Richard F. Heier scite author profile

Increased mucus production is a common cause of morbidity and mortality in inflammatory airway diseases, including asthma, chronic obstructive pulmonary disease (COPD), and cystic fibrosis. However, the precise molecular mechanisms for pathogenic mucus production are largely undetermined. Accordingly, there are no specific and effective anti-mucus therapeutics. Here, we define a signaling pathway from chloride channel calcium-activated 1 (CLCA1) to MAPK13 that is responsible for IL-13-driven mucus production in human airway epithelial cells. The same pathway was also highly activated in the lungs of humans with excess mucus production due to COPD. We further validated the pathway by using structure-based drug design to develop a series of novel MAPK13 inhibitors with nanomolar potency that effectively reduced mucus production in human airway epithelial cells. These results uncover and validate a new pathway for regulating mucus production as well as a corresponding therapeutic approach to mucus overproduction in inflammatory airway diseases.

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Self-cleavage of Human CLCA1 Protein by a Novel Internal Metalloprotease Domain Controls Calcium-activated Chloride Channel Activation

Yurtsever

Sala-Rabanal

Randolph

et al. 2012

Journal of Biological Chemistry

108

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Background: CLCA proteins activate CaCCs; CLCAs have roles in cancer and inflammatory lung diseases, but their mechanism of action is unknown. Results: CLCA proteins must undergo self-cleavage via their own novel metalloprotease domain in the N terminus to activate CaCCs. Conclusion: Self-cleavage unmasks the N-terminal fragment, which alone activates CaCCs. Significance: This work identifies a unique ion channel activation mechanism defining framework to understand CLCA functions in diseases.

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Synthesis and Biological Activities of (R)-5,6-Dihydro-N,N-dimethyl-4H-imidazo[4,5,1-ij]quinolin-5-amine and Its Metabolites

et al. 1997

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The imidazoquinoline (R)-5,6-Dihydro-N,N-dimethyl-4H-imidazo[4,5,1-ij]quinolin-5-amine [(R)-3] is a potent dopamine agonist when tested in animals but surprisingly shows very low affinity in in vitro binding assays. When incubated with mouse or monkey liver S9 microsomes, (R)-3 is metabolized by N-demethylation and oxidation to (R)-5,6-dihydro-5-(methylamino)-4H-imidazo[4,5,1-ij]quinolin-2(1H) -one [(R)-6], intermediate metabolites, where N-demethylation to the imidazoquinoline (R)-4 and where oxidation to the imidazoquinolinone (R)-5 has taken place, are also observed in these incubates. A cross-species study on the metabolism of (R)-3 in vitro has shown large variations in the extent of metabolism from species to species. Imidazoquinolinones (R)-5 and (R)-6 have comparable activity to (R)-3 in animals and also show good dopaminergic (D2) and serotonergic (5HT1A) activities in binding assays. It is probable that these metabolites account at least in part for the in vivo activity found for (R)-3. Efficient syntheses for compounds 3-6 as single enantiomers from quinoline are presented together with information on the biological activities and metabolic stabilities of these compounds.

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Targeting VLA4 integrin and CXCR2 mobilizes serially repopulating hematopoietic stem cells

Karpova¹,

Rettig²,

Ritchey³

et al. 2019

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he is an Advisory Board Member for Cellworks Group, RiverVest Venture Partners, and Arch Oncology. DMM is an employee of and owns equity in Magenta Therapeutics Inc. PGR has stock in Pfizer Inc. PGR and DWG are cofounders of, consultants for, and own equity in Indalo Therapeutics, a company pursuing clinical development of RGD-binding integrin antagonists, but not of antagonists of a α4β1 (VLA4). MPR serves as a consultant for RiverVest Venture Partners, and has received research funding from Amphivena Therapeutics, Novimmmune, and Cantex. MJM receives research funding from Ultragenyx Pharmaceutical Inc. and is the founder and owner of Meyers MedChem Consulting LLC. RFH is currently an employee of Confluence Discovery Technologies. LE has received research funding from MaxCyte Inc. HBB is a coinventor of patent PCT/EP2015/066083 from which he receives royalties and licensing fees; he has received honoraria from Miltenyi,

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Antifungal Phenothiazines: Optimization, Characterization of Mechanism, and Modulation of Neuroreceptor Activity

et al. 2017

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New classes of antifungal drugs are an urgent unmet clinical need. One approach to the challenge of developing new antifungal drugs is to optimize the antifungal properties of currently used drugs with favorable pharmacologic properties, so-called drug or scaffold repurposing. New therapies for cryptococcal meningitis are particularly important given its worldwide burden of disease and limited therapeutic options. We report the first systematic structure-activity study of the anticryptococcal properties of the phenothiazines. We also show that the antifungal activity of the phenothiazine scaffold correlates well with its calmodulin antagonism properties and, thereby, provides the first insights into the mechanism of its antifungal properties. Guided by this mechanism, we have generated improved trifluoperazine derivatives with increased anticryptococcal activity and, importantly, reduced affinity for receptors that modulate undesired neurological effects. Taken together, these data suggest that phenothiazines represent a potentially useful scaffold for further optimization in the search for new antifungal drugs.

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Richard F. Heier

IL-13–induced airway mucus production is attenuated by MAPK13 inhibition

Self-cleavage of Human CLCA1 Protein by a Novel Internal Metalloprotease Domain Controls Calcium-activated Chloride Channel Activation

Synthesis and Biological Activities of (R)-5,6-Dihydro-N,N-dimethyl-4H-imidazo[4,5,1-ij]quinolin-5-amine and Its Metabolites

Targeting VLA4 integrin and CXCR2 mobilizes serially repopulating hematopoietic stem cells

Antifungal Phenothiazines: Optimization, Characterization of Mechanism, and Modulation of Neuroreceptor Activity

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