C. Cade scite author profile

Mycobacterium tuberculosis catalase-peroxidase (KatG) is a bifunctional hemoprotein that has been shown to activate isoniazid (INH), a pro-drug that is integral to frontline antituberculosis treatments. The activated species, presumed to be an isonicotinoyl radical, couples to NAD 1 /NADH forming an isoniazid-NADH adduct that ultimately confers anti-tubercular activity. To better understand the mechanisms of isoniazid activation as well as the origins of KatG-derived INH-resistance, we have compared the catalytic properties (including the ability to form the INH-NADH adduct) of the wild-type enzyme to 23 KatG mutants which have been associated with isoniazid resistance in clinical M. tuberculosis isolates. Neither catalase nor peroxidase activities, the two inherent enzymatic functions of KatG, were found to correlate with isoniazid resistance. Furthermore, catalase function was lost in mutants which lacked the Met-TyrTrp crosslink, the biogenic cofactor in KatG which has been previously shown to be integral to this activity. The presence or absence of the crosslink itself, however, was also found to not correlate with INH resistance. The KatG resistance-conferring mutants were then assayed for their ability to generate the INH-NADH adduct in the presence of peroxide (t-BuOOH and H 2 O 2 ), superoxide, and no exogenous oxidant (air-only background control). The results demonstrate that residue location plays a critical role in determining INH-resistance mechanisms associated with INH activation; however, different mutations at the same location can produce vastly different reactivities that are oxidant-specific. Furthermore, the data can be interpreted to suggest the presence of a second mechanism of INH-resistance that is not correlated with the formation of the INH-NADH adduct.

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Modifying Caspase-3 Activity by Altering Allosteric Networks

Cade

Swartz

MacKenzie

et al. 2014

Biochemistry

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Caspases have several allosteric sites that bind small molecules or peptides. Allosteric regulators are known to affect caspase enzyme activity, in general, by facilitating large conformational changes that convert the active enzyme to a zymogen-like form in which the substrate-binding pocket is disordered. Mutations in presumed allosteric networks also decrease activity, although large structural changes are not observed. Mutation of the central V266 to histidine in the dimer interface of caspase-3 inactivates the enzyme by introducing steric clashes that may ultimately affect positioning of a helix on the protein surface. The helix is thought to connect several residues in the active site to the allosteric dimer interface. In contrast to the effects of small molecule allosteric regulators, the substrate-binding pocket is intact in the mutant, yet the enzyme is inactive. We have examined the putative allosteric network, in particular the role of helix 3, by mutating several residues in the network. We relieved steric clashes in the context of caspase-3(V266H), and we show that activity is restored, particularly when the restorative mutation is close to H266. We also mimicked the V266H mutant by introducing steric clashes elsewhere in the allosteric network, generating several mutants with reduced activity. Overall, the data show that the caspase-3 native ensemble includes the canonical active state as well as an inactive conformation characterized by an intact substrate-binding pocket, but with an altered helix 3. The enzyme activity reflects the relative population of each species in the native ensemble.

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Caspases – Key Players in Apoptosis

Cade

Clark

2015

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Caspases are the terminal proteases involved in apoptosis, as well as being involved in inflammation. The apoptotic caspases can be classified as either initiator or effector caspases based on both their position in the caspase cascade and their activation mechanism. Initiator caspases require dimerization to be activated, and cleavage of a loop called the intersubunit linker stabilizes the active enzyme. Effector caspases, on the other hand, are found as dimers in the cell and cleavage of the intersubunit linker is the key step in their activation.The name caspase is short for cysteinyl aspartate-specific protease. As their name suggests, these enzymes hydrolyze peptide bonds after certain aspartate residues using a catalytic cysteine (with the aid of an active-site histidine residue). Caspases can be inhibited by endogenous inhibitors such as XIAP, by synthetic inhibitors which target either the active site or an allosteric site, or by post-translational modification. Further research is needed to find novel activators and inhibitors of caspases to treat diseases which involve misregulation of apoptosis.

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Caspase-3 T140F

Cade¹,

Swartz²,

MacKenzie³

et al. 2014

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Caspase-3 T140GV266H

Cade¹,

Swartz²,

MacKenzie³

et al. 2014

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C. Cade

Isoniazid‐resistance conferring mutations inMycobacterium tuberculosisKatG: Catalase, peroxidase, and INH‐NADH adduct formation activities

Modifying Caspase-3 Activity by Altering Allosteric Networks

Caspases – Key Players in Apoptosis

Caspase-3 T140F

Caspase-3 T140GV266H

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