Recombinant<i>Mycobacterium tuberculosis</i>KatG(S315T) Is a Competent Catalase‐Peroxidase with Reduced Activity toward Isoniazid

Wengenack, Nancy L.; Uhl, James R.; Amand, Allison L. St.; Tomlinson, Andy J.; Benson, Linda M.; Naylor, Stephen; Kline, Bruce C.; Cockerill, F. R.; Rusnak, Frank

doi:10.1086/514096

Cited by 101 publications

(98 citation statements)

References 20 publications

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“…Both enzymes exhibited saturable catalase activity under the conditions employed for the kinetic study. The k cat (WT KatG, 6000 s Ϫ1 ; KatG(Y229F), 0.1 s Ϫ1 ) and K m values (WT KatG, 2.5 mM; KatG(Y229F), 40 mM) are within the ranges reported for these two enzymes (47,51), with minor differences being attributed to either different assay conditions (pH, temperature, and buffer) or differences in the recombinant enzymes used in the various studies. Overall, however, the result that catalase activity is severely disrupted for KatG(Y229F) versus that in WT KatG (k cat /K m ϳ 10 6 lower) is consistent with literature observations (25,27,47) that the Met-Tyr-Trp crosslink is essential for catalatic activity.…”

Section: Uv-visible Spectroscopy Of Wt Katg and Katg(y229f)-supporting

confidence: 59%

“…In the only other example of a Tyr-Trp bond, CcP(H52Y) (73), the histidine-to-tyrosine mutation allows for the formation of a C-N bond (as opposed to the C-C bond in M. tuberculosis KatG) between the indolic-N (N⑀1) of Trp 51 and the C⑀1 of Tyr 52 . Poulos and coworkers (73) argue that, given the short lifetimes of protein radicals, two sequential one-electron oxidations by two compound I intermediates (resulting from two enzyme turnovers) yielding the Tyr-Trp bond is unlikely to occur in CcP(H52Y).…”

Section: Fig 10mentioning

confidence: 99%

See 1 more Smart Citation

The Met-Tyr-Trp Cross-link in Mycobacterium tuberculosis Catalase-peroxidase (KatG)

Ghiladi

Knudsen

Medzihradszky

et al. 2005

Journal of Biological Chemistry

103

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Section: Uv-visible Spectroscopy Of Wt Katg and Katg(y229f)-supporting

confidence: 59%

Section: Fig 10mentioning

confidence: 99%

The Met-Tyr-Trp Cross-link in Mycobacterium tuberculosis Catalase-peroxidase (KatG)

Ghiladi

Knudsen

Medzihradszky

et al. 2005

Journal of Biological Chemistry

103

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“…Reports of INH activation in mixtures lacking an external oxidant (4,5,6,9,12,14,15) initially suggested that the peroxidatic process may not be required, but the mixtures of INH, NADH, and KatG would have supported NADH reduction of molecular oxygen to superoxide and low levels of H 2 O 2 (15) to activate the peroxidase reaction.…”

Section: Isonicotinic Acid Hydrazide (Isoniazid or Inh)mentioning

confidence: 99%

“…A multiplicity of methods has been employed to directly and indirectly assay INH activation, including the determination of INH oxidation to isonicotinic acid (9,10), the HPLC assay of INH disappearance (11), the inactivation of InhA in a mixture of InhA and KatG (7,12,13,14), the HPLC detection of IN⅐NAD (4,15), and the direct measurement of IN⅐NAD using its characteristic absorbance at 326 nm (6,7,12,15,16). Reports of INH activation in mixtures lacking an external oxidant (4,5,6,9,12,14,15) initially suggested that the peroxidatic process may not be required, but the mixtures of INH, NADH, and KatG would have supported NADH reduction of molecular oxygen to superoxide and low levels of H 2 O 2 (15) to activate the peroxidase reaction.…”

Section: Isonicotinic Acid Hydrazide (Isoniazid or Inh)mentioning

confidence: 99%

Isonicotinic Acid Hydrazide Conversion to Isonicotinyl-NAD by Catalase-peroxidases

Wiseman

Carpena

Feliz

et al. 2010

Journal of Biological Chemistry

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Activation of the pro-drug isoniazid (INH) as an anti-tubercular drug in Mycobacterium tuberculosis Isonicotinic acid hydrazide (isoniazid or INH)3 is a widely used anti-tubercular pro-drug that requires activation in a reaction involving the catalase-peroxidase KatG of Mycobacterium tuberculosis (MtKatG) (1) whereby the hydrazine group is removed and the isonicotinyl portion is added to NAD ϩ to generate isonicotinyl-NAD or IN⅐NAD (see Fig. 1). Once formed, IN⅐NAD inhibits the synthesis of mycolic acids, and therefore, the growth of M. tuberculosis, by binding to the longchain enoyl acyl carrier protein reductase (InhA) (2). Despite understanding the role of IN⅐NAD in the inhibition of mycolic acid synthesis and knowing that KatG is required for INH activation in vivo, uncertainties about the mechanism of its formation remain.The involvement of MtKatG in INH activation suggested that the peroxidatic process had a role, and this provided a focus for several studies employing external oxidants such as peroxyacetic acid (3), t-butyl hydroperoxide (4 -6) and low levels of H 2 O 2 (7, 6) to activate the peroxidatic pathway for INH oxidation and activation. In addition, EPR studies have demonstrated that INH can serve as an electron source to reduce peroxidatic intermediates, including specific Trp ⅐ radical species following peroxyacetic acid oxidation of MtKatG (3,8).A multiplicity of methods has been employed to directly and indirectly assay INH activation, including the determination of INH oxidation to isonicotinic acid (9, 10), the HPLC assay of INH disappearance (11), the inactivation of InhA in a mixture of InhA and KatG (7,12,13,14), the HPLC detection of IN⅐NAD (4, 15), and the direct measurement of IN⅐NAD using its characteristic absorbance at 326 nm (6,7,12,15,16). Reports of INH activation in mixtures lacking an external oxidant (4,5,6,9,12,14,15) initially suggested that the peroxidatic process may not be required, but the mixtures of INH, NADH, and KatG would have supported NADH reduction of molecular oxygen to superoxide and low levels of H 2 O 2 (15) to activate the peroxidase reaction.Despite the considerable evidence that a peroxidatic process is involved in IN⅐NAD synthesis, attempts to rationalize the reaction entirely in terms of the peroxidatic pathway generally produced models that were incomplete from the standpoint of electron balance (5,7,10) or that involved hypothetical intermediates not characterized in any other system (5, 6). For example, a common scheme shows the isonicotinyl radical, generated in a peroxidatic reaction, reacting with NAD ϩ to yield IN⅐NAD, when such a reaction would actually yield the IN⅐NAD ϩ ⅐ radical (Fig. 1). The need to reduce this radical in an oxidizing environment suggests that more than a simple peroxidatic pathway is involved in the INH activation process. This rationale leads to superoxide, O 2. , a known reducing agent with

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“…One of the most common causes of INH resistance is the Ser305Thr (S305T) mutation and, while remaining significant catalase and peroxidase activities, the [S305T] variant enzyme maintains the equivalent affinity for INH (Musser et al, 1996;Haas et al, 1997;Dobner et al, 1997;Marttila et al, 1998;Wengenack et al, 1997;Heym et al, 1995). The MtKatG [S305N] variant completely lost the ability to convert INH into the InhA inhibitor (Wei et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Functional Implication Guided by Structure-Based Study on Catalase – Peroxidase (KatG) from Haloarcula Marismortui

Sato¹

2012

Chemical Biology

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RecombinantMycobacterium tuberculosisKatG(S315T) Is a Competent Catalase‐Peroxidase with Reduced Activity toward Isoniazid

Cited by 101 publications

References 20 publications

The Met-Tyr-Trp Cross-link in Mycobacterium tuberculosis Catalase-peroxidase (KatG)

The Met-Tyr-Trp Cross-link in Mycobacterium tuberculosis Catalase-peroxidase (KatG)

Isonicotinic Acid Hydrazide Conversion to Isonicotinyl-NAD by Catalase-peroxidases

Functional Implication Guided by Structure-Based Study on Catalase – Peroxidase (KatG) from Haloarcula Marismortui

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