Abstract
Metal tolerance proteins (MTPs) are plant members of the cation diffusion facilitator (CDF) transporter family involved in cellular metal homeostasis. Members of the CDF family are ubiquitously found in all living entities and show principal selectivity for Zn(2+), Mn(2+), and Fe(2+). Little is known regarding metal selectivity determinants of CDFs. We identified a novel cereal member of CDFs in barley, termed HvMTP1, that localizes to the vacuolar membrane. Unlike its close relative AtMTP1, which is highly selective for Zn(2+), HvMTP1 exhibits selectivity for both Zn(2+) and Co(2+) as assessed by its ability to suppress yeast mutant phenotypes for both metals. Expression of HvMTP1/AtMTP1 chimeras in yeast revealed a five-residue sequence within the AtMTP1 N-segment of the His-rich intracytoplasmic loop that confines specificity to Zn(2+). Furthermore, mutants of AtMTP1 generated through random mutagenesis revealed residues embedded within transmembrane domain 3 that additionally specify the high degree of Zn(2+) selectivity. We propose that the His-rich loop, which might play a role as a zinc chaperone, determines the identity of the metal ions that are transported. The residues within transmembrane domain 3 can also influence metal selectivity, possibly through conformational changes induced at the cation transport site located within the membrane or at the cytoplasmic C-terminal domain.
Highlights
Metal selectivity is an important feature of the plant cation diffusion facilitator (CDF) transporter family
HvMTP1 Characterization and Metal Selectivity—We cloned from barley a CDF family member that we termed HvMTP1
Phylogenetic analysis of HvMTP1 positions it in the Zn2ϩ clade of the CDF family, alongside the Arabidopsis thaliana Metal tolerance proteins (MTPs) 1 through 4
Summary
Metal selectivity is an important feature of the plant cation diffusion facilitator (CDF) transporter family. Residues, and often with histidine, to generate a rigid local structure in transcription factors These diverse roles of zinc notwithstanding, it is astonishing that bioinformatics approaches predict that no less than around 10% of the human proteome comprises zinc-binding proteins [3]. CDFs function as homodimeric antiporters, transporting metal ions against concentration gradients using Hϩ or Kϩ to create an electrochemical gradient [12,13,14,15,16] These possess six transmembrane domains (TMDs), cytosolic N- and C-terminals, and, in the case of Zn2ϩ-transporters only, a His-rich cytosolic loop (IL2) between TMD4 and TMD5 thought to be involved in metal binding [11, 15]. The results are interpreted in terms of a structural model that might involve a metal chaperone role for the His-rich loop
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