Terence G. Porter

A Newly Identified Member of the Tumor Necrosis Factor Receptor Superfamily with a Wide Tissue Distribution and Involvement in Lymphocyte Activation

The tumor necrosis factor receptor (TNFR) superfamily consists of approximately 10 characterized members of human proteins. We have identified a new member of the TNFR superfamily, TR2, from a search of an expressed sequence tag data base. cDNA cloning and Northern blot hybridization demonstrated multiple mRNA species, of which a 1.7-kilobase form was most abundant. However, TR2 is encoded by a single gene which, maps to chromosome 1p36.22–36.3, in the same region as several other members of the TNFR superfamily. The most abundant TR2 open reading frame encodes a 283-amino acid single transmembrane protein with a 36-residue signal sequence, two perfect and two imperfect TNFR-like cysteine-rich domains, and a short cytoplasmic tail with some similarity to 4–1BB and CD40. TR2 mRNA is expressed in multiple human tissues and cell lines and shows a constitutive and relatively high expression in peripheral blood T cells, B cells, and monocytes. A TR2-Fc fusion protein inhibited a mixed lymphocyte reaction-mediated proliferation suggesting that the receptor and/or its ligand play a role in T cell stimulation.

Structure-activity studies of rapamycin analogs: evidence that the C-7 methoxy group is part of the effector domain and positioned at the FKBP12-FRAP interface

BACKGROUND Rapamycin is an immunosuppressant natural product, which blocks T-cell mitogenesis and yeast proliferation. In the cytoplasm, rapamycin binds to the immunophilin FKBP12 and the complex of these two molecules binds to a recently discovered protein, FRAP. The rapamycin molecule has two functional domains, defined by their interaction with FKBP12 (binding domain) or with FRAP (effector domain). We previously showed that the allylic methoxy group at C-7 of rapamycin could be replaced by a variety of different substituents. We set out to examine the effects of such substitutions on FKBP12 binding and on biological activity. RESULTS Rapamycin C-7-modified analogs of both R and S configurations were shown to have high affinities for FKBP12, yet these congeners displayed a wide range of potencies in splenocyte and yeast proliferation assays. The X-ray crystal structures of four rapamycin analogs in complexes with FKBP12 were determined and revealed that protein and ligand backbone conformations were essentially the same as those observed for the parent rapamycin-FKBP12 complex and that the C-7 group remained exposed to solvent. We then prepared a rapamycin analog with a photoreactive functionality as part of the C-7 substituent. This compound specifically labeled, in an FKBP12-dependent manner, a protein of approximately 250 kDa, which comigrates with recombinant FRAP. CONCLUSIONS We conclude that the C-7 methoxy group of rapamycin is part of the effector domain. In the ternary complex, this group is situated in close proximity to FRAP, at the interface between FRAP and FKBP12.

Induction of cytolytic and antibody responses using Plasmodium falciparum repeatless circumsporozoite protein encapsulated in liposomes

Plasmodium circumsporozoite (CS) protein-induced antibody and T-cell responses are considered to be important in protective immunity. Since the key repeat determinant of the CS protein may actually restrict the recognition of other potential T- and B-cell sites, a modified Plasmodium falciparum CS protein lacking the central repeat region, RLF, was expressed in Escherichia coli. On purification, RLF was encapsulated into liposomes [L(RLF)] and used for the in vivo induction of cytolytic T lymphocytes (CTL) and antibodies. Immunization of B10.Br (H-2k) mice with L(RLF), but not with RLF, induced CD8+ CTL specific for the P. falciparum CS protein CTL epitope, amino acid residues 368-390. Anti-L(RLF) serum reacted with antigens on intact sporozoites and inhibited sporozoite invasion of hepatoma cells. Antibody specificity studies in New Zealand White rabbits revealed new B-cell sites localized in amino acid residues 84-94, 91-99, 97-106 and 367-375. Although the mechanisms by which liposomes enhance cellular and humoral immune responses remain unknown, liposome-formulated vaccines have been well tolerated in humans; hence, their use in vaccines, when efficacy depends on antibody and CTL responses, may be broadly applicable.

Evaluation of the protective efficacy of reshaped human monoclonal antibody RSHZ19 against respiratory syncytial virus in cotton rats.

Reshaped human MAb RSHZ19, which is specific for the surface fusion protein of respiratory syncytial virus (RSV) is in clinical development for the prevention and treatment of RSV-induced disease in human infants. The current studies profile lung virus clearance and evaluate lung histopathology in MAb-treated, RSV-infected cotton rats, a well characterized model of RSV infection. The highest dose of this MAb (10 mg/kg) administered parenterally 24 h before infection decreased subgroup A or B RSV lung titers to below detectable levels (≥2.3 log10 reduction), and significantly reduced lung virus titers (≥2.0 log10 reduction) when administered 96 h postinfection. Prophylactic administration of 10 mg/kg RSHZ19 was significantly more protective than 1000 mg/kg conventional human immune serum globulin (HSIg), and protective serum-neutralizing titers in MAb-treated animals (1:32, which correlated with approximately 40 μg/ml determined by anti-idiotype ELISA) were significantly lower than those reported previously for HSIg or for convalescent human serum (1:200-1:400). MAb concentration in lung lavages was determined by ELISA to be approximately 1% of the serum MAb concentration, but was not detectable by neutralization assay. The degree of lung histopathology in MAb-treated cotton rats was proportional to lung virus titer, and inversely proportional to the RSHZ19 dose administered. There was no evidence of exacerbated disease in the lungs of MAb-treated animals. These studies thus support the potential clinical utility of RSHZ19 MAb in the prevention and treatment of RSV-induced disease in humans.

Progressive epitope-blocked panning of a phage library for isolation of human RSV antibodies

Epitope-blocked panning is an approach to mining antigen-specific diversity from phage display antibody libraries. Previously, we developed and used this method to recover a neutralizing antibody to respiratory syncytial virus (RSV) by blocking a dominant response to a nonneutralizing epitope on a recombinant derivative of the viral F antigen. We have extended this approach to the blocking of multiple epitopes simultaneously, which led to the recovery of new antibodies of different specificity, including one new neutralizing activity. A phage display Fab library was selected on recombinant F antigen in the presence of three representative antibodies recovered in the unblocked and subsequent single-blocked panning procedures. Restriction endonuclease fingerprinting of 13 F+ clones revealed seven unique Fabs. DNA sequence analysis of five of these clones revealed five new light chains in combination with different heavy chains, three of which were very similar or identical to Fabs previously isolated from this library. The blocking antibodies did not compete with the new Fabs, demonstrating effective masking of their binding sites in the panning procedure. Conversely, these Fabs did show variable inhibition of two of the blocking antibodies suggesting a close proximity or interdependence of their epitopes. One of the antibodies did inhibit virus infection, albeit with modest potency. These results demonstrate that epitope-blocked panning is a self-progressing approach to retrieving diverse antibodies from phage libraries.