Lack of T-cell immunity in humans with preexisting anti-mouse immunoglobulin reactivity.

We have identified five normal individuals without known exposure to mouse immunoglobulin with "preexisting" human anti-mouse antibody (HAMA) against a panel of four mouse monoclonal antibodies and polyclonal mouse IgG. Competitive inhibition by polyclonal mouse IgG of HAMA binding to monoclonal antibody coated beads demonstrates the mouse constant region specificity of these sera. Lack of such inhibition by polyclonal human IgG eliminates polyclonal rheumatoid factors as an explanation. Lymphoblastic transformation studies in these five persons failed to demonstrate a memory T-cell response to the four mouse monoclonals or polyclonal mouse IgG. Positive controls included T-cell responses to streptolysin O in these five individuals as well as responses to monoclonal antibody D612 in three patients following treatment with that antibody. This lack of T-cell immunity to mouse IgG suggests that "preexisting" HAMA is the product of inadvertent cross-reactivity with murine constant region by antibodies directed against other antigens. Therefore, "preexisting" HAMA should pose no risk of anamnestic or allergic response in patients considered for murine monoclonal therapy.     

Development of a dual label fluorescence technique that can be utilized to elucidate the mechanism of action of monoclonal antibody-drug conjugates

A method is described that allows the simultaneous visualization and relative assessment of both the antibody and drug components of monoclonal antibody-drug conjugates at the target cell membrane. The antibody is detected by a fluorescein-conjugated anti-mouse immunoglobulin serum while the drug is visualized by rhodamine avidin or phycoerythrin-streptavidin binding to a biotinylated anti-Vinca alkaloid monoclonal antibody. This technique was effective in demonstrating the cell surface localization of a monoclonal antibody-Vinca alkaloid conjugate to human lung adenocarcinoma cells grown in vitro and was also used to demonstrate targeting of the conjugate in vivo to the membranes of these same tumor cells grown as a nude mouse xenograft. This method was also utilized to help elucidate the mechanism of action of monoclonal antibody-drug conjugates.     

Therapy of chronic lymphocytic leukemia and cutaneous T-cell lymphoma with T101 monoclonal antibody

The findings accompanying the administration of 50 intravenous courses of monoclonal antibody to human T-cell (T101) in eight patients, four with chronic lymphocytic leukemia and four with cutaneous T-cell lymphoma are reported. Infusion rates of 0.7 to 1 mg/min were associated with unacceptable toxicity in the presence of circulating target cells, but slower rates were well-tolerated. Immunofluorescence techniques confirmed that circulating cells did bind the antibody in vivo and were subsequently removed from the circulation. Modulation of the antigen on target cells in the bone marrow and skin has important implications for the schedule of administration of such antibodies, and points out the possible limitation of effector cell-mediated cytotoxicity at the tissue level. Production of anti-mouse antibodies resulted in neutralization of therapy in two patients with cutaneous T-cell lymphoma, and suggests that whether such an anti-mouse response is produced may be secondary to the underlying immune status of the patient or the amount of mouse protein to which immunocompetent cells are exposed. The relative specificity and efficacy of monoclonal antibody therapy is encouraging, but the limited clinical benefit and problems of modulation and anti-mouse antibody production underscore the need for continued research into passive therapy and suggest that cytotoxic conjugates may be of more clinical value.     

Effects of humanization and gene shuffling on immunogenicity and antigen binding of anti-TAG-72 single-chain Fvs.

One major constraint in the clinical application of murine monoclonal antibodies (MAbs) is the development of a human antimurine antibody response. The immunogenicity of MAbs can be minimized by replacing nonhuman regions with corresponding human sequences. The studies reported in our article were undertaken to analyze the immunoreactivity and the immunogenicity of the CC49 single-chain antibody fragments (scFvs): (i) an scFv construct comprised of mouse CC49 VL and VH (m/m scFv), (ii) a light chain shuffled scFv with human VL (Hum4 VL) and mouse CC49 VH (h/m scFv), and (iii) a humanized scFv assembled from Hum4 VL and CC49 VH complementary determining regions (CDRs) grafted onto a VH framework of MAb 21/28' CL (h/CDR scFv). The CC49 scFvs competed for an antigen binding site with CC49 IgG in a similar fashion in a competition radioimmunoassay and were able to inhibit the binding of CC49 IgG to the antigen completely. The immunogenicity of CC49 scFvs was tested using sera with antiidiotypic antibodies to MAb CC49 obtained from patients treated by CC49 IgG in clinical trials. All tested sera exhibited the highest reactivity to the m/m scFv. However, the sera demonstrated differential reactivities to h/CDR scFv and h/m scFv. Replacement of the mouse chain in h/m scFv and h/CDR scFv decreased or completely averted serum reactivity. Our studies compared for the first time the antigen binding and immunogenicity of different scFv constructs containing the mouse, CDR grafted or human variable chains. These results indicate that the humanized CC49 scFv is potentially an important agent for imaging and therapeutic applications with TAG-72-positive tumors.     

Pharmacokinetics of internally labeled monoclonal antibodies as a gold standard: comparison of biodistribution of 75Se-, 111In-, and 125I-labeled monoclonal antibodies in osteogenic sarcoma xenografts in nude mice

In order to know the true biodistribution of anti-tumor monoclonal antibodies, three monoclonal antibodies (OST6, OST7, and OST15) against human osteosarcoma and control antibody were internally labeled with 75Se by incubating [75Se]methionine and hybridoma cells. 75Se-labeled monoclonal antibodies were evaluated both in vitro and in vivo using the human osteogenic sarcoma cell line KT005, and the results were compared with those of 125I- and 111In-labeled antibodies. 75Se-, 125I- and 111In-labeled monoclonal antibodies had identical binding activities to KT005 cells, and the immunoreactivity was in the decreasing order of OST6, OST7, and OST15. On the contrary, in vivo tumor uptake (% injected dose/g) of 75Se- and 125I-labeled antibodies assessed using nude mice bearing human osteosarcoma KT005 was in the order of OST7, OST6, and OST15. In the case of 111In, the order was OST6, OST7, and OST15. High liver uptake was similarly seen with 75Se- and 111In-labeled antibodies, whereas 125I-labeled antibodies showed the lowest tumor and liver uptake. These data indicate that tumor targeting of antibody conjugates are not always predictable from cell binding studies due to the difference of blood clearance of labeled antibodies. Furthermore, biodistribution of both 111In- and 125I-labeled antibodies are not identical with internally labeled antibody. Admitting that internally labeled antibody is a "gold standard" of biodistribution of monoclonal antibody, high liver uptake of 111In-radiolabeled antibodies may be inherent to antibodies. Little, if any, increase in tumor-to-normal tissue ratios of antibody conjugates will be expected compared to those of 111In-labeled antibodies if stably coupled conjugates are administered i.v.     

Development of humoral immune responses against a macrocyclic chelating agent (DOTA) in cancer patients receiving radioimmunoconjugates for imaging and therapy.

The development of stable immunoconjugates by the advent of macrocyclic metal chelating agents (DOTA) has enabled us to study the ability of 111In-DOTA-labeled monoclonal antibodies to detect tumor lesions in a pilot radioimmunolocalization study, as well as to evaluate the kinetics, toxicity, and efficacy of i.p. administered 90Y-DOTA-labeled murine monoclonal antibody in a Phase I/II clinical trial of advanced ovarian cancer. The development of serum sickness-like reactions in three of six treated patients, in the absence of previous monoclonal antibody administration, led us to study the potential immunogenicity of the new chelate. Six patients with ovarian cancer received 25 mg of HMFG1 monoclonal antibody coupled with 90Y-DOTA (doses of radioactivity, 15 to 25 mCi), administered i.p. Eight patients with various malignant tumors received low doses (220 micrograms to 1 mg) of monoclonal antibodies, labeled with 111In-DOTA, i.v. for imaging studies. Using a solid-phase enzyme-linked immunosorbent assay method, the immunogenicity of DOTA was evaluated. Serial dilutions of patients' sera, before and after imaging or therapy with DOTA-coupled monoclonal antibodies, as well as sera from patients who did not receive DOTA-coupled antibody, were screened on enzyme-linked immunosorbent assay plates coated with human serum albumin (HSA), HSA-2-iminothiolane, and HSA-2-iminothiolane-benzyl-DOTA. All patients treated with i.p. monoclonal antibody developed anti-DOTA antibodies. Four of eight patients who received i.v. "imaging" doses of DOTA-coupled monoclonal antibody developed antibodies against DOTA. The levels of anti-DOTA response correlated with the amount of injected radioimmunoconjugate (r = 0.889, P less than 0.001). None of the patients who received DOTA-coupled antibody had detectable antibodies against the macrocycle before immunoconjugate administration. We then addressed further the restriction of the immune response against the macrocycle. We found that there was no or very low response against the aromatic ring attached to DOTA. Most, if not all, of the immune response is directed against the DOTA ring structure. Affinity purification of anti-DOTA antibody from serum enabled quantitation of these antibodies in the serum of patients. An inverse, statistically significant correlation was observed between the percentage of binding inhibition of a patient's serum to DOTA, by HSA-2-iminothiolane-DOTA (100 micrograms/ml) and the level of anti-DOTA immunoglobulin in the serum.(ABSTRACT TRUNCATED AT 400 WORDS)     

Tumour localisation with a radioactively labelled reshaped human monoclonal antibody

A genetically reshaped human IgG1 monoclonal antibody (Hu2PLAP) with anti-tumour specificity, was radiolabelled with Indium-111 by chelation with a new macrocyclic compound (DOTA) which allows the production of stable radioimmunoconjugates for in vivo application. This was used to image seven patients with malignant disease, of whom two had been previously exposed to mouse monoclonal antibodies and had developed human anti-mouse antibodies (HAMA). Successful tumour localisation was seen in the four patients with active disease and antigen positive tumours. No patient showed any antibody responses against Hu2PLAP, but three out of six patients tested showed an immune response against the macrocycle DOTA. Reshaped human monoclonal antibodies with anti-tumour specificity may facilitate repeated administrations of radioactive antibodies, thus allowing new possibilities, both in the diagnosis and treatment of cancer.     

Locoregional treatment of low-grade B-cell lymphoma with CD3xCD19 bispecific antibodies and CD28 costimulation. I. Clinical phase I evaluation

We describe the first clinical application of T-cell-recruiting bispecific antibodies directly into the tumor without the need to preactivate the effector cells. In a Phase I clinical trial, 10 patients with low-grade B-cell lymphoma were treated by a single locoregional injection of CD3xCD19 bispecific antibodies. Costimulatory signaling, which is required for the optimal activation of resting T cells, was provided by the simultaneous administration of CD28 antibodies. Equal amounts of both antibodies were injected together at 4 different dose levels (30 microg: 3 patients; 270 microg: 3 patients; 810 microg: 3 patients; 1,600 microg: 1 patient). The injection was well tolerated with mild to moderate adverse effects (2/10 patients) consisting of erythema and fever at the third dose level. The maximum tolerated dose was not reached at 810 microg of injected antibodies. Three patients showed a serum peak of TNFalpha on day 2 or 3 after the antibody application, reflecting rather an activation of CD4-positive T cells than an FcR-mediated effect. Five patients developed anti-mouse antibodies after injection of the murine immunoglobulins. Nine patients were evaluable for restaging examinations 6 weeks after the antibody application, with 2 of them (22%) showing a local clinical response. We found that a single locoregional injection of CD3xCD19+CD28 antibodies is feasible up to a dose of at least 1,600 microg of each antibody. However, the development of human anti-mouse antibodies points toward the requirement for new formats of bispecific proteins with reduced immunogenicity.     

Anti-Tac-H, a humanized antibody to the interleukin 2 receptor with new features for immunotherapy in malignant and immune disorders

The Mr 55,000 interleukin 2 receptor peptide (Tac; CD25) is not expressed by normal resting T-cells but is markedly up-regulated in adult T-cell leukemia and other malignancies, as well as on T-cells activated in normal immune, autoimmune, allograft, and graft-versus-host settings. Anti-Tac is a mouse monoclonal antibody directed against the Tac peptide. Our prior attempts to use this antibody in humans for antitumor therapy and immune regulation have been limited by weak recruitment of effector functions and neutralization by antibodies to mouse immunoglobulins. To circumvent these difficulties, we prepared several chimeric "humanized" anti-Tac antibodies by genetic engineering, including one "hyperchimeric" antibody (anti-Tac-II) in which the molecule is human except for the small hypervariable segments of the complementarity-determining regions retained from the mouse antibody. These constructs maintain high affinities for antigen and abilities to block T-cell activation and demonstrate new capabilities to perform antibody-dependent cell-mediated cytotoxicity, absent in the mouse anti-Tac. Hence, humanized antibodies have been developed to a tumor-associated antigen and activated T-cell marker with significant features that offer new therapeutic possibilities for select neoplastic and immune disorders.     

The Spatial Distribution of Parenterally Administered Monoclonal Antibodies Against Cea in A Human Colorectal Tumour Xenograft

A recently developed experimental model consisting of athymic rats carrying human colonic tumours from the cell line LS 174 T in both hind legs was used. ¹²⁵I-labelled anti-carcinoem-bryonic (anti-CEA) monoclonal antibodies were injected either intra-arterially after a bolus injection of mannitol, or intra-perito-neally with or without mannitol. On the fourth day the rats were killed and pieces from the tumours and various organs were measured in a well scintillation counter. Tumour pieces were then submitted to autoradiography and immunohistochemistry for examination of the antibody distribution at the cellular level. In all examined tumours injected with anti-CEA antibodies, most of the antibodies were located in the periphery close to fibrovascular septa. It appears, in addition to the specificity of the antibody for the CEA, that the tumour vascular permeability and anatomy are of utmost importance for tumour targeting in this experimental model with the particular antibody used.     

Antitumor immune response and interleukin 2 production induced in colorectal cancer patients by immunization with human monoclonal anti-idiotypic antibody

The immunogenicity of human anti-idiotypic antibody has been investigated using a human monoclonal anti-idiotypic antibody (105AD7) which interacts with the binding site of 791T/36, a mouse monoclonal antibody against gp72 antigen. This antigen is frequently expressed in gastrointestinal cancer, therefore, six patients with advanced colorectal cancer have been immunized with 105AD7 as an aluminum hydroxide gel precipitate in a phase I clinical study. Cryopreserved blood mononuclear cells were tested for in vitro proliferative responses by [3H]thymidine incorporation; plasma samples were tested by enzyme-linked immunosorbent assay for anti-anti-idiotypic and antitumor antibodies, and for interleukin 2. Proliferative responses to gp72 positive tumor cells were seen in four of five patients tested; parallel in vitro responses to 105AD7 anti-idiotypic antibody were seen in most of these patients. Interleukin 2 was detected in the plasma of four of six patients after 105AD7 immunization, with peak levels up to 7 units/ml. No toxicity related to anti-idiotype immunization and no antitumor or anti-anti-idiotype antibodies were seen. This study shows that human monoclonal anti-idiotype 105AD7 is immunogenic in cancer patients, inducing cellular antitumor responses and interleukin 2 production. This suggests that human monoclonal anti-idiotype antibodies may have considerable potential for immunotherapy of human cancer.     

Treatment of high-risk neuroblastoma with anti-GD2 antibodies

Anticancer monoclonal antibodies (mAbs) targeting specific antigens on the tumour surface are increasingly being applied in cancer treatment. Potential advantages include long half-life, low toxicity, high affinity and specificity. In order to develop novel immune therapies for high-risk cancers, finding tumour targets that are not widely shared by normal cells is a goal. GD2-disialoganglioside is one of them. It is expressed on the surface of a variety of tumours with no curative therapies for patients with advanced disease. In childhood, neuroblastoma is the most common GD2-expressing tumour. Because of this tumour-selective expression, it is an attractive target for tumour-specific therapies such as antibody therapy. Over the last two decades, several anti-GD2 antibodies have been developed. To reduce both toxicity and development of human anti-mouse antibodies (HAMA), research efforts have primarily focused on exploring anti-GD2 antibodies that substitute mouse components by human ones. This review will examine antibodies currently undergoing clinical testing as well as the most recent advances to improve antibody therapy for patients with high-risk neuroblastoma.     

Immune function of patients with gastrointestinal carcinoma after treatment with multiple infusions of monoclonal antibody 17.1A

Ten patients with metastatic adenocarcinomas of the colon or pancreas were treated with multiple injections of monoclonal antibody 17.1A. For each injection, antibody concentration in the patients' sera plateaued during the entire treatment course, and then decreased, with faster antibody clearance in patients given previous injections of mouse monoclonal antibodies for immunoscintigraphy. Six of the ten patients were able to generate anti-mouse antibodies, detectable 7 days after the initial infusion. Peripheral blood mononuclear cells from patients showed only low level ability to mediate spontaneous and antibody-dependent cytotoxicity in vitro, both before monoclonal antibody treatment and during the entire treatment period. Undiluted sera from these patients were unable to generate antibody-dependent cytotoxicity activity in vitro at any time during the observation period.     

Peptide-antibody conjugates for tumour therapy: A MHC-class-II-restricted tetanus toxin peptide coupled to an anti-IG light chain antibody can induce cytotoxic lysis of a human B-cell lymphoma by specific CD4 T cells

Anti-idiotype antibody therapy of B-cell lymphomas, despite numerous promising experimental and clinical studies, has so far met with limited success. Tailor-made monoclonal anti-idiotype antibodies have been injected into a large series of lymphoma patients, with a few impressive complete tumour remissions but a large majority of negative responses. The results presented here suggest that, by coupling to anti-lymphoma idiotype antibodies a few molecules of the tetanus toxin universal epitope peptide P2 (830–843), one could markedly increase the efficiency of this therapy. We show that after 2-hr incubation with conjugates consisting of the tetanus toxin peptide P2 coupled by an S-S bridge to monoclonal antibodies directed to the X light chain of human immunoglobulin, human B-lymphoma cells can be specifically lysed by a CD4 T-lymphocyte clone specific for the P2 peptide. Antibody without peptide did not induce B-cell killing by the CD4 T-lymphocyte clone. The free cystein-peptide was also able to induce lysis of the B-lymphoma target by the T-lymphocyte clone, but at a molar concentration 500 to 1000 times higher than that of the coupled peptide. Proliferation assays confirmed that the antibody-peptide conjugate was antigenically active at a much lower concentration than the free peptide. They also showed that antibody-peptide conjugates required an intact processing function of the B cell for peptide presentation, which could be selectively inhibited by leupeptin and chloroquine. It is reasonable to expect that, in vivo, the anti-idiotype antibodies will selectively transport the tetanus toxin peptides to the B-lymphoma cells, which will process the conjugates and present the peptides to the patients' CD4 T-cell repertoire. Our tetanus-toxoid-vaccinated population has T cells specific for the immunogenic peptide and these, in principle, could be further expanded prior to injection of the conjugate.     

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. To minimize the anti-idiotypic responses that could still be evoked by the murine CDRs in humanized antibodies, two approaches have also been described. These are based on grafting onto the human frameworks the 'abbreviated' CDRs or only the specificity-determining residues (SDRs), the CDR residues that are involved in antigen interaction. The SDRs are identified through the help of the database of three-dimensional structures of antibody:antigen complexes or by mutational analysis of the antibody-combining site. In addition, we also describe the use of in vitro affinity maturation to enhance the binding affinity of humanized antibodies, as well as the manipulation of framework residues to maximize their human content and minimize their immunogenic potential.     

Reduction of immunogenicity by covalent modification of murine and rabbit immunoglobulins with oxidized dextrans of low molecular weight.

This communication describes the covalent modification of monoclonal and polyclonal antibodies with oxidized dextrans of low molecular weight to generate conjugates having low immunogenicity in vivo. Conjugation conditions were optimized to generate monomeric, dextran-modified antibodies, free of both high-molecular-weight polymeric aggregates and unmodified antibodies. Conjugates could be prepared with varying levels of dextran substitution. These conjugates retained optimal immunoreactivity as well as in vivo pharmacokinetics and tumor-localization properties. In addition, multiple i.v. administrations of dextran-modified antibodies in animals did not elicit a measurable immune response to either the antibody or the dextran portion of these conjugates.     

Monoclonal Antibodies in the Treatment of Malignancy: Basic Concepts and Recent Developments

Antibodies have long been considered to be potential anticancer agents because of their specificity for cell-membrane antigens. Applications of hybridoma and recombinant DNA technology have led to the production of unlimited quantities of clinical-grade murine, chimeric, and humanized monoclonal antibodies for clinical use. Whole antibodies may produce anticancer effects in conjunction with the immune system by interaction with complement proteins and/or effector cells via the Fc portion of the antibody molecule. Antibodies may also neutralize circulating ligands or block cell membrane receptors and thus interrupt ligand/receptor interactions and signal transduction that are associated with proliferative or anti-apoptotic effects. The anti-idiotype network cascade provides a rationale for antibodies as vaccine therapy. Antibodies may also serve as the guiding or targeting system for other cytotoxic pharmaceutical products such as (i) radiolabeled antibodies for radioimmunodetection and radioimmunotherapy; (ii) immunotoxins; (iii) chemotherapy/antibody conjugates; (iv) cytokine/antibody conjugates; and (v) immune cell/antibody conjugates. After years of anticipation, as of late 1999 there were four monoclonal antibodies that had been approved by the U.S. Food and Drug Administration based on activity against human malignancy, all of which are in widespread clinical use. Several other products are in various stages of clinical trial testing. Monoclonal antibodies have joined interferon-alpha, interleukin-2 (IL-2), and various hematopoietic growth factors as well-established components of biological therapy, the fourth modality of cancer treatment.     

BAT monoclonal antibody immunotherapy of human metastatic colorectal carcinoma in mice

BAT monoclonal antibody exhibited anti-tumor activity mediated by T and NK cells. We have evaluated the efficacy of murine and humanized BAT for the treatment of human colorectal carcinoma liver metastases in nude mice. HM7, a human colorectal carcinoma was injected into the spleen to colonize the liver. A single intravenous administration of both BAT antibodies significantly reduced the number of metastases and liver weights. Histological examinations demonstrated lymphocyte accumulation near remnant tumors and in tumor-free tissues of BAT treated mice. The efficacy of humanized BAT in the regression of hepatic metastases in human colorectal carcinoma has potential clinical use.     

Phase I evaluation of humanized OKT3: toxicity and immunomodulatory effects of hOKT3gamma4

Murine anti-CD3 (OKT3, Muromonab-CD3) is a potent human T-lymphocyte mitogen. A previous clinical Phase I trial examined OKT3 as an immunomodulator for the treatment of cancer. However, the murine monoclonal antibody triggered a potent humoral response that neutralized the antibody activity during subsequent administration. Thus, a "humanized" form of OKT3 (hOKT3gamma4) was developed to minimize immunogenicity. The genetically engineered human anti-CD3 retained its binding activity and effectively activated T cells in vitro. Therefore, we evaluated the safety and activity of hOKT3gamma4 in a Phase I clinical trial. hOKT3gamma4 was administered as a 10-min i.v. infusion every 2 weeks for three injections (one course of therapy). Six dose levels ranging from 50 to 1600 microg/injection were evaluated. Headache and fever were common, transient toxicities but were not dose limiting. The dose-limiting toxicities were rigors and dyspnea at the 1600-microg dose level, which defined 800 microg as the maximally tolerated dose in this trial. A dose-dependent in vivo T-lymphocyte activation was produced by this treatment, and the most significant T-lymphocyte activation occurred in patients treated at the two highest dose levels (800 and 1600 microg). Persistent CD3 modulation occurred after administration of 1600 microg of hOKT3gamma4. Anti-idiotypic antibodies were detected in only 6 of 24 patients after multiple injections and were not associated with attenuation of T-lymphocyte activation. Malignant ascites resolved in three patients, one each with peritoneal mesothelioma, pancreatic adenocarcinoma, and ovarian adenocarcinoma. hOKT3gamma4 can induce T-lymphocyte activation in patients with cancer, and the immunogenicity of the "humanized" antibody is sufficiently reduced relative to its murine "parent" to permit immunostimulation by repetitive i.v. administration. The therapeutic potential of biweekly i.v. hOKT3gamma4 at a dose of 800 microg should be further evaluated.     

Phase I and imaging trial of a monoclonal antibody directed against gastrin-releasing peptide in patients with lung cancer.

Small cell lung cancer (SCLC) cells express and secrete bombesin-like peptides (BLP) that can activate specific receptors that stimulate the growth of these cells. A murine monoclonal antibody, 2A11, which binds to the BLP, gastrin-releasing peptide with high affinity, has been reported to decrease the growth of SCLC cells in vitro and in athymic nude mice. A Phase I trial in lung cancer patients was performed using multiple doses of 2A11. Thirteen patients with lung cancer received 12 doses of 2A11 antibody three times a week for 4 weeks at one of four dose levels. Serum samples were obtained prior to initiation and before each dose of 2A11 antibody therapy for measurement of 2A11 antibody levels and determination of serum human anti-mouse antibody levels. A pilot imaging evaluation using 111In conjugated 2A11 monoclonal antibody was also performed in the same patients to aid in the study of pharmacokinetics and biodistribution. No toxic reactions were observed, and none of the patients developed detectable human antimouse antibody; however, no objective antitumor responses were observed. The mean trough serum 2A11 levels in patients increased with increasing dose level: 0.26+/-0.2 microg/ml, 6.7+/-6 microg/ml, 71.5+/-60 microg/ml, 248+/-184 microg/ml for dose levels 1 mg/m2, 10 mg/m2, 100 mg/m2, and 250 mg/m2, respectively. At each dose level, sustained detectable serum levels of the monoclonal antibody were achieved. Tumor uptake was noted in 11 of 12 patients who were injected with 111In conjugated 2A11. Because no dose-limiting clinical toxicity was observed, a mathematical model was used to define the recommended Phase II dose of 250 mg/m2. This trial established that repeated doses of monoclonal antibody 2A11 could be given safely to patients, and sustained levels could be achieved for a 4-week schedule. Further evaluation of the antitumor effects of 2A11 is warranted.