The relaxin peptide family and their novel G-protein coupled receptors

Relaxin-1 is a heterodimeric peptide hormone primarily produced by the pregnant corpus luteum and/or placenta and is involved in many essential physiological processes centered on its action as a potent extracellular matrix (ECM) remodeling agent. Insulin-like peptide 3 (INSL3), also known as relaxin-like factor, is predominantly expressed in the Leydig cells of the testes and is an important mediator of testicular descent. The relaxin-1 equivalent peptide in humans is actually the product of the human RLN2 gene, human 2 (H2) relaxin. Recently identified and thought to be the ancestral relaxin, relaxin-3 is specifically expressed in the nucleus incertus of the mouse and rat brain and is most likely an important neuropeptide. Each of the hormones above act on cell membrane G-protein coupled receptors (GPCRs). The relaxin-1 receptor is leucine-rich repeat-containing GPCR 7 (LGR7) whereas INSL3 acts on the closely related LGR8. These receptors have large extra-cellular domains containing multiple leucine-rich repeats (LRRs) and a unique LDL receptor-like cysteine-rich motif (LDLR-domain). Relaxin-3 will bind and activate LGR7 with 50-fold lower activity than H2 relaxin. Two relaxin-3 selective GPCRs; somatostatin and angiotensin like peptide receptor (SALPR) and GPCR 142 were recently identified, these type I GPCRs are unrelated to LGR7 and LGR8. The discovery and characterisation of these receptors is greatly aiding the quest to unravel the mechanics of these important hormones, however with three other family members, insulin-like peptides 4–6 (INSL4, INSL5 and INSL6) with unknown functions and unidentified receptors, there is still much to be learnt about this hormone family.     

Discovery of a small molecule RXFP3/4 agonist that increases food intake in rats upon acute central administration

The relaxin family peptide receptors have been implicated in numerous physiological processes including energy homeostasis, cardiac function, wound healing, and reproductive function. Two family members, RXFP3 and RXFP4, are class A GPCRs with endogenous peptide ligands (relaxin-3 and insulin-like peptide 5 (INSL5), respectively). Polymorphisms in relaxin-3 and RXFP3 have been associated with obesity, diabetes, and hypercholesterolemia. Moreover, central administration of relaxin-3 in rats has been shown to increase food intake, leading to body weight gain. Reported RXFP3 and RXFP4 ligands have been restricted to peptides (both endogenous and synthetic) as well as a low molecular weight positive allosteric modulator requiring a non-endogenous orthosteric ligand. Described here is the discovery of the first potent low molecular weight dual agonists of RXFP3/4. The scaffold identified is competitive with a chimeric relaxin-3/INSL5 peptide for RXFP3 binding, elicits similar downstream signaling as relaxin-3, and increases food intake in rats following acute central administration. This is the first report of small molecule RXFP3/4 agonism.     

Structure of the R3/I5 chimeric relaxin peptide, a selective GPCR135 and GPCR142 agonist

The human relaxin family comprises seven peptide hormones with various biological functions mediated through interactions with G-protein-coupled receptors. Interestingly, among the hitherto characterized receptors there is no absolute selectivity toward their primary ligand. The most striking example of this is the relaxin family ancestor, relaxin-3, which is an agonist for three of the four currently known relaxin receptors: GPCR135, GPCR142, and LGR7. Relaxin-3 and its endogenous receptor GPCR135 are both expressed predominantly in the brain and have been linked to regulation of stress and feeding. However, to fully understand the role of relaxin-3 in neurological signaling, the development of selective GPCR135 agonists and antagonists for in vivo studies is crucial. Recent reports have demonstrated that such selective ligands can be achieved by making chimeric peptides comprising the relaxin-3 B-chain combined with the INSL5 A-chain. To obtain structural insights into the consequences of combining A- and B-chains from different relaxins we have determined the NMR solution structure of a human relaxin-3/INSL5 chimeric peptide. The structure reveals that the INSL5 A-chain adopts a conformation similar to the relaxin-3 A-chain, and thus has the ability to structurally support a native-like conformation of the relaxin-3 B-chain. These findings suggest that the decrease in activity at the LGR7 receptor seen for this peptide is a result of the removal of a secondary LGR7 binding site present in the relaxin-3 A-chain, rather than conformational changes in the primary B-chain receptor binding site.     

The A-chain of human relaxin family peptides has distinct roles in the binding and activation of the different relaxin family peptide receptors

The relaxin peptides are a family of hormones that share a structural fold characterized by two chains, A and B, that are cross-braced by three disulfide bonds. Relaxins signal through two different classes of G-protein-coupled receptors (GPCRs), leucine-rich repeat-containing GPCRs LGR7 and LGR8 together with GPCR135 and GPCR142, now referred to as the relaxin family peptide (RXFP) receptors 1-4, respectively. Although key binding residues have been identified in the B-chain of the relaxin peptides, the role of the A-chain in their activity is currently unknown. A recent study showed that INSL3 can be truncated at the N terminus of its A-chain by up to 9 residues without affecting the binding affinity to its receptor RXFP2 while becoming a high affinity antagonist. This suggests that the N terminus of the INSL3 A-chain contains residues essential for RXFP2 activation. In this study, we have synthesized A-chain truncated human relaxin-2 and -3 (H2 and H3) relaxin peptides, characterized their structure by both CD and NMR spectroscopy, and tested their binding and cAMP activities on RXFP1, RXFP2, and RXFP3. In stark contrast to INSL3, A-chain-truncated H2 relaxin peptides lost RXFP1 and RXFP2 binding affinity and concurrently cAMP-stimulatory activity. H3 relaxin A-chain-truncated peptides displayed similar properties on RXFP1, highlighting a similar binding mechanism for H2 and H3 relaxin. In contrast, A-chain-truncated H3 relaxin peptides showed identical activity on RXFP3, highlighting that the B-chain is the sole determinant of the H3 relaxin-RXFP3 interaction. Our results provide new insights into the action of relaxins and demonstrate that the role of the A-chain for relaxin activity is both peptide- and receptor-dependent.     

Preliminary Structure–Function Relationship Studies on Insulin-Like Peptide 5 (INSL5)

Insulin-like peptide 5 (INSL5) is a two-chain, three-disulfide bonded member of insulin/relaxin superfamily of peptides that includes insulin, insulin-like growth factor I and II (IGFI and IGFII), insulin-like peptide 3, 4, 5 and 6 (INSL3, 4, 5 and 6), relaxin-1 (H1 relaxin), -2 (H2 relaxin) and -3 (H3 relaxin). Although it is expressed in relatively high levels in the gut, its biological function remains unclear. However, recent reports suggest a significant orexigenic action and a role in the regulation of insulin secretion and β-cell homeostasis, which implies that both agonists and antagonists of the peptide may have significant therapeutic applications. Modern solid phase synthesis techniques together with regioselective disulfide bond formation were employed for a preliminary structure–function relationship study of mouse INSL5. Two point mutated analogues, mouse INSL5 A-B(R24A, W25A) and mouse INSL5 A-B(K6A, R14A, Y18A) were chemically prepared, where the residues in the B-chain that may be involved in receptor activation and affinity binding, were respectively mutated. Synthetic mouse INSL5 A-B(R24A, W25A) analogue was inactive on RXFP4, the native receptor for INSL5, suggesting Arg^B24 and Trp^B25 are probably directly involved in INSL5 receptor activation. Mouse INSL5 A-B(K6A, R14A, Y18A) analogue had both decreased affinity and potency on RXFP4 (pIC₅₀ 7.7 ± 0.2, pEC₅₀ 7.87 ± 0.18) which indicated that one or more of these residues are critical for the binding to the receptor.     

Human relaxin-2: historical perspectives and role in cancer biology

One of the most recognised and studied family of peptide hormones is the insulin superfamily. Within this family is the relaxin subfamily which comprises seven members: relaxin-1, -2 and -3 and insulin-like peptides 3, 4, 5 and 6. Besides exhibiting sequence similarities, each member exists as an active A-B heterodimer linked by three disulfide bonds. This mini-review is divided into three broad themes: an overview of all insulin superfamily members (including structural similarities); roles of each superfamily member and finally, a focus on the pleiotropic peptide hormone, human relaxin-2. In addition to promoting vasodilatory effects leading to evaluation in Phase III clinical trials for the treatment of acute heart failure, relaxin has recently been shown to be highly expressed by cancer cells, aiding in their proliferation, invasiveness and metastasis. These contrary effects of relaxin are discussed together with current efforts in the development of relaxin antagonists that may possess future therapeutic potential for the treatment of certain cancers.     

Searching the human genome database for novel relaxin- and insulin-like peptides

In recent times, new members of the insulin/relaxin peptidesuperfamily have been identified by both differential cloningstrategies as well as bioinformatic searching of the ESTdatabases. We have used the public and Celera Genomicsdatabases to search for novel members of this peptide family.No new members of the insulin/relaxin family were identifiedalthough the human (H3) and mouse (M3) relaxin 3 genes that werecently discovered in the Celera Genomics database wereidentified in the public database. We were able to confirmthat there are no mouse equivalents of human INSL4 or humangene 1 relaxin. Hence, as the two human relaxin genes (H1 andH2) are localized together with INSL6 and INSL4 on chromosome9 it is probable that INSL4 and H1 relaxin are the result of agene duplication which did not occur in non-primates. Thediscovery of a full relaxin 3 sequences in a new Zebrafishbrain EST library, which retains a high homology in both A andB chain peptide sequence with the H3 peptide, indicate thatthis novel peptide has important conserved functions.     

Relaxin-3: improved synthesis strategy and demonstration of its high-affinity interaction with the relaxin receptor LGR7 both in vitro and in vivo

Relaxin-3 is a member of the human relaxin peptide family, the gene for which, RLN3, is predominantly expressed in the brain. Mapping studies in the rodent indicate a highly developed network of RLN3, RLN1, and relaxin receptor-expressing cells in the brain, suggesting that relaxin peptides have important functional roles in the central nervous system. A regioselective disulfide-bond synthesis protocol was developed and used for the chemical synthesis of human (H3) relaxin-3. The selectively S-protected A and B chains were combined by stepwise formation of each of the three insulin-like disulfides via aeration, thioloysis, and iodolysis. Judicious positioning of the three sets of S-protecting groups was crucial for acquisition of synthetic H3 relaxin in a good overall yield. The activity of the peptide was tested against relaxin family peptide receptors. Although the highest activity was demonstrated on the human relaxin-3 receptor (GPCR135), the peptide also showed high activity on relaxin receptors (LGR7) from various species and variable activity on the INSL3 receptor (LGR8). Recombinant mouse prorelaxin-3 demonstrated similar activity to H3 relaxin, suggesting that the presence of the C peptide did not influence the conformation of the active site. H3 relaxin was also able to activate native LGR7 receptors. It stimulated increased MMP-2 expression in LGR7-expressing rat ventricular fibroblasts in a dose-dependent manner and, following infusion into the lateral ventricle of the brain, stimulated water drinking in rats, activating LGR7 receptors located in the subfornical organ. Thus, H3 relaxin is able to interact with the relaxin receptor LGR7 both in vitro and in vivo.     

Searching the human genome database for novel relaxin- and insulin-like peptides

Summary In recent times, new members of the insulin/relaxin peptide superfamily have been identified by both differential cloning strategies as well as bioinformatic searching of the EST databases. We have used the public and Celera Genomics databases to search for novel members of this peptide family. No new members of the insulin/relaxin family were identified although the human (H3) and mouse (M3) relaxin 3 genes that we recently discovered in the Celera Genomics database were identified in the public database. We were able to confirm that there are no mouse equivalents of human INSL-4 or human gene 1 relaxin. Hence, as the two human relaxin genes (H1 and H2) are localized together with INSL6 and INSL4 on chromosome 9 it is probable that INSL4 and H1 relaxin are the result of a gene duplication which did not occur in non-primates. The discovery of a full relaxin 3 sequences in a new Zebrafish brain EST library, which retains a high homology in both A and B chain peptide sequence with the H3 peptide, indicate that this novel peptide has important conserved functions.     

INSL5 is a high affinity specific agonist for GPCR142 (GPR100)

Insulin-like peptide 5 (INSL5) is a peptide that belongs to the relaxin/insulin family, and its receptor has not been identified. In this report, we demonstrate that INSL5 is a specific agonist for GPCR142. Human INSL5 displaces the binding of (125)I-relaxin-3 to GPCR142 with a high affinity (K(i) = 1.5 nM). In a saturation binding assay, (125)I-INSL5 binds GPCR142 with a K(d) value of 2.5 nM. In functional guanosine (gamma-thio)-triphosphate binding and cAMP accumulation assays, INSL5 potently activates GPCR142 with EC(50) values of 1.3 and 1.2 nM, respectively. In addition, INSL5 stimulates Ca(2+) mobilization in HEK293 cells expressing GPCR142 and G alpha(16). Overall, INSL5 behaves as an agonist for GPCR142 similar to relaxin-3. However, unlike relaxin-3, which is also a potent agonist for GPCR135 and LGR7, INSL5 does not activate either GPCR135 or LGR7. INSL5 inhibits (125)I-relaxin-3 binding to GPCR135 with a low potency (K(i) = 500 nM). A functional assay shows that INSL5 (1 microm) is a weak antagonist for GPCR135. In addition, INSL5 (up to 1 microm) shows no affinity or activity at LGR7 or LGR8 either in a binding assay or a bio-functional assay. Previously, we have demonstrated that GPCR142 mRNA is expressed in peripheral tissues, particularly in the colon. Here we show that INSL5 mRNA is expressed in many peripheral tissues, similar to GPCR142. The high affinity interaction between INSL5 and GPCR142 coupled with their co-evolution and partially overlapping tissue expression patterns strongly suggest that INSL5 is an endogenous ligand for GPCR142.     

INSL4 Pseudogenes Help Define the Relaxin Family Repertoire in the Common Ancestor of Placental Mammals

The relaxin/insulin-like (RLN/INSL) gene family comprises a group of signaling molecules that perform physiological roles related mostly to reproduction and neuroendocrine regulation. They are found on three different locations in the mammalian genome, which have been called relaxin family locus (RFL) A, B, and C. Early in placental mammalian evolution, the ancestral proto-RLN gene at the RFLB locus underwent successive rounds of small-scale duplications resulting in variable number of paralogous genes in different placental lineages. Most placental mammals harbor copies of the RLN2 and INSL6 paralogs in the RFLB. However, the origin of an additional paralog, INSL4 (also known as placentin), has been controversial as its phyletic distribution does not converge with its phylogenetic position. In principle, by searching for INSL4 genes in representative species of all major groups of mammals we can gain insights into when the gene originated and better reconstruct its evolutionary history. Here we identified INSL4 pseudogenes in two laurasiatherian, (alpaca and dolphin) and one xenarthran (armadillo) species. Phylogenetic and synteny analyses confirmed that the identified pseudogenes are orthologs of INSL4. According to these results, the proto-RLN gene in the RFLB underwent two successive tandem duplications which gave rise the INSL6 and INSL4 paralogs in the last common ancestor of placental mammals. The INSL4 gene was subsequently inactivated or lost from the genome in all placentals other than catarrhine primates, where its product became functionally relevant. Our results highlight the contribution of relatively old gene duplicates to the gene complement of extant species.     

Hydrocarbon stapled B chain analogues of relaxin-3 retain biological activity

Relaxin-3 or insulin-like peptide 7 (INSL7) is the most recently discovered relaxin/insulin-like family peptide. Mature relaxin-3 consists of an A chain and a B chain held by disulphide bonds. According to structure activity relationship studies, the relaxin-3 B chain is more important in binding and activating the receptor. RXFP3 (also known as Relaxin-3 receptor 1, GPCR 135, somatostatin- and angiotensin- like peptide receptor or SALPR) was identified as the cognate receptor for relaxin-3 by expression profiles and binding studies. Recent studies imply roles of this system in mediating stress and anxiety, feeding, metabolism and cognition. Stapling of peptides is a technique used to develop peptide drugs for otherwise undruggable targets. The main advantages of stapling include, increased activity due to reduced proteolysis, increased affinity to receptors and increased cell permeability. Stable agonists and antagonists of RXFP3 are crucial for understanding the physiological significance of this system. So far, agonists and antagonists of RXFP3 are peptides. In this study, for the first time, we have introduced stapling of the relaxin-3 B chain at 14th and 18th positions (14s18) and 18th and 22nd position (18s22). These stapled peptides showed greater helicity than the unstapled relaxin-3 B chain in circular dichroism analysis. Both stapled peptides bound RXFP3 and activated RXFP3 as observed in an inhibition of forskolin-induced cAMP assay and a ERK1/2 activation assay, although with different potencies. Therefore, we conclude that stapling of the relaxin3 B chain does not compromise its ability to activate RXFP3 and is a promising method for developing stable peptide agonists and antagonists of RXFP3 to aid relaxin-3/RXFP3 research.     

Identification of relaxin-3/INSL7 as an endogenous ligand for the orphan G-protein-coupled receptor GPCR135

GPCR135, publicly known as somatostatin- and angiotensin-like peptide receptor, is expressed in the central nervous system and its cognate ligand(s) has not been identified. We have found that both rat and porcine brain extracts stimulated 35S-labeled guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) incorporation in cells over-expressing GPCR135. Multiple rounds of extraction, purification, followed by N-terminal sequence analysis of the ligand from porcine brain revealed that the ligand is a product of the recently identified gene, relaxin-3 (aka insulin-7 or INSL7). Recombinant human relaxin-3 potently stimulates GTPgammaS binding and inhibits cAMP accumulation in GPCR135 overexpressing cells with EC50 values of 0.25 and 0.35 nM, respectively. 125I-Relaxin-3 binds GPCR135 at high affinity with a Kd value of 0.31 nM. Relaxin-3 is the only member of the insulin/relaxin superfamily that can activate GPCR135. In situ hybridization showed that relaxin-3 mRNA is predominantly expressed in the dorsomedial ventral tegmental nucleus of the brainstem (aka nucleus incertus), as well as in discrete cells in the lateral periaqueductal gray and in the central gray nucleus. GPCR135 is expressed abundantly in the hypothalamus with discrete expression in the paraventricular nucleus of the hypothalamus and supraoptic nucleus, as well as in the cortex, septal nucleus, and preoptical area. Relaxin-3 has previously been shown to bind and activate the LGR7 relaxin receptor. However, we believe that neuroanatomical colocalization of GPCR135 and relaxin-3, coupled with a clear high affinity interaction, suggest that GPCR135 is the receptor for relaxin-3. The identification of relaxin-3 as the ligand for GPCR135 provides the framework for the discovery of a new brainstem/hypothalamus circuitry.     

Chemical synthesis and biological activity of rat INSL3.

The recently identified protein, insulin 3 (INSL3), has structural features that make it a bona fide member of the insulin superfamily. Its predicted amino acid sequence contains the classic two-peptide chain (A- and B-) structure with conserved cysteine residues that results in a disulphide bond disposition identical to that of insulin. Recently, the generation of insl3 knockout mice has demonstrated that testicular descent is blocked due to the failure of a specific ligament, the gubernaculum, to develop. The mechanism by which INSL3 exerts its action on the gubernaculum is currently unknown. The purpose of this study was to, for the first time, synthesize rat INSL3 and test its action on organ cultures of foetal rat gubernaculum. INSL3 also contains a cassette of residues Arg-X-X-X-Arg within the B-chain, a motif that is essential for characteristic activity of another related member of the superfamily, relaxin. Hence, the relaxin activity of rat INSL3 was also tested in two different relaxin bioassays. The primary structure of rat INSL3 was determined by deduction from its cDNA sequence and successfully prepared by solid phase peptide synthesis of the two constituent chains followed by their combination in solution. Following confirmation of its chemical integrity by a variety of analytical techniques, circular dichroism spectroscopy confirmed the presence of high beta-turn and alpha-helical content, with a remarkable spectral similarity to the synthetic ovine INSL3 peptide and to synthetic rat relaxin. The synthetic rat INSL3 bound with very low affinity to rat relaxin receptors and had no activity in a relaxin bioassay. Furthermore, it did not augment or antagonize relaxin activity. The rat INSL3 did however induce growth of foetal rat gubernaculum in whole organ cultures demonstrating that INSL3 has a direct action on this structure.     

Site-specific DOTA/europium-labeling of recombinant human relaxin-3 for receptor-ligand interaction studies

Relaxin-3 (also known as INSL7) is a recently identified neuropeptide belonging to the insulin/relaxin superfamily. It has putative roles in the regulation of stress responses, food intake, and reproduction by activation of its cognate G-protein-coupled receptor RXFP3. It also binds and activates the relaxin family peptide receptors RXFP1 and RXFP4 in vitro. To obtain a europium-labeled relaxin-3 as tracer for studying the interaction of these receptors with various ligands, in the present work we propose a novel site-specific labeling strategy for the recombinant human relaxin-3 that has been previously prepared in our laboratory. First, the N-terminal 6 × His-tag of the single-chain relaxin-3 precursor was removed by Aeromonas aminopeptidase and all of the primary amines of the resultant peptide were reversibly blocked by citroconic anhydride. Second, the A-chain N-terminus of the blocked peptide was released by endoproteinase Asp-N cleavage that removed the linker peptide between the B- and A-chains. Third, an alkyne moiety was introduced to the newly released A-chain N-terminus by reaction with the highly active primary amine-specific N-hydroxysuccinimide ester. Fourth, after removal of the reversible blockage under mild acidic condition, europium-loaded DOTA with an azide moiety was introduced to the two-chain relaxin-3 carrying the alkyne moiety through click chemistry. Using this site-specific labeling strategy, homogeneous monoeuropium-labeled human relaxin-3 could be obtained with good overall yield. In contrast, conventional random labeling resulted in a complex mixture that was poorly resolved because human relaxin-3 has four primary amine moieties that all react with the modification reagent. Both saturation and competition binding assays demonstrated that the DOTA/Eu(3+)-labeled relaxin-3 retained high binding affinity for human RXFP3, RXFP4, and RXFP1 and was therefore a suitable non-radioactive and stable tracer to study the interaction of various natural or designed ligands with these receptors. Using this site-specific labeling strategy, other functional probes, such as fluorescent dyes, biotin, or nanoparticles could also be introduced to the A-chain N-terminal of the recombinant human relaxin-3. Additionally, we improved the time-resolved fluorescence assay for the DOTA-bound europium ion which paves the way for the use of DOTA as a lanthanide chelator for protein and peptide labeling in future studies.     

Hypothalamic mapping of orexigenic action and Fos-like immunoreactivity following relaxin-3 administration in male Wistar rats

The insulin superfamily, characterized by common disulphide bonds, includes not only insulin but also insulin-like peptides such as relaxin-1 and relaxin-3. The actions of relaxin-3 are largely unknown, but recent work suggests a role in regulation of food intake. Relaxin-3 mRNA is highly expressed in the nucleus incertus, which has extensive projections to the hypothalamus, and relaxin immunoreactivity is present in several hypothalamic nuclei. In the rat, relaxin-3 binds and activates both relaxin family peptide receptor 1, which also binds relaxin-1, and a previously orphaned G protein-coupled receptor, RXFP3. These receptors are extensively expressed in the hypothalamus. The aims of these studies were twofold: 1) map the hypothalamic site(s) of the orexigenic action of relaxin-3 and 2) examine the site(s) of neuronal activation following central relaxin-3 administration. After microinjection into hypothalamic sites, human relaxin-3 (H3; 180 pmol) significantly stimulated 0- to 1-h food intake in the supraoptic nucleus (SON), arcuate nucleus (ARC), and the anterior preoptic area (APOA) [SON 0.4+/-0.2 (vehicle) vs. 2.9+/-0.5 g (H3), P<0.001; ARC 0.7+/-0.3 (vehicle) vs. 2.7+/-0.2 g (H3), P<0.05; and APOA 0.8+/-0.1 (vehicle) vs. 2.2+/-0.2 g (H3), P<0.05]. Cumulative food intake was significantly increased相似文献   

A novel ultrasensitive bioluminescent receptor-binding assay of INSL3 through chemical conjugation with nanoluciferase

Insulin-like peptide 3 (INSL3) is a reproduction-related peptide hormone belonging to the insulin/relaxin superfamily, which mediates testicular descent in the male fetus, suppresses male germ cell apoptosis and promotes oocyte maturation in adults by activating the relaxin family peptide receptor 2 (RXFP2). To establish an ultrasensitive receptor-binding assay for INSL3−RXFP2 interaction studies, in the present work we labeled a recombinant INSL3 peptide with a newly developed nanoluciferase (NanoLuc) reporter through a convenient chemical conjugation approach, including the introduction of an active disulfide bond to INSL3 by chemical modification and engineering of a 6× His-Cys-NanoLuc carrying a unique exposed cysteine at the N-terminus. The bioluminescent NanoLuc-conjugated INSL3 retained high binding affinity with the target receptor RXFP2 (K_d = 2.0 ± 0.1 nM, n = 3) and was able to sensitively monitor the receptor-binding of a variety of ligands, representing a novel ultrasensitive tracer for non-radioactive receptor-binding assays. Our present chemical conjugation approach could readily be adapted for conjugation of NanoLuc with other proteins, even other macrobiomolecules, for various highly sensitive bioluminescent assays.     

Defining the LGR8 residues involved in binding insulin-like peptide 3

The peptide hormone insulin-like peptide 3 (INSL3) is essential for testicular descent and has been implicated in the control of adult fertility in both sexes. The human INSL3 receptor leucine-rich repeat-containing G protein-coupled receptor 8 (LGR8) binds INSL3 and relaxin with high affinity, whereas the relaxin receptor LGR7 only binds relaxin. LGR7 and LGR8 bind their ligands within the 10 leucine-rich repeats (LRRs) that comprise the majority of their ectodomains. To define the primary INSL3 binding site in LGR8, its LRRs were first modeled on the crystal structure of the Nogo receptor (NgR) and the most likely binding surface identified. Multiple sequence alignment of this surface revealed the presence of seven of the nine residues implicated in relaxin binding to LGR7. Replacement of these residues with alanine caused reduced [(125)I]INSL3 binding, and a specific peptide/receptor interaction point was revealed using competition binding assays with mutant INSL3 peptides. This point was used to crudely dock the solution structure of INSL3 onto the LRR model of LGR8, allowing the prediction of the INSL3 Trp-B27 binding site. This prediction was then validated using mutant INSL3 peptide competition binding assays on LGR8 mutants. Our results indicated that LGR8 Asp-227 was crucial for binding INSL3 Arg-B16, whereas LGR8 Phe-131 and Gln-133 were involved in INSL3 Trp-B27 binding. From these two defined interactions, we predicted the complete INSL3/LGR8 primary binding site, including interactions between INSL3 His-B12 and LGR8 Trp-177, INSL3 Val-B19 and LGR8 Ile-179, and INSL3 Arg-B20 with LGR8 Asp-181 and Glu-229.