A Molecular Analysis of the Shared Epitope Hypothesis: Binding of Arthritogenic Peptides to DRB1*04 Alleles.

OBJECTIVE: The shared epitope hypothesis posits that amino acids QR/KRAA in positions 70-74 of the DRΒ1 chain are responsible for rheumatoid arthritis susceptibility. However, even DRB1*04 alleles containing the shared epitope vary greatly with respect to degrees of susceptibility. This study was undertaken to conduct a molecular examination of the shared epitope hypothesis by measuring binding of arthritogenic peptides to susceptibility and resistance alleles. METHODS: We measured binding of native and citrullinated forms of vimentin(66-78) and α-enolase(11-25) and noncitrullinated type II collagen(258-272) to 88 class II alleles on Luminex beads (which includes alleles of many varying degrees of susceptibility and resistance). We expressed DRΒ1*04:01, *04:02, and *08:01 in T2 cells and mutated DRΒ1*04:01 at positions 67, 70, 71, 74, and 86 to corresponding residues in DRB1*04:02, *04:03, *04:04, *04:05, and *08:01. Finally, we measured responses of 4 DRΒ1*04:01 restricted collagen(258-272) T cell hybridomas against wild-type DRΒ1*04:01, *04:02, and all mutated alleles. RESULTS: The most susceptible allele, DRΒ1*04:01, preferentially bound citrullinated vimentin(66-78) and citrullinated α-enolase(11-25) over the native forms. DRΒ1*04:02 exhibited no preference for citrullinated peptides, and *08:01 preferred native peptides. Similarly, DRB1*04:01 bound collagen(258-272) , but *04:02 and *08:01 did not. Mutating DRΒ1*04:01 at positions 70, 71, 74, and 86 to the corresponding residues in DRΒ1*04:02 or *08:01 dramatically reduced the specificity for citrullinated peptides and collagen(258-272) binding. CONCLUSION: These observations demonstrate that while amino acids at positions 70, 71, and 74 within the shared epitope in DRΒ1 mediate binding and T cell responses of arthritogenic peptides, position 86 outside the shared epitope also plays a critical role.

Cigarette tar phenols impede T cell cycle progression by inhibiting cyclin-dependent kinases.

Cigarette smoking causes profound suppression of pulmonary T cell responses, which is associated with increased susceptibility to respiratory tract infections and decreased tumor surveillance. We previously demonstrated that the phenolic compounds in cigarette tar inhibit blastogenesis and interfere with human T cell cycle progression. To identify the mechanism by which cell cycle arrest occurs, we examined the effects of these compounds on cyclin-dependent kinases (Cdk) that control the G0/G1 transition. We found that hydroquinone inhibited induction of Cdk4 and Cdk6 kinase activities by >80%, while catechol and phenol were markedly less potent. HQ did not affect mitogenic induction of the Cdk6 protein, but inhibited expression of cyclin D3 by >90% resulting in a dramatic reduction in proper Cdk6/Cyclin D3 complex formation.

Acrolein in cigarette smoke inhibits T-cell responses.

BACKGROUND: Cigarette smoking inhibits T-cell responses in the lungs, but the immunosuppressive compounds have not been fully identified. Cigarette smoke extracts inhibit IL-2, IFN-gamma, and TNF-alpha production in stimulated lymphocytes obtained from peripheral blood, even when the extracts were diluted 100-fold to 1000-fold. OBJECTIVE: The objective of these studies was to identify the immunosuppressive compounds found in cigarette smoke. METHODS: Gas chromatography/mass spectroscopy and HPLC were used to identify and quantitate volatile compounds found in cigarette smoke extracts. Bioactivity was measured by viability and production of cytokine mRNA and protein levels in treated human lymphocytes. RESULTS: The vapor phase of the cigarette smoke extract inhibited cytokine production, indicating that the immunosuppressive compounds were volatile. Among the volatile compounds identified in cigarette smoke extracts, only the alpha,beta-unsaturated aldehydes, acrolein (inhibitory concentration of 50% [IC50] = 3 micromol/L) and crotonaldehyde (IC50 = 6 micromol/L), exhibited significant inhibition of cytokine production. Although the levels of aldehydes varied 10-fold between high-tar (Camel) and ultralow-tar (Carlton) extracts, even ultralow-tar cigarettes produced sufficient levels of acrolein (34 micromol/L) to suppress cytokine production by >95%. We determined that the cigarette smoke extract inhibited transcription of cytokine genes. The inhibitory effects of acrolein could be blocked with the thiol compound N-acetylcysteine. CONCLUSION: The vapor phase from cigarette smoke extracts potently suppresses cytokine production. The compound responsible for this inhibition appears to be acrolein.