The family of SMF metal ion transporters in yeast cells

Metal ions are vital for all organisms, and metal ion transporters play a crucial role in maintaining their homeostasis. The yeast (Saccharomyces cerevisiae) Smf transporters and their homologs in other organisms have a central role in the accumulation of metal ions and their distribution in different tissues and cellular organelles. In this work we generated null mutations in each individual SMF gene in yeast as well as in all combinations of the genes. Each null mutation exhibited sensitivity to metal ion chelators at different concentrations. The combination of null mutants DeltaSMF1 + DeltaSMF2 and the triple null mutant Delta3SMF failed to grow on medium buffered at pH 8 and 7.5, respectively. Addition of 5 microm copper or 25 microm manganese alleviated the growth arrest at the high pH or in the presence of the chelating agent. The transport of manganese was analyzed in the triple null mutant and in this mutant expressing each Smf protein. Although overexpression of Smf1p and Smf2p resulted in uptake that was higher than wild type cells, the expression of Smf3p gave no significant uptake above that of the triple mutant Delta3SMF. Western analysis with antibody against Smf3p indicated that this transporter does not reach the plasma membrane and may function at the Golgi or post-Golgi complexes. The iron uptake resulting from expression of Smf1p and Smf2p was analyzed in a mutant in which its iron transporters FET3 and FET4 were inactivated. Overexpression of Smf1p gave rise to a significant iron uptake that was sensitive to the sodium concentrations in the medium. We conclude that the Smf proteins play a major role in copper and manganese homeostasis and, under certain circumstances, Smf1p may function in iron transport into the cells.     

Genome-wide screening of yeast metal homeostasis genes involved in mitochondrial functions

Metal ions are essential for mitochondria to execute their roles. Yeast mutants that are sensitive to metals (either excess or deficiency) on non-fermentable media but not on fermentable media may carry mutations in genes that participate in metal homeostasis involving mitochondrial functions. A collection of approximately 4,800 haploid yeast deletion mutants was screened for metal ion homeostasis genes linked to mitochondrial respiration. In addition to several well-characterized metal homeostasis genes, 45 new mutants, impaired in various molecular functions, were identified on non-fermentable media that were sensitive to adscititious metals or metal deficiency. While 35 of these mutants displayed metal-sensitivity only on non-fermentable media, the remaining 10 also exhibited metal sensitivity on fermentable media, suggesting metal-sensitivity of the latter is not due to mitochondrial dysfunction. Inductively coupled plasma optical emission spectrometry (ICP-OES) was conducted for 12 mutants that were sensitive to metal excess to analyze their metal contents. Among these 12 mutants 7 were sensitive to metal excess on non-fermentable but not on fermentable media. All the seven respiration-dependent mutants displayed abnormal levels of metal ions inside mitochondria, indicative of disrupted mitochondrial metal homeostasis. This study therefore effectively identified multiple new genes involved in metal homeostasis pathways possibly pertinent to mitochondrial functions, and should be helpful for future studies to further understand their molecular roles.     

The role of copper transporters in the development of resistance to Pt drugs

Recent studies in yeast, mouse and human cells suggest that the conserved metal binding transporters of the Cu homeostasis pathway can mediate resistance to Pt drugs in cancer cells. This review summarizes the data available from these studies. The observation that cells selected for resistance to Cu or the Pt drugs display bidirectional cross-resistance, parallel defects in the transport of Cu and the Pt drugs and altered expression of Cu transporters is consistent with the concept that the Cu homeostasis proteins regulate sensitivity to the Pt drugs by influencing their uptake, efflux and intracellular distribution. This model is supported by the finding that when mammalian and yeast cells are genetically engineered to express altered levels of the Cu transporters they exhibit altered sensitivity to Pt drugs and are defective in intracellular Pt accumulation due to altered uptake and/or efflux rates. Negative associations between the expression of ATP7A and ATP7B and the outcome of Pt therapy further support the significance of the Cu homeostasis proteins as both markers of and contributors to Pt resistance.     

The long physiological reach of the yeast vacuolar H+-ATPase

V-ATPases are structurally conserved and functionally versatile proton pumps found in all eukaryotes. The yeast V-ATPase has emerged as a major model system, in part because yeast mutants lacking V-ATPase subunits (vma mutants) are viable and exhibit a distinctive Vma- phenotype. Yeast vma mutants are present in ordered collections of all non-essential yeast deletion mutants, and a number of additional phenotypes of these mutants have emerged in recent years from genomic screens. This review summarizes the many phenotypes that have been associated with vma mutants through genomic screening. The results suggest that V-ATPase activity is important for an unexpectedly wide range of cellular processes. For example, vma mutants are hypersensitive to multiple forms of oxidative stress, suggesting an antioxidant role for the V-ATPase. Consistent with such a role, vma mutants display oxidative protein damage and elevated levels of reactive oxygen species, even in the absence of an exogenous oxidant. This endogenous oxidative stress does not originate at the electron transport chain, and may be extra-mitochondrial, perhaps linked to defective metal ion homeostasis in the absence of a functional V-ATPase. Taken together, genomic data indicate that the physiological reach of the V-ATPase is much longer than anticipated. Further biochemical and genetic dissection is necessary to distinguish those physiological effects arising directly from the enzyme’s core functions in proton pumping and organelle acidification from those that reflect broader requirements for cellular pH homeostasis or alternative functions of V-ATPase subunits.     

Manipulation of intracellular magnesium levels in Saccharomyces cerevisiae with deletion of magnesium transporters

Magnesium is an important divalent ion for organisms. There have been a number of studies in vitro suggesting that magnesium affects enzyme activity. Surprisingly, there have been few studies to determine the cellular mechanism for magnesium regulation. We wished to determine if magnesium levels could be regulated in vivo. It is known that Saccharomyces cerevisiae has two magnesium transporters (ALR1 and ALR2) across the plasma membrane. We created S. cerevisiae strains with deletion of one (alr1 or alr2) or both (alr1 alr2) transporters. The deletion of ALR1 resulted in a decrease in intracellular magnesium levels. An increase from 5 to 100 mM in the exogenous magnesium level increased the intracellular levels of magnesium in the alr1 and alr1 alr2 strains, whereas the expression of magnesium transporters from S. cerevisiae or Arabidopsis thaliana led to a change of the intracellular levels of magnesium in those strains. The deletion of magnesium transporters in A. cerevisiae and overexpression of magnesium transporters from A. thaliana also affected the intracellular concentrations of a range of metal ions, which suggests that cells use non-specific transporters to help regulate metal homeostasis.     

Heterologously expressed protein phosphatase calcineurin downregulates plant plasma membrane H+-ATPase activity at the post-translational level

To investigate the effects of calcineurin expression on cellular ion homeostasis in plants, we have obtained a transgenic cell culture of tomato, expressing constitutively activated yeast calcineurin. Transgenic cells exhibited reduced growth rates and proton extrusion activity in vivo. We show that reduction of plasma membrane H+-ATPase activity by expression of calcineurin is the basis for the observed phenotypes. Transgenic calli and cell suspensions displayed also increased salt tolerance and contained slightly higher Ca2+ and K+ levels. This demonstrates that calcineurin can modulate ion homeostasis in plants as it does in yeast by affecting the activity of primary ion transporters.     

Elesclomol elevates cellular and mitochondrial iron levels by delivering copper to the iron import machinery

Copper (Cu) and iron (Fe) are redox-active metals that serve as cofactors for many essential cellular enzymes. Disruption in the intracellular homeostasis of these metals results in debilitating and frequently fatal human disorders, such as Menkes disease and Friedreich’s ataxia. Recently, we reported that an investigational anticancer drug, elesclomol (ES), can deliver Cu to critical mitochondrial cuproenzymes and has the potential to be repurposed for the treatment of Cu deficiency disorders. Here, we sought to determine the specificity of ES and the ES-Cu complex in delivering Cu to cuproenzymes in different intracellular compartments. Using a combination of yeast genetics, subcellular fractionation, and inductively coupled plasma-mass spectrometry–based metal measurements, we showed that ES and ES-Cu treatment results in an increase in cellular and mitochondrial Fe content, along with the expected increase in Cu. Using yeast mutants of Cu and Fe transporters, we demonstrate that ES-based elevation in cellular Fe levels is independent of the major cellular Cu importer but is dependent on the Fe importer Ftr1 and its partner Fet3, a multicopper oxidase. As Fet3 is metalated in the Golgi lumen, we sought to uncover the mechanism by which Fet3 receives Cu from ES. Using yeast knockouts of genes involved in Cu delivery to Fet3, we determined that ES can bypass Atx1, a metallochaperone involved in Cu delivery to the Golgi membrane Cu pump, Ccc2, but not Ccc2 itself. Taken together, our study provides a mechanism by which ES distributes Cu in cells and impacts cellular and mitochondrial Fe homeostasis.     

Metal transport across biomembranes: emerging models for a distinct chemistry

Transition metals are essential components of important biomolecules, and their homeostasis is central to many life processes. Transmembrane transporters are key elements controlling the distribution of metals in various compartments. However, due to their chemical properties, transition elements require transporters with different structural-functional characteristics from those of alkali and alkali earth ions. Emerging structural information and functional studies have revealed distinctive features of metal transport. Among these are the relevance of multifaceted events involving metal transfer among participating proteins, the importance of coordination geometry at transmembrane transport sites, and the presence of the largely irreversible steps associated with vectorial transport. Here, we discuss how these characteristics shape novel transition metal ion transport models.     

Probing metal ion substrate-binding to the E. coli ZitB exporter in native membranes by solid state NMR

Metal ion homeostasis is important for healthy cell function and is regulated by metal ion transporters and chaperones. To explore metal ion binding to membrane transport proteins we have used cadmium-113 as a solid state NMR probe of the Escherichia coli zinc exporter ZitB present in native membrane preparations. Competition experiments with other metal ions indicated that nickel and copper are also able to bind to this protein. Metal ion uptake studies were also performed using ZitB-reconstituted into proteoliposomes for a well established fluorescence assay. The results of both the solid state NMR and the uptake studies demonstrate that ZitB is potentially capable of transporting not only zinc but also cadmium, nickel and copper. The solid state NMR approach therefore offers great potential for defining the substrate spectrum of metal ion transporter proteins in their native membrane environments. Further, it should be useful for functional dissection of transporter mechanisms by facilitating the identification of functional residues by mutational studies.     

Vacuolar transporters and their essential role in plant metabolism

Following the unequivocal demonstration that plants contain at least two types of vacuoles, scientists studying this organelle have realized that the plant 'vacuome' is far more complex than they expected. Some fully developed cells contain at least two large vacuoles, with different functions. Remarkably, even a single vacuole may be subdivided and fulfil several functions, which are supported in part by the vacuolar membrane transport systems. Recent studies, including proteomic analyses for several plant species, have revealed the tonoplast transporters and their involvement in the nitrogen storage, salinity tolerance, heavy metal homeostasis, calcium signalling, guard cell movements, and the cellular pH homeostasis. It is clear that vacuolar transporters are an integrated part of a complex cellular network that enables a plant to react properly to changing environmental conditions, to save nutrients and energy in times of plenty, and to maintain optimal metabolic conditions in the cytosol. An overview is given of the main features of the transporters present in the tonoplast of plant cells in terms of their function, regulation, and relationships with the microheterogeneity of the vacuome.     

Transporters of ligands for essential metal ions in plants

Essential metals are required for healthy plant growth but can be toxic when present in excess. Therefore plants have mechanisms of metal homeostasis which involve coordination of metal ion transporters for uptake, translocation and compartmentalization. However, very little metal in plants is thought to exist as free ions. A number of small, organic molecules have been implicated in metal ion homeostasis as metal ion ligands to facilitate uptake and transport of metal ions with low solubility and also as chelators implicated in sequestration for metal tolerance and storage. Ligands for a number of essential metals have been identified and proteins involved in the transport of these ligands and of metal-ligand complexes have been characterized. Here we review recent advances in understanding the role of mugineic acid, nicotianamine, organic acids (citrate and malate), histidine and phytate as ligands for iron (Fe), zinc (Zn), copper (Cu), manganese (Mn) and nickel (Ni) in plants, and the proteins identified as their transporters.     

Trace element nutrition of infants--molecular approaches.

Newborn infants are exposed to widely varying intakes of trace elements, but little is known about their ability to homeostatically adjust to these intakes. Recent discoveries of several metal ion transporters in the small intestine are likely to enhance our understanding of molecular mechanisms regulating trace element absorption. Iron absorption is regulated by divalent metal ion transporter 1 (DMT1) and ferroportin 1 (FPN1). Studies on human infants have shown that young infants cannot regulate iron absorption, whereas older infants can. Our studies on infant rat pups show that there is no regulation of DMT1 and FPN1 at young age, but that this develops at older age. These findings may explain adverse effects of iron supplementation on growth in young human infants. Zinc absorption in the small intestine is regulated by the transporters ZnT1, ZnT2, ZnT4 and Zip-4 and zinc status affects the expression of these transporters in an attempt to achieve zinc homeostasis. Copper absorption is regulated by the transporters Ctrl, Atp7A and Atp7B, and exposure to copper at early age affects the expression and cellular localization of these proteins, affecting copper uptake and transport. To date, most studies on homeostatic regulation of trace mineral absorption have been done in cell systems and animal models; further studies on human infants are needed. The consequences of trace element interactions during infancy also need to be investigated in more detail.     

PIC1, an ancient permease in Arabidopsis chloroplasts, mediates iron transport

In chloroplasts, the transition metals iron and copper play an essential role in photosynthetic electron transport and act as cofactors for superoxide dismutases. Iron is essential for chlorophyll biosynthesis, and ferritin clusters in plastids store iron during germination, development, and iron stress. Thus, plastidic homeostasis of transition metals, in particular of iron, is crucial for chloroplast as well as plant development. However, very little is known about iron uptake by chloroplasts. Arabidopsis thaliana PERMEASE IN CHLOROPLASTS1 (PIC1), identified in a screen for metal transporters in plastids, contains four predicted alpha-helices, is targeted to the inner envelope, and displays homology with cyanobacterial permease-like proteins. Knockout mutants of PIC1 grew only heterotrophically and were characterized by a chlorotic and dwarfish phenotype reminiscent of iron-deficient plants. Ultrastructural analysis of plastids revealed severely impaired chloroplast development and a striking increase in ferritin clusters. Besides upregulation of ferritin, pic1 mutants showed differential regulation of genes and proteins related to iron stress or transport, photosynthesis, and Fe-S cluster biogenesis. Furthermore, PIC1 and its cyanobacterial homolog mediated iron accumulation in an iron uptake-defective yeast mutant. These observations suggest that PIC1 functions in iron transport across the inner envelope of chloroplasts and hence in cellular metal homeostasis.     

Disruption of AtMRP4, a guard cell plasma membrane ABCC-type ABC transporter, leads to deregulation of stomatal opening and increased drought susceptibility

ATP-binding cassette (ABC) transporters are membrane proteins responsible for cellular detoxification processes in plants and animals. Recent evidence shows that this class of transporters may also be involved in many other cellular processes. Because of their homology with human multidrug resistance-associated proteins (MRP), cystic fibrosis transmembrane conductance regulator (CFTR) and sulfonylurea receptor (SUR), some plant ABC transporters have been implicated in the regulation of ion channel activities. This paper describes an investigation of the AtMRP4 gene and its role in stomatal regulation. Reporter gene studies showed that AtMRP4 is highly expressed in stomata and that the protein is localized to the plasma membrane. Stomatal aperture in three independent atmrp4 mutant alleles was larger than in wild-type plants, both in the light and in the dark, resulting in increased water loss but no change in the photosynthetic rate. In baker's yeast, AtMRP4 shows ATP-dependent, vanadate-sensitive transport of methotrexate (MTX), an antifolate and a substrate of mammalian MRPs. Treatment with MTX reduced stomatal opening in wild-type plants, but had no effect in atmrp4 mutants. These results indicate the involvement of AtMRP4 in the complex regulation of stomatal aperture.