Direct thrombin inhibitors built on the azaphenylalanine scaffold provoke degranulation of mast cells

Peternel, Luka; Štempelj, Mateja; Černe, Manica; Zega, Anamarija; Obreza, Aleš; Oblak, Marko; Drevenšek, Gorazd; Budihna, Marjan; Stanovnik, Lovro; Urleb, U.

doi:10.1160/th05-10-0683

Cited by 7 publications

(5 citation statements)

References 24 publications

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“…Hence, we suspected that an as‐yet‐unknown off‐target is responsible for the toxicity of these inhibitors, rather than the furin inhibition. As other groups have reported toxic effects of benzamidine‐derived protease inhibitors through a G i ‐dependent histamine release associated with a drop in blood pressure, [30,31] we speculated, if the MRGPRX2 could be an off‐target for these furin inhibitors. Our results reveal that the toxic effects of the strongly multibasic inhibitor MI‐1148 in mice may be explained at least in part by activation of MRGPRX2.…”

Section: Resultsmentioning

confidence: 94%

“…This suggested a different, but so far unknown mechanism, underlying the toxicity of these compounds. Other groups have also reported toxic effects via a sharp drop of arterial blood pressure for various benzamidine‐derivatives in rats, which were developed as thrombin inhibitors [29,30] . A benzamidine‐induced mast cell degranulation leading to a strong histamine release was described as reason for the drop of blood pressure and reduced tracheal airflow causing the mortality [30] .…”

Section: Resultsmentioning

confidence: 99%

“…Other groups have also reported toxic effects via a sharp drop of arterial blood pressure for various benzamidine‐derivatives in rats, which were developed as thrombin inhibitors [29,30] . A benzamidine‐induced mast cell degranulation leading to a strong histamine release was described as reason for the drop of blood pressure and reduced tracheal airflow causing the mortality [30] . In subsequent work, one of the groups reported that benzamidines provoke a release of histamine from mast cells via an activation of G i proteins, because the release could be blocked by treatment with pertussis toxin (PTX), an inhibitor of the G i protein [31] .…”

Section: Resultsmentioning

confidence: 99%

“…[29,30] A benzamidine-induced mast cell degranulation leading to a strong histamine release was described as reason for the drop of blood pressure and reduced tracheal airflow causing the mortality. [30] In subsequent work, one of the groups reported that benzamidines provoke a release of histamine from mast cells via an activation of G i proteins, because the release could be blocked by treatment with pertussis toxin (PTX), an inhibitor of the G i protein. [31] Therefore, we were interested in assessing whether the PTXsensitive G i -coupled Mas-related GPCR-X2 (MRGPRX2) could be a potential off-target of our benzamidine-derived furin inhibitors.…”

Section: The Mas-related Gpcr-x2 As Potential Off-target Of Benzamidi...mentioning

confidence: 99%

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Fragment‐Based Design, Synthesis, and Characterization of Aminoisoindole‐Derived Furin Inhibitors

Lange,

Bloch,

Heindl

et al. 2024

ChemMedChem

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A 1H‐isoindol‐3‐amine was identified as suitable P1 group for the proprotein convertase furin using a crystallographic screening with a set of 20 fragments known to occupy the S1 pocket of trypsin‐like serine proteases. Its binding mode is very similar to that observed for the P1 group of benzamidine‐derived peptidic furin inhibitors suggesting an aminomethyl substitution of this fragment to obtain a couplable P1 residue for the synthesis of substrate‐analogue furin inhibitors. The obtained inhibitors possess a slightly improved picomolar inhibitory potency compared to their benzamidine‐derived analogues. The crystal structures of two inhibitors in complex with furin revealed that the new P1 group is perfectly suited for incorporation in peptidic furin inhibitors. Selected inhibitors were tested for antiviral activity against respiratory syncytial virus (RSV) and a furin‐dependent influenza A virus (SC35M/H7N7) in A549 human lung cells and demonstrated an efficient inhibition of virus activation and replication at low micromolar or even submicromolar concentrations. First results suggest that the Mas‐related G‐protein coupled receptor GPCR‐X2 could be a potential off‐target for certain benzamidinederived furin inhibitors.

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Section: Resultsmentioning

confidence: 94%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: The Mas-related Gpcr-x2 As Potential Off-target Of Benzamidi...mentioning

confidence: 99%

See 2 more Smart Citations

Fragment‐Based Design, Synthesis, and Characterization of Aminoisoindole‐Derived Furin Inhibitors

Lange,

Bloch,

Heindl

et al. 2024

ChemMedChem

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“…Although ximelagatran was approved for clinical use in Europe, the US FDA rejected its application in 2004 due to concerns of hepatotoxicity [67]. Recent studies suggest that direct inhibitors that use a basic group as a P1-arginine mimic Fondaparinux for recognizing the enzyme appear to have another side effect -the degranulation of mast cells leading to histamine release [68,69]. Finally, trials with ximelagatran, and other direct inhibitors, e.g., dabigatran, DX9065a and razaxaban, show the persistence of bleeding risk [56,57,[60][61][62][63][64].…”

Section: Current Status Of Anticoagulation Therapymentioning

confidence: 99%

Recent Research Developments in the Direct Inhibition of Coagulation Proteinases – Inhibitors of the Initiation Phase

Henry¹,

Desai²

2008

CHAMC

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Physiologic clotting is a defensive action. The new cell-based model of hemostasis proposes three steps -initiation, amplification and propagation -occurring on specific cell surfaces to generate a thrombus in a tightly regulated manner. The initiation phase relies on key players including tissue factor (TF), factor VIIa (fVIIa), platelets, Ca 2+ , phospholipids, and factor X/Xa (fX/fXa). Exposure of TF on sub-endothelial and other blood cells triggers a coagulation response, which may have to be inhibited to prevent a deleterious thrombotic effect. Inhibiting TF-initiated coagulation, akin to 'nipping coagulation in the bud', is predicted to have major advantages, including a more efficient separation of the antithrombotic and hemorrhagic responses. The availability of crystal structures of TF, fVIIa and TFfVIIa complex makes structure-based drug design feasible. Although no initiation phase small molecule inhibitor has reached the clinic as yet, several molecules have displayed promise. We discuss recent results on the discovery of inhibitors of the initiation phase with special emphasis on peptides, peptidomimetics and organic small molecules.Key Words: Anticoagulants, coagulation, factor VIIa, tissue factor, thrombin, factor Xa, Enzyme Inhibition, small molecule inhibitors. CELL-BASED HEMOSTASISPhysiologic clotting is a defensive action preventing excessive loss of blood and infiltration of microbes. The physiologic mechanism that produces this defensive reaction is an enzymatic cascade ( Fig. 1), proposed nearly 50 years ago [1,2]. In vivo, the enzymatic reactions occur on specific cell surfaces. The cell-dependent coagulation cascade is proposed to proceed sequentially in three stepsinitiation, amplification and propagation -on specific cell surfaces to generate a thrombus in a tightly regulated manner [3][4][5]. InitiationTissue factor (TF) is an integral membrane protein present on several extravascular cells [6] and is the most important initiator of coagulation. Under normal conditions, it is sequestered from circulating proteinases, especially factor VII (fVII), thus preventing inappropriate initiation of clotting. Vascular injury exposes TF to blood, resulting in rapid complex formation with free activated fVII (fVIIa) on TF-bearing cells (Fig. 1). It is believed that some fVIIa is always present in blood (~1-2%), which can rapidly interact with TF to initiate clotting. The formation of TF/fVIIa complex activates the circulating factor X (fX) to fXa, the formation of which can induce further production of fVIIa and fXa [7][8][9]. The TF/fVIIa complex can also activate factor IX (fIX) to fIXa [10][11][12], which in turn can result in more fXa. The earliest fXa formed remains localized to the site of TF-bearing cells, yet is free enough to form the prothrombinase complex with factor Va (fVa). The small amount of the prothrombinase complex so formed is responsible for the initial production of thrombin from prothrombin [12]. The in vivo source of the initial fVa needed for the assembly of p...

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Anticoagulants

Henry

Desai

2010

Burger's Medicinal Chemistry and Drug Discovery

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Thrombotic disorders are a major cause of morbidity and mortality in humans. Examples of thrombotic disorders include pulmonary embolism, deep vein thrombosis, disseminated intravascular coagulation, acute myocardial infarction, unstable angina, and cerebrovascular thrombosis. Anticoagulants are the mainstay of treatment and prevention of these disorders. The most widely used anticoagulants include unfractionated heparin, low molecular weight heparins and warfarin. Newer agents introduced in the past decade include bivalirudin, fondaparinux, and argatroban. Mechanistically, these anticoagulants either directly inhibit thrombin or indirectly reduce the activity of thrombin and factor Xa. Several new molecules have been recently designed to directly inhibit thrombin and factor Xa with high potency and considerable selectivity, of which dabigatran and rivaroxaban were approved for clinical use in few countries in 2008. Molecules being pursued in clinical trials include AZD0837, LB‐30870, otamixaban, apixaban, YM‐150, and others. Ximelagatran, which was introduced in 2004 as a direct thrombin inhibitor, was taken off the market within 20 months due to significant hepatotoxicity. Indirect anticoagulants utilize the antithrombin‐mediated conformational activation and bridging mechanisms for inhibiting coagulation enzymes. Among the indirect anticoagulants that are currently being investigated in clinical trials are a biotinylated idraparinux and SR123781. Over the last two decades, major conceptual strides have been made including the design of the first anticoagulant based solely on factor Xa inhibition (fondaparinux) and the establishment of the paradigm that anticoagulation is possible without frequent laboratory monitoring (ximelagatran). Current work attempts to establish other concepts such as the dual inhibition of free and clot‐bound thrombin by a heparin‐based molecule (ORG42675) and the applicability of neutral P1‐group containing active site‐directed molecules as effective inhibitors of coagulation enzymes (rivaroxaban). To date, no molecule has been designed that satisfies all the properties of an ideal anticoagulant including a broad therapeutic window, absence of bleeding risk, no requirement for frequent coagulation monitoring, oral bioavailability, availability of an effective antidote, lack of hepatoxicity and absence other adverse effects. Yet, the newer agents are likely to be more attractive than the heparin‐ and coumarin‐based therapy. In this chapter, we review the structure, design, and mechanism of action of clinically used and new potential anticoagulants. Special emphasis is placed on the molecular interaction of anticoagulants with their targets.

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Direct thrombin inhibitors built on the azaphenylalanine scaffold provoke degranulation of mast cells

Cited by 7 publications

References 24 publications

Fragment‐Based Design, Synthesis, and Characterization of Aminoisoindole‐Derived Furin Inhibitors

Fragment‐Based Design, Synthesis, and Characterization of Aminoisoindole‐Derived Furin Inhibitors

Recent Research Developments in the Direct Inhibition of Coagulation Proteinases – Inhibitors of the Initiation Phase

Anticoagulants

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