4def Citations

Active site loop dynamics of a class IIa fructose 1,6-bisphosphate aldolase from Mycobacterium tuberculosis.

Pegan SD, Rukseree K, Capodagli GC, Baker EA, Krasnykh O, Franzblau SG, Mesecar AD
Biochemistry 52 912-25 (2013)
Cited: 17 times
EuropePMC logo PMID: 23298222

Abstract

Class II fructose 1,6-bisphosphate aldolases (FBAs, EC 4.1.2.13) comprise one of two families of aldolases. Instead of forming a Schiff base intermediate using an ε-amino group of a lysine side chain, class II FBAs utilize Zn(II) to stabilize a proposed hydroxyenolate intermediate (HEI) in the reversible cleavage of fructose 1,6-bisphosphate, forming glyceraldehyde 3-phosphate and dihydroxyacetone phosphate (DHAP). As class II FBAs have been shown to be essential in pathogenic bacteria, focus has been placed on these enzymes as potential antibacterial targets. Although structural studies of class II FBAs from Mycobacterium tuberculosis (MtFBA), other bacteria, and protozoa have been reported, the structure of the active site loop responsible for catalyzing the protonation-deprotonation steps of the reaction for class II FBAs has not yet been observed. We therefore utilized the potent class II FBA inhibitor phosphoglycolohydroxamate (PGH) as a mimic of the HEI- and DHAP-bound form of the enzyme and determined the X-ray structure of the MtFBA-PGH complex to 1.58 Å. Remarkably, we are able to observe well-defined electron density for the previously elusive active site loop of MtFBA trapped in a catalytically competent orientation. Utilization of this structural information and site-directed mutagenesis and kinetic studies conducted on a series of residues within the active site loop revealed that E169 facilitates a water-mediated deprotonation-protonation step of the MtFBA reaction mechanism. Also, solvent isotope effects on MtFBA and catalytically relevant mutants were used to probe the effect of loop flexibility on catalytic efficiency. Additionally, we also reveal the structure of MtFBA in its holoenzyme form.

Articles - 4def mentioned but not cited (4)

  1. A noncompetitive inhibitor for Mycobacterium tuberculosis's class IIa fructose 1,6-bisphosphate aldolase. Capodagli GC, Sedhom WG, Jackson M, Ahrendt KA, Pegan SD. Biochemistry 53 202-213 (2014)
  2. Identification of potential small molecule allosteric modulator sites on IL-1R1 ectodomain using accelerated conformational sampling method. Yang CY. PLoS One 10 e0118671 (2015)
  3. Active site loop dynamics of a class IIa fructose 1,6-bisphosphate aldolase from Mycobacterium tuberculosis. Pegan SD, Rukseree K, Capodagli GC, Baker EA, Krasnykh O, Franzblau SG, Mesecar AD. Biochemistry 52 912-925 (2013)
  4. Structural and functional characterization of methicillin-resistant Staphylococcus aureus's class IIb fructose 1,6-bisphosphate aldolase. Capodagli GC, Lee SA, Boehm KJ, Brady KM, Pegan SD. Biochemistry 53 7604-7614 (2014)


Reviews citing this publication (3)

  1. Targeting Metalloenzymes for Therapeutic Intervention. Chen AY, Adamek RN, Dick BL, Credille CV, Morrison CN, Cohen SM. Chem Rev 119 1323-1455 (2019)
  2. Multifunctional Fructose 1,6-Bisphosphate Aldolase as a Therapeutic Target. Pirovich DB, Da'dara AA, Skelly PJ. Front Mol Biosci 8 719678 (2021)
  3. Inverse Solvent Isotope Effects in Enzyme-Catalyzed Reactions. Fernandez PL, Murkin AS. Molecules 25 E1933 (2020)

Articles citing this publication (10)

  1. Inactivation of fructose-1,6-bisphosphate aldolase prevents optimal co-catabolism of glycolytic and gluconeogenic carbon substrates in Mycobacterium tuberculosis. Puckett S, Trujillo C, Eoh H, Marrero J, Spencer J, Jackson M, Schnappinger D, Rhee K, Ehrt S. PLoS Pathog 10 e1004144 (2014)
  2. What's in your buffer? Solute altered millisecond motions detected by solution NMR. Wong M, Khirich G, Loria JP. Biochemistry 52 6548-6558 (2013)
  3. Active site remodeling during the catalytic cycle in metal-dependent fructose-1,6-bisphosphate aldolases. Jacques B, Coinçon M, Sygusch J. J Biol Chem 293 7737-7753 (2018)
  4. Aldolases Utilize Different Oligomeric States To Preserve Their Functional Dynamics. Katebi AR, Jernigan RL. Biochemistry 54 3543-3554 (2015)
  5. Structural basis of head to head polyketide fusion by CorB. Zocher G, Vilstrup J, Heine D, Hallab A, Goralski E, Hertweck C, Stahl M, Schäberle TF, Stehle T. Chem Sci 6 6525-6536 (2015)
  6. Proteomics for Drug Resistance on the Food Chain? Multidrug-Resistant Escherichia coli Proteomes from Slaughtered Pigs. Ramos S, Silva N, Hébraud M, Santos HM, Nunes-Miranda JD, Pinto L, Pereira JE, Capelo JL, Poeta P, Igrejas G. OMICS 20 362-374 (2016)
  7. Interrogating the Role of the Two Distinct Fructose-Bisphosphate Aldolases of Bacillus methanolicus by Site-Directed Mutagenesis of Key Amino Acids and Gene Repression by CRISPR Interference. Schultenkämper K, Gütle DD, López MG, Keller LB, Zhang L, Einsle O, Jacquot JP, Wendisch VF. Front Microbiol 12 669220 (2021)
  8. Asymmetric aldol reactions between acetone and benzaldehydes catalyzed by chiral Zn2+ complexes of aminoacyl 1,4,7,10-tetraazacyclododecane: fine-tuning of the amino-acid side chains and a revised reaction mechanism. Itoh S, Tokunaga T, Sonoike S, Kitamura M, Yamano A, Aoki S. Chem Asian J 8 2125-2135 (2013)
  9. Defining the molecular architecture, metal dependence, and distribution of metal-dependent class II sulfofructose-1-phosphate aldolases. Sharma M, Kaur A, Madiedo Soler N, Lingford JP, Epa R, Goddard-Borger ED, Davies GJ, Williams SJ. J Biol Chem 299 105338 (2023)
  10. Dynamozones are the most obvious sign of the evolution of conformational dynamics in HIV-1 protease. Rahimi M, Taghdir M, Abasi Joozdani F. Sci Rep 13 14179 (2023)


Quick links