Your search keyword '"Iron-sulfur cluster biogenesis"' showing total 44 results

1. Defects in the Maturation of Mitochondrial Iron–Sulfur Proteins: Biophysical Investigation of the MMDS3 Causing Gly104Cys Variant of IBA57.

Author

Bargagna, Beatrice, Staderini, Tommaso, Lang, Steven H., Banci, Lucia, and Camponeschi, Francesca

Subjects

*GEL permeation chromatography, *MITOCHONDRIAL proteins, *FLUORESCENCE spectroscopy, *CIRCULAR dichroism, *LIGHT scattering

Abstract

Multiple mitochondrial dysfunctions syndrome type 3 (MMDS3) is a rare autosomal recessive mitochondrial leukoencephalopathy caused by biallelic pathogenic variants in the IBA57 gene. The gene protein product, IBA57, has an unknown role in iron–sulfur (Fe-S) cluster biogenesis but is required for the maturation of mitochondrial [4Fe-4S] proteins. To better understand the role of IBA57 in MMDS3, we have investigated the impact of the pathogenic p.Gly104Cys (c.310G > T) variant on the structural and functional properties of IBA57. The Gly104Cys variant has been associated with a severe MMDS3 phenotype in both compound heterozygous and homozygous states, and defects in the activity of mitochondrial respiratory complexes and lipoic acid-dependent enzymes have been demonstrated in the affected patients. Size exclusion chromatography, also coupled to multiple angle light scattering, NMR, circular dichroism, and fluorescence spectroscopy characterization has shown that the Gly104Cys variant does not impair the conversion of the homo-dimeric [2Fe-2S]–ISCA22 complex into the hetero-dimeric IBA57–[2Fe-2S]–ISCA2 but significantly affects the stability of IBA57, in both its isolated form and in complex with ISCA2, thus providing a rationale for the severe MMDS3 phenotype associated with this variant. [ABSTRACT FROM AUTHOR]

Published

2024

2. Considerations for Using Neuroblastoma Cell Lines to Examine the Roles of Iron and Ferroptosis in Neurodegeneration.

Author

Cardona, Cameron J., Kim, Yoo, Chowanadisai, Winyoo, and Montgomery, McKale R.

Subjects

*BRAIN degeneration, *APOPTOSIS, *ALZHEIMER'S disease, *IRON metabolism, *NEURONAL differentiation

Abstract

Ferroptosis is an iron-dependent form of programmed cell death that is influenced by biological processes such as iron metabolism and senescence. As brain iron levels increase with aging, ferroptosis is also implicated in the development of age-related pathologic conditions such as Alzheimer's disease (AD) and related dementias (ADRD). Indeed, inhibitors of ferroptosis have been shown to be protective in models of degenerative brain disorders like AD/ADRD. Given the inaccessibility of the living human brain for metabolic studies, the goal of this work was to characterize an in vitro model for understanding how aging and iron availability influence neuronal iron metabolism and ferroptosis. First, the human (SH-SY5Y) and mouse (Neuro-2a) neuroblastoma lines were terminally differentiated into mature neurons by culturing in all-trans-retinoic acid for at least 72 h. Despite demonstrating all signs of neuronal differentiation and maturation, including increased expression of the iron storage protein ferritin, we discovered that differentiation conferred ferroptosis resistance in both cell lines. Gene expression data indicates differentiated neurons increase their capacity to protect against iron-mediated oxidative damage by augmenting cystine import, and subsequently increasing intracellular cysteine levels, to promote glutathione production and glutathione peroxidase activity (GPX). In support of this hypothesis, we found that culturing differentiated neurons in cysteine-depleted media sensitized them to GPX4 inhibition, and that these effects are mitigated by cystine supplementation. Such findings are important as they provide guidance for the use of in vitro experimental models to investigate the role of ferroptosis in neurodegeneration in pathologies such as ADRD. [ABSTRACT FROM AUTHOR]

Published

2024

3. Downregulation of Iron–Sulfur Cluster Biogenesis May Contribute to Hyperglycemia-Mediated Diabetic Peripheral Neuropathy in Murine Models.

Author

Wu, Lin, Huang, Fei, Sun, Zichen, Zhang, Jinghua, Xia, Siyu, Zhao, Hongting, Liu, Yutong, Yang, Lu, Ding, Yibing, Bian, Dezhi, Li, Kuanyu, and Sun, Yu

Subjects

SCIATIC nerve injuries, PERIPHERAL nerve injuries, DIABETIC neuropathies, ANIMAL behavior, SCAFFOLD proteins

Abstract

Background: Diabetic peripheral neuropathy (DPN) is considered one of the most common chronic complications of diabetes. Impairment of mitochondrial function is regarded as one of the causes. Iron–sulfur clusters are essential cofactors for numerous iron–sulfur (Fe-S)-containing proteins/enzymes, including mitochondrial electron transport chain complex I, II, and III and aconitase. Methods: To determine the impact of hyperglycemia on peripheral nerves, we used Schwann-like RSC96 cells and classical db/db mice to detect the expression of Fe-S-related proteins, mitochondrially enzymatic activities, and iron metabolism. Subsequently, we treated high-glucose-induced RSC96 cells and db/db mice with pioglitazone (PGZ), respectively, to evaluate the effects on Fe-S cluster biogenesis, mitochondrial function, and animal behavior. Results: We found that the core components of Fe-S biogenesis machinery, such as frataxin (Fxn) and scaffold protein IscU, significantly decreased in high-glucose-induced RSC96 cells and db/db mice, accompanied by compromised mitochondrial Fe-S-containing enzymatic activities, such as complex I and II and aconitase. Consequently, oxidative stress and inflammation increased. PGZ not only has antidiabetic effects but also increases the expression of Fxn and IscU to enhance mitochondrial function in RSC96 cells and db/db mice. Meanwhile, PGZ significantly alleviated sciatic nerve injury and improved peripheral neuronal behavior, accompanied by suppressed oxidative stress and inflammation in the sciatic nerve of the db/db mice. Conclusions: Iron–sulfur cluster deficiency may contribute to hyperglycemia-mediated DPN. [ABSTRACT FROM AUTHOR]

Published

2024

4. Downregulation of Iron–Sulfur Cluster Biogenesis May Contribute to Hyperglycemia-Mediated Diabetic Peripheral Neuropathy in Murine Models

Author

Lin Wu, Fei Huang, Zichen Sun, Jinghua Zhang, Siyu Xia, Hongting Zhao, Yutong Liu, Lu Yang, Yibing Ding, Dezhi Bian, Kuanyu Li, and Yu Sun

Subjects

iron–sulfur cluster biogenesis, frataxin, IscU, DPN, inflammation, Therapeutics. Pharmacology, RM1-950

Abstract

Background: Diabetic peripheral neuropathy (DPN) is considered one of the most common chronic complications of diabetes. Impairment of mitochondrial function is regarded as one of the causes. Iron–sulfur clusters are essential cofactors for numerous iron–sulfur (Fe-S)-containing proteins/enzymes, including mitochondrial electron transport chain complex I, II, and III and aconitase. Methods: To determine the impact of hyperglycemia on peripheral nerves, we used Schwann-like RSC96 cells and classical db/db mice to detect the expression of Fe-S-related proteins, mitochondrially enzymatic activities, and iron metabolism. Subsequently, we treated high-glucose-induced RSC96 cells and db/db mice with pioglitazone (PGZ), respectively, to evaluate the effects on Fe-S cluster biogenesis, mitochondrial function, and animal behavior. Results: We found that the core components of Fe-S biogenesis machinery, such as frataxin (Fxn) and scaffold protein IscU, significantly decreased in high-glucose-induced RSC96 cells and db/db mice, accompanied by compromised mitochondrial Fe-S-containing enzymatic activities, such as complex I and II and aconitase. Consequently, oxidative stress and inflammation increased. PGZ not only has antidiabetic effects but also increases the expression of Fxn and IscU to enhance mitochondrial function in RSC96 cells and db/db mice. Meanwhile, PGZ significantly alleviated sciatic nerve injury and improved peripheral neuronal behavior, accompanied by suppressed oxidative stress and inflammation in the sciatic nerve of the db/db mice. Conclusions: Iron–sulfur cluster deficiency may contribute to hyperglycemia-mediated DPN.

Published

2024

5. Tip of the Iceberg: A New Wave of Iron–Sulfur Cluster Proteins Found in Viruses.

Author

Heffner, Audrey L. and Maio, Nunziata

Subjects

*IRON-sulfur proteins, *VIRAL proteins, *IRON, *BACTERIAL diseases, *VIRUS diseases, *CELL survival, *SULFUR bacteria

Abstract

Viruses rely on host cells to replicate their genomes and assemble new viral particles. Thus, they have evolved intricate mechanisms to exploit host factors. Host cells, in turn, have developed strategies to inhibit viruses, resulting in a nuanced interplay of co-evolution between virus and host. This dynamic often involves competition for resources crucial for both host cell survival and virus replication. Iron and iron-containing cofactors, including iron–sulfur clusters, are known to be a heavily fought for resource during bacterial infections, where control over iron can tug the war in favor of the pathogen or the host. It is logical to assume that viruses also engage in this competition. Surprisingly, our knowledge about how viruses utilize iron (Fe) and iron–sulfur (FeS) clusters remains limited. The handful of reviews on this topic primarily emphasize the significance of iron in supporting the host immune response against viral infections. The aim of this review, however, is to organize our current understanding of how viral proteins utilize FeS clusters, to give perspectives on what questions to ask next and to propose important avenues for future investigations. [ABSTRACT FROM AUTHOR]

Published

2024

6. Understanding the Molecular Basis of the Multiple Mitochondrial Dysfunctions Syndrome 2: The Disease-Causing His96Arg Mutation of BOLA3.

Author

Bargagna, Beatrice, Banci, Lucia, and Camponeschi, Francesca

Subjects

*MITOCHONDRIAL membranes, *GEL permeation chromatography, *MITOCHONDRIA, *ELECTRON paramagnetic resonance spectroscopy, *GENETIC mutation, *MITOCHONDRIAL pathology

Abstract

Multiple mitochondrial dysfunctions syndrome type 2 with hyperglycinemia (MMDS2) is a severe disorder of mitochondrial energy metabolism, associated with biallelic mutations in the gene encoding for BOLA3, a protein with a not yet completely understood role in iron-sulfur (Fe-S) cluster biogenesis, but essential for the maturation of mitochondrial [4Fe-4S] proteins. To better understand the role of BOLA3 in MMDS2, we have investigated the impact of the p.His96Arg (c.287A > G) point mutation, which involves a highly conserved residue, previously identified as a [2Fe-2S] cluster ligand in the BOLA3-[2Fe-2S]-GLRX5 heterocomplex, on the structural and functional properties of BOLA3 protein. The His96Arg mutation has been associated with a severe MMDS2 phenotype, characterized by defects in the activity of mitochondrial respiratory complexes and lipoic acid-dependent enzymes. Size exclusion chromatography, NMR, UV-visible, circular dichroism, and EPR spectroscopy characterization have shown that the His96Arg mutation does not impair the interaction of BOLA3 with its protein partner GLRX5, but leads to the formation of an aberrant BOLA3-[2Fe-2S]-GLRX5 heterocomplex, that is not functional anymore in the assembly of a [4Fe-4S] cluster on NFU1. These results allowed us to rationalize the severe phenotype observed in MMDS2 caused by His96Arg mutation. [ABSTRACT FROM AUTHOR]

Published

2023

7. Iron regulatory proteins: players or pawns in ferroptosis and cancer?

Author

Cameron J. Cardona and McKale R. Montgomery

Subjects

iron homeostasis, cancer, iron-sulfur cluster biogenesis, programmed cell death, reactive oxygen species, lipid peroxidation, Biology (General), QH301-705.5

Abstract

Cells require iron for essential functions like energy production and signaling. However, iron can also engage in free radical formation and promote cell proliferation thereby contributing to both tumor initiation and growth. Thus, the amount of iron within the body and in individual cells is tightly regulated. At the cellular level, iron homeostasis is maintained post-transcriptionally by iron regulatory proteins (IRPs). Ferroptosis is an iron-dependent form of programmed cell death with vast chemotherapeutic potential, yet while IRP-dependent targets have established roles in ferroptosis, our understanding of the contributions of IRPs themselves is still in its infancy. In this review, we present the growing circumstantial evidence suggesting that IRPs play critical roles in the adaptive response to ferroptosis and ferroptotic cell death and describe how this knowledge can be leveraged to target neoplastic iron dysregulation more effectively.

Published

2023

8. Synergy of native mass spectrometry and other biophysical techniques in studies of iron‑sulfur cluster proteins and their assembly.

Author

Crack, Jason C. and Le Brun, Nick E.

Subjects

*BIOCHEMISTRY, *MASS spectrometry, *METALLOPROTEINS, *NITRIC oxide, *MACROMOLECULES

Abstract

The application of mass spectrometric methodologies has revolutionised biological chemistry, from identification through to structural and conformational studies of proteins and other macromolecules. Native mass spectrometry (MS), in which proteins retain their native structure, is a rapidly growing field. This is particularly the case for studies of metalloproteins, where non-covalently bound cofactors remain bound following ionisation. Such metalloproteins include those that contain an iron‑sulfur (Fe S) cluster and, despite their fragility and O 2 sensitivity, they have been a particular focus for applications of native MS because of its capacity to accurately monitor mass changes that reveal chemical changes at the cluster. Here we review recent advances in these applications of native MS, which, together with data from more traditionally applied biophysical methods, have yielded a remarkable breadth of information about the Fe S species present, and provided key mechanistic insight not only for Fe S cluster proteins themselves, but also their assembly. • Iron-sulfur (Fe S) clusters are widely distributed in life and functionally diverse. • Fe S clusters are ideally suited to act as sensors of environment change. • Use of native mass spectrometry (MS) in studies of Fe S proteins is growing. • Native MS is highly complementary to more traditional biophysical methods. • Native MS has provided novel insight into Fe S cluster chemistry. [ABSTRACT FROM AUTHOR]

Published

2025

9. The Intriguing mitoNEET: Functional and Spectroscopic Properties of a Unique [2Fe-2S] Cluster Coordination Geometry.

Author

Camponeschi, Francesca, Piccioli, Mario, and Banci, Lucia

Subjects

*CANCER cell proliferation, *MOLECULAR recognition, *DNA fingerprinting, *INHIBITION of cellular proliferation, *OXIDATION-reduction reaction, *DRUG design, *CELL physiology

Abstract

Despite the number of cellular and pathological mitoNEET-related processes, very few details are known about the mechanism of action of the protein. The recently discovered existence of a link between NEET proteins and cancer pave the way to consider mitoNEET and its Fe-S clusters as suitable targets to inhibit cancer cell proliferation. Here, we will review the variety of spectroscopic techniques that have been applied to study mitoNEET in an attempt to explain the drastic difference in clusters stability and reactivity observed for the two redox states, and to elucidate the cellular function of the protein. In particular, the extensive NMR assignment and the characterization of first coordination sphere provide a molecular fingerprint helpful to assist the design of drugs able to impair cellular processes or to directly participate in redox reactions or protein–protein recognition mechanisms. [ABSTRACT FROM AUTHOR]

Published

2022

10. Towards a metabolomic approach to investigate iron–sulfur cluster biogenesis.

Author

Marengo, Mauro, Fissore, Alex, Oliaro‐Bosso, Simonetta, Adinolfi, Salvatore, and Pastore, Annalisa

Subjects

*SCAFFOLD proteins, *FRIEDREICH'S ataxia, *FRATAXIN, *IRON, *SIMPLE machines, *METABOLOMICS

Abstract

Iron–sulfur clusters are prosthetic groups that are assembled on their acceptor proteins through a complex machine centered on a desulfurase enzyme and a transient scaffold protein. Studies to establish the mechanism of cluster formation have so far used either in vitro or in vivo methods, which have often resulted in contrasting or non‐comparable results. We suggest, here, an alternative approach to study the enzymatic reaction, that is based on the combination of genetically engineered bacterial strains depleted of specific components, and the detection of the enzymatic kinetics in cellular extracts through metabolomics. Our data prove that this ex vivo approach closely reproduces the in vitro results while retaining the full complexity of the system. We demonstrate that co‐presence of bacterial frataxin and iron is necessary to observe an inhibitory effect of the enzymatic activity of bacterial frataxin. Our approach provides a new powerful tool for the study of iron–sulfur cluster biogenesis. [ABSTRACT FROM AUTHOR]

Published

2022

11. Iron Pathophysiology in Friedreich’s Ataxia

Author

Li, Kuanyu, COHEN, IRUN R., Editorial Board Member, LAJTHA, ABEL, Editorial Board Member, LAMBRIS, JOHN D., Editorial Board Member, PAOLETTI, RODOLFO, Editorial Board Member, REZAEI, NIMA, Editorial Board Member, and Chang, Yan-Zhong, editor

Published

2019

12. Mitochondrial iron metabolism and its role in diseases.

Author

Gao, Jiayin, Zhou, Qionglin, Wu, Di, and Chen, Linxi

Subjects

*IRON metabolism, *MITOCHONDRIA, *NEURODEGENERATION, *ENERGY policy, *PLANT mitochondria, *HEME, *FERRITIN

Abstract

• The well-defined molecular mechanisms of cellular iron uptake, metabolism and homeostasis. • Iron may be imported from the cytoplasm to mitochondria by three potential mechanisms. • The utilization of iron by mitochondria mainly involves in three important metabolic pathways. • Perturbed mitochondrial iron metabolism is involved in neurodegenerative disorders and sideroblastic anemia. Iron is one of the most important elements for life, but excess iron is toxic. Intracellularly, mitochondria are the center of iron utilization requiring sufficient amounts to maintain normal physiologic function. Accordingly, disruption of iron homeostasis could seriously impact mitochondrial function leading to impaired energy state and potential disease development. In this review, we discuss mechanisms of iron metabolism including transport, processing, heme synthesis, iron-sulfur cluster biogenesis and storage. We highlight the vital role of mitochondrial iron in pathologic states including neurodegenerative disorders and sideroblastic anemia. [ABSTRACT FROM AUTHOR]

Published

2021

13. Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein-Protein Interactions of Metalloproteins: The Case of Iron-Sulfur Proteins.

Author

Piccioli, Mario

Subjects

PROTEIN-protein interactions, METALLOPROTEINS, IRON-sulfur compounds, NUCLEAR magnetic resonance, ELECTRONIC structure

Abstract

The study of cellular machineries responsible for the iron-sulfur (Fe-S) cluster biogenesis has led to the identification of a large number of proteins, whose importance for life is documented by an increasing number of diseases linked to them. The labile nature of Fe-S clusters and the transient protein-protein interactions, occurring during the various steps of the maturation process, make their structural characterization in solution particularly difficult. Paramagnetic nuclear magnetic resonance (NMR) has been used for decades to characterize chemical composition, magnetic coupling, and the electronic structure of Fe-S clusters in proteins; it represents, therefore, a powerful tool to study the protein-protein interaction networks of proteins involving into iron-sulfur cluster biogenesis. The optimization of the various NMR experiments with respect to the hyperfine interaction will be summarized here in the form of a protocol; recently developed experiments for measuring longitudinal and transverse nuclear relaxation rates in highly paramagnetic systems will be also reviewed. Finally, we will address the use of extrinsic paramagnetic centers covalently bound to diamagnetic proteins, which contributed over the last twenty years to promote the applications of paramagnetic NMR well beyond the structural biology of metalloproteins. [ABSTRACT FROM AUTHOR]

Published

2020

14. Iron–Sulfur Cluster Biogenesis as a Critical Target in Cancer

Author

Michael S. Petronek, Douglas R. Spitz, and Bryan G. Allen

Subjects

iron–sulfur cluster biogenesis, iron metabolism, carcinogenesis, cancer therapy, Therapeutics. Pharmacology, RM1-950

Abstract

Cancer cells preferentially accumulate iron (Fe) relative to non-malignant cells; however, the underlying rationale remains elusive. Iron–sulfur (Fe–S) clusters are critical cofactors that aid in a wide variety of cellular functions (e.g., DNA metabolism and electron transport). In this article, we theorize that a differential need for Fe–S biogenesis in tumor versus non-malignant cells underlies the Fe-dependent cell growth demand of cancer cells to promote cell division and survival by promoting genomic stability via Fe–S containing DNA metabolic enzymes. In this review, we outline the complex Fe–S biogenesis process and its potential upregulation in cancer. We also discuss three therapeutic strategies to target Fe–S biogenesis: (i) redox manipulation, (ii) Fe chelation, and (iii) Fe mimicry.

Published

2021

15. Iron-sulfur cluster assembly scaffold protein IscU is required for activation of ferric uptake regulator (Fur) in Escherichiacoli.

Author

Purcell AG, Fontenot CR, and Ding H

Subjects

Iron-Sulfur Proteins metabolism, Iron-Sulfur Proteins genetics, Escherichia coli Proteins metabolism, Escherichia coli Proteins genetics, Escherichia coli metabolism, Escherichia coli genetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Repressor Proteins metabolism, Repressor Proteins genetics, Iron metabolism

Abstract

It was generally postulated that when intracellular free iron content is elevated in bacteria, the ferric uptake regulator (Fur) binds its corepressor a mononuclear ferrous iron to regulate intracellular iron homeostasis. However, the proposed iron-bound Fur had not been identified in any bacteria. In previous studies, we have demonstrated that Escherichia coli Fur binds a [2Fe-2S] cluster in response to elevation of intracellular free iron content and that binding of the [2Fe-2S] cluster turns on Fur as an active repressor to bind a specific DNA sequence known as the Fur-box. Here we find that the iron-sulfur cluster assembly scaffold protein IscU is required for the [2Fe-2S] cluster assembly in Fur, as deletion of IscU inhibits the [2Fe-2S] cluster assembly in Fur and prevents activation of Fur as a repressor in E. coli cells in response to elevation of intracellular free iron content. Additional studies reveal that IscU promotes the [2Fe-2S] cluster assembly in apo-form Fur and restores its Fur-box binding activity in vitro. While IscU is also required for the [2Fe-2S] cluster assembly in the Haemophilus influenzae Fur in E. coli cells, deletion of IscU does not significantly affect the [2Fe-2S] cluster assembly in the E. coli ferredoxin and siderophore-reductase FhuF. Our results suggest that IscU may have a unique role for the [2Fe-2S] cluster assembly in Fur and that regulation of intracellular iron homeostasis is closely coupled with iron-sulfur cluster biogenesis in E. coli., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

16. Paramagnetic NMR Spectroscopy Is a Tool to Address Reactivity, Structure, and Protein–Protein Interactions of Metalloproteins: The Case of Iron–Sulfur Proteins

Author

Mario Piccioli

Subjects

iron–sulfur proteins, paramagnetic NMR, iron–sulfur cluster biogenesis, solution structures, metalloproteins, Chemistry, QD1-999

Abstract

The study of cellular machineries responsible for the iron–sulfur (Fe–S) cluster biogenesis has led to the identification of a large number of proteins, whose importance for life is documented by an increasing number of diseases linked to them. The labile nature of Fe–S clusters and the transient protein–protein interactions, occurring during the various steps of the maturation process, make their structural characterization in solution particularly difficult. Paramagnetic nuclear magnetic resonance (NMR) has been used for decades to characterize chemical composition, magnetic coupling, and the electronic structure of Fe–S clusters in proteins; it represents, therefore, a powerful tool to study the protein–protein interaction networks of proteins involving into iron–sulfur cluster biogenesis. The optimization of the various NMR experiments with respect to the hyperfine interaction will be summarized here in the form of a protocol; recently developed experiments for measuring longitudinal and transverse nuclear relaxation rates in highly paramagnetic systems will be also reviewed. Finally, we will address the use of extrinsic paramagnetic centers covalently bound to diamagnetic proteins, which contributed over the last twenty years to promote the applications of paramagnetic NMR well beyond the structural biology of metalloproteins.

Published

2020

17. NMR as a Tool to Investigate the Processes of Mitochondrial and Cytosolic Iron-Sulfur Cluster Biosynthesis.

Author

Kai Cai and Markley, John L.

Subjects

*BIOSYNTHESIS, *ANTIBIOTICS, *PROTEINS, *COFACTORS (Biochemistry), *NUCLEAR magnetic resonance

Abstract

Iron-sulfur (Fe-S) clusters, the ubiquitous protein cofactors found in all kingdoms of life, perform a myriad of functions including nitrogen fixation, ribosome assembly, DNA repair, mitochondrial respiration, and metabolite catabolism. The biogenesis of Fe-S clusters is a multi-step process that involves the participation of many protein partners. Recent biophysical studies, involving X-ray crystallography, nuclear magnetic resonance (NMR) spectroscopy, mass spectrometry (MS), and small angle X-ray scattering (SAXS), have greatly improved our understanding of these steps. In this review, after describing the biological importance of iron sulfur proteins, we focus on the contributions of NMR spectroscopy has made to our understanding of the structures, dynamics, and interactions of proteins involved in the biosynthesis of Fe-S cluster proteins. [ABSTRACT FROM AUTHOR]

Published

2018

18. New Techniques for Ancient Proteins: Direct Coupling Analysis Applied on Proteins Involved in Iron Sulfur Cluster Biogenesis

Author

Marco Fantini, Duccio Malinverni, Paolo De Los Rios, and Annalisa Pastore

Subjects

co-evolution, computational methods, direct coupling analysis, iron-sulfur cluster biogenesis, molecular machines, protein folding, Biology (General), QH301-705.5

Abstract

Direct coupling analysis (DCA) is a powerful statistical inference tool used to study protein evolution. It was introduced to predict protein folds and protein-protein interactions, and has also been applied to the prediction of entire interactomes. Here, we have used it to analyze three proteins of the iron-sulfur biogenesis machine, an essential metabolic pathway conserved in all organisms. We show that DCA can correctly reproduce structural features of the CyaY/frataxin family (a protein involved in the human disease Friedreich's ataxia) despite being based on the relatively small number of sequences allowed by its genomic distribution. This result gives us confidence in the method. Its application to the iron-sulfur cluster scaffold protein IscU, which has been suggested to function both as an ordered and a disordered form, allows us to distinguish evolutionary traces of the structured species, suggesting that, if present in the cell, the disordered form has not left evolutionary imprinting. We observe instead, for the first time, direct indications of how the protein can dimerize head-to-head and bind 4Fe4S clusters. Analysis of the alternative scaffold protein IscA provides strong support to a coordination of the cluster by a dimeric form rather than a tetramer, as previously suggested. Our analysis also suggests the presence in solution of a mixture of monomeric and dimeric species, and guides us to the prevalent one. Finally, we used DCA to analyze interactions between some of these proteins, and discuss the potentials and limitations of the method.

Published

2017

19. Anaerobic Copper Toxicity and Iron-Sulfur Cluster Biogenesis in Escherichia coli.

Author

Guoqiang Tan, Jing Yang, Tang Li, Jin Zhao, Shujuan Sun, Xiaokang Li, Chuxian Lin, Jianghui Li, Huaibin Zhou, Jianxin Lyu, and Huangen Ding

Subjects

*COPPER poisoning, *IRON-sulfur proteins, *ESCHERICHIA coli, *GROUNDWATER pollution, *ORGANELLE formation

Abstract

While copper is an essential trace element in biology, pollution of groundwater from copper has become a threat to all living organisms. Cellular mechanisms underlying copper toxicity, however, are still not fully understood. Previous studies have shown that iron-sulfur proteins are among the primary targets of copper toxicity in Escherichia coli under aerobic conditions. Here, we report that, under anaerobic conditions, iron-sulfur proteins in E. coli cells are even more susceptible to copper in medium. Whereas addition of 0.2 mM copper(II) chloride to LB (Luria-Bertani) medium has very little or no effect on iron-sulfur proteins in wild-type E. coli cells under aerobic conditions, the same copper treatment largely inactivates iron-sulfur proteins by blocking iron-sulfur cluster biogenesis in the cells under anaerobic conditions. Importantly, proteins that do not have iron-sulfur clusters (e.g., fumarase C and cysteine desulfurase) in E. coli cells are not significantly affected by copper treatment under aerobic or anaerobic conditions, indicating that copper may specifically target iron-sulfur proteins in cells. Additional studies revealed that E. coli cells accumulate more intracellular copper under anaerobic conditions than under aerobic conditions and that the elevated copper content binds to the iron-sulfur cluster assembly proteins IscU and IscA, which effectively inhibits iron-sulfur cluster biogenesis. The results suggest that the copper-mediated inhibition of iron-sulfur proteins does not require oxygen and that iron-sulfur cluster biogenesis is the primary target of anaerobic copper toxicity in cells. IMPORTANCE Copper contamination in groundwater has become a threat to all living organisms. However, cellular mechanisms underlying copper toxicity have not been fully understood up to now. The work described here reveals that iron-sulfur proteins in Escherichia coli cells are much more susceptible to copper in medium under anaerobic conditions than they are under aerobic conditions. Under anaerobic conditions, E. coli cells accumulate excess intracellular copper, which specifically targets iron-sulfur proteins by blocking iron-sulfur cluster biogenesis. Since iron-sulfur proteins are involved in diverse and vital physiological processes, inhibition of ironsulfur cluster biogenesis by copper disrupts multiple cellular functions and ultimately inhibits cell growth. The results from this study illustrate a new interplay between intracellular copper toxicity and iron-sulfur cluster biogenesis in bacterial cells under anaerobic conditions. [ABSTRACT FROM AUTHOR]

Published

2017

20. Plasmodium Iron-Sulfur [Fe-S] cluster assembly protein Dre2 as a plausible target of Artemisinin: Mechanistic insights derived in a prokaryotic heterologous system.

Author

Kirtikumar Bub, Nidhi, Anand, Sakshi, Garg, Swati, Saxena, Vishal, Khanna, Dhanabala Subhiksha Rajesh, Agarwal, Deeptanshu, Kochar, Sanjay Kumar, Singh, Shailja, and Garg, Shilpi

Subjects

*ARTEMISININ, *ESCHERICHIA coli, *GENETIC regulation, *IRON clusters, *REACTIVE oxygen species, *PLASMODIUM

Abstract

[Display omitted] • Dre2, a Fe-S biogenesis protein is conserved throughout the Plasmodium species. • Plasmodium Dre2 expression in E. coli led to cell death and activation of stress machinery. • Plasmodium Dre2 mediated bacterial cell death is rescued by addition of exogenous DHA/ Artemether. • Interaction of ART derivatives with Dre2 indicate it as probable target of drug. Iron-sulfur (Fe-S) cluster containing proteins have been assigned roles in various essential cellular processes, such as regulation of gene expression, electron transfer, sensing of oxygen and balancing free radical chemistry. However, their role as the drug target remains sparse. Recently the screening of protein alkylation targets for artemisinin in Plasmodium falciparum led to identification of Dre2, a protein involved in redox mechanism for the cytoplasmic Fe-S cluster assembly in different organisms. In the present study, to further explore the interaction between artemisinin and Dre2, we have expressed the Dre2 protein of both P. falciparum and P. vivax in E. coli. The opaque brown colour of the IPTG induced recombinant Plasmodium Dre2 bacterial pellet, suggested iron accumulation as confirmed by the ICP-OES analysis. In addition, overexpression of r Pv Dre2 in E. coli reduced its viability, growth and increased the ROS levels of bacterial cells, which in turn led to an increase in expression of stress response genes of E. coli such as recA, soxS, mazF. Moreover, the overexpression of rDre2 induced cell death could be rescued by treatment with Artemisinin derivatives suggesting their interaction. The interaction between DHA and Pf Dre2 was later demonstrated by CETSA and microscale thermophoresis. Overall, this study suggests that Dre2 is the probable target of Artemisinin and the antimalarial activity of DHA/Artemether could also be due to yet unidentified molecular mechanism altering the Dre2 activity in addition to inducing DNA and protein damage. [ABSTRACT FROM AUTHOR]

Published

2023

21. Understanding the role of dynamics in the iron sulfur cluster molecular machine.

Author

di Maio, Danilo, Chandramouli, Balasubramanian, Yan, Robert, Brancato, Giuseppe, and Pastore, Annalisa

Subjects

*PROTEIN-protein interactions, *BACTERIAL proteins, *CRYSTAL structure, *MOLECULAR recognition, *MOLECULAR dynamics, *NUCLEAR magnetic resonance spectroscopy

Abstract

Background The bacterial proteins IscS, IscU and CyaY, the bacterial orthologue of frataxin, play an essential role in the biological machine that assembles the prosthetic Fe S cluster groups on proteins. They form functionally binary and ternary complexes both in vivo and in vitro. Yet, the mechanism by which they work remains unclear. Methods We carried out extensive molecular dynamics simulations to understand the nature of their interactions and the role of dynamics starting from the crystal structure of a IscS-IscU complex and the experimentally-based model of a ternary IscS-IscU-CyaY complex and used nuclear magnetic resonance to experimentally test the interface. Results We show that, while being firmly anchored to IscS, IscU has a pivotal motion around the interface. Our results also describe how the catalytic loop of IscS can flip conformation to allow Fe S cluster assembly. This motion is hampered in the ternary complex explaining its inhibitory properties in cluster formation. Conclusions We conclude that the observed ‘fluid’ IscS-IscU interface provides the binary complex with a functional adaptability exploited in partner recognition and unravels the molecular determinants of the reported inhibitory action of CyaY in the IscS-IscU-CyaY complex explained in terms of the hampering effect on specific IscU-IscS movements. General significance Our study provides the first mechanistic basis to explain how the IscS-IscU complex selects its binding partners and supports the inhibitory role of CyaY in the ternary complex. [ABSTRACT FROM AUTHOR]

Published

2017

22. Iron–Sulfur Cluster Biogenesis as a Critical Target in Cancer

Author

Bryan G. Allen, Michael S. Petronek, and Douglas R. Spitz

Subjects

Cell division, Physiology, Cell growth, Clinical Biochemistry, Iron–sulfur cluster, Cell Biology, RM1-950, Review, medicine.disease_cause, Biochemistry, iron–sulfur cluster biogenesis, Cell biology, chemistry.chemical_compound, chemistry, Downregulation and upregulation, Cancer cell, medicine, cancer therapy, iron metabolism, Therapeutics. Pharmacology, Carcinogenesis, Molecular Biology, carcinogenesis, Biogenesis, DNA

Abstract

Cancer cells preferentially accumulate iron (Fe) relative to non-malignant cells; however, the underlying rationale remains elusive. Iron–sulfur (Fe–S) clusters are critical cofactors that aid in a wide variety of cellular functions (e.g., DNA metabolism and electron transport). In this article, we theorize that a differential need for Fe–S biogenesis in tumor versus non-malignant cells underlies the Fe-dependent cell growth demand of cancer cells to promote cell division and survival by promoting genomic stability via Fe–S containing DNA metabolic enzymes. In this review, we outline the complex Fe–S biogenesis process and its potential upregulation in cancer. We also discuss three therapeutic strategies to target Fe–S biogenesis: (i) redox manipulation, (ii) Fe chelation, and (iii) Fe mimicry.

Published

2021

23. The determinants of sensitivity and mechanism of action of eprenetapopt (APR-246)

Author

Fujihara, Kenji Mark and Fujihara, Kenji Mark

Abstract

The tumour suppressor gene TP53 is mutated in over half of all cancers, resulting in mutant p53 protein accumulation and poor patient survival. Decades after the discovery that p53 plays a central role in the human body’s defence against cancer, the development of effective therapeutic strategies to target mutant p53 cancers still remains an unmet need in oncology. Eprenetapopt (also known as APR-246 and PRIMA-1MET) is currently in clinical development as a mutant p53 reactivator. The reported mechanism of action of eprenetapopt is to restore wild-type p53 functionality to mutant p53 in cancer cells, triggering p53-dependent cell cycle arrest and caspase- dependent apoptosis. As a result, clinical investigation of eprenetapopt has focused on TP53-mutated cancers, relying solely on TP53 mutation status for patient selection into clinical trials. However, the mechanism of action of eprenetapopt remains contentious, as evidence demonstrates that eprenetapopt maintains strong potency in cancer cells with no mutant p53. Herein, utilising novel unbiased approaches, including CRISPR perturbation screening, metabolomics, proteomics and pan-cancer cellular-feature profiling, this thesis demonstrates two major innovations regarding the determinants of sensitivity and mechanisms of action of eprenetapopt. First, the expression of SLC7A11, which encodes the functional subunit of the cystine- glutamate antiporter, not TP53-mutation status, is the major determinant of sensitivity to eprenetapopt. Second, eprenetapopt triggers a caspase-independent, iron- dependent form of cell death known as ferroptosis, following glutathione depletion and inhibition of iron-sulfur cluster biogenesis. Together, this thesis provides a roadmap for broadening the clinical utility of eprenetapopt as a ferroptosis inducer in haematological and solid malignancies, beyond TP53-mutant cancers.

Published

2021

24. Ferredoxin, in conjunction with NADPH and ferredoxin-NADP reductase, transfers electrons to the IscS/IscU complex to promote iron–sulfur cluster assembly.

Author

Yan, Robert, Adinolfi, Salvatore, and Pastore, Annalisa

Subjects

*FERREDOXINS, *NICOTINAMIDE adenine dinucleotide phosphate, *PROTEIN-protein interactions, *OXIDATION-reduction reaction, *IRON-sulfur proteins, *DITHIOTHREITOL, *IN vitro studies

Abstract

Fe–S cluster biogenesis is an essential pathway coordinated by a network of protein–protein interactions whose functions include desulfurase activity, substrate delivery, electron transfer and product transfer. In an effort to understand the intricacies of the pathway, we have developed an in vitro assay to follow the ferredoxin role in electron transfer during Fe–S cluster assembly. Previously, assays have relied upon the non-physiological reducing agents dithionite and dithiothreitol to assess function. We have addressed this shortcoming by using electron transfer between NADPH and ferredoxin-NADP-reductase to reduce ferredoxin. Our results show that this trio of electron transfer partners are sufficient to sustain the reaction in in vitro studies, albeit with a rate slower compared with DTT-mediated cluster assembly. We also show that, despite overlapping with the CyaY protein in binding to IscS, Fdx does not interfere with the inhibitory activity of this protein. We suggest explanations for these observations which have important consequences for understanding the mechanism of cluster formation. Cofactor-dependent proteins: evolution, chemical diversity and bio-applications. [ABSTRACT FROM AUTHOR]

Published

2015

25. What a difference a cluster makes: The multifaceted roles of IscR in gene regulation and DNA recognition.

Author

Santos, Joana A., Pereira, Pedro José Barbosa, and Macedo-Ribeiro, Sandra

Subjects

*GENETIC regulation, *IRON-sulfur proteins, *COFACTORS (Biochemistry), *GRAM-negative bacteria, *BACTERIAL operons, *DNA-binding proteins, *TRANSCRIPTION factors

Abstract

Iron–sulfur clusters are essential cofactors in a myriad of metabolic pathways. Therefore, their biogenesis is tightly regulated across a variety of organisms and environmental conditions. In Gram-negative bacteria, two pathways – ISC and SUF – concur for maintaining intracellular iron–sulfur cluster balance. Recently, the mechanism of iron–sulfur cluster biosynthesis regulation by IscR, an iron–sulfur cluster-containing regulator encoded by the isc operon, was found to be conserved in some Gram-positive bacteria. Belonging to the Rrf2 family of transcriptional regulators, IscR displays a single helix-turn-helix DNA-binding domain but is able to recognize two distinct DNA sequence motifs, switching its specificity upon cluster ligation. This review provides an overview of gene regulation by iron–sulfur cluster-containing sensors, in the light of the recent structural characterization of cluster-less free and DNA-bound IscR, which provided insights into the molecular mechanism of nucleotide sequence recognition and discrimination of this unique transcription factor. This article is part of a Special Issue entitled: Cofactor-dependent proteins: evolution, chemical diversity and bio-applications. [ABSTRACT FROM AUTHOR]

Published

2015

26. Molecular modeling of the binding modes of the iron-sulfur protein to the Jac1 co-chaperone from S accharomyces cerevisiae by all-atom and coarse-grained approaches.

Author

Mozolewska, Magdalena A., Krupa, Paweł, Scheraga, Harold A., and Liwo, Adam

Abstract

ABSTRACT The iron-sulfur protein 1 (Isu1) and the J-type co-chaperone Jac1 from yeast are part of a huge ATP-dependent system, and both interact with Hsp70 chaperones. Interaction of Isu1 and Jac1 is a part of the iron-sulfur cluster biogenesis system in mitochondria. In this study, the structure and dynamics of the yeast Isu1-Jac1 complex has been modeled. First, the complete structure of Isu1 was obtained by homology modeling using the I-TASSER server and YASARA software and thereafter tested for stability in the all-atom force field AMBER. Then, the known experimental structure of Jac1 was adopted to obtain initial models of the Isu1-Jac1 complex by using the ZDOCK server for global and local docking and the AutoDock software for local docking. Three most probable models were subsequently subjected to the coarse-grained molecular dynamics simulations with the UNRES force field to obtain the final structures of the complex. In the most probable model, Isu1 binds to the left face of the Γ-shaped Jac1 molecule by the β-sheet section of Isu1. Residues L105, L109, and Y163 of Jac1 have been assessed by mutation studies to be essential for binding (Ciesielski et al., J Mol Biol 2012; 417:1-12). These residues were also found, by UNRES/molecular dynamics simulations, to be involved in strong interactions between Isu1 and Jac1 in the complex. Moreover, N95, T98, P102, H112, V159, L167, and A170 of Jac1, not yet tested experimentally, were also found to be important in binding. Proteins 2015; 83:1414-1426. © 2015 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2015

27. Hyperactivation of mTOR and AKT in a cardiac hypertrophy animal model of Friedreich ataxia.

Author

Tong WH, Ollivierre H, Noguchi A, Ghosh MC, Springer DA, and Rouault TA

Abstract

Cardiomyopathy is a primary cause of death in Friedreich ataxia (FRDA) patients with defective iron-sulfur cluster (ISC) biogenesis due to loss of functional frataxin and in rare patients with functional loss of other ISC biogenesis factors. The mechanistic target of rapamycin (mTOR) and AKT signaling cascades that coordinate eukaryotic cell growth and metabolism with environmental inputs, including nutrients and growth factors, are crucial regulators of cardiovascular growth and homeostasis. We observed increased phosphorylation of AKT and dysregulation of multiple downstream effectors of mTORC1, including S6K1, S6, ULK1 and 4EBP1, in a cardiac/skeletal muscle specific FRDA conditional knockout (cKO) mouse model and in human cell lines depleted of ISC biogenesis factors. Knockdown of several mitochondrial metabolic proteins that are downstream targets of ISC biogenesis, including lipoyl synthase and subunit B of succinate dehydrogenase, also resulted in activation of mTOR and AKT signaling, suggesting that mTOR and AKT hyperactivations are part of the metabolic stress response to ISC deficiencies. Administration of rapamycin, a specific inhibitor of mTOR signaling, enhanced the survival of the Fxn cKO mice, providing proof of concept for the potential of mTOR inhibition to ameliorate cardiac disease in patients with defective ISC biogenesis. However, AKT phosphorylation remained high in rapamycin-treated Fxn cKO hearts, suggesting that parallel mTOR and AKT inhibition might be necessary to further improve the lifespan and healthspan of ISC deficient individuals., Competing Interests: The authors declare no conflict of interest.

Published

2022

28. X-linked sideroblastic anemia and ataxia: A new family with identification of a fourth ABCB7 gene mutation.

Author

D’Hooghe, Marc, Selleslag, Dominik, Mortier, Geert, Van Coster, Rudy, Vermeersch, Pieter, Billiet, Johan, and Bekri, Soumeya

Subjects

X-linked genetic disorders, ANEMIA, ATAXIA, GENETIC mutation, ATP-binding cassette transporters, HOMEOSTASIS, GENETICS

Abstract

Abstract: X-linked sideroblastic anemia and ataxia (XLSA-A) is a rare cause of early onset ataxia, which may be overlooked due to the usually mild asymptomatic anemia. The genetic defect has been identified as a mutation in the ABCB7 gene at Xq12-q13. The gene encodes a mitochondrial ATP-binding cassette (ABC) transporter protein involved in iron homeostasis. Until now only three families have been reported, each with a distinct missense mutation in this gene. We describe a fourth family with XLSA-A and a novel mutation in the ABCB7 gene. [Copyright &y& Elsevier]

Published

2012

29. Both human ferredoxins 1 and 2 and ferredoxin reductase are important for iron-sulfur cluster biogenesis

Author

Shi, Yanbo, Ghosh, Manik, Kovtunovych, Gennadiy, Crooks, Daniel R., and Rouault, Tracey A.

Subjects

*FERREDOXINS, *IRON, *SULFUR, *MONOOXYGENASES, *REDUCTASES, *METAL clusters

Abstract

Abstract: Ferredoxins are iron–sulfur proteins that have been studied for decades because of their role in facilitating the monooxygenase reactions catalyzed by p450 enzymes. More recently, studies in bacteria and yeast have demonstrated important roles for ferredoxin and ferredoxin reductase in iron–sulfur cluster assembly. The human genome contains two homologous ferredoxins, ferredoxin 1 (FDX1) and ferredoxin 2 (FDX2 — formerly known as ferredoxin 1L). More recently, the roles of these two human ferredoxins in iron–sulfur cluster assembly were assessed, and it was concluded that FDX1 was important solely for its interaction with p450 enzymes to synthesize mitochondrial steroid precursors, whereas FDX2 was used for synthesis of iron–sulfur clusters, but not steroidogenesis. To further assess the role of the FDX–FDXR system in mammalian iron–sulfur cluster biogenesis, we performed siRNA studies on FDX1 and FDX2, on several human cell lines, using oligonucleotides identical to those previously used, along with new oligonucleotides that specifically targeted each gene. We concluded that both FDX1 and FDX2 were important in iron–sulfur cluster biogenesis. Loss of FDX1 activity disrupted activity of iron–sulfur cluster enzymes and cellular iron homeostasis, causing mitochondrial iron overload and cytosolic iron depletion. Moreover, knockdown of the sole human ferredoxin reductase, FDXR, diminished iron–sulfur cluster assembly and caused mitochondrial iron overload in conjunction with cytosolic depletion. Our studies suggest that interference with any of the three related genes, FDX1, FDX2 or FDXR, disrupts iron–sulfur cluster assembly and maintenance of normal cytosolic and mitochondrial iron homeostasis. [Copyright &y& Elsevier]

Published

2012

30. Folding and turnover of human iron regulatory protein 1 depend on its subcellular localization.

Author

Martelli, Alain, Salin, Bénédicte, Dycke, Camille, Louwagie, Mathilde, Andrieu, Jean-Pierre, Richaud, Pierre, and Moulis, Jean-Marc

Subjects

*IRON in the body, *IRON metabolism, *CYTOLOGY, *ORGANELLES, *CELLS, *PHYSIOLOGY

Abstract

Aconitases are iron–sulfur hydrolyases catalysing the interconversion of citrate and isocitrate in a wide variety of organisms. Eukaryotic aconitases have been assigned additional roles, as in the case of the metazoan dual activity cytosolic aconitase–iron regulatory protein 1 (IRP1). This human protein was produced in yeast mitochondria to probe IRP1 folding in this organelle where iron–sulfur synthesis originates. The behaviour of human IRP1 was compared with that of genuine mitochondrial (yeast or human) aconitases. All enzymes were functional in yeast mitochondria, but IRP1 was found to form dense particles as detected by electron microscopy. MS analysis of purified inclusion bodies evidenced the presence of human IRP1 and α-ketoglutarate dehydrogenase complex component 1 (KGD1), one of the subunits of α-ketoglutarate dehydrogenase. KGD1 triggered formation of the mitochondrial aggregates, because the latter were absent in a KGD1– mutant, but it did not efficiently do so in the cytosol. Despite the iron-binding capacity of IRP1 and the readily synthesis of iron–sulfur clusters in mitochondria, the dense particles were not iron-rich, as indicated by elemental analysis of purified mitochondria. The data show that proper folding of dual activity IRP1-cytosolic aconitase is deficient in mitochondria, in contrast to genuine mitochondrial aconitases. Furthermore, efficient clearance of the aggregated IRP1–KGD1 complex does not occur in the organelle, which emphasizes the role of molecular interactions in determining the fate of IRP1. Thus, proper folding of human IRP1 strongly depends on its cellular environment, in contrast to other members of the aconitase family. [ABSTRACT FROM AUTHOR]

Published

2007

31. Distinct TP53 Mutation Subtypes Differentially Influence Cellular Iron Metabolism

Author

Eshan Dandekar, Aishwarya Srinivasan, Stephen L. Clarke, Mckale Montgomery, and Laurie R. Thompson

Subjects

0301 basic medicine, Tumor suppressor gene, endocrine system diseases, Iron, iron-sulfur cluster biogenesis, lcsh:TX341-641, Transferrin receptor, Cell Growth Processes, Article, 03 medical and health sciences, 0302 clinical medicine, stomatognathic system, mutant TP53, Cell Line, Tumor, Homeostasis, Humans, cancer, Gene, neoplasms, Cell Proliferation, chemistry.chemical_classification, Nutrition and Dietetics, biology, Cell growth, Iron-Regulatory Proteins, DNA-binding domain, Cell biology, Ferritin, 030104 developmental biology, chemistry, iron regulator proteins, Transferrin, 030220 oncology & carcinogenesis, Mutation, Cancer cell, biology.protein, Tumor Suppressor Protein p53, lcsh:Nutrition. Foods and food supply, metabolism, Food Science

Abstract

The most commonly mutated gene in all human cancers is the tumor suppressor gene TP53, however, in addition to the loss of tumor suppressor functions, mutations in TP53 can also promote cancer progression by altering cellular iron acquisition and metabolism. The primary objective of this work was to determine how TP53 mutation status influences the molecular control of iron homeostasis. The effect of TP53 mutation type on cellular iron homeostasis was examined using cell lines with inducible versions of either wild-type TP53 or a representative mutated TP53 gene from exemplary &ldquo, hotspot&rdquo, mutations in the DNA binding domain (R248, R273, and R175) as well as H193Y. The introduction of distinct TP53 mutation types alone was sufficient to disrupt cellular iron metabolism. These effects were mediated, at least in part, due to differences in the responsiveness of iron regulatory proteins (IRPs) to cellular iron availability. IRPs are considered the master regulators of intracellular iron homeostasis because they coordinate the expression of iron storage (ferritin) and iron uptake (transferrin receptor) genes. In response to changes in iron availability, cells harboring either a wild-type TP53 or R273H TP53 mutation displayed canonical IRP-mediated responses, but neither IRP1 RNA binding activity nor IRP2 protein levels were affected by changes in iron status in cells harboring the R175H mutation type. However, all mutation types exhibited robust changes in ferritin and transferrin receptor protein expression in response to iron loading and iron chelation, respectively. These findings suggest a novel, IRP-independent mode of iron regulation in cells expressing distinct TP53 mutations. As TP53 is mutated in nearly half of all human cancers, and iron is necessary for cancer cell growth and proliferation, the studies have implications for a wide range of clinically important cancers.

Published

2019

32. Biological iron-sulfur clusters: Mechanistic insights from mass spectrometry.

Author

Crack, Jason C. and Le Brun, Nick E.

Subjects

*MASS spectrometry, *COFACTORS (Biochemistry), *SMALL molecules, *CHARGE exchange, *CONDITIONED response, *OXIDATION-reduction reaction

Abstract

• Iron-sulfur clusters are ubiquitous in life and diverse in function. • Native mass spectrometry provides novel insight into iron-sulfur cluster chemistry. • Cluster-specific Fe/S isotope substitutions confirm mass spectrometric assignments. • Time-resolved native mass spectrometry unravels mechanisms of cluster conversion. Iron-sulfur (FeS) clusters are protein cofactors that are ubiquitous in life, performing a wide range of functions, such as in electron transfer, catalysis and gene regulation. This functional diversity is underpinned by the inherent reactivity of FeS clusters towards redox change and reaction with small molecules such as molecular oxygen and nitric oxide. Such reactivity also presents significant challenges for their study, and difficulties in obtaining sufficient quantities of stable, homogenous FeS protein samples have severely hampered progress in understanding these fascinating proteins. Recently, the application of mass spectrometry, under conditions where the cluster cofactor remains protein-associated, has yielded major new insight, particularly into FeS cluster assembly and the chemistry occurring at the FeS clusters of transcriptional regulators that coordinate the cell's response to changing conditions, such as availability of O 2 and cellular iron status, or the onset of oxidative or nitrosative stress. Here we review this recent progress, highlighting the power of native mass spectrometric approaches for studies of protein cofactors. [ABSTRACT FROM AUTHOR]

Published

2021

33. Iron–Sulfur Cluster Biogenesis as a Critical Target in Cancer.

Author

Petronek, Michael S., Spitz, Douglas R., and Allen, Bryan G.

Subjects

CELL physiology, DEOXYRIBOZYMES, CELL survival, CANCER cell growth, ELECTRON transport, IRON, CELL division, CANCER cells

Abstract

Cancer cells preferentially accumulate iron (Fe) relative to non-malignant cells; however, the underlying rationale remains elusive. Iron–sulfur (Fe–S) clusters are critical cofactors that aid in a wide variety of cellular functions (e.g., DNA metabolism and electron transport). In this article, we theorize that a differential need for Fe–S biogenesis in tumor versus non-malignant cells underlies the Fe-dependent cell growth demand of cancer cells to promote cell division and survival by promoting genomic stability via Fe–S containing DNA metabolic enzymes. In this review, we outline the complex Fe–S biogenesis process and its potential upregulation in cancer. We also discuss three therapeutic strategies to target Fe–S biogenesis: (i) redox manipulation, (ii) Fe chelation, and (iii) Fe mimicry. [ABSTRACT FROM AUTHOR]

Published

2021

34. ISCU interacts with NFU1, and ISCU[4Fe-4S] transfers its Fe-S cluster to NFU1 leading to the production of holo-NFU1

Author

Ronnie O. Frederick, Kai Cai, and John L. Markley

Subjects

Iron-Sulfur Proteins, Magnetic Resonance Spectroscopy, Protein-protein interactions, Small angle X-ray scattering, NFU1, Article, Protein Structure, Secondary, Protein–protein interaction, Iron-sulfur cluster biogenesis, 03 medical and health sciences, ISCU, Structural Biology, Scattering, Small Angle, Humans, 030304 developmental biology, 0303 health sciences, biology, Chemistry, Small-angle X-ray scattering, 030302 biochemistry & molecular biology, Isothermal titration calorimetry, Nuclear magnetic resonance spectroscopy, NMR, Dissociation constant, Sulfonylurea Compounds, Chaperone (protein), biology.protein, Biophysics, Carrier Proteins, Biogenesis, Protein Binding

Abstract

NFU1 is a late-acting factor in the biogenesis of human mitochondrial iron-sulfur proteins. Mutations in NFU1 are associated with genetic diseases such as multiple mitochondrial dysfunctions syndrome 1 (MMDS1) that involve defects in mitochondrial [4Fe-4S] proteins. We present results from NMR spectroscopy, small angle X-ray scattering, size exclusion chromatography, and isothermal titration calorimetry showing that the structured conformer of human ISCU binds human NFU1. The dissociation constant determined by ITC is Kd = 1.1 ± 0.2 μM. NMR and SAXS studies led to a structural model for the complex in which the cluster binding region of ISCU interacts with two α-helices in the C-terminal domain of NFU1. In vitro experiments demonstrate that ISCU[4Fe-4S] transfers its Fe-S cluster to apo-NFU1, in the absence of a chaperone, leading to the assembly of holo-NFU1. By contrast, the cluster of ISCU[2Fe-2S] remains bound to ISCU in the presence of apo-NFU1.

Published

2020

35. Cloning, overproduction, purification, crystallization and preliminary X-ray diffraction analysis of yeast glutaredoxin Grx5.

Author

Wang, Yi, He, Yong-Xing, Yu, Jiang, and Zhou, Cong-Zhao

Subjects

*YEAST research, *SACCHAROMYCES cerevisiae, *CRYSTALLIZATION, *X-ray diffraction, *GLUTAREDOXIN, *ORIGIN of life, *ESCHERICHIA coli

Abstract

Grx5 from the yeast Saccharomyces cerevisiae is a monothiol glutaredoxin that is involved in iron-sulfur cluster biogenesis. Here, yeast Grx5 was cloned and overproduced in Escherichia coli. The purified protein was crystallized using the hanging-drop vapour-diffusion method. Diffraction data for Grx5 were collected to 1.67 Å resolution. The crystal of Grx5 belonged to space group R3, with unit-cell parameters a = b = 85.12, c = 48.95 Å, α = β = 90.00, γ = 120.00°. [ABSTRACT FROM AUTHOR]

Published

2009

36. Iron-sulfur cluster biogenesis, trafficking, and signaling: Roles for CGFS glutaredoxins and BolA proteins.

Author

Talib, Evan A. and Outten, Caryn E.

Subjects

*CHLOROPLASTS, *ORIGIN of life, *METABOLIC regulation, *PROTEINS, *IRON metabolism, *CHLOROPLAST formation, *HUMAN genes, *FERRITIN

Abstract

The synthesis and trafficking of iron-sulfur (Fe-S) clusters in both prokaryotes and eukaryotes requires coordination within an expanding network of proteins that function in the cytosol, nucleus, mitochondria, and chloroplasts in order to assemble and deliver these ancient and essential cofactors to a wide variety of Fe-S-dependent enzymes and proteins. This review focuses on the evolving roles of two ubiquitous classes of proteins that operate in this network: CGFS glutaredoxins and BolA proteins. Monothiol or CGFS glutaredoxins possess a Cys-Gly-Phe-Ser active site that coordinates an Fe-S cluster in a homodimeric complex. CGFS glutaredoxins also form [2Fe-2S]-bridged heterocomplexes with BolA proteins, which possess an invariant His and an additional His or Cys residue that serve as cluster ligands. Here we focus on recent discoveries in bacteria, fungi, humans, and plants that highlight the shared and distinct roles of CGFS glutaredoxins and BolA proteins in Fe-S cluster biogenesis, Fe-S cluster storage and trafficking, and Fe-S cluster signaling to transcriptional factors that control iron metabolism--. • Glutaredoxins with a CGFS active site and BolA proteins are ubiquitous in nature. • CGFS glutaredoxins form iron-sulfur bridged complexes with BolA proteins. • BolA proteins function with CGFS glutaredoxins in iron-sulfur cluster assembly and trafficking. • CGFS glutaredoxin-BolA complexes regulate iron homeostasis in fungi. • Mutations in GLRX5 and BOLA3 genes cause human mitochondrial diseases. [ABSTRACT FROM AUTHOR]

Published

2021

37. ISCU interacts with NFU1, and ISCU[4Fe-4S] transfers its Fe-S cluster to NFU1 leading to the production of holo-NFU1.

Author

Cai, Kai, Frederick, Ronnie O., and Markley, John L.

Subjects

*SMALL-angle X-ray scattering, *SMALL-angle scattering, *IRON-sulfur proteins, *ISOTHERMAL titration calorimetry, *GEL permeation chromatography, *MITOCHONDRIAL proteins

Abstract

• NFU1 and ISCU have been found to interact with K d = 1.1 ± 0.2 μM. • In the complex, the Fe-S cluster binding region of ISCU interacts with two α-helices in the C-terminal domain of NFU1. • ISCU[4Fe-4S] transfers its Fe-S cluster to apo-NFU1, whereas ISCU[2Fe-2S] does not. • The results suggest a physiological role for ISCU[4Fe-4S]. NFU1 is a late-acting factor in the biogenesis of human mitochondrial iron-sulfur proteins. Mutations in NFU1 are associated with genetic diseases such as multiple mitochondrial dysfunctions syndrome 1 (MMDS1) that involve defects in mitochondrial [4Fe-4S] proteins. We present results from NMR spectroscopy, small angle X-ray scattering, size exclusion chromatography, and isothermal titration calorimetry showing that the structured conformer of human ISCU binds human NFU1. The dissociation constant determined by ITC is K d = 1.1 ± 0.2 μM. NMR and SAXS studies led to a structural model for the complex in which the cluster binding region of ISCU interacts with two α-helices in the C-terminal domain of NFU1. In vitro experiments demonstrate that ISCU[4Fe-4S] transfers its Fe-S cluster to apo-NFU1, in the absence of a chaperone, leading to the assembly of holo-NFU1. By contrast, the cluster of ISCU[2Fe-2S] remains bound to ISCU in the presence of apo-NFU1. [ABSTRACT FROM AUTHOR]

Published

2020

38. Distinct TP53 Mutation Subtypes Differentially Influence Cellular Iron Metabolism.

Author

Clarke, Stephen L., Thompson, Laurie R., Dandekar, Eshan, Srinivasan, Aishwarya, and Montgomery, McKale R.

Abstract

The most commonly mutated gene in all human cancers is the tumor suppressor gene TP53; however, in addition to the loss of tumor suppressor functions, mutations in TP53 can also promote cancer progression by altering cellular iron acquisition and metabolism. The primary objective of this work was to determine how TP53 mutation status influences the molecular control of iron homeostasis. The effect of TP53 mutation type on cellular iron homeostasis was examined using cell lines with inducible versions of either wild-type TP53 or a representative mutated TP53 gene from exemplary "hotspot" mutations in the DNA binding domain (R248, R273, and R175) as well as H193Y. The introduction of distinct TP53 mutation types alone was sufficient to disrupt cellular iron metabolism. These effects were mediated, at least in part, due to differences in the responsiveness of iron regulatory proteins (IRPs) to cellular iron availability. IRPs are considered the master regulators of intracellular iron homeostasis because they coordinate the expression of iron storage (ferritin) and iron uptake (transferrin receptor) genes. In response to changes in iron availability, cells harboring either a wild-type TP53 or R273H TP53 mutation displayed canonical IRP-mediated responses, but neither IRP1 RNA binding activity nor IRP2 protein levels were affected by changes in iron status in cells harboring the R175H mutation type. However, all mutation types exhibited robust changes in ferritin and transferrin receptor protein expression in response to iron loading and iron chelation, respectively. These findings suggest a novel, IRP-independent mode of iron regulation in cells expressing distinct TP53 mutations. As TP53 is mutated in nearly half of all human cancers, and iron is necessary for cancer cell growth and proliferation, the studies have implications for a wide range of clinically important cancers. [ABSTRACT FROM AUTHOR]

Published

2019

39. Metabolic regulation of citrate and iron by aconitases: role of iron–sulfur cluster biogenesis

Author

Tong, Wing-Hang and Rouault, Tracey A.

Published

2007

40. Mécanisme de biogenèse des centres Fe/S chez les mammifères : rôle de la frataxine dans le contrôle de la réactivité des persulfures

Author

Parent, Aubérie, Institut de Chimie des Substances Naturelles (ICSN), Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Université Paris Sud - Paris XI, and Jean-Michel Camadro

Subjects

Mammals, Frataxin, Mécanisme, Mitochondries, Frataxine, Ataxie de Friedreich, Mitochondria, Iron-sulfur cluster biogenesis, Biogenèse des centres Fe/S, Mammifères, Persulfide, Friedreich ataxia, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Mechanism, Persulfures

Abstract

Friedreich ataxia is a severe neurodegenerative disease caused by reduced expression of frataxin (FXN), a small mitochondrial protein involved in iron-sulfur (Fe/S) cluster biogenesis which are prostetic groups with essential cellular functions. It has been shown in vitro that mammalian FXN activates Fe/S cluster synthesis on the scaffold protein ISCU, by rising up suflide ion production by NFS1-ISD11-ISCU complex. However, the mechanism by which frataxin stimulates Fe/S cluster biogenesis has not been yet defined. We have studied the effect of FXN on the kinetics of formation and reduction of persulfides that are key intermediates of sulfide ion production generated by NFS1, using mass spectrometry and a new detection assay for persulfide based on gel-mobility shift following alkylation by maleimide-peptide compounds. We demonstrate that frataxin activates two similar reactions : sulfur transfer from cysteine desulfurase NFS1 to ISCU leading to accumulation of a persulfide on ISCUcysteine C104 and reduction of NFS1 persulfide by thiol reducers such as DTT, L-cysteine and glutathion. We have observed that FXN does not stimulate the rate of ISCU persulfide reduction by thiols and that this persulfide is reduced much more slowly than NFS1 persulfide. We have then correlated the reduction of NFS1 persulfide with Fe/S cluster assembly. Under our experimental conditions, the sulfur from ISCU persulfide is not incorporated into the Fe/S cluster. However, we cannot exclude that an as yet not identfiied reductase could reduces ISCU persulfide and trigger Fe/S cluster assembly. Overall, our data point to a regulatory function of FXN as an enhancer of persulfide reduction, stimulating the rates of sulfur transfer to ISCU and NFS1 persulfide.; L’ataxie de Friedreich est une maladie neurodégénérative sévère causée par un défaut d’expression de la frataxine (FXN), une petite protéine mitochondriale impliquée dans la biogenèse des centres fer-soufre (Fe/S), des groupement prosthétiques aux fonctions cellulaires essentielles. Chez les mammifères, il a été montré que la frataxine stimule la synthèse in vitro de centres Fe/S sur la protéine d’échaffaudage ISCU, grâce à l’augmentation de la production d’ions sulfures par le complexe NFS1-ISD11-ISCU. Cependant, le mécanisme par lequel la frataxine active la biogenèse des centres Fe/S n’a pas encore été défini. Nous avons étudié les effets de FXN sur les cinétiques de formation et de réduction des persulfures, des intermédiaires clés de la production d’ions sulfures, générés par la cystéiene désulfurase NFS1, à l’aide d’un test de détection des persulfures basé sur l’utilisation de composés synthétiques peptide-maléimide et de la spectrométrie de masse. Nous avons montré que FXN active deux réactions très similaires : la réduction du persulfure de NFS1 par des réducteurs à thiols comme le DTT, la L-cystéine et le glutathion et le transfert de soufre de NFS1 vers ISCU, conduisant à l’accumulation de persulfure sur la cystéine C104 d’ISCU. Nous avons constaté que la vitesse de réduction du persulfure d’ISCU par les thiols n’est pas affectée en présence de FXN et que ce persulfure est réduit plus lentement que celui de NFS1. Nous avons corrélé l’activation par FXN de la réduction du persulfure de NFS1 par les thiols à une stimulation de l’assemblage d’un centre Fe/S sur ISCU. Dans nos conditions expérimentales, l’atome de soufre du persulfure d’ISCU n’est pas incorporé dans le centre Fe/S synthétisé, mais nos résultats ne permettent pas d’exclure que ce persulfure puisse être réduit par une réductase dédiée, encore non identifiée. L’ensemble de nos données indiquent que le rôle de la frataxine est de contrôler la réduction du persulfure de NFS1, en augmentant les vitesses de transfert de soufre vers ISCU et de réduction du persulfure de NFS1 par les thiols.

Published

2014

41. Both human ferredoxins 1 and 2 and ferredoxin reductase are important for iron-sulfur cluster biogenesis

Author

Daniel R. Crooks, Gennadiy Kovtunovych, Manik C. Ghosh, Tracey A. Rouault, and Yanbo Shi

Subjects

inorganic chemicals, Iron-Sulfur Proteins, Heme biosynthesis, Iron, Molecular Sequence Data, Iron–sulfur cluster, Sequence alignment, Heme, Biology, Article, Cell Line, chemistry.chemical_compound, Cytosol, Humans, Amino Acid Sequence, Iron Regulatory Protein 1, Iron–sulfur cluster biogenesis, Peptide sequence, Molecular Biology, Iron Regulatory Protein 2, Cellular iron homeostasis, Ferredoxin, chemistry.chemical_classification, Electron Transport Complex I, Cell Biology, Monooxygenase, Mitochondria, Enzyme, Biochemistry, chemistry, RNAi, Gene Knockdown Techniques, Multigene Family, Mitochondrial iron accumulation, Ferredoxins, RNA Interference, Oxidoreductases, Sequence Alignment, Biogenesis

Abstract

Ferredoxins are iron–sulfur proteins that have been studied for decades because of their role in facilitating the monooxygenase reactions catalyzed by p450 enzymes. More recently, studies in bacteria and yeast have demonstrated important roles for ferredoxin and ferredoxin reductase in iron–sulfur cluster assembly. The human genome contains two homologous ferredoxins, ferredoxin 1 (FDX1) and ferredoxin 2 (FDX2 — formerly known as ferredoxin 1L). More recently, the roles of these two human ferredoxins in iron–sulfur cluster assembly were assessed, and it was concluded that FDX1 was important solely for its interaction with p450 enzymes to synthesize mitochondrial steroid precursors, whereas FDX2 was used for synthesis of iron–sulfur clusters, but not steroidogenesis. To further assess the role of the FDX–FDXR system in mammalian iron–sulfur cluster biogenesis, we performed siRNA studies on FDX1 and FDX2, on several human cell lines, using oligonucleotides identical to those previously used, along with new oligonucleotides that specifically targeted each gene. We concluded that both FDX1 and FDX2 were important in iron–sulfur cluster biogenesis. Loss of FDX1 activity disrupted activity of iron–sulfur cluster enzymes and cellular iron homeostasis, causing mitochondrial iron overload and cytosolic iron depletion. Moreover, knockdown of the sole human ferredoxin reductase, FDXR, diminished iron–sulfur cluster assembly and caused mitochondrial iron overload in conjunction with cytosolic depletion. Our studies suggest that interference with any of the three related genes, FDX1, FDX2 or FDXR, disrupts iron–sulfur cluster assembly and maintenance of normal cytosolic and mitochondrial iron homeostasis.

Published

2011

42. Biogenesis and functions of mammalian iron-sulfur proteins in the regulation of iron homeostasis and pivotal metabolic pathways.

Author

Rouault TA and Maio N

Subjects

Animals, Apoenzymes chemistry, Apoenzymes metabolism, Carbon-Sulfur Lyases biosynthesis, Carbon-Sulfur Lyases chemistry, Carbon-Sulfur Lyases physiology, Electron Transport, Gene Expression Regulation, Enzymologic, HSP70 Heat-Shock Proteins biosynthesis, HSP70 Heat-Shock Proteins chemistry, HSP70 Heat-Shock Proteins physiology, Humans, Iron Regulatory Protein 1 biosynthesis, Iron Regulatory Protein 1 chemistry, Iron-Binding Proteins biosynthesis, Iron-Binding Proteins chemistry, Iron-Binding Proteins physiology, Iron-Regulatory Proteins biosynthesis, Iron-Regulatory Proteins chemistry, Iron-Regulatory Proteins physiology, Iron-Sulfur Proteins biosynthesis, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins physiology, Mitochondrial Proteins biosynthesis, Mitochondrial Proteins chemistry, Mitochondrial Proteins physiology, Molecular Chaperones biosynthesis, Molecular Chaperones chemistry, Molecular Chaperones physiology, Protein Folding, Protein Interaction Domains and Motifs, Protein Multimerization, Response Elements, Succinate Dehydrogenase biosynthesis, Succinate Dehydrogenase chemistry, Succinate Dehydrogenase physiology, Frataxin, Homeostasis, Iron physiology, Iron Regulatory Protein 1 physiology, Models, Molecular

Abstract

Fe-S cofactors are composed of iron and inorganic sulfur in various stoichiometries. A complex assembly pathway conducts their initial synthesis and subsequent binding to recipient proteins. In this minireview, we discuss how discovery of the role of the mammalian cytosolic aconitase, known as iron regulatory protein 1 (IRP1), led to the characterization of the function of its Fe-S cluster in sensing and regulating cellular iron homeostasis. Moreover, we present an overview of recent studies that have provided insights into the mechanism of Fe-S cluster transfer to recipient Fe-S proteins., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

43. Molecular modeling of the binding modes of the iron-sulfur protein to the Jac1 co-chaperone from Saccharomyces cerevisiae by all-atom and coarse-grained approaches.

Author

Mozolewska MA, Krupa P, Scheraga HA, and Liwo A

Subjects

Molecular Dynamics Simulation, Protein Binding, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Mitochondrial Proteins chemistry, Mitochondrial Proteins metabolism, Molecular Chaperones chemistry, Molecular Chaperones metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism

Abstract

The iron-sulfur protein 1 (Isu1) and the J-type co-chaperone Jac1 from yeast are part of a huge ATP-dependent system, and both interact with Hsp70 chaperones. Interaction of Isu1 and Jac1 is a part of the iron-sulfur cluster biogenesis system in mitochondria. In this study, the structure and dynamics of the yeast Isu1-Jac1 complex has been modeled. First, the complete structure of Isu1 was obtained by homology modeling using the I-TASSER server and YASARA software and thereafter tested for stability in the all-atom force field AMBER. Then, the known experimental structure of Jac1 was adopted to obtain initial models of the Isu1-Jac1 complex by using the ZDOCK server for global and local docking and the AutoDock software for local docking. Three most probable models were subsequently subjected to the coarse-grained molecular dynamics simulations with the UNRES force field to obtain the final structures of the complex. In the most probable model, Isu1 binds to the left face of the Γ-shaped Jac1 molecule by the β-sheet section of Isu1. Residues L105 , L109 , and Y163 of Jac1 have been assessed by mutation studies to be essential for binding (Ciesielski et al., J Mol Biol 2012; 417:1-12). These residues were also found, by UNRES/molecular dynamics simulations, to be involved in strong interactions between Isu1 and Jac1 in the complex. Moreover, N(95), T(98), P(102), H(112), V(159), L(167), and A(170) of Jac1, not yet tested experimentally, were also found to be important in binding., (© 2015 Wiley Periodicals, Inc.)

Published

2015

44. The N-terminal Domain of Escherichia coli Assimilatory NADPH-Sulfite Reductase Hemoprotein Is an Oligomerization Domain That Mediates Holoenzyme Assembly.

Author

Askenasy I, Pennington JM, Tao Y, Marshall AG, Young NL, Shang W, and Stroupe ME

Subjects

Amino Acid Sequence, Catalytic Domain, Molecular Sequence Data, Protein Binding, Protein Interaction Domains and Motifs, Protein Multimerization, Protein Structure, Quaternary, Scattering, Small Angle, X-Ray Diffraction, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Sulfite Reductase (NADPH) chemistry

Abstract

Assimilatory NADPH-sulfite reductase (SiR) from Escherichia coli is a structurally complex oxidoreductase that catalyzes the six-electron reduction of sulfite to sulfide. Two subunits, one a flavin-binding flavoprotein (SiRFP, the α subunit) and the other an iron-containing hemoprotein (SiRHP, the β subunit), assemble to make a holoenzyme of about 800 kDa. How the two subunits assemble is not known. The iron-rich cofactors in SiRHP are unique because they are a covalent arrangement of a Fe4S4 cluster attached through a cysteine ligand to an iron-containing porphyrinoid called siroheme. The link between cofactor biogenesis and SiR stability is also ill-defined. By use of hydrogen/deuterium exchange and biochemical analysis, we show that the α8β4 SiR holoenzyme assembles through the N terminus of SiRHP and the NADPH binding domain of SiRFP. By use of small angle x-ray scattering, we explore the structure of the SiRHP N-terminal oligomerization domain. We also report a novel form of the hemoprotein that occurs in the absence of its cofactors. Apo-SiRHP forms a homotetramer, also dependent on its N terminus, that is unable to assemble with SiRFP. From these results, we propose that homotetramerization of apo-SiRHP serves as a quality control mechanism to prevent formation of inactive holoenzyme in the case of limiting cellular siroheme., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015