1f9n Citations

The structure of AhrC, the arginine repressor/activator protein from Bacillus subtilis.

Dennis C CA, Glykos NM, Parsons MR, Phillips SE
Acta Crystallogr D Biol Crystallogr 58 421-30 (2002)
Cited: 23 times
EuropePMC logo PMID: 11856827

Abstract

In the Gram-positive bacterium Bacillus subtilis the concentration of the amino acid L-arginine is controlled by the transcriptional regulator AhrC. The hexameric AhrC protein binds in an L-arginine-dependent manner to pseudo-palindromic operators within the promoter regions of arginine biosynthetic and catabolic gene clusters. AhrC binding results in the repression of transcription of biosynthetic genes and in the activation of transcription of catabolic genes. The crystal structure of AhrC has been determined at 2.7 A resolution. Each subunit of the protein has two domains. The C-terminal domains are arranged with 32 point-group symmetry and mediate the major intersubunit interactions. The N-terminal domains are located around this core, where they lie in weakly associated pairs but do not obey strict symmetry. A structural comparison of AhrC with the arginine repressor from the thermophile B. stearothermophilus reveals close similarity in regions implicated in L-arginine binding and DNA recognition, but also reveals some striking sequence differences, especially within the C-terminal oligomerization domain, which may contribute to the different thermostabilities of the proteins. Comparison of the crystal structure of AhrC with a 30 A resolution model obtained by combining X-ray structure-factor amplitudes with phases derived from electron-microscopic analyses of AhrC crystals confirms the essential accuracy of the earlier model and suggests that such an approach may be more widely useful for obtaining low-resolution phase information.

Articles - 1f9n mentioned but not cited (8)

  1. Listeria monocytogenes 10403S Arginine Repressor ArgR Finely Tunes Arginine Metabolism Regulation under Acidic Conditions. Cheng C, Dong Z, Han X, Sun J, Wang H, Jiang L, Yang Y, Ma T, Chen Z, Yu J, Fang W, Song H. Front Microbiol 8 145 (2017)
  2. A high-resolution structure of the DNA-binding domain of AhrC, the arginine repressor/activator protein from Bacillus subtilis. Garnett JA, Baumberg S, Stockley PG, Phillips SE. Acta Crystallogr Sect F Struct Biol Cryst Commun 63 914-917 (2007)
  3. Expression, purification and preliminary X-ray analysis of the C-terminal domain of an arginine repressor protein from Mycobacterium tuberculosis. Lu GJ, Garen CR, Cherney MM, Cherney LT, Lee C, James MN. Acta Crystallogr Sect F Struct Biol Cryst Commun 63 936-939 (2007)
  4. L-Proline Synthesis Mutants of Bacillus subtilis Overcome Osmotic Sensitivity by Genetically Adapting L-Arginine Metabolism. Stecker D, Hoffmann T, Link H, Commichau FM, Bremer E. Front Microbiol 13 908304 (2022)
  5. All Atom Motion Tree detects side chain-related motions and their coupling with domain motion in proteins. Koike R, Ota M. Biophys Physicobiol 16 280-286 (2019)
  6. Conserved Dynamic Mechanism of Allosteric Response to L-arg in Divergent Bacterial Arginine Repressors. Pandey SK, Melichercik M, Řeha D, Ettrich RH, Carey J. Molecules 25 E2247 (2020)
  7. Structural Analysis and Insights into the Oligomeric State of an Arginine-Dependent Transcriptional Regulator from Bacillus halodurans. Park YW, Kang J, Yeo HK, Lee JY. PLoS One 11 e0155396 (2016)
  8. Crystallization and preliminary X-ray diffraction analysis of the arginine repressor of the hyperthermophile Thermotoga neapolitana. Massant J, Peeters E, Charlier D, Maes D. Acta Crystallogr Sect F Struct Biol Cryst Commun 62 26-28 (2006)


Reviews citing this publication (1)

  1. Pathways and regulation of bacterial arginine metabolism and perspectives for obtaining arginine overproducing strains. Lu CD, Lu CD. Appl Microbiol Biotechnol 70 261-272 (2006)

Articles citing this publication (14)

  1. Regulation of arginine acquisition and virulence gene expression in the human pathogen Streptococcus pneumoniae by transcription regulators ArgR1 and AhrC. Kloosterman TG, Kuipers OP. J Biol Chem 286 44594-44605 (2011)
  2. Regulation of the arginine deiminase system by ArgR2 interferes with arginine metabolism and fitness of Streptococcus pneumoniae. Schulz C, Gierok P, Petruschka L, Lalk M, Mäder U, Hammerschmidt S. mBio 5 e01858-14 (2014)
  3. Structure and function of the arginine repressor-operator complex from Bacillus subtilis. Garnett JA, Marincs F, Baumberg S, Stockley PG, Phillips SE. J Mol Biol 379 284-298 (2008)
  4. Two arginine repressors regulate arginine biosynthesis in Lactobacillus plantarum. Nicoloff H, Arsène-Ploetze F, Malandain C, Kleerebezem M, Bringel F. J Bacteriol 186 6059-6069 (2004)
  5. Hyperthermophilic Thermotoga arginine repressor binding to full-length cognate and heterologous arginine operators and to half-site targets. Morin A, Huysveld N, Braun F, Dimova D, Sakanyan V, Charlier D. J Mol Biol 332 537-553 (2003)
  6. Structure of the C-terminal effector-binding domain of AhrC bound to its corepressor L-arginine. Garnett JA, Baumberg S, Stockley PG, Phillips SE. Acta Crystallogr Sect F Struct Biol Cryst Commun 63 918-921 (2007)
  7. The structure of the arginine repressor from Mycobacterium tuberculosis bound with its DNA operator and Co-repressor, L-arginine. Cherney LT, Cherney MM, Garen CR, James MN. J Mol Biol 388 85-97 (2009)
  8. Crystal structure of the arginine repressor protein in complex with the DNA operator from Mycobacterium tuberculosis. Cherney LT, Cherney MM, Garen CR, Lu GJ, James MN. J Mol Biol 384 1330-1340 (2008)
  9. Regulation of arginine biosynthesis in the psychropiezophilic bacterium Moritella profunda: in vivo repressibility and in vitro repressor-operator contact probing. Xu Y, Sun Y, Huysveld N, Gigot D, Glansdorff N, Charlier D. J Mol Biol 326 353-369 (2003)
  10. Assembly of the hexameric Escherichia coli arginine repressor investigated by nano-electrospray ionization time-of-flight mass spectrometry. Samalíková M, Carey J, Grandori R. Rapid Commun Mass Spectrom 19 2549-2552 (2005)
  11. Catabolic Ornithine Carbamoyltransferase Activity Facilitates Growth of Staphylococcus aureus in Defined Medium Lacking Glucose and Arginine. Reslane I, Halsey CR, Stastny A, Cabrera BJ, Ahn J, Shinde D, Galac MR, Sladek MF, Razvi F, Lehman MK, Bayles KW, Thomas VC, Handke LD, Fey PD. mBio 13 e0039522 (2022)
  12. The argRB of Escherichia coli is rare in isolates obtained from natural sources. Merlo LM, Sadowsky MJ, Ferguson JA, Dean AM. Gene 376 240-247 (2006)
  13. Application of the linear interaction energy method (LIE) to estimate the binding free energy values of Escherichia coli wild-type and mutant arginine repressor C-terminal domain (ArgRc)-l-arginine and ArgRc-l-citrulline protein-ligand complexes. Asi AM, Rahman NA, Merican AF. J Mol Graph Model 22 249-262 (2004)
  14. Staphylococcus aureus Does Not Synthesize Arginine from Proline under Physiological Conditions. Jeong B, Shah MA, Roh E, Kim K, Park I, Bae T. J Bacteriol 204 e0001822 (2022)


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