METHOD FOR THE DIAGNOSIS AND/OR PROGNOSIS OF INFLAMMATORY STATES

Abstract

The invention relates to a method for the diagnosis and/or prognosis of inflammatory states.

Description

The invention relates to a method for the diagnosis and/or prognosis of inflammatory states.

Virus receptor-binding domain (RBD) are found in particular in the envelope glycoprotein (Env) of viruses and are able to bind to membrane receptors of different target cells.

Gamma and deltaretroviruses have been shown to interact with cell surface through active receptors that belong to the multimembrane protein family. Those receptors for which a function has been identified (or most certainly those with no identified function) are directly involved in cellular metabolism.

Retroviral envelope-derived probes, which can be used for specific, high-affinity tagging of metabolic transporters on human cells, have been disclosed in WO 2010/079208. These transporters carry a wide variety of metabolites, including, but not limited to: neutral amino acids (AA), cationic AA, glucose, heme and vitamins.

Retroviral envelope-derived probes of WO 2010/079208 have been used for the detection of membrane receptors present in a target cell such as haematopoietic stem cells, such as CD34 cells, or differentiated cells such as B-cell or T-cell

Myelocyte and monocyte lines (granulocytes) play a major role in body's response to stress. During infestation by pathogens, regulated signals by epithelial and inflammatory cells get position to coordinate innate and acquired immunity. A rapid intervention is necessary and involves a complete reprogramming of quiescent circulating myelocyte and monocyte lines to be activated and migrate to injury sites. This turn over, requiring gene transcription and protein production, is energy-dependent. It needs nutrients and metabolites absorption that can be reflected with an increase of metabolic transporters at the surface of inflammatory cells.

Asthma is a chronic disease characterized by bronchoconstriction, wheezing, cough and breath difficulties during exacerbations. This pathology affects about 300 million worldwide. The airway inflammation is generated by an influx of myelocyte and monocyte lines in the lungs; mostly eosinophils seem to be implied as well as neutrophils.

Allergy is also a disorder of the immune system caused by the suractivation of mast cells and basophils when they identify allergen-specific immunoglobulin IgE. Activated cells release histamine and cytokines maintaining and aggravating the reaction of inflammation. Allergic crisis could manifest minor symptoms but also serious reactions as respiratory difficulties and coma.

Cystic fibrosis (also known as CF) is a common disease which affects the entire body, causing progressive disability and often early death.

Difficulty breathing is the most serious symptom and results from frequent lung infections that are treated, though not cured, by antibiotics and other medications. A multitude of other symptoms, including sinus infections, poor growth, diarrhea, and infertility result from the effects of CF on other parts of the body.

The increasing importance of these pathologies makes the discovery of a rapid detection of them or of therapeutical agents highly desirable.

One of the aims of the present invention is to provide RBD for the detection of membrane receptors present in granulocytes indicating an inflammatory state.

Another aim of the invention is to provide a diagnosis and/or prognosis process of an inflammation state.

Still another aim of the invention is to provide a method for measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal

The present invention relates to the use of at least one soluble receptor-binding domain (RBD), for the identification and quantification of the expression of membrane receptors present on the surface of target granulocytes, said identification and quantification taking place at a given time or during a given time interval, and allowing the diagnosis and/or prognosis of inflammatory states in a mammal

By receptor-binding domain (RBD) is meant is a functional fragment (or a part) of a glycoprotein contained in the envelope of a virus so long it retains some or all of the binding properties of the RBD to a membrane receptor present on the surface of target granulocytes, and can be obtained for example by cloning.

One or more amino acids can be added to, deleted, or substituted from the RBD sequence of this fragment or part of glycoprotein so long it retains the ability to bind to a membrane receptor present on the surface of target granulocytes.

By the term “glycoprototein” is meant an envelope glycoprotein, a coat glycoprotein or a fusion glycoprotein.

Said part or fragment or totality of the RBD of the glycoprotein of the virus is liable to bind to or interact with one or more membrane receptor(s) of a target granulocyte.

The expression “liable to bind or to interact with at least one or more membrane receptor(s)” means that said part or fragment or totality of the RBD forms a complex with a receptor of the target granulocyte or to several receptors of the target granulocyte.

The complex may thus be formed in vitro in the case where the target granulocytes have been previously isolated from an animal

The complex can also be formed ex vivo.

The complex can also be formed in vivo in the case where the RBD is injected to an animal and interact with the target granulocytes in the animal organism.

By “membrane receptor” it is defined in the invention any protein or polypeptide anchored in the plasma membrane of cells. Said membrane receptor allows the interaction with glycoprotein of viruses.

Preferably the membrane receptors according to the invention are members of the multimembrane-spanning protein family which functions as transporters, such as nutriment and metabolite transporters, i.e. multimembrane-spanning proteins that allow the transport of nutriments and metabolites across the plasma membrane. (RBD and receptors are described in FIG. 1).

By “target granulocyte” is meant a cell belonging to myelocyte or monocyte lines and presenting a distinctive array of receptors anchored within the membrane of the cell.

The “target granulocyte” can be isolated from an animal, and is for example a mammalian granulocyte, in particular neutrophils, eosinophils, basophils and mast cells, preferably during an inflammation state.

The expression “identification and the quantification of the expression of membrane receptors present on the surface of target granulocyte” means that when a target granulocyte expresses a membrane receptor, i.e. said receptor is present on the surface of the target granulocyte, therefore a complex is formed between the membrane receptor of a biological interest target granulocyte and RBD.

That complex can be detected if the RBD has been for instance, but without being limited to, covalently coupled with a detectable molecule such as an antibody constant fragment (Fc) or a fluorescent compound (cyanins, alexa, quantum dots . . . . )

That complex can also be detected if the RBD has been tagged with different means well known by a person skilled in the art.

For instance, but without limitations, the tag used in the invention can be Hemaglutinin Tag, Poly Arginine Tag, Poly Histidine Tag, Myc Tag, Strep Tag, Flag Tag, S-Tag, HAT Tag, 3× Flag Tag, Calmodulin-binding peptide Tag, SBP Tag, Chitin-binding domain Tag, GST Tag, Maltose-Binding protein Tag, GFP and EGFP Tag, RFPs Tag, YFP Tag, CFP Tag, T7 tag, V5 tag, Xpress tag and all fluorescent molecules having an emission maximum comprised from 445 nm to 655 nm available from Olympus America Inc.

The use of a RBD allows therefore on the one hand the identification of the receptor expressed on the target granulocyte depending on the RBD used and on the other hand the quantification of the complex formed, and thus the presence or not of a membrane receptor on the target granulocyte and its quantification.

The expression “at a given time or during a given time interval” means that the detection and/or the quantification of the complex formed can be made just after the contacting of the RBD and the membrane receptor of the target granulocyte or after several minutes, in particular from 1 to 59 minutes, or several hours, in particular from 1 to 47 h, preferably 24 h, or days, in particular from 2 to 7 days, preferably 3 days, or several weeks, preferably 3 to 6 weeks when evaluating decay of said membrane receptors on the target granulocyte, after said contacting, depending on the cells and the contacting conditions, in order to evaluate the modification of the expression of membrane receptors.

Contacting conditions include also the temperature that can vary from 0° C. to 37° C., in particular 0, 1, 2, 3 or 4° C., preferably near room temperature, in particular from 18° C. to 25° C., in particular 18, 19, 20, 21, 22, 23, 24 or 25° C., more preferably from 26 to 37° C., in particular 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, or 37° C., preferably 30 or 37° C. depending on the target granulocytes.

By “inflammation state” is meant acute or chronic inflammation occurring during allergy, asthma, acne vulgaris, autoimmune diseases, chronic prostatitis, glomerulonephritis, hypersensitivities, inflammatory bowel diseases, pelvic inflammatory disease, reperfusion injury, rheumatoid arthritis, sarcoidosis, transplant rejection, vasculitis, interstitial cystitis.

In an advantageous embodiment, said inflammatory state is an inflammation of the respiratory tract.

The invention thus allows, by using the receptor binding domains defined above, the identification and quantification of particular expressed receptors at the surface of granulocytes cells, indicating an inflammatory state of said granulocytes, said expressed receptors being not expressed or expressed in a lesser extent in normal conditions, and therefore allowing the diagnosis and/or the prognosis of pathologies in which an inflammatory state is implicated such as pathologies defined above.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, for the identification and quantification of the expression of membrane receptors present on the surface of target granulocytes, said identification and quantification taking place at a given time or during a given time interval, and allowing the diagnosis and/or prognosis of inflammatory states, provided that when only one RBD is used, said membrane receptor is not GLUT1.

In this embodiment, when one RBD is used for the identification and quantification of the expression of membrane receptors present on the surface of target granulocytes for the diagnosis and/or prognosis of inflammatory states, then said membrane receptor identified and quantified is not GLUT1. In other words, said membrane receptor is a membrane receptor other than GLUT1.

Said inflammatory states can be as defined above or in particular, inflammation of the respiratory tract.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said at least one soluble receptor-binding domain is a set of three to twenty soluble receptor-binding domains, preferably a set of three to twelve soluble receptor-binding domain in particular three, four, five, six seven, eight, nine, ten, eleven, or twelve receptor-binding domain.

In this embodiment, three to up to twenty RBD are used, depending of the number of receptors being present at the surface of the cell.

Each RBD recognizes at least one membrane receptor and each membrane receptor is recognized by at least one RBD.

That means that each RBD of said set can interact either with only one receptor, or with two or more distinct receptors, and that two or more RBDs can interact with the same membrane receptor or with two or more distinct receptors.

Whatever the number of RBD used, if several RBD are used, each RBD can recognize the same receptor named R₁ for example, or two or more distinct receptors R₁ and R₂ for example, or more than two distinct receptors R₁ to R_n (n>3) for example, the receptors recognized by each RBD being the same or different.

Therefore, in this embodiment, all the combinations between the three to twenty RBD and the membrane receptors are included.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said at least one soluble receptor-binding domain is a set of three to twenty soluble receptor-binding domain, preferably a set of three to twelve soluble receptor-binding domain in particular three, four, five, six seven, eight, nine, ten, eleven, or twelve receptor-binding domain, provided that at least one soluble receptor-binding domain of said set does not interact with GLUT1 membrane receptor.

In this embodiment, each RBD recognizes at least one membrane receptor and each membrane receptor is recognized by at least one RBD.

That means that each RBD of said set can interact either with the same receptor, but in this case at least one soluble receptor-binding domain of said set does not interact with GLUT1 membrane receptor, that is at least one soluble receptor-binding domain of said set interacts with a membrane receptor other than GLUT1, or with two or more distinct receptors.

Therefore, in this embodiment, all the combinations between the three to twenty RBD and the membrane receptors are included provide that at least one soluble receptor-binding domain of said set interacts with a membrane receptor other than GLUT 1.

The upper limit of the number of RBD is only due to the method used to detect the formed complex, i.e. by Fluorescence Activated Cell Sorting (FACS) the number of channels of which is at present time limited to twenty but it could be higher than twenty with other methods.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said target granulocytes are selected from the list consisting of neutrophils, eosinophils, basophils and mast cells.

Neutrophil granulocytes are generally referred to as either neutrophils or polymorphonuclear neutrophils (or PMNs) and form an essential part of the innate immune system.

Neutrophils are normally found in the blood stream. However, during the beginning (acute) phase of inflammation, neutrophils are one of the first-responders of inflammatory cells to migrate toward the site of inflammation, firstly through the blood vessels, then through interstitial tissue.

Basophil granulocytes, also referred to as basophils, are the least common of the granulocytes. Basophils appear in many specific kinds of inflammatory reactions, particularly those that cause allergic symptoms.

Eosinophil granulocytes, usually called eosinophils, are one of the immune system components responsible for combating multicellular parasites and certain infections in vertebrates. Along with mast cells, they also control mechanisms associated with allergy and asthma.

Mast cells play a key role in the inflammatory process. When activated, a mast cell rapidly releases its characteristic granules and various hormonal mediators into the interstitium. Mast cells can be stimulated to degranulate by direct injury (e.g. physical or chemical [such as opioids, alcohols, and certain antibiotics such as polymyxins]).

In an advantageous embodiment, said membrane receptors can be chosen among, but without being limited to, CAT1, PiT2, XPR1, SMIT1, Plasmolipin, PiT1, ASCT1, ASCT2, FLVCR, feTHTR1, PAR, GLUT1.

The above mentioned membrane receptors are disclosed in Manel et al. Frontiers in Bioscience, 9, 3218-3241, 2004.

PAR has been identified as PAR 1 (or hRFT3) (GenBank accession no. NM_—024531) and PAR 2 (or hRFT1).

Said membrane receptor can also be an unidentified receptor the complex of which with a RBD can be identified and quantify in order to identify and quantify the expression of said receptor at the surface of target granulocyte.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said target granulocytes are neutrophils and said inflammatory state is cystic fibrosis.

Cystic fibrosis (also known as CF) is a common disease which affects the entire body, causing progressive disability and often early death.

Difficulty breathing is the most serious symptom and results from frequent lung infections that are treated, though not cured, by antibiotics and other medications. A multitude of other symptoms, including sinus infections, poor growth, diarrhea, and infertility result from the effects of CF on other parts of the body.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said neutrophils are blood neutrophils or lung neutrophils.

Airway disease in cystic fibrosis (CF) is due to the massive recruitment of blood polymorphonuclear neutrophils (PMN) into lungs. PMN in this context have been shown to go through an anabolic reprogramming suspected to be due to a complete change of metabolic physiology.

One of the advantages of the invention is to characterize these changes of metabolic physiology, with receptor-binding domain (RBD) of retrovirus envelope glycoproteins (Env) liable to bind transporters directly linked to cell metabolism.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said target granulocytes are eosinophils and said inflammatory state is allergy and/or asthma.

As previously indicated, the airway inflammation is generated by an influx of myelocyte and monocyte lines in the lungs; mostly eosinophils seem to be implied as well as neutrophils.

The identification and quantification of membrane receptors expressed on eosinophils and/or neutrophils is thus of interest in the diagnosis and/or prognosis of allergy and/or asthma.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said target granulocytes are basophils and said inflammatory state is allergy.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said target granulocytes are masts and said inflammatory state is allergy.

Allergy is also a disorder of the immune system caused by the suractivation of mast cells and/or basophils when they identify allergen-specific immunoglobulin IgE.

The identification and quantification of membrane receptors expressed on eosinophils and/or masts is thus of interest in the diagnosis and/or prognosis of allergy.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said RBD is selected from the list consisting of SEQ ID NO: 1 to 31.

The SEQ IDs 1 to 31 are constituted of the signal peptide when known, the receptor binding domain, the proline rich region (PRR) when known and the CXXC motif located downstream of the PRR.

The list comprising SEQ IDs 1 to 31 defined above is not limitative and can be extended to all the RBD that can be found in a mammal

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said RBD is selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

Depending on the granulocytes implied in said pathology, one RBD can be enough to identify and quantify the membrane receptors expressed on said granulocyte, but in some cases, two or more RBD are necessary to carry out said identification and quantification.

Thus, single RBD or combinations of RBD of examples 1 to 3 are used as examples only and it is obvious that other single RBD or combinations of RBD can be used for identification and quantification of the expression of membrane receptors present on the surface of target granulocytes.

Therefore, in one embodiment, the invention discloses the use as defined above, wherein said RBD is Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is Feline endogenous retrovirus (RD 114, SEQ ID NO:3).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is Bovine Leukaemia Virus (BLV, SEQ ID NO: 30).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is a combination of two soluble RBD selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is a combination of three soluble RBD selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is a combination of four soluble RBD selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is a combination of five soluble RBD selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In another embodiment, the invention discloses the use as defined above, wherein said RBD is a combination of six soluble RBD selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21).

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said at least one soluble receptor-binding domain is a combination of two soluble receptor-binding domain (RBD).

In an advantageous embodiment, at least one of said soluble receptor-binding domain of said combination does not interact with GLUT1 membrane receptor, that is at least one soluble receptor-binding domain of said combination interacts with a membrane receptor other than GLUT1.

The following combinations of two RBD illustrate said both embodiments (with and without the proviso concerning GLUT1) without limiting the invention and other combinations of two RBDs can be under the scope of the present invention.

Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1) and Feline endogenous retrovirus (RD114, SEQ ID NO:3),

Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1) and Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20),

Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1) and Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28),

Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1) and Bovine Leukaemia Virus (BLV, SEQ ID NO: 30),

Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1) and Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21),

Feline endogenous retrovirus (RD114, SEQ ID NO:3) and Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20),

Feline endogenous retrovirus (RD 114, SEQ ID NO:3) and Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28),

Feline endogenous retrovirus (RD114, SEQ ID NO:3) and Bovine Leukaemia Virus (BLV, SEQ ID NO: 30),

Feline endogenous retrovirus (RD114, SEQ ID NO:3) and Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21),

Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20) and Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28),

Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20) Bovine Leukaemia Virus (BLV, SEQ ID NO: 30),

Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20) Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21),

Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28) and Bovine Leukaemia Virus (BLV, SEQ ID NO: 30).

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said combination is the combination of HTLV-2 RBD (SEQ ID NO: 28) and KoRV RBD (SEQ ID NO: 20) and said membrane receptors are GLUT1 and PiT1 respectively, said membrane receptors being expressed in particular in lung neutrophils and blood neutrophils.

In an advantageous embodiment, the present invention relates to the use of said combination of HTLV-2 RBD (SEQ ID NO: 28) and KoRV RBD (SEQ ID NO: 20) as defined above, wherein the expression of said membrane receptors in lung neutrophils is increased compared with the expression of said membrane receptor in blood neutrophils.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said soluble receptor binding domains are a combination of RD114 RBD (SEQ ID NO:3) and AMLV RBD (SEQ ID NO:1) and said membrane receptors are ASCT2 and PiT2 respectively.

In an advantageous embodiment, the present invention relates to the use of said combination of RD114 RBD (SEQ ID NO:3) and AMLV RBD (SEQ ID NO:1) as defined above, wherein the expression of one or both said membrane receptors in lung neutrophils is increased or decreased compared with the expression of said membrane receptors in blood neutrophils.

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein said combination is the combination of PERVA RBD (SEQ ID NO: 21) and BLV RBD (SEQ ID NO: 30) and said membrane receptors are PAR and a membrane receptor interacting with BLV respectively, said membrane receptors being potentially expressed in particular in lung neutrophils and blood neutrophils.

PERVA RBD can interact with PAR1 (hRFT3) and PAR2 (hRFT1).

In an advantageous embodiment, the present invention relates to the use of at least one soluble receptor-binding domain (RBD) as defined above, wherein the expression of said PAR membrane receptor in lung neutrophils is decreased compared with the expression of said membrane receptor in blood neutrophils and said receptor interacting with BLV in lung neutrophils is increased compared with the expression of said membrane receptor in blood neutrophils.

In another aspect, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, comprising the identification and quantification of the expression of at least one membrane receptors, said identification and quantification being as defined as defined above, present on the surface of target granulocytes.

In an advantageous embodiment the present invention relates to a process of in vitro diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein the target granulocytes have been previously isolated from a mammal

In an advantageous embodiment the present invention relates to a process of ex vivo diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above.

In an advantageous embodiment the present invention relates to a process of in vivo diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above. In this embodiment, the RBD is injected to a mammal and interact with the target granulocytes in the mammal organism, the identification and quantification of the expression of at least one membrane receptors being carried out on the surface of target granulocytes of said mammal

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, comprising the identification and quantification of the expression of at least one membrane receptors, said identification and quantification being as defined above, present on the surface of target granulocytes, provided that when only one RBD is used, said membrane receptor is not GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor.

In an advantageous embodiment the present invention relates to a process of in vitro diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein when only one RBD is used, said membrane receptor is not GLUT1, i.e. said membrane receptor is a membrane receptor other than GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor, i.e. at least one soluble receptor-binding domain interacts with a membrane receptor other than GLUT 1.

In an advantageous embodiment the present invention relates to a process of ex vivo diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein when only one RBD is used, said membrane receptor is not GLUT1, i.e. said membrane receptor is a membrane receptor other than GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor, i.e. at least one soluble receptor-binding domain interacts with a membrane receptor other than GLUT 1.

In an advantageous embodiment the present invention relates to a process of in vivo diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein when only one RBD is used, said membrane receptor is not GLUT1, i.e. said membrane receptor is a membrane receptor other than GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor, i.e. at least one soluble receptor-binding domain interacts with a membrane receptor other than GLUT 1.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, comprising the following steps:

• • a. contacting at least one soluble receptor-binding domain, as defined above, optionally marked with a tag, with target granulocytes of a diseased mammal to form at last one complex, said at least one complex being constituted by said at least one soluble receptor-binding domain and at least one membrane receptor of said target granulocytes,
  • b. identifying said at least complex formed,
  • c. quantifying the expression of each membrane receptor of said target granulocytes able to form said complex,
  • d. contacting said at least one soluble receptor-binding domain of step a. with target granulocytes of a control mammal and identifying each complex formed as in step b. and quantifying the expression of each membrane receptor of said target granulocytes able to form said complex as in step c.
  • e. comparing the level of expression of membrane receptors in step c and d., an overexpression or underexpression of membrane receptors of target granulocytes of said diseased mammal compared with control mammal indicating an inflammatory state

In this embodiment, granulocytes of a healthy mammal that has no inflammatory state is the control of the process.

Tag used are as defined above and identification of the complexes formed are carried out as described above.

The contact of at least one soluble receptor-binding domain, as defined above, optionally marked with a tag, with target granulocytes of a diseased mammal or of a control mammal is comprised from about 15 min to about 45 min and in particular 30 min at a temperature as defined above.

In this embodiment, the overexpression or the underexpression of one membrane receptor of a diseased mammal compared with the expression of said membrane receptor in a control mammal is a specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein two RBD are used as specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein three RBD are used as specific biomarker of inflammation as specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein four RBD are used as specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein five RBD are used as specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein six RBD are used as specific biomarker of inflammation.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal, defined above, comprises a step a. wherein seven to twenty RBD are used as specific biomarker of inflammation.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, wherein said control mammal is the same mammal species as the diseased mammal

In this embodiment, granulocytes of said diseased mammal that has an inflammatory state is also the control of the process.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, wherein said granulocytes are neutrophils, in particular blood neutrophils and lung neutrophils.

Thus in this embodiment, blood PMNs (quiescents) that have been sampled from each patients, at the same time, are the control of lung PMN (activated).

Nevertheless, patient group having a level of inflammation significantly different from patient groups with higher level of inflammation can also be considered as controls group (see Example 2).

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein the inflammatory state is cystic fibrosis.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, comprising the following steps:

• • a. contacting HTLV-2 RBD (SEQ ID NO: 28) and/or KoRV RBD (SEQ ID NO: 20), optionally marked with a tag, with lung neutrophils of a mammal to form at least one complex,
  • b. identifying said at least one complex formed and being constituted by HTLV-2 receptor-binding domain and GLUT1 membrane receptor and/or KoRV receptor-binding domain and PiT1 membrane receptor of said lung neutrophils,
  • c. quantifying the expression of said GLUT1 and/or PiT1 membrane receptor of said lung neutrophils able to form said complex,
  • d. contacting said HTLV-2 RBD and/or KoRV RBD with blood neutrophils and identifying and quantifying the expression of said GLUT1 and/or PiT1 membrane receptor of said blood neutrophils able to form said complex,
  • e. comparing the level of expression of each membrane receptor, an overexpression of GLUT1 and/or PiT1 in lung neutrophils compared with blood neutrophils indicating a pulmonary inflammatory state during cystic fibrosis.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, comprising the following steps:

• • a. contacting RD114 RBD (SEQ ID NO:3) and AMLV RBD (SEQ ID NO:1), optionally marked with a tag, with lung neutrophils of a mammal to form at least one complex,
  • b. identifying said at least one complex formed and being constituted by RD114 receptor-binding domain and ASCT2 membrane receptor and/or AMLV receptor-binding domain and PiT2 membrane receptor of said lung neutrophils,
  • c. quantifying the expression of said ASCT2 and/or PiT2 membrane receptor of said lung neutrophils able to form said complex,
  • d. contacting said RD114 RBD and/or AMLV RBD with blood neutrophils and identifying and quantifying the expression of said ASCT2 and/or PiT2 membrane receptor of said blood neutrophils able to form said complex,
  • e. comparing the level of expression of each membrane receptor, an overexpression and/or underexpression of ASCT2 and/or PiT2 in blood neutrophils compared with lung neutrophils indicating a pulmonary inflammatory state during cystic fibrosis.

The level of expression of both receptors (ASCT2 and PiT2) is a biomarker of a severe pulmonary inflammatory state during cystic fibrosis.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, comprising the following steps:

• • a. contacting PERVA RBD (SEQ ID NO: 21) and and/or BLV RBD (SEQ ID NO: 30) optionally marked with a tag, with lung neutrophils of a mammal to form at least one complex,
  • b. identifying said at least one complex formed and being constituted by PERVA receptor-binding domain and PAR membrane receptor of said lung neutrophils, and/or BLV receptor-binding domain and a membrane receptor interacting with BLV,
  • c. quantifying the expression of said PAR and/or a membrane receptor interacting with BLV of said lung neutrophils able to form said complex,
  • d. contacting said PERVA RBD and/or BLV RBD with blood neutrophils and identifying and quantifying the expression of each said PAR and/or a membrane receptor interacting with BLV of said blood neutrophils able to form said complex,
  • e. comparing the level of expression of each membrane receptor, an overexpression of said membrane receptor interacting with BLV in blood neutrophils compared with lung neutrophils and/or an underexpression of PAR in blood neutrophils compared with lung neutrophils indicating a pulmonary inflammatory state during cystic fibrosis.

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal defined above comprised a step a. wherein three RBD, are used as specific biomarkers of CF.

Table I specifies all the combinations of three RBD that can be used:

	TABLE I
	HTLV-2	KoRV	RD114	AMLV	PERVA	BLV
Combinations	X	X	X
of three RBD	X	X		X
	X	X			X
	X	X				X
	X		X	X
	X		X		X
	X		X			X
	X			X	X
	X			X		X
	X				X	X
		X	X	X
		X	X		X
		X	X			X
		X		X	X
		X		X		X
		X			X	X
			X	X	X
			X	X		X
			X		X	X
				X	X	X

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal defined above comprised a step a. wherein four RBD are used as specific biomarker of CF.

Table II specifies all the combinations of four RBD that can be used:

	TABLE II
	HTLV-2	KoRV	RD114	AMLV	PERVA	BLV
Combinations	X	X	X	X
of four RBD	X	X	X		X
	X	X	X			X
	X	X		X	X
	X	X		X		X
	X	X			X	X
	X		X	X	X
	X		X	X		X
	X		X		X	X
		X	X	X	X
		X	X	X		X
		X	X		X	X
			X	X	X	X
		X		X	X	X
	X			X	X	X

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal defined above comprised a step a. wherein five RBD are used as specific biomarker of CF.

Table III specifies all the combinations of five receptor RBD that can be used:

	TABLE III
	HTLV-2	KoRV	RD114	AMLV	PERVA	BLV
Combinations	X	X	X	X	X
of five RBD	X	X	X	X		X
	X		X	X	X	X
	X	X		X	X	X
	X	X	X		X	X
		X	X	X	X	X

In an advantageous embodiment, the process of diagnosis and/or prognosis of an inflammatory state in a mammal defined above comprised a step a. wherein six RBD such as HTLV-2/KoRV/RD114/AMLV/BLV/PERVA are used as specific biomarker of CF.

The processes according to the invention defined above show that overexpression and/or underexpression membrane receptors of target granulocytes expressed in lung neutrophils compared with blood neutrophils, and identified and quantified by of one, two, three four, five or six RBD or more(up to twenty) are specific biomarkers of an inflammatory state during cystic fibrosis.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein said granulocytes are eosinophils.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein said granulocytes are basophils.

In an advantageous embodiment, the present invention relates to a process of diagnosis and/or prognosis of an inflammatory state in a mammal, as defined above, wherein said granulocytes are mast cells.

In another aspect, the present invention relates to a method for measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, comprising the following steps:

• • a. identifying and quantifying the expression of at least one membrane receptor, said identification and quantification being as defined as defined in claim 1, present on the surface of target granulocytes,
  • b. contacting said granulocytes with a drug liable to treat said inflammatory state to give treated granulocytes,
  • c. identifying and quantifying the expression of at least one membrane receptor as defined in claim 1, present on the surface of treated granulocytes,
  • d. comparing the level of expression of said at least one membrane receptor before and after contacting with said drug, an increase and/or a decrease of the expression of said at least one membrane receptor after contacting indicating a therapeutic efficacy of said drug depending of said inflammatory state.

In an advantageous embodiment the present invention relates to a method for in vitro measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, comprising the step a. to d. defined above, wherein the target granulocytes have been previously isolated from a mammal

In an advantageous embodiment the present invention relates to a method for ex vivo measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, comprising the step a. to d. defined above.

In an advantageous embodiment the present invention relates to a method for in vivo measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, comprising the step a. to d. defined above, wherein the RBD is injected to a mammal and interact with the target granulocytes in the mammal organism, and the drug liable to treat said inflammatory state is injected to a mammal, the identification and quantification of the expression of at least one membrane receptors being carried out on the surface of target granulocytes of said mammal

In an advantageous embodiment the present invention relates to methods for measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, as defined above, wherein step a. is carried out provided that when only one RBD is used, said membrane receptor is not GLUT1, i.e. said membrane receptor is a membrane receptor other than GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor, i.e. at least one soluble receptor-binding domain interacts with a membrane receptor other than GLUT 1.

In an advantageous embodiment, anti-inflammatory drug identified above, can be used for the preparation of a drug intended for the treatment of inflammatory states, such as cystic fibrosis, allergy or asthma.

DESCRIPTION OF THE FIGURES

FIG. 1 presents the construction strategy of receptor-binding domain (RBD or RBD-derived probes) from y and 8 viral Receptor-Binding Domain (RBD) of envelope glycoprotein (Env).

FIG. 2 presents the sample processing in CF. Both blood and sputum are collected from children and adults, centrifuged at 400 g to pellet cells, which are fixed and then frozen at −80° C. until analyze.

FIGS. 3A to 3D present the gating strategy for population discrimination.

Typically, single live neutrophils are gated via two analytical gates, as depicted on the upper left panel (FIGS. 3A and 3B).

Then subpopulations of blood leucocytes (Eo: eosinophils, Ly: Lymphocytes, M: monocytes and N: neutrophils) are discriminated and airways neutrophils (N) are selected with CTB staining, down left panel (PMN are CTB^hi/SSC-A^hi) (FIGS. 3C and 3D).

FSC-A: Forward light scatter-area

SSC-A: Side light scatter-area

FSC-H: Forward light scatter-Height

CTB: Cholera Toxin B

DRAQ5™: marker of cell viability.

FIGS. 4A and 4B presents the RBD binding and transporter expression.

FIG. 4A present the expression of GLUT1 in Blood neutrophils (upper half, upper unfilled curve corresponding to the mock and black filled curve correspond to the binding of GLUT1) and in Sputum neutrophils (lower half, upper unfilled curve corresponding to the mock and black filled curve corresponding to the binding of GLUT1).

FIG. 4B present the expression of PiT1 in Blood neutrophils (upper half, upper unfilled curve corresponding to the mock and black filled curve correspond to the binding of PiT1) and in Sputum neutrophils (lower half, upper unfilled curve corresponding to the mock and black filled curve corresponding to the binding of PiT1).

Measures (Geomean of fluorescence) of Glut1, PiT1 on gated CF PMN. Statistical analyses are performed with the Wilcoxon test. Histograms on left are representative of 16 patients for Glut1 and PiT1 expression.

EXAMPLES

Example 1

HTLV-2 and KoRV RBDs as Markers of CF in Blood and Lung Neutrophils

To use soluble RBD, a protocol requiring few experimental steps until flow cytometry measures was elaborated.

In brief, HTLV-2 RBD/KoRV RBD were mixed together to obtained a combination of probes. Cells (˜250.10³, blood and sputum neutrophils, see FIG. 2) are incubated with this combination holding tagged-RBD either with EGFP, mouse-IgG Fc or rabbit-IgG Fc. The latters required a secondary stain with a specific antibody to the particular Fc to be detected (Anti-mouse Fc Alexa Fluor® 405 conjugate and/or Anti-rabbit Fc Alexa Fluor® 488 conjugate; both from MOLECULAR PROBES® by Invitrogen™).

In the same time a conjugate of Cholera Toxin B (CTB, Alexa Fluor® 555 conjugate; MOLECULAR PROBES® by Invitrogen™) was added that allowed to differentiate leucocyte subpopulations in blood and define neutrophil population in sputum during analyze.

Then, cells were permeabilized with saponin (or Perm/Wash Buffer I; BD™ Phosflow; BD Biosciences) and a marker of cell viability (DRAQ5; AXXORA® PLATFORM; Biostatus Limited) was introduced. Assays were running on LSRII cytometer 4-laser LSRII digital FACS (BD™ flow cytometer; BD Biosciences)

Results are presented on table IV:

	TABLE IV
	Blood	Sputum
	Glu†1	2634.5	4392
		[2150.5; 3096]	[3672.5; 5207.5]
	Pi†1	594	2483
		[328.25; 881.7]	[2138.25; 3378.5]

Data show deltaGeomean of fluorescence by Median and Interquartile range [25%; 75%].

Table IV is representative of 16 patients for Glutl and PiT1 expression.

It must be noted that:

HTLV-2 RBD or KoRV RBD used in example 1 could have been used alone as specific biomarkers of PMN activation in CF, and

a combination of two RBD: HTLV-2/AMLV or HTLV-2/RD114 or KoRV/AMLV or KoRV/RD 114 would have lead to similar diagnosis prognosis, and

Example 2

RD114 and AMLV RBDs as Markers of CF in Blood and Lung Neutrophils

To use soluble RBD, a protocol requiring few experimental steps until flow cytometry measures was elaborated.

In brief, RD114 RBD/AMLV RBD were mixed together to obtained a combination of probes. Cells (˜250.10³, blood and sputum neutrophils, see FIG. 2) are incubated with this combination holding tagged-RBD either with EGFP, mouse-IgG Fc or rabbit-IgG Fc. The latters required a secondary stain with a specific antibody to the particular Fc to be detected.

In the same time a conjugate of Cholera Toxin B (CTB) was added that allowed to differentiate leucocyte subpopulations in blood and define neutrophil population in sputum during analyze.

Then, cells were permeabilized with saponin and a marker of cell viability (DRAQ5) was introduced. Assays were running on LSRII cytometer.

Results are presented on table V: Characterization of CF inflammation by airway PMN count, ASCT2 and PiT2 expression.

Patients (N=16) are divided in 3 groups considering airway PMN quantity (PMN/mL). ASCT2 and Pit2 level expression data are classified according to the comparison between blood (B) and sputum (S). Values represent deltaGeomean of fluorescence by Median and Interquartile range [25%; 75%].

TABLE V
Airway PMN	ASCT2	PiT2 (×103)
Count (n/mL)	B < S	B ≧ S	B < S	B ≧ S
<3.106	B = 556 [52; 1138]	—	B = 22 [16.4; 23.9]	B = 35.5
(180.103-2.25.106)	S = 1652		S = 37 [20.6; 42.1]	S = 32.7
	[1327; 2027]		(N = 3)	(N = 1)
	(N = 4)
3.106 ≦ n <12.106	B = 474 [257; 752]	—	B = 20.3 [16; 25.8]	B = 35.5 [27; 37.4]
(3.1.106-6.9.106)	S = 1763		S = 43.5 [23.4; 48.4]	S = 31.1 [12.7; 34]
N = 6	[1122; 2170]		(N = 3)	(N = 3)
	(N = 6)
≧12.106	B = 192	B = 1011	B = 18.8	B = 32.9 [28.7; 36.2]
(12.7.106-49.106)	S = 1747	[605; 1272]	S = 33.7	S = 17.2 [14.2; 23.4]
N = 6	(N = 1)	S = 580[518; 900]	(N = 1)	(N = 5)
		(N = 5)

This analyze showed that a combined overexpression of ASCT2 and PiT2 in blood when compared to sputum (B≧S) correlates with the most elevated airway PMN counts (superior or equal to 12.10⁶ cells), corresponding to a high level of inflammation.

Moreover, it could be concluded that a combined expression of ASCT2 and PiT2 in blood PMN comprised within a deltaGeomean range of [605; 1272] and [28.7; 36.2] (×10³), respectively, is predictive of the highest inflammation level (N=5).

It must be noted that in this example, use of AMLV RBD alone is not enough to allow a diagnosis of inflammation contrary to RD114 RBD alone with which the difference between (B<S) and (B≧S) is higher.

It must also be noted that RBD of examples 1 and 2 can be combined.

As an example, a combination of three RBD described in example 1 and 2: HTLV-2/KoRV/RD114 or HTLV-2/KoRV/AMLV or HTLV-2/RD 114/AMLV or KoRV/RD114/AMLV, or

a combination of four RBD: HTLV-2/KoRV/RD114/AMLV

would have lead to more specific biomarkers of PMN activation in CF, in particular a severe pulmonary inflammatory state during cystic fibrosis, and a more precise diagnosis and/or prognosis of inflammation.

Example 3

PERVA and BLV RBDs as markers of CF in blood and lung neutrophils

To use soluble RBD, a protocol requiring few experimental steps until flow cytometry measures was elaborated.

In brief, PERVA RBD/BLV RBD were mixed together to obtained a combination of probes, or used separately. Cells (˜250.10³, blood and sputum neutrophils, see FIG. 2) are incubated with this combination holding tagged-RBD either with EGFP, mouse-IgG Fc or rabbit-IgG Fc. The latters required a secondary stain with a specific antibody to the particular Fc to be detected.

In the same time a conjugate of Cholera Toxin B (CTB) was added that allowed to differentiate leucocyte subpopulations in blood and define neutrophil population in sputum during analyze.

Then, cells were permeabilized with saponin and a marker of cell viability (DRAQ5) was introduced. Assays were running on LSRII cytometer.

Results are presented on table VI: PervA and BLV RBDs binding. DeltaGeomean of fluorescence measures on one patient samples.

PERVA RBD, derived from the porcine endogenous retrovirus A, binds PAR (for PeRV A Receptor) receptors, including the human Riboflavin Transporter 1 (hRFT1 or PAR2) and hRFT3 (or PAR1), was tested in a single patient and allowed to see a down regulation of its cognate receptors on airway neutrophils.

Some of the RBDs are probes for not yet identified transporters.

BLV RBD, derived from Bovine Leukemia Virus has been used to see if it was differentially expressed between blood and airway PMN.

Results obtained from one patient showed a higher binding on CF pulmonary activated neutrophils, evidencing the relevance of BLV RBD as a specific biomarker of PMN activation in CF.

	TABLE VI
	(N = 1)	Blood	Sputum
	PerVA	4161	284
	PAR1
	hRFT1 (PAR2)
	BLV	0	140
	Unknown

Example 3 shows that PAR1 (hRFT3) and PAR2 (hRFT1) on airway PMN in patients is downregulated in the sputum compared to the blood and that the receptor interacting with BLV is overexpressed in blood compared with the blood. In the tested patient, the receptor interacting with BLV has not been detected in blood but it cannot be said that this receptor in not present at all in blood neutrophils.

It must be noted that said receptor interacting with BLV used alone can be relevant as a specific biomarker of PMN activation in CF.

Coupling of the information given by BLV RBD or PERVA RBD and one or more RBD of examples 1 and 2 would have lead to more specific biomarkers of PMN activation in CF and a more precise diagnosis and/or prognosis of inflammation.

Example 4

RBDs as Markers of Asthma and/or Allergy in Blood and Lung Eosinophils

Example 4 show that overexpression and/or underexpression membrane receptors of target granulocytes expressed in lung eosinophils compared with blood eosinophils and identified and quantified by of one, two, three four, five or six RBD are specific biomarkers of allergy and/or asthma.

Example 5

RBDs as Markers of Allergy in Blood and Lung Basophils

Example 5 show that overexpression and/or underexpression membrane receptors of target granulocytes expressed in lung basophils compared with blood basophils and identified and quantified by of one, two, three four, five or six RBD are specific biomarkers of allergy.

Example 6

RBDs as Markers of Allergy in Blood and Lung Mast Cells

Example 6 show that overexpression and/or underexpression membrane receptors of target granulocytes expressed in lung mast cells compared with blood mast cells and identified and quantified by of one, two, three four, five or six RBD are specific biomarkers of allergy.

Claims

1. A method for the identification and quantification of the expression of membrane receptors present on the surface of target granulocytes, comprising contacting at least one soluble receptor-binding domain (RBD) with target granulocytes from a mammal, said identification and quantification taking place at a given time or during a given time interval, and allowing the diagnosis and/or prognosis of inflammatory states in a mammal.

2. The method according to claim 1, wherein the method is for the identification and quantification of the expression of membrane receptors present on the surface of target granulocytes (neutrophils, eosinophils, basophils and mast cells), said identification and quantification taking place at a given time or during a given time interval, and allowing the diagnosis and/or prognosis of inflammatory states, provided that when only one RBD is used, said membrane receptor is not GLUT1.

3. The method according to claim 1, wherein said at least one soluble receptor-binding domain is a set of three to twenty soluble receptor-binding domain, preferably a set of three to twelve soluble receptor-binding domain in particular three, four, five, six seven, eight, nine, ten, eleven, or twelve receptor-binding domain.

4. The method according to claim 1, wherein said at least one soluble receptor-binding domain is a set of three to twenty soluble receptor-binding domain, preferably a set of three to twelve soluble receptor-binding domain in particular three, four, five, six seven, eight, nine, ten, eleven, or twelve receptor-binding domain, provided that at least one soluble receptor-binding domain of said set does not interact with GLUT1 membrane receptor.

5. The method according to claim 1, wherein said target granulocytes are selected from the list consisting of neutrophils, eosinophils, basophils and mast cells.

6. The method according to claim 1, wherein said target granulocytes are neutrophils and said inflammatory state is cystic fibrosis.

7. The method according to claim 1, wherein said neutrophils are blood neutrophils or lung neutrophils.

8. The method according to claim 1, wherein said target granulocytes are eosinophils and said inflammatory state is allergy and/or asthma.

9. The method according to claim 1, wherein said target granulocytes are basophils and said inflammatory state is allergy.

10. The method according to claim 1, wherein said RBD is selected from the list consisting of: SEQ ID NO: 1 to 31.

11. The method according to claim 1 according to claim 10, wherein said RBD is selected from the list consisting of: Amphotropic Murine Leukemia Retrovirus (AMLV, SEQ ID NO:1), Feline endogenous retrovirus (RD114, SEQ ID NO:3), Koala endogeneous Retrovirus (KoRV, SEQ ID NO: 20), Human T Leukaemia Virus-2 (HTLV2, SEQ ID NO:28), Bovine Leukaemia Virus (BLV, SEQ ID NO: 30), or Porcine Endogeneous Retrovirus-A (Pery A, SEQ ID NO:21),

12. The method according to claim 1, wherein said at least one soluble receptor-binding domain is a combination of two soluble receptor-binding domain (RBD).

13. The method according to claim 1 according to claim 12, wherein said combination is the combination of HTLV-2 RBD (SEQ ID NO: 28) and KoRV RBD (SEQ ID NO: 20) and said membrane receptors are GLUT1 and PiT1 respectively, said membrane receptors being expressed in particular in lung neutrophils and blood neutrophils.

14. The method according to claim 1 according to claim 13, wherein the expression of said membrane receptors in lung neutrophils is increased compared with the expression of said membrane receptor in blood neutrophils.

15. The method according to claim 1 according to claim 12, wherein said combination is the combination of PERVA RBD (SEQ ID NO: 21) and BLV RBD (SEQ ID NO: 30) and said membrane receptors are PAR and a membrane receptor interacting with BLV respectively, said membrane receptors being expressed in particular in lung neutrophils and blood neutrophils.

16. The method according to claim 1 according to claim 15, wherein the expression of said PAR membrane receptor in lung neutrophils is decreased compared with the expression of said membrane receptor in blood neutrophils and said receptor interacting with BLV in lung neutrophils is increased compared with the expression of said membrane receptor in blood neutrophils.

17. Process of in vitro diagnosis and/or prognosis of an inflammatory state in a mammal, comprising the identification and quantification of the expression of at least one membrane receptors, said identification and quantification being as defined as defined in claim 1, present on the surface of target granulocytes.

18. Process of in vitro diagnosis and/or prognosis of an inflammatory state in a mammal, comprising the identification and quantification of the expression of at least one membrane receptors, said identification and quantification being as defined as defined in claim 1, present on the surface of target granulocytes, provided that when only one RBD is used, said membrane receptor is not GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor.

19. Process of in vitro diagnosis and/or prognosis of an inflammatory state according to claim 16, comprising the following steps:

a. contacting at least one soluble receptor-binding domain, optionally marked with a tag, with target granulocytes of a diseased mammal to form at last one complex, said at least one complex being constituted by said at least one soluble receptor-binding domain and at least one membrane receptor of said target granulocytes,

b. identifying said at least complex formed,

c. quantifying the expression of each membrane receptor of said target granulocytes able to form said complex,

d. contacting said at least one soluble receptor-binding domain of step a. with target granulocytes of a control mammal and identifying each complex formed as in step b. and quantifying the expression of each membrane receptor of said target granulocytes able to form said complex as in step c.

e. comparing the level of expression of membrane receptors in step c and d., an overexpression or underexpression of membrane receptors of target granulocytes of said diseased mammal compared with control mammal indicating an inflammatory state

20. Process according to claim 19, wherein said control mammal is the same mammal species as the diseased mammal.

21. Process according to claim 20, wherein said granulocytes are neutrophils, in particular blood neutrophils and lung neutrophils.

22. Process according to claim 19, wherein the inflammatory state is cystic fibrosis.

23. Process of in vitro diagnosis and/or prognosis of cystic fibrosis according to claim 21, comprising the following steps:

a. contacting HTLV-2 RBD (SEQ ID NO: 28) and/or KoRV RBD (SEQ ID NO: 20) optionally marked with a tag, with lung neutrophils of a mammal to form at least one complex,

b. identifying said at least one complex formed and being constituted by HTLV-2 receptor-binding domain and GLUT1 membrane receptor and/or KoRV receptor-binding domain and Pill membrane receptor of said lung neutrophils,

c. quantifying the expression of said GLUT1 and/or Pill membrane receptor of said lung neutrophils able to form said complex,

d. contacting said HTLV-2 RBD and/or KoRV RBD with blood neutrophils and identifying and quantifying the expression of said GLUT1 and/or Pill membrane receptor of said blood neutrophils able to form said complex,

e. comparing the level of expression of each membrane receptor, an overexpression of GLUT1 and/or Pill in lung neutrophils compared with blood neutrophils indicating a pulmonary inflammatory state during cystic fibrosis.

24. Process of in vitro diagnosis and/or prognosis of cystic fibrosis according to claim 21, comprising the following steps:

a. contacting PERVA RBD (SEQ ID NO: 21) and and/or BLV RBD (SEQ ID NO: 30) optionally marked with a tag, with lung neutrophils of a mammal to form at least one complex,

b. identifying said at least one complex formed and being constituted by PERVA receptor-binding domain and PAR membrane receptor of said lung neutrophils, and/or BLV receptor-binding domain and a membrane receptor interacting with BLV,

c. quantifying the expression of said PAR and/or a membrane receptor interacting with BLV of said lung neutrophils able to form said complex,

d. contacting said PERVA RBD and/or BLV RBD with blood neutrophils and identifying and quantifying the expression of each said PAR and/or a membrane receptor interacting with BLV of said blood neutrophils able to form said complex,

e. comparing the level of expression of each membrane receptor, an overexpression of said membrane receptor interacting with BLV in blood neutrophils compared with lung neutrophils and/or an underexpression of PAR in blood neutrophils compared with lung neutrophils indicating a pulmonary inflammatory state during cystic fibrosis.

25. Process according to claim 20, wherein said granulocytes are eosinophils.

26. Process according to claim 20, wherein said granulocytes are basophils.

27. Process according to claim 20, wherein said granulocytes are mast cells.

28. Method for in vitro measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, comprising the following steps:

a. identifying and quantifying the expression of at least one membrane receptor, said identification and quantification being as defined as defined in claim 1, present on the surface of target granulocytes,

b. contacting said granulocytes with a drug liable to treat said inflammatory state to give treated granulocytes,

c. identifying and quantifying the expression of at least one membrane receptor, present on the surface of treated granulocytes,

d. comparing the level of expression of said at least one membrane receptor before and after contacting with said drug, an increase and/or a decrease of the expression of said at least one membrane receptor after contacting indicating a therapeutic efficacy of said drug depending of said inflammatory state.

29. Method for in vitro measuring the therapeutic efficacy of a potential anti-inflammatory drug in a mammal, according to claim 28, wherein step a is carried out provided that when only one RBD is used, said membrane receptor is not GLUT1, and when two or more RBD are used, at least one of said soluble receptor-binding domain does not interact with GLUT1 membrane receptor.