Essential mitochondrial role in iron-sulfur cluster assembly of the cytoplasmic isopropylmalate isomerase Leu1 in Saccharomyces cerevisiae

Mitochondrial glutaredoxin Grx5 functions as a central hub for cellular iron-sulfur cluster assembly

Iron-sulfur (Fe-S) protein biogenesis in eukaryotes is mediated by two different machineries-one in the mitochondria and another in the cytoplasm. Glutaredoxin 5 (Grx5) is a component of the mitochondrial iron-sulfur cluster machinery. Here, we define the roles of Grx5 in maintaining overall mitochondrial/cellular Fe-S protein biogenesis, utilizing mitochondria and cytoplasm isolated from Saccharomyces cerevisiae cells. We previously demonstrated that isolated wild-type (WT) mitochondria themselves can synthesize new Fe-S clusters, but isolated WT cytoplasm alone cannot do so unless it is mixed with WT mitochondria. WT mitochondria generate an intermediate, called (Fe-S)int, that is exported to the cytoplasm and utilized for cytoplasmic Fe-S cluster assembly. We here show that mitochondria lacking endogenous Grx5 (Grx5↓) failed to synthesize Fe-S clusters for proteins within the organelle. Similarly, Grx5↓ mitochondria were unable to synthesize (Fe-S)int, as judged by their inability to promote Fe-S cluster biosynthesis in WT cytoplasm. Most importantly, purified Grx5 precursor protein, imported into isolated Grx5↓ mitochondria, rescued these Fe-S cluster synthesis/trafficking defects. Notably, mitochondria lacking immediate downstream components of the mitochondrial iron-sulfur cluster machinery (Isa1 or Isa2) could synthesize [2Fe-2S] but not [4Fe-4S] clusters within the organelle. Isa1↓ (or Isa2↓) mitochondria could still support Fe-S cluster biosynthesis in WT cytoplasm. These results provide evidence for Grx5 serving as a central hub for Fe-S cluster intermediate trafficking within mitochondria and export to the cytoplasm. Grx5 is conserved from yeast to humans, and deficiency or mutation causes fatal human diseases. Data as presented here will be informative for human physiology.

Converging Roles of the Metal Transporter SMF11 and the Ferric Reductase FRE1 in Iron Homeostasis of Candida albicans

Pathogenic fungi must appropriately sense the host availability of essential metals such as Fe. In Candida albicans and other yeasts, sensing of Fe involves mitochondrial Fe-S clusters. Yeast mutants for Fe-S cluster assembly sense Fe limitation even when Fe is abundant and hyperaccumulate Fe. We observe this same disrupted Fe sensing with C. albicans mutants of SMF11, a NRAMP transporter of divalent metals. Mutants of smf11 hyperaccumulate both Mn and Fe and the elevated Mn is secondary to Fe overload. As with Fe-S biogenesis mutants, smf11∆/∆ mutants show upregulation of ferric reductases that are normally repressed under high Fe, and Fe import is activated. However, unlike Fe-S biogenesis mutants, smf11∆/∆ mutants show no defects in mitochondrial Fe-S enzymes. Intriguingly, this exact condition of disrupted Fe sensing without inhibiting Fe-S clusters occurs with C. albicans fre1∆/∆ mutants encoding a ferric reductase. Mutants of fre1 and smf11 display similar perturbations in the cell wall, in filamentation and in the ROS burst of morphogenesis, a Fe-dependent process. As with FRE1, SMF11 is important for virulence in a mouse model for disseminated candidiasis. We propose a model in which FRE1 and SMF11 operate outside the mitochondrial Fe-S pathway to donate ferrous Fe for Fe sensing.

Mitochondrial acyl carrier protein, Acp1, required for iron-sulfur cluster assembly in mitochondria and cytoplasm in Saccharomyces cerevisiae

Mitochondria perform vital biosynthetic processes, including fatty acid synthesis and iron-sulfur (FeS) cluster biogenesis. In Saccharomyces cerevisiae mitochondria, the acyl carrier protein Acp1 participates in type II fatty acid synthesis, requiring a 4-phosphopantetheine (PP) prosthetic group. Acp1 also interacts with the mitochondrial FeS cluster assembly complex that contains the cysteine desulfurase Nfs1. Here we investigated the role of Acp1 in FeS cluster biogenesis in mitochondria and cytoplasm. In the Acp1-depleted (Acp1↓) cells, biogenesis of mitochondrial FeS proteins was impaired, likely due to greatly reduced Nfs1 protein and/or its persulfide-forming activity. Formation of cytoplasmic FeS proteins was also deficient, suggesting a disruption in generating the (Fe-S)int intermediate, that is exported from mitochondria and is subsequently utilized for cytoplasmic FeS cluster assembly. Iron homeostasis was perturbed, with enhanced iron uptake into the cells and accumulation of iron in mitochondria. The Δppt2 strain, lacking the mitochondrial ability to add PP to Acp1, phenocopied the Acp1↓ cells. These data suggest that the holo form of Acp1 with the PP-conjugated acyl chain is required for stability of the Nfs1 protein and/or stimulation of its persulfide-forming activity. Thus, mitochondria lacking Acp1 (or Ppt2) cannot support FeS cluster biogenesis in mitochondria or cytoplasm, leading to disrupted iron homeostasis.

Structural aspects of iron‑sulfur protein biogenesis: An NMR view

Over the last decade, structural aspects involving iron‑sulfur (Fe/S) protein biogenesis have played an increasingly important role in understanding the high mechanistic complexity of mitochondrial and cytosolic machineries maturing Fe/S proteins. In this respect, solution NMR has had a significant impact because of its ability to monitor transient protein-protein interactions, which are abundant in the networks of pathways leading to Fe/S cluster biosynthesis and transfer, as well as thanks to the developments of paramagnetic NMR in both terms of new methodologies and accurate data interpretation. Here, we review the use of solution NMR in characterizing the structural aspects of human Fe/S proteins and their interactions in the framework of Fe/S protein biogenesis. We will first present a summary of the recent advances that have been achieved by paramagnetic NMR and then we will focus our attention on the role of solution NMR in the field of human Fe/S protein biogenesis.

Mitochondria function in cytoplasmic FeS protein biogenesis

Iron‑sulfur (FeS) clusters are cofactors of numerous proteins involved in essential cellular functions including respiration, protein translation, DNA synthesis and repair, ribosome maturation, anti-viral responses, and isopropylmalate isomerase activity. Novel FeS proteins are still being discovered due to the widespread use of cryogenic electron microscopy (cryo-EM) and elegant genetic screens targeted at protein discovery. A complex sequence of biochemical reactions mediated by a conserved machinery controls biosynthesis of FeS clusters. In eukaryotes, a remarkable epistasis has been observed: the mitochondrial machinery, termed ISC (Iron-Sulfur Cluster), lies upstream of the cytoplasmic machinery, termed CIA (Cytoplasmic Iron‑sulfur protein Assembly). The basis for this arrangement is the production of a hitherto uncharacterized intermediate, termed X-S or (Fe-S)int, produced in mitochondria by the ISC machinery, exported by the mitochondrial ABC transporter Atm1 (ABCB7 in humans), and then utilized by the CIA machinery for the cytoplasmic/nuclear FeS cluster assembly. Genetic and biochemical findings supporting this sequence of events are herein presented. New structural views of the Atm1 transport phases are reviewed. The key compartmental roles of glutathione in cellular FeS cluster biogenesis are highlighted. Finally, data are presented showing that every one of the ten core components of the mitochondrial ISC machinery and Atm1, when mutated or depleted, displays similar phenotypes: mitochondrial and cytoplasmic FeS clusters are both rendered deficient, consistent with the epistasis noted above.

Requirements for the biogenesis of [2Fe-2S] proteins in the human and yeast cytosol

The biogenesis of iron-sulfur (Fe/S) proteins entails the synthesis and trafficking of Fe/S clusters, followed by their insertion into target apoproteins. In eukaryotes, the multiple steps of biogenesis are accomplished by complex protein machineries in both mitochondria and cytosol. The underlying biochemical pathways have been elucidated over the past decades, yet the mechanisms of cytosolic [2Fe-2S] protein assembly have remained ill-defined. Similarly, the precise site of glutathione (GSH) requirement in cytosolic and nuclear Fe/S protein biogenesis is unclear, as is the molecular role of the GSH-dependent cytosolic monothiol glutaredoxins (cGrxs). Here, we investigated these questions in human and yeast cells by various in vivo approaches. [2Fe-2S] cluster assembly of cytosolic target apoproteins required the mitochondrial ISC machinery, the mitochondrial transporter Atm1/ABCB7 and GSH, yet occurred independently of both the CIA system and cGrxs. This mechanism was strikingly different from the ISC-, Atm1/ABCB7-, GSH-, and CIA-dependent assembly of cytosolic-nuclear [4Fe-4S] proteins. One notable exception to this cytosolic [2Fe-2S] protein maturation pathway defined here was yeast Apd1 which used the CIA system via binding to the CIA targeting complex through its C-terminal tryptophan. cGrxs, although attributed as [2Fe-2S] cluster chaperones or trafficking proteins, were not essential in vivo for delivering [2Fe-2S] clusters to either CIA components or target apoproteins. Finally, the most critical GSH requirement was assigned to Atm1-dependent export, i.e. a step before GSH-dependent cGrxs function. Our findings extend the general model of eukaryotic Fe/S protein biogenesis by adding the molecular requirements for cytosolic [2Fe-2S] protein maturation.