Juanlo Catena scite author profile

G protein-coupled receptors (GPCR), including the metabotrobic glutamate 5 receptor (mGlu5), are important therapeutic targets and the development of allosteric ligands for targeting GPCRs has become a desirable approach toward modulating receptor activity. Traditional pharmacological approaches toward modulating GPCR activity are still limited since precise spatiotemporal control of a ligand is lost as soon as it is administered. Photopharmacology proposes the use of photoswitchable ligands to overcome this limitation, since their activity can be reversibly controlled by light with high precision. As this is still a growing field, our understanding of the molecular mechanisms underlying the light-induced changes of different photoswitchable ligand pharmacology is suboptimal. For this reason, we have studied the mechanisms of action of alloswitch-1 and MCS0331; two freely diffusible, mGlu5 phenylazopyridine photoswitchable negative allosteric modulators. We combined photochemical, cell-based, and in vivo photopharmacological approaches to investigate the effects of trans–cis azobenzene photoisomerization on the functional activity and binding ability of these ligands to the mGlu5 allosteric pocket. From these results, we conclude that photoisomerization can take place inside and outside the ligand binding pocket, and this leads to a reversible loss in affinity, in part, due to changes in dissociation rates from the receptor. Ligand activity for both photoswitchable ligands deviates from high-affinity mGlu5 negative allosteric modulation (in the trans configuration) to reduced affinity for the mGlu5 in their cis configuration. Importantly, this mechanism translates to dynamic and reversible control over pain following local injection and illumination of negative allosteric modulators into a brain region implicated in pain control.

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A Photoswitchable Ligand Targeting the β₁‐Adrenoceptor Enables Light‐Control of the Cardiac Rhythm**

Duran-Corbera

Faria

et al. 2022

Angew Chem Int Ed

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Catecholamine-triggered β-adrenoceptor (β-AR) signaling is essential for the correct functioning of the heart. Although both β 1 -and β 2 -AR subtypes are expressed in cardiomyocytes, drugs selectively targeting β 1 -AR have proven this receptor as the main target for the therapeutic effects of beta blockers in the heart. Here, we report a new strategy for the light-control of β 1 -AR activation by means of photoswitchable drugs with a high level of β 1 -/β 2 -AR selectivity. All reported molecules allow for an efficient real-time optical control of receptor function in vitro. Moreover, using confocal microscopy we demonstrate that the binding of our best hit, pAzo-2, can be reversibly photocontrolled. Strikingly, pAzo-2 also enables a dynamic cardiac rhythm management on living zebrafish larvae using light, thus highlighting the therapeutic and research potential of the developed photoswitches. Overall, this work provides the first proof of precise control of the therapeutic target β 1 -AR in native environments using light.

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Correction: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Font¹,

López-Cano²,

Notartomaso³

et al. 2018

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Author response: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Font

López-Cano

Notartomaso

et al. 2017

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Light-operated drugs constitute a major target in drug discovery, since they may provide spatiotemporal resolution for the treatment of complex diseases (i.e. chronic pain). JF-NP-26 is an inactive photocaged derivative of the metabotropic glutamate type 5 (mGlu 5 ) receptor negative allosteric modulator raseglurant. Violet light illumination of JF-NP-26 induces a photochemical reaction prompting the active-drug's release, which effectively controls mGlu 5 receptor activity both in ectopic expressing systems and in striatal primary neurons. Systemic administration in mice followed by local light-emitting diode (LED)-based illumination, either of the thalamus or the peripheral tissues, induced JF-NP-26-mediated light-dependent analgesia both in neuropathic and in acute/tonic inflammatory pain models. These data offer the first example of optical control of analgesia in vivo using a photocaged mGlu 5 receptor negative allosteric modulator. This approach shows potential for precisely targeting, in time and space, endogenous receptors, which may allow a better management of difficult-to-treat disorders.

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Caged-carvedilol as a new tool for visible-light photopharmacology of β-adrenoceptors in native tissues

et al. 2022

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Juanlo Catena

Mechanistic Insights into Light-Driven Allosteric Control of GPCR Biological Activity

A Photoswitchable Ligand Targeting the β₁‐Adrenoceptor Enables Light‐Control of the Cardiac Rhythm**

Correction: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Author response: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Caged-carvedilol as a new tool for visible-light photopharmacology of β-adrenoceptors in native tissues

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Juanlo Catena

Mechanistic Insights into Light-Driven Allosteric Control of GPCR Biological Activity

A Photoswitchable Ligand Targeting the β1‐Adrenoceptor Enables Light‐Control of the Cardiac Rhythm**

Correction: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Author response: Optical control of pain in vivo with a photoactive mGlu5 receptor negative allosteric modulator

Caged-carvedilol as a new tool for visible-light photopharmacology of β-adrenoceptors in native tissues

Contact Info

Product

Resources

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A Photoswitchable Ligand Targeting the β₁‐Adrenoceptor Enables Light‐Control of the Cardiac Rhythm**