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A Journal on Nuclear Medicine and Molecular Imaging
Affiliated to the and to the International Research Group of Immunoscintigraphy
Indexed/Abstracted in: Current Contents/Clinical Medicine, EMBASE, PubMed/MEDLINE, Science Citation Index (SciSearch), Scopus
Impact Factor 2,413
Online ISSN 1827-1936
MOLECULAR MANIPULATION AND PHARMACOKINETICS
Colcher D.*, Pavlinkova G., Beresford G., Booth B. J. M., Choudhury A., Batra S. K.
From the Department of Pathology and Microbiology [DC, GP, GB, BJMB] and Department of Biochemistry and Molecular Biology [AC, SKB] University of Nebraska Medical Center, Omaha, Nebrasca, USA
Monoclonal antibodies (MAbs), because of their inherent specificity, are ideal targeting agents. They can be used to deliver radionuclides, toxins or cytotoxic drugs to a specific tissue or malignant cell populations. Intact immunoglobulin (IgG) molecules have several practical limitations of their pharmacology; their relatively large size of approximately 150,000 daltons leads to a slow clearance from the blood pool and the body resulting in significant exposure to normal organs with limited quantities delivered to tumors. The IgG molecule shows a relatively poor diffusion from the vasculature into and through the tumor. Attempts to modify the pharmacology of the Ig molecule have classically involved the use of proteases to generate F(ab’)2 and Fab’ fragments with molecular weights of ≈100,000 and 50,000 daltons, respectively. Fv fragments of IgG are one of the smallest size functional modules of antibodies that retain high affinity binding of an antigen. Their smaller size, ≈25,000 daltons, enables better tumor penetration and makes them potentially more useful than a whole antibody molecule for clinical applications. Molecular cloning and expression of the variable region genes of IgG has greatly facilitated the generation of engineered antibodies. A single-chain Fv (scFv) recombinant protein, prepared by connecting genes encoding for heavy-chain and light-chain variable regions at the DNA level by an appropriate oligonucleotide linker, clears from the blood at much faster rate than intact IgG. The scFv fragment can retain an antigen-binding affinity similar to that of a monovalent Fab’ fragment; this however, represents a relative decrease in binding affinity when compared to intact antibodies. The scFv with its faster clearance and lower affinity results in a lower percent-injected dose localizing in tumors when compared to the divalent IgG molecule. This may be adequate for imaging but probably not for therapy. The valency of the MAb fragment is critical for the functional affinity of an antibody to a cell surface or a polymeric antigen. In attempts to generate multivalent forms of scFv molecules, non-covalently linked scFv dimeric and trimeric molecules, disulfide linked dimeric scFvs, as well as covalently linked chimeric scFvs have been studied. These multivalent scFvs generally have a higher functional affinity than the monovalent form resulting in better in vivo targeting. Another way to alter the pharmacology of the scFvs is to modify its net charge. Charge-modified scFvs with desired isoelectric points (pI), have been prepared by inserting negatively charged amino acids on the template of the variable region genes. This can help to overcome undesirable elevations in renal uptake seen with most antibody fragments. In conclusion, genetic manipulations of the immunoglobulin molecules are effective means of altering stability, functional affinity, pharmacokinetics, and biodistribution of the antibodies required for the generation of the “magic bullet”.