Human secreted stabilin-1-interacting chitinase-like protein aggravates the inflammation associated with rheumatoid arthritis and is a potential macrophage inflammatory regulator in rodents.

OBJECTIVE: To study the relationship between the human secreted protein stabilin-1-interacting chitinase-like protein (SI-CLP) and rheumatoid arthritis (RA). METHODS: The expression of SI-CLP in peripheral blood mononuclear cells (PBMCs) and synovial fluid from patients with RA and the effects of cytokines on SI-CLP expression were examined by Western blotting. Fluorescence-activated cell sorting analysis was performed to investigate the binding between SI-CLP and cells. Bone marrow-derived macrophages were isolated from wild-type and SI-CLP(-/-) mice, and real-time quantitative polymerase chain reaction was performed to detect the levels of messenger RNA for cytokines or SI-CLP in SI-CLP- or cytokine-treated macrophages. Histologic studies were conducted to evaluate inflammation and the expression of interleukin-12 (IL-12), IL-13, and SI-CLP in lesions. Enzyme-linked immunosorbent assays were used to detect the cytokine levels in bone marrow-derived macrophages. Rats or mice with collagen-induced arthritis (CIA) and SI-CLP(-/-) mice were used to study the function of SI-CLP in RA. RESULTS: SI-CLP expression was increased in PBMCs and detectable in synovial fluid from patients with RA. Administration of SI-CLP to rats with CIA aggravated arthritis-associated inflammation. SI-CLP was specifically attached to the surface protein of macrophages, which elevated the expression of IL-1ß, IL-6, IL-12, and IL-13 in macrophages and mouse bone marrow-derived macrophages, up-regulating ERK phosphorylation. Moreover, SI-CLP was up-regulated by both IL-12 and IL-13 through JNK and JAK/STAT signaling, respectively. Knockout of SI-CLP resulted in a decrease in the expression of IL-1ß, IL-6, IL-12, and IL-13 and lower susceptibility to CIA compared with wild-type mice. SI-CLP treatment also aggravated arthritis-related inflammation in wild-type and SI-CLP(-/-) mice. CONCLUSION: SI-CLP functions as a regulator of the inflammatory response by macrophages. The decrease in inflammation-associated cytokine levels resulting from SI-CLP knockout may explain the lower susceptibility to CIA in SI-CLP(-/-) mice.

Temperature effects on neuronal membrane potentials and inward currents in rat hypothalamic tissue slices.

Preoptic-anterior hypothalamic (PO/AH) neurones sense and regulate body temperature. Although controversial, it has been postulated that warm-induced depolarization determines neuronal thermosensitivity. Supporting this hypothesis, recent studies suggest that temperature-sensitive cationic channels (e.g. vanilloid receptor TRP channels) constitute the underlying mechanism of neuronal thermosensitivity. Moreover, earlier studies indicated that PO/AH neuronal warm sensitivity is due to depolarizing sodium currents that are sensitive to tetrodotoxin (TTX). To test these possibilities, intracellular recordings were made in rat hypothalamic tissue slices. Thermal effects on membrane potentials and currents were compared in PO/AH warm-sensitive, temperature-insensitive and silent neurones. All three types of neurones displayed slight depolarization during warming and hyperpolarization during cooling. There were no significant differences in membrane potential thermosensitivity for the different neuronal types. Voltage clamp recordings (at -92 mV) measured the thermal effects on persistent inward cationic currents. In all neurones, resting holding currents decreased during cooling and increased during warming, and there was no correlation between firing rate thermosensitivity and current thermosensitivity. To determine the thermosensitive contribution of persistent, TTX-sensitive currents, voltage clamp recordings were conducted in the presence of 0.5 microm TTX. TTX decreased the current thermosensitivity in most neurones, but there were no resulting differences between the different neuronal types. The present study found no evidence of a resting ionic current that is unique to warm-sensitive neurones. This supports studies suggesting that neuronal thermosensitivity is controlled, not by resting currents, but rather by currents that determine rapid changes in membrane potential between successive action potentials.