The effect of circulating antigen on the biodistribution of the engineered human antibody hCTM01 in a nude mice model

Understanding Inter-Individual Variability in Monoclonal Antibody Disposition

Monoclonal antibodies (mAbs) are currently the largest and most dominant class of therapeutic proteins. Inter-individual variability has been observed for several mAbs; however, an understanding of the underlying mechanisms and factors contributing to inter-subject differences in mAb disposition is still lacking. In this review, we analyze the mechanisms of antibody disposition and the putative mechanistic determinants of inter-individual variability. Results from in vitro, preclinical, and clinical studies were reviewed evaluate the role of the neonatal Fc receptor and Fc gamma receptors (expression and polymorphism), target properties (expression, shedding, turnover, internalization, heterogeneity, polymorphism), and the influence of anti-drug antibodies. Particular attention is given to the influence of co-administered drugs and disease, and to the physiological relevance of covariates identified by population pharmacokinetic modeling, as determinants of variability in mAb pharmacokinetics.

A straightforward protocol for the preparation of high performance microarray displaying synthetic MUC1 glycopeptides

BACKGROUND

Human serum MUC1 peptide fragments bearing aberrant O-glycans are secreted from columnar epithelial cell surfaces and known as clinically important serum biomarkers for the epithelial carcinoma when a specific monoclonal antibody can probe disease-relevant epitopes. Despite the growing importance of MUC1 glycopeptides as biomarkers, the precise epitopes of most anti-MUC1 monoclonal antibodies remains unclear.

METHODS

A novel protocol for the fabrication of versatile microarray displaying peptide/glycopeptide library was investigated for the construction of highly sensitive and accurate epitope mapping assay of various anti-MUC1 antibodies.

RESULTS

Selective imine-coupling between aminooxy-functionalized methacrylic copolymer with phosphorylcholine unit and synthetic MUC1 glycopeptides-capped by a ketone linker at N-terminus provided a facile and seamless protocol for the preparation of glycopeptides microarray platform. It was demonstrated that anti-KL-6 monoclonal antibody shows an extremely specific and strong binding affinity toward MUC1 fragments carrying sialyl T antigen (Neu5Acα2,3Galβ1,3GalNAcα1→) at Pro-Asp-Thr-Arg motif when compared with other seven anti-MUC1 monoclonal antibodies such as VU-3D1, VU-12E1, VU-11E2, Ma552, VU-3C6, SM3, and DF3. The present microarray also uncovered the occurrence of IgG autoantibodies in healthy human sera that bind specifically with sialyl T antigen attached at five potential O-glycosylation sites of MUC1 tandem repeats.

CONCLUSION

We established a straightforward strategy toward the standardized microarray platform allowing highly sensitive and accurate epitope mapping analysis by reducing the background noise due to nonspecific protein adsorption.

GENERAL SIGNIFICANCE

The present approach would greatly accelerate the discovery research of new class autoantibodies as well as the development of therapeutic mAbs reacting specifically with disease-relevant epitopes.

Antibody-drug conjugates: using monoclonal antibodies for delivery of cytotoxic payloads to cancer cells

One approach to improving activity of anticancer drugs is to conjugate them to antibodies that recognize tumor-associated, cell-surface antigens. The antibody-drug conjugate concept evolved following major advances, first, in the development of humanized and fully human antibodies; second, in the discoveries of highly cytotoxic compounds ('drugs) linkable to antibodies; and finally, in the optimization of linkers that couple the drug to the antibody and provide sufficient stability of the antibody-drug conjugate in the circulation, optimal activation of the drug in the tumor, and the ability of the activated drug to overcome multidrug resistance. In this article, we will review the considerations for selecting a target antigen, the design of the conjugate, and the pre-clinical and clinical experiences with the current generation of antibody-drug conjugates.

Effect of immune complex formation on the distribution of a novel antibody to the ovarian tumor antigen CA125

3A5 is a novel antibody that binds repeated epitopes within CA125, an ovarian tumor antigen that is shed into the circulation. Binding to shed antigen may limit the effectiveness of therapeutic antibodies because of unproductive immune complex (IC) formation and/or altered antibody distribution. To evaluate this possibility, we characterized the impact of shed CA125 on the in vivo distribution of 3A5. In vitro, 3A5 and CA125 were found to form ICs in a concentration-dependent manner. This phenomenon was then evaluated in vivo using quantitative whole-body autoradiography to assess the tissue distribution of (125)I-3A5 in an orthotopic OVCAR-3 tumor mouse model at different stages of tumor burden. Low doses of 3A5 (75 μg/kg) and pathophysiological levels of shed CA125 led to the formation of ICs in vivo that were rapidly distributed to the liver. Under these conditions, increased clearance of 3A5 from normal tissues was observed in mice bearing CA125-expressing tumors. Of importance, despite IC formation, 3A5 uptake by tumors was sustained over time. At a therapeutically relevant dose of 3A5 (3.5 mg/kg), IC formation was undetectable and distribution to normal tissues followed that of blood. In contrast, increased levels of radioactivity were observed in the tumors. These data demonstrate that CA125 and 3A5 do form ICs in vivo and that the liver is involved in their uptake. However, at therapeutic doses of 3A5 and clinically relevant CA125 levels, IC formation consumes only a minor fraction of 3A5, and tumor targeting seems to be unaffected.

PH1-derived bivalent bibodies and trivalent tribodies bind differentially to shed and tumour cell-associated MUC1

Most adenocarcinomas express altered MUC1 as a tumour-associated antigen. Due to suboptimal glycosylation in tumour-associated MUC1, the apomucin core is exposed, revealing new epitopes for antibody-directed immunotherapy. The human PH1 Fab binds specifically to this MUC1 apomucin. We describe the engineering and functional characterization of bi- and trivalent recombinant antibody derivatives from the PH1 Fab. Bi- and tribodies were made using the disulfide-stabilized Fab fragment as a heterodimerization scaffold with PH1 single-chain variable fragments fused to either one or both Fab-chain C-termini. Immunoassays revealed 27- and 165-fold improved dissociation constants (K(D) = 30 and 5 nM) of the PH1 bi- and tribodies compared with the parental Fab (K(D) = 820 nM). Unexpectedly, major differences were seen in the ability of the antibody constructs to bind shed and tumour cell-tethered MUC1. While the tribody did not discriminate between both MUC1 forms, the bibody demonstrated preferential interaction with membrane-bound MUC1 compared with shed MUC1. This preferential recognition of membrane-bound MUC1, along with the high serum stability of the bibody, its intermediate size and efficient internalization by MUC1(+) cells, makes the human PH1-derived bibody a valuable candidate as a cancer-targeting therapeutic.

Characterization of antibodies to CA 125 that bind preferentially to the cell-associated form of the antigen

OBJECTIVE

Antibodies to CA 125 have been used to predict relapse of ovarian cancer, but have performed poorly as therapeutic agents. One rationale for this is antibody binding to circulating shed antigen. Our aim in this study was to develop antibodies to human CA 125 that have enhanced selectivity for the cell-associated form of the antigen.

METHODS

Monoclonal antibodies were raised to a recombinant fragment of CA 125 that included sequence proximal to the putative membrane attachment site. Antibodies were characterized in terms of their binding site, affinity and selectivity for cell-associated CA 125.

RESULTS

In assays using patient-derived CA 125, a subset of high-affinity (KD <5 nM) monoclonal antibodies demonstrated a 10- to greater than 200-fold increase in selectivity for cell-associated CA 125 when compared with controls. Based on mapping of the various monoclonal antibodies obtained, it was determined that shedding of CA 125 most likely occurs in the most C-terminal repeat domain.

CONCLUSION

Results from competition analysis using patient-derived shed antigen predict that the antibodies described in this study may have significantly enhanced tumor-targeting properties when compared with existing antibodies to CA 125 in a tumor environment having high concentrations (>10,000 CA 125 units) of shed CA 125.

Pharmacokinetics, Biodistribution, and Radioimmunotherapy with Monoclonal Antibody 776.1 in a Murine Model of Human Ovarian Cancer

776.1 is a murine IgG1 monoclonal antibody to the human ovarian cancer antigen CA 125 that has the unique property of having a clear preference for binding to the cell-associated form of the antigen. We have examined the tumor localization properties and efficacy of 776.1 in a subcutaneous OVCAR-3 xenograft mouse model of human ovarian cancer. Biodistribution experiments using (125)I-labeled 776.1 demonstrated a peak uptake in tumors at 72 hours postinjection, with an average of 17.7% of injected dose per gram localized to the tumor. Little uptake in other organs was observed. Further experiments using CA 125-transfected syngeneic tumors, as well as an immunoprecipitation assay using human chimeric 776.1, both clearly demonstrated that 776.1 localizes to the tumor in a CA 125-dependent manner. DOTA-776.1 (1,4,7,10-tetraazacyclododecane-N,N',N",N'" tetraacetic acid-conjugated 776.1) was labeled with (90)Y and used in efficacy studies. [(90)Y-DOTA]776.1 at a single dose of 150 microCi was able to mediate efficient reduction of tumor growth, with regression observed in a subset of animals for a period ranging from 3 to 48 days, equivalent to 3 weekly administrations of cisplatin at 6 mg/kg. No significant regression was observed in groups receiving [(90)Y-DOTA]MOPC-21 control antibody at any dose. These results suggest that 776.1 may be a promising radioimmunotherapeutic agent for the treatment of human ovarian cancer.

An anti-MUC1 antibody-calicheamicin conjugate for treatment of solid tumors. Choice of linker and overcoming drug resistance

The anti-MUC1 antibody, CTM01, has been chosen to target the potently cytotoxic calicheamicin antitumor antibiotics to solid tumors of epithelial origin that express this antigen. Earlier calicheamicin conjugates relied on the attachment of a hydrazide derivative to the oxidized carbohydrates that occur naturally on antibodies. This produced a "carbohydrate conjugate" capable of releasing active drug by hydrolysis in the lysosomes where the pH is low. Conjugates have now been made that are formed by reacting a calicheamicin derivative containing an activated ester with the lysines of antibodies. This gives an "amide conjugate" that is stable to hydrolysis, leaving the disulfide that is present in all calicheamicin conjugates as the only likely site of drug release from the conjugate. As previously shown for the carbohydrate conjugate, this amide conjugate of CTM01 produces complete regressions of xenograft tumors at doses of 300 microg/kg (calicheamicin equivalents) given three times. This indicates that hydrolytic drug release is not necessary for potent, selective cytotoxicity for calicheamicin conjugates of CTM01. Although the unconjugated calicheamicins are in general less active in cells expressing the multidrug resistance phenotype, both in vitro and in vivo results of studies reported here suggest that the efficacy of the calicheamicins toward such tumors is unexpectedly enhanced by antibody conjugation, especially for the "amide conjugate". These hydrolytically stable conjugates are also active toward cisplatin-resistant ovarian carcinoma cells as well. Such studies indicate that the calicheamicin amide conjugate of CTM01 may have potential for the treatment of MUC1-positive solid tumors, including some types of resistant tumors.

A Calicheamicin Conjugate with a Fully Humanized Anti-MUC1 Antibody Shows Potent Antitumor Effects in Breast and Ovarian Tumor Xenografts

Murine CTM01 is an internalizing murine IgG(1) monoclonal antibody that recognizes the MUC1 antigen expressed on many solid tumors of epithelial origin. Calicheamicin conjugates of this antibody have previously been shown to be potent, selective antitumor agents in preclinical models. A conjugate has now been made with a genetically engineered human version of this antibody, hCTM01. The hCTM01 is an IgG(4) isotype, has an immunoaffinity approximately 30% higher than mCTM01 by competitive RIA, and is efficiently internalized into target cells. The hCTM01-NAc-gamma calicheamicin DM amide conjugate, referred to as CMB-401, shows targeted killing of MUC1-expressing cells in vitro and produces pronounced dose-related antitumor effects over an 8-fold dose range against a MUC1-expressing, ovarian xenograft tumor, OvCar-3. The specificity of CMB-401 was confirmed by comparing its antitumor effects with those of an isotype-matched nonspecific conjugate against the MX-1 breast carcinoma. CMB-401, given either ip or iv, was highly active in these models in single and multiple dose regimens and gave complete regressions at the highest doses examined with good overall therapeutic ratios. CMB-401 also gave good antitumor effects at similar doses with a cisplatin-resistant MUC1-expressing cell line.

Tumour-targeted chemotherapy with immunoconjugates of calicheamicin

Antibody-targeted chemotherapy is a therapeutic strategy in cancer therapy that involves a monoclonal antibody specific for a tumour-associated antigen, covalently linked via a suitable linker to a potent cytotoxic agent. Tumour-targeted delivery of a cytotoxic agent in the form of an immunoconjugate is expected to improve its antitumour activity and safety. Calicheamicin is a cytotoxic natural product isolated from Micromonospora echinospora that is at least 1000-fold more potent than conventional cytotoxic chemotherapeutics. Calicheamicin binds DNA in the minor groove and causes double-strand DNA breaks, leading to cell death. Immunoconjugates of calicheamicin targeted against tumour-associated antigens exhibit tumour-specific cytotoxic effects and cause regression of established human tumour xenografts in nude mice. Gemtuzumab ozogamicin is the first clinically validated cytotoxic immunoconjugate in which a humanised anti-CD33 antibody is linked to a derivative of calicheamicin. Gemtuzumab ozogamicin is indicated for the treatment of elderly patients with relapsed acute myeloid leukaemia. A similar conjugate, inotuzumab ozogamicin, is being evaluated at present in Phase I clinical trials in patients with non-Hodgkin's lymphoma. A number of tumour-targeted immunoconjugates of calicheamicin are being explored preclinically at present for their therapeutic applications.

Radioimmunoscintigraphy in patients with ovarian cancer

The use of radiolabeled monoclonal antibodies (MoAbs) has significantly improved the ability to detect tumor antigens, thus improving in vivo tumor diagnosis and treatment. The management of ovarian carcinoma still poses a challenging medical problem. Clinical trials using radioimmunoscintigraphy or a hand-held gamma detection probe intraoperatively were performed in patients with clinical evidence of primary or recurrent ovarian cancer. Immunoscintigraphy of ovarian cancer lesions has been performed mainly with 99mTc, 111In and 123I labeled with HMFG1, HMFG2, OC-125, B72.3, H17E2, OVTL3, MoAb170, Mov18 and other MoAbs. Antibody guided imaging using radioimmunoscintigraphy has demonstrated improved targeting of ovarian cancer, resulting in a highly sensitive and specific method. However, it is not yet known which type of MoAb is the most efficient for radioimmunoscintigraphy. Since these tumors represent a potentially curable disease, radioimmunoscintigraphy could contribute mainly to accurate staging as a supplementary to conventional diagnostic methods, as well as for the localization of active disease after chemotherapy and monitoring for the presence of recurrent disease. Nevertheless, prospective studies in a large number of patients should be undertaken in order to further evaluate the diagnostic contribution of this approach.

An immunoscintigraphic evaluation of the engineered human monoclonal antibody (hCTMO1) for use in the treatment of ovarian carcinoma

OBJECTIVE

To assess the safety and targeting ability of the engineered human antibody (hCTMO1) in women with ovarian carcinoma.

DESIGN

The monoclonal antibody labelled with Indium-111 was administered to women with suspected primary or recurrent ovarian carcinoma six days pre-operatively. The first group of women was given a dose of 0.1 mg per kg body weight of radiolabelled antibody. A second group of women received 1 mg per kg body weight and finally a third group was given 1 mg per kg body weight of unlabelled antibody followed one hour later by 0.1 mg per kg body weight of radiolabelled antibody. All the women were then imaged using a gamma camera one hour and up to 96 hours after injection.

PARTICIPANTS

Fourty-four women in whom there was a high suspicion of primary ovarian carcinoma on the basis of ultrasound or CT imaging and serum CA125 and those in whom there was a suspicion of recurrent ovarian carcinoma after being treated for histologically confirmed carcinoma.

SETTING

The Queen's Medical Centre, Nottingham and University Hospital Vrije Universiteit, Amsterdam, The Netherlands.

RESULTS

At the low dose of antibody the sensitivity for detection of ovarian carcinoma was 70%. After increasing the dose of antibody and also after pre-dosing with unlabelled antibody the sensitivity increased to 100%, but there was a large number of false positive results at the higher dose, and therefore the specificity was low. The liver and bone marrow were the organs with the highest activities.

CONCLUSION

The genetically engineered antibody hCTMO1 is safe for use in women. This antibody effectively targets ovarian carcinoma and has greater potential as a vector for therapeutic use than as a diagnostic agent.