Hydrogen sulfide (H₂S), a gasotransmitter naturally produced in the body by enzymes such as cystathionine γ lyase (CSE), helps reduce inflammation, oxidative stress, and abnormal tissue calcification. We present a novel strategy to boost endogenous H₂S production via CSE allosteric activation. Two CSE positive allosteric modulators (CSE-PAMs) were identified. Despite moderate binding affinity, both compounds induced a strong allosteric effect, increasing H₂S production by approximately 200 %. Cryo-electron microscopy and proteomics identified a distinct allosteric binding pocket on recombinant human CSE. In cellular assays, both compounds elevated H₂S levels. This correlated with inhibition of calcification. In chondrocytes, CSE-PAMs reduced alkaline phosphatase activity, inflammatory cytokine secretion, and oxidative stress, while enhancing protein persulfidation. These results highlight CSE-PAMs as promising therapeutic agents for conditions involving pathological calcification and inflammation, such as osteoarthritis. Additionally, they serve as valuable tools for investigating CSE-derived H₂S biology, previously limited by a lack of specific modulators.
Allosteric activators of cystathionine γ lyase to augment endogenous hydrogen sulfide and inhibit pathologic calcification / Nasi, S; Ehirchiou, D; Blatter, C; Chobaz, V; Germann, S; Brandenberger, A; Bommeli, E; Uchikawa, E; Cirino, G; Riedl, R; So, A; Busso, N. - In: PHARMACOLOGICAL RESEARCH. - ISSN 1043-6618. - 219:(2025). [10.1016/j.phrs.2025.107869]
Allosteric activators of cystathionine γ lyase to augment endogenous hydrogen sulfide and inhibit pathologic calcification.
Cirino G;
2025
Abstract
Hydrogen sulfide (H₂S), a gasotransmitter naturally produced in the body by enzymes such as cystathionine γ lyase (CSE), helps reduce inflammation, oxidative stress, and abnormal tissue calcification. We present a novel strategy to boost endogenous H₂S production via CSE allosteric activation. Two CSE positive allosteric modulators (CSE-PAMs) were identified. Despite moderate binding affinity, both compounds induced a strong allosteric effect, increasing H₂S production by approximately 200 %. Cryo-electron microscopy and proteomics identified a distinct allosteric binding pocket on recombinant human CSE. In cellular assays, both compounds elevated H₂S levels. This correlated with inhibition of calcification. In chondrocytes, CSE-PAMs reduced alkaline phosphatase activity, inflammatory cytokine secretion, and oxidative stress, while enhancing protein persulfidation. These results highlight CSE-PAMs as promising therapeutic agents for conditions involving pathological calcification and inflammation, such as osteoarthritis. Additionally, they serve as valuable tools for investigating CSE-derived H₂S biology, previously limited by a lack of specific modulators.| File | Dimensione | Formato | |
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