Ribonucleases and immunoRNases as anticancer drugs.

Ribonucleases degrade RNA, now considered an important drug target. The parent member of this protein superfamily is bovine pancreatic RNase A that functions as a digestive enzyme. Other physiological roles and activities have been ascribed to more recently discovered members of this superfamily. Angiogenin was isolated by following angiogenic activity from cell culture media conditioned by colon cancer cells. ONCONASE kills tumor cells in vitro and in vivo and has advanced to a phase IIIb confirmatory clinical trial for the treatment of unresectable malignant mesothelioma. All three of these RNA degrading enzymes have been used to generate immunoRNases; chemical conjugates and ligand-RNase fusion proteins, for cancer therapy. The properties of each of these RNases are described along with the increasingly sophisticated construction of recombinant immunoRNases. The advantages of using RNase as an antibody payload is compared to using plant or bacterial toxins in the construction of immunotoxins, a related strategy for specifically killing malignant cells.

Multimerization domains for antibody phage display and antibody production.

High-throughput generation of antibodies for proteome research has become feasible by using antibody gene libraries and in vitro selection methods like phage display. Typically monovalent antibody fragments like scFv, Fab or scFab are obtained by this technology. To mimic the IgG molecule and gain avidity, resulting in stronger binding, multimerization domains can be fused to antibody fragments. Here we systematically analyzed different multimerization domains in respect to three key parameters, crucial for the high-throughput generation of binders. (i) The compatibility to be displayed on phage (assessed for at least three different antibody formats, scFv, Fab and scFab) in combination with five different multimerization domains; (ii) production yields and (iii) oligomerization properties were analyzed for three different scFv fragments. We found that the use of a biotin acceptor domain in combination with an in vivo biotinylation system performed best concerning the key parameters and thus would be a useful tool to generate multimeric antibody complexes on demand from phage display selected antibody fragments with the least effort.

Functional knockdown of VCAM-1 at the posttranslational level with ER retained antibodies.

Vascular cell adhesion molecule 1 (VCAM-1) is involved in the recruitment of leukocytes to inflammatory sites. In this study we present the first functional knockdown of VCAM-1 using an ER retained antibody construct. We generated a knockdown construct encoding the VCAM-1 specific single chain variable fragment scFv6C7.1 fused to the C-terminal ER retention sequence KDEL. HEK-293:VCAM-YFP cells stably expressing a VCAM-YFP fusion protein were transiently transfected with the knockdown construct and showed down-regulation of surface VCAM-1. Knockdown efficiency of the system is time-dependent due to used transient transfection of the intrabody construct. Furthermore, intrabody mediated knockdown of HEK-293:VCAM-YFP cells also impaired cell-cell interaction with Jurkat cells that are endogenously expressing VLA-4, the physiological partner of VCAM-1. Posttranslational knockdown with ER retained antibodies seems to be a promising technique, as shown here for VCAM-1.

Efficient cryopreservation of dendritic cells transfected with cDNA of a tumour antigen for clinical application.

Dendritic cells (DCs) are the most potent antigen-presenting cells of the immune system and are currently being investigated in clinical applications as cancer vaccines. An efficient cryopreservation method would greatly contribute to their use in clinical trials. We have established a method for freezing of DCs derived from peripheral blood mononuclear cells using the plasma expander Gelifundol. This enabled us to reduce the concentration of the toxic DMSO to 5%. The method could be performed without the addition of fetal calf serum or any other serum. After freezing, the viability of the DCs was 90%. The cells exhibited all the phenotypic characteristics (CD11c+, HLA-DR+, CD80+, CD83+, CD86+) of DCs, as tested by flow cytometry. Cells transfected with cDNA for the tumour antigen mucin expressed this protein on their surfaces in the same manner as before freezing. The stimulating capacity of a mixed lymphocyte culture was also preserved. These findings offer an efficient method for the cryopreservation of DCs for use in clinical trials.

Mucin gene (MUC1) transfer into human dendritic cells by cationic liposomes and recombinant adenovirus.

BACKGROUND: Dendritic cells (DC) as antigen presenting cells play an important role in immunotherapy of cancer. Mucin, encoded by the gene MUC1, is a human tumor antigen expressed in breast, pancreatic and ovarian cancers. Therefore, MUC1-transfected DC would be an attractive tool in constructing cancer vaccines. MATERIALS AND METHODS: Using two different cationic liposome preparations and, for comparison, a recombinant adenovirus expressing mucin, we tested the efficiency of mucin gene transfer into DC by flow cytometry. We investigated if these transfected DC were able to specifically stimulate autologous peripheral blood lymphocytes (PBL) from healthy donors. RESULTS: Flow cytometry revealed that 5-20% of DC transfected with liposomes Lipofectin and 20-40% of DC transduced with adenovirus expressed the relevant mucin epitopes. The expression of mucin on DC was similar to the expression of mucin found on carcinoma cells. After antigen uptake, DC specifically stimulated autologous PBL. CONCLUSION: We have shown that cationic liposomal gene transfer into human DC was feasible. We could obtain antigen specific stimulation of PBL at a similar rate as with adenoviral MUC1-transduced DC.

Tumor-specific targeting of a cell line with natural killer cell activity by asialoglycoprotein receptor gene transfer.

Targeting of immunological effector cells to tumor cells could be an efficient strategy of adoptive immunotherapy. The success of this strategy depends on the specificity of the effector cells and their availability in sufficient numbers. The aim of this study was to target the human natural killer cell line YT specifically to tumor cells. The cell line was modified by transfection with the cDNA of the human asialoglycoprotein receptor (ASGPR). This C-type lectin recognizes carbohydrates containing terminal galactosyl (Gal) residues, including the beta1-Gal bearing Thomsen-Friedenreich (TF) antigen, which is found on tumor cells. Binding assays revealed that the ASGPR-gene-transfected YT cell line binds significantly higher to tested target tumor cell lines than the mock-transfected control cells. Cytolytic activity against the tumor cell lines Raji, Jurkat and the TF-positive KG1 subline was increased. Genetic modification of YT cells could provide a useful tool for tumor targeting in immunotherapy.