AU2002346999A1

AU2002346999A1 - Methods and compositions to evaluate antibody treatment response

Info

Publication number: AU2002346999A1
Application number: AU2002346999A
Authority: AU
Inventors: Guillaume Cartron; Philippe Colombat; Herve Watier
Original assignee: Innate Pharma SA; Centre Hospitalier Regional Universitaire de Tours
Current assignee: Innate Pharma SA; Centre Hospitalier Regional Universitaire de Tours
Priority date: 2001-10-19
Filing date: 2002-10-11
Publication date: 2003-07-03
Anticipated expiration: 2022-10-11

Description

METHODS AND COMPOSITIONS TO EVALUATE ANTIBODY TREATMENT RESPONSE

The present invention relates to methods and compositions to evaluate or assess the response of a subject to particular therapeutic treatment. More particularly, the invention provides methods to determine the response of subjects, or to adapt the treatment protocol of subjects treated with therapeutic antibodies. The invention can be used for patients with malignancies, particularly lymphoma, and is suited to select best responders and/or adjust treatment condition or protocol for low responders.

INTRODUCTION

Various therapeutic strategies in human beings are based on the use of therapeutic antibodies. This includes, for instance, the use of therapeutic antibodies developed to deplete target cells, particularly diseased cells such as virally-infected cells, tumor cells or other pathogenic cells, including allogenic immunocompetent cells. Such antibodies are typically monoclonal antibodies, of IgG species, typically IgGl and IgG3. These antibodies can be recombinant antibodies and humanized antibodies, comprising functional domains from various species or origin or specificity. A particular example of such therapeutic antibodies is rituximab (Mabthera^®, Rituxan^®), which is a chimeric anti-CD20 IgGl monoclonal antibody made with human γl and K constant regions linked to murine variable domains -\ For a few years, rituximab has been considerably modifying the therapeutical strategy against B lymphoproliferative malignancies, particularly non-Hodgkin's lymphomas (NHL). Other examples of intact humanized IgGl antibodies include alemtuzumab (Campath-1H^®), which is used in the treatment of B cell malignancies or trastuzumab (Herceptin , which is used in the treatment of breast cancer. Additional examples of therapeutic antibodies under development are disclosed in the art.

While these antibodies represent a novel efficient approach to human therapy, particularly for treatment of tumors, they do not always exhibit a strong efficacy and their use could be improved by evaluating the response of subjects thereto. For instance, while rituximab, alone or in combination with chemotherapy was shown to be effective in the treatment of both low- intermediate^ _nd high-grade NHL^» 9, 30% to 50% of patients with low grade NHL have no clinical response to rituximab^* -\ It has been suggested that the level of CD20 expression on lymphoma cells^, the presence of high tumor burden at the time of treatment^ or low serum rituximab concentrations^ may explain the lack of efficacy of rituximab in some patients. Nevertheless, the actual causes of treatment failure remain largely unknown.

The availability of methods allowing the evaluation of patient response to antibody treatment would greatly enhance the therapeutic efficacy of these products. However, the precise mode of action in vivo of such therapeutic antibodies is not clearly documented. Indeed, while in vitro studies suggest various possible modes of action of rituximab (antibody-dependant cell- mediated cytotoxicity (ADCC)^* H, complement-dependant cytotoxicity^' ^-> l*, direct signalling leading to apoptosisl4* *^■$, etc.), the clear action of these target cell-depleting antibodies in vivo is not documented in humans. Furthermore, while ADCC is an important effector mechanism in the eradication of intracellular pathogens and tumor cells, the role of an ADCC is still controversial^, 13.

The present invention now proposes novel methods and compositions to assess the therapeutic response of a subject to a therapeutic antibody. The invention also proposes methods to select patients having best responding profile to therapeutic antibody treatment. The invention also relates to methods of treating patients with therapeutic antibodies, comprising a prior step of evaluating the patient's response. The invention also relates to compositions and kits suitable to perform the invention. The invention may as well be used in clinical trials or experimental settings, to assess or monitor a subject's response, or to verify the mode of action of an antibody.

The invention is based, in part, on the demonstration of a correlation between the genotype of a subject and its ability to respond to therapeutic antibody treatment. More specifically, the invention shows that the genotype of the FcγRIIIa receptor directly correlates with the subject's response to therapeutic antibody treatment.

Three classes of FcγR (FcγRI, FcγRlT and FcγRIlT) and their subclasses are encoded by eight genes in humans, all located on the long arm of chromosome 1. Some of these genes display a functional allelic polymorphism generating allotypes with different receptor properties. These polymorphisms have been identified as genetic factors increasing the susceptibility to autoimmune or infectious diseases!^¹. One of these genetic factors is a gene dimorphism in FCGR3A, which encodes FcγRILTa with either a phenylalanine (F) or a valine (V) at amino- acid position 15822* 23 fhis residue directly interacts with the lower hinge region of IgGl as recently shown by IgGl-FcyRLTI co-cristallization24. It has been clearly demonstrated that human IgGl binds more strongly to homozygous FcγRIIIa-158V natural killer cells (NK) than to homozygous FcγRILTa-158F or heterozygous NK cells22> 23

We undertook to evaluate a possible correlation between the FCGR3A genotype and a patient response to therapeutic antibody treatment in vivo. Our invention stems in part from the unexpected discovery that a very strong correlation exists between said genotype and said response profile, the presence of a valine residue at position 158 being indicative of a high response rate. More specifically, the genotyping of FCGR3A was performed in patients with previously untreated follicular NHL who had received rituximab alone, a particular situation in which the response rate is very high-*. The ECGR2 -131H/R was also determined as control since this gene co-localizes with FCGR3A on chromosome lq22 and encodes the macrophage FcγRIIa receptor.

The ECGE3-4-158V/F genotype was determined in 47 patients having received rituximab for a previously untreated follicular non-Hodgkin's lymphoma. Clinical and molecular response were evaluated at two months (M2) and at one year (M12). Positive molecular response was defined as a disappearance of the BCL2-JH gene rearrangement in both peripheral blood and bone marrow. ECGRλ4-158V homozygous patients were 21% whereas ECGR3.4-158F homozygous and heterozygous patients (ECGR-L -158F carriers) were 34% and 45%, respectively. The objective response rates at M2 and M12 were 100% and 90% in FCGR3A- 158V homozygous patients compared with 65% (p = 0.02) and 51% (p-0.03) in FCGR3A- 158F carriers. A positive molecular response was observed at M12 in 5/6 of homozygous ECGR3. -158V patients compared with 5/16 of ECGE3 -158F carriers (p-0.04). Furthermore, the homozygous ECGR34-158V genotype was confirmed to be the single parameters associated with clinical and molecular responses in multivariate analysis and was also associated with a lower rate of disease progression (p = 0.05).

Accordingly, the present invention establishes, for the first time, an association between the FCGR3A genotype and clinical and molecular responses to therapeutic antibodies. The invention thus provides a first unique marker that can be used to monitor, evaluate or select a patient's response. This invention thus introduces new pharmacogenetical approaches in the management of patients with malignancies, viral infections or other diseases related to the presence of pathological cells in a subject, particularly non-Hodgkin's lymphoma.

An object of this invention resides in a method of assessing the response of a subject to a therapeutic antibody treatment, comprising determining in vitro the FCGR3A genotype and/or the presence of a polymorphism in the FcγRIIIa receptor of said subject. More specifically, the method comprises determining in vitro the FCGR3A158 genotype of said subject.

A further object of this invention is a method of selecting patients for therapeutic antibody treatment, the method comprising determining in vitro the FCGR3A genotype and/or the presence of a polymorphism in the FcγRIIIa receptor of said subject. More specifically, the method comprises determining in vitro the FCGR3A158 genotype of said subject.

An other object of this invention is a method of improving the efficacy or treatment condition or protocol of a therapeutic antibody treatment in a subject, comprising determining in vitro the FCGR3A genotype and/or the presence of a polymorphism in the FcγRIIIa receptor of said subject. More specifically, the method comprises determining in vitro ύι FCGR3A158 genotype of said subject.

More specifically, determining in vitro the FCGR3A158 genotype of a subject comprises determining amino acid residue at position 158 of FcyRLTIa receptor (or corresponding codon in the FCGR3A gene), a valine at position 158 being indicative of a better response to said treatment and a phenylalanine at position 158 being indicative of a lower response to said treatment.

Within the context of this invention, the term "therapeutic antibody or antibodies" designates more specifically any antibody that functions to deplete target cells in a patient. Specific examples of such target cells include tumor cells, virus-infected cells, allogenic cells, pathological immunocompetent cells (e.g., B lymphocytes, T lymphocytes, antigen-presenting cells, etc.) involved in allergies, autoimmune diseases, allogenic reactions, etc., or even healthy cells (e.g., endothelial cells in an anti-angiogenic therapeutic strategy). Most preferred target cells within the context of this invention are tumor cells and virus-infected cells. The therapeutic antibodies may, for instance, mediate a cytotoxic effect or a cell lysis, particularly by antibody-dependant cell-mediated cytotoxicity (ADCC). ADCC requires leukocyte receptors for the Fc portion of IgG (FcγR) whose function is to link the IgG-sensitized antigens to FcγR-bearing cytotoxic cells and to trigger the cell activation machinery. While this mechanism of action has not been evidenced in vivo in humans, it may account for the efficacy of such target cell-depleting therapeutic antibodies. The therapeutic antibodies may by polyclonal or, preferably, monoclonal. They may be produced by hybridomas or by recombinant cells engineered to express the desired variable and constant domains. The antibodies may by single chain antibodies or other antibody derivatives retaining the antigen specificity and the lower hinge region or a variant thereof. These may be polyfunctional antibodies, recombinant antibodies, ScFv, humanized antibodies, or variants thereof. Therapeutic antibodies are specific for surface antigens, e.g., membrane antigens. Most preferred therapeutic antibodies are specific for tumor antigens (e.g., molecules specifically expressed by tumor cells), such as CD20, CD52, ErbB2 (or HER2/Neu), CD33, CD22, CD25, MUOl, CEA, KDR, αVβ3, etc., particularly lymphoma antigens (e.g., CD20). The therapeutic antibodies are preferably IgGl or IgG3, more preferably IgGl.

Typical examples of therapeutic antibodies of this invention are rituximab, alemtuzumab and trastuzumab. Such antibodies may be used according to clinical protocols that have been authorized for use in human subjects. Additional specific examples of therapeutic antibodies include, for instance, epratuzumab, basiliximab, daclizumab, cetuximab, labetuzumab, sevirumab, tuvurimab, palivizumab, infliximab, omalizumab, efalizumab, natalizumab, clenoliximab, etc., as listed in the following table:

Within the context of the present invention, a subject or patient includes any mammalian subject or patient, more preferably a human subject or patient.

According to the invention the term FCGR3A gene refers to any nucleic acid molecule encoding a FcyRLTIa polypeptide in a subject. This term includes, in particular, genomic DNA, cDNA, RNA (pre-rRNA, messenger RNA, etc.), etc. or any synthetic nucleic acid comprising all or part of the sequence thereof. Synthetic nucleic acid includes cDNA, prepared from RNAs, and containing at least a portion of a sequence of the FCGR3 A genomic DNA as for example one or more introns or a portion containing one or more mutations. Most preferably, the term FCGR3A gene refers to genomic DNA, cDNA or mRNA, typically genomic DNA or mRNA. The FCGR3A gene is preferably a human FCGRIIIa gene or nucleic acid, i.e., comprises the sequence of a nucleic acid encoding all or part of a FcγRLTIa polypeptide having the sequence of human FcγRILTa polypeptide. Such nucleic acids can be isolated or prepared according to known techniques. For instance, they may be isolated from gene libraries or banks, by hybridization techniques. They can also be genetically or chemically synthesized. The genetic organization of a human FCGRIIIa gene is depicted on Figure 2. The amino acid sequence of human FcγRffla is represented figure 3. Amino acid position 158 is numbered from residue 1 of the mature protein. It corresponds to residue 176 of the pre-protein having a signal peptide. The sequence of a wild type FCGR3A gene is represented on figure 4 (see also Genbank accession Number AL590385 or NM_000569 for partial sequence).

Within the context of this invention, a portion or part means at least 3 nucleotides (e.g., a codon), preferably at least 9 nucleotides, even more preferably at least 15 nucleotides, and can contain as much as 1000 nucleotides. Such a portion can be obtained by any technique well known in the art, e.g., enzymatic and/or chemical cleavage, chemical synthesis or a combination thereof. The sequence of a portion of a FCGR3 A gene encoding amino acid position 158 is represented below, for sake of clarity:

CDNA 540 550 560 570 580 genomic DNA 4970 4980 4990 5000 .

158F allele tcctacttctgcagggggctttttgggagtaaaaatgtgtcttca

S Y F C R G L F G S K N V S S

158V allele tcctacttctgcagggggcttgttgggagtaaaaatgtgtcttca S Y F C R G L V G S K N V S S

As indicated above, the invention comprises a method of determining in vitro the

FCGR3A158 genotype of said subject. This more particularly comprises determining the nature of amino acid residue present (or encoded) at position 158 of the FcγRIIIa polypeptide.

Genotyping the FCGR3A gene or corresponding polypeptide in said subject may be achieved by various techniques, comprising analysing the coding nucleic acid molecules or the encoded polypeptide. Analysis may comprise sequencing, migration, electrophoresis, immuno- techniques, amplifications, specific digestions or hybridisations, etc.

In a particular embodiment, determining amino acid residue at position 158 of Fc RITJa receptor comprises a step of sequencing the FCGR3A receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158. In an other particular embodiment, determining amino acid residue at position 158 of FcγRlIIa receptor comprises a step of amplifying the FCGR3A receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158. Amplification may be performed by pol merase chain reaction (PCR), such as simple PCR, RT-PCR or nested PCR, for instance, using conventional methods and primers.

In this regard, amplification primers for use in this invention more preferably contain less than about 50 nucleotides even more preferably less than 30 nucleotides, typically less than about 25 or 20 nucleotides. Also, preferred primers usually contain at least 5, preferably at least 8 nucleotides, to ensure specificity. The sequence of the primer can be prepared based on the sequence of the FCGR3A gene, to allow full complementarity therewith, preferably. The probe may be labelled using any known techniques such as radioactivity, fluorescence, enzymatic, chemical, etc. This labeling can use for example Phosphor 32, biotin (16-dUTP), digoxygenin (11-dUTP). It should be understood that the present invention shall not be bound or limited by particular detection or labelling techniques. The primers may further comprise restriction sites to introduce allele-specific restriction sites in the amplified nucleic acids, as disclosed below.

Specific examples of such amplification primers are, for instance, SEQ ID NO: 1-4.

It should be understood that other primers can be designed by the skilled artisan, such as any fragment of the FCGR3A gene, for use in the amplification step and especially a pair of primers comprising a forward sequence and a reverse sequence wherein said primers of said pair hybridize with a region of a FCGR3A gene and allow amplification of at least a portion of the FCGR3A gene containing codon 158. In a preferred embodiment, each pair of primers comprises at least one primer that is complementary, and overlaps with codon 158, and allows to discriminate between 158V (gtt) and 158F (ttt). The amplification conditions may also be adjusted by the skilled person, based on common general knowledge and the guidance contained in the specification. In a particular embodiment, the method of the present invention thus comprises a PCR amplification of a portion of the FCGR3a mRNA or gDNA with specific oligonucleotide primers, in the cell or in the biological sample, said portion comprising codon 158, and a direct or indirect analysis of PCR products, e.g., by electrophoresis, particularly Denaturing Gel Gradient Electrophoresis (DGGE).

In an other particular embodiment, determining amino acid residue at position 158 of FcγRLTIa receptor comprises a step of allele-specific restriction enzyme digestion. This can be done by using restriction enzymes that cleave the coding sequence of a particular allele (e.g., the 158V allele) and that do not cleave the other allele (e.g., the 158F allele, or vice versa). Where such allele-specific restriction enzyme sites are not present naturally in the sequence, they may be introduced therein artificially, by amplifying the nucleic acid with allele-specific amplification primers containing such a site in their sequence. Upon amplification, determining the presence of an allele may be carried out by analyzing the digestion products, for instance by electrophoresis. This technique also allows to discriminate subjects that are homozygous or heterozygous for the selected allele.

Examples of allele-specific amplification primers include for instance SEQ ID NO: 3. SEQ LO NO: 3 introduces the first 3 nucleotides of the Nlalll site (S'-CATG^ . Cleavage occurs after G. This primer comprises 11 bases that do not hybridise with FCGR3A, that extend the primer in order to facilitate electrophoretic analysis of the amplification products) and 21 bases that hybridise to FCGR3A, except for nucleotide 31 (A) which creates the restriction site.

In a further particular embodiment, determining amino acid residue at position 158 of FcγRLTIa receptor comprises a step of hybridization of the FCGR3A receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158, with a nucleic acid probe specific for the genotype Valine or Phenylalanine, and determining the presence or absence of hybrids. It should be understood that the above methods can be used either alone or in various combinations. Furthermore, other techniques known to the skilled person may be used as well to determine the FCGR3A158 genotype, such as any method employing amplification (e.g. PCR), specific primers, specific probes, migration, etc., typically quantitative RT-PCR, LCR (Ligase Chain Reaction), TMA (Transcription Mediated Amplification), PCE (an enzyme amplified immunoassay) and bDNA (branched DNA signal amplification) assays.

In a preferred embodiment of this invention, determining amino acid residue at position 158 of FcγRπia receptor comprises: - Obtaining genomic DNA from a biological sample,

- Amplifying the FcyRHIa receptor gene or a portion thereof comprising the nucleotides encoding amino acid residue 158, and

- determining amino acid residue at position 158 of said FcγRIIIa receptor gene.

Amplification can be accomplished with any specific technique such as PCR, including nested PCR, using specific primers as described above. In a most preferred embodiment, determining amino acid residue at position 158 is performed by allele-specific restriction enzyme digestion. In that case, the method comprises:

- Obtaining genomic DNA from a biological sample, - Amplifying the FcγRILTa receptor gene or a portion thereof comprising the nucleotides encoding amino acid residue 158,

- Introducing an allele-specific restriction site,

Digesting the nucleic acids with the enzyme specific for said restriction site and, - Analysing the digestion products, i.e., by electrophoresis, the presence of digestion products being indicative of the presence of the allele.

In an other particular embodiment, the genotype is determined by a method comprising : total (or messenger) RNA extraction from cell or biological sample or biological fluid in vitro or ex vivo, optionally cDNA synthesis, (PCR) amplification with ECGR-M-specific oligonucleotide primers, and analysis of PCR products.

The method of this invention may also comprise determining amino acid residue at position 158 of FcγRLUa receptor directly by sequencing the FcγRILTa receptor polypeptide or a portion thereof comprising amino acid residue 158 or by using reagents specific for each allele of the FcγRHIa polypeptide. This can be determined by any suitable technique known to the skilled artisan, including by immuno-assay (ΕLISA, ΕIA, RIA, etc.). This can be made using any affinity reagent specific for a FcγRIIIal58 polypeptide, more preferably any antibody or fragment or derivative thereof. In a particular embodiment, the FcγRIIIal58 polypeptide is detected with an anti- FcγRHIal58 antibody (or a fragment thereof) that discriminates between FcγRIIIal58V and FcγRIIIal58F, more preferably a monoclonal antibody. The antibody (or affinity reagent) may be labelled by any suitable method (radioactivity, fluorescence, enzymatic, chemical, etc.). Alternatively, FcγRIϋal58 antibody immune complexes may be revealed (and/or quantified) using a second reagent (e.g., antibody), labelled, that binds to the anti- FcγRπial58 antibody, for instance.

The above methods are based on the genotyping of FCGR3A158 in a biological sample of the subject. The biological sample may be any sample containing a FCGR3A gene or corresponding polypeptide, particularly blood, bone marrow, lymph node or a fluid, particularly blood or urine, that contains a FCGR3A158 gene or polypeptide. Furthermore, because the FCGR3 A 158 gene is generally present within the cells, tissues or fluids mentioned above, the method of this invention usually uses a sample treated to render the gene or polypeptide available for detection or analysis. Treatment may comprise any conventional fixation techniques, cell lysis (mechanical or chemical or physical), or any other conventional method used in immunohistology or biology, for instance.

The method is particularly suited to determine the response of a subject to an anti-tumor therapeutic antibody treatment. In this regard, in a particular embodiment, the subject has a tumor and the therapeutic antibody treatment aims at reducing the tumor burden, particularly at depleting the tumor cells. More preferably, the tumor is a lymphoma, such as more preferably a B lymphoma, particularly a NHL. As indicated above, the antibody is preferably an IgGl or an IgG3, particularly an anti-CD20 IgGl or IgG3, further preferably a humanized antibody, for instance rituximab.

The invention also relates to a bispecific antibody, wherein said bispecif ic antibody specifically binds CD16 and a tumor antigen, for instance a CD20 antigen. The invention also encompasses pharmaceutical compositions comprising such a bispecific antibody and a pharmaceutically acceptable excipient or adjuvant.

Further aspects and advantages of this invention will be disclosed in the following examples, which should be regarded as illustrative and not limiting the scope of this application.

FIGURE LEGENDS

FIGURE 1: Adjusted KAPLAN-MEIER estimates of progression-free survival after rituximab treatment according to FcγR3a-158V/Ε^! genotype (p=0.05). FIGURE 2: Genetic organization of the human FCGR3A gene FIGURE 3: Amino acid sequences of human Ec/RrUal58F (SΕQ ID NO:7) FIGURE 4: Nucleic acid sequence of human FCGR3A158F (SEQ ID NO:8)

MATERIALS AND METHODS

Patients and treatment Clinical trial design, eligibility criteria and end-point assessment have been previously reported.-' In brief, patients were eligible for inclusion in this study if they had previously untreated follicular CD20 positive NHL according to the REAL classif ication .2° Patients were required to present with stage II to TV disease according to Ann-Arbor classification and at least one measurable disease site. All patients were required to have low tumor burden according to the GELF criteria.27 A total of four 375 mg/m² doses of rituximab (Roche, Neuilly, France) were administered by intravenous infusion (days 1, 8, 15, 22). The management of infusion and adverse events has already been reported.-' The study protocol was approved by an ethics committee, and all patients gave their informed consent.

Monitoring and endpoints

Baseline evaluation included clinical examination, chest X-ray, computed tomography (CT) of the chest, abdomen and pelvis, and unilateral bone marrow biopsy. Response was assessed by an independent panel of radiologists who reviewed all the CT scans of the included patients. The primary efficacy endpoint was the objective response rate, i.e the proportion of patients achieving either complete remission (CR), unconfirmed CR (CRu) or partial response (PR) according to the criteria recently proposed by an international expert committee.2° Clinical response was evaluated at days 50 and 78. Only the maximum response was taken into account and that assessment time point named M2. All patients were evaluated for progression at one year (M12). Patients in CR or CRu with disappearance of bone marrow infiltration at M2 and reappearance of lymphoma cells in bone marrow at M12 were considered " progressive "; patients in PR with negative bone marrow biopsy at M2 and positive biopsy at M12 were considered in PR. Molecular analysis of BCL2-JH gene rearrangement was performed by PCR, as previously described,*' on a lymph node obtained at diagnosis and on both peripheral blood and bone marrow at diagnosis, M2 and M12.

ECGR3Λ-158V/F genotyping

Out of the 50 patients included in the clinical trial, one patient was excluded after histological review and DΝA was not available for two other patients. Forty seven patients were therefore available for FCGR3A genotype analysis. All samples were analysed in the same laboratory and DΝA was extracted using standard procedures including precautions to avoid cross- contamination. DΝA was isolated from peripheral blood (n = 43), bone marrow (n = 3) or lymph node (n = l). Genotyping of ECGR3τl-158V/F polymorphism was performed as described by Koene et al with a nested PCR followed by an allele-specific restriction enzyme digestion. Briefly, two FCGR3A specific primers (5'-ATATTTACAGAATGGCACAGG-3', SEQ LO NO: 1 ; 5'-GACTTGGTACCCAGGTTGAA-3', SEQ ID NO: 2) (Eurobio, Les Ulis, France) were used to amplify a 1.2 kb fragment containing the polymorphic site. The PCR assay was performed with 1.25 μg of genomic DNA, 200 ng of each primer, 200 μmol/L of each dNTP (MBI Fermentas, Vilnius, Lithuania) and 1 U of Taq DNA polymerase (Promega, Charbonniere, France) as recommended by the manufacturer. This first PCR consisted in 10 min at 95°C, then 35 cycles (each consisting in 3 steps at 95°C for 1 min, 57°C for 1.5 min, 72°C for 1.5 min) and 8 min at 72°C to achieve complete extension. The second PCR used primers (5'-ATCAGATTCGATCCTACTTCTGCAGGGGGCAT-3' SEQ LO NO: 3; 5'- ACGTGCTGAGCTTGAGTGATGGTGATGTTCAC-3' SEQ ID NO: 4) (Eurobio) amplifying a 94 bp fragment and creating a NlaWl restriction site only in the ECGR3 -158V allele. This nested PCR was performed with 1 μL of the amplified DNA, 150 ng of each primer, 200 μmol/L of each dNTP and 1 U of Taq DNA polymerase. The first cycle consisted in 5 min at 95°C then 35 cycles (each consisting in 3 steps at 95°C for 1 min, 64°C for 1 min, 72°C for 1 min) and 9.5 min at 72°C to complete extension. The amplified DNA (10 μL)was then digested with 10 U of NlaHl (New England Biolabs, Hitchin, England) for 12 h at 37°C and separated by electrophoresis on a 8% polyacrylamide gel. After staining with ethidium bromide, DNA bands were visualized with UV light. For homozygous ECGR3. -158F patients, only one undigested band (94 bp) was visible. Three bands (94 bp, 61 bp and 33 bp) were seen in heterozygous individuals whereas for homozygous ECGR3./4-158V patients, only two digested bands (61 bp and 33 bp) were obtained.

FCGR2AΛ31H/K genotyping

Genotyping of ECGR2 -131H/R was done by PCR followed by an allele-specific restriction enzyme digestion according to Liang et afi°. The sense primer (5'- GGAAAATCCCAGAAATTCTCGC-3' SΕQ ID NO: 5) (Eurobio) has been modified to create a BsiUl restriction site in case of R allele whereas the antisense primer (5'- CAACAGCCTGACTACCTATTACGCGGG-3' SEQ ID NO: 6) (Eurobio) has been modified to carry a second E5tUI restriction site that served as an internal control. PCR amplification was performed in a 50 μL reaction with 1.25 μg genomic DNA, 170 ng of each primer, 200 μmol/L of each dNTP, 0.5 U of Taq DNA polymerase, and the manufacturer's buffer. The first cycle consisted of 3 minutes at 94°C followed by 35 cycles (each consisting in 3 steps at 94°C for 15 seconds, 55°C for 30 seconds, 72°C for 40 seconds) and 7 min at 72°C to complete extension. The amplified DNA (7 μL) were then digested with 20 U of E5tUI (New England Biolabs) for 12 h at 60° C. Further analysis was performed as described for FCGR3A genotyping. The ECGR2 -131H and -131R alleles were visualized as a 337 bp and 316 bp DNA fragments, respectively.

Statistical analysis

Clinical and biological characteristics as well as clinical and molecular responses of the patients in the different genotypic groups were compared using a Chi-squared test or by Fisher's exact test when appropriated. A logistic regression analysis including: sex, age (> or < 60 years), number of extra-nodal sites involved (> or < 2), bone marrow involvement, BCL2-JH rearrangement status at diagnosis and FCGR3A genotype was used to identify independent prognostic variables influencing clinical and molecular responses. Progression-free survival was calculated according to the method of Kaplan and Meier 9 _an was measured from the start of treatment until progression/relapse or death. Comparison of the progression-free survival by FCGR3A genotype was performed using the log-rank test. P < 0.05 was considered as statistically significant.

RESULTS

Clinical response

Out of the 49 patients tested for the ECGR3Λ-158V/F polymorphism, 10 (20%) and 17 (35%) were homozygous for ECGE3Λ-158V and ECGE3. -158F, respectively, and 22 (45%) were heterozygous. The three groups were not different in terms of sex, disease stage, bone marrow involvement, number of extra-nodal sites involved or presence of BCL2-fH rearrangement in peripheral blood and bone marrow at diagnosis (Table 1). No difference was found when homozygous ECGE3 1-158V patients were compared with ECGR3 -158F carriers (FCGR3A- 158F homozygous and heterozygous patients) or when homozygous ECGR34-158F patients were compared with ECGE3 -158V carriers (ECGR3/1-158V homozygous and heterozygous patients). The objective response rate at M2 was 100% (CR+CRu=40%), 70% (CR + CRu = 29%) and 64% (CR + CRu = 18%) in ECGR3Λ-158V homozygous, ECGE3 1-158F homozygous and heterozygous patients respectively (E=0.09). A significant difference in objective response rate was observed between ECGE3 l-158V homozygous patients and ECGE3 -158F carriers with 67% (CR+CRu = 23%) objective response rate for this latter group (relative risk= 1.5; 95% CI, 1.2-1.9; E=0.03) (Table 2). No difference was observed between ECGE3 1-158F homozygous patients and ECGR3 -158V carriers. At M12, the objective response rate was 90% (CR+CRu=70%), 59% (CR+CRu=35%) and 45% (CR+CRu = 32%) in ECGR3 -158V homozygous, ECGE3 -158F homozygous and heterozygous patients respectively (P= 0.06) . The difference in objective response rate was still present one year after treatment between ECGE3 -158V homozygous group and FCGR3A- 158F carriers with 51% (CR + CRu = 33%) objective response rate for this latter group (relative risk= 1.7; 95% CI, 1.2-2.5; E=0.03). The logistic regression analysis showed that the homozygous ECGE3 -158V genotype was the only predictive factor for clinical response both at M2 (E=0.02) and at M12 (E=0.01). The progression-free survival at 3 years (median follow-up: 35 months; 31-41) (Figure 1) was 56% in ECGE34-158V homozygous patients and 35% in ECGE3,4-158F carriers (ns). Out of the 45 patients analyzed for ECGE2 -131H/R polymorphism, 9 (20%) and 13 (29%) were homozygous for ECGR2Λ-131R and FCGR2A- 131H, respectively, while 23 (51%) were heterozygous. There was no difference in the characteristics at inclusion or clinical response to rituximab treatment for these three groups or for homozygous ECGE2 -131H patients and ECGE2/1-131R carriers, or for homozygous ECGE2. -131R patients and ECGR2 -131H carriers (data not shown).

Molecular response At diagnosis, BCL2-JH rearrangement was detected in both peripheral blood and in bone marrow in 30 (64%) patients, enabling further follow-up. Twenty-five patients (six FCGR3A- 158V homozygous patients and 19 ECGE3Λ-158F carriers) and 23 patients (six FCGR3A- 158V homozygous patients and 17 ECGE3/4-158F carriers) were analysed for BCL2-JH rearrangement in both peripheral blood and bone marrow at M2 and at M12 (Table 3) . At M2, a cleaning of BCL2-JH rearrangement was observed in 3/6 of the ECGE3 1-158V homozygous patients and in 5/19 of the ECGR3 1-158F carriers (ns). In contrast, the rate of BCL2-JH rearrangement cleaning at M12 was higher (5/6) in the ECGR3/ -158V homozygous patients than in the ECGR3Λ-158F carriers (5/17) (relative risk=2.8; 95% CI, 1.2-6.4; E=0.03). The logistic regression analysis showed that the ECGE-3/4-158V homozygous genotype was the only factor associated with a greater probability of exhibiting BCL2-JH rearrangement cleaning at M12 (_°=0.04). The single homozygous ECGR3 -158V patient still presenting with BCL2-JH rearrangement in peripheral blood and bone marrow at M12 was in CR 23 months after rituximab treatment. In contrast, the molecular responses at M2 and M12 were not influenced by the ECGR24-131H/R polymorphism (data not shown).

DISCUSSION

Because of the increasing use of rituximab in B cell lymphoproliferative malignancies, enhanced understanding of treatment failures and of the mode of action of rituximab is required. In this regard, we genotyped FCGR3A in follicular NHL patients with well-defined clinical and laboratory characteristics and treated with rituximab alone.-' In particular, all the patients included in this study had a low tumor burden NHL and a molecular analysis of BCL2-JH at diagnosis and during follow-up. The FCGR3A allele frequencies in this population were similar to those of a general Caucasian population.23,24 Our results show an association between the FCGR3A genotype and the response to rituximab. Indeed, homozygous ECGE3 1-158V patients, who account for one fifth of the population, had a greater probability of experiencing clinical response, with 100% and 90% objeαive response rates at M2 and M12, respectively. Moreover, five of the six ECGR3/ -158V homozygous patients analysed for BCL2-JH rearrangement showed molecular response at M12, compared to 5 of the 17 ECGE3 1-158F carriers. ECGE3 -158V homozygosity was the only factor associated with the clinical and molecular responses. However, these higher clinical and molecular responses were still unsufficient to significantly improve the progression-free survival in homozygous FCGR3A-158V patients.

This is the first report of an easily assessable genetic predictive factor for both clinical and molecular responses to rituximab. However, the genetic association does not demonstrate the mode of action of rituximab involves FcγRIIIa. The association observed between FCGR3A genotype and response to rituximab might be due to another genetic polymorphism in linkage disequilibrium. Those polymorphisms could be located in FCGR3A itself like the triallelic ECG -48L/H/R polymorphism-' 1 or in other FcγR-coding genes, since FCGR3A is located on the long arm of chromosome 1, which includes the three FCGR2 genes and

FCGR3B.ⁱ² A linkage disequilibrium has been reported between FCGR2A and FCGR3B.^ However, the fact that ECGE2/1-131H/R polymorphism was not associated with a better response to rituximab strongly supports the fact that a gene very close to FCGR3A or FCGR3A itself is directly involved.

Several in vitro studies argue in favor of direct involvement of ECGE3 1-158V/F polymorphism. shown that the previously reported differences in IgG binding among the three FcyRTJIa-48L/H/R isoforms-'l are a consequence of the linked FcγRIIIa-158V/F polymorphism and several teams have demonstrated that NK cells from individuals homozygous for the ECGR3.4-158V allotype have a higher affinity for human complexed IgGl and are more cytotoxic towards IgGl-sensitized targets.23 ,24,34 Qur present results establish that ECGR3 1-158V homozygous patients have a better response to rituximab, which is probably due to a better in vivo binding of that chimeric human IgGl to FcγRLUa. Secondly, NK cell- and macrophage-mediated ADCC is one of the mechanisms triggered by anti-CD20 antibodies in vitro 8>H>12 _{as we}u as in murine models in vivo, 17-19 and rituximab-mediated apoptosis is amplified by FcγR-expressing cells.15,16 Qut of all FcγR, FcγRIHa is the only receptor shared by NK cells and macrophages. We thus postulate that ECGE3 -158V patients show a better response to rituximab because they have better ADCC activity against lymphoma cells. The fact that more than 50% of theECGE3_4-158F carriers nonetheless present a clinical response to rituximab could be explained by lower, but still sufficient, ADCC activity or, more likely, by other mechanisms operating in vivo such as complement-dependent cytotoxicity, complement-dependent cell-mediated cytotoxicity 11*13, 14 and/or apoptosis.15,16 ADCC could then be viewed as an additional mechanism in the response to rituximab that is particularly effective in ECGE3 1-158V homozygous patients.

The in vitro studies suggest a " gene-dose " effect with a level of IgGl binding to NK cells from FCGR3A heterozygous donors intermediate between that observed with NK cells from ECGR3/4-158V and ECGR34-158F homozygotes23. However, the clinical response of heterozygous patients appears similar to that of ECGE-3 1-158F homozygous patients. Further studies with larger groups of patients will be required to conclude against a " gene-dose " effect in vivo. Since FcγRffla is strongly associated with a better response to rituximab, it needs to be taken into account in the development of new drugs targetting the CD20 antigen. For example, it may be possible to use engineered rituximab to treat ECGE34-158F-carrier patients with B cell lymphomas. Indeed, by modifying various residues in the IgGl lower hinge region, Shields et al have recently obtained IgGl mutants which bind more strongly to FcγRLTIa-158F than native IgGl³⁴.

Taken together, these results allow to set up new therapeutic strategies against B lymphoproliferative disorders based upon prior determination of the patients FCGR3A genotype. Since this polymorphism has the same distribution in various ethnic population, including blacks and Japanese, such a strategy may be applied worldwide.23,35,36 Furthermore, such a pharmacogenetic approach may also be applied to other intact humanized IgGl antibodies used in the treatment of B cell malignancies, such as Campath-IH, or those used in the treatment of other malignancies, such as trastuzumab (Herceptin^®). Even more generally, this approach may apply to other intact (humanized) therapeutic (IgGl) antibodies developed to deplete target cells.

REFERENCES

1. Maloney DG, Liles TM, Czerwinski DK, et al.: Phase I clinical trial using escalating single-dose infusion of chimeric anti-CD20 monoclonal antibody (IDEC-C2B8) in patients with recurrent B-cell lymphoma. Blood. 1994;84:2457-2466.

2. McLaughlin P, Grillo-Lopez AJ, Link BK, et al.: Rituximab chimeric anti-CD20 monoclonal antibody therapy for relapsed indolent lymphoma: half of patients respond to a four-dose treatment program. J Clin Oncol. 1998;16:2825-2833.

3. Maloney DG, Grillo-Lopez AJ, White CA, et al.: IDEC-C2B8 (Rituximab) anti-CD20 monoclonal antibody therapy in patients with relapsed low-grade non-Hodgkin's lymphoma. Blood.

1997;90:2188-2195.

4. Hainsworth JD, Bums HA, 3rd, Morrissey LH, et al.: Rituximab monoclonal antibody as initial systemic therapy for patients with low-grade non-Hodgkin lymphoma. Blood. 2000;95:3052-3056.

5. Colombat P, Salles G, Brousse N, et al.: Rituximab (anti-CD20 monoclonal antibody) as first- line therapy of follicular lymphoma patients with low tumor burden: clinical and molecular evaluation. Blood.

2001;97:101-106.

6. Coiffier B, Haioun C, Ketterer N, et al.: Rituximab (anti-CD20 monoclonal antibody) for the treatment of patients with relapsing or refractory aggressive lymphoma: a multicenter phase II study. Blood. 1998;92:1927-1932. 7. Foran JM, Rohatiner AZ, Cunningham D, et al.: European phase II study of rituximab

(chimeric anti-CD20 monoclonal antibody) for patients with newly diagnosed mantle-cell lymphoma and previously treated mantle-cell lymphoma, immunocytoma, and small B-cell lymphocytic lymphoma. J Clin Oncol. 2000;18:317-324.

8. Anderson DR, Grillo-Lopez A, Varns C, Chambers KS, Hanna N: Targeted anti-cancer therapy using rituximab, a chimaeric anti-CD20 antibody (IDEC-C2B8) in the treatment of non-Hodgkin's B-cell lymphoma. Biochem Soc Trans. 1997;25:705-708.

9. Vose J, Link B, Grossbard M, et al. : Phase II study of rituximab in combination with CHOP chemotherapy in patients with preiously untreated intermediate or high-grade non-Hodgkin's lymphoma (NHL). Ann Oncol. 1999;10:58. 10. Berinstein NL, Grillo-Lopez AJ, White CA, et al.: Association of serum Rituximab (TDEC-

C2B8) concentration and anti-tumor response in the treatment of recurrent low-grade or follicular non- Hodgkin's lymphoma. Ann Oncol. 1998;9:995-1001.

11. Hariunpaa A, Junnikkala S, Meri S: Rituximab (anti-CD20) therapy of B-cell lymphomas: direct complement killing is superior to cellular effector mechanisms. Scand J Immunol. 2000;51:634-641. 12. Reff ME, Carner K, Chambers KS, et al.: Depletion of B cells in vivo by a chimeric mouse human monoclonal antibody to CD20. Blood. 1994;83:435-445. 13. Idusogie EE, Presta LG, Gazzano-Santoro H, et al.: Mapping of the Clq binding site on rituxan, a chimeric antibody with a human IgGl Fc. J Immunol. 2000;164:4178-4184.

14. Golay J, Zaffaroni L, Vaccari T, et al.: Biologic response of B lymphoma cells to anti-CD20 monoclonal antibody rituximab in vitro: CD55 and CD59 regulate complement-mediated cell lysis. Blood. 2000;95:3900-3908.

15. Shan D, Ledbetter JA, Press OW: Apoptosis of malignant human B cells by ligation of CD20 with monoclonal antibodies. Blood. 1998;91:1644-1652.

16. Shan D, Ledbetter JA, Press OW: Signaling events involved in anti-CD20-induced apoptosis of malignant human B cells. Cancer Immunol Immunother. 2000;48:673-683. 17. Hooijberg E, Sein JJ, van den Berk PC, et al.: Eradication of large human B cell tumors in nude mice with unconjugated CD20 monoclonal antibodies and interleukin 2. Cancer Res. 1995;55:2627-2634.

18. Funakoshi S, Longo DL, Murphy WJ: Differential in vitro and in vivo antitumor effects mediated by anti- CD40 and anti-CD20 monoclonal antibodies against human B-cell lymphomas. J Immunother

Emphasis Tumor Immunol. 1996;19:93-101. 19. Clynes RA, Towers TL, Presta LG, Ravetch JV: Inhibitory Fc receptors modulate in vivo cytoxicity against tumor targets. Nat Med. 2000;6:443-446.

20. Fijen CA, Bredius RG, Kuijper EJ, et al.: The role of Fcγ receptor polymorphisms and C3 in the immune defence against Neisseria meningitidis in complement-deficient individuals. Clin Exp Immunol.

2000;120:338-345. 21. Dijstelbloem HM, Scheepers RH, Oost WW, et al.: Fcγ receptor polymorphisms in Wegener's granulomatosis: risk factors for disease relapse. Arthritis Rheum. 1999;42:1823-1827.

22. Myhr KM, Raknes G, Nyland H, Vedeler C: Immunoglobulin G Fc-receptor (FcγR) IIA and IIIB polymorphisms related to disability in MS. Neurology. 1999;52:1771-1776.

23. Koene HR, Kleijer M, Algra J, Roos D, von dem Borne AE, de Haas M: Fc γRIIIa-158V/F polymorphism influences the binding of IgG by natural killer cell Fc γRIIIa, independently of the Fc γRIIIa-

48L/R/H phenotype. Blood. 1997;90:1109-1114.

24. Wu J, Edberg JC, Redecha PB, et al.: A novel polymorphism of FcγRIIIa (CD16) alters receptor function and predisposes to autoimmune disease. J Clin Invest. 1997;100:1059-1070.

25. Sondermann P, Huber R, Oosthuizen V, Jacob U: The 3.2-A crystal structure of the human IgGl Fc fragment-Fc γRIII complex. Nature. 2000;406:267-273.

26. Harris NL, Jaffe ES, Stein H, et al. : A revised European- American classification of lymphoid neoplasms: a proposal from the International Lymphoma Study Group. Blood. 1994;84:1361-1392.

27. Brice P, Bastion Y, Lepage E, et al.: Comparison in low-tumor-burden follicular lymphomas between an initial no-treatment policy, prednimustine, or interferon alfa: a randomized study from the Groupe d'Etude des Lymphomes Folliculaires. Groupe d'Etude des Lymphomes de 1' Adulte. J Clin Oncol. 1997;15:1110- 1117. 28. Cheson BD, Horning SJ, Coiffier B, et al.: Report of an international workshop to standardize response criteria for non-Hodgkin's lymphomas. NCI Sponsored International Working. J Clin Oncol. 1999;17:1244.

29. Jiang XM, Arepally G, Poncz M, McKenzie SE: Rapid detection of the Fc γ RIIA-H/R 131 ligand-binding polymorphism using an allele-specific restriction enzyme digestion (ASRED) . J Immunol Methods.

1996;199:55-59.

30. Kaplan E, Meier P: Nonparametric estimation from incomplete observations. J Am Stat Assoc. 1958;53:457-481.

31. de Haas M, Koene HR, Kleijer M, et al.: A triallelic Fc γ receptor type IIIA polymorphism influences the binding of human IgG by NK cell Fc γ RHIa. J Immunol. 1996;156:3948-3955.

32. Peltz GA, Grundy HO, Lebo RV, Yssel H, Barsh GS, Moore KW: Human Fc γ RIII: cloning, expression, and identification of the chromosomal locus of two Fc receptors for IgG. Proc Natl Acad Sci U SA. 1989;86:1013-1017.

33. Schnackenberg L, Flesch BK, Neppert J: Linkage disequilibria between Duffy blood groups, Fc γ Ila and Fc γ Illb allotypes. Exp Clin Immunogenet. 1997;14:235-242.

34. Shields RL, Namenuk AK, Hong K, et al.: High resolution mapping of the binding site on human IgGl for Fc γ RI, Fc γ RII, Fc γ RIII, and FcRn and design of IgGl variants with improved binding to the Fc γ R. J Biol Chem. 2001;276:6591-6604.

35. Leppers-van de Straat FG, van der Pol W, Jansen MD, et al. : A novel PCR-based method for direct Fcγ receptor Ilia (CD16) allotyping. J Immunol Methods. 2000;242:127-132.

36. Lehrnbecher T, Foster CB, Zhu S, et al.: Variant genotypes of the low-affinity Fcγ receptors in two control populations and a review of low-affinity Fcγ receptor polymorphisms in control and disease populations. Blood. 1999;94:4220-4232.

TABLE 1. CHARACTERISTICS OF PATIENTS ACCORDING TO THEECGR3Λ-158V/F POLYMORPHISM.

ECGR3.4- FCGR3A- FCGR3A- p* 158 158VF 158FF n (%) 10 (20%) 22 : (45%) 17 (35%)

Sex

M 3 12 10 ns

F 7 10 7

Disease stage π-m 3 6 6 ns

TN 7 16 11

Bone marrow involvement yes 7 16 9 ns no 3 6 8

Εxtra-nodal sites involved

< 2 8 20 13 ns

> 2 2 2 4

BCL2-fH rearrangement in peripheral blood 8 12 11 ns

BCL2-JH rearrangement in bone marrow 7 12 11 ns

* Satistical comparisons of the three groups of homozygous ECGR3 -158V patients vs ECGR3Λ-158F carriers and of homozygous ECGE-3 -158F patients against ECGR3Λ-158V carriers. TABLE 2. CLINICAL RESPONSE TO RITUXIMAB BY ECGR3 -158V/F POLYMORPHISM.

ECGi?3A-158W ECGR3A-158F carriers P*

Clinical response at M2

Objective response 10 (100%) 26 (67%) 0.03 complete remission 3 7 complete remission unconfirmed 1 2 partial response 6 17

No response 0 (0%) 13 (33%) no change 0 10 progressive disease 0 3

Clinical response at M12

Objective response 9 9 ((9900%%)) 2 200 ((5511 %%)) 0.03 complete remission 6 11 complete remission unconfirmed 1 v. 2 partial response 2 7

No response 1 (10%) 19 (49%) no change 0 2 progressive disease 1 17 * Satistical comparison of homozygous ECGE-3/4-158N patients against ECGR3 -158F carriers. Data concerning the three genotype subgroups are given in the text.

TABLE 3. MOLECULAR RESPONSE TO RITUXIMAB AT M2 AND AT M12 BY THE ECGR3Λ-158V/F POLYMORPHISM.

carriers

Molecular response at M2 ns

Cleaning ofBCL2-JH rearrangement 3 5

Persistent BCL2-JH rearrangement 3 14

Molecular response at M12 0.03

Cleaning ofBCL2-JH rearrangement 5 5

Persistent BCL2-JH rearrangement 1 12

Claims

1. A method of assessing the response of a subject to a therapeutic antibody treatment, comprising determining in vitro the FCGR3A158 genotype of said subject.

2. A method of selecting patients for therapeutic antibody treatment, the method comprising determining in vitro the FCGR3A158 genotype of said subject.

3. A method of improving the efficacy or treatment condition or protocol of a therapeutic antibody treatment in a subject, comprising determining in vitro the FCGR3A158 genotype of said subject.

4. The method of any one of claims 1 to 3, comprising determining amino acid residue at position 158 of FcγRLTIa receptor, a Valine at position 158 being indicative of a better response to said treatment and a phenylalanine at position 158 being indicative of a lower response to said treatment.

5. The method of any one of claims 1 to 4, wherein determining amino acid residue at position 158 of FcyRIIIa receptor comprises a step of sequencing the FcγRuTa receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158.

6. The method of any one of claims 1 to 5, wherein determining amino acid residue at position 158 of FcγRπia receptor comprises a step of amplifying the FcyRIIIa receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158.

7. The method of claim 6, wherein amplificatin is performed by polymerase chain reaction (PCR), such as PCR, RT-PCR and nested PCR.

8. The method of any one of claims 1 to 7, wherein determining amino acid residue at position 158 of FcγRHIa receptor comprises a step of allele-specific restriction enzyme digestion.

9. The method of any one of claims 1 to 8, wherein determining amino acid residue at position 158 of FcγRIHa receptor comprises a step of hybridization of the FcγRπia receptor gene or RNA or a portion thereof comprising the nucleotides encoding amino acid residue 158, with a nucleic acid probe specific for the genotype Valine or Phenylalanine.

10. The method of any one of claims 1 to 9, wherein determining amino acid residue at position 158 of FcγRIHa receptor comprises:

- Obtaining genomic DNA from a biological sample, - Amplifying the FcyRIHa receptor gene or a portion thereof comprising the nucleotides encoding amino acid residue 158, and

11. The method of any one of claims 1 to 9, wherein determining amino acid residue at position 158 of FcγRIHa receptor comprises:

Obtaining genomic DNA from a biological sample,

- Amplifying the FcγRHIa receptor gene or a portion thereof comprising the nucleotides encoding amino acid residue 158, - Introducing an allele-specific restriction site,

- Digesting the nucleic acids with the enzyme specific for said restriction site and,

Analysing the digestion products, i.e., by electrophoresis, the presence of digestion products being indicative of the presence of the allele.

12. The method of any one of claims 1 to 9, wherein determining amino acid residue at position 158 of FcγRHIa receptor comprises: total (or messenger) RNA extraction from cell or biological sample or biological fluid in vitro or ex vivo, optionally cDNA synthesis, (PCR) amplification with specific FCGRIIIa oligonucleotide primers, and analysis of PCR products.

13. The method of any one of claims 1 to 4, wherein determining amino acid residue at position 158 of FcγRHIa receptor comprises a step of sequencing the FcγRπia receptor polypeptide or a portion thereof comprising amino acid residue 158.

14. The method of any one of the preceding claims, wherein the subject is a human subject.

15. The method of claim 14, wherein the subject has a tumor, a viral infection, or a disease condition associated with allogenic or pathological immunocompetent cells.

16. The method of claim 15, wherein the subject has a tumor and the therapeutic antibody treatment aims at reducing the tumor burden.

17. The method of claim 16, wherein the tumor is a lymphoma, particularly a NHL.

18. The method of any one of the preceding claims, wherein the antibody is an IgGl or an IgG3.

19. The method of claim 18, wherein the antibody is an anti-CD20 antibody, particularly rituximab.