The L1 cell adhesion molecule is implicated in the control of proliferation, migration, and invasion of several tumor cell types in vitro. Recently, L1 overexpression was found to correlate with tumor progression of ovarian carcinoma, one of the most common causes of cancer-related deaths in gynecologic malignant diseases. To evaluate L1 as a potential target for ovarian cancer therapy, we investigated the effects of anti-L1 monoclonal antibodies (chCE7 and L1-11A) on proliferation and migration of L1-positive human SKOV3ip ovarian carcinoma cells in vitro and the therapeutic efficacy of L1-11A against i.p. SKOV3ip tumor growth in nude mice. In vitro, both anti-L1 antibodies efficiently inhibited the proliferation of SKOV3ip cells as well as other L1-expressing tumor cell lines (renal carcinoma, neuroblastoma, and colon carcinoma). On two cell lines, hyper-cross-linking of L1-11A with a secondary antibody was necessary for significant inhibition of proliferation, indicating that cross-linking of L1 is required for the antiproliferative effect. L1-negative prostate carcinoma cells were not influenced by antibody treatment. Biweekly treatment of ovarian carcinoma-bearing mice with L1-11A led to a dose-dependent and significant reduction of tumor burden (up to À63.5%) and ascites formation (up to À75%). This effect was associated with reduced proliferation within the tumors. L1-directed antibody-based inhibition of peritoneal growth and dissemination of human ovarian carcinoma cells represents important proof-of-principle for the development of a new therapy against one of the leading gynecologic malignant diseases. (Cancer Res 2006; 66(2): 936-43)
Treatment of Swiss mouse 3T3 cells with epidermal growth factor, orthovanadate, or serum results in the activation of a kinase that phosphorylates protein S6 of the 40S ribosomal subunit in vitro. This kinase is eluted as a single peak of activity from either a Mono Q anion-exchange column at 0.34 M NaCl or a Mono S cation-exchange column at 0.20 M NaCl. Treatment of the peak fraction from the Mono S column with phosphatase 2A completely abolishes the activity of the enzyme. The kinase appears to be distinct from protein kinase C, cAMP-dependent protein kinase, and two proteaseactivated kinases, PAK H and H4P. The kinase has been purified to apparent homogeneity and migrates as a single band at Mr 70,000 in NaDodSOn/polyacrylamide gels. The kinase exhibits the ability to autophosphorylate, and this activity directly parallels S6 phosphorylation activity on the final step of purification. In vitro, the kinase incorporates up to 5 mol of phosphate into S6, and the tryptic phosphopeptide maps obtained are equivalent to those from S6 phosphorylated in vivo. Most important, treatment of the purified kinase with phosphatase 2A results in complete inactivation of the enzyme, arguing that the activity of the kinase is directly controlled by phosphorylation.The activation of protein synthesis and subsequent cell growth in numerous biological systems is preceded by the multiple phosphorylation of S6, a protein of the 40S ribosomal subunit (1-6). In the case of quiescent animal cells stimulated to proliferate by specific mitogens, protein synthesis increases by as much as 3-fold and up to 5 mol of phosphate are incorporated per mol of S6 (7,8). The function of S6 phosphorylation in this system is not clearly understood; however, a central role in controlling the initiation of protein synthesis has been suggested by several lines of evidence (9-15).The possibility that protein phosphorylation cascades may be involved in the activation of cell growth has recently focused a great deal of attention on the kinase that phosphorylates S6 (16-24). Earlier we described an S6 kinase activity from Swiss mouse 3T3 cells that was stimulated up to 25-fold by serum, epidermal growth factor (EGF), or sodium orthovanadate (vanadate) (16,17). The S6 kinase activity in extracts prepared from cells treated with increasing concentrations of EGF was found to closely parallel the dose-response curve observed for S6 phosphorylation in the intact cell (16). In addition, the two-dimensional tryptic phosphopeptide maps derived from S6 phosphorylated in vitro and in vivo were equivalent (25). Together, these two findings suggested that the S6 kinase activity being followed in vitro was responsible for phosphorylating S6 in the intact cell.To recover full kinase activity from cell extracts, it was crucial to include phosphatase inhibitors such as glycerol 2-phosphate (16, 17). This finding suggested that the kinase might be regulated by phosphorylation and that the kinase inactivator in cell extracts was a phosphatase. Recently, we confirmed t...
The application of the beta particle-emitting nuclide 67Cu in radioimmunotherapy is reviewed. The production of the nuclide is outlined, and different production modes are discussed with an emphasis on cyclotron production. A short survey of copper chelators currently used for antibody labelling and their impact on the pharmacokinetics of 67Cu-labelled immunoconjugates is provided. Protocols for antibody labelling with 67Cu as well as quality control procedures for 67Cu-labelled antibodies are described. Preclinical data on the biological properties of 67Cu-labelled immunoconjugates are reported and discussed. 67Cu-labelled antibodies show higher and more persistent tumour uptake than their radioiodinated counterparts due to accumulation of labelled metabolites in tumour cells. Biodistribution of 67Cu-labelled antibody fragments has been improved by selection of negatively charged chelators and peptide linkers. Pharmacokinetic analysis of the accumulated dose in tumour and critical organs such as the kidney and liver indicates that, despite this improvement, intact 67Cu-labelled antibodies achieve higher tumour uptake and better therapeutic ratios than 67Cu-labelled antibody fragments and that they are at present the logical choice for clinical studies. Clinical studies using 67Cu-labelled antibodies in lymphoma, colon carcinoma and bladder cancer patients are reviewed. Some of the advantages over radioiodinated antibodies found in the preclinical work, such as higher tumour uptake and better tumour/blood ratios, have also been found with systemic application in lymphoma and colon carcinoma. However, in both lymphoma and colon carcinoma patients, the radiation dose to the liver has been found to be higher from 67Cu- than from 131I-labelled antibodies. The intravesical application of 67Cu-labelled antibody has been shown to be a promising approach for targetting cytotoxic radiation to superficial bladder tumours, without detectable systemic absorption. Given the favourable properties of 67Cu-labelled antibodies, it is the reliable availability of the 67Cu nuclide which is the limiting factor for their more widespread evaluation in radioimmunotherapy trials.
Purpose: We examined the tumor-targeting and therapeutic effects of 67 Cu-labeled single amino acid mutant forms of anti-L1 monoclonal antibody chCE7 in nude mice with orthotopically implanted SKOV3ip human ovarian carcinoma cells. Experimental Design: For radioimmunotherapy, chCE7 antibodies with a mutation of histidine 310 to alanine (chCE7H310A) and a mutation of asparagine 297 to glutamine (chCE7agl) were generated to achieve more rapid blood clearance. Biodistributions of Cu-chCE7agl alone on tumor reduction and survival were investigated. In addition, a combination of low-dose 67 Cu-radioimmunotherapy with unlabeled anti-L1 antibody L1-11A on survival was investigated. Results:67 Cu-CPTA-chCE7agl showed high (up to 49% ID/g) and persistent (up to 168 h) uptake in SKOV3ip metastases, with low levels in normal tissues. Cu-radioimmunotherapy, thereby increasing the efficiency of antibody treatment of metastatic ovarian carcinoma.
The modification of proteins by chemical methods is well-established, however usually difficult to control. In this paper, we describe the posttranslational modification of different IgGs via the Lys or Gln side chains catalyzed by bacterial and human tissue transglutaminase (BTGase and TG2). For proof of concept, different IgG1s (commercial bovine IgG1, and L1CAM targeting chCE7 and chCE7 aglycosylated) were enzymatically functionalization with different fluorescent TGase substrates based on the CY3 analogue Dy547. The optimal reaction conditions were determined in order to assess the two enzymes. The efficiency of the enzymatic method was also compared with a standard chemical method employing a reactive NHS ester of Dy547. Three new TGase substrates were synthesized for this study including Lys-substrate 1 useful for BTGase and TG2 and two Gln-substrates tailor-made for BTGase (substrate 2) and TG2 (substrate 3). Of the two TGases tested, BTGase incorporated Lys-substrate 1 more efficiently than TG2. On the other hand, both enzymes reacted equally efficiently with the corresponding Gln-substrates 2 and 3. Reproducible labeling could be achieved in a broad concentration "window" of the substrates (up to 400 microM) without the risk of overlabeling of chCE7 or chCE7 aglycosylated. The biological activities of the functionalized antibodies were unaltered as shown by in vitro antigen affinity measurements and cell internalization experiments using confocal laser scanning microscopy. A maximum label-to-protein ratio of approximately 1 was achieved with chCE7 aglycosylated and substrate 1 using BTGase. It is important to recognize that the enzymatic activity of TGases enables the stable functionalization of proteins via the side chains of Gln, which is not possible by any chemical method available today. In addition, we could prove that the enzymatic modification of all antibodies occurred selectively at the heavy chain whereas the chemical method led to labeling of both the heavy and the light chains.
Radioimmunotherapy of cancer utilizes anti-tumor antibodies or antibody fragments conjugated to radionuclides to deliver radiation selectively to tumors. However, radiolabeled proteins deposit radioactivity in normal organs that metabolize or conserve proteins and peptides, primarily liver and kidneys. To accelerate the clearance of radioactivity from normal tissues, linkers between the antibody or antibody fragment and the radioactive moiety have been designed for cleavage in the liver and kidneys, to liberate low molecular weight radioactive species for rapid excretion. Modest success in improving the tumor-to-liver and tumor-to-kidney radiation dose ratios have been achieved in preclinical studies. Such changes when taken to clinical studies have suggested useful impact on therapeutic work. Recent advances in the development of cleavable linkers are described.
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