Teresa Di Prospero

Bivalent and bispecific antibodies and their fragments have immense potential for practical application. Here we describe the design of small antibody fragments with two antigen-binding sites. The fragments comprise a heavy-chain variable domain (VH) connected to a light-chain variable domain (VL) on the same polypeptide chain (VH-VL). By using a linker that is too short to allow pairing between the two domains on the same chain, the domains are forced to pair with the complementary domains of another chain and create two antigen-binding sites. As indicated by a computer graphic model of the dimers, the two pairs of domains can pack together with the antigen-binding sites pointing in opposite directions. The dimeric antibody fragments, or "diabodies," can be designed for bivalent or bispecific interactions. Starting from the monoclonal antibodies NQ11.7.22 (NQ11) and D1.3 directed against the hapten phenyloxazolone and hen egg lysozyme, respectively, we built bivalent fragments (VHNQ11-VLNQ11)2 and (VHD1.3-VLD1.3)2 and bispecific fragments VHNQ11-VLD1.3 and VHD1.3-VLNQ11. The fragments were expressed by secretion from bacteria and shown to bind specifically to the hapten and/or antigen. Those with 5- and 15-residue linkers had similar binding affinities to the parent antibodies, but a fragment with the VH domain joined directly to the VL domain was found to have slower dissociation kinetics and an improved affinity for hapten. Diabodies offer a ready means of constructing small bivalent and bispecific antibody fragments in bacteria.

Rat monoclonal antibodies were used to deplete selectively Lyt 2 (cytotoxic) and L3T4 (helper) T cell populations in vivo. These antibodies produced greater than 95% depletion of the respective T cell subset as determined by fluorescent antibody and cytofluorographic analyses. Antibody-treated mice were infected in the ear pinna with herpes simplex virus (HSV) and the induction of virus-specific T cell and antibody responses were monitored during the acute infection. Lyt 2-deficient mice produced delayed hypersensitivity and HSV-specific antibodies comparable to those in untreated animals. However, major histocompatibility complex class I-restricted T cell killing was abolished. In contrast, L3T4-deficient animals failed to produce either primary delayed hypersensitivity response or specific antibodies to the virus, but cytotoxic T cell responses were induced and even augmented in comparison with infected, normal animals. This observation clearly demonstrates that Lyt 2 cytotoxic T cells can be induced in a helper T cell-deficient environment. The ability of T cell subset-deficient mice to clear infectious virus was investigated in the skin of the ear and the part of the nervous system innervating the site of infection. L3T4-deficient animals showed a markedly delayed clearance of virus from the ear and also had a more florid infection of the nervous system. However, Lyt 2-deficient mice cleared the infection in the ear normally, but a severe infection of the nervous system was still observed. The implication of these observations to the pathogenesis of this virus is discussed.

We have previously reported that peripheral blood gamma/delta + T cells proliferate in high frequency (1 in 2-20) in response to heat-killed Mycobacterium tuberculosis (M.tb.). In the present study, the T cell receptor phenotype of mycobacteria-responsive human gamma/delta + T cells was analyzed in primary cultures with a set of monoclonal antibodies (mAbs) directed against V gamma 9, V delta 1, and V delta 2. When unseparated T cells were stimulated with M.tb., all proliferating gamma/delta + T cells expressed V gamma 9 (and V delta 2) after culture. Selective depletion of V gamma 9-bearing cells before culture completely abolished the proliferative response of all gamma/delta + cells (but did not inhibit reactivity of alpha/beta + T cells). In addition, when CD4- CD8- thymocytes were stimulated with M.tb., there was again selective outgrowth of V gamma 9+ cells. In this case, the starting responder population contained few (0.5-1.8%) V gamma 9+ and many (11.5-31.5%) V delta 1+ cells that did not coexpress V gamma 9. These V delta 1+ cells were not activated by M.tb. but could be readily stimulated by anti-V delta 1 mAb A13. Finally, a V gamma 9-specific mAb selectively suppressed the proliferative response of gamma/delta + T cells to M.tb. Taken together, our results demonstrate that, within gamma/delta + T cells, reactivity towards M.tb. is an exclusive property of V gamma 9+/V delta (2+)-bearing cells.

Trypanosomes compartmentalize most of their glycolytic enzymes in a peroxisome-like microbody, the glycosome. The specificity of glycosomal targeting was examined by expression of chloramphenicol acetyltransferase fusion proteins in trypanosomes and monkey cells. Compartmentalization was assessed by cell fractionation, differential detergent permeabilization, and immunofluorescence. The targeting signal of trypanosome phosphoglycerate kinase resides in the COOH-terminal hexapeptide, NRWSSL; a basic amino acid is not required. The minimal targeting signal is, as for mammalian cells, a COOH-terminal tripeptide related to -SKL. However, the acceptable degeneracy of the signal for glycosomal targeting in trypanosomes is considerably greater than that for peroxisomal targeting in mammals, with particularly relaxed requirements in the penultimate position.