Compound heterozygous mutations in SLC30A2/ZnT2 results in low milk zinc concentrations: a novel mechanism for zinc deficiency in a breast-fed infant

Zinc concentrations in breast milk are considerably higher than those of the maternal serum, to meet the infant's requirements for normal growth and development. Thus, effective mechanisms ensuring secretion of large amounts of zinc into the milk operate in mammary epithelial cells during lacta...

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Veröffentlicht in:	PloS one 2013-05, Vol.8 (5), p.e64045-e64045
Hauptverfasser:	Itsumura, Naoya, Inamo, Yasuji, Okazaki, Fumiko, Teranishi, Fumie, Narita, Hiroshi, Kambe, Taiho, Kodama, Hiroko
Format:	Artikel
Sprache:	eng
Schlagworte:	Alzheimer's disease Alzheimers disease Amino Acid Sequence Animals Arginine Asian Continental Ancestry Group B-Lymphocytes - cytology B-Lymphocytes - metabolism Babies Baldness Base Sequence Biology Breast Breast Feeding Breast milk Breastfeeding & lactation Cation Transport Proteins - genetics Cations, Divalent Cell Line Chickens Congenital diseases Dermatitis Diabetes Epithelial cells Exons Family medical history Female Food science Genomes Growth Disorders Heterozygote Humans Infant Infants Ion Transport Lactation Leucine Life sciences Mammary gland Medicine Metal Metabolism, Inborn Errors - genetics Metal Metabolism, Inborn Errors - metabolism Metal Metabolism, Inborn Errors - pathology Milk Milk, Human - chemistry Milk, Human - metabolism Missense mutation Molecular Sequence Data Mutation Neonates Newborn babies Nutrient deficiency Pediatrics Reduction Review boards Rodents Secretion Serine Substitutes Tryptophan Womens health Zinc Zinc - metabolism Zinc compounds
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creator	Itsumura, Naoya Inamo, Yasuji Okazaki, Fumiko Teranishi, Fumie Narita, Hiroshi Kambe, Taiho Kodama, Hiroko
description	Zinc concentrations in breast milk are considerably higher than those of the maternal serum, to meet the infant's requirements for normal growth and development. Thus, effective mechanisms ensuring secretion of large amounts of zinc into the milk operate in mammary epithelial cells during lactation. ZnT2 was recently found to play an essential role in the secretion of zinc into milk. Heterozygous mutations of human ZnT2 (hZnT2), including H54R and G87R, in mothers result in low (>75% reduction) secretion of zinc into the breast milk, and infants fed on the milk develop transient neonatal zinc deficiency. We identified two novel missense mutations in the SLC30A2/ZnT2 gene in a Japanese mother with low milk zinc concentrations (>90% reduction) whose infant developed severe zinc deficiency; a T to C transition (c.454T>C) at exon 4, which substitutes a tryptophan residue with an arginine residue (W152R), and a C to T transition (c.887C>T) at exon 7, which substitutes a serine residue with a leucine residue (S296L). Biochemical characterization using zinc-sensitive DT40 cells indicated that the W152R mutation abolished the abilities to transport zinc and to form a dimer complex, indicating a loss-of-function mutation. The S296L mutation retained both abilities but was extremely destabilized. The two mutations were found on different alleles, indicating that the genotype of the mother with low milk zinc was compound heterozygous. These results show novel compound heterozygous mutations in the SLC30A2/ZnT2 gene causing zinc deficiency in a breast-fed infant.
doi_str_mv	10.1371/journal.pone.0064045
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Thus, effective mechanisms ensuring secretion of large amounts of zinc into the milk operate in mammary epithelial cells during lactation. ZnT2 was recently found to play an essential role in the secretion of zinc into milk. Heterozygous mutations of human ZnT2 (hZnT2), including H54R and G87R, in mothers result in low (>75% reduction) secretion of zinc into the breast milk, and infants fed on the milk develop transient neonatal zinc deficiency. We identified two novel missense mutations in the SLC30A2/ZnT2 gene in a Japanese mother with low milk zinc concentrations (>90% reduction) whose infant developed severe zinc deficiency; a T to C transition (c.454T>C) at exon 4, which substitutes a tryptophan residue with an arginine residue (W152R), and a C to T transition (c.887C>T) at exon 7, which substitutes a serine residue with a leucine residue (S296L). Biochemical characterization using zinc-sensitive DT40 cells indicated that the W152R mutation abolished the abilities to transport zinc and to form a dimer complex, indicating a loss-of-function mutation. The S296L mutation retained both abilities but was extremely destabilized. The two mutations were found on different alleles, indicating that the genotype of the mother with low milk zinc was compound heterozygous. 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Thus, effective mechanisms ensuring secretion of large amounts of zinc into the milk operate in mammary epithelial cells during lactation. ZnT2 was recently found to play an essential role in the secretion of zinc into milk. Heterozygous mutations of human ZnT2 (hZnT2), including H54R and G87R, in mothers result in low (>75% reduction) secretion of zinc into the breast milk, and infants fed on the milk develop transient neonatal zinc deficiency. We identified two novel missense mutations in the SLC30A2/ZnT2 gene in a Japanese mother with low milk zinc concentrations (>90% reduction) whose infant developed severe zinc deficiency; a T to C transition (c.454T>C) at exon 4, which substitutes a tryptophan residue with an arginine residue (W152R), and a C to T transition (c.887C>T) at exon 7, which substitutes a serine residue with a leucine residue (S296L). 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subjects	Alzheimer's disease Alzheimers disease Amino Acid Sequence Animals Arginine Asian Continental Ancestry Group B-Lymphocytes - cytology B-Lymphocytes - metabolism Babies Baldness Base Sequence Biology Breast Breast Feeding Breast milk Breastfeeding & lactation Cation Transport Proteins - genetics Cations, Divalent Cell Line Chickens Congenital diseases Dermatitis Diabetes Epithelial cells Exons Family medical history Female Food science Genomes Growth Disorders Heterozygote Humans Infant Infants Ion Transport Lactation Leucine Life sciences Mammary gland Medicine Metal Metabolism, Inborn Errors - genetics Metal Metabolism, Inborn Errors - metabolism Metal Metabolism, Inborn Errors - pathology Milk Milk, Human - chemistry Milk, Human - metabolism Missense mutation Molecular Sequence Data Mutation Neonates Newborn babies Nutrient deficiency Pediatrics Reduction Review boards Rodents Secretion Serine Substitutes Tryptophan Womens health Zinc Zinc - metabolism Zinc compounds
title	Compound heterozygous mutations in SLC30A2/ZnT2 results in low milk zinc concentrations: a novel mechanism for zinc deficiency in a breast-fed infant
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