Klaus Dembowsky scite author profile

Nitric oxide (NO) is a widespread, potent, biological mediator that has many physiological and pathophysiological roles. Research in the field of NO appears to have followed a straightforward path, and the findings have been progressive: NO and cyclic GMP are involved in vasodilatation; glycerol trinitrate relaxes vascular smooth muscles by bioconversion to NO; mammalian cells synthesize NO; and last, NO mediates vasodilatation by stimulating the soluble guanylate cyclase (sGC), a heterodimeric (alpha/beta) haem protein that converts GTP to cGMP2-4. Here we report the discovery of a regulatory site on sGC. Using photoaffinity labelling, we have identified the cysteine 238 and cysteine 243 region in the alpha1-subunit of sGC as the target for a new type of sGC stimulator. Moreover, we present a pyrazolopyridine, BAY 41-2272, that potently stimulates sGC through this site by a mechanism that is independent of NO. This results in antiplatelet activity, a strong decrease in blood pressure and an increase in survival in a low-NO rat model of hypertension, and as such may offer an approach for treating cardiovascular diseases.

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NO‐ and haem‐independent activation of soluble guanylyl cyclase: molecular basis and cardiovascular implications of a new pharmacological principle

Stasch

Schmidt

Alonso‐Alija

et al. 2002

British J Pharmacology

287

280

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1 Soluble guanylyl cyclase (sGC) is the only proven receptor for the ubiquitous biological messenger nitric oxide (NO) and is intimately involved in many signal transduction pathways, most notably in regulating vascular tone and platelet function. sGC is a heterodimeric (a/û) protein that converts GTP to cyclic GMP; NO binds to its prosthetic haem group. Here, we report the discovery of a novel sGC activating compound, its interaction with a previously unrecognized regulatory site and its therapeutic implications. 2 Through a high-throughput screen we identi®ed BAY 58-2667, an amino dicarboxylic acid which potently activates sGC in an NO-independent manner. In contrast to NO, YC-1 and BAY 41-2272, the sGC stimulators described recently, BAY 58-2667 activates the enzyme even after it has been oxidized by the sGC inhibitor ODQ or rendered haem de®cient. 3 Binding studies with radiolabelled BAY 58-2667 show a high anity site on the enzyme. 4 Using photoanity labelling studies we identi®ed the amino acids 371 (a-subunit) and 231 ± 310 (û-subunit) as target regions for BAY 58-2667. 5 sGC activation by BAY 58-2667 results in an antiplatelet activity both in vitro and in vivo and a potent vasorelaxation which is not in¯uenced by nitrate tolerance. 6 BAY 58-2667 shows a potent antihypertensive eect in conscious spontaneously hypertensive rats. In anaesthetized dogs the hemodynamic eects of BAY 58-2667 and GTN are very similar on the arterial and venous system. 7 This novel type of sGC activator is a valuable research tool and may oer a new approach for treating cardiovascular diseases.

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Atrial but Not Ventricular Fibrosis in Mice Expressing a Mutant Transforming Growth Factor-β ₁ Transgene in the Heart

Nakajima

Salcher

et al. 2000

Circulation Research

244

213

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Increased transforming growth factor (TGF)-beta(1) activity has been observed during pathologic cardiac remodeling in a variety of animal models. In an effort to establish a causal role of TGF-beta(1) in this process, transgenic mice with elevated levels of active myocardial TGF-beta(1) were generated. The cardiac-restricted alpha-myosin heavy chain promoter was used to target expression of a mutant TGF-beta(1) cDNA harboring a cysteine-to-serine substitution at amino acid residue 33. This alteration blocks covalent tethering of the TGF-beta(1) latent complex to the extracellular matrix, thereby rendering a large proportion (>60%) of the transgene-encoded TGF-beta(1) constitutively active. Although similar levels of active TGF-beta(1) were present in the transgenic atria and ventricles, overt fibrosis was observed only in the atria. Surprisingly, increased active TGF-beta(1) levels inhibited ventricular fibroblast DNA synthesis in uninjured hearts and delayed wound healing after myocardial injury. These data suggest that increased TGF-beta(1) activity by itself is insufficient to promote ventricular fibrosis in the adult mouse ventricle.

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The Role of Neutrophil Elastase Inhibitors in Lung Diseases

Polverino

Rosales-Mayor

Dale

et al. 2017

Chest

183

125

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Klaus Dembowsky

NO-independent regulatory site on soluble guanylate cyclase

NO‐ and haem‐independent activation of soluble guanylyl cyclase: molecular basis and cardiovascular implications of a new pharmacological principle

Atrial but Not Ventricular Fibrosis in Mice Expressing a Mutant Transforming Growth Factor-β ₁ Transgene in the Heart

The Role of Neutrophil Elastase Inhibitors in Lung Diseases

Contact Info

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Resources

About

Klaus Dembowsky

NO-independent regulatory site on soluble guanylate cyclase

NO‐ and haem‐independent activation of soluble guanylyl cyclase: molecular basis and cardiovascular implications of a new pharmacological principle

Atrial but Not Ventricular Fibrosis in Mice Expressing a Mutant Transforming Growth Factor-β 1 Transgene in the Heart

The Role of Neutrophil Elastase Inhibitors in Lung Diseases

Contact Info

Product

Resources

About

Atrial but Not Ventricular Fibrosis in Mice Expressing a Mutant Transforming Growth Factor-β ₁ Transgene in the Heart