This invention relates to a method for the inhibition of leukemic stem cells, and in particular for the inhibition of leukemic stem cells associated with acute myelogenous leukemia (AML) and other haematologic cancer conditions as an effective therapy against these hematologic cancer conditions.
Hematological cancer conditions are the types of cancer such as leukemia and malignant lymphoproliferative conditions that affect blood, bone marrow and the lymphatic system.
Leukemia can be classified as acute leukemia and chronic leukemia. Acute leukemia can be further classified as acute myelogenous leukemia (AML) and acute lymphoid leukemia (ALL). Chronic leukemia includes chronic myelogenous leukemia (CML) and chronic lymphoid leukemia (CLL). Other related conditions include myelodysplastic syndromes (MDS, formerly known as “preleukemia”) which are a diverse collection of hematological conditions united by ineffective production (or dysplasia) of myeloid blood cells and risk of transformation to AML.
Leukemic stem cells (LSCs) are cancer cells that possess characteristics associated with normal stem cells, that is, the property of self renewal and the capability to develop multiple lineages. Such cells are proposed to persist in hematological cancers such as AML as distinct populations.1
Acute myelogenous leukemia (AML) is a clonal disorder clinically presenting as increased proliferation of heterogeneous and undifferentiated myeloid blasts. The leukemic hierarchy is maintained by a small population of LSCs, which have the distinct ability for self-renewal, and are able to differentiate into leukemic progenitors1. These progenitors generate the large numbers of leukemic blasts readily detectable in patients at diagnosis and relapse, leading ultimately to mortality2-4. AML-LSC have been commonly reported as quiescent cells, in contrast to rapidly dividing clonogenic progenitors3,5,6. This property of LSCs renders conventional chemotherapeutics that target proliferating cells less effective, potentially explaining the current experience in which a high proportion of AML patients enter complete remission, but almost invariably relapse, with <30% of adults surviving for more than 4 years7. In addition, minimal residual disease occurrence and poor survival has been attributed to high LSC frequency at diagnosis in AML patients8. Consequently, it is imperative for the long term management of AML (and similarly other above mentioned hematological cancer conditions) that new treatments are developed to specifically eliminate LSCs9-14.
AML-LSCs and normal hematopoietic stem cells (HSCs) share the common properties of slow division, self-renewal ability, and surface markers such as the CD34+CD38− phenotype. Nevertheless, LSCs have been reported to possess enhanced self-renewal activity, in addition to altered expression of other cell surface markers, both of which present targets for therapeutic exploitation. Interleukin-3 (IL-3) mediates its action through interaction with cell surface receptors that consist of 2 subunits, the α subunit (CD123) and the β common (βc) chain (CD131). The interaction of an α chain with a β chain forms a high affinity receptor for IL-3, and the βc chain mediates the subsequent signal transduction15,16. Over-expression of CD123 on AML blasts, CD34+ leukemic progenitors and LSCs relative to normal hematopoietic cells has been widely reported17-23, and has been proposed as a marker of LSCs in some studies24,25. CD131 was also reported to be expressed on AML cells21,25 but there are conflicting reports on its expression on AML-LSCs23,25.
Overexpression of CD123 on AML cells confers a range of growth advantages over normal hematopoietic cells, with a large proportion of AML blasts reported to proliferate in culture in response to IL-326-31. Moreover, high-level CD123 expression on AML cells has been correlated with: the level of IL-3-stimulated STAT-5 activation; the proportion of cycling cells; more primitive cell surface phenotypes; and resistance to apoptosis. Clinically, high CD123 expression in AML is associated with lower survival duration, a lower complete remission rate and higher blast counts at diagnosis19,21,32.
The increased expression of CD123 on LSCs compared with HSCs presents an opportunity for therapeutic targeting of AML-LSCs. The monoclonal antibody (MAb) 7G3, raised against CD123, has previously been shown to inhibit IL-3 mediated proliferation and activation of both leukemic cell lines and primary cells33. However, it has remained unclear whether targeting CD123 can functionally impair AML-LSCs, and whether it can inhibit the homing, lodgment and proliferation of AML-LSCs in their bone marrow niche. Moreover, the relative contributions of direct inhibition of IL-3 mediated signaling versus antibody-dependent cell-mediated cytotoxicity (ADCC) in the ability of 7G3 to target AML-LSCs remain unresolved.
U.S. Pat. No. 6,177,078 (Lopez) discloses the anti-IL-3Receptor alpha chain (IL-3Rα) monoclonal antibody 7G3, and the ability of 7G3 to bind to the N-terminal domain, specifically amino acid residues 19-49, of IL-3Rα. Accordingly, this patent discloses the use of a monoclonal antibody such as 7G3 or antibody fragment thereof with binding specificity for amino acid residues 19-49 of IL-3Rα in the treatment of conditions resulting from an overproduction of IL-3 in a patient (including myeloid leukemias, lymphomas and allergies) by antagonizing the functions of the IL-3.
U.S. Pat. No. 6,733,743 (Jordan) discloses a method of impairing a hematologic cancer progenitor cell that expresses CD123 but does not significantly express CD131, by contacting the cell with a composition of an antibody and a cytotoxic agent (selected from a chemotherapeutic agent, a toxin or an alpha-emitting radioisotope) whereby the composition binds selectively to CD123 in an amount effective to cause cell death. The hematologic cancer may be leukemia or a malignant lymphoproliferative disorder such as lymphoma.
In work leading to the present invention, the inventors have tested the ability of MAb 7G3 to exploit the overt differences in CD123 expression and function between AML-LSCs and HSCs. MAb 7G3 inhibited the IL-3 signaling pathway and proliferation of primary AML cells. Moreover, the homing and engraftment of AML blasts in the nonobese diabetic/severe combined immunodeficient (NOD/SCID) xenograft model were profoundly reduced by MAb 7G3, and LSC function was inhibited.
In one aspect, the present invention provides a method for inhibition of leukemic stem cells expressing IL-3Rα (CD123), which comprises contacting said cells with an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
The present invention also provides a method for the treatment of a hematologic cancer condition in a patient, which comprises administration to the patient of an effective amount of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In another aspect, the present invention also provides the use of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function in, or in the manufacture of a medicament for, the inhibition of leukemic stem cells expressing IL-3Rα (CD123), wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In this aspect, the invention also provides the use of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function in, or in the manufacture of a medicament for, the treatment of a hematologic cancer condition in a patient, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
The present invention also provides an agent for inhibition of leukemic stem cells expressing IL-3Rα (CD123), which comprises an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to the IL-3Rα (CD123).
In this aspect, the invention also provides an agent for the treatment of a hematologic cancer condition in a patient, which comprises an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In one aspect, the present invention provides a method for inhibition of leukemic stem cells expressing IL-3Rα (CD123), which comprises contacting said cells with an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In this aspect, the invention also provides a method for the treatment of a hematologic cancer condition in a patient, which comprises administration to the patient of an effective amount of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
Preferably, the patient is a human.
The antigen binding molecule is preferably a monoclonal antibody or antibody fragment comprising a Fc region or a modified Fc region having enhanced Fc effector function.
Antibodies provide a link between the humoral and the cellular immune system with IgG being the most abundant serum immunoglobulin. While the Fab regions of the antibody recognize antigens, the Fc portion binds to Fcγ receptors (Fcγ Rs) that are differentially expressed by all immune accessory cells such as natural killer (NK) cells, neutrophils, mononuclear phagocytes or dendritic cells. Such binding crosslinks FcR on these cells and they become activated as a result. Activation of these cells has several consequences; for example, NK cells kill cancer cells and also release cytokines and chemokines that can inhibit cell proliferation and tumour-related angiogenesis, and increase tumour immunogenicity through increased cell surface expression of major histocompatibility antigens (MHC) antigens. Upon receptor crosslinking by a multivalent antigen/antibody complex, effector cell degranulation and transcriptional-activation of cytokine-encoding genes are triggered and is followed by cytolysis or phagocytosis of the target cell.
The effector functions mediated by the antibody Fc region can be divided into two categories: (1) effector functions that operate after the binding of antibody to an antigen (these functions involve, for example, the participation of the complement cascade or Fc receptor (FcR)-bearing cells); and (2) effector functions that operate independently of antigen binding (these functions confer, for example, persistence in the circulation and the ability to be transferred across cellular barriers by transcytosis). For example, binding of the C1 component of complement to antibodies activates the complement system. Activation of complement is important in the opsonisation and lysis of cell pathogens. The activation of complement also stimulates the inflammatory response and may also be involved in autoimmune hypersensitivity. Further, antibodies bind to cells via the Fc region, with an Fc receptor binding site on the antibody Fc region binding to a Fc receptor (FcR) on a cell. Binding of antibody to Fc receptors on cell surfaces triggers a number of important and diverse biological responses including engulfment and destruction of antibody-coated particles, clearance of immune complexes, lysis of antibody-coated target cells by killer cells (known as antibody-dependent cell-mediated cytotoxicity, or ADCC), release of inflammatory mediators, placental transfer and control of immunoglobulin production.
The present inventors have shown that the presence in the antigen binding molecule of a Fc region or a modified Fc region having enhanced Fc effector function is important for inhibition of leukemic stem cells expressing CD123, and hence in treatment of hematologic cancer conditions associated with leukemic stem cells.
The hematologic cancer conditions associated with leukemic stem cells (LSCs) which may be treated in accordance with the present invention include leukemias (such as acute myelogenous leukemia, chronic myelogenous leukemia, acute lymphoid leukemia, chronic lymphoid leukemia and myelodysplastic syndrome) and malignant lymphoproliferative conditions, including lymphomas (such as multiple myeloma, non-Hodgkin's lymphoma, Burkitt's lymphoma, and small cell- and large cell-follicular lymphoma).
As used herein the term “antigen binding molecule” refers to an intact immunoglobulin, including monoclonal antibodies, such as chimeric, humanized or human monoclonal antibodies, or to an antigen-binding and/or variable-domain-comprising fragment of an immunoglobulin that competes with the intact immunoglobulin for specific binding to the binding partner of the immunoglobulin, e.g. a host cell protein. Regardless of structure, the antigen-binding fragment binds with the same antigen that is recognized by the intact immunoglobulin. Antigen-binding fragments may be produced synthetically or by enzymatic or chemical cleavage of intact immunoglobulins or they may be genetically engineered by recombinant DNA techniques. The methods of production of antigen binding molecules and fragments thereof are well known in the art and are described, for example, in Antibodies: A Laboratory Manual, Edited by E. Harlow and D, Lane (1988), Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., which is incorporated herein by reference.
The term “inhibition” as used herein, in reference to leukemic stem cells, includes any decrease in the functionality or activity of the LSCs (including growth or proliferation and survival activity), in particular any decrease or limitation in the ability of the LSCs to survive, proliferate and/or differentiate into progenitors of leukemia or other malignant hyperproliferative hematologic cancer cells.
The term “binds selectively”, as used herein, in reference to the interaction of a binding molecule, e.g. an antibody, and its binding partner, e.g. an antigen, means that the interaction is dependent upon the presence of a particular structure, e.g. an antigenic determinant or epitope, on the binding partner. In other words, the antibody preferentially binds or recognizes the binding partner even when the binding partner is present in a mixture of other molecules or organisms.
The term “effective amount” refers to an amount of the binding molecule as defined herein that is effective for treatment of a hematologic cancer condition.
The term “treatment” refers to therapeutic treatment as well as prophylactic or preventative measures to cure or halt or at least retard progress of the condition. Those in need of treatment include those already afflicted with a hematologic cancer condition as well as those in which such a condition is to be prevented. Subjects partially or totally recovered from the condition might also be in need of treatment. Prevention encompasses inhibiting or reducing the onset, development or progression of one or more of the symptoms associated with a hematologic cancer condition.
In the method of the present invention, administration to the patient of a chemotherapeutic agent may be combined with the administration of the antigen binding molecule, with the chemotherapeutic agent being administered either prior to, simultaneously with, or subsequent to, administration of the antigen binding molecule.
Preferably, the chemotherapeutic agent is a cytotoxic agent, for example a cytotoxic agent selected from the group consisting of:
Other examples of chemotherapeutic agents include, but are not limited to: acivicin; aclarubicin; acodazole hydrochloride; acronine; adozelesin; aldesleukin; altretamine; ambomycin; ametantrone acetate; aminoglutethimide; anastrozole; anthracyclin; anthramycin; asperlin; azacitidine (Vidaza); azetepa; azotomycin; batimastat; benzodepa; bicalutamide; bisantrene hydrochloride; bisnafide dimesylate; bisphosphonates (e.g., pamidronate (Aredria), sodium clondronate (Bonefos), zoledronic acid (Zometa), alendronate (Fosamax), etidronate, ibandornate, cimadronate, risedromate, and tiludromate); bizelesin; brequinar sodium; bropirimine; cactinomycin; calusterone; caracemide; carbetimer; carmustine; carubicin hydrochloride; carzelesin; cedefingol; cirolemycin; crisnatol mesylate; decitabine (Dacogen); demethylation agents; dexormaplatin; dezaguanine; dezaguanine mesylate; diaziquone; droloxifene; droloxifene citrate; dromostanolone propionate; duazomycin; edatrexate; eflornithine hydrochloride; EphA2 inhibitors; elsamitrucin; enloplatin; enpromate; epipropidine; erbulozole; esorubicin hydrochloride; etanidazole; etoprine; fadrozole hydrochloride; fazarabine; fenretinide; floxuridine; flurocitabine; fosquidone; fostriecin sodium; histone deacetylase inhibitors (HDAC-Is); ilmofosine; imatinib mesylate (Gleevec, Glivec); iproplatin; lanreotide acetate; lenalidomide (Revlimid); letrozole; leuprolide acetate; liarozole hydrochloride; lometrexol sodium; lomustine; losoxantrone hydrochloride; masoprocol; maytansine; megestrol acetate; melengestrol acetate; menogaril; metoprine; meturedepa; mitindomide; mitocarcin; mitocromin; mitogillin; mitomalcin; mitosper; mycophenolic acid; nocodazole; nogalamycin; ormaplatin; oxisuran; peliomycin; pentamustine; peplomycin sulfate; perfosfamide; pipobroman; piposulfan; piroxantrone hydrochloride; plomestane; porfimer sodium; porfiromycin; prednimustine; puromycin; puromycin hydrochloride; pyrazofurin; riboprine; rogletimide; safingol; saflngol hydrochloride; semustine; simtrazene; sparfosate sodium; sparsomycin; spirogermanium hydrochloride; spiromustine; spiroplatin; streptonigrin; streptozocin; sulofenur; talisomycin; tecogalan sodium; tegafur; teloxantrone hydrochloride; temoporfin; teroxirone; testolactone; thiamiprine; tiazofurin; tirapazamine; toremifene citrate; trestolone acetate; triciribine phosphate; trimetrexate; trimetrexate glucuronate; triptorelin; tubulozole hydrochloride; uracil mustard; uredepa; vapreotide; verteporfin; vindesine; vindesine sulfate; vinepidine sulfate; vinglycinate sulfate; vinleurosine sulfate; vinrosidine sulfate; vinzolidine sulfate; vorozole; zeniplatin; zinostatin; zorubicin hydrochloride; 20-epi-1,25 dihydroxyvitamin D3; 5-ethynyluracil; abiraterone; aclarubicin; acylfulvene; adecypenol; adozelesin; aldesleukin; ALL-TK antagonists; altretamine; ambamustine; amidox; amifostine; aminolevulinic acid; amrubicin; anagrelide; anastrozole; andrographolide; angiogenesis inhibitors; antagonist D; antagonist G; antarelix; antiandrogen, prostatic carcinoma; antiestrogen; antineoplaston; antisense oligonucleotides; aphidicolin glycinate; apoptosis gene modulators; apoptosis regulators; apurinic acid; ara-CDP-D L-PTBA; asulacrine; atamestane; atrimustine; axinastatin 1; axinastatin 2; axinastatin 3; azasetron; azatoxin; azatyrosine; baccatin III derivatives; balanol; batimastat; BCR/ABL antagonists; benzochlorins; benzoylstaurosporine; beta lactam derivatives; beta-alethine; betaclamycin B; betulinic acid; bFGF inhibitor; bicalutamide; bisantrene; bisaziridinylspermine; bisnafide; bistratene A; bizelesin; breflate; bropirimine; budotitane; buthionine sulfoximine; calcipotriol; calphostin C; camptothecin derivatives; canarypox IL-2; carboxamide-amino-triazole; carboxyamidotriazole; CaRest M3; CARN 700; cartilage derived inhibitor; carzelesin; casein kinase inhibitors (ICOS); castanospermine; cecropin B; cetrorelix; chlorins; chloroquinoxaline sulfonamide; cicaprost; cis-porphyrin; clomifene analogues; clotrimazole; collismycin A; collismycin B; combretastatin A4; combretastatin analogue; conagenin; crambescidin 816; crisnatol; cryptophycin 8; cryptophycin A derivatives; curacin A; cyclopentanthraquinones; cycloplatam; cypemycin; cytolytic factor; cytostatin; dacliximab; decitabine; dehydrodidemnin B; deslorelin; dexamethasone; dexifosfamide; dexrazoxane; dexverapamil; diaziquone; didemnin B; didox; diethylnorspermine; dihydro-5-azacytidine; dihydrotaxol, dioxamycin; diphenyl spiromustine; docosanol; dolasetron; doxifluridine; droloxifene; dronabinol; duocarmycin SA; ebselen; ecomustine; edelfosine; edrecolomab; eflornithine; elemene; emitefur; epristeride; estramustine analogue; estrogen agonists; estrogen antagonists; etanidazole; exemestane; fadrozole; fazarabine; fenretinide; filgrastim; finasteride; flavopiridol; flezelastine; fluasterone; fluorodaunorunicin hydrochloride; forfenimex; formestane; fostriecin; fotemustine; gadolinium texaphyrin; gallium nitrate; galocitabine; ganirelix; gelatinase inhibitors; glutathione inhibitors; HMG CoA reductase inhibitors (e.g., atorvastatin, cerivastatin, fluvastatin, lescol, lupitor, lovastatin, rosuvastatin, and simvastatin); hepsulfam; heregulin; hexamethylene bisacetamide; hypericin; ibandronic acid; idoxifene; idramantone; ilmofosine; ilomastat; imidazoacridones; imiquimod; insulin-like growth factor-1 receptor inhibitor; interferon agonists; interferons; interleukins; iobenguane; iododoxorubicin; ipomeanol, 4-iroplact; irsogladine; isobengazole; isohomohalicondrin B; itasetron; jasplakinolide; kahalalide F; lamellarin-N triacetate; lanreotide; leinamycin; lenograstim; lentinan sulfate; leptolstatin; letrozole; leuprolide and, estrogen, and progesterone; leuprorelin; levamisole; LFA-3TIP (Biogen, Cambridge, Mass.; International Publication No. WO 93/0686 and U.S. Pat. No. 6,162,432); liarozole; linear polyamine analogue; lipophilic disaccharide peptide; lipophilic platinum compounds; lissoclinamide 7; lobaplatin; lombricine; lometrexol; lonidamine; losoxantrone; lovastatin; loxoribine; lurtotecan; lutetium texaphyrin; lysofylline; lytic peptides; maitansine; mannostatin A; marimastat; masoprocol; matrilysin inhibitors; matrix metal loproteinase inhibitors; menogaril; merbarone; meterelin; metoclopramide; MIF inhibitor; mifepristone; miltefosine; mirimostim; mismatched double stranded RNA; mitoguazone; mitolactol; mitonafide; mitotoxin fibroblast growth factor-saporin; mofarotene; molgramostim; monophosphoryl lipid A+myobacterium cell wall sk; mopidamol; multiple drug resistance gene inhibitor; multiple tumor suppressor 1-based therapy; mustard anticancer agent; mycaperoxide B; mycobacterial cell wall extract; myriaporone; N-acetyldinaline; N-substituted benzamides; nafarelin; nagrestip; naloxone+pentazocine; napavin; naphterpin; nartograstim; nedaplatin; nemorubicin; neridronic acid; nilutamide; nisamycin; nitric oxide modulators; nitroxide antioxidant; nitrullyn; O6-benzylguanine; octreotide; okicenone; oligonucleotides; onapristone; oracin; oral cytokine inducer; ormaplatin; osaterone; oxaunomycin; paclitaxel; paclitaxel analogues; paclitaxel derivatives; palauamine; palmitoylrhizoxin; pamidronic acid; panaxytriol; panomifene; parabactin; pazelliptine; peldesine; pentosan polysulfate sodium; pentrozole; perflubron; perfosfamide; perillyl alcohol; phenazinomycin; phenylacetate; phosphatase inhibitors; picibanil; pilocaine hydrochloride; pirarubicin; piritrexim; placetin A; placetin B; platinum complex; platinum compounds; platinum-triamine complex; porfimer sodium; porfiromycin; prednisone; propyl bis-acridone; prostaglandin J2; proteasome inhibitors; protein A-based immune modulator; protein kinase C inhibitors, microalgal; protein tyrosine phosphatase inhibitors; purine nucleoside phosphorylase inhibitors; purpurins; pyrazoloacridine; pyridoxylated hemoglobin polyoxyethylene conjugate; raf antagonists; raltitrexed; ramosetron; ras farnesyl protein transferase inhibitors; ras inhibitors; ras-GAP inhibitor; retelliptine demethylated; rhenium Re 186 etidronate; rhizoxin; RII retinamide; rogletimide; rohitukine; romurtide; roquinimex; rubiginone B1; ruboxyl; safingol; saintopin; SarCNU; sarcophytol A; sargramostim; Sdi 1 mimetics; semustine; senescence derived inhibitor 1; sense oligonucleotides; signal transduction inhibitors; signal transduction modulators; gamma secretase inhibitors, sizofiran; sobuzoxane; sodium borocaptate; sodium phenylacetate; solverol; sonermin; sparfosic acid; spicamycin D; spiromustine; splenopentin; spongistatin 1; squalamine; stem cell inhibitor; stem-cell division inhibitors; stipiamide; stromelysin inhibitors; sulfinosine; superactive vasoactive intestinal peptide antagonist; suradista; suramin; swainsonine; synthetic glycosaminoglycans; tallimustine; leucovorin; tamoxifen methiodide; tauromustine; tazarotene; tecogalan sodium; tegafur; tellurapyrylium; telomerase inhibitors; temoporfin; tetrachlorodecaoxide; tetrazomine; thaliblastine; thiocoraline; thrombopoietin; thrombopoietin mimetic; thymalfasin; thymopoietin receptor agonist; thymotrinan; tin ethyl etiopurpurin; tirapazamine; titanocene bichloride; topsentin; toremifene; totipotent stem cell factor; translation inhibitors; triacetyluridine; triciribine; trimetrexate; triptorelin; tropisetron; turosteride; tyrosine kinase inhibitors; tyrphostins; UBC inhibitors; ubenimex; urokinase receptor antagonists; vapreotide; variolin B; vector system, erythrocyte gene therapy; thalidomide; velaresol; veramine; verdins; verteporfin; vinxaltine; vorozole; zanoterone; zeniplatin; zilascorb; and zinostatin stimalamer.
In accordance with the present invention, the antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function is preferably administered to a patient by a parenteral route of administration. Parenteral administration includes any route of administration that is not through the alimentary canal (that is, not enteral), including administration by injection, infusion and the like. Administration by injection includes, by way of example, into a vein (intravenous), an artery (intraarterial), a muscle (intramuscular) and under the skin (subcutaneous). The antigen binding molecule may also be administered in a depot or slow release formulation, for example, subcutaneously, intradermally or intramuscularly, in a dosage which is sufficient to obtain the desired pharmacological effect.
In one embodiment of the invention, the antigen binding molecule comprises a modified Fc region, more particularly a Fc region which has been modified to provide enhanced effector functions, such as enhanced binding affinity to Fc receptors, antibody-dependent cellular cytotoxicity (ADCC) and complement-dependent cytotoxicity (CDC). For the IgG class of antibodies, these effector functions are governed by engagement of the Fc region with a family of receptors referred to as the Fcγ receptors (FcγRs) which are expressed on a variety of immune cells. Formation of the Fc/FcγR complex recruits these cells to sites of bound antigen, typically resulting in signaling and subsequent immune responses. Methods for optimizing the binding affinity of the FcγRs to the antibody Fc region in order to enhance the effector functions, in particular to alter the ADCC and/or CDC activity relative to the “parent” Fc region, are well known to persons skilled in the art. By way of example only, procedures for the optimization of the binding affinity of a Fc region are described by Niwa et al.34 Lazar et al.35, Shields et al.36 and Desjarlais et al37. These methods can include modification of the Fc region of the antibody to enhance its interaction with relevant Fc receptors and increase its potential to facilitate antibody-dependent cell-mediated cytotoxicity (ADCC) and antibody-dependent cell-mediated phagocytosis (ADCP)34. Enhancements in ADCC activity have also been described following the modification of the oligosaccharide covalently attached to IgG1 antibodies at the conserved Asn297 in the Fc region35,36. Other methods include the use of cell lines which inherently produce antibodies with enhanced Fc effector function (e.g. Duck embryonic derived stem cells for the production of viral vaccines, WO/2008/129058; Recombinant protein production in avian EBX® cells, WO/2008/142124). Methods for enhancing CDC activity can include isotype chimerism, in which portions of IgG3 subclass are introduced into corresponding regions of IgG1 subclass (e.g. Recombinant antibody composition, US2007148165).
In another aspect, the present invention provides the use of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function in, or in the manufacture of a medicament for, the inhibition of leukemic stem cells expressing IL-3Rα (CD123), wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In this aspect, the invention also provides the use of an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function in, or in the manufacture of a medicament for, the treatment of a hematologic cancer condition in a patient, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
In yet another aspect, the invention provides an agent for inhibition of leukemic stem cells expressing IL-3Rα (CD123), which comprises an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to the IL-3Rα (CD123).
In this aspect, the invention also provides an agent for the treatment of a hematologic cancer condition in a patient, which comprises an antigen binding molecule comprising a Fc region or a modified Fc region having enhanced Fc effector function, wherein said antigen binding molecule binds selectively to IL-3Rα (CD123).
The agent of this aspect of the invention may be a pharmaceutical composition comprising the antigen binding molecule together with one or more pharmaceutically acceptable excipients and/or diluents.
Compositions suitable for parenteral administration conveniently comprise a sterile aqueous preparation of the active component which is preferably isotonic with the blood of the recipient. This aqueous preparation may be formulated according to known methods using suitable dispersing or wetting agents and suspending agents. The sterile injectable preparation may also be a sterile injectable solution or suspension in a non-toxic parenterally-acceptable diluent or solvent, for example as a solution in polyethylene glycol and lactic acid. Among the acceptable vehicles and solvents that may be employed are water, Ringer's solution, suitable carbohydrates (e.g. sucrose, maltose, trehalose, glucose) and isotonic sodium chloride solution. In addition, sterile, fixed oils are conveniently employed as a solvent or suspending medium. For this purpose, any bland fixed oil may be employed including synthetic mono- or di-glycerides. In addition, fatty acids such as oleic acid find use in the preparation of injectables.
The formulation of such therapeutic compositions is well known to persons skilled in this field. Suitable pharmaceutically acceptable carriers and/or diluents include any and all conventional solvents, dispersion media, fillers, solid carriers, aqueous solutions, coatings, antibacterial and antifungal agents, isotonic and absorption delaying agents, and the like. The use of such media and agents for pharmaceutically active substances is well known in the art, and it is described, by way of example, in Remington's Pharmaceutical Sciences, 18th Edition, Mack Publishing Company, Pennsylvania, USA. Except insofar as any conventional media or agent is incompatible with the active ingredient, use thereof in the pharmaceutical compositions of the present invention is contemplated. Supplementary active ingredients can also be incorporated into the compositions.
Throughout this specification and the claims which follow, unless the context requires otherwise, the word “comprise”, and or variations such as “comprises” or “comprising”, will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps.
The reference in this specification to any prior publication (or information derived from it), or to any matter which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that that prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of Endeavour to which this specification relates.
The present invention is further illustrated by the following non-limiting Examples:
This Example demonstrates the ability of MAb 7G3 to exploit the overt differences in CD123 expression and function between AML-LSCs and HSCs. MAb 7G3 inhibits the IL-3 signaling pathway and proliferation of primary AML cells. In addition, the homing and engraftment of AML blasts in the NOD/SCID xenograft model is profoundly reduced by MAb 7G3, and LSC function is inhibited.
Apheresis product, bone marrow or peripheral blood samples were obtained from newly diagnosed and relapsed patients with AML. Patient samples were collected after informed consent according to institutional guidelines and studies were approved by the Royal Adelaide Hospital Human Ethics Committee, Melbourne Health Human Research Ethics Committee, Research Ethics Board of the University Health Network, and the South Eastern Sydney & Illawarra Area Health Service Human Research Ethics Committee. Diagnosis was made using cytomorphology, cytogenetics, leukocyte antigen expression and evaluated according to the French-American-British (FAB) classification. Mononuclear cells were enriched by Lymphoprep or Ficoll density gradient separation and frozen in liquid nitrogen. Human cord blood and BM cells were obtained from full-term deliveries or consenting patients receiving hip replacement surgery or commercially from Cambrex (US), respectively, and processed as previously described38.
AML cell growth responses to IL-3 or GM-CSF were measured by [3H]-thymidine assay as previously described39. Briefly, 2×104 mononuclear cells per well in 96 well plates were stimulated with IL-3 (1 nM) or GM-CSF (0.1 nM) in the presence of 0.001-10 nM 7G3 or isotype-matched control BM4 (IgG2a) in 200 μl IMDM+10% Heat Inactivated Fetal Calf Serum (HI-FCS) (Hyclone, Utah) for 48 hours at 37° C., 5% CO2 with 0.5 μCi of 3H-thymidine (MP Biomedicals, NSW, Australia) added for the last 6 hours of culture. Cells were deposited onto glass fiber paper using a Packard Filtermate cell harvester (Perkin Elmer, Victoria, Australia) and counted using a Top Count (Perkin Elmer). All cytokines and antibodies were obtained commercially (R&D Systems, Minneapolis, Minn.) or supplied by CSL Limited (Melbourne, Australia).
Phosphorylation of signaling proteins was detected by immunoprecipitation and immunoblots. TF-1 cells and AML MNC cells were washed and rendered quiescent in IMDM medium with 0.5% HI-FCS (Hyclone, Utah) or with 0.5% human albumin (CSL, Melbourne, Australia) in the absence of growth factors for 18 hours. One hundred million cells were incubated with IgG2a (100 nM), 9F5, 6H6 (non-blocking anti-CD123 antibodies), or 7G3 (0.0001-100 nM) for 30 min on ice, and then stimulated with 50 ng/mL IL-3 for 15 min at 37° C. Cells were lysed in NP-40 lysis buffer40 and human βc (CD131) was immunoprecipitated using 1C1 and 8E4 antibodies conjugated to Sepharose beads. Immunoprecipitates were subjected to SDS-PAGE and immunoblotting as previously described41. Antibodies used to probe the immunoblots were: 4G10, antiphosphotyrosine MAbs (Upstate Biotech, Lake Placid, N.Y.); anti-phospho-Akt Ser473 (Cell Signaling, Beverly, Mass.); and anti-phosphorylated signal transducer and activator of transcription 5 (STAT-5) MAb (Zymed, San Francisco, Calif.). All antibodies were used according to manufacturer's instructions. Signals were developed using enhanced chemiluminescence (ECL; Amersham Pharmacia or West Dura from Pierce).
STAT-5 activation was also detected by intracellular FACS on leukemic cell lines M07e and TF1, and primary AML cells. Cells were incubated in MEDM plus 10% FCS and 10 ng/mL of huIL-3 (CSL, Melbourne, Australia) for 60 minutes, and fixed with BD Cytofix™ Buffer (Becton-Dickinson) followed by methanol permeabilization. Cells were then stained with anti-phosphoSTAT-5 (Becton-Dickinson) and analyzed using a FACSCalibur (Becton-Dickinson) instrument.
Thawed AML or normal hematopoietic cells were incubated with control IgG2a or 7G3 (10 μg/mL) for 2 hours in X-VIVO 10 (Cambrex BioScience) supplemented with 15-20% BIT (StemCell Technologies, Vancouver, BC Canada)) at 3T C before intravenous transplantation into sub-lethally irradiated NOD/SCID mice for repopulating assays (see below). Engraftment was measured at 4-10 weeks at 2 different time points.
For in vivo testing, control IgG2a or 7G3 (300-500 μg per injection) were injected intraperitoneally (i.p.) into mice 3 times a week with schedules described in the legends to each figure. To investigate possible synergistic effects of 7G3 with cytarabine (Ara-C), 35 days post-transplantation, 500 μg of antibodies were injected once a day for 3 consecutive days followed by i.p. injection of Ara-C at 40 mg/kg/d for 5 consecutive days. Antibody treatments resumed at 500 μg per injection 3 times a week for another 4 weeks following which engraftment was measured 3 days after the last injection of antibody.
Xenotransplantion of Human Cells into NOD/SCID Mice
Animal studies were performed under the institutional guidelines approved by the University Health Network/Princess Margaret Hospital Animal Care Committee or the Animal Care and Ethics Committee of the University of New South Wales. Transplantation of human cells into NOD/SCID mice was performed as previously described38. Briefly, all mice received sublethal irradiation (250-350 cGy) 24 hours before intravenous (i.v.) or intrafemoral transplantation with 5-10 million human cells per mouse. Anti-CD122 antibody was purified from the hybridoma cell line TM-β1 (generously provided by Prof. T. Tanaka, Hyogo University of Health Sciences)42 and 200 μg was injected i.p. into mice immediately after irradiation for natural killer cell depletion as previously described43. Similarly, 8 million normal bone marrow cells, or 1 million sorted CD34+ normal bone marrow cells, or 3×105 lineage depleted CD34+ normal cord blood cells were transplanted i.v. per mouse. Engraftment levels of human AML and normal hematopoietic cells in the murine bone marrow, peripheral blood, liver and spleen were evaluated based on the percentage of hCD45+ cells by flow cytometry. To measure 7G3 effects on LSC activity, secondary transplantations were also performed by i.v. transplantation of identical numbers of human cells (9 million cells/mouse) isolated from the bone marrow of previously engrafted mice in the IgG2a or 7G3 treatment groups.
Identical numbers of human cells from primary patient samples or harvested from engrafted mice were injected i.v. into sublethally irradiated NOD/SCID mice. Sixteen-twenty-four hours after injection, mononucleated cells from bone marrow, spleen, and peripheral blood of the recipient mice were analyzed by flow cytometry for human cells using 5×104-1×105 collected events. Homing efficiency of human cells into the mouse tissues was determined by measuring the % of the injected cells found in specific organs, calculated by the formula: % of huCD45+ cells assessed in the tissue×total number of cells in the specific tissue/total number of injected human cells×10044-46.
Cells from the bone marrow, spleen, liver and peripheral blood of treated mice were stained with fluorescein isothiocyanate (FITC)-conjugated antimurine and phycoerythrin-cyanin 5 (PC5, Beckman-Coulter) or allophycocyanin (APC, BioLegend and Becton-Dickinson) conjugated anti-human antibodies, as previously described2. CD123 expression was measured with phycoerythrin (PE) conjugated anti-human CD123 antibody (clone 9F5). 7G3 binding on human cells recovered from 7G3 treated mice was measured by staining duplicate samples with 9F5-PE or 7G3-PE, since the two clones bind to completely separate epitopes and produce similar levels of fluorescence on untreated primary cells (data not shown). The level of 7G3 binding was calculated by the formula: [(RFI of 9F5-PE detected CD123)−(RFI of 7G3-PE detected CD123)]÷(RFI of 9F5-PE detected CD123)×100. Immunophenotype and stem cell population were identified using a range of anti-human antibodies: anti-CD15-FITC, anti-CD14 conjugated to PE, anti-CD19-PE, anti-CD33-PE, anti-CD34-FITC or anti-CD34-PC5, and anti-CD38-PE or PE-Cyanine 7 (all antibodies from Becton-Dickinson unless otherwise stated). Isotype control antibodies were used to exclude 99.9% of negative cells, and cells were analyzed using FACScan or FACS Calibur flow cytometers (Becton-Dickinson).
Data are presented as the mean±s.e.m. The significance of the differences between groups was determined by using Student's t-test.
The monoclonal antibody 7G3, raised against the IL-3Receptor a subunit (IL-3Rα, CD123), has previously been shown to inhibit IL-3 binding to CD123 as well as IL-3-mediated effects in vitro, including proliferation of a leukemic cell line (TF-1), histamine release from human basophils, and endothelial cell activation33. Consistent with these findings it has now been found that MAb 7G3 inhibited intracellular signaling in TF-1 cells and primary human AML cells. Stimulation of growth factor-deprived TF-1 cells with IL-3 (1 nM) resulted in tyrosine phosphorylation of the receptor β subunit (CD131), and activation of the STAT-5 and Akt downstream signaling molecules that play a role in cell proliferation and survival (
CD123 (IL-3Receptor α Chain) is Co-Expressed with CD131 (Receptor β Chain) on AML Leukemic Stem Cells
Overexpression of CD123 on CD34+/CD38− cells from AML patients has been widely reported17-21 and has been proposed as a marker of leukemic CD34+/CD38− stem cells (LSCs) in some studies24,25. In the current study, CD123 expression on multiple AML samples was measured independently at 2 different laboratories. CD123 expression on AML CD34+/CD38− cells (RFI 67.7±24.2, n=9) was significantly higher than that on normal hematopoietic CD34+/CD38− cells (RFI 17.1±8.6, n=4, P=0.21, (data summarized in Table 1 below), consistent with other reports17-21,24,25. This overexpression appeared to be selective, in that the GM-CSF receptor α chain (CD116) was not expressed in the equivalent population in AML samples as measured by flow cytometry. Instead, the GM-CSF receptor α chain was abundantly expressed on CD34− blast cells (data not shown). Furthermore, flow cytometry and PCR analyses demonstrated that CD34+ cells that express CD123 also express CD131 (data not shown) suggesting that signal transduction occurs through the classical heterdimeric IL-3Receptor and not through CD123 alone, which is also supported by the CD131 phosphorylation data (
The ability of 7G3 to inhibit IL-3-induced proliferation was investigated using 38 primary AML patient samples. Representative plots for 3 primary samples are shown in
Pretreatment with 7G3 Inhibits AML but not Normal Hematopoietic Cell Engraftment in NOD/SCID Mice
To assess the effects of 7G3 on the ability of normal and malignant cells to repopulate in immune-deficient mice, primary AML and normal bone marrow (NBM) or umbilical cord blood (CB) cells were incubated ex vivo with 7G3 or irrelevant IgG2a (10 μg/mL, 2 h) and transplanted into sub-lethally irradiated NOD/SCID mice. Ex vivo 7G3 incubation markedly reduced the engraftment of 9/10 primary AML samples whose controls showed evidence of bone marrow engraftment at 4-8 weeks post-inoculation (mean 89.7±1.9% reduction relative to controls, P=0.013,
Ex vivo 7G3 treatment inhibited to a similar extent the engraftment of AML-8 harvested at both diagnosis and relapse, indicating that both diagnosis and relapse samples may have comparable sensitivity to 7G3 treatment. AML-5 was the only AML sample in which engraftment was not reduced by ex vivo 7G3 treatment, which could be attributed to this sample exhibiting a high proportion of LSC (CD34+/CD38−) and the lowest CD123 expression of all the AML samples evaluated (Table 1). Overall, these results demonstrate the reduced sensitivity of normal hematopoietic stem cells to 7G3 treatment in comparison with AML LSC.
The reduction in AML engraftment caused by ex vivo 7G3 treatment was also associated with improved survival. Mice transplanted with IgG2a or 7G3 treated AML-9 cells exhibited median survival of 11.5 and 24 weeks, respectively (P=0.0188, n=10 for each group,
The inhibitory effect of ex vivo 7G3 treatment on engraftment of AML or normal hematopoietic cells was inversely associated with the intensity of CD123 expression on the CD34+/CD38− population, with a significant relationship (
To determine the effects of 7G3 on the ability of intravenously-inoculated AML cells to home to the bone marrow and spleen, ex vivo-treated AML-8-rel and AML-9 cells were transplanted and mice were euthanased and examined 24 h later. 7G3 significantly diminished homing to the bone marrow to between 46-93% compared with isotype-treated controls (P<0.05), while homing to the spleen was reduced to 35 to 90% of control but the difference was not statistically significant (P>0.05) (
To further characterize the effects of 7G3 on AML homing to the bone marrow, AML-8-rel cells were exposed to 7G3 or isotype control antibodies, and subsequently transplanted via the tail-vein (IV) or directly into the right femur (RF), and the animals euthanased 5 weeks thereafter.
To determine whether 7G3 treatment of NOD/SCID mice affected AML cell engraftment, mice were administered a single intraperitoneal injection of 7G3 or isotype control antibodies (300 μg) followed by IV transplantation of AML-1 cells 6 hours later. 7G3 treatment almost completely ablated engraftment in the bone marrow, to 1.3±0.9% of control at 5 weeks post-transplantation (P=0.0006, n=5,
The efficacy of 7G3 in controlling the progression of AML in NOD/SCID mice was also examined by initiating treatments either 24 h or 4 days post-transplantation, presumably allowing the SL-IC to home to the bone marrow microenvironment before commencement of treatments44-46. When treatment was initiated 24 hours post-transplantation, engraftment was reduced in 2/3 AML samples. With this treatment regimen of 4 doses administered every other day, engraftment of AML-2 and -3 was reduced to 41.1±27.1% (P=0.096) and 39.6±10.0% (P=0.026) of controls, respectively, while engraftment of AML-1 was not affected (
Despite the relatively modest effects of 7G3 in both post-transplantation treatment regimens, 7G3 coating on AML cells harvested from the mouse bone marrow was clearly evident (data not shown). Moreover, 7G3 treatment decreased CD123 expression on AML-1 cells in any treatment regimen tested. For illustration, 7G3 treatment commencing 4 days post-transplantation decreased CD123 expression of AML-1 harvested from the BM to 51.3±4.0% of control (
While the primary aim of this study was to test the effect of targeting CD123 on AML stem cells, the ability of 7G3 to exhibit any single agent therapeutic activity on established leukemic disease, above and beyond its effects on leukemic stem cell engraftment was evaluated by initiating continuous 7G3 or control IgG2a treatments 28 days post-transplantation in an established disease model, and continuing treatment until the time of sacrifice. There was variation in response to 7G3 treatment in this model between patient samples likely reflective of the heterogeneity of AML seen clinically. A significant reduction in the BM burden of AML was seen in 2 of 5 samples (shown in
The serial transplantation experiments address an important question for all cancer stem cell (CSC)-directed therapies and provide evidence that the CSC is actually being targeted in vivo. In the case of AML, it is known that when AML-LSCs repopulate primary NOD/SCID mice they must self-renew3; self-renewal is a key property of all stem cells and is best assessed by secondary transplantation.
To examine whether 7G3 can also be used to target the LSC with self-renewal ability as an adjuvant to conventional therapy, which targets the more rapidly proliferating AML blasts, 7G3 or IgG2a were combined with cytarabine (Ara-C) and their effect on SL-IC and leukemic burden determined. At 35 days post transplantation with AML-10 cells, mice were treated with 7G3 or IgG2a control (500 μg/d) each day for 3 days followed by Ara-C (40 mg/kg/d) for 5 consecutive days. Following the Ara-C treatments, 7G3 was administered for another 4 weeks. Leukemic engraftment in the bone marrow and spleen of the mice treated with 7G3 and Ara-C was not decreased compared to mice treated with IgG2a and Ara-C (
To establish whether 7G3 can act as a single agent, serial transplantation was performed following in vivo 7G3 treatment in the absence of Ara-C. As shown in
Collectively, combining data from all 3 independent experiments depicted in
NK cells, macrophages, neutrophils and dendritic cells are among the effector cells in the immune system that facilitate Fc-dependent, antibody-dependent cellular cytotoxicity (ADCC). Their contribution to the ability of 7G3 to inhibit engraftment of AML was assessed by injecting a monoclonal antibody against murine IL-2R β-chain (IL-2Rβ) also known as CD122 to irradiated NOD/SCID mice before leukemic cell transplantation of ex vivo 7G3-treated AML cells. IL-2Rβ is widely expressed on NK cells, T cells, and macrophages and blocking IL-2Rβ by mAb can improve the engraftment of human hematopoietic cells in the NOD/SCID xenotransplant system.
At 4 weeks post-transplantation, leukemic engraftment in the NK cell depleted mice transplanted with AML-8-rel cells treated ex vivo with IgG2a control was increased to 113.3±2.8% (P=0.023) of non-depleted mice (
c9.9
c27.4
c51.7
c52.4
c20
c86
a FAB criteria
b The engraftment of 7G3 treated cells is expressed as mean engraftment in the 7G3 ex vivo incubated j group as a percentage of the mean engraftment level in IgG2a incubated group based on FIG. 1.
cSample had very low CD34 expression or number of CD34+ cells
The consistent overexpression of CD123 on AML blasts and LSCs provides a promising therapeutic target for the treatment of AML either alone or in combination with established therapies, especially for relapse or minimal residual disease. Several therapeutics based on CD123 have been devised and have demonstrated anti-AML effects in various assays23,47-49. In the current study, 7G3 has been demonstrated to specifically and consistently inhibit IL-3 mediated signaling pathways and subsequent induced proliferation of different AML samples in vitro. Moreover, 7G3 treatment profoundly reduced AML-LSC engraftment and improved mouse survival. Mice with pre-established disease showed reduced AML burden in the BM and periphery and impaired secondary transplantation upon treatment establishing that AML-LSCs in treated mice were directly targeted. These results provide clear validation for therapeutic anti-CD123 monoclonal antibody targeting of AML-LSCs, and for translation of in vivo preclinical research findings towards a potential clinical application.
CSL360 is a chimeric antibody obtained by grafting the light variable and heavy variable regions of the mouse monoclonal antibody 7G3 onto a human IgG1 constant region. Like 7G3, CSL360 binds to CD123 (human IL-3Rα) with high affinity, competes with IL-3 for binding to the receptor and blocks its biological activities.33 The mostly human chimeric antibody CSL360, can thus potentially also be used to target and eliminate AML LSC cells. CSL360 also has the advantage of potential utility as a human therapeutic agent by virtue of its human IgG1 Fc region which would be able to initiate effector activity in a human setting Moreover, it is likely that in humans it would show reduced clearance relative to the mouse 7G3 equivalent and be less likely to be immunogenic. The mechanisms of action of CSL360 in treatment of CD123 expressing leukemias may involve 1) inhibition of IL-3 signalling by blocking IL-3 from binding to its receptor, 2) recruitment of complement after the antibody has bound to a target cell and cause complement-dependent cytotoxicity (CDC), or 3) recruitment of effector cells after the antibody has bound to a target cell and cause antibody dependent cell cytotoxicity (ADCC).
Methods developed to study antibody dependent cell cytotoxicity (ADCC) are described below, and can be categorised into methods which analyse (1) target cell population or (2) effector cell population in the assay. Methods involved with analysis of target cells measure target cell lysis or early apoptosis of target cells brought about by ADCC. Methods that examine the effector population measure induction of membrane granules on effector cells such as NK cells as a marker for NK cell-induced cell lysis.
The murine lymphoid cell line CTL-EN engineered to express CD123 as described by Jenkins et al50 or freshly thawed leukemic cells (5×106) were incubated with 250 μCi of 51Cr-sodium chromate for one hour at 37° C. Cells were washed three times with RPMI-10% FCS medium to remove any free 51Cr-sodium chromate. Chromium labelled target cells were dispensed at 10,000 cells/well in round bottom 96-well plates. CSL360 or an isotype control antibody, (MonoRho, recombinant anti-Rhesus D human immunoglobulin G1), was added at 10 μg/mL.
Freshly isolated PBMC were added as effector cells at different ratios in triplicates and incubated for four hours at 37° C. in a 5% CO2 incubator. Total sample volume was 200 μL/well. After the incubation period, plates were centrifuged for 5 minutes at 600×g, 100 μL of supernatant removed and 51Cr released measured in a Wallace γ-counter.
Specific lysis was determined by using the formula, % lysis=100×[(mean cpm with antibody-mean spontaneous cpm)/(mean maximum cpm−mean spontaneous cpm)]. Spontaneous release was obtained from samples that had target cells with no antibody and no effector cells. Maximum release was determined from target cells treated with 1% (v/v) Triton X-100.
ADCC induced by CSL360 was measured by the method described by Neri et al52. This method involved labelling of target cells with Calcein AM instead of 51Chromium. Target cells were incubated with 10 μM Calcein AM (Invitrogen, cat. no. C3099) for 30 minutes at 37° C. in a 5% CO2 incubator. Labelled cells were washed to remove any free Calcein AM and then dispensed in round bottom plates at 5000 cells per well. Effector cells were added at different ratios. Relevant antibodies were added to a final concentration of 10 μg/mL, cells with no antibody serving as negative controls. Plates were incubated for 4 hours at 37° C. in a 5% CO2 incubator. After the incubation period, plates were centrifuged at 600×g for 5 minutes. 100 μL of supernatant was removed and fluorescence measured in an Envision microplate reader (excitation filter 485 nm, emission filter 535 nm). Specific lysis was calculated by using the formula, % lysis=100×[(mean fluorescence with antibody-mean spontaneous fluorescence)/(mean maximum fluorescence−mean spontaneous fluorescence)]. Maximum fluorescence was determined by the lysis of cells with 3% Extran and spontaneous lysis was the fluorescence obtained with target cells without any antibody or effector cells.
Fischer et al51 demonstrated that expression levels of CD107a, a membrane-associated lytic granule protein, by NK cells correlates with target cell cytotoxicity. This method was used to assess ADCC activity of CSL360. The method involved incubation of freshly isolated human PBMC from a buffy coat with target cells. Target cells used were either CD123-expressing cell lines or primary human AML cells. Target cells were added to human PBMC at 1:1 ratio in presence or absence of antibody. Nonspecific or spontaneous expression of CD107a was assessed with human PBMC without any antibody or target cells added. PE-Cy5 conjugated CD107a monoclonal antibody (BD Pharmingen, cat. no. 555802) was added to all samples and cells were incubated for three hours at 37° C. in a 5% CO2 incubator. After the first hour of incubation, Brefeldin A (BFA) was added. At the end of incubation, cells were washed and stained with anti-CD56-PE (BD Pharmingen, cat. no. 347747) and anti-CD16-FITC (BD Pharmingen, cat. no. 555406) monoclonal antibodies. Cells were then analysed by flow cytometry using a FACS Calibur and analysed (Flow Jo Software Tree Star, Inc.) for CD56dimCD16+CD107a cells that represent NK cells expressing FcRγIIIA receptor that have expressed the membrane associated lytic granule protein.
Total uptake of 51Chromium by CTLEN cells were between 2000-1500 cpm as compared to only about 400-200 cpm by AML cells as determined by maximum chromium release with detergent lysis. 15% lysis of AML (SL) cells was observed with CSL360 at 100:1 ratio of effector to target cells compared to 1.9% lysis with negative control antibody, MonoRho. 51% lysis of CTLEN cells was observed with CSL360 at 100:1 ratio of effector to target cells compared to 5% lysis with negative control antibody MonoRho (Table 2). These results suggested that CTLEN cells were more susceptible to CSL360-mediated ADCC lysis than the AML cells even though AML cells had higher levels of surface expression of CD123.
Data generated in a similar way as above from a number of cell lines engineered to express human CD123 (CTLEN, EL4) or human leukemic cell line expressing endogenous CD123 (TF-1) and primary samples from leukemic patients as target cells incubated with effector cells derived from up to 3 different donors are included in Table 3. The data are expressed as percentages of NK cells that expressed CD 107a incubated with different samples in presence of CSL360 or without added antibody. Two mouse cell lines expressing human CD123 induced CD107a expression in NK cells in presence of CSL360. 4/8 primary leukemic samples demonstrated CSL360-mediated expression of CD107a on NK cells. RMH007 induced expression of CD107a in NK cells even in absence of CSL360. RBH013 gave similar results with PBMC from one donor, however, with a different donor CD107a expression was specific to CSL360 indicating donor-specific susceptibility to NK-mediated ADCC induced by CSL360 in this case.
Six of the eight primary leukemic samples were examined for ADCC effects with different donors as a source for effector cells. An important observation was that samples that were susceptible to ADCC usually induced CD107a in effector cells irrespective of the donor. Similarly, samples that were resistant to ADCC also generally remained negative irrespective of donor cells.
Calcein released in the medium by lysed cells is an indicator of ADCC-mediated cell lysis. Patients RMH003 and RMH008 showed susceptibility to ADCC in this assay whereas RMH009, RMH010 and RBH013 appeared resistant to lysis (Table 4). All of these five patients were tested for their susceptibility to CSL360-mediated ADCC in a NK cell CD107a expression assay with same effector cells as used for this assay and comparative results are shown in Table 5. Status of ADCC in three out of six patients samples were in agreement with the two different assays.
a,b,c indicate that samples were tested for ADCC with different donors asa source for effector cells.
51Chromium
a These samples were tested for ADCC using CD107a and Calcein release assays with same effector cells for both assays.
Through the use of several assays all acknowledged to measure ADCC activity, albeit with varying sensitivity, it has been shown that CSL360 can induce ADCC responses in mouse cell lines maintained in culture that express ectopic human CD123. Importantly, CSL360 also was able to induce an ADCC response against primary human AML patient samples in the presence of functional effector cells from normal donors. This data suggests that in some leukemic patients whose leukemic cells including LSC, express sufficient levels of CD123 that CSL360 administered therapeutically may be able to induce ADCC-directed elimination of the leukemic cells particularly if the patients retained some functional effector cells in their circulation, for example such as those in remission or with minimal residual disease.
The ubiquitous expression of CD123 on AML cells including LSC and the evidence implicating IL-3 having an important role in the etiology of AML suggested that the ability to block IL-3Rα function would be critical for any therapeutic activity of an antibody targeting IL-3Rα such as 7G3. In this example, it is demonstrated somewhat surprisingly, that the ability of 7G3 to inhibit the engraftment or repopulation of NOD/SCID mice by AML patient samples is at least partially dependent upon the effector function responses elicited by the Fc domain of 7G3. Also, other IL-3Rα antibodies that do not significantly inhibit IL-3Rα function also block engraftment and hence demonstrate therapeutic activity in the NOD/SCID mouse model of AML.
F(ab)′2 fragments for 6H6, 9F5 and 7G3 were derived by pepsin cleavage using immobilised pepsin-agarose (22.5U pepsin agarose/mg antibody) incubated with antibody at 37° C. for 2 hr. Digestion was quenched by pH adjustment using 3M Tris to 6.5. Immobilised beads were separated from resultant F(ab)′2 by centrifugation.
F(ab)′2 of 7G3 was purified from residual immuunoglobulin and other contaminants using tandem chromatographic procedures: thiophilic adsorption chromatography (20-0% ammonium sulphate gradient in 40 mM HEPES over 15 column volumes) and anion exchange chromatography. 9F5 F(ab)′2 and 6H6 F(ab)′2 were purified by ion exchange chromatography followed by affinity chromatography. Endotoxin levels were quantitated by LAL chromogenic assay. Where endotoxin levels were >10EU/mL, Detoxigel was used to reduce endotoxin levels. 7G3 F(ab)′2 as expected, retained CD123-neutralising activity as assessed by the IL-3-dependent TF-1 proliferation assay (data not shown).
Peripheral blood cells were collected from 3 newly diagnosed patients after informed consent was obtained. AML patients were diagnosed and classified according to the French-American-British (FAB) criteria. AML-8-rel was originally classified as M4 at first diagnosis, AML-9 was classified as M5a, and AML-10 was unclassified. AML blasts were isolated by Ficoll density gradient centrifugation and frozen in aliquots in liquid nitrogen.
Monoclonal antibodies against IL-3 receptor α chain (CD123), 7G3, 9F5, 6H6 and their F(ab)′2 fragments, were used to treat the cells harvested from AML patients. IgG2a was used in parallel as a control. Thawed AML cells were seeded in XVIVO10 plus 15% BIT and independently incubated with antibodies at the concentration of 10 μg/mL. After 2 hours of incubation at 37° C., harvested leukemic cells were intravenously injected into sub-lethally irradiated NOD/SCID mice for repopulating assays.
Xenotransplantion of Human Cells into NOD/SCID Mice
Xenotransplantion was performed essentially performed as outlined in Example 1. NOD/SCID mice were bred and housed at the Animal facility of the University Health Network/Princess Margaret Hospital. Animal studies were performed under the institutional guidelines approved by the University Health Network/Princess Margaret Hospital Animal Care Committee. Transplantation of leukemic cells into NOD/SCID mice was performed as previously described3. Briefly, all mice in the same experiment were irradiated at the same time with the dose of 300cGy before being injected with an equal number of human cells. For intravenous transplantation, 5 mice were used for each group with injection of 5-10 million leukemic cells per mouse. Engraftment levels of human AML were evaluated based on the percentage of CD45+ cells by flow cytometry of the murine bone marrow.
Cells from the bone marrow of treated mice were stained with mouse antibody specific to human CD45 (anti-CD45) conjugated to APC (Beckman-Coulter), anti-CD34 conjugated to fluorescein isothiocyanate (FITC), and anti-CD38-PC5 (Becton-Dickinson). Isotypic controls were used to avoid false positive cells. Anti-CD123-PE (clone 9F5 and 7G3, Becton-Dickinson) was used to test the expression of IL-3 receptor α chain on the AML cells. Stained cells were analyzed using Caliber (Becton-Dickinson).
Data are presented as the mean±s.e.m. The significance of the differences between treated groups was determined by p value using Student's t-test. Results were considered statistically significant at P<0.05.
The data in Example 1,
The contribution of the Fc domain for the effects of 7G3 for inhibition of homing was assessed by testing F(ab)′2 fragments of both 7G3 and 6H6. Antibody F(ab)′2 fragments lack the Fc effector immunoglobulin domain and are not able to elicit ADCC or CDC responses.
The experiment was then extended to evaluate the contribution of IL-3Rα neutralisation and effector activity for the inhibition of engraftment of AML cells into the bone marrow of recipient mice. Two AML patient samples were treated ex vivo with the various intact antibodies and antibody fragments at a concentration of 10 μg/mL at 37° C. for 2 hours. Following incubation, cells were centrifuged to remove unbound antibodies and transplanted to sub-lethally irradiated NOD/SCID mice. The engraftment levels of human AML were analyzed by assessing the percentage of huCD45 positive cells in the bone marrow of the mice 4 weeks post-transplantation. As shown in
Taken together, these results indicate that in addition to the ability of 7G3 to neutralise IL-3Rα function, that the Fc domain of 7G3 is also important for inhibition of the homing and engraftment capacities of AML cells. Without the Fc domain, antibodies against CD123 significantly lose their capacity to inhibit homing, lodgement, and repopulation of AML-LSCs in NOD/SCID mice.
A number of methods have been described for increasing the effector function activity of antibodies. These methods can include amino acid modification of the Fc region of the antibody to enhance its interaction with relevant Fc receptors and increase its potential to facilitate antibody-dependent cell-mediated cytotoxicity (ADCC) and antibody-dependent cell-mediated phagocytosis (ADCP)34,35. Enhancements in ADCC activity have also been described following the modification of the oligosaccharide covalently attached to IgG1 antibodies at the conserved Asn297 in the Fc region34. In a further study36 the expression of human IgG1 antibodies in Lec13 cells, a variant Chinese hamster ovary cell line which is deficient in its ability to add fucose to an otherwise normal oligosaccharide, resulted in a fucose-deficient antibody with up to 50-fold improved binding to human FcγRIIIA and improved ADCC activity.
Alternative approaches to producing defucosylated antibodies have also been described through culturing antibody-expressing cells in the presence of certain glycosidase inhibitors53. In this study, CHO cells expressing antibodies of interest were cultured in the presence of kifunensine, a potent α-mannosidase I inhibitor, which resulted in secretion of IgGs with oligomannose-type glycans that do not contain fucose. These antibodies exhibited increased affinity for FcR and enhanced ADCC activity.
In this example, generation and testing of CSL360 variants with enhanced ADCC activity through Fc-engineering or defucosylation is described.
The genes for both the light and heavy chain variable region of the murine anti-CD123 antibody 7G3 were cloned from total 7G3.1B8 hybridoma RNA isolated using the NucleoSpin RNA II kit (BD Bioscience) according to the manufacturer's instructions. First-strand cDNA was synthesized using the SMART RACE Amplification kit (Clontech) and the variable regions amplified by RACE-PCR using proof-reading DNA polymerase, Plantinum® Pfx DNA polymerase (Invitrogen). The primers used for the variable heavy region were UPM (Universal Primer A mix, DB Bioscience) and MH2a (5′AATAACCCTTGACCAGGCATCCTA3′ (SEQ ID NO: 1)). Similarly, the variable light region was amplified using UPM and MK (5′CTGAGGCACCTCCAGATGTTAACT3′ SEQ ID NO: 2)). Using standard molecular biology techniques, the heavy chain variable region was cloned into either; a) the mammalian expression vector pcDNA3.1(+)-hIgG1, which is based on the pcDNA3.1(+) expression vector (Invitrogen) modified to include the human IgG1 constant region or, b) pcDNA3.1(+)-hIgG1S239D/A330L/I332E, or c) pcDNA3.1(+)-hIgG1S239D/I332E. The vectors used in b) and c) encode for protein that incorporate amino acid mutations which are reported to result in an antibody with significantly improved ADCC activity35. These mutations were introduced using QuikChange mutagenesis techniques (Stratagene). The light chain variable region was cloned into the expression vector pcDNA3.1(+)-hκ, which is based on the pcDNA3.1(+) expression vector modified to include the human kappa constant region.
FreeStyle™ 293-F cells were obtained from Invitrogen. Cells were cultured in FreeStyle™ Expression Medium (Invitrogen) supplemented with penicillin/streptomycin/fungizone reagent (Invitrogen). Prior to transfection the cells were maintained at 37° C. with an atmosphere of 8% CO2.
Transient transfections of the expression plasmids using FreeStyle™ 293-F cells were performed using 293fectin transfection reagent (Invitrogen) according to the manufacturer's instructions. The light and heavy chain expression vectors were combined and co-transfected into the FreeStyle™ 293-F cells. Cells (1000 ml) were transfected at a final concentration of 1×106 viable cells/mL and incubated in a Cellbag 2 L (Wave Biotech/GE Healthcare) for 5 days at 37° C. with an atmosphere of 8% CO2 on a 2/10 Wave Bioreactor system 2/10 or 20/50 (Wave Biotech/GE Healthcare). Pluronic® F-68 (Invitrogen), to a final concentration of 0.1% v/v, was added 4 hours post-transfection. 24 hours post-transfection the cell cultures were supplemented with Tryptone N1 (Organotechnie, France) to a final concentration of 0.5% v/v. The cell culture supernatants were then harvested by filtration through a Millistak+POD filter (Millipore) prior to purification.
For production of defucosylated antibodies where indicated kifunensine (Toronto Research Chemicals) was added to the culture medium of transiently transfected FreeStyle™ 293-F cells (24 hours post transfection) to a final concentration of 0.5 μg/mL as described53.
After 5 days 20 μl of culture supernatant was electrophoresed on a 4-20% Tris-Glycine SDS polyacrylamide gel and the antibody was visualised by staining with Coomassie Blue reagent.
In addition to the chimeric CSL360 described in Example 2, in this example the use of a humanised variant of CSL360 (hCSL360) is also described. This was produced by standard CDR grafting techniques where the murine CDR regions from 7G3 were grafted on suitable human variable framework regions54. The resulting humanised antibody contains entirely human framework sequence. As a result of the humanisation process, the MAb affinity for CD123 was moderately decreased (indicative KD's of 1.06 nM vs 12.8 nM for CSL360 and hCSL360 respectively) however, the binding specificity remained unchanged and the hCSL360 retained potent CD123-neutralisation activity as measured by IL-3-dependent TF-1 cell proliferation (indicative IC50's of 5 nM vs 19 nM for CSL360 and hCSL360 respectively). Affinity optimisation was employed using standard ribosome display-based mutagenesis55 to restore the binding affinity of hCSL360 to levels at least equivalent to the parent mouse MAb 7G3 and the chimeric CSL360. An affinity optimised MAb clone was produced (168-26) that exhibited comparable CD123 binding affinity and neutralisation of CD123 activity to the parent MAb (indicative KD of 0.6 nM for binding to CD123 and IL-3 neutralisation IC50 of 6 nM). Fc engineered derivatives of this clone containing the IgG1 Fc domains with the three amino acid substitutions S239D/A330L/I332E (168-26Fc3) or with the two amino acid substitutions S239D/I332E (168-26Fc2) were also produced as described above for hCSL360.
The unmodified chimeric CSL360, humanised variant (hCSL360) and the ADCC-optimised and humanised CSL360S239D/I332E (hCSL360Fc2) and CSL360S239D/A330L/I332E (hCSL360Fc3) and material derived from kifunensine-treated cells were purified using protein A affinity chromatography at 4° C., with MabSelect resin (5 ml, GE Healthcare, UK) packed into a 30 mL Poly-Prep empty column (Bio-Rad, CA). The resin was first washed with 10 column volumes of pyrogen free GIBCO Distilled Water (Invitrogen, CA) to remove storage ethanol and then equilibrated with 5 column volumes of pyrogen free phosphate buffered saline (PBS) (GIBCO PBS, Invitrogen, CA). The filtered conditioned cell culture media (1 L) was then loaded onto the resin by gravity feed. The resin was then washed with 5 column volumes of pyrogen free PBS to remove non-specific proteins. The bound antibody was eluted with 2 column volumes of 0.1M glycine pH 2.8 (Sigma, Mo.) into a fraction containing 0.2 column volumes of 2M Tris-HCl pH 8.0 (Sigma, Mo.) to neutralise the low pH. The eluted antibody was dialysed for 18 hrs at 4° C. in a 12 ml Slide-A-Lyzer cassette MW cutoff 3.5kD (Pierce, Ill.) against 5 L PBS. The antibody concentration was determined by measuring the absorbance at 280 nm using an Ultraspec 3000 (GE Healthcare, UK) spectrophotometer. The purity of the antibody was analysed by SDS-PAGE, where 2 μg protein in reducing Sample Buffer (Invitrogen, CA) was loaded onto a Novex 10-20% Tris Glycine Gel (Invitrogen, CA) and a constant voltage of 150V applied for 90 minutes in an XCell SureLock Mini-Cell (Invitrogen, CA) with Tris Glycine SDS running buffer before visualised using Coomassie Stain, as per the manufacturer's instructions.
To test the effector activity of the various variant antibodies the CD123-expressing CTLEN cell line was used as a target cell line and ADCC activity assessed using the calcein AM release assay as outlined in Example 2 in the presence of normal PBMC as a source of effecter cells.
Testing of CSL360, Fc-Engineered CSL360 Variants and Defucosylated CSL360 for Binding to Fc Receptors
As already mentioned, antibody Fc effector function is mediated through binding to Fc gamma receptors (FcγR) expressed on the various effector cells of the innate immune system37.
The relative affinities of the various human FcγR's for hCSL360, the Fc engineered variants hCSL360Fc2 and hCSL360Fc3 and defucosylated hCSL360 produced by kifunensine treatment (hCSL360kif) were measured with a BIAcore A100 biosensor. The various antibodies were individually captured on a CM5 BIAcore chip coupled with CD123. Soluble FcγR's (huFcγRI, huFcγRIIb/c and huFcγRIIIa (obtained from R & D Systems) at concentrations ranging from 0.3 nM to 800 nM were flowed over the respective surfaces and affinity measurements determined by fitting the data to kinetic and/or steady state models.
Recent studies have shown that rather than absolute affinities, a high activating/inhibitory (A/I) (FcγRIII:huFcγRIIb) ratio in IgG affinity is important for maximal antibody-mediated effector activity56.
These data confirm that, as expected, the various hCSL360 Fc enhanced variants exhibit increased affinities for FcγR's with greater effects for the activating versus inhibitory FcγR's.
It is shown here that Fc-engineered and defucosylated CSL360 variants demonstrate significantly increased affinities and A/I binding ratio's for FcRγ as well as improved ADCC effector activity in vitro. This result, taken together with the data provided in Examples 1 and 3 demonstrating an important role for effector function activity for therapeutic efficacy of anti-CD123 antibodies in mouse models of AML, strongly suggest that effector function enhanced variant anti-CD123 antibody therapeutics would likely demonstrate improved therapeutic activity for the treatment of AML and other CD123-positive leukemias in human patients.
In this example, the various Fc-enhanced antibodies were tested for enhanced ADCC activity against cell lines engineered to express CD123 as well as human leukemic cell lines that express native CD123. The Fc-enhanced MAb's were also tested using ex vivo ADCC assays against a panel of primary leukemia samples from AML and ALL patients.
ADCC was measured using a lactate dehydrogenase (LDH) release assay as described35. LDH is a stable cytosolic enzyme that is released upon cell lysis. LDH released in to the culture medium is measured using a colorimetric assay where LDH converts a specific substrate into a red coloured product. Lysis is measured as LDH released and is directly proportional to the colour formed. Target cells that express CD123 were incubated with varying amounts of anti-CD123 antibodies in the presence of NK cells used as effector cells for ADCC. NK cells were purified from a normal buffy pack using Miltenyi Biotec's NK Isolation Kit (Cat#130-092-657). Cells were incubated for a period of four hours at 37° C. in presence of 5% CO2. Target cells with no antibody or NK cells were used as spontaneous LDH release (background) controls and target cells lysed with lysis buffer were used as maximal lysis controls. LDH released into the culture media was measured using Promega's CytoTox 96® Non-Radioactive Cytotoxicity Assay Kit according to manufacturers instructions (Cat# G1780).
All other methods are as described in the previous Examples.
a shows a repeat of the above experiment this time using TF-1 human leukemic cells which naturally express CD123 as target cells. Once again the hCSL360Fc3 variant showed significantly improved ADCC with hCSL360Fc2 and hCSL360kif, although less potent, also demonstrating increased activity compared to Fc unoptimised hCSL360.
b compares in TF-1 cells the activity of the humanised and affinity optimised anti-CD123 antibody variant 168-26 and its Fc-enhanced derivatives 168-26Fc3 and 168-26Fc2. The data in this Figure demonstrate that Fc engineering improved ADCC activity of the humanised and affinity optimised 168-26 variant similarly to that seen with the humanised only variant (hCSL360).
Next, the activity for the various Fc-enhanced hCSL360 variants was compared against a panel of primary leukemic cell samples from 5 AML patients (
These data are consistent with the results depicted in Example 2 where CSL360 treatment induced modest ADCC activity in 4/6 AML samples and 0/2 ALL samples assessed by various ADCC methodologies.
The data in Example 5 demonstrate that Fc optimisation of the CD123 MAbs resulted in significant effector function responses against all primary leukemia samples tested in ex vivo assays and represents a significant improvement compared to Fc unoptimised anti-CD123 MAbs.
These findings with ALL tumors that express CD123 are consistent with the notion that other malignancies that express CD123 in addition to AML are also likely to be sensitive to anti-CD123 MAb therapeutics with enhanced Fc effector functions57-61.
The results described in Examples 4 and 5 indicate that CSL360 variants with enhanced Fc effector function exhibit increased ADCC activity in vitro against a panel of cell lines engineered to express CD123, human leukemic cell lines which naturally express CD123 and importantly also in ex vivo assays using primary leukemic samples taken from patients with AML or ALL. The ex vivo ADCC data against both AML and ALL patient primary samples is particularly important as testing in this ex vivo setting allows for some estimation of the potential for efficacy in a human disease setting.
In this example, the experiments are extended to test an Fc-engineered variant of CSL360 (168-26Fc3) for therapeutic efficacy in a NOD/SCID mouse xenograft model of human ALL. This is a preclinical model which has been demonstrated to accurately reflect ALL clinical disease and significantly correlates with patient outcome62. The clinical relevance of this model is well recognized and is currently an integral part of the National Cancer Institute initiative: the Pediatric Preclinical Testing Program63.
Human ALL leukemia cells (ALL-2) derived from a pediatric ALL patient were propagated by intravenous inoculation in female non-obese diabetic (NOD)/scid−/− mice as described previously62. This xenograft was derived from the third relapse of a 65 month old female diagnosed with common CD10+ B-cell precursor ALL. The patient has since died of her disease and this xenograft is resistant to conventional chemotherapy62. Mice were randomized into treatment and control groups of 6-7 mice each to give an approximately equal median leukemic burden in all groups at commencement of treatment. All mice were maintained under barrier conditions and experiments were conducted using protocols and conditions approved by the Committee and the Animal Care and Ethics Committee of the University of New South Wales. Percentages of human CD45-positive (hCD45+) cells were determined as previously described62.
The exact log-rank test, as implemented using GraphPad Prism 4.0a, was used to compare event-free survival distributions between treatment and control groups. P values were two-sided and were not adjusted for multiple comparisons given the exploratory nature of the studies.
Treatment commenced on day 34 post transplantation and mice received treatments of 300 μg per 100 μL of antibody dissolved in phosphate-buffered saline. Antibodies were administered by intraperitoneal injection given three times per week (every 2-3 days). Leukemic burden was monitored by weekly tail vein bleed of the mice. Treatment continued until event was reached and was defined as 25% hCD45+ burden in peripheral blood.
These data significantly extend those presented in the previous examples in that they demonstrate that anti-CD123 MAbs with enhanced Fc effector function have improved therapeutic efficacy in mice with pre-established leukemia compared to Fc-unmodified MAbs. Importantly, the use of a preclinically validated model of ALL that has been demonstrated to predict the course of human disease62 strongly supports that such Fc optimised anti CD123 MAbs may also exhibit improved clinical efficacy in leukemic patients.
38. Mazurier, F., Doedens, M., Gan, O. I. & Dick, J. E. Rapid myeloerythroid repopulation after intrafemoral transplantation of NOD-SCID mice reveals a new class of human stem cells. Nat Med. 9, 959-963 (2003).
50. Jenkins et al., A Cell Type-specific Constitutive Point Mutant of the Common-Subunit of the Human Granulocyte-Macrophage Colony-stimulating Factor (GM-CSF), Interleukin (IL)-3, and IL-5 Receptors Requires the GM-CSF Receptor-Subunit for Activation. J Biol Chem, 1999 274:13, 8669-8677)
57. Feuillard et al, Clinical and biologic features of CD4(+)CD56(+) malignancies Blood 2002 99(5):1556-63
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