Antibody chemical reactivity: Beneficial and pathogenic roles

Antibodies (Abs) to autoantigens and foreign antigens (Ags) mediate, respectively, various pathogenic and beneficial effects. Abs express enzyme-like nucleophiles that react covalently with electrophiles. A subpopulation of nucleophilic Abs expresses proteolytic activity, which can inactivate the Ag permanently. This thesis shows how the nucleophilicity can be exploited to inhibit harmful Abs or potentially protect against a virus. ^ Inactivation of pathogenic Abs from Hemophilia A (HA) patients by means of nucleophile-electrophile pairing was studied. Deficient factor VIII (FVIII) in HA subjects impairs blood coagulation. FVIII replacement therapy fails in 20-30% of HA patients due to production of anti-FVIII Abs. FVIII analogs containing electrophilic phosphonate group (E-FVIII and E-C2) were hypothesized to inactivate the Abs by reacting specifically and covalently with nucleophilic sites. Anti-FVIII IgGs from HA patients formed immune complexes with E-FVIII and E-C2 that remained irreversibly associated under conditions that disrupt noncovalent Ab-Ag complexes. The reaction induced irreversible loss of Ab anti-coagulant activity. E-FVIII alone displayed limited interference with coagulation. E-FVIII is a prototype reagent suitable for further development as a selective inactivator of pathogenic anti-FVIII Abs. ^ The beneficial function of Abs to human immunodeficiency virus type 1 (HIV-1) was analyzed. HIV-1 eludes the immune system by rapidly changing its coat protein structure. IgAs from noninfected subjects hydrolyzed gp120 and neutralized HIV-1 with modest potency by recognizing the gp120 421-433 epitope, a conserved B cell superantigenic region that is also essential for HIV-1 attachment to host cell CD4 receptors. An adaptive immune response to superantigens is generally prohibited due to their ability to downregulate B cells. IgAs from subjects with prolonged HIV-1 infection displayed improved catalytic hydrolysis of gp120 and exceptionally potent and broad neutralization of diverse CCR5-dependent primary HIV isolates attributable to recognition of the 421-433 epitope. This indicates that slow immunological bypass of the superantigenic character of gp120 is possible, opening the path to effective HIV vaccination. ^ My research reveals a novel route to inactivate pathogenic nucleophilic Abs using electrophilic antigens. Conversely, naturally occurring nucleophilic Abs may help impede HIV infection, and the Abs could be developed for passive immunotherapy of HIV infected subjects. ^

CHARACTERIZATION OF SERINE KINASE ACTIVITY ASSOCIATED WITH MOLONEY MURINE SARCOMA VIRUS V-MOS GENE PRODUCTS

Various Moloney murine sarcoma virus (Mo-MuSV) isolates contain a cellular sequence, termed mos, which is responsible for the transforming ability of Mo-MuSV. A serine kinase activity has been found to be associated with mos gene products of several isolates of Mo-MuSV. A mutant of Mo-MuSV strain 124 (designated MuSV ts110) is temperature-sensitive (ts) for transformation and encodes two proteins, P85('gag-mos) (an 85,000 M(,r) protein encoded by the gag and mos genes) and P58('gag), at the permissive temperature (28(DEGREES)C). At the nonpermissive temperature (39(DEGREES)C), only P58('gag) is found in MuSV ts110-infected NRK cells (6m2 cells). Both P85('gag-mos) and P58('gag) were phosphorylated when anti-gag immune complexes containing these proteins were incubated at 22(DEGREES)C with (lamda)-('32)P -ATP and MnCl(,2). The kinase detected in anti-gag complexes from 6m2 cells at permissive temperature was associated with P85('gag-mos) since immune complexes from 39(DEGREES)C 6m2 cells, which lack P85('gag-mos), produced no phosphorylated P58('gag) molecules. In addition, an anti-mos complex (anti-mos 37-55 complexes) allowed in vitro phosphorylation of P85('gag-mos) in the absence of P58('gag). No kinase activity was detectable with other gag gene products (e.g., Mo-MuSV-124 P62('gag)), suggesting that the P85('gag-mos) kinase activity was present within the mos portion of the protein. The P85('gag-mos) kinase activity was very thermolabile upon shifting 6m2 cells from permissive to nonpermissive temperatures (t(, 1/2) for inactivation = 5 min). In contrast, a spontaneous revertant of MuSV ts110 encodes a larger gag-mos protein (termed P100('gag-mos)) which contained a kinase activity stable to 39(DEGREES)C. Using the optimal conditions developed for the P85('gag-mos) kinase, Mo-MuSV-encoded p37('mos) was also found to be associated with a serine kinase activity. Phosphorylation of p37('mos) and a 43 Kd protein (super-phosphorylated p37('mos)) occurred in anti-mos(37-55) complexes from Mo-MuSV-124 acutely-infected NIH 3T3 cells, but neither in mos 37-55 peptide-blocked anti-mos(37-55) complexes nor in immune complexes from uninfected NIH 3T3 cells. Antibodies directed against the C-terminus of v-mos were found to inhibit the in vitro phosphorylation of p37('mos), suggesting that the extreme C-terminal sequence of v-mos may be important for an intrinsic kinase activity. This inhibitory action by antibodies to the C-terminus of p37('mos), when considered with all the other data reported here, provides convincing evidence that the v-mos gene encodes a serine protein kinase activity. ^

Regulation of {\it neu\/} gene expression by the simian virus 40 large T antigen and tumor suppressors Rb and p53

The neu gene (also c-erbB-2 or HER2) encodes a 185 kilodalton protein that is frequently overexpressed in breast, ovarian and non-small cell lung cancers. Study of the regulation of neu indicates that neu gene expression can be modulated by c-myc or by the adenovirus 5 E1a gene product. This study demonstrates that the transforming protein, large T antigen, of the simian virus 40 represses neu promoter activity. Repression of neu by large T antigen is mediated through the region $-$172 to $-$79 (relative to first ATG) of the neu promoter--unlike through $-$312 to $-$172 for c-myc or E1a. This suggests a different pathway for repression of neu by large T antigen. The 10 amino acid region of large T required for binding the tumor suppressor, retinoblastoma gene product, Rb, is not necessary for repression of neu. Moreover, the tumor suppressors, Rb and p53 can independently inhibit neu promoter activity. Rb inhibits neu through a 10 base pair G-rich enhancer (GTG element) ($-$243 to $-$234) and also through regions close to transcription initiation sites ($-$172 to $-$79). Mutant Rb unable to complex large T is able to repress the region close to transcription initiation but not the GTG enhancer. Thus, Rb inhibits the two regulatory domains of the neu gene by different mechanisms. Both Rb and p53 can repress the transforming activity of activated neu in focus forming assays. These data provide evidence that tumor suppressors regulate expression of growth stimulatory genes such as neu. Therefore, one reason for the overexpression of neu that is frequently seen in breast cancer cells may be due to functional inactivation of Rb and p53 which is also a common occurrence in breast cancer cells. ^