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13. Sensing the cellular Fe-S cluster demand: a structural, functional, and phylogenetic overview of Escherichia coli IscR

  • Erin L. Mettert , Nicole T. Perna and Patricia J. Kiley
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Iron-Sulfur Clusters in Chemistry and Biology
This chapter is in the book Iron-Sulfur Clusters in Chemistry and Biology

Chapters in this book

  1. Frontmatter i
  2. Preface v
  3. Tracey A. Rouault biography vii
  4. Contents ix
  5. Contributing authors xxi
  6. 1. Iron-sulfur proteins: a historical perspective 1
  7. 2. Chemistry of iron-sulfur clusters 11
  8. 3. Quantitative interpretation of EPR spectroscopy with applications for iron-sulfur proteins 21
  9. 4. The utility of Mössbauer spectroscopy in eukaryotic cell biology and animal physiology 49
  10. 5. The interstitial carbide of the nitrogenase M-cluster: insertion pathway and possible function 77
  11. 6. The iron-molybdenum cofactor of nitrogenase 89
  12. 7. Biotin synthase: a role for iron-sulfur clusters in the radical-mediated generation of carbon-sulfur bonds 107
  13. 8. Molybdenum-containing iron-sulfur enzymes 133
  14. 9. The role of iron-sulfur clusters in the biosynthesis of the lipoyl cofactor 211
  15. 10. Iron-sulfur clusters and molecular oxygen: function, adaptation, degradation, and repair 239
  16. 11. A retrospective on the discovery of [Fe-S] cluster biosynthetic machineries in Azotobacter vinelandii 267
  17. 12. A stress-responsive Fe-S cluster biogenesis system in bacteria – the suf operon of Gammaproteobacteria 297
  18. 13. Sensing the cellular Fe-S cluster demand: a structural, functional, and phylogenetic overview of Escherichia coli IscR 325
  19. 14. Fe-S assembly in Gram-positive bacteria 347
  20. 15. Fe-S cluster assembly and regulation in yeast 367
  21. 16. The role of Fe-S clusters in regulation of yeast iron homeostasis 411
  22. 17. Biogenesis of Fe-S proteins in mammals 437
  23. 18. Iron-sulfur proteins and human diseases 455
  24. 19. Connecting the biosynthesis of the molybdenum cofactor, Fe-S clusters, and tRNA thiolation in humans 513
  25. 20. Iron-sulfur proteins and genome stability 541
  26. 21. Eukaryotic iron-sulfur protein biogenesis and its role in maintaining genomic integrity 563
  27. 22. Iron-sulfur cluster assembly in plants 599
  28. 23. Origin and evolution of Fe-S proteins and enzymes 619
  29. Index 637
https://doi.org/10.1515/9783110308426.325

Chapters in this book

  1. Frontmatter i
  2. Preface v
  3. Tracey A. Rouault biography vii
  4. Contents ix
  5. Contributing authors xxi
  6. 1. Iron-sulfur proteins: a historical perspective 1
  7. 2. Chemistry of iron-sulfur clusters 11
  8. 3. Quantitative interpretation of EPR spectroscopy with applications for iron-sulfur proteins 21
  9. 4. The utility of Mössbauer spectroscopy in eukaryotic cell biology and animal physiology 49
  10. 5. The interstitial carbide of the nitrogenase M-cluster: insertion pathway and possible function 77
  11. 6. The iron-molybdenum cofactor of nitrogenase 89
  12. 7. Biotin synthase: a role for iron-sulfur clusters in the radical-mediated generation of carbon-sulfur bonds 107
  13. 8. Molybdenum-containing iron-sulfur enzymes 133
  14. 9. The role of iron-sulfur clusters in the biosynthesis of the lipoyl cofactor 211
  15. 10. Iron-sulfur clusters and molecular oxygen: function, adaptation, degradation, and repair 239
  16. 11. A retrospective on the discovery of [Fe-S] cluster biosynthetic machineries in Azotobacter vinelandii 267
  17. 12. A stress-responsive Fe-S cluster biogenesis system in bacteria – the suf operon of Gammaproteobacteria 297
  18. 13. Sensing the cellular Fe-S cluster demand: a structural, functional, and phylogenetic overview of Escherichia coli IscR 325
  19. 14. Fe-S assembly in Gram-positive bacteria 347
  20. 15. Fe-S cluster assembly and regulation in yeast 367
  21. 16. The role of Fe-S clusters in regulation of yeast iron homeostasis 411
  22. 17. Biogenesis of Fe-S proteins in mammals 437
  23. 18. Iron-sulfur proteins and human diseases 455
  24. 19. Connecting the biosynthesis of the molybdenum cofactor, Fe-S clusters, and tRNA thiolation in humans 513
  25. 20. Iron-sulfur proteins and genome stability 541
  26. 21. Eukaryotic iron-sulfur protein biogenesis and its role in maintaining genomic integrity 563
  27. 22. Iron-sulfur cluster assembly in plants 599
  28. 23. Origin and evolution of Fe-S proteins and enzymes 619
  29. Index 637
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