In humans, the acute inflammatory reaction caused by ultraviolet (UV) radiation is well studied and the sensory changes that are found have been used as a model of cutaneous hyperalgesia. Similar paradigms are now emerging as rodent models of inflammatory pain. Using a narrowband UVB source, we irradiated the plantar surface of rat hind paws. This produced the classical feature of inflammation, erythema, and a significant dose-dependent reduction in both thermal and mechanical paw withdrawal thresholds. These sensory changes peaked 48h after irradiation. At this time there is a graded facilitation of noxious heat evoked (but not basal) c-fos-like immunoreactivity in the L4/5 segments of the spinal cord. We also studied the effects of established analgesic compounds on the UVB-induced hyperalgesia. Systemic as well as topical application of ibuprofen significantly reduced both thermal and mechanical hyperalgesia. Systemic morphine produced a dose-dependent and naloxone sensitive reversal of sensory changes. Similarly, the peripherally restricted opioid loperamide also had a dose-dependent anti-hyperalgesic effect, again reversed by naloxone methiodide. Sequestration of NGF, starting at the time of UVB irradiation, significantly reduced sensory changes. We conclude that UVB inflammation produces a dose-dependent hyperalgesic state sensitive to established analgesics. This suggests that UVB inflammation in the rat may represent a useful translational tool in the study of pain and the testing of analgesic agents.
Nerve growth factor (NGF) promotes cell survival via binding to the tyrosine kinase receptor A (TrkA). Its precursor, proNGF, binds to p75NTR and sortilin receptors to initiate apoptosis. Current disagreement exists over whether proNGF acts neurotrophically following binding to TrkA. As in Alzheimer’s disease the levels of proNGF increase and TrkA decrease, it is important to clarify the properties of proNGF. Here, wild‐type and cleavage‐resistant mutated forms (M) of proNGF were engineered and their binding characteristics determined. M‐proNGF and NGF bound to p75NTR with similar affinities, whilst M‐proNGF had a lower affinity than NGF for TrkA. M‐proNGF behaved neurotrophically, albeit less effectively than NGF. M‐proNGF addition resulted in phosphorylation of TrkA and ERK1/2, and in PC12 cells elicited neurite outgrowth and supported cell survival. Conversely, M‐proNGF addition to cultured cortical neurons initiated caspase 3 cleavage. Importantly, these biological effects were shown to be mediated by unprocessed M‐proNGF. Surprisingly, binding of the pro region alone to TrkA, at a site other than that of NGF, caused TrkA and ERK1/2 phosphorylation. Our data show that M‐proNGF stimulates TrkA to a lesser degree than NGF, suggesting that in Alzheimer brain the increased proNGF : NGF and p75NTR : TrkA ratios may permit apoptotic effects to predominate over neurotrophic effects.
Leptospirosis is a global public health problem, primarily in the tropical developing world. The pathogenic mechanisms of the causative agents, several members of the genus Leptospira, have been underinvestigated. The exception to this trend has been the demonstration of the binding of pathogenic leptospires to the extracellular matrix (ECM) and its components. In this work, interactions of Leptospira interrogans bacteria with mammalian cells, rather than the ECM, were examined. The bacteria bound more efficiently to the cells than to the ECM, and a portion of this cell-binding activity was attributable to attachment to glycosaminoglycan (GAG) chains of proteoglycans (PGs). Chondroitin sulfate B PGs appeared to be the primary targets of L. interrogans attachment, while heparan sulfate PGs were much less important. Inhibition of GAG/PGmediated attachment resulted in partial inhibition of bacterial attachment, suggesting that additional receptors for L. interrogans await identification. GAG binding may participate in the pathogenesis of leptospirosis within the host animal. In addition, because GAGs are expressed on the luminal aspects of epithelial cells in the proximal tubules of the kidneys, this activity may play a role in targeting the bacteria to this critical site.
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