In this article we show how the polymerase chain reaction (PCR) and primers designed for conserved sequences of leader (L), framework one (FR1) and constant (CONST) regions of immunoglobulin light and heavy chain genes can be used for the cloning and sequencing of rearranged antibody variable regions from mouse hybridoma cells. RNA was extracted from the mouse hybridoma cells secreting MAbs: IOR-T3a (anti-CD3), C6 (anti-P1 of N. meningitidis B385), IOR-T1 (anti-CD6), CB-CEA.1 (anti-carcinoembryonic antigen), and CB-Fib.1 (anti-human fibrin). First strand cDNA was synthesized and amplified using PCR. The newly designed primers are superior to others reported recently in the literature. Isolated PCR DNA fragments of C6 and IOR-T3a were sequenced after asymmetric amplification, or M13 cloning. The FR1/CONST primer combinations selectively amplified mouse lights chain of groups kappa II, V, and VI, and heavy chains of groups IIa and IIc. The L/CONST primers for light chains amplified light chains from all four hybridomas. These methods greatly facilitate structural and functional studies of antibodies by reducing the efforts required to clone and sequence their variable regions.
From genetic material of hybridoma cells, we have generated a recombinant single-chain antibody fragment (scFv antibody) specific to carcinoembryonic antigen (CEA), which can substitute an intact murine monoclonal immunoglobulin G1 (IgG1) antibody, also developed by our group, and used in clinical practice for many years. In this paper, we examine a novel one-step method for direct 99mTc labelling of a recombinant anti-CEA scFv fragment through a C-terminal peptide tag containing a six-histidine sequence. This C-terminal peptide tag does not affect antigen binding, and was employed as a strategy for the one-step method of direct 99mTc labelling of a recombinant antibody fragment, based on the criteria of Zamora and Rhodes (Zamora PO, Rhodes BA. Imidazoles as well as thiolates in proteins bind technetium-99m. Bioconj Chem 1992; 3: 493-498). This is a novel technique for the rapid labelling of molecules, suitable for in vivo trials. The method yields >95% labelling efficiency without major effects on biological or in vitro stability.
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