Elucidation of the ATP7B N-Domain Mg2+-ATP Coordination Site and Its Allosteric Regulation

The diagnostic of orphan genetic disease is often a puzzling task as less attention is paid to the elucidation of the pathophysiology of these rare disorders at the molecular level. We present here a multidisciplinary approach using molecular modeling tools and surface plasmonic resonance to study the function of the ATP7B protein, which is impaired in the Wilson disease. Experimentally validated in silico models allow the elucidation in the Nucleotide binding domain (N-domain) of the Mg2+-ATP coordination site and answer to the controversial role of the Mg2+ ion in the nucleotide binding process. The analysis of protein motions revealed a substantial effect on a long flexible loop branched to the N-domain protein core. We demonstrated the capacity of the loop to disrupt the interaction between Mg2+-ATP complex and the N-domain and propose a role for this loop in the allosteric regulation of the nucleotide binding process

Further evidence for a gamma/delta T cell receptor-mediated TCT.1/CD48 recognition

We have demonstrated recently that a molecule, termed TCT.1 (Blast-1/CD48), is recognized on the surface of target cells by a series of alloreactive gamma/delta T cell clones generated from PBL of one healthy individual (designated E). Southern blot analyses suggested that these clones express a TCR associating a V3-JP2-C2 gamma-chain and V1-D-J1-C delta-chain. In the present study, we have developed from PBL of a second normal donor (designated G) a novel series of gamma/delta cloned T cell lines with similar functional activity (i.e., specific recognition of TCT.1 protein). The TCR-gamma- and delta-chain nucleotide sequences of both the E and G clones were determined. Results show that 1) sequences from all the clones are identical in each individual donor, 2) the delta-chains expressed by the E and the G clones are encoded by distinct gene rearrangements including V1-D-J-delta-1 and V1-D-J-delta-2, respectively, 3) the gamma-chains expressed by the E and the G clones are encoded by the same genomic variable elements, namely V-gamma-3 and JP2, whereas the junctional regions are distinct. Because the latter rearrangement is very infrequent in human peripheral blood, these data support the view that TCT.1/CD48 recognition is likely to be TCR dependent

T cell target 1 (TCT.1): A novel target molecule for human non-major histocompatibility complex-restricted T lymphocytes

We have studied two γ/δ T cell clones, E102 and E117, generated in a mixed lymphocyte culture using an allogeneic Epstein-Barr virus-transformed B cell line, E418. These clones were both found to express a molecular form of T cell receptor (TCR) infrequent in human peripheral blood, associating a V1-J1-C δ chain and a V3-JP2-C2 γ chain. Functionally, they appeared as cytotoxic T lymphocytes (CTL) with non-major histocompatibility complex (MHC) (class I and II) requiring cytotoxicity, able to kill both the immunizing (i.e., E418) and unrelated (e.g., K562, REX, F601, and KAS) target cells. A monoclonal antibody, anti-10H3, able to selectively inhibit the cytotoxic activity of the clones has been produced. This reagant defines a 43-kD molecule, designated TCT.1, with broad distribution in the hematopoietic system, that appears to be distinct from class I MHC gene products. A series of functional experiments using various effector/target cell combinations strongly suggested that TCT.1 may represent a unique TCR ligand involved in the interaction between these particular CTL clones and certain of the target cells tested, while others were likely to be recognized and killed through a TCR-independent natural killer-like pathway. Although further experimentation will be needed to strengthen our interpretation of the present data, this study provides additional evidence that some T lymphocytes, in particular of the γ/δ type, may interact specifically with target cells in a non-MHC class I/II-requiring fashion