2ddw Citations

Crystal structure of pyridoxal kinase from the Escherichia coli pdxK gene: implications for the classification of pyridoxal kinases.

Safo MK, Musayev FN, di Salvo ML, Hunt S, Claude JB, Schirch V
J Bacteriol 188 4542-52 (2006)
Related entries: 2ddm, 2ddo

Cited: 27 times
EuropePMC logo PMID: 16740960

Abstract

The pdxK and pdxY genes have been found to code for pyridoxal kinases, enzymes involved in the pyridoxal phosphate salvage pathway. Two pyridoxal kinase structures have recently been published, including Escherichia coli pyridoxal kinase 2 (ePL kinase 2) and sheep pyridoxal kinase, products of the pdxY and pdxK genes, respectively. We now report the crystal structure of E. coli pyridoxal kinase 1 (ePL kinase 1), encoded by a pdxK gene, and an isoform of ePL kinase 2. The structures were determined in the unliganded and binary complexes with either MgATP or pyridoxal to 2.1-, 2.6-, and 3.2-A resolutions, respectively. The active site of ePL kinase 1 does not show significant conformational change upon binding of either pyridoxal or MgATP. Like sheep PL kinase, ePL kinase 1 exhibits a sequential random mechanism. Unlike sheep pyridoxal kinase, ePL kinase 1 may not tolerate wide variation in the size and chemical nature of the 4' substituent on the substrate. This is the result of differences in a key residue at position 59 on a loop (loop II) that partially forms the active site. Residue 59, which is His in ePL kinase 1, interacts with the formyl group at C-4' of pyridoxal and may also determine if residues from another loop (loop I) can fill the active site in the absence of the substrate. Both loop I and loop II are suggested to play significant roles in the functions of PL kinases.

Articles - 2ddw mentioned but not cited (2)

  1. Crystal structure of pyridoxal kinase from the Escherichia coli pdxK gene: implications for the classification of pyridoxal kinases. Safo MK, Musayev FN, di Salvo ML, Hunt S, Claude JB, Schirch V. J Bacteriol 188 4542-4552 (2006)
  2. Crystal structure and molecular dynamics simulations of a promiscuous ancestor reveal residues and an epistatic interaction involved in substrate binding and catalysis in the ATP-dependent vitamin kinase family members. Gonzalez-Ordenes F, Bravo-Moraga F, Gonzalez E, Hernandez-Cabello L, Alzate-Morales J, Guixé V, Castro-Fernandez V. Protein Sci 30 842-854 (2021)


Reviews citing this publication (5)

  1. Vitamin B6: a long known compound of surprising complexity. Mooney S, Leuendorf JE, Hendrickson C, Hellmann H. Molecules 14 329-351 (2009)
  2. Canonical and ECF-type ATP-binding cassette importers in prokaryotes: diversity in modular organization and cellular functions. Eitinger T, Rodionov DA, Grote M, Schneider E. FEMS Microbiol Rev 35 3-67 (2011)
  3. Vitamin B₆ and Its Role in Cell Metabolism and Physiology. Parra M, Stahl S, Hellmann H. Cells 7 E84 (2018)
  4. Vitamin B6: Killing two birds with one stone? Mooney S, Hellmann H. Phytochemistry 71 495-501 (2010)
  5. Intracellular trafficking of the pyridoxal cofactor. Implications for health and metabolic disease. Whittaker JW. Arch Biochem Biophys 592 20-26 (2016)

Articles citing this publication (20)

  1. Molecular mechanisms of the non-coenzyme action of thiamin in brain: biochemical, structural and pathway analysis. Mkrtchyan G, Aleshin V, Parkhomenko Y, Kaehne T, Di Salvo ML, Parroni A, Contestabile R, Vovk A, Bettendorff L, Bunik V. Sci Rep 5 12583 (2015)
  2. The vitamin B₆ biosynthesis pathway in Streptococcus pneumoniae is controlled by pyridoxal 5'-phosphate and the transcription factor PdxR and has an impact on ear infection. El Qaidi S, Yang J, Zhang JR, Metzger DW, Bai G. J Bacteriol 195 2187-2196 (2013)
  3. Pyridoxal 5'-phosphate is a slow tight binding inhibitor of E. coli pyridoxal kinase. Ghatge MS, Contestabile R, di Salvo ML, Desai JV, Gandhi AK, Camara CM, Florio R, González IN, Parroni A, Schirch V, Safo MK. PLoS One 7 e41680 (2012)
  4. (p)ppGpp-mediated stress response induced by defects in outer membrane biogenesis and ATP production promotes survival in Escherichia coli. Roghanian M, Semsey S, Løbner-Olesen A, Jalalvand F. Sci Rep 9 2934 (2019)
  5. Lentivirus-mediated microRNA-124 gene-modified bone marrow mesenchymal stem cell transplantation promotes the repair of spinal cord injury in rats. Song JL, Zheng W, Chen W, Qian Y, Ouyang YM, Fan CY. Exp Mol Med 49 e332 (2017)
  6. Crystal Structure of human pyridoxal kinase: structural basis of M(+) and M(2+) activation. Musayev FN, di Salvo ML, Ko TP, Gandhi AK, Goswami A, Schirch V, Safo MK. Protein Sci 16 2184-2194 (2007)
  7. Ribokinase family evolution and the role of conserved residues at the active site of the PfkB subfamily representative, Pfk-2 from Escherichia coli. Cabrera R, Babul J, Guixé V. Arch Biochem Biophys 502 23-30 (2010)
  8. Crystal structures of human pyridoxal kinase in complex with the neurotoxins, ginkgotoxin and theophylline: insights into pyridoxal kinase inhibition. Gandhi AK, Desai JV, Ghatge MS, di Salvo ML, Di Biase S, Danso-Danquah R, Musayev FN, Contestabile R, Schirch V, Safo MK. PLoS One 7 e40954 (2012)
  9. Salmonella typhimurium PtsJ is a novel MocR-like transcriptional repressor involved in regulating the vitamin B6 salvage pathway. Tramonti A, Milano T, Nardella C, di Salvo ML, Pascarella S, Contestabile R. FEBS J 284 466-484 (2017)
  10. Chemical, genetic and structural assessment of pyridoxal kinase as a drug target in the African trypanosome. Jones DC, Alphey MS, Wyllie S, Fairlamb AH. Mol Microbiol 86 51-64 (2012)
  11. Kinetic and structural studies of the role of the active site residue Asp235 of human pyridoxal kinase. Gandhi AK, Ghatge MS, Musayev FN, Sease A, Aboagye SO, di Salvo ML, Schirch V, Safo MK. Biochem Biophys Res Commun 381 12-15 (2009)
  12. Reversible unfolding of dimeric phosphofructokinase-2 from Escherichia coli reveals a dominant role of inter-subunit contacts for stability. Baez M, Babul J. FEBS Lett 583 2054-2060 (2009)
  13. Pyridoxal kinase inhibition by artemisinins down-regulates inhibitory neurotransmission. Kasaragod VB, Pacios-Michelena A, Schaefer N, Zheng F, Bader N, Alzheimer C, Villmann C, Schindelin H. Proc Natl Acad Sci U S A 117 33235-33245 (2020)
  14. The expression of four pyridoxal kinase (PDXK) human variants in Drosophila impacts on genome integrity. Mascolo E, Barile A, Mecarelli LS, Amoroso N, Merigliano C, Massimi A, Saggio I, Hansen T, Tramonti A, Di Salvo ML, Barbetti F, Contestabile R, Vernì F. Sci Rep 9 14188 (2019)
  15. Cloning, purification and preliminary crystallographic analysis of a putative pyridoxal kinase from Bacillus subtilis. Newman JA, Das SK, Sedelnikova SE, Rice DW. Acta Crystallogr Sect F Struct Biol Cryst Commun 62 1006-1009 (2006)
  16. Inhibition of human pyridoxal kinase by 2-acetyl-4-((1R,2S,3R)-1,2,3,4-tetrahydroxybutyl)imidazole (THI). Elsinghorst PW, di Salvo ML, Parroni A, Contestabile R. J Enzyme Inhib Med Chem 30 336-340 (2015)
  17. MicroRNA339 Targeting PDXK Improves Motor Dysfunction and Promotes Neurite Growth in the Remote Cortex Subjected to Spinal Cord Transection. Xiong LL, Qin YX, Xiao QX, Jin Y, Al-Hawwas M, Ma Z, Wang YC, Belegu V, Zhou XF, Xue LL, Du RL, Liu J, Bai X, Wang TH. Front Cell Dev Biol 8 577 (2020)
  18. Catalytic and regulatory roles of species involved in metal-nucleotide equilibriums in human pyridoxal kinase. Navarro F, Ramírez-Sarmiento CA, Guixé V. Biometals 26 805-812 (2013)
  19. New Insights Into Pyridoxal Kinase Inhibitors and Their Antileukemic Effects. Banerjee P, Singh T, Qamar I. Cureus 15 e48176 (2023)
  20. Successful data recovery from oscillation photographs containing strong polycrystalline diffraction rings from an unknown small-molecule contaminant: preliminary structure solution of Salmonella typhimurium pyridoxal kinase (PdxK). Deka G, Kalyani JN, Benazir JF, Savithri HS, Murthy MR. Acta Crystallogr F Struct Biol Commun 70 526-529 (2014)


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