Magdalena Zasadzki scite author profile

Acute lung injury (ALI) associated with sepsis and iatrogenic ventilator-induced lung injury resulting from mechanical ventilation are major medical problems with an unmet need for small molecule therapeutics. Prevailing hypotheses identify endothelial cell (EC) layer dysfunction as a cardinal event in the pathophysiology, with intracellular protein kinases as critical mediators of normal physiology and possible targets for drug discovery. The 210,000 molecular weight myosin light chain kinase (MLCK210, also called EC MLCK because of its abundance in EC) is hypothesized to be important for EC barrier function and might be a potential therapeutic target. To test these hypotheses directly, we made a selective MLCK210 knockout mouse that retains production of MLCK108 (also called smooth-muscle MLCK) from the same gene. The MLCK210 knockout mice are less susceptible to ALI induced by i.p. injection of the endotoxin lipopolysaccharide and show enhanced survival during subsequent mechanical ventilation. Using a complementary chemical biology approach, we developed a new class of small-molecule MLCK inhibitor based on the pharmacologically privileged aminopyridazine and found that a single i.p. injection of the inhibitor protected WT mice against ALI and death from mechanical ventilation complications. These convergent results from two independent approaches demonstrate a pivotal in vivo role for MLCK in susceptibility to lung injury and validate MLCK as a potential drug discovery target for lung injury.C urrent hypotheses (1, 2) identify dysfunction of the endothelial cell (EC) layer as a cardinal event in the pathophysiology of multiple medical conditions, including sepsis. The mortality associated with sepsis alone is similar (3) to that of acute myocardial infarction (MI). In contrast to MI, available therapies are limited for the treatment of sepsis and its associated tissue injuries (3, 4). Mechanical ventilation is often required for the support of patients with sepsis but is itself associated with additional, iatrogenic pulmonary injury that also appears to involve EC barrier dysfunction (5). Recent progress in the use of controlled ventilator strategies, such as positive end-expiratory pressure (PEEP), lessens the potential for ventilator-induced lung injury (VILI), but a need still exists for therapies that would prevent this clinical complication (5). Most recently, in vitro studies have linked a variety of EC signal transduction pathways to the physiological mechanisms of EC barrier function and identified several endothelial protein kinases as potential drug discovery targets (1). However, the integration of the knowledge regarding in vitro signal transduction pathways with in vivo pathophysiology related to compromised EC barrier function and the validation of potential EC therapeutic targets have not occurred.Homeostasis and resistance to tissue injury are maintained by a balance between intracellular EC cytoskeletal contractionrelaxation cycles and modulation of EC extracellular adhesion properties, whi...

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An aminopyridazine-based inhibitor of a pro-apoptotic protein kinase attenuates hypoxia-ischemia induced acute brain injury

Velentza

Wainwright

Zasadzki

et al. 2003

Bioorganic & Medicinal Chemistry Letters

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Discovery of a 3-Amino-6-phenyl-pyridazine Derivative as a New Synthetic Antineuroinflammatory Compound

et al. 2001

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Excessive glial activation, with overproduction of cytokines and oxidative stress products, is detrimental and a hallmark of neurodegenerative disease pathology. Suppression of glial activation is a potential therapeutic approach, and protein kinases are targets of some antiinflammatory drugs. To address an unmet need for selective inhibitors of glial activation, we developed a novel 3-amino-6-phenylpyridazine derivative that selectively blocks increased IL-1 beta, iNOS, and NO production by activated glia, without inhibition of potentially beneficial glial functions.

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Aminopyridazines Attenuate Hippocampus-Dependent Behavioral Deficits Induced by Human β-Amyloid in a Murine Model of Neuroinflammation

Craft

Eldik

Zasadzki

et al. 2004

JMN

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The importance of glial cell-driven neuroinflammation in the pathogenesis and progression of Alzheimer's disease (AD) led us to initiate a drug discovery effort targeting the neuroinflammatory cycle that is characteristic of AD. We used our synthetic chemistry platform focused on bioavailable aminopyridazines as a new chemotype for AD drug discovery to develop novel, selective suppressors of key inflammatory and oxidative pathways in glia. We found that MW01-070C, an aminopyridazine that works via mechanisms distinct from NSAIDs and p38 MAPK inhibitors, attenuates beta-amyloid (Abeta)-induced neuroinflammation and neuronal dysfunction in a dose-dependent manner, and prevents Abeta-induced behavioral impairment. In vivo data were obtained with a murine model that uses intraventricular infusion of human Abeta1-42 peptide and replicates many of the hallmarks of AD pathology, including neuroinflammation, neuronal and synaptic degeneration, and amyloid deposition. The quantifiable endpoint pathology is robust, reproducible, and rapid in onset. Our results provide a proof of concept that targeting neuroinflammation with aminopyridazines is a viable AD drug discovery approach that has the potential to modulate disease progression and document the utility of this mouse model for preclinical screening of compounds targeting AD-relevant neuroinflammation and neuronal death.

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Discovery of a New Class of Synthetic Protein Kinase Inhibitors that Suppress Selective Aspects of Glial Activation and Protect Against β-Amyloid Induced Injury: A Foundation for Future Medicinal Chemistry Efforts Focused on Targeting Alzheimer's Disease Progression

Watterson

Velentza

Zasadzki

et al. 2003

JMN

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A prevailing hypothesis in Alzheimer's disease (AD) research is that chronically activated glia may contribute to neuronal dysfunction, through generation of a detrimental state of neuroinflammation. This raises the possibility in drug discovery research of targeting the cycle of untoward glial activation and neuronal dysfunction that characterizes neuroinflammation. Success over the past century with effective anti-inflammatory drug development, in which the molecular targets are intracellular enzymes involved in signal transduction events and cellular homeostasis, demands that a similar approach be tried with neuroinflammation. Suggestive clinical correlations between inflammation markers and AD contribute to the urgency in addressing the hypothesis that targeting selective glial activation processes might be a therapeutic approach complementary to existing drugs and discovery efforts. An academic collaboratorium initiated a rapid inhibitor discovery effort 2 yr ago, focused on development of novel compounds with new mechanisms of action in AD-relevant cellular processes, in order to obtain the small-molecule compounds required to address the neuroinflammation hypothesis and provide a proof of concept for future medicinal chemistry efforts. We summarize here our progress toward this goal in which novel pyridazine-based inhibitors of gene-regulating protein kinases have been discovered. Feasibility studies indicate their potential utility in current medicinal chemistry efforts focused on improvement in molecular properties and the longer term targeting of AD-related pathogenic processes.

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