Cytosolic Iron-sulfur Cluster Assembly Research Articles

Reactivating PTEN to impair glioma stem cells by inhibiting cytosolic iron-sulfur assembly.

Glioblastoma, the most lethal primary brain tumor, harbors glioma stem cells (GSCs) that not only initiate and maintain malignant phenotypes but also enhance therapeutic resistance. Although frequently mutated in glioblastomas, the function and regulation of PTEN in PTEN-intact GSCs are unknown. Here, we found that PTEN directly interacted with MMS19 and competitively disrupted MMS19-based cytosolic iron-sulfur (Fe-S) cluster assembly (CIA) machinery in differentiated glioma cells. PTEN was specifically succinated at cysteine (C) 211 in GSCs compared with matched differentiated glioma cells. Isotope tracing coupled with mass spectrometry analysis confirmed that fumarate, generated by adenylosuccinate lyase (ADSL) in the de novo purine synthesis pathway that is highly activated in GSCs, promoted PTEN C211 succination. This modification abrogated the interaction between PTEN and MMS19, reactivating the CIA machinery pathway in GSCs. Functionally, inhibiting PTEN C211 succination by reexpressing a PTEN C211S mutant, depleting ADSL by shRNAs, or consuming fumarate by the US Food and Drug Administration-approved prescription drug N-acetylcysteine (NAC) impaired GSC maintenance. Reexpressing PTEN C211S or treating with NAC sensitized GSC-derived brain tumors to temozolomide and irradiation, the standard-of-care treatments for patients with glioblastoma, by slowing CIA machinery-mediated DNA damage repair. These findings reveal an immediately practicable strategy to target GSCs to treat glioblastoma by combination therapy with repurposed NAC.

Structural investigations of the cytosolic iron-sulfur cluster assembly pathway late acting proteins

Structural investigations of the cytosolic iron-sulfur cluster assembly pathway late acting proteins

Structural and biochemical investigations of a HEAT-repeat protein involved in the cytosolic iron-sulfur cluster assembly pathway

Iron-sulfur clusters are essential for life and defects in their biosynthesis lead to human diseases. The mechanism of cluster assembly and delivery to cytosolic and nuclear client proteins via the cytosolic iron-sulfur cluster assembly (CIA) pathway is not well understood. Here we report cryo-EM structures of the HEAT-repeat protein Met18 from Saccharomyces cerevisiae, a key component of the CIA targeting complex (CTC) that identifies cytosolic and nuclear client proteins and delivers a mature iron-sulfur cluster. We find that in the absence of other CTC proteins, Met18 adopts tetrameric and hexameric states. Using mass photometry and negative stain EM, we show that upon the addition of Cia2, these higher order oligomeric states of Met18 disassemble. We also use pulldown assays to identify residues of critical importance for Cia2 binding and recognition of the Leu1 client, many of which are buried when Met18 oligomerizes. Our structures show conformations of Met18 that have not been previously observed in any Met18 homolog, lending support to the idea that a highly flexible Met18 may be key to how the CTC is able to deliver iron-sulfur clusters to client proteins of various sizes and shapes, i.e. Met18 conforms to the dimensions needed.

NARFL deficiency caused mitochondrial dysfunction in lung cancer cells by HIF-1α–DNMT1 axis

NARFL was reported to be a component of cytosolic iron–sulfur cluster assembly pathway and a causative gene of the diffused pulmonary arteriovenous malformations (dPAVMs). NARFL knockout dramatically impaired mitochondrial integrity in mice, which might promote mitochondrial dysfunction and lead to worse survival rate of lung cancer. However, the underlying molecular mechanism of NARFL deficiency in non-small cell lung cancer (NSCLC) is unknown. Knockdown assay was performed in A549 and H1299 cells. The protein levels of HIF-1α and DNMT1 were measured, and then Complex I activity, mtDNA copy numbers and mRNA levels of mtND genes were determined. Cisplatin resistance and cell proliferation were conducted using CCK8 assay. Cell migration and invasion were detected using wound heal assay and transwell assay. Survival analysis of lung cancer patients and KM plotter database were used for evaluating the potential value of NARFL deficiency. NARFL protein was expressed in two cell lines and knockdown assay significantly reduced its levels. Knockdown NARFL increased the protein levels of HIF-1α and DNMT1, and downregulated the mRNA levels of ND genes, mitochondrial Complex I activity, mtDNA copy number, and ATP levels. The mitochondrial dysfunction caused by NARFL deficiency were ameliorated by siHIF-1α and DNMT1 inhibitor. Knockdown NARFL increased the drug resistance and cell migration, and siHIF-1α reversed this effect. Moreover, NSCLC patients with NARFL deficiency had a poor survival rate using a tissue array and KM plotter database, and it would be a target for cancer prognosis and treatment. NARFL deficiency caused dysregulation of energy metabolism in lung cancer cells via HIF-1α–DNMT1 axis, which promoted drug resistance and cell migration. It provided a potential target for treatment and prognosis of lung cancer.

Isolation and characterization of IbAE7-like 1 gene encoding the cytosolic iron-sulfur cluster assembly pathway in response to skinning injury in sweetpotato

Abstract. Effendy J. 2022. Isolation and characterization of IbAE7-like 1 gene encoding the cytosolic iron-sulfur cluster assembly pathway in response to skinning injury in sweetpotato. Biodiversitas 23: 4223-4233. Skinning injury is a major constrain in postharvest loss in sweetpotato due to the loss of skin from the surface of the roots. ASYMMETRIC LEAVES1/2 ENHANCER7(AE7) is an important cytosolic iron-sulfur (Fe-S) protein assembly (CIA) pathway. A partial cDNAIbI51 encoding AE7-like 1 was isolated from a skinning injury cDNA library to evaluate its potential role in response to skinning injury. The open reading frameof IbAE7-like 1 consisted of 324 nucleotides and the deduced polypeptide sequences consistedof 108 amino acids with missing 46 amino acid residues at 5? end. The amino acid sequence ofIbAE7-like 1 shared 100% identity toAE7-like 1 previously identified in Ipomoea triloba and Ipomoea nil and 89.91-100% identity from other plants species. The findings indicated that AE7-like 1 was highly conserved in Ipomoea sp. In addition to similarity to AE7-like 1, IbAE7-like 1 also showed similarities to MIP18 (89.91-93.52%); DUF59 (91.67%); FAM96B (90.74%); and proteins with unknown function (90.74-91.67%). IbAE7-like 1 mRNA transcripts showed transient expression in response to skinning injury. The phylogenetic analysis classified IbAE7-like 1 into three main classes. This study revealed IbAE7-like 1 may play a key role in plant defense and wound repair to prevent DNA damage due to skinning injuryin storage roots of sweetpotato.

Cryo‐EM Structural Determination of Met18, a Scaffold Protein for Iron‐Sulfur Protein Maturation

Iron‐sulfur ([Fe‐S]) clusters are essential cofactors for sustaining life. Because [Fe‐S] clusters play a role in a wide range of cellular processes, defects in their biosynthesis, trafficking, and incorporation into target proteins lead to human diseases. The molecular details of how iron‐sulfur clusters are assembled and transferred to their target proteins are not well understood. Therefore, the goal of this work is to structurally and biophysically characterize proteins involved in the Cytosolic Iron‐Sulfur Cluster Assembly (CIA) pathway. One of these proteins, Met18, is in the CIA targeting complex, and this complex is believed to receive a mature [4Fe‐4S] cluster and transfer it to target proteins downstream. To better understand its function, we determined a 3.3 Å resolution cryo‐EM structure of Met18. In the absence of other CIA targeting complex proteins and target proteins, we observed that Met18 forms a hexamer with its N‐terminus exposed and its C‐terminus buried. Conserved sequences within Met18 assist in forming the hexamer. Upon the addition of Cia2, a CIA targeting complex protein, the hexamer appears to be broken up. We hypothesize that the hexamer is a storage form of Met18 that protects itself from ubiquitination and proteosomal degradation. Here we present the cryo‐EM structure determination of the Met18 hexamer.

A VDAC1-mediated NEET protein chain transfers [2Fe-2S] clusters between the mitochondria and the cytosol and impacts mitochondrial dynamics

Mitochondrial inner NEET (MiNT) and the outer mitochondrial membrane (OMM) mitoNEET (mNT) proteins belong to the NEET protein family. This family plays a key role in mitochondrial labile iron and reactive oxygen species (ROS) homeostasis. NEET proteins contain labile [2Fe-2S] clusters which can be transferred to apo-acceptor proteins. In eukaryotes, the biogenesis of [2Fe-2S] clusters occurs within the mitochondria by the iron-sulfur cluster (ISC) system; the clusters are then transferred to [2Fe-2S] proteins within the mitochondria or exported to cytosolic proteins and the cytosolic iron-sulfur cluster assembly (CIA) system. The last step of export of the [2Fe-2S] is not yet fully characterized. Here we show that MiNT interacts with voltage-dependent anion channel 1 (VDAC1), a major OMM protein that connects the intermembrane space with the cytosol and participates in regulating the levels of different ions including mitochondrial labile iron (mLI). We further show that VDAC1 is mediating the interaction between MiNT and mNT, in which MiNT transfers its [2Fe-2S] clusters from inside the mitochondria to mNT that is facing the cytosol. This MiNT-VDAC1-mNT interaction is shown both experimentally and by computational calculations. Additionally, we show that modifying MiNT expression in breast cancer cells affects the dynamics of mitochondrial structure and morphology, mitochondrial function, and breast cancer tumor growth. Our findings reveal a pathway for the transfer of [2Fe-2S] clusters, which are assembled inside the mitochondria, to the cytosol.

Cryo-EM structural determination of Met18, a scaffold protein for iron-sulfur protein maturation

Iron-sulfur ([Fe-S]) clusters are essential cofactors for sustaining life. Because [Fe-S] clusters play a role in a wide range of cellular processes, defects in their biosynthesis, trafficking, and incorporation into target proteins lead to human diseases. The molecular details of how iron-sulfur clusters are assembled and transferred to their target proteins are not well understood. Therefore, the goal of this work is to structurally and biophysically characterize proteins involved in the Cytosolic Iron-Sulfur Cluster Assembly (CIA) pathway.

Sulfur Administration in Fe-S Cluster Homeostasis.

Mitochondria are the key organelles of Fe–S cluster synthesis. They contain the enzyme cysteine desulfurase, a scaffold protein, iron and electron donors, and specific chaperons all required for the formation of Fe–S clusters. The newly formed cluster can be utilized by mitochondrial Fe–S protein synthesis or undergo further transformation. Mitochondrial Fe–S cluster biogenesis components are required in the cytosolic iron–sulfur cluster assembly machinery for cytosolic and nuclear cluster supplies. Clusters that are the key components of Fe–S proteins are vulnerable and prone to degradation whenever exposed to oxidative stress. However, once degraded, the Fe–S cluster can be resynthesized or repaired. It has been proposed that sulfurtransferases, rhodanese, and 3-mercaptopyruvate sulfurtransferase, responsible for sulfur transfer from donor to nucleophilic acceptor, are involved in the Fe–S cluster formation, maturation, or reconstitution. In the present paper, we attempt to sum up our knowledge on the involvement of sulfurtransferases not only in sulfur administration but also in the Fe–S cluster formation in mammals and yeasts, and on reconstitution-damaged cluster or restoration of enzyme’s attenuated activity.

Evolution of the human mitochondrial ABCB7 [2Fe–2S](GS)4 cluster exporter and the molecular mechanism of an E433K disease-causing mutation

Iron-sulfur cluster proteins play key roles in a multitude of cellular processes. Iron-sulfur cofactors are assembled primarily in mitochondria and are then exported to the cytosol by use of an ABCB7 transporter. It has been shown that the yeast mitochondrial transporter Atm1 can export glutathione-coordinated iron-sulfur clusters, [2Fe–2S](SG)4, providing a source of cluster units for cytosolic iron-sulfur cluster assembly systems. This pathway is consistent with the endosymbiotic model of mitochondrial evolution where homologous bacterial heavy metal transporters, utilizing metal glutathione adducts, were adapted for use in eukaryotic mitochondria. Herein, the basis for endosymbiotic evolution of the human cluster export protein (ABCB7) is developed through a BLAST analysis of transporters from ancient proteobacteria. In addition, a functional comparison of native human protein, versus a disease-causing mutant, demonstrates a key role for residue E433 in promoting cluster transport. Dysfunction in mitochondrial export of Fe–S clusters is a likely cause of the disease condition X-linked sideroblastic anemia.

Defining the mechanism of the mitochondrial Atm1p [2Fe-2S] cluster exporter.

Iron-sulfur cluster proteins play key roles in a multitude of physiological processes; including gene expression, nitrogen and oxygen sensing, electron transfer, and DNA repair. Biosynthesis of iron-sulfur clusters occurs in mitochondria on iron-sulfur cluster scaffold proteins in the form of [2Fe-2S] cores that are then transferred to apo targets within metabolic or respiratory pathways. The mechanism by which cytosolic Fe-S cluster proteins mature to their holo forms remains controversial. The mitochondrial inner membrane protein Atm1p can transport glutathione-coordinated iron-sulfur clusters, which may connect the mitochondrial and cytosolic iron-sulfur cluster assembly systems. Herein we describe experiments on the yeast Atm1p/ABCB7 exporter that provide additional support for a glutathione-complexed cluster as the natural physiological substrate and a reflection of the endosymbiotic model of mitochondrial evolution. These studies provide insight on the mechanism of cluster transport and the molecular basis of human disease conditions related to ABCB7. Recruitment of MgATP following cluster binding promotes a structural transition from closed to open conformations that is mediated by coupling helices, with MgATP hydrolysis facilitating the return to the closed state.

CIAO3 protein forms a stable ternary complex with two key players of the human cytosolic iron-sulfur cluster assembly machinery.

The CIAO3 protein operates at a crossroad of the cytosolic iron-sulfur protein assembly (CIA) machinery. Although the functional role of CIAO3 has been recently characterized, a description of its interaction network is still not complete. Literature data suggested that CIAO3 interacts individually with CIA2A and CIAO1 protein, with the latter two interacting each other. However, no experimental data are available yet showing the formation of a possible ternary complex composed by CIAO3, CIAO1, and CIA2A. This work shows, for the first time, via size exclusion chromatography coupled with multiangle light scattering, UV-vis absorption and electron paramagnetic resonance (EPR) spectroscopies, the formation of a stable, [4Fe-4S]-bound, complex, composed by CIAO3 and the hetero-CIA2A-CIAO1 complex. Moreover, site-directed mutagenesis data suggested a structural role for the C-terminal [4Fe-4S] cluster of the CIAO3 protein. These findings can provide solid bases for further investigation of the molecular mechanisms involving these CIA machinery proteins.

Canonical cytosolic iron-sulfur cluster assembly and non-canonical functions of DRE2 in Arabidopsis.

As a component of the Cytosolic Iron-sulfur cluster Assembly (CIA) pathway, DRE2 is essential in organisms from yeast to mammals. However, the roles of DRE2 remain incompletely understood largely due to the lack of viable dre2 mutants. In this study, we successfully created hypomorphic dre2 mutants using the CRISPR/Cas9 technology. Like other CIA pathway mutants, the dre2 mutants have accumulation of DNA lesions and show constitutive DNA damage response. In addition, the dre2 mutants exhibit DNA hypermethylation at hundreds of loci. The mutant forms of DRE2 in the dre2 mutants, which bear deletions in the linker region of DRE2, lost interaction with GRXS17 but have stronger interaction with NBP35, resulting in the CIA-related defects of dre2. Interestingly, we find that DRE2 is also involved in auxin response that may be independent of its CIA role. DRE2 localizes in both the cytoplasm and the nucleus and nuclear DRE2 associates with euchromatin. Furthermore, DRE2 directly associates with multiple auxin responsive genes and maintains their normal expression. Our study highlights the importance of the linker region of DRE2 in coordinating CIA-related protein interactions and identifies the canonical and non-canonical roles of DRE2 in maintaining genome stability, epigenomic patterns, and auxin response.

Identifying the Binding Interface between Rad3 and the Cytosolic Iron Sulfur Cluster Assembly Targeting Complex

The Cytosolic Iron Sulfur Cluster Assembly (CIA) pathway is a highly conserved pathway that assembles and inserts iron sulfur (FeS) cluster cofactors into a variety of target proteins. These targets are involved in many cellular processes including DNA repair, iron homeostasis, and nucleotide metabolism. For CIA targets to receive the FeS cluster, they must be recruited for FeS cluster insertion by the CIA targeting complex. Although it is known that the targeting complex recognizes and binds to targets, the mechanisms of target recognition are not fully understood. In this work, mutagenesis and affinity co‐purification were utilized to elucidate the binding interface of Met18, a protein in the CIA targeting complex, and Rad3, a DNA helicase that receives an FeS cluster from the CIA pathway. Although this interaction has been investigated by other groups, there has been contradiction as to which portion of Rad3 binds to the targeting complex. Vashist et al. (J. Biol. Chem., 2012, 287, 43351) reported that the N‐terminus of Rad3 is responsible for binding to the targeting complex, while Ito et al. (Mol. Cell., 2010, 39, 632) reported that the C‐terminus of Rad3 is responsible for binding. To help resolve this discrepancy and gain insight into the targeting mechanism of the CIA targeting complex, truncated versions of Rad3 were expressed and isolated, and it was found that the N‐terminal region of the protein is responsible for binding to the targeting complex. Our current work involves investigating a 10 amino acid N‐terminal region of Rad3 identified by Vashist et al. Their group identified this region as participating in binding to Met18. In this work, we split the region into multiple alanine scans to further narrow down the Rad3‐Met18 binding interface. The identification of a region involved in Rad3‐Met18 binding could help define a target recognition motif for the CIA targeting complex.Support or Funding InformationBU Undergraduate Research Opportunities Program; NIH R01 GM121673This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Coupling Nucleotide Binding and Hydrolysis to Iron-Sulfur Cluster Acquisition and Transfer Revealed through Genetic Dissection of the Nbp35 ATPase Site.

The cytosolic iron-sulfur cluster assembly (CIA) scaffold, comprising Nbp35 and Cfd1 in yeast, assembles iron-sulfur (FeS) clusters destined for cytosolic and nuclear enzymes. ATP hydrolysis by the CIA scaffold plays an essential but poorly understood role in cluster biogenesis. Here we find that mutation of conserved residues in the four motifs comprising the ATPase site of Nbp35 diminished the scaffold's ability to both assemble and transfer its FeS cluster in vivo. The mutants fall into four phenotypic classes that can be understood by how each set of mutations affects ATP binding and hydrolysis. In vitro studies additionally revealed that occupancy of the bridging FeS cluster binding site decreases the scaffold's affinity for the nucleotide. On the basis of our findings, we propose that nucleotide binding and hydrolysis by the CIA scaffold drive a series of protein conformational changes that regulate association with other proteins in the pathway and with its newly formed FeS cluster. Our results provide insight into how the ATPase and cluster scaffolding activities are allosterically integrated.

The Cfd1 Subunit of the Nbp35-Cfd1 Iron Sulfur Cluster Scaffolding Complex Controls Nucleotide Binding.

The cytosolic iron sulfur cluster assembly (CIA) scaffold biosynthesizes iron sulfur cluster cofactors for enzymes residing in the cytosol and the nucleus. In fungi and animals, it comprises two homologous ATPases, called Nbp35 and Cfd1 in yeast, which can form homodimeric and heterodimeric complexes. Both proteins are required for CIA function, but their individual roles are not well understood. Here we investigate the nucleotide affinity of each form of the scaffold for ATP and ADP to reveal any differences that could shed light on the functions of the different oligomeric forms of the protein or any distinct roles of the individual subunits. All forms of the CIA scaffold are specific for adenosine nucleotides and not guanosine nucleotides. Although the Cfd1 homodimer has no detectable ATPase activity, it binds ATP with an affinity comparable to that of the hydrolysis competent forms, Nbp352 and Nbp35-Cfd1. Titrations to determine the number of nucleotide binding sites combined with site-directed mutagenesis demonstrate that the nucleotide must bind to the Cfd1 subunit of the heterodimer before it can bind to Nbp35 and that the Cfd1 subunit is hydrolysis competent when bound to Nbp35 in the heterodimer. Altogether, our work reveals the distinct roles of the Nbp35 and Cfd1 subunits in their heterodimeric complex. Cfd1 controls nucleotide binding, and the Nbp35 subunit is required to activate nucleotide hydrolysis.

Sensing Changes in Cellular Iron Metabolism: Regulation of IRP1 by FBXL5 and Cytosolic Iron‐Sulfur Cluster Assembly

Iron is a micronutrient essential for the viability of nearly all cells, but in excess, iron can overwhelm antioxidant defense mechanisms resulting in damage of cellular structures and cell death. Therefore, cellular iron levels must be maintained within narrow limits to prevent iron deficiency and iron toxicity. In order to maintain optimal iron levels, mammalian cells utilize Iron Regulatory Proteins (IRP). IRP1 and IRP2 are iron‐regulated RNA binding proteins that control the fate of mRNAs encoding proteins important for maintaining cellular iron homeostasis. For example, in iron replete cells IRP RNA binding is inactivated resulting in decreased iron uptake by transferrin receptor 1 and increased iron storage by ferritin. IRP1 RNA binding is inactivated primarily by the insertion of a [4Fe–4S] cluster by the cytosolic iron‐sulfur cluster assembly (CIA) system converting it into the cytosolic isoform of aconitase (c‐acon). IRP1 can also be inactivated by the iron‐dependent E3 ligase FBXL5 that also targets IRP2. Since, human diseases associated with impaired Fe‐S cluster assembly can disrupt cellular iron metabolism, we sought to understand the mechanism by which CIA and FBXL5 regulate IRP1. I will discuss a model for how CIA and FBXL5 collaborate to control the level of IRP1 RNA binding activity and optimize iron metabolism to meet cellular needs for proliferation.Support or Funding InformationThis work was supported by National Institutes of Health Grant RO1 DK66600, United States Department of Agriculture Hatch Project WIS01667, and the Iron Metabolism Research Fund.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Approaches to Interrogate the Role of Nucleotide Hydrolysis by Metal Trafficking NTPases: The Nbp35-Cfd1 Iron-Sulfur Cluster Scaffold as a Case Study.

Nucleotide hydrolases play integral yet poorly understood roles in several metallocluster biosynthetic pathways. For example, the cytosolic iron-sulfur cluster assembly (CIA) is initiated by the CIA scaffold, an ATPase which builds new iron-sulfur clusters for proteins localized to the cytosol and the nucleus in eukaryotic organisms. While in vivo studies have demonstrated the scaffold's nucleotide hydrolase domain is vital for its function, in vitro approaches have not revealed tight allosteric coupling between the cluster scaffolding site and the ATPase site. Thus, the role of ATP hydrolysis has been hard to pinpoint. Herein, we describe methods to probe the nucleotide affinity and hydrolysis activity of the CIA scaffold from yeast, which is comprised of two homologous polypeptides called Nbp35 and Cfd1. In particular, we report two different equilibrium binding assays that make use of commercially available fluorescent nucleotide analogs. Importantly, these assays can be applied to probe nucleotide affinity of both the apo- and holo-forms of the CIA scaffold. Generally, these fluorescent nucleotide analogs have been underutilized to probe metal trafficking NTPase because one of the most commonly used probes, mantATP, which is labeled with the methylanthraniloyl probe via the 2' or 3' sugar hydroxyls, has an absorption which overlaps with the UV-Vis features of many metal-binding proteins. However, by exploiting analogs like BODIPY-FL and trinitrophenyl-labeled nucleotides which have better photophysical properties for metalloprotein applications, these approaches have the potential to reveal the mechanistic underpinnings of NTPases required for metallocluster biosynthesis.

Cytosolic Iron-Sulfur Assembly Is Evolutionarily Tuned by a Cancer-Amplified Ubiquitin Ligase

The cytosolic iron-sulfur (Fe-S) cluster assembly (CIA) pathway functions to incorporate inorganic Fe-S cofactors into a variety of proteins, including several DNA repair enzymes. However, the mechanisms regulating the CIA pathway are unknown. We describe here that the MAGE-F1-NSE1 E3 ubiquitin ligase regulates the CIA pathway through ubiquitination and degradation of the CIA-targeting protein MMS19. Overexpression or knockout of MAGE-F1 altered Fe-S incorporation into MMS19-dependent DNA repair enzymes, DNA repair capacity, sensitivity to DNA-damaging agents, and iron homeostasis. Intriguingly, MAGE-F1 has undergone adaptive pseudogenization in select mammalian lineages. In contrast, MAGE-F1 is highly amplified in multiple human cancer types and amplified tumors have increased mutational burden. Thus, flux through the CIA pathway can be regulated by degradation of the substrate-specifying MMS19 protein and its downregulation is a common feature in cancer and is evolutionarily controlled.

A synergistic role of IRP1 and FBXL5 proteins in coordinating iron metabolism during cell proliferation

Iron-regulatory protein 1 (IRP1) belongs to a family of RNA-binding proteins that modulate metazoan iron metabolism. Multiple mechanisms are employed to control the action of IRP1 in dictating changes in the uptake and metabolic fate of iron. Inactivation of IRP1 RNA binding by iron primarily involves insertion of a [4Fe-4S] cluster by the cytosolic iron-sulfur cluster assembly (CIA) system, converting it into cytosolic aconitase (c-acon), but can also involve iron-mediated degradation of IRP1 by the E3 ligase FBXL5 that also targets IRP2. How CIA and FBXL5 collaborate to maintain cellular iron homeostasis through IRP1 and other pathways is poorly understood. Because impaired Fe-S cluster biogenesis associates with human disease, we determined the importance of FBXL5 for regulating IRP1 when CIA is impaired. Suppression of FBXL5 expression coupled with induction of an IRP1 mutant (IRP13C>3S) that cannot insert the Fe-S cluster, or along with knockdown of the CIA factors NUBP2 or FAM96A, reduced cell viability. Iron supplementation reversed this growth defect and was associated with FBXL5-dependent polyubiquitination of IRP1. Phosphorylation of IRP1 at Ser-138 increased when CIA was inhibited and was required for iron rescue. Impaired CIA activity, as noted by reduced c-acon activity, was associated with enhanced FBXL5 expression and a concomitant reduction in IRP1 and IRP2 protein level and RNA-binding activity. Conversely, expression of either IRP induced FBXL5 protein level, demonstrating a negative feedback loop limiting excessive accumulation of iron-response element RNA-binding activity, whose disruption reduces cell growth. We conclude that a regulatory circuit involving FBXL5 and CIA acts through both IRPs to control iron metabolism and promote optimal cell growth.