Monoclonal antibodies directed against the lac carrier protein purified' from the membrane of Escherichia coli were prepared by somatic cell fusion of mouse myeloma cells with splenocytes from an immunized mouse. Several-clones produce antibodies that react with the purified protein as demonstrated by solid-phase radioimmunoassay and by immunoblotting experiments; culture' supernatants from the clones inhibit active transport of lactose in isolated membrane vesicles. Five stable clones were selected for expansion, formal cloning, and production of ascites fluid, and the antibodies secreted in vivo by each clone also were found to inhibit lactose transport. Antibody from hybridoma 4B1, an IgG2a immunoglobulin, inhibits active transport of lactose in proteoliposomes reconstituted with purified lac carrier and in right-side-out membrane vesicles. In contrast, the antibody has no effect on the generation ofthe proton electrochemical gradient by membrane vesicles nor does it alter the ability of vesicles containing the lac carrier to bind p-nitrophenyl-a-D-galactopyranoside. In order to achieve 50% inhibition of transport activity, a 2-to 3-fold molar excess of antibody to lac carrier is required, regardless of the amount of lac carrier in the membrane. Thus, the concentration ofantibody required for a given degree ofinhibition is proportional to the amount of lac carrier in the membrane. Finally, antibody-induced inhibition occurs within seconds, an observation suggesting that the epitope is accessible on the surface of the membrane.Transport of f-galactosides in Escherichia coli is catalyzed by the product of the lac y gene (1), the lac carrier protein, which translocates 13-galactosides with protons in a symport reaction (2). Accordingly, in the presence of a proton electrochemical gradient (ASH+), hydrogen ion moves down the electrochemical gradient and drives the uphill translocation of sugar (see ref. 3 for a review). The lac carrier was identified as a membranebound protein chemically in 1965 (4) and functionally in 1970 (5). Eight years later in rapid succession, the lac y gene was cloned in a recombinant plasmid, its product was amplified (6) and synthesized in vitro (7), and the sequence of the protein was deduced from the DNA sequence (8). Shortly thereafter, it was demonstrated (9) that lactose transport activity can be solubilized and reconstituted into proteoliposomes, and a highly specific photoaffinity label for the lac carrier was developed (10). Most recently, use of these techniques has led to the purification of a single protein, its identification as the product of the lac y gene, and the demonstration that it is the only polypeptide in the cytoplasmic membrane required for lactose/ proton symport (11, 12).The lac carrier protein is a 46.5 kilodalton (kDal) polypeptide chain of 417 amino acid residues of known sequence (8,11). A preliminary secondary structure model for the molecule has been formulated (unpublished data) based on the hydropathic nature of the protein along its sequence...
