A different function for a critical tryptophan in c-Raf and Hck.

The similarity of the catalytic domains of Raf and Src family members suggests that functions of homologous residues may be similar in both kinase families. A tryptophan residue, W260, in the WEI region of the Src family kinase Hck has an important role in regulating ATP binding. We tested the hypothesis that the tryptophan, W342, in the WEI region of c-Raf may have a similar role to the W260 of Hck. Mutation of W260 to A in Hck activates kinase activity, but we found that mutation of W342 to A in c-Raf inactivates the kinase activity. Mutating W342 to aspartate (D), lysine (K) or histidine (H) also inactivated c-Raf whether assayed as a purified immunoprecipitate or when recruited to the plasma membrane. A constitutively active c-Raf can be generated by mutating two regulatory tyrosines to aspartate. When placed into this active c-Raf mutant, mutation of W342 to D, K or H enabled phosphorylation and activation of the c-Raf substrate MEK at the plasma membrane but not in an immunoprecipitation assay. We conclude that (1) Tryptophan has a different role in the WEI regions of c-Raf and Hck, (2) W342 is not directly involved in MEK binding as both positive and negative residues at 342 are permissive for MEK activation at the membrane in a constitutively active c-Raf mutant, (3) Factors at the membrane are capable of potentiating activation of c-Raf containing mutated W342 in a hyperactivated c-Raf, but not in a wild type c-Raf and (4) There is a stringent structural requirement for W at residue 342 in c-Raf.

The antigenic surface of staphylococcal nuclease. I. Mapping epitopes by site-directed mutagenesis.

The analysis of the antigenic surface of staphylococcal nuclease was begun by generating and characterizing a panel of mAb. Twelve mAb were selected from a large number of anti-nuclease mAb and characterized for affinity and isotype, by their ability to block enzyme activity, and by complementation and competitive inhibition assays for the relative location of epitopes. The mAb were placed in complementation groups based on their distinct binding patterns. These groups define a series of eight overlapping epitopes that are estimated to cover a large portion of the nuclease surface. Four mAb blocked the enzyme activity of nuclease. The epitopes defined by two of these four mAb were localized on the surface of nuclease using single amino acid variant Ag generated by site-directed mutagenesis of the cloned nuclease coding sequence. mAb-25 maps to residue 46 which is located at the edge of the enzyme active site consistent with its ability to inhibit enzyme activity. mAb-19, which also blocks enzyme activity and belongs to the same complementation group as mAb-25, was unaffected by the substitution at position 46. This suggests that mAb-19 and mAb-25, if they do react with the same epitope, have differences in fine specificity. mAb-22 blocks enzyme activity and belongs to an overlapping complementation group. The fourth mAb, mAb-1, which belongs to a distinct, nonoverlapping, complementation group, does not blocks enzyme activity, and is directed to a region of nuclease that includes the amino acid at position 133. This residue is located a short distance from the active site in a region that has been suggested to participate in binding of DNA, a substrate for nuclease. Therefore, the four epitopes defined by these mAb are localized at or near the enzyme active site.

Tolerance to azobenzenearsonate: idiotype-specific suppression, B cell dominance, and clonal elimination.

Twenty to 70% of the antibody molecules produced by individual A/J mice in response to azobenzenearsonate (ABA) bear a particular idiotype termed the major cross-reactive idiotype (CRI). Mice that were made tolerant to ABA by injection of ABA coupled to human gamma-globulin show a decrease in production of ABA-specific antibody and a preferential loss of the major CRI. In the experiments reported here, we have used adoptive cell transfers and splenic fragment culture assays to study the mechanism(s) involved in the tolerance to ABA, with emphasis on the preferential loss of the CRI. These studies show that the decrease in total anti-ABA after the induction of tolerance is the result of a decrease in the number of ABA-responsive B cells independent of CRI expression. The preferential loss of the CRI is due to idiotype-specific T cell suppression and/or B cell dominance. In addition, it is demonstrated that immunization in the presence of idiotype-specific suppression converts a normally immunogenic stimulus into a tolerogenic signal, resulting in a decrease in the absolute number of CRI+ B cell precursors.