AFT1 - A MEDIATOR OF IRON-REGULATED TRANSCRIPTIONAL CONTROL IN SACCHAROMYCES-CEREVISIAE

被引：272

作者：

YAMAGUCHIIWAI, Y ^{[1
]}

DANCIS, A ^{[1
]}

KLAUSNER, RD ^{[1
]}

机构：

[1] NICHHD, CELL BIOL & METAB BRANCH, BETHESDA, MD 20892 USA

来源：

EMBO JOURNAL | 1995年 / 14卷 / 06期

关键词：

FERRIC REDUCTASE; IRON; TRANSCRIPTION; TRANSPORT;

D O I：

10.1002/j.1460-2075.1995.tb07106.x

中图分类号：

Q5 [生物化学]; Q7 [分子生物学];

学科分类号：

071010 ; 081704 ;

摘要：

Using a scheme for selecting mutants of Saccharomyces cerevisiae with abnormalities of iron metabolism, we have identified a gene, AFT1, that mediates the control of iron uptake. AFT1 encodes a 78 kDa protein with a highly basic amino terminal domain and a glutamine-rich C-terminal domain, reminiscent of transcriptional activators. The protein also contains an amino terminal and a C-terminal region with 10% His residues. A dominant mutant allele of this gene, termed AFT1-1(up), results in high levels of ferric reductase and ferrous iron uptake that are not repressed by exogenous iron. The increased iron uptake is associated with enhanced susceptibility to iron toxicity. These effects may be explained by the failure of iron to repress transcription of FRE1, FRE2 and FET3. FRE1 and FRE2 encode plasma membrane ferric reductases, obligatory for ferric iron assimilation, and FET3 encodes a copper-dependent membrane-associated oxidase required for ferrous iron uptake. Conversely, a strain with interruption of the AFT1 gene manifests low ferric reductase and ferrous iron uptake and is susceptible to iron deprivation, because of deficient expression of FRE1 and negligible expression of FRE2 and FET3. Thus, AFT1 functions to activate transcription of target genes in response to iron deprivation and thereby plays a central role in iron homeostasis.

引用

页码：1231 / 1239

页数：9

共 41 条

[1] ENGINEERED METAL-BINDING PROTEINS - PURIFICATION TO PROTEIN FOLDING [J].

ARNOLD, FH ;

HAYMORE, BL .

SCIENCE, 1991, 252 (5014) :1796-1797

[2] THE FET3 GENE OF SACCHAROMYCES-CEREVISIAE ENCODES A MULTICOPPER OXIDASE REQUIRED FOR FERROUS IRON UPTAKE [J].

ASKWITH, C ;

EIDE, D ;

VANHO, A ;

BERNARD, PS ;

LI, LT ;

DAVISKAPLAN, S ;

SIPE, DM ;

KAPLAN, J .

CELL, 1994, 76 (02) :403-410

[3] FERRIC UPTAKE REGULATION PROTEIN ACTS AS A REPRESSOR, EMPLOYING IRON(II) AS A COFACTOR TO BIND THE OPERATOR OF AN IRON TRANSPORT OPERON IN ESCHERICHIA-COLI [J].

BAGG, A ;

NEILANDS, JB .

BIOCHEMISTRY, 1987, 26 (17) :5471-5477

[4] MOLECULAR MECHANISM OF REGULATION OF SIDEROPHORE-MEDIATED IRON ASSIMILATION [J].

BAGG, A ;

NEILANDS, JB .

MICROBIOLOGICAL REVIEWS, 1987, 51 (04) :509-518

[5] A REEVALUATION OF THE FE(II), CA(II), ZN(II), AND PROTON FORMATION-CONSTANTS OF 4,7-DIPHENYL-1,10-PHENANTHROLINEDISULFONATE [J].

BELL, PF ;

CHEN, Y ;

POTTS, WE ;

CHANEY, RL ;

ANGLE, JS .

BIOLOGICAL TRACE ELEMENT RESEARCH, 1991, 30 (02) :125-144

[6] OBLIGATORY REDUCTION OF FERRIC CHELATES IN IRON UPTAKE BY SOYBEANS [J].

CHANEY, RL ;

BROWN, JC ;

TIFFIN, LO .

PLANT PHYSIOLOGY, 1972, 50 (02) :208-+

[7] MOLECULAR CHARACTERIZATION OF A COPPER TRANSPORT PROTEIN IN SACCHAROMYCES-CEREVISIAE - AN UNEXPECTED ROLE FOR COPPER IN IRON TRANSPORT [J].

DANCIS, A ;

YUAN, DS ;

HAILE, D ;

ASKWITH, C ;

EIDE, D ;

MOEHLE, C ;

KAPLAN, J ;

KLAUSNER, RD .

CELL, 1994, 76 (02) :393-402

[8] FERRIC REDUCTASE OF SACCHAROMYCES-CEREVISIAE - MOLECULAR CHARACTERIZATION, ROLE IN IRON UPTAKE, AND TRANSCRIPTIONAL CONTROL BY IRON [J].

DANCIS, A ;

ROMAN, DG ;

ANDERSON, GJ ;

HINNEBUSCH, AG ;

KLAUSNER, RD .

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 1992, 89 (09) :3869-3873

[9]

DANCIS A, 1994, J BIOL CHEM, V269, P25660

[10] GENETIC-EVIDENCE THAT FERRIC REDUCTASE IS REQUIRED FOR IRON UPTAKE IN SACCHAROMYCES-CEREVISIAE [J].

DANCIS, A ;

KLAUSNER, RD ;

HINNEBUSCH, AG ;

BARRIOCANAL, JG .

MOLECULAR AND CELLULAR BIOLOGY, 1990, 10 (05) :2294-2301

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