Imaging flow cytometry of tumoroids: A new method for studying GPCR expression

Fluorescence confocal microscopy is commonly used to analyze the regulation membrane proteins expression such as G protein-coupled receptors (GPCRs). With this approach, the internal movement of GPCRs within the cell can be observed with a high degree of resolution. However, these microscopy techniques led to complex and time-consuming analysis and did not allow a large population of events to be sampled. A recent approach termed imaging flow cytometry (IFC), which combines flow cytometry and fluorescence microscopy, had two main advantages to study the regulation of GPCRs expression such as orexins receptors (OXRs): the ability (1) to analyze large numbers of cells and; (2) to visualize cell integrity and fluorescent markers localization. Here, we compare these two technologies using the orexin A (OxA) ligand coupled to rhodamine (OxA-rho) to investigate anti-tumoral OX1R expression in human digestive cancers. IFC has been adapted for cancer epithelial adherent cells and also to 3D cell culture tumoroids which partially mimic tumoral structures. In the absence of specific antibody, expression of OX1R is examined in the presence of OxA-rho. 2D-culture of colon cancer cells HT-29 exhibits a maximum level of OX1R internalization induced by OxA with 19% ± 3% colocalizing to early endosomes. In 3D-culture of HT-29 cells, internalization of OX1R/OxA-rho reached its maximum at 60 min, with 30.7% ± 6.4% of OX1R colocalizing with early endosomes. This is the first application of IFC to the analysis of the expression of a native GPCR, OX1R, in both 2D and 3D cultures of adherent cancer cells.

Acinar-to-Ductal Metaplasia (ADM): On the Road to Pancreatic Intraepithelial Neoplasia (PanIN) and Pancreatic Cancer

Adult pancreatic acinar cells show high plasticity allowing them to change in their differentiation commitment. Pancreatic acinar-to-ductal metaplasia (ADM) is a cellular process in which the differentiated pancreatic acinar cells transform into duct-like cells. This process can occur as a result of cellular injury or inflammation in the pancreas. While ADM is a reversible process allowing pancreatic acinar regeneration, persistent inflammation or injury can lead to the development of pancreatic intraepithelial neoplasia (PanIN), which is a common precancerous lesion that precedes pancreatic ductal adenocarcinoma (PDAC). Several factors can contribute to the development of ADM and PanIN, including environmental factors such as obesity, chronic inflammation and genetic mutations. ADM is driven by extrinsic and intrinsic signaling. Here, we review the current knowledge on the cellular and molecular biology of ADM. Understanding the cellular and molecular mechanisms underlying ADM is critical for the development of new therapeutic strategies for pancreatitis and PDAC. Identifying the intermediate states and key molecules that regulate ADM initiation, maintenance and progression may help the development of novel preventive strategies for PDAC.

The Orexin-A/OX1R System Induces Cell Death in Pancreatic Cancer Cells Resistant to Gemcitabine and Nab-Paclitaxel Treatment

Pancreatic ductal adenocarcinoma (PDAC) represents the fourth cause of cancer-associated death in the West. This type of cancer has a very poor prognosis notably due to the development of chemoresistance when treatments including gemcitabine and Abraxane (Nab-paclitaxel) were prescribed. The identification of new treatment circumventing this chemoresistance represents a key challenge. Previous studies demonstrated that the activation of orexin receptor type 1 (OX1R), which was ectopically expressed in PDAC, by its natural ligand named orexin-A (OxA), led to anti-tumoral effect resulting in the activation of mitochondrial pro-apoptotic mechanism. Here, we demonstrated that OxA inhibited the pancreatic cancer cell (AsPC-1) growth and inhibited the tumor volume in preclinical models as effectively as gemcitabine and Nab-paclitaxel. Moreover, the combination therapy including OxA plus gemcitabine or OxA plus Nab-paclitaxel was additive on the inhibition of cancer cell growth and tumor development. More importantly, the treatment by OxA of chemoresistant tumors to gemcitabine or Nab-paclitaxel obtained by successive xenografts in mice revealed that OxA was able to induce a strong inhibition of tumor development, whereas no OxA resistance was identified in tumors. The OX1R/OxA system might be an innovative and powerful alternative treatment of chemoresistant PDAC.

The Orexin receptors: Structural and anti-tumoral properties

At the end of the 20th century, two new neuropeptides (Orexin-A/hypocretin-1 and Orexin-B/hypocretins-2) expressed in hypothalamus as a prepro-orexins precursor, were discovered. These two neuropeptides interacted with two G protein-coupled receptor isoforms named OX1R and OX2R. The orexins/OX receptors system play an important role in the central and peripheral nervous system where it controls wakefulness, addiction, reward seeking, stress, motivation, memory, energy homeostasis, food intake, blood pressure, hormone secretions, reproduction, gut motility and lipolysis. Orexins and their receptors are involved in pathologies including narcolepsy type I, neuro- and chronic inflammation, neurodegenerative diseases, metabolic syndrome, and cancers. Associated with these physiopathological roles, the extensive development of pharmacological molecules including OXR antagonists, has emerged in association with the determination of the structural properties of orexins and their receptors. Moreover, the identification of OX1R expression in digestive cancers encompassing colon, pancreas and liver cancers and its ability to trigger mitochondrial apoptosis in tumoral cells, indicate a new putative therapeutical action of orexins and paradoxically OXR antagonists. The present review focuses on structural and anti-tumoral aspects of orexins and their receptors.

Orexins: A promising target to digestive cancers, inflammation, obesity and metabolism dysfunctions

Hypothalamic neuropeptides named hypocretin/orexins which were identified in 1998 regulate critical functions such as wakefulness in the central nervous system. These past 20 years had revealed that orexins/receptors system was also present in the peripheral nervous system where they participated to the regulation of multiple functions including blood pressure regulation, intestinal motility, hormone secretion, lipolyze and reproduction functions. Associated to these peripheral functions, it was found that orexins and their receptors were involved in various diseases such as acute/chronic inflammation, metabolic syndrome and cancers. The present review suggests that orexins or the orexin neural circuitry represent potential therapeutic targets for the treatment of multiple pathologies related to inflammation including intestinal bowel disease, multiple sclerosis and septic shock, obesity and digestive cancers.

Orexins as Novel Therapeutic Targets in Inflammatory and Neurodegenerative Diseases

Orexins [orexin-A (OXA) and orexin-B (OXB)] are two isoforms of neuropeptides produced by the hypothalamus. The main biological actions of orexins, focused on the central nervous system, are to control the sleep/wake process, appetite and feeding, energy homeostasis, drug addiction, and cognitive processes. These effects are mediated by two G protein-coupled receptor (GPCR) subtypes named OX1R and OX2R. In accordance with the synergic and dynamic relationship between the nervous and immune systems, orexins also have neuroprotective and immuno-regulatory (i.e., anti-inflammatory) properties. The present review gathers recent data demonstrating that orexins may have a therapeutic potential in several pathologies with an immune component including multiple sclerosis, Alzheimer's disease, narcolepsy, obesity, intestinal bowel diseases, septic shock, and cancers.

Ectopic expression of OX1R in ulcerative colitis mediates anti-inflammatory effect of orexin-A

Orexins (orexin-A and orexin-B) are hypothalamic peptides that are produced by the same precursor and are involved in sleep/wake control, which is mediated by two G protein-coupled receptor subtypes, OX1R and OX2R. Ulcerative colitis (UC) is an inflammatory bowel disease, (IBD) which is characterized by long-lasting inflammation and ulcers that affect the colon and rectum mucosa and is known to be a significant risk factor for colon cancer development. Based on our recent studies showing that OX1R is aberrantly expressed in colon cancer, we wondered whether orexin-A could play a role in UC. Immunohistochemistry studies revealed that OX1R is highly expressed in the affected colonic epithelium of most UC patients, but not in the non-affected colonic mucosa. Injection of exogenous orexin-A specifically improved the inflammatory symptoms in the two colitis murine models. Conversely, injection of inactive orexin-A analog, OxB7-28 or OX1R specific antagonist SB-408124 did not have anti-inflammatory effect. Moreover, treatment with orexin-A in DSS-colitis induced OX1R^-/- knockout mice did not have any protective effect. The orexin-A anti-inflammatory effect was due to the decreased expression of pro-inflammatory cytokines in immune cells and specifically in T-cells isolated from colonic mucosa. Moreover, orexin-A inhibited canonical NFκB activation in an immune cell line and in intestinal epithelial cell line. These results suggest that orexin-A might represent a promising alternative to current UC therapies.

The Anti-tumoral Properties of Orexin/Hypocretin Hypothalamic Neuropeptides: An Unexpected Therapeutic Role

Orexins (OxA and OxB) also termed hypocretins are hypothalamic neuropeptides involved in central nervous system (CNS) to control the sleep/wake process which is mediated by two G protein-coupled receptor subtypes, OX1R, and OX2R. Beside these central effects, orexins also play a role in various peripheral organs such as the intestine, pancreas, adrenal glands, kidney, adipose tissue and reproductive tract.In the past few years, an unexpected anti-tumoral role of orexins mediated by a new signaling pathway involving the presence of two immunoreceptor tyrosine-based inhibitory motifs (ITIM) in both orexin receptors subtypes, the recruitment of the phosphotyrosine phosphatase SHP2 and the induction of mitochondrial apoptosis has been elucidated. In the present review, we will discuss the anti-tumoral effect of orexin/OXR system in colon, pancreas, prostate and other cancers, and its interest as a possible therapeutic target.

Microvasculature alters the dispersion properties of shear waves--a multi-frequency MR elastography study

Magnetic Resonance Elastography (MRE) uses macroscopic shear wave propagation to quantify mechanical properties of soft tissues. Micro-obstacles are capable of affecting the macroscopic dispersion properties of shear waves. Since disease or therapy can change the mechanical integrity and organization of vascular structures, MRE should be able to sense these changes if blood vessels represent a source for wave scattering. To verify this, MRE was performed to quantify alteration of the shear wave speed cs due to the presence of vascular outgrowths using an aortic ring model. Eighteen fragments of rat aorta included in a Matrigel matrix (n=6 without outgrowths, n=6 with a radial outgrowth extent of ~600 µm and n=6 with ~850 µm) were imaged using a 7 Tesla MR scanner (Bruker, PharmaScan). High resolution anatomical images were acquired in addition to multi-frequency MRE (ν = 100, 115, 125, 135 and 150 Hz). Average cs was measured within a ring of ~900 µm thickness encompassing the aorta and were normalized to cs0 of the corresponding Matrigel. The frequency dependence was fit to the power law model cs ~ν(y). After scanning, optical microscopy was performed to visualize outgrowths. Results demonstrated that in presence of vascular outgrowths (1) normalized cs significantly increased for the three highest frequencies (Kruskal-Wallis test, P = 0.0002 at 125 Hz and P = 0.002 at 135 Hz and P = 0.003 at 150 Hz) but not for the two lowest (Kruskal-Wallis test, P = 0.63 at 100 Hz and P = 0.87 at 115 Hz), and (2) normalized cs followed a power law behavior not seen in absence of vascular outgrowths (ANOVA test, P < 0.0001). These results showed that vascular outgrowths acted as micro-obstacles altering the dispersion relationships of propagating shear waves and that MRE could provide valuable information about microvascular changes.

Crucial role of the orexin-B C-terminus in the induction of OX1 receptor-mediated apoptosis: analysis by alanine scanning, molecular modelling and site-directed mutagenesis

BACKGROUND AND PURPOSE

Orexins (A and B) are hypothalamic peptides that interact with OX1 and OX2 receptors and are involved in the sleep/wake cycle. We previously demonstrated that OX1 receptors are highly expressed in colon cancer tumours and colonic cancer cell lines where orexins induce apoptosis and inhibit tumour growth in preclinical animal models. The present study explored the structure-function relationships of orexin-B and OX1 receptors.

EXPERIMENTAL APPROACH

The contribution of all orexin-B residues in orexin-B-induced apoptosis was investigated by alanine scanning. To determine which OX1 receptor domains are involved in orexin-B binding and apoptosis, a 3D model of OX1 receptor docked to the orexin-B C-terminus (AA-20-28) was developed. Substitution of residues present in OX1 receptor transmembrane (TM) domains by site-directed mutagenesis was performed.

KEY RESULTS

Alanine substitution of orexin-B residues, L(11) , L(15) , A(22) , G(24) , I(25) , L(26) and M(28) , altered orexin-B's binding affinity. Substitution of these residues and of the Q(16) , A(17) , S(18) , N(20) and T(27) residues inhibited apoptosis in CHO-S-OX1 receptor cells. The K(120) , P(123) , Y(124) , N(318) , K(321) , F(340) , T(341) , H(344) and W(345) residues localized in TM2, TM3, TM6 and TM7 of OX1 receptors were shown to play a role in orexin-B recognition and orexin-B/OX1 receptor-induced apoptosis.

CONCLUSIONS AND IMPLICATIONS

The C-terminus of orexin-B (i) plays an important role in its pro-apoptotic effect; and (ii) interacts with some residues localized in the OX1 receptor TM. This study defines the structure-function relationship for orexin-B recognition by human OX1 receptors and orexin-B/OX1 receptor-induced apoptosis, an important step for the future development of new agonist molecules.

Kallikrein-related peptidase 7 (KLK7) is a proliferative factor that is aberrantly expressed in human colon cancer

Emerging evidence indicates that serine proteases of the tissue kallikrein-related peptidases family (KLK) are implicated in tumorigenesis. We recently reported the ectopic expression of KLK4 and KLK14 in colonic cancers and their signaling to control cell proliferation. Human tissue kallikrein-related peptidase 7 (KLK7) is often dysregulated in many cancers; however, its role in colon tumorigenesis has not yet been established. In the present study, we analyzed expression of KLK7 in 15 colon cancer cell lines and in 38 human colonic tumors. In many human colon cancer cells, KLK7 mRNA was observed, which leads to KLK7 protein expression and secretion. Furthermore, KLK7 was detected in human colon adenocarcinomas, but it was absent in normal epithelia. KLK7 overexpression in HT29 colon cancer cells upon stable transfection with a KLK7 expression plasmid resulted in increased cell proliferation. Moreover, subcutaneous inoculation of transfected cells into nude mice led to increased tumor growth that was associated with increased tumor cell proliferation as reflected by a positive Ki-67 staining. Our results demonstrate the aberrant expression of KLK7 in colon cancer cells and tissues and its involvement in cell proliferation in vitro and in vivo. Thus, KLK7 may represent a potential therapeutic target for human colon tumorigenesis.

Abstract 5299: The C-terminus of orexin plays a crucial role in the cellular apoptosis induction mediated by OX1 receptor

Orexins (orexin-A and orexin-B) are hypothalamic peptides involved in the sleep/wake control which interact with two GPCR sub-types, OX1R and OX2R. Our group has demonstrated that OX1R was highly expressed in colonic cancer cell lines (HT29, Caco-2, SW480, Lovo…) in which orexins: 1) induce a strong mitochondrial apoptosis; 2) induce a strong inhibition of tumor growth in nude mice xenografted with those cells. This effect was mediated by an original mechanism involving: i) the presence of two ITIMs (immunoreceptor tyrosine inhibitory motif) in the OX1R sequence; ii) the recruitment and activation of the tyrosine phosphatase SHP-2. Moreover, OX1R was expressed in resected colonic tumors and in liver metastases but not in normal tissue. The present study explores the structure-function relationships between orexin-B and its OX1R. The contribution of each side chains of orexin-B were investigated by systematic single alanine (alanine-scanning) exchange of each residue of the native peptides. All modified orexin-B peptides were analyzed for their binding affinities and abilities to induce apoptosis in CHO cells stably transfected with recombinant human OX1R (CHO-OX1R). The data shows that the substitution of L11, L15, I25, G24, L26 and M28 in alanine and A22 in leucine resulted in the loss of binding affinity of orexin-B to its OX1R. Moreover, the substitution of these residues and some others including Q16, A17, S18, N20 and T27 localized mainly in the C-terminal part of orexin-B, strongly alter the ability of the peptide to induce mitochondrial apoptosis in CHO-OX1R. To determine which OX1R domains are involved in orexin-B-induced apoptosis, we have constructed a 3D-molecular model of OX1R derived of structural data recently obtained for beta2 adrenergic receptor. Based on this 3D-model, we have docked the C-terminal end of orexin-B (sequence 20-28) into the whole receptor and performed the substitution of residues presents in transmembrane domains (TM) by directed mutagenesis. Our data reveal that K120, P123, Y124, F340, T341, H344 and W345 localized in TM2, TM3, TM6 and TM7 of OX1R residues play a role in orexin-B recognition and in orexin-B-induced apoptosis. These results strongly suggest that 1) the C-terminal end of orexin-B plays an important role in the pro-apoptotic effect of the peptide; 2) the C-terminal end of orexin-B interacts with some residues localized into the TM of receptor. In conclusion, this study defines the structure-function relationship of ligand recognition and orexin-B-induced apoptosis of human OX1R and should allow the development of new agonist molecules.

Citation Format: Alain Couvineau, Pascal Nicole, Thierry Voisin, Pierre Couvineau. The C-terminus of orexin plays a crucial role in the cellular apoptosis induction mediated by OX1 receptor. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 5299. doi:10.1158/1538-7445.AM2014-5299

Intestinal cell targeting of a stable recombinant Cu-Zn SOD from Cucumis melo fused to a gliadin peptide

The mRNA encoding full length chloroplastic Cu-Zn SOD (superoxide dismutase) of Cucumis melo (Cantaloupe melon) was cloned. This sequence was then used to generate a mature recombinant SOD by deleting the first 64 codons expected to encode a chloroplastic peptide signal. A second hybrid SOD was created by inserting ten codons to encode a gliadin peptide at the N-terminal end of the mature SOD. Taking account of codon bias, both recombinant proteins were successfully expressed and produced in Escherichia coli. Both recombinant SODs display an enzymatic activity of ~5000U mg(-1) and were shown to be stable for at least 4h at 37°C in biological fluids mimicking the conditions of intestinal transit. These recombinant proteins were capable in vitro, albeit at different levels, of reducing ROS-induced-apoptosis of human epithelial cells. They also stimulated production and release in a time-dependent manner of an autologous SOD activity from cells located into jejunum biopsies. Nevertheless, the fused gliadin peptide enable the recombinant Cu-Zn SOD to maintain a sufficiently sustained interaction with the intestinal cells membrane in vivo rather than being eliminated with the flow. According to these observations, the new hybrid Cu-Zn SOD should show promise in applications for managing inflammatory bowel diseases.

Spatial proximity between the VPAC1 receptor and the amino terminus of agonist and antagonist peptides reveals distinct sites of interaction

Vasoactive intestinal peptide (VIP) plays a major role in pathophysiology. Our previous studies demonstrated that the VIP sequence 6-28 interacts with the N-terminal ectodomain (N-ted) of its receptor, VPAC1. Probes for VIP and receptor antagonist PG97-269 were synthesized with a photolabile residue/Bpa at various positions and used to explore spatial proximity with VPAC1. PG97-269 probes with Bpa at position 0, 6, and 24 behaved as high-affinity receptor antagonists (K(i)=12, 9, and 7 nM, respectively). Photolabeling experiments revealed that the [Bpa(0)]-VIP probe was in physical contact with VPAC1 Q(135), while [Bpa(0)]-PG97-269 was covalently bound to G(62) residue of N-ted, indicating different binding sites. In contrast, photolabeling with [Bpa(6)]- and [Bpa(24)]-PG97-269 showed that the distal domains of PG97-269 interacted with N-ted, as we previously showed for VIP. Substitution with alanine of the K(143), T(144), and T(147) residues located in the first transmembrane domain of VPAC1 induced a loss of receptor affinity (IC(50)=1035, 874, and 2070 nM, respectively), and pharmacological studies using VIP2-28 indicated that these three residues play an important role in VPAC1 interaction with the first histidine residue of VIP. These data demonstrate that VIP and PG97-269 bind to distinct domains of VPAC1.

The VPAC1 receptor: structure and function of a class B GPCR prototype

The class B G protein-coupled receptors (GPCRs) represents a small sub-family encompassing 15 members, and are very promising targets for the development of drugs to treat many diseases such as chronic inflammation, neurodegeneration, diabetes, stress, and osteoporosis. The VPAC1 receptor which is an archetype of the class B GPCRs binds Vasoactive Intestinal Peptide (VIP), a neuropeptide widely distributed in central and peripheral nervous system modulating many physiological processes including regulation of exocrine secretions, hormone release, foetal development, immune response … VIP appears to exert beneficial effect in neurodegenerative and inflammatory diseases. This article reviews the current knowledge regarding the structure and molecular pharmacology of VPAC1 receptors. Over the past decade, structure-function relationship studies have demonstrated that the N-terminal ectodomain (N-ted) of VPAC1 plays a pivotal role in VIP recognition. The use of different approaches such as directed mutagenesis, photoaffinity labeling, Nuclear Magnetic Resonance (NMR), molecular modeling, and molecular dynamic simulation has led to demonstrate that: (1) the central and C-terminal part of the VIP molecule interacts with the N-ted of VPAC1 receptor which is itself structured as a « Sushi » domain; (2) the N-terminal end of the VIP molecule interacts with the first transmembrane domain of the receptor where three residues (K(143), T(144), and T(147)) play an important role in VPAC1 interaction with the first histidine residue of VIP.

The N-terminal parts of VIP and antagonist PG97-269 physically interact with different regions of the human VPAC1 receptor

Vasoactive intestinal peptide (VIP) is a widespread neuropeptide, which exerts many biological functions through interaction with the VPAC1 receptor, a class II G protein-coupled receptor. Photoaffinity labeling studies combined with 3D molecular modeling demonstrated that the central and C-terminal parts of VIP (segment 6-28) have physical contacts with the N-terminal ectodomain (N-Ted) of VPAC1 receptor. However, the domain of the hVPAC1 receptor interacting with the N-terminus of VIP (1-5) is still unknown. We have synthesized a photoreactive probe Bpa0-VIP. After photolabeling and receptor cleavage, Nu-PAGE analysis revealed a 5-kDa labeled fragment corresponding to the 130-137 sequence of hVPAC1 receptor, indicating that the N-terminus of VIP also interacts with the N-ted. A photoreactive probe, Bpa0-PG97-269, was also synthesized with the specific peptide antagonist PG97-269. After photoaffinity labeling, a glycosylated 15-kDa fragment is identified by cyanogen bromide (CNBr) cleavage and corresponds to the 43-66 sequence of the hVPAC1 receptor N-ted. These results indicate that: (1) the N-terminal part of VIP physically interacts with the N-ted in the continuity of 6-28 VIP sequence; (2) the N-terminal part of VIP and the selective peptide antagonist (PG97-269) have different sites of interaction with the VPAC1 receptor N-ted.

Serine 447 in the carboxyl tail of human VPAC1 receptor is crucial for agonist-induced desensitization but not internalization of the receptor

The VPAC1 receptor for vasoactive intestinal peptide (VIP) belongs to the class II family of G protein-coupled receptors and is coupled to Gs protein/adenylyl cyclase. We assessed whether 10 different Ser/Thr residues in human VPAC1 receptor intracellular domains play a role in the process of VIP-induced desensitization/internalization by performing a site-directed mutagenesis study. The Ser/Thr residues mutated to Ala include potential G protein-coupled receptor kinase, protein kinase A and protein kinase C targets that are of particular interest for VPAC1 receptor desensitization. The data show that when Chinese hamster ovary cells expressing wild-type receptors were pretreated for 5 min with VIP (50 nM), receptor desensitization occurred with a 10-fold right shift of the ED50 for adenylyl cyclase activation. When the construct with the widest span of mutations was studied, there was no longer any short-term desensitization. By using constructs with fewer and fewer mutations, we identified Ser447 in the C-terminal tail to be crucial for rapid desensitization. We also showed that Ser447 plays an essential role for VIP-induced VPAC1 phosphorylation in Chinese hamster ovary cells. Furthermore, we demonstrated that none of the mutated Ser/Thr residues was involved in down-regulation after a 12-h treatment of cells with 50 nM VIP. Neither were they involved in VIP and VIP-induced receptor internalization as shown using a novel fluorescein-tagged VIP and VPAC1 receptor bearing a Flag epitope in the N-terminal domain and a green fluorescent protein at the C terminus. We conclude that Ser447, a likely G protein-coupled receptor kinase target, is crucial for VIP-induced phosphorylation and rapid desensitization of VPAC1 receptor.

Identification of cytoplasmic domains of hVPAC1 receptor required for activation of adenylyl cyclase. Crucial role of two charged amino acids strictly conserved in class II G protein-coupled receptors

The VPAC1 receptor mediates the action of two neuropeptides, vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating peptide. It is a class II G protein-coupled receptor-activating adenylyl cyclase (AC). The role of the N-terminal extracellular domain of hVPAC1 receptor for VIP binding is now established (Laburthe, M., Couvineau, A. and Marie, J. C. (2002) Recept. Channels 8, 137-153), but nothing is known regarding the cytoplasmic domains responsible for AC activation. Here, we constructed a large series of mutants by substituting amino acids with alanine in the intracellular loops (IL) 1, 2, and 3 and proximal C-terminal tail of the receptor. The mutation of 40 amino acids followed by expression of mutants in chinese hamster ovary cells showed the following. (i) Mutations IL1 result in the absence of expression of mutants, suggesting a role of this loop in receptor folding. (ii) All residues of IL2 can be mutated without alteration of receptor expression and AC response to VIP. (iii) Mutation of residues IL3 points to the specific role of lysine 322 in the efficacy of the stimulation of AC activity by VIP. This efficacy is reduced by 50% in the K322A mutant. (iv) The proximal C-terminal tail is equipped with another important amino acid since mutation of glutamic acid 394 reduces AC response by 50%. The double mutant K322A/E394A exhibits a drastic reduction of >85% in the efficacy of VIP in stimulating AC activity in membranes and cAMP response in intact cells without alteration of receptor expression or affinity for VIP. These data highlight the role of charged residues in IL3 and the proximal C-terminal tail of hVPAC1 receptor for agonist-induced AC activation. Because these charged residues are absolutely conserved in class II receptors for peptides, which are all mediating AC activation, they may play a general role in coupling of class II receptors with the Gs protein.

Human VPAC1 receptor selectivity filter. Identification of a critical domain for restricting secretin binding

The human VPAC1 receptor for vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase activating peptide (PACAP) belongs to the class II family of G protein coupled receptors with seven transmembrane segments. It recognizes several VIP-related peptides and displays a very low affinity for secretin despite >70% homology between VIP and secretin. Conversely, the human secretin receptor has high affinity for secretin but low affinity for VIP. We took advantage of this reversed selectivity to identify a domain of the VPAC1 receptor responsible for selectivity toward secretin by constructing human VPAC1-secretin receptor chimeras. A first set of chimeras consisted of exchanging the entire N-terminal ectodomain or large parts of this domain. They were constructed by overlap PCR, transfected in COS-7 cells, and their ligand selectivity, expressed as the ratio of EC(50) for secretin/EC(50) for VIP (referred to as S/V), in stimulating cAMP production was measured. Two very informative chimeras respectively referred to as S144V and S123V were obtained by replacing the entire ectodomain or only the first 123 amino acids of the VPAC1 receptor by the corresponding sequences of the secretin receptor. Whereas S144V no longer discriminated between VIP and secretin (S/V = 1.2), S123V discriminated between the two peptides (S/V = 300) in the same manner as the wild-type VPAC1 receptor. The motif responsible for discrimination was determined by introducing small blocks or individual amino acids of secretin receptor in the 123-144 sequence of the S123V chimera. The data obtained from 14 new chimeras sustained that two nonadjacent pairs of amino acids, Gln(135) Thr(136) and Gly(140) Ser(141) in the C-terminal end of the N-terminal VPAC1 receptor ectodomain constitute a selective filter that strongly restricts access of secretin to the VPAC1 receptor.

The human VPAC1 receptor: three-dimensional model and mutagenesis of the N-terminal domain

The human VPAC(1) receptor for vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase activating peptide belongs to the class II family of G-protein-coupled receptors with seven transmembrane segments. Like for all class II receptors, the extracellular N-terminal domain of the human VPAC(1) receptor plays a predominant role in peptide ligand recognition. To determine the three-dimensional structure of this N-terminal domain (residues 1-144), the Protein Data Bank (PDB) was screened for a homologous protein. A subdomain of yeast lipase B was found to have 27% sequence identity and 50% sequence homology with the N-terminal domain (8) of the VPAC(1) receptor together with a good alignment of the hydrophobic clusters. A model of the N-terminal domain of VPAC(1) receptor was thus constructed by homology. It indicated the presence of a putative signal sequence in the N-terminal extremity. Moreover, residues (Glu(36), Trp(67), Asp(68), Trp(73), and Gly(109)) which were shown to be crucial for VIP binding are gathered around a groove that is essentially negatively charged. New putatively important residues for VIP binding were suggested from the model analysis. Site-directed mutagenesis and stable transfection of mutants in CHO cells indicated that Pro(74), Pro(87), Phe(90), and Trp(110) are indeed important for VIP binding and activation of adenylyl cyclase activation. Combination of molecular modeling and directed mutagenesis provided the first partial three-dimensional structure of a VIP-binding domain, constituted of an electronegative groove with an outspanning tryptophan shell at one end, in the N-terminal extracellular region of the human VPAC(1) receptor.

Tryptophan 67 in the human VPAC(1) receptor: crucial role for VIP binding

The human receptor subtype for VIP and PACAP, referred to as VPAC(1) receptor, has a large N-terminal extracellular domain which is critical for VIP binding. We further investigated this domain by mutating 12 amino acid residues which could participate in the formation of a tight bend (W67) or a coiled coil motif. They were changed to alanine (A) and the cDNAs were transiently transfected into Cos cells. All mutants but W67A exhibited K(d) values similar to that of the wild-type receptor. For the W67A mutant, no specific (125)I-VIP binding could be observed. Mutants at the W67 site were further characterized after stable transfection of epitope-tagged VPAC(1) receptor-GFP fusion proteins into CHO cells. W67A, W67E, W67H, and W67K mutants neither bound VIP nor mediated adenylyl cyclase activation by VIP. The W67F mutant mediated stimulation of adenylyl cyclase only at high VIP concentrations. Microscopic analysis and antibody binding experiments showed that all mutants were similarly expressed at the cell surface of CHO cells. Therefore tryptophan 67 in the human VPAC(1) receptor plays a crucial role in VIP binding due, in part, to its aromatic moiety.

Identification of key residues for interaction of vasoactive intestinal peptide with human VPAC1 and VPAC2 receptors and development of a highly selective VPAC1 receptor agonist. Alanine scanning and molecular modeling of the peptide

The widespread neuropeptide vasoactive intestinal peptide (VIP) has two receptors VPAC(1) and VPAC(2). Solid-phase syntheses of VIP analogs in which each amino acid has been changed to alanine (Ala scan) or glycine was achieved and each analog was tested for: (i) three-dimensional structure by ab initio molecular modeling; (ii) ability to inhibit (125)I-VIP binding (K(i)) and to stimulate adenylyl cyclase activity (EC(50)) in membranes from cell clones stably expressing human recombinant VPAC(1) or VPAC(2) receptor. The data show that substituting residues at 14 positions out of 28 in VIP resulted in a >10-fold increase of K(i) or EC(50) at the VPAC(1) receptor. Modeling of the three-dimensional structure of native VIP (central alpha-helice from Val(5) to Asn(24) with random coiled N and C terminus) and analogs shows that substitutions of His(1), Val(5), Arg(14), Lys(15), Lys(21), Leu(23), and Ile(26) decreased biological activity without altering the predicted structure, supporting that those residues directly interact with VPAC(1) receptor. The interaction of the analogs with human VPAC(2) receptor is similar to that observed with VPAC(1) receptor, with three remarkable exceptions: substitution of Thr(11) and Asn(28) by alanine increased K(i) for binding to VPAC(2) receptor; substitution of Tyr(22) by alanine increased EC(50) for stimulating adenylyl cyclase activity through interaction with the VPAC(2) receptor. By combining 3 mutations at positions 11, 22, and 28, we developed the [Ala(11,22,28)]VIP analog which constitutes the first highly selective (>1,000-fold) human VPAC(1) receptor agonist derived from VIP ever described.

Site-directed mutagenesis of human vasoactive intestinal peptide receptor subtypes VIP1 and VIP2: evidence for difference in the structure-function relationship

Vasoactive intestinal peptide (VIP1 and VIP2) receptors belong to the new class II subfamily of G protein-coupled receptors. We investigated here human VIP1 and VIP2 receptors by mutating in their extracellular domains all amino acid residues that are conserved in VIP receptors but are different in other members of their subfamily. They are present in 1) the N-terminal domain, i.e., E36, I43, S64, D132 and F138 in the VIP1 receptor and E24, I31, S53, D116 and F122 in the VIP2 receptor; 2) the second extracellular loop, i.e., T288 and S292 in the VIP1 receptor and T274 and S278 in the VIP2 receptor. These residues were changed to alanine (A), and cDNAs were transfected into Cos cells. For the VIP1 receptor, no specific 125I-VIP binding could be detected in cells transfected with the E36A mutant, whereas other mutants exhibited Kd values similar to that of the wild-type receptor, with the exception of S64A, for which a 3-fold increase of Kd was observed. For the VIP2 receptor, no specific 125I-VIP binding could be observed with the E24A mutant, whereas other mutants exhibited dissociation constants similar to that of the wild-type receptor, with the exception of I31A and T274A mutants, for which a 11- and 5-fold increase of Kd was observed, respectively. cAMP production experiments provided evidence that the E36A VIP1 receptor and the E24A VIP2 receptor mutants mediated almost no response upon VIP exposure. For the I31A and T274A mutants of the VIP2 receptor and the S64A mutant of the VIP1 receptor, the EC50 values of VIP for stimulating cAMP production were increased 35, 8 and 3 times as compared with that observed for the wild-type receptor, respectively. Immunofluorescence studies indicated that all mutants were normally expressed by Cos cells. These data provide the first evidence for differences in the structure-function relationship of VIP1 and VIP2 receptors.

Aspartate 196 in the first extracellular loop of the human VIP1 receptor is essential for VIP binding and VIP-stimulated cAMP production

VIP receptors belong to a subfamily of G protein-coupled receptors that includes secretin, glucagon, PTH and several other receptors. We have used site-directed mutagenesis to investigate the requirement of some highly conserved residues in the extracellular loops including aspartate 196 (mutant D196A), leucine 199 (mutant L199A), tryptophane 286 (mutant W286A) and tryptophane 294 (mutant W294A) for the ability of the human VIP1 receptor to bind VIP and to mediate VIP-stimulated cAMP production. After transfection of mutated cDNAs in Cos-7 cells, it appeared that 1) mutants L199A, W286A and W294A bound VIP with the same dissociation constant as the wild-type receptor whereas mutant D196A did not bind 125I-VIP; 2) mutants L199A, W286A and W294A mediate VIP-stimulated cAMP production with the same EC50 as the wild-type receptor whereas VIP displayed a 500-fold decrease of potency in promoting cAMP production through mutant D196A. Since all mutated receptor proteins were expressed and delivered at the plasma membrane (immunofluorescence studies), it is concluded that the first extracellular loop of the human VIP1 receptor contains a highly conserved aspartate residue which is essential for VIP binding and VIP-stimulated cAMP production.

[Directed mutagenesis of human recombinant receptors of vasoactive intestinal peptide of VIP1 and VIP2 type. Difference in structure-activity relationship]

OBJECTIVES

Two vasoactive intestinal peptide (VIP) receptor subtypes have been cloned. We studied the structure-function relationship of human VIP1 and VIP2 receptors by mutating residues specifically conserved in extracellular domains of these receptors: N-terminal domain (E36, I43, S64, D132 and F138 in VIP1 receptor corresponding to E24, I31, S53, D116 and F122 in VIP2 receptor) and second loop (T288 and S292 in VIP1 receptor corresponding to T274 and S278 in VIP2 receptor).

METHODS

Residues were mutated into alanine (A) and the corresponding cDNAs were transfected into Cos cells. Wild-type and mutated receptors were characterized in transfected cells by ligand binding assay using 125I-VIP and cAMP measurements upon VIP challenge.

RESULTS

Regarding the VIP1 receptor, no specific binding of 125I-VIP could be detected on Cos cells transfected with the E36A mutant whereas other mutants, with the exception of S64A, exhibited dissociation constants similar to that of the wild-type receptor. The S64A mutant showed a 3-fold increase of its dissociation constant as compared to the wild-type receptor. cAMP experiments showed that the E36A mutant mediated a very weak stimulation by VIP. Regarding the VIP2 receptor, no specific binding of 125I-VIP could be detected on Cos cells transfected with the E24A. I31A and T274A mutants whereas all other mutants exhibited dissociation constants similar to that of the wild-type receptor. cAMP experiments showed that the E24A mutant mediated a very weak stimulation by VIP. Regarding I31A and T274A mutants, the EC50 values were increased 10 and 50 times as compared to the wild-type receptor, respectively.

CONCLUSION

a) The conserved glutamate (E) residue in the N-terminal domain of VIP1 and VIP2 receptors is crucial for VIP binding; b) The VIP2 receptor contains two conserved residues isoleucine 31 and threonine 274 which are critical for VIP binding while they can be mutated without loss of function in the VIP1 receptor. This difference in the structure-function relationship should be instrumental for the development of a selective pharmacology of VIP receptor subtypes.

Vasoactive intestinal peptide (VIP)1 receptor. Three nonadjacent amino acids are responsible for species selectivity with respect to recognition of peptide histidine isoleucineamide

Vasoactive intestinal peptide (VIP)1 receptors in rats and humans recognize peptide histidine isoleucineamide (PHI) with high and low affinity, respectively. We took advantage of this phenotypic difference to identify the domain responsible for the selective recognition of PHI by rat and human receptors which display >80% sequence identity. After transfection of human and rat receptors in COS cells, the ratio of IC50 for PHI/IC50 for VIP (referred to as P/V) in inhibiting 125I-VIP binding was shown to be >1,000 and <40, respectively. Construction of eight rat/human receptor chimerae by overlap polymerase chain reaction and determination of their P/V ratios demonstrated that the critical domain for PHI recognition is present within a sequence comprising part of the first extracellular loop and third transmembrane domain. This domain contains three different amino acids numbered according to human and rat sequences, respectively, e.g. Gln207 (human) versus His208 (rat), Gly211 versus Ala212 and Met219 versus Val220. Site-directed mutagenesis introducing individual, double, or triple mutations in a chimeric construct revealed that all three amino acids were involved in the recognition of PHI. Triple mutations were then introduced in the wild-type receptors i.e. Q207H, G211A, M219V human VIP1 receptor and H208Q, A212G, V220M rat VIP1 receptor, resulting in a complete change in their phenotype from human to rat and from rat to human, respectively. The results demonstrate that three nonadjacent amino acids are responsible for the selective recognition of PHI by human and rat VIP1 receptors.

Highly conserved aspartate 68, tryptophane 73 and glycine 109 in the N-terminal extracellular domain of the human VIP receptor are essential for its ability to bind VIP

The human VIP receptor belongs to a subfamily of G protein-coupled receptors that includes secretin, glucagon and several other receptors. We have used site-directed mutagenesis to investigate the requirement of highly conserved aspartate 68 (mutant D68G), tryptophane 73 (mutant W73G), proline 87 (mutant P87G), glycine 109 (mutant delta 109) and tryptophane 110 (mutant W110G) for the ability of the human VIP receptor to bind VIP. After transfection of mutated cDNAs in Cos-7 cells, it appeared that mutants G87P and W110G bound VIP with the same dissociation constant as the wild type receptor whereas mutants W73G, P87G and delta 109 did not bind VIP. Since all mutated receptor proteins were synthesized by Cos-7 cells (Western blot) and expressed at the plasma membrane level (immunofluorescence studies), it is concluded that the N-terminal extracellular domain of the human VIP receptor contains highly conserved amino acid residues which are essential for its intrinsic binding activity.

Effects of sulindac and oltipraz on the tumorigenicity of 4-(methylnitrosamino)1-(3-pyridyl)-1-butanone in A/J mouse lung

The efficacies of the non-steroidal, anti-inflammatory drug sulindac and the schistosomicidal agent oltipraz in inhibiting lung tumorigenesis was measured in A/J mice. Lung tumors (15.7 tumors/mouse) were induced by the tobacco-specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK; 9.1 mg/mouse) administered in drinking water for 7 weeks. Feeding mice with sulindac (123 mg/kg diet), 2 weeks before carcinogen treatment until they were killed reduced tumor multiplicity by 53%. Oltipraz (250 mg/kg diet), however, has no effect on tumorigenesis. The absorption and metabolism of NNK were compared in the stomachs and intestines isolated from mice fed AIN-76A diet or sulindac + diet. Sulindac had no effect on alpha-carbon hydroxylation, pyridine N-oxidation or carbonyl reduction of NNK. Mouse lung explants were cultured with 4.7 microM [5-3H]NNK for 4 or 8 h. The addition of 1 mM sulindac to the culture medium reduces the alpha-carbon hydroxylation and pyridine N-oxidation of NNK. However, the administration of sulindac in the diet prior to the excision of the lung explants had no effect on these two metabolic pathways. We compared the levels of sulindac and its sulfide and sulfone metabolites in the lungs, livers and plasma of mice fed an AIN-76A diet containing 130 mg sulindac/kg for 2 weeks. The sulfide metabolite was the most abundant of the three compounds in plasma (17.6 pmol/microliters) and liver tissues (17.7 pmol/mg) but it could not be detected in lung tissues. These results show that non-steroidal anti-inflammatory drugs constitute a new class of chemopreventive agents in lung tumorigenesis. The tumor chemopreventive activity of sulindac is not mediated by the sulfide metabolite responsible for its anti-inflammatory activity.