Structural determinants of metal selectivity in prokaryotic metal-responsive transcriptional regulators

Metal ion homeostasis in prokaryotes is maintained by metal-responsive transcriptional regulatory proteins that regulate the transcription of genes encoding proteins responsible for metal detoxification, sequestration, efflux and uptake. These metalloregulatory, or metal sensor proteins, bind a wide...

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Bibliographic Details
Published in:Biometals 2005-08, Vol.18 (4), p.413-428
Main Authors: Pennella, Mario A, Giedroc, David P
Format: Article
Language:English
Subjects:
Allosteric Site
Amino Acid Motifs
Amino Acid Sequence
Bacterial Proteins - chemistry
Bacterial Proteins - metabolism
Binding Sites
Chelates
Detoxification
DNA - chemistry
DNA-Binding Proteins - chemistry
DNA-Binding Proteins - metabolism
Escherichia coli - metabolism
Ions - metabolism
Ligands
Metal ions
Metals - chemistry
Metals, Heavy - metabolism
Models, Molecular
Molecular Sequence Data
Protein Conformation
Protein Structure, Quaternary
Proteins
Repressor Proteins - chemistry
Sequence Homology, Amino Acid
Trans-Activators - metabolism
Transcription, Genetic
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Summary:Metal ion homeostasis in prokaryotes is maintained by metal-responsive transcriptional regulatory proteins that regulate the transcription of genes encoding proteins responsible for metal detoxification, sequestration, efflux and uptake. These metalloregulatory, or metal sensor proteins, bind a wide range of specific metal ions directly; this in turn, allosterically regulates (enhances or decreases) operator/promoter binding affinity or promoter structure. Recent structural studies reveal five distinct families of metal sensor proteins. The MerR and ArsR/SmtB families regulate the expression of genes required for metal ion detoxification, efflux and sequestration; here, metal binding leads to activation (MerR) or derepression (ArsR/SmtB) of the resistance operon. In contrast, the DtxR, Fur, and NikR families regulate genes encoding proteins involved in metal ion uptake; in these cases, the metal ion functions as a co-repressor in turning off uptake genes under metal-replete conditions. Inspection of the structures of representative members from each metal sensor family reveals several common characteristics: (1) they function as homo-oligomers (either dimers or tetramers); (2) metal-binding ligands are found at subunit interfaces, with ligands derived from more than one protomer; this likely helps drive quaternary structural changes that mediate allosteric coupling between the metal and DNA binding sites; and (3) the primary determinant of metal ion selectivity within each protein family is dictated by the coordination geometry of the metal chelate, with trends consistent with expectations from fundamental inorganic chemistry. This review highlights recent efforts to elucidate the structure of metal sensing chelates and the molecular mechanisms of allosteric coupling in metal sensor proteins.
ISSN:0966-0844
1572-8773
DOI:10.1007/s10534-005-3716-8