Pharmacokinetics and tumor localization of (111)in-labeled HuCC49DeltaC(H)2 in BALB/c mice and athymic murine colon carcinoma xenograft.

The primary limitation of IgG antibodies for radioimmunotherapy of solid tumors is their prolonged serum half-life, leading to dose-limiting bone marrow toxicity at doses providing inadequate radiation to the tumor. A humanized C(H)2 domain-deleted variant of the anti-TAG-72 antibody CC49 (HuCC49DeltaC(H)2) has faster blood clearance, compared to the IgG, while retaining tumor targeting. We compared the pharmacokinetics and tumor uptake of (111)In-HuCC49DeltaC(H)2 in BALB/c mice and a colon carcinoma (LS-174T) mouse xenograft with that of (111)In-labeled chimeric CC49 (cCC49), an antibody with pharmacokinetics similar to the humanized CC49 parent.

Construction, affinity maturation, and biological characterization of an anti-tumor-associated glycoprotein-72 humanized antibody.

The tumor-associated glycoprotein (TAG)-72 is expressed in the majority of human adenocarcinomas but is rarely expressed in most normal tissues, which makes it a potential target for the diagnosis and therapy of a variety of human cancers. Here we describe the construction, affinity maturation, and biological characterization of an anti-TAG-72 humanized antibody with minimum potential immunogenicity. The humanized antibody was constructed by grafting only the specificity-determining residues (SDRs) within the complementarity-determining regions (CDRs) onto homologous human immunoglobulin germ line segments while retaining two mouse heavy chain framework residues that support the conformation of the CDRs.

SDR grafting--a new approach to antibody humanization.

A major impediment to the clinical utility of the murine monoclonal antibodies is their potential to elicit human anti-murine antibody (HAMA) response in patients. To circumvent this problem, murine antibodies have been genetically manipulated to progressively replace their murine content with the amino acid residues present in their human counterparts. To that end, murine antibodies have been humanized by grafting their complementarity determining regions (CDRs) onto the variable light (V(L)) and variable heavy (V(H)) frameworks of human immunoglobulin molecules, while retaining those murine framework residues deemed essential for the integrity of the antigen-combining site.

Minimizing the immunogenicity of antibodies for clinical application.

The clinical utility of murine monoclonal antibodies has been greatly limited by the human anti-murine antibody responses they effect in patients. To make them less immunogenic, murine antibodies have been genetically engineered to progressively replace their murine content with that of their human counterparts. This review describes the genetic approaches that have been used to humanize murine antibodies, including the generation of mouse-human chimeric antibodies, veneering of the mouse variable regions, and the grafting of murine complementarity-determining regions (CDRs) onto the variable light (VL) and variable heavy (VH) frameworks of human immunoglobulin molecules, while retaining only those murine framework residues deemed essential for the integrity of the antigen-binding site.

Inhibition of CD4(+)25+ T regulatory cell function implicated in enhanced immune response by low-dose cyclophosphamide.

Regulatory T cells (T(REGs)) control the key aspects of tolerance and play a role in the lack of antitumor immune responses. Cyclophosphamide (CY) is a chemotherapeutic agent with a dose-dependent, bimodal effect on the immune system. Although a previous study demonstrated that CY reduces the number of T(REGs), the mechanism involved in this process has yet to be defined.

SDR grafting of a murine antibody using multiple human germline templates to minimize its immunogenicity.

The humanization of mAbs by complementarity-determining region (CDR)-grafting has become a standard procedure to improve the clinical utility of xenogeneic Abs by reducing human anti-murine Ab (HAMA) responses elicited in patients. However, CDR-grafted humanized Abs may still evoke anti-V region responses when administered in patients. To minimize anti-V region responses, the Ab may be humanized by grafting onto the human templates only the specificity-determining residues (SDRs), the residues that are essential for the surface complementarity of the Ab and its ligand.

In vitro affinity maturation of a specificity-determining region-grafted humanized anticarcinoma antibody: isolation and characterization of minimally immunogenic high-affinity variants.

Purpose: HuCC49V10 (V10), a humanized anticarcinoma monoclonal antibody (Ab) CC49, was generated by grafting only the specificity-determining regions (SDRs) of CC49 onto the variable light and variable heavy frameworks of the human Abs LEN and 21/28'CL, respectively. SDRs are those residues of the complementarity-determining regions that are most critical for antigen (Ag) binding. Compared with HuCC49, which was developed by conventional complementarity-determining region grafting, V10 has lower reactivity to the sera from patients who were previously given murine CC49 in clinical trials, although its Ag-binding affinity is 2-3-fold lower than that of HuCC49.

Grafting of "abbreviated" complementarity-determining regions containing specificity-determining residues essential for ligand contact to engineer a less immunogenic humanized monoclonal antibody.

Murine mAb COL-1 reacts with carcinoembryonic Ag (CEA), expressed on a wide range of human carcinomas. In preclinical studies in animals and clinical trials in patients, murine COL-1 showed excellent tumor localization. To circumvent the problem of immunogenicity of the murine Ab in patients, a humanized COL-1 (HuCOL-1) was generated by grafting the complementarity-determining regions (CDRs) of COL-1 onto the frameworks of the variable light and variable heavy regions of human mAbs.

Surface plasmon resonance-based competition assay to assess the sera reactivity of variants of humanized antibodies.

While clinical trials are the only way to evaluate the immunogenicity, in patients, of murine or genetically engineered humanized variants of a potentially therapeutic or diagnostic monoclonal antibody (MAb), ethical and logistical considerations of clinical trials do not permit the evaluation of variants of a given MAb that are generated to minimize its immunogenicity. The most promising variant could be identified by comparing the reactivities of the parental antibody (Ab) and its variants to the sera of patients containing anti-variable region (anti-VR) Abs to the administered parental Ab. We have developed a surface plasmon resonance (SPR) biosensor-based assay to monitor the binding of the sera anti-VR Abs to the parental Ab and the inhibition of this binding by the variants.