A novel gene involved in zinc transport is deficient in the lethal milk mouse (original) (raw)
References
Vallee, B.L. & Falchuk, K.H. The biochemical basis of zinc physiology. Physiol. Rev.73, 79–118 (1993). ArticleCAS Google Scholar
Palmiter, R.D. & Findley, S.D. Cloning and functional characterization of a mammalian zinc transporter that confers resistance to zinc. EMBOJ.14, 639–649 (1995). ArticleCAS Google Scholar
Palmiter, R.D., Cole, T.B. & Findley, S.D., ZnT2, a mammalian protein that confers resistance to zinc by facilitating vesicular sequestration. EMBO J.15, 1784–1791 (1996). ArticleCAS Google Scholar
Palmiter, R.D., Cole, T.B., Quaife, C.J. & Findley, S.D., ZnT3, a putative transporter of zinc into synaptic vesicles. Proc. Natl. Acad. Sci. USA93, 14934–14939 (1996). ArticleCAS Google Scholar
Kamizono, A., Nishizawa, M., Y, Murata,, K. & Kimura,, A. Identification of a gene conferring resistance to zinc and cadmium ions in the yeast Saccharamyces cerevisiae . Mol. Gen. Genet.219, 161–167 (1989). ArticleCAS Google Scholar
Conklin, D.S., McMaster, J.A., Culbertson, M.R. & Kung, C. COT1, a gene involved in cobalt accumulation in Saccharomyces cerevisiae. Mol. Cell. Biol.12, 3678–3688 (1992). ArticleCAS Google Scholar
Nies, D.H., Nies, A., Chu, L. & Silver, S. Expression and nucleotide sequence of a plasmid-determined divalent cation efflux system from Alcaligenes eutrophus. Proc. Nat. Acad. Sci. USA86, 7351–7355 (1989). ArticleCAS Google Scholar
Zhao, H. & Hide, D. The yeast ZRT1 gene encodes the zinc transporter protein of a high-affinity uptake system induced by zinc limitation. Proc. Natl. Acad. Sci. USA93, 2454–2458 (1996). ArticleCAS Google Scholar
Zhao, H. & Eide, D. The ZRT2 gene encodes the low affinity zinc transporter in Saccharomyces cervisiae. J. Biol. Chem.271, 23202–23210 (1996). Google Scholar
van Wouwe,, J.P. Clinical and laboratory diagnosis of acrodermatitis enteropathica. Eur. J. Pediatr.149, 2–8 (1989). ArticleCAS Google Scholar
Piletz, J.E. & Ganschow, R.E. Zinc deficiency in murine milk underlies expression of the lethal milk (Im) mutation. Science199, 181–183 (1978). ArticleCAS Google Scholar
Ackland, M.L. & Mercer, J.F.B. The murine mutation, lethal milk, results in production of zinc-deficient milk. J. Nutrition122, 1214–1218 (1992). ArticleCAS Google Scholar
Lee, D.Y., Shay, N.F. & Cousins, R.J. Altered zinc metabolism occurs in murine lethal milk syndrome. J. Nutrition122, 2233–2238 (1992). ArticleCAS Google Scholar
Erway, L.C. & Grider, A. Zinc metabolism in lethal milk mice: otolith, lactation, and aging effects. J. Heredity75, 480–484 (1984). ArticleCAS Google Scholar
Piletz, J.E. & Ganschow, R.E. Lethal milk mutations results in dietary zinc deficiency in nursing mice. Am. J. Clin. Nutr.31, 560–562 (1978). ArticleCAS Google Scholar
Dickie, M.M., Mouse News Letter41, 30 (1969). Google Scholar
Roberts, E. A new mutation in the house mouse (Mus musculus). Science74, 569 (1931). ArticleCAS Google Scholar
Siracusa, L.D., Morgan, J.L., Fisher, J.K., Abbott, C.M. & Peters, J. Mouse chromosome 2. Mamm. Genome6,, S51–S63 (1996). Google Scholar
Robinson, P.J. et al. Location of the mouse β2-microglobulin gene B2m determined by linkage analysis. Immunogenetics14, 449–452 (1981). ArticleCAS Google Scholar
White, R.A. et al. The murine pallid mutation is a platelet storage pool disease associated with the protein 4.2 (pallidin) gene. Nature Genet.2, 80–83 (1992). ArticleCAS Google Scholar
Gwynn, B., Ciciotte, S., Korsgren, C., Cohen, C.M. & Peters, L.L. Genetic mapping distinguishes the gene encoding protein 4.2 from the mouse platelet storage pool deficiency mutation pallid. Mol. Biol. Cell7, 550a (1996). Google Scholar
Lyon, M.F. & Searle, A.G. Variants and Strains of the Laboratory Mouse (Oxford University Press, Oxford, UK, 1989).
von Heijne,, G. Membrane proteins: from sequence to structure. Annu. Rev. Biophys. Biomol. Struct.23, 167–192 (1994). ArticleCAS Google Scholar
Purichia, N. & Erway, L.C. Effects of dichlorophenamide, zinc, and manganese on otolith development in mice. Dev. Biol.27, 395–405 (1972). ArticleCAS Google Scholar
Kuramoto, Y., Igarashi, Y. & Tagami, H. Acquired zinc deficiency in breast-fed infants. Semin. Dermatol.10, 309–312 (1991). CASPubMed Google Scholar
Glover, M.T. & Atherton, D.J. Transient zinc deficiency in two full-term breast-fed siblings associated with low maternal breast milk zinc concentration. Pediatr. Dermatol.5, 10–13 (1988). ArticleCAS Google Scholar
Eckhert, C.D., Sloan, M.V., Duncan, J.R. & LS.Zinc binding: a difference between human and bovine milk. Science195, 789 (1977). ArticleCAS Google Scholar
Moynahan, E.J. Acrodermatitis enteropahtic: a lethal inherited human zinc-deficiency disorder. LancetII, 399–400 (1974). Article Google Scholar
Theophilos, M.B., Cox, D.W. & Mercer, J.F.B. The toxic milk mouse is a murine model of Wilson disease. Hum. Mol. Genet.5, 1619–1624 (1996). ArticleCAS Google Scholar
Riley, J. et al. A novel, rapid method for the isolation of terminal sequences from yeast artificial chromosome (YAC) clones. Nucleic Acid Res.18, 2887–2890 (1990). ArticleCAS Google Scholar
Chaplin, D.D. & Brownstein, B.H., Protocols in Molecular Biology (ed. Janssen, K.) 6.10.1–6.10.9 (John Wiley & Sons, New York, 1994). Google Scholar