Two amino acid residues, His274 and Asp375, were replaced singly in the active site of pig citrate synthase (PCS) with Gly274, Arg274, Gly375, Asn375, Glu375, and Gln375. The nonmutant protein and the mutant proteins were expressed in and purified from Escherichia coli, and the effects of these amino acid substitutions on the overall reaction rate and conformation of the PCS protein were studied by initial velocity and full time course kinetic analysis, behavior during affinity column chromatography, and monoclonal antibody reactivity. Native and mutant proteins purified similarly had a subunit molecular weight of 50,000 and were homologous when examined with 10 independent a-PCS monoclonal IgGs or with a polyclonal anti-PHCS serum. No activity was detected for Asn375 or Gln375. The kcats of the other purified mutant proteins, however, were decreased by about 10(3) compared to the nonmutant enzyme activity. The Km for oxalacetate was decreased 10-fold in the Glu375 protein and was reduced by half in Gly274 and Arg274 PCSs, while the Km for acetyl-CoA was decreased 2-3-fold in Gly274, Arg274, and Gln375 PCSs. A mechanism is proposed that electrostatically links His274 and Asp375.
Citrate synthase (EC 4.1.3.7), which is present in all living organisms as a key enzyme in aerobic energy metabolism, is one of the most highly phylogenetically conserved enzymes known in terms of its primary and active site structure. However, in terms of other parameters such as in vitro stability, tolerance to changes in pH, degree of self-polymerization, etc., citrate synthases from different sources are markedly different. These divergences can be observed even between isoforms of the enzyme within the same species. Data documenting these diversities suggest that a high degree of difference in tertiary structures may occur. Therefore, the surface profiles of citrate synthase enzymes from yeast, pig, rat, tomato and Escherichia coli were investigated with immunological methods using monoclonal antibody families generated against either pig citrate synthase (alpha-PCS) or yeast citrate synthase-2 (alpha-YCS-2). A high degree of homology of enzyme epitopes was detected on the mitochondrial citrate synthases originating from yeast, tomato, pig and rat cells. Major differences were found between the hexameric citrate synthase originating from E. coli compared with those dimeric forms prepared from eukaryotic cells. Only modest similarities were detected between the highly homologous peroxisomal and mitochondrial yeast citrate synthases. Furthermore, a point mutation of one of the catalytic residues (H274R on recombinant pig and H313R on yeast enzyme) of mitochondrial citrate synthase (CS-1) resulted in a significant increase in immunological similarity with the peroxisomal isoenzyme (CS-2). These findings are discussed in terms of the possible mechanism of evolution of CS-2 in yeast.
A new method for the detection and separation of antigen-specific antibody-producing cells on the basis of antibody-mediated recognition of solid-phase immobilized antigen molecules is described. Hybridoma cells are placed on microtiter plate wells coated with antigen molecules, and antigen-specific antibody-producing cells bind to the immobilized antigen molecules; antibody nonproducing or nonspecific antibody-producing cells can be easily separated from the bound cells by inverting the plate. Cells bound to solid-phase immobilized antigen molecules can readily be quantitated by counting under a light microscope, and the cells recovered can produce antibody in culture. Unspecific binding of cells in antigen-specific cell adherence assay (ASCAA) is optimally below 5%. Also, effect of drugs interfering with processes related to antibody production of antigen-specific cells can be detected and evaluated by ASCAA.
Antibody-producing hybridoma cells specifically bind to microgram quantities of antigen molecules adsorbed onto the surface of plastic microtiter plates. The binding of hybridoma cells to nonantigen is optimally below 5%, similar binding of non-antibody-producing cells is 4-7%, compared to the binding of the hybridomas to their antigen. There is a difference in the kinetics of binding hybridomas to antigen compared to nonantigen. The number of bound cells depends on the amount, i.e., the surface density, of the antigen molecules and shows typical saturation effects. Preincubation of hybridomas with excess free antigen and saturation of the antibody binding site on the surface with the hybridoma-produced antibody reduces binding of the hybridoma cells to the antigen. Treatment of cells with trypsin reduces binding to antigen-coated plastic surfaces. Drugs such as sodium azide, cytochalasin B, colchicine, vinpocetine, and vincristine sulfate reduce binding to the antigen. Hybridoma cells adhering to the antigen produce more antibody than nonadhering cells. The results reported in this paper show that antigen molecules adsorbed to include a plastic surface and hybridoma cells interact specifically. This system forms a suitable model to study the interaction of antigen with antigen-specific cells and may be useful as a separation method for specific antibody-producing cells.
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