatology.

[6]  D. Fisher,et al.  Linking osteopetrosis and pycnodysostosis: Regulation of cathepsin K expression by the microphthalmia transcription factor family , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[7]  A. Ferré-D’Amaré,et al.  The semidominant Mi(b) mutation identifies a role for the HLH domain in DNA binding in addition to its role in protein dimerization. , 1996, The EMBO journal.

[8]  S Shibahara,et al.  An L1 element intronic insertion in the black-eyed white (Mitf[mi-bw]) gene: the loss of a single Mitf isoform responsible for the pigmentary defect and inner ear deafness. , 1999, Human molecular genetics.

[9]  B. Shilo,et al.  Interallelic complementation among DER/flb alleles: implications for the mechanism of signal transduction by receptor-tyrosine kinases. , 1991, Genetics.

[10]  V. Perry,et al.  A new allele of microphthalmia induced in the mouse: microphthalmia--defective iris (midi). , 1985, Genetical research.

[11]  E. Morii,et al.  Regulation of mouse mast cell protease 6 gene expression by transcription factor encoded by the mi locus. , 1996, Blood.

[12]  E. Morii,et al.  The recessive phenotype displayed by a dominant negative microphthalmia-associated transcription factor mutant is a result of impaired nucleation potential , 1996, Molecular and cellular biology.

[13]  J. Lingrel,et al.  A helix-loop-helix transcription factor-like gene is located at the mi locus. , 1993, The Journal of biological chemistry.

[14]  M. Nguyen,et al.  Mutations in microphthalmia, the mouse homolog of the human deafness gene MITF, affect neuroepithelial and neural crest-derived melanocytes differently , 1998, Mechanisms of Development.

[15]  S. Shibahara,et al.  Microphthalmia-associated transcription factor as a regulator for melanocyte-specific transcription of the human tyrosinase gene , 1994, Molecular and cellular biology.

[16]  K. J. Moore Insight into the microphthalmia gene. , 1995, Trends in genetics : TIG.

[17]  N. Copeland,et al.  Mitf and Tfe3, two members of the Mitf-Tfe family of bHLH-Zip transcription factors, have important but functionally redundant roles in osteoclast development , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[18]  James A. Vaught,et al.  microphthalmia, a critical factor in melanocyte development, defines a discrete transcription factor family. , 1994, Genes & development.

[19]  D. Coleman,et al.  Mi-spotted. A mutation in the mouse. , 1964 .

[20]  N. Jenkins,et al.  Mutations at the mouse microphthalmia locus are associated with defects in a gene encoding a novel basic-helix-loop-helix-zipper protein , 1993, Cell.

[21]  S. Shibahara,et al.  Molecular cloning of cDNA encoding a human TFEC isoform, a newly identified transcriptional regulator. , 1997, Biochimica et biophysica acta.

[22]  J. Nordlund,et al.  The vit gene maps to the mi (microphthalmia) locus of the laboratory mouse. , 1992, The Journal of heredity.

[23]  B. Konyukhov,et al.  Interallelic complementation of microphthalmia and white genes in mice. , 1968 .

[24]  P. Sternberg,et al.  Mutations in the Caenorhabditis elegans let‐23 EGFR‐like gene define elements important for cell‐type specificity and function. , 1994, The EMBO journal.