1urb Citations

Kinetic and structural consequences of replacing the aspartate bridge by asparagine in the catalytic metal triad of Escherichia coli alkaline phosphatase.

Tibbitts TT, Murphy JE, Kantrowitz ER
J Mol Biol 257 700-15 (1996)
Related entries: 1alk, 1ani, 1anj, 1ura, 2anh

Cited: 20 times
EuropePMC logo PMID: 8648634

Abstract

In each subunit of the homodimeric enzyme Escherichia coli alkaline phosphatase, two of the three metal cofactors Zn2+ and Mg2+, are bound by an aspartate side-chain at position 51. Using site-specific mutagenesis, Asp51 was mutated both to alanine and to asparagine to produce the D51A and D51N enzymes, respectively. Over the range of pH values examined, the D51A enzyme did not catalyze phosphate ester hydrolysis above non-enzymic levels and was not activated by the addition of millimolar excess Zn2+ or Mg2+. Replacement of Asp51 by asparagine, however, resulted in a mutant enzyme with reduced activity and a higher pH optimum, compared with the wild-type enzyme. At pH 8.0 the D51N enzyme showed about 1% of the activity of the wild-type enzyme, and as the pH was raised to 9.2, the activity of the D51N enzyme increased to about 10% of the value for the wild-type enzyme. Upon the addition of excess Mg2+ at pH 9.2, the D51N enzyme was activated in a time-dependent fashion to nearly the same level as the wild-type enzyme. The affinity for phosphate of the D51N enzyme decreased tenfold as the concentration of Mg2+ increased. Under optimal conditions, the k(cat)/K(m) ratio for the D51N enzyme indicated that it was 87% as efficient as the wild-type enzyme. To investigate the molecular basis for the observed kinetic differences, X-ray data were collected for the D51N enzyme to 2.3 angstroms resolution at pH 7.5, and then to 2.1 angstroms resolution at pH 9.2 with 20 mM MgCl2. The two structures were then refined. The low magnesium, low pH D51N structure showed that the third metal site was unoccupied, apparently blocked by the amide group of Asn51. At this pH the phosphate anion was bound via one oxygen atom, between the zinc cations at the first and second metal sites, which strongly resembled the arrangement previously determined for the D153H enzyme at pH 7.5. In the high magnesium, high pH D51N structure, the third metal site was also vacant, but the phosphate anion bound closer to the surface of the enzyme, coordinated to the first metal site alone. Electron density difference maps provide evidence that magnesium activates the D51N enzyme by replacing zinc at the second metal site.

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  2. Comparative enzymology in the alkaline phosphatase superfamily to determine the catalytic role of an active-site metal ion. Zalatan JG, Fenn TD, Herschlag D. J Mol Biol 384 1174-1189 (2008)
  3. High-resolution analysis of Zn(2+) coordination in the alkaline phosphatase superfamily by EXAFS and x-ray crystallography. Bobyr E, Lassila JK, Wiersma-Koch HI, Fenn TD, Lee JJ, Nikolic-Hughes I, Hodgson KO, Rees DC, Hedman B, Herschlag D. J Mol Biol 415 102-117 (2012)
  4. Crystal structure of alkaline phosphatase from the Antarctic bacterium TAB5. Wang E, Koutsioulis D, Leiros HK, Andersen OA, Bouriotis V, Hough E, Heikinheimo P. J Mol Biol 366 1318-1331 (2007)
  5. Role of metal ions on the secondary and quaternary structure of alkaline phosphatase from bovine intestinal mucosa. Bortolato M, Besson F, Roux B. Proteins 37 310-318 (1999)
  6. The zinc-binding site of a class I aminoacyl-tRNA synthetase is a SWIM domain that modulates amino acid binding via the tRNA acceptor arm. Banerjee R, Dubois DY, Gauthier J, Lin SX, Roy S, Lapointe J. Eur J Biochem 271 724-733 (2004)
  7. Extensive site-directed mutagenesis reveals interconnected functional units in the alkaline phosphatase active site. Sunden F, Peck A, Salzman J, Ressl S, Herschlag D. Elife 4 (2015)
  8. Effects of replacing active site residues in a cold-active alkaline phosphatase with those found in its mesophilic counterpart from Escherichia coli. Gudjónsdóttir K, Asgeirsson B. FEBS J 275 117-127 (2008)
  9. Prediction of distal residue participation in enzyme catalysis. Brodkin HR, DeLateur NA, Somarowthu S, Mills CL, Novak WR, Beuning PJ, Ringe D, Ondrechen MJ. Protein Sci 24 762-778 (2015)
  10. Crystal structure of rat intestinal alkaline phosphatase--role of crown domain in mammalian alkaline phosphatases. Ghosh K, Mazumder Tagore D, Anumula R, Lakshmaiah B, Kumar PP, Singaram S, Matan T, Kallipatti S, Selvam S, Krishnamurthy P, Ramarao M. J Struct Biol 184 182-192 (2013)
  11. Differentiation of the slow-binding mechanism for magnesium ion activation and zinc ion inhibition of human placental alkaline phosphatase. Hung HC, Chang GG. Protein Sci 10 34-45 (2001)
  12. Characterization of a monomeric heat-labile classical alkaline phosphatase from Anabaena sp. PCC7120. Luo M, Guo YC, Deng JY, Wei HP, Zhang ZP, Leng Y, Men D, Song LR, Zhang XE, Zhou YF. Biochemistry (Mosc) 75 655-664 (2010)
  13. Coordination sphere of the third metal site is essential to the activity and metal selectivity of alkaline phosphatases. Koutsioulis D, Lyskowski A, Mäki S, Guthrie E, Feller G, Bouriotis V, Heikinheimo P. Protein Sci 19 75-84 (2010)
  14. Computational modeling of the catalytic mechanism of human placental alkaline phosphatase (PLAP). Borosky GL, Lin S. J Chem Inf Model 51 2538-2548 (2011)
  15. Distinct structure and activity recoveries reveal differences in metal binding between mammalian and Escherichia coli alkaline phosphatases. Zhang L, Buchet R, Azzar G. Biochem J 392 407-415 (2005)
  16. Effect of a T81A mutation at the subunit interface on catalytic properties of alkaline phosphatase from Escherichia coli. Orhanović S, Bucević-Popović V, Pavela-Vrancic M, Vujaklija D, Gamulin V. Int J Biol Macromol 40 54-58 (2006)
  17. Effects of magnesium ions on thermal inactivation of alkaline phosphatase. Zhu Y, Song XY, Zhao WH, Zhang YX. Protein J 24 479-485 (2005)


Related citations provided by authors (3)

  1. Mutations at positions 153 and 328 in Escherichia coli alkaline phosphatase provide insight towards the structure and function of mammalian and yeast alkaline phosphatases.. Murphy JE, Tibbitts TT, Kantrowitz ER J Mol Biol 253 604-17 (1995)
  2. Kinetics and Crystal Structure of a Mutant E. Coli Alkaline Phosphatase (Asp-369->Asn): A Mechanism Involving One Zinc Per Active Site. Tibbitts TT, Xu X, Kantrowitz ER Protein Sci. 3 2005- (1994)
  3. Reaction mechanism of alkaline phosphatase based on crystal structures. Two-metal ion catalysis.. Kim EE, Wyckoff HW J Mol Biol 218 449-64 (1991)

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