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This Sandbox is Reserved from 25/11/2019, through 30/9/2020 for use in the course "Structural Biology" taught by Bruno Kieffer at the University of Strasbourg, ESBS. This reservation includes Sandbox Reserved 1091 through Sandbox Reserved 1115.

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Human Angiotensin Receptor

Angiotensin receptors belong to the G protein coupled receptor (GPCR) family. This is the hormone receptor of the angiotensin II type 1. This is a trans-membrane protein located mainly in heart, brain, liver and kidneys.

1 Functions
2 History
3 Structure (function relationship)
4 Application in the therapeutic field

Functions

The AT1 receptors are playing an important role in the regulation of the renin-angiotensin-aldosterone system and therefore in the regulation of the cardiovascular physiology. It occupies a crucial place in the maintaining of blood pressure, electrolyte homeostasis, water balance, hormone secretion and renal functions.

AT1 receptors are seven transmembrane-spanning G protein-coupled receptors. They interact with the angiotensin II, their ligand, and are therefore responsible for the triggering of intracellular signal transduction cascades mediating most functions of Angiotensin II, such as vasoconstriction, sympathetic nervous stimulation, increased aldosterone biosynthesis and renal functions. AT1 receptors are predominantly expressed in cardiovascular tissues including heart, endothelium, kidney, vascular smooth muscle cells as well as lungs, brain and adrenal cortex.

When activated by the binding of angiotensin II, AT1R initiates a vascular remodelling activity. By its coupling with the G proteins Gq and Gi of the Gαq/11 subtype, the intracellular signal transduction has started. During these transduction cascades, a large variety of protein kinases are activated. Among them are counted: mitogen-activated protein kinase (MAPK) family, extracellular signal regulated kinase (ERK), c-Jun N terminal kinase (JNK), p38MAPK], p70 S6 kinase, AKT/protein kinase B(PKB), various protein kinase C (PKC) isoforms, receptor and non-receptor tyrosine kinases and serine/threonine kinases. This in turn regulates VSMCs contraction via activation of myosin light chain kinase (MLCK) or inhibition of myosin light chain phosphatase (MLCP). The complex functioning of AT1 receptor signalling involve crosstalk with other signalling cascades too.

History

Discovery of angiotensin receptors

Researchers suspected since 70s the existence of different angiotensin receptors. However, tools to identify those distinct trans-membrane receptors became available ten years later. Receptors binding assays identified angiotensin receptors in vitro using radioactive angiotensin. Results showed several types of angiotensin receptors, found in different tissues. The main receptors are AT1 and AT2 ^[1].

Nomenclature

Three labs discovered in the same time these two angiotensin receptors and proposed their own nomenclature, leading to confusion. To avoid this, a group of researchers met in Baltimore in 1991 to define a coherent nomenclature. Under the presidency of Merlin Bumpus, a common ground has been found and angiotensin receptors have been classified into two groups called AT1 and AT2 receptors. ^[2].

Recent studies

Finally, around 2015, researchers have found the crystal structure of the receptor in complex with its antagonist ZD7155 and with an inverse agonist olmesartan^[3]. X-ray cryogenic-crystallography has been used. They have found similar conformation of the receptor when it is linked to the antagonist or to the inverse agonist. They have also found conserved molecular recognition modes. To complete this, they have performed mutagenesis experiments and managed to identify several residues in interaction with the ligand. The structure of this protein have also been solved in 2017 using an other method called serial femtosecond crystallography, corresponding to the structure 4YAY ^[4].

Structure (function relationship)

Primary and secondary structure

Human angiotensin receptor consists in a 376 amino acid string ^[5]. The protein is composed of and . Moreover, 7 alpha helix are made of a majority of hydrophobic amino acids. These helix are long enough to cross the membrane and create an which is situated into the membrane. The human angiotensin receptor is therefore an alpha helical trans-membrane protein. Since the angiotensin receptor belongs to the GPCRs family, those 7 alpha helix contain 3 extracellular and 3 intracellular loops.

Ligand binding pocket

In the extracellular environment, there is a beta-hairpin in conjugation with two extracellular disulfure bridges. This structure is responsible for the opening and the locking of the ligand binding pocket ^[6]. The ligand goes into an created into the membrane thanks to the 7 alpha helix which create a gate between the membrane and the extracellular environment.

AngII mediates AT1 receptor activation via stacking interactions between Phe8(AngII)/His256(AT1 receptor) and Tyr4(AngII)/Asn111(AT1 receptor). This phenomenon results in a conformational change in transmembrane (TM)3-TM6 helices and in interaction between TM2 and TM7.

G protein-binding site

When the angiotensin II binds to the angiotensin receptor in the ligand binding pocket, the conformation of the trans-membrane domain changes to create a cytosolic cleft for the binding and activation of G proteins. In this cleft, several conserved residues can be found, which form functional motifs present in all GPCRs ^[7].

Interaction with drugs

Olmesartan anchored to ATR1 by the residues , and . Those three amino acids seem to play an important role in the binding of the drug to AT1R, thanks to the formation of extensive networks of hydrogen bonds and salt bridges with the ligand ^[3]. An other amino acid, the , seems to be involved in the binding of the angiotensin II

Many drugs used to cure diseases linked with the angiotensin receptor contain a tetrazole group. Studies showed that tetrazole plays an important role in the binding with AT1R.

Interaction with other GPCRs

It has been discovered that AT1Rs were also able to bind with other GPCRs to form homo- or heterodimers. Those interactions can modify the sensitivity of the receptor, which leads to different physiological and pathological conditions than the GPCR monomer ^[3]^[8]. The most known heterodimers including AT1 receptor are with ß2-adrenergic receptor, the apelin receptor, and AT2 receptor. Those interactions could be facilitated by several transmembrane domains.

The oligomeric complexes' formation complicate the understanding of AT1R pharmacology.

Application in the therapeutic field

Since angiotensin receptor is involved in the renin-angiotenisin system, it represents a target of choice to cure some diseases like hypertension or heart failure. An over-stimulation of this receptor seems to be involved in hypertension, coronary artery disease, cardiac hypertrophy, heart failure, arrhythmia, stroke, diabetic nephropathy and ischemic heart and renal diseases ^[8].

Several anti-hypertensive drugs are targeting the angiotensin receptor in order to block it. This kind of drugs are called angiotensin receptor blockers (ARBs). This category include olmesartan, candesartan, and losartan. One of the common characteristic they share is their biphenyl-tetrazole scaffold.

References

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 === Ligand binding pocket ===
 In the extracellular environment, there is a beta-hairpin in conjugation with two extracellular disulfure bridges. This structure is responsible for the opening and the locking of the ligand binding pocket <ref name="Fillion2013"> [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3605637/ Fillion D, Cabana J, Guillemette G, Leduc R, Lavigne P, Escher E. Structure of the human angiotensin II type 1 (AT1) receptor bound to angiotensin II from multiple chemoselective photoprobe contacts reveals a unique peptide binding mode. J Biol Chem. 2013;288(12):8187–8197. doi:10.1074/jbc.M112.442053] </ref>. The ligand goes into an <scene name='82/829348/Ligand_blinding_pocket/1'>hydrophilic pocket</scene> created into the membrane thanks to the 7 alpha helix which create a gate between the membrane and the extracellular environment.
+AngII mediates AT1 receptor activation via stacking interactions between Phe8(AngII)/His256(AT1 receptor) and Tyr4(AngII)/Asn111(AT1 receptor). This phenomenon results in a conformational change in transmembrane (TM)3-TM6 helices and in interaction between TM2 and TM7.
 === G protein-binding site ===