Defective NF-kappaB Activation in Response to LPS in Type 1 Diabetes Dendritic Cells

Dendritic cells (DC) are the potent antigen presenting cells which modulate T cell responses to self or non-self antigens. DC play a significant role in the pathogenesis of autoimmune diseases, inflammation and infection, but also in the maintenance of tolerance. NF-kappaB, particularly RelB is a crucial pathway for myeloid DC differentiation and functional maturation. While the current paradigm is that mature, nuclear RelB+ DC prime T cells for immunity/autoimmunity and immature DC for tolerance, RelB-deficient mice paradoxically develop generalised systemic autoimmune inflammatory disease with myelopoiesis and splenomegaly. Previous studies suggested abnormal DC differentiation in healthy relatives of type 1 diabetes (t1dm) patients. Therefore, we compared NF- kB activation in monocyte-derived DC from t1dm and non-t1dm controls in response to LPS. While resting DC appeared normal, DC from 6 out of 7 t1dm patients but no t2dm or rheumatoid arthritis patients failed to translocate NF- kB subunits to the nucleus in response to LPS, along with a failure to up-regulate expression of cell surface CD40 and MHC class I. NF- kB subunit mRNA increased normally in t1dm DC after LPS. Both the classical or non-canonical NF- kB pathways were affected as both TNF-a and CD40 stimulation led to a similarly abnormal NF- kB response. In contrast, expression of phosphorylated p38 MAPK and pro-inflammatory cytokine production was intact. These abnormalities in NF- kB activation appear to be generally and specifically applicable at a post-translational level in t1dm, and have the capacity to profoundly influence immunoregulation in affected individuals.

IL-1 beta breaks tolerance through expansion of CD25(+) effector T cells

IL-1 is a key proinflammatory driver of several autoimmune diseases including juvenile inflammatory arthritis, diseases with mutations in the NALP/cryopyrin complex and Crohn's disease, and is genetically or clinically associated with many others. IL-1 is a pleiotropic proinflammatory cytokine; however the mechanisms by which increased IL-1 signaling promotes autoreactive T cell activity are not clear. Here we show that autoimmune-prone NOD and IL-1 receptor antagonist-deficient C57BL/6 mice both produce high levels of IL-1, which drives autoreactive effector cell expansion. IL-1 beta drives proliferation and cytokine production by CD4(+)CD25(+)FoxP3(-) effector/memory T cells, attenuates CD4(+)CD25(+)FoxP3(+) regulatory T cell function, and allows escape of CD4(+)CD25(-) autoreactive effectors from suppression. Thus, inflammation or constitutive overexpression of IL-1 beta in a genetically predisposed host can promote autoreactive effector T cell expansion and function, which attenuates the ability of regulatory T cells to maintain tolerance to self.

Use of methotrexate in older patients - A risk-benefit assessment

Methotrexate is eliminated almost entirely by the kidneys. The risk of methotrexate toxicity is therefore increased in patients with poor renal function, most likely as a result of drug accumulation. Declining renal function with age may thus be an important predictor of toxicity to methotrexate. Up to 60% of all patients who receive methotrexate for rheumatoid arthritis (RA) discontinue taking it because of adverse effects, most of which occur during the first year of therapy. Gastrointestinal complications are the most common adverse effects of methotrexate, but hepatotoxicity, haematological toxicity, pulmonary toxicity, lymphoproliferative disorders and exacerbation of rheumatic nodules have all been reported, Decreased renal function as a result of disease and/or aging appears to be an important determinant of hepatic, lymphoproli ferative and haematological toxicity, Concomitant use of low doses of folic acid has been recommended as an approach to limiting toxicity. Interactions between methotrexate and several nonsteroidal anti-inflammatory drugs have been reported, but they may not be clinically significant. However, caution is advised in the use of such combinations in patients with reduced renal function. More serious toxicities (e.g. pancytopenia) may result when other inhibitors of folate utilisation [e.g. cotrimoxazole (trimethoprim-sulfamethoxazole)] or inhibitors of renal tubular secretion (e.g. probenecid) are combined with methotrexate. Before starting low dose methotrexate therapy in patients with RA, a full blood count, liver function tests, renal function tests and chest radiography should be performed. Blood counts and liver function tests should be repeated at regular intervals. Therapeutic drug monitoring of methotrexate has also been suggested as a means of limiting toxicity. Patients with RA usually respond very favourably to low dose methotrexate therapy, and the probability of patients continuing their treatment beyond 5 years is greater than for other slow-acting antirheumatic drugs. Thus, given its sustained clinical utility and relatively predictable toxicity profile, low dose methotrexate is a useful addition to the therapy of RA.