Interaction of a small molecule Natura-α and STAT3-SH2 domain to block Y705 phosphorylation and inhibit lupus nephritis.

A small molecule, Natura-α, a clinical stage investigational new drug for certain inflammatory diseases, has been evaluated for drug interaction with STAT3 and inhibiting systemic lupus erythematosus (SLE). Studies have revealed that it selectively inhibits STAT3-Y705 phosphorylation and, suppresses pro-inflammatory cytokines, stimulates anti-inflammatory cytokine IL-10, thereby skewing T cell differentiation from the Th1/Th17 lineages toward the Treg lineage. The potential binding of the drug to STAT3 protein has been investigated with a computational modeling and docking simulation using X-ray crystal structure of the STAT3ß homodimer. Natura-α was shown to directly bind to SH2 domain of STAT3 and forms H-bonds with amino acids Glu594 and Arg609. The phosphorylation of Y705 was prevented and making the formation of STAT3 homodimer impossible, thereby blocking STAT3 activation. The in vivo efficacy of Natura-α in SLE was evaluated in a bioassay with NZB/W female mice. Mice at week 19 were given orally Natura-α at 25 or 75 mg/kg, once a day, 5 days per week for 29 weeks. Mice were monitored weekly until 52 weeks of age. Both dosages were effective to reduce proteinuria and significantly improved animal survival rate. The renal functions were preserved with glomerular lesions reversed, which paralleled with decreased C3 deposit. The numbers of kidney cells stained with phosphorylated STAT3-Y705 remarkably decreased, demonstrating blocking of Y-705 phosphorylation by the treatment. Since NZB/W mice develop nephritis which resembles SLE in men, the data strongly suggests that Natura-α may be a potential effective therapeutic agent for lupus.

Generation of cytotoxic T-cell lines using overlapping pentadecapeptides derived from conserved regions of the adenovirus hexon protein.

Many of the 51 serotypes of adenovirus have been associated with clinically relevant infection. Adenovirus can disseminate rapidly in patients with a compromised immune system, such as that which occurs secondary to haematopoietic progenitor-cell transplantation. The higher rate of infection in recipients of T cell-depleted grafts and in those undergoing T cell-targeted treatment during graft versus host disease demonstrates the importance of a T-cell response in preventing disseminated infection. Studies have shown that the memory response to adenovirus is directed primarily to the hexon protein and is dominated by CD4+ T cells, probably due to the ability of the virus to block its presentation on HLA class I antigens. We have developed an approach to expand adenovirus-specific T cells using a pool of overlapping pentadecapeptides derived from selected conserved regions of hexon. We characterized responses to identify the peptides that are recognized, the responding T-cell subsets and their HLA restriction. Of eight lines that were characterized extensively, seven included both CD4+ and CD8+ T cells and each recognized between two and eight unique peptide sequences. By focusing the response on the conserved sequences of hexon, the cell lines are likely to recognize most of the serotypes responsible for clinically relevant disease. The 15 aa peptides used to prime the responses are more likely than whole virus or longer peptides to expand the less frequent CD8+ memory subset. Lines prepared by using our method may be more effective in adoptive immunotherapy protocols designed to prevent or treat disseminated adenovirus infections in high-risk patients.