Hydralazine Inhibits Rapid Acrolein-Induced Protein Oligomerization: Role of Aldehyde Scavenging and Adduct Trapping in Cross-Link Blocking and Cytoprotection

Burcham, Philip; Pyke, Simon M.

doi:10.1124/mol.105.018168

Cited by 78 publications

(83 citation statements)

References 37 publications

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“…Thus, the production of ROS or so-called free radicals (such as superoxide (O 2 -), hydroxyl ions (OH), and hydrogen peroxide (H 2 O 2 ), is a direct result leading to skyrocketing, secondary oxidative stress. Understandably, such endogenous and deleterious substances continue to result in progressive cell destruction via LPO and its derivatives, toxic intracellular aldehydes (Burcham et al, 2004;Burcham and Pyke, 2006;Shi et al, 2002). Since these toxins, like acrolein, can pass through intact healthy membranes, their intracellular concentration increases in the microenvironment permitting the poisoning of nearby undamaged cells (called 'bystander damage').…”

Section: Chitosan Blocks the Generation Of Ros And Lpomentioning

confidence: 99%

“…Thus, as with reactive oxygen species, chitosan does not show any ability to scavenge acrolein, and even the application of highly concentrated chitosan does not repair injury associated with acrolein toxicity (Fig.6). On the contrary immediate treatment with hydralazine, a well-known acrolein scavenger, permitted recovery from mitochondrial injury and abnormal oxidative metabolism (Burcham and Pyke, 2006;LiuSnyder et al, 2006). In summary, chitosan enabled the reduction of ROS and LPO production by the restoration of disrupted plasma membrane.…”

Section: Chitosan Blocks the Generation Of Ros And Lpomentioning

confidence: 99%

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Chitosan produces potent neuroprotection and physiological recovery following traumatic spinal cord injury

Cho

Shi

Borgens

2010

Journal of Experimental Biology

115

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SUMMARYChitosan, a non-toxic biodegradable polycationic polymer with low immunogenicity, has been extensively investigated in various biomedical applications. In this work, chitosan has been demonstrated to seal compromised nerve cell membranes thus serving as a potent neuroprotector following acute spinal cord trauma. Topical application of chitosan after complete transection or compression of the guinea pig spinal cord facilitated sealing of neuronal membranes in ex vivo tests, and restored the conduction of nerve impulses through the length of spinal cords in vivo, using somatosensory evoked potential recordings. Moreover, chitosan preferentially targeted damaged tissues, served as a suppressor of reactive oxygen species (free radical) generation, and the resultant lipid peroxidation of membranes, as shown in ex vivo spinal cord samples. These findings suggest a novel medical approach to reduce the catastrophic loss of behavior after acute spinal cord and brain injury.

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Section: Chitosan Blocks the Generation Of Ros And Lpomentioning

confidence: 99%

Section: Chitosan Blocks the Generation Of Ros And Lpomentioning

confidence: 99%

Chitosan produces potent neuroprotection and physiological recovery following traumatic spinal cord injury

Cho

Shi

Borgens

2010

Journal of Experimental Biology

115

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“…Strong adduct trapping also accompanied hydralazine protection against allyl alcohol hepatotoxicity in mice (Kaminskas et al, 2004b). How adduct trapping might confer protection was unclear, but one possibility was that hydralazine inactivated carbonyl-retaining Michael adducts before their participation in cross-linking with neighboring macromolecules (Burcham and Pyke, 2006). Contrary to this expectation however, hydralazine failed to block acrolein-induced protein crosslinking in cultured lung cells (Burcham et al, 2007).…”

Section: Introductionmentioning

confidence: 60%

“…Although hydralazine displays excellent reactivity toward "free" unsaturated aldehydes in model in vitro systems, it is unclear whether these properties apply within complex intracellular environments (Burcham and Pyke, 2006). To address this issue in the lung cell model used in the present study, we determined whether hydralazine suppressed acrolein-induced adduction of IFs, which are known targets for acrolein in lung cells (Burcham et al, 2010).…”

Section: Resultsmentioning

confidence: 99%

“…The mechanism(s) underlying drug efficacy in these models is unclear because the direct reactivity of hydralazine with electrophilic carbonyls may be constrained within biological systems. For example, in a hepatocyte model in which acrolein was generated enzymatically from allyl alcohol, hydralazine prevented cell death without lowering either extracellular "free acrolein" levels or the formation of protein adducts (Burcham et al, 2006). Others have also observed that hydralazine fails to block protein carbonylation in cultured cells, concluding instead that antioxidant actions mediate the cytoprotection (Mehta et al, 2009;Zheng and Bizzozero, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Chaperone Heat Shock Protein 90 Mobilization and Hydralazine Cytoprotection against Acrolein-Induced Carbonyl Stress

Burcham

Raso²,

Kaminskas

2012

Mol Pharmacol

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Toxic carbonyls such as acrolein participate in many degenerative diseases. Although the nucleophilic vasodilatory drug hydralazine readily traps such species under "test-tube" conditions, whether these reactions adequately explain its efficacy in animal models of carbonyl-mediated disease is uncertain. We have previously shown that hydralazine attacks carbonyl-adducted proteins in an "adduct-trapping" reaction that appears to take precedence over direct "carbonyl-sequestering" reactions, but how this reaction conferred cytoprotection was unclear. This study explored the possibility that by increasing the bulkiness of acrolein-adducted proteins, adduct-trapping might alter the redistribution of chaperones to damaged cytoskeletal proteins that are known targets for acrolein. Using A549 lung adenocarcinoma cells, the levels of chaperones heat shock protein (Hsp) 40, Hsp70, Hsp90, and Hsp110 were measured in intermediate filament extracts prepared after a 3-h exposure to acrolein. Exposure to acrolein alone modestly increased the levels of all four chaperones. Coexposure to hydralazine (10 -100 M) strongly suppressed cell ATP loss while producing strong adduct-trapping in intermediate filaments. Most strikingly, hydralazine selectively boosted the levels of cytoskeletal-associated Hsp90, including a high-mass species that was sensitive to the Hsp90 inhibitor 17-N-allylamino-17-demethoxygeldanamycin. Biochemical fractionation of acrolein-and hydralazine-treated cells revealed that hydralazine likely promoted Hsp90 migration from cytosol into other subcellular compartments. A role for Hsp90 mobilization in cytoprotection was confirmed by the finding that brief heat shock treatment suppressed acute acrolein toxicity in A549 cells. Taken together, these findings suggest that by increasing the steric bulk of carbonyl-adducted proteins, adduct-trapping drugs trigger the intracellular mobilization of the key molecular chaperone Hsp90.

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Acrolein and Unsaturated Aldehydes

Bein¹,

Leikauf²

2020

Environmental Toxicants

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Hydralazine Inhibits Rapid Acrolein-Induced Protein Oligomerization: Role of Aldehyde Scavenging and Adduct Trapping in Cross-Link Blocking and Cytoprotection

Cited by 78 publications

References 37 publications

Chitosan produces potent neuroprotection and physiological recovery following traumatic spinal cord injury

Chitosan produces potent neuroprotection and physiological recovery following traumatic spinal cord injury

Chaperone Heat Shock Protein 90 Mobilization and Hydralazine Cytoprotection against Acrolein-Induced Carbonyl Stress

Acrolein and Unsaturated Aldehydes

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