Jean-Yves Couraud

Systemic Capsaicin Pretreatment Fails to Block the Decrease in Food-Motivated Behavior Induced by Lipopolysaccharide and Interleukin-1β

The physiological and behavioral disturbances observed during an infection can be reproduced by systemic administration of proinflammatory cytokines (e.g., interleukin (IL)-1, IL-6, tumor necrosis factor-alpha) or lipopolysaccharide (LPS), a potent inducer of these cytokines. It is now well established that these molecules induce their effects by acting centrally, however, the mechanisms by which they reach central structures are not clear. We have earlier proposed that the humoral immune message is converted to a central neural activation by the action of cytokines on peripheral terminations of afferent neurons. Subdiaphragmatic vagotomy abolishes several effects of peripherally injected IL-1beta and LPS (e.g., decreased food-motivated behavior and social exploration, central expression of cytokines). To further define the nature of the peripheral fibers implicated in this phenomenon, we used a potent sensory neurotoxin, capsaicin, to selectively destroy C-fiber afferents. Adult rats were injected I.P. with a total dose of 25 mg/kg capsaicin in a series of 10 injections over a 48-h period. Adult mice were injected I.P. with a total dose of 75 mg/kg in a series of seven injections over a 7-day period. Although capsaicin treatment altered visceral chemosensory function, corneal and pain sensitivity, vagal-mediated anorexic effects of cholecystokinin, and depleted levels of substance P in the thoracic spinal cord, it was completely ineffective in blocking the decrease in food-motivated behavior induced by IL-1beta (4 microg/rat I.P. in rats) and LPS (250 microg/kg I.P. in rats and 400 microg/kg I.P. in mice). Thus, other afferents besides capsaicin-sensitive C-fibers appear to be involved in the transduction of cytokine effects during inflammatory and infectious events.

Identification in the NK1 tachykinin receptor of a domain involved in recognition of neurokinin A and septide but not of substance P

The three mammalian tachykinins, substance P (SP), neurokinin A (NKA) and neurokinin B (NKB), exert their physiological effects through specific receptors, NK1, NK2 and NK3, respectively. However, homologous binding studies have recently demonstrated that, contrary to the generally accepted belief, NKA could bind NK1 receptor with high affinity (Hastrup and Schwartz, 1996). Using COS‐7 cells expressing the human NK1 receptor, we show that two simultaneous point mutations (E193L and V195R) in a restricted five amino acid sequence (the (193–197) region), selected because of its hydropathic complementarity with the common C‐terminal extremity of tachykinins, abolish both the high‐affinity binding and highly potent biological activity of NKA, without affecting those of SP. In addition, the same mutations also suppressed the high functional activity of septide, a synthetic SP atypical agonist ([pGlu6‐Pro9] SP 6–11). These results suggest that the (193–197) region, located at the end of the second extracellular loop of the receptor, could be part of a common high‐affinity binding domain for both NKA and septide, distinct from the SP binding site.

Antipeptide Polyclonal Antibodies that Recognize a Substance P-Binding Site in Mammalian Tissues: A Biochemical and Immunocytochemical Study

Abstract: We used complementary peptide methodology to obtain antibodies against the receptor for the neuropeptide substance P, specifically directed at the ligand‐binding domain. Rabbits were immunized with two distinct peptides derived from the sequence of the RNA complementary to the mRNA for substance P. Binding experiments revealed that antipeptide polyclonal antibodies were able to recognize, through their paratope, a specific binding site on the rat parotid cell membranes. Substance P and antibodies competed for this binding site, because preincubation of membranes in the presence of substance P significantly reduced antibody binding, and conversely, preincubation of membranes in the presence of antibodies partly inhibited the binding of radioiodinated substance P. Immunocytochemical experiments performed on the rat cervical spinal cord show that the distribution of labeling by antibodies is similar to that observed by conventional autoradiography using 125I‐substance P. Here again, control experiments demonstrated that antibodies and substance P were competing for the same binding site on the spinal cord. These biochemical and immunocytochemical data indicate that antipeptide antibodies recognize a substance P membrane binding site in nervous and nonnervous mammalian tissues. This site is likely to correspond to the NK1 specific receptor for substance P.

A monoclonal antibody to the ligand-binding domain of the neurokinin 1 receptor (NK1-R) for the neuropeptide substance P

Monoclonal antibodies to the binding site of the NK1 receptor for the neuropeptide substance P were produced in mice using the complementary or antisense peptide methodology. Among several anti-peptide monoclonal antibodies, we selected the mAb12 antibody which specifically crossreacted, through its paratope, with a binding site present on membranes from rat parotid gland cells, with an affinity close to 2 x 10(-7) M and with membranes from CHO cells expressing human brain NK1 receptors. Immunocytochemical investigations using mAb12 revealed immunostaining whose distribution in the dorsal horns of rat spinal cord fits well with the known location of NK1 receptors. In both biochemical and immunocytochemical experiments, the competition occurring between the antibody and substance P, or a substance P-protein conjugate, indicates that mAb12 recognizes a membrane epitope located at or near the substance P binding domain on the NK1 receptor. Immunization of mice with mAb12 led to the production of specific anti-substance P antibodies, again suggesting that mAb12 shares common structural features with the neuropeptide. This monoclonal antibody can now be used in further biochemical or cytochemical characterizations of NK1 receptors. Owing to its fine specificity, mAb12 could also serve as a molecular model for designing peptides, possibly displaying pharmacological properties in the various processes in which substance P is involved, e.g. immunomodulation, inflammation or chronic pain.

Enhancement of Antibody Responses in DNA Vaccination Using a Vector Encoding a Universal T-Helper Cell Epitope

DNA vaccination appears as a very promising approach to raise protective antibodies against a variety of proteins from pathogens or tumor cells, but is often hindered by the low immunogenicity of the genetic vectors used for the immunizations. To enhance the humoral response through improvement of the antigenic presentation of newly synthesized proteins upon vaccination, we engineered a plasmid coding for a low immunogenic protein (an scFv, i.e. the single-chain Fragment variable of a well-characterized antibody) fused to a small-size universal T-helper cell epitope derived from tetanus toxin, whose efficiency in classical protein-based immunization protocols has already been demonstrated. We found that immunization of C57Bl/6 mice using this vector greatly enhanced the production not only of specific antibodies recognizing essentially conformational epitopes on the undenatured scFv protein but also of antibodies against linear epitopes on the denatured protein. Since this T-epitope is known to be accommodated by several haplotypes of H-2 molecules in mice, as well as by various class II MHC molecules in humans, the results reported here allow us to conclude that this method could be of general interest for future applications of genetic immunization, including DNA-based vaccinations in humans.

Anti-idiotypic antibodies as a tool for cytochemical identification of substance P receptors in the central nervous system.

Anti-idiotypic antibodies may serve as valuable probes for cytological identification of peptide receptors in the CNS. We have previously described the preparation of anti-substance P (SP) anti-idiotypic antibodies (anti-Id Ab) and have shown that they recognize SP receptors. These anti-Id Ab can be used in cytology to label SP receptors in CNS. We chose rat cervical spinal cord as a model because SP is present in large amounts in the dorsal and ventral horns, where it is implicated in pain and in motor function, respectively. After application of an indirect immunoperoxidase technique to tissue sections from perfused animals, immunolabeling was seen in the two superficial layers of the dorsal horn, the area surrounding the central canal, extending along the white matter in lamina VII, and in part of the ventral horn. This localization is in accordance with the classical distribution of SP receptors as seen by autoradiography with labeled SP. In the light of control experiments, as well as of biochemical and pharmacological arguments, we discuss the specificity of the immunolabeling. We conclude that anti-Id Ab recognize NK-P receptors, although crossreaction with NK-A or NK-B receptors cannot be totally ruled out.

Substance P receptor immunodetection in the spinal cord: comparative use of direct anti-receptor antibody and anti-complementary peptide antibody

The immunolocalization of substance P (SP) receptors was compared in the rat spinal cord using either a direct anti-substance P NK1-receptor antibody (anti-SPR) or an anti-complementary peptide antibody (anti-CP). The first antibody recognizes an intracellular epitope, the C-terminal tail of the NK1-receptor. The second antibody recognizes an extracellular epitope located at or near the ligand-binding domain because anti-CP antibody and SP were previously shown to compete for binding to the receptor. At the light microscope level, it was observed that anti-CP antibody labels both laminae I and II of the dorsal horn, while anti-SPR antibody labels exclusively lamina I, except at the lumbar level. This could suggest that spinal NK1 receptors are heterogeneous. Anti-SPR antibodies may recognize an NK1 receptor subclass confined to lamina I. Conversely, anti-CP antibody may recognize either another receptor subclass or two different subclasses present in laminae I and II. At the electron microscope level, labeling was localized either on the intracellular or the extracellular face of the plasma membrane depending on the location of the epitope recognized by both antibodies on the transmembrane receptor. However, using either antibody, the ultrastructural labeling was found at non-junctional sites, suggesting that SP may act in a non-synaptic manner on all putative receptor subclasses.

IMPORTANCE OF HYDROPATHIC COMPLEMENTARITY FOR THE BINDING OF THE NEUROPEPTIDE SUBSTANCE P TO A MONOCLONAL ANTIBODY : EQUILIBRIUM AND KINETIC STUDIES

In a previous study (Boquet et al., 1995, Molec. Immunol. 32, 303-308) we observed remarkable inversions of hydropathic profiles between complementarity determining regions (CDRs) of an anti-substance P monoclonal antibody (SP31) and the corresponding 5 amino acid C-terminal peptide epitope. Here we demonstrate the importance this hydropathic complementarity by measuring the immunoreactivity of SP-related peptides which have been modified in their C-terminal parts so that hydropathic profile has been conserved (by substituting amino acids in the epitope) or modified (by mixing the sequence of amino acids in the epitope). Experiments performed in equilibrium conditions using a competitive enzyme immunoassay showed that most of the peptides conserving the hydropathic profile of SP epitope were recognized by mAb SP31 (even if marked variations in affinity were observed), while those for which the hydropathic profile was modified exhibited very low or undetectable affinity. The kinetic parameters (ka and kd) of peptide-antibody interactions were determined using Surface Plasmon Resonance technology (BIACORE 2000). These measurements showed that all peptides recognized by mAb SP31 had similar association rate constants (close to 2 x 10[5] M[-1] s[-1]), differences in binding affinities essentially resulting from differences in dissociation rate constants (ranging from 1.61 x 10[-4] to 1.15 x 10[-1] s[-1]). From these results, it was concluded that hydropathic complementarity between the epitope and the paratope could be a necessary but not sufficient condition for establishing high-affinity binding. We hypothesize that hydropathic interactions may play a critical role during the first contacts between antibody CDRs and the peptide, possibly by favouring reorganization of water molecules at the antibody-peptide interface.

Generating antibodies against the native form of the human prion protein (hPrP) in wild-type animals: a comparison between DNA and protein immunizations.

Generation of therapeutic antibodies against human proteins is hampered by the difficulty of obtaining large quantities of correctly folded immunogens when following classic immunization procedures. Here we compared several genetic immunization protocols for their potential ability to generate high levels of antibodies against proteins expressed in their native form. We chose as a model the prion protein (PrP) because it has been demonstrated that the recognition of the native conformation of PrP is an absolute prerequisite for anti-PrP antibodies to be used as therapeutic tools for prion diseases, a group of lethal neurodegenerative disorders. We designed two human PrP-DNA vectors, containing or not a stimulatory T cell epitope, which were injected into mice following four different protocols: in the naked form with or without electroporation, or protected by cationic polymers or block copolymers. For comparison, other animals received conventional injections of recombinant human PrP with Freunds adjuvant or alum. We found that genetic immunization, carried out especially through DNA electroporation and, to a lesser extent, through injection of block copolymer-protected DNA, was able to generate high amounts of antibodies recognizing native PrP as expressed on the cell surface. Conversely, protein immunizations led to very high levels of antibodies against PrP immobilized on microtiter plates, but unable to recognize the native cell membrane-bound PrP. This clearly demonstrates the usefulness of genetic immunization, when performed under well defined conditions, in raising antibodies to native proteins. These results are of interest not only in view of passive immunotherapy of prion diseases, but also, more generally, in view of generating antibodies to human membrane proteins for immunotherapeutic or immunodiagnostic purposes.

Curative properties of antibodies against prion protein: a comparative in vitro study of monovalent fragments and divalent antibodies.

Prion diseases, which include Creutzfeldt-Jakob disease (CJD) in humans, are a group of devastating neurodegenerative disorders for which no therapy is yet available. However, passive immunotherapy appears to be a promising therapeutic approach, given that antibodies against the cellular prion protein (PrPc) have been shown in vitro to antagonize deposition of the disease-associated prion protein (PrPSc). Nevertheless, in vivo deleterious side effects of injected anti-PrP antibodies have been reported, mainly due to their Fc fragments and divalence. In this context, we examined here the ability of five Fabs (monovalent fragments devoid of the Fc part), prepared from antibodies already characterized in the laboratory, to inhibit prion replication in infected neuronal cells. We show that all Fabs (which all retain the same apparent affinity for PrPc as their whole antibody counterpart, as measured in EIA experiments) recognize quite well membrane bound-PrP in neuronal cells (as shown by flow cytometry analysis) and inhibit PrPSc formation in infected cells in a dose-dependent manner, most of them (four out of five) exhibiting a similar efficiency as whole antibodies. From a fundamental point of view, this report indicates that the in vitro curative effect of antibodies i) is epitope independent and only related to the efficiency of recognizing the native, membrane-inserted form of neuronal PrP and ii) probably occurs by directly or indirectly masking the PrPc epitopes involved in PrPSc interaction, rather than by cross-linking membrane bound PrPc. From a practical point of view, i.e. in the context of a possible immunotherapy of prion diseases, our data promote the use of monovalent antibodies (either Fabs or engineered recombinant fragments) for further in vivo studies.