D J Eide
Overview
Explore the profile of D J Eide including associated specialties, affiliations and a list of published articles.
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Articles
19
Citations
1136
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Recent Articles
1.
Evans-Galea M, Blankman E, Myszka D, Bird A, Eide D, Winge D
Biochemistry
. 2003 Jan;
42(4):1053-61.
PMID: 12549926
The Zap1 transcriptional activator from Saccharomyces cerevisiae induces expression of a series of genes containing an 11 base pair conserved promoter element (ZRE) under conditions of zinc deficiency. This work...
2.
Gaither L, Eide D
Biometals
. 2002 Feb;
14(3-4):251-70.
PMID: 11831460
The last ten years have witnessed major advances in our understanding of zinc transporters and their regulation in eukaryotic organisms. Two families of transporters, the ZIP (Zrt-, Irt-like Protein) and...
3.
Eide D
Genome Biol
. 2001 Oct;
2(10):REVIEWS1028.
PMID: 11597338
Metal ions are essential nutrients, yet they can also be toxic if they over-accumulate. Homeostatic mechanisms and detoxification systems therefore precisely control their intracellular levels and distribution. The tools of...
4.
Gaither L, Eide D
J Biol Chem
. 2001 Apr;
276(25):22258-64.
PMID: 11301334
The ZIP superfamily of transporters plays important roles in metal ion uptake in diverse organisms. There are 12 ZIP-encoding genes in humans, and we hypothesize that many of these proteins...
5.
Rogers E, Eide D, Guerinot M
Proc Natl Acad Sci U S A
. 2000 Oct;
97(22):12356-60.
PMID: 11035780
Plants require metals for essential functions ranging from respiration to photosynthesis. These metals also contribute to the nutritional value of plants for both humans and livestock. Additionally, plants have the...
6.
Hassett R, Dix D, Eide D, Kosman D
Biochem J
. 2000 Oct;
351 Pt 2:477-84.
PMID: 11023834
The plasma-membrane of Saccharomyces cerevisiae contains high affinity permeases for Cu(I) and Fe(II). A low affinity Fe(II) permease has also been identified, designated Fet4p. A corresponding low affinity copper permease...
7.
Eide D
Adv Microb Physiol
. 2000 Jul;
43:1-38.
PMID: 10907553
Metal ions such as iron, copper, manganese, and zinc are essential nutrients for all eukaryotic microorganisms. Therefore, these organisms possess efficient uptake mechanisms to obtain these nutrients from their extracellular...
8.
Bird A, Zhao H, Luo H, Jensen L, Srinivasan C, Winge D, et al.
EMBO J
. 2000 Jul;
19(14):3704-13.
PMID: 10899124
The Zap1 transcriptional activator of Saccharomyces cerevisiae controls zinc homeostasis. Zap1 induces target gene expression in zinc-limited cells and is repressed by high zinc. One such target gene is ZAP1...
9.
Lyons T, Gasch A, Gaither L, Botstein D, Brown P, Eide D
Proc Natl Acad Sci U S A
. 2000 Jul;
97(14):7957-62.
PMID: 10884426
The Zap1p transcription factor senses cellular zinc status and increases expression of its target genes in response to zinc deficiency. Previously known Zap1p-regulated genes encode the Zrt1p, Zrt2p, and Zrt3p...
10.
Bird A, Evans-Galea M, Blankman E, Zhao H, Luo H, Winge D, et al.
J Biol Chem
. 2000 Apr;
275(21):16160-6.
PMID: 10747942
The Zap1 transcriptional activator of Saccharomyces cerevisiae plays a major role in zinc homeostasis by inducing the expression of several genes under zinc-limited growth conditions. This activation of gene expression...