Activation of p38 mitogen-activated protein kinase (p38) in spinal microglia is implicated in spinal nociceptive processing. Minocycline, a tetracycline derivative, displays selective inhibition of microglial activation, a function that is distinct from its antibiotic activity. In the present study we examined antinociceptive effects of intrathecal (IT) administration of minocycline in experimental models of inflammation-evoked hyperalgesia in addition to the effect of minocycline on stimulation-induced activation of p38 in spinal microglia. Intrathecal minocycline produced a dose-dependent reduction of formalin-evoked second-phase flinching behaviour in rats, and prevented thermal hyperalgesia induced by carrageenan injection into the paw. In contrast, systemic delivery (intraperitoneally) of minocycline inhibited the first but not the second phase of formalin-induced flinching, and it had no effect on carrageenan-induced hyperalgesia. Centrally mediated hyperalgesia induced by IT delivery of N-methyl-d-aspartate was completely blocked by IT minocycline. An increase in phosphorylation (activation) of p38 (P-p38) was observed in the dorsal spinal cord after carrageenan paw injection, assessed by both Western blotting and immunohistochemistry. The increased P-p38 immunoreactivity was seen primarily in microglia but also in a small population of neurons. Minocycline, at the IT dose that blocked carrageenan-induced hyperalgesia, also attenuated the increased P-p38 in microglia. In addition, minocycline suppressed lipopolysaccharide-evoked P-p38 in cultured spinal microglial cells. Taken together, these findings show that minocycline given IT produces a potent and consistent antinociception in models of tissue injury and inflammation-evoked pain, and they provide strong support for the idea that this effect is mediated by direct inhibition of spinal microglia and subsequent activation of p38 in these cells.
Antagonist studies show that spinal p38 mitogen-activated protein kinase plays a crucial role in spinal sensitization. However, there are two p38 isoforms found in spinal cord and the relative contribution of these two to hyperalgesia is not known. Here we demonstrate that the isoforms are distinctly expressed in spinal dorsal horn: p38a in neurons and p38b in microglia. In lieu of isoform selective inhibitors, we examined the functional role of these two individual isoforms in nociception by using intrathecal isoform-specific antisense oligonucleotides to selectively block the expression of the respective isoform. In these rats, down-regulation of spinal p38b, but not p38a, prevented nocifensive flinching evoked by intraplantar injection of formalin and hyperalgesia induced by activation of spinal neurokinin-1 receptors through intrathecal injection of substance P. Both intraplantar formalin and intrathecal substance P produced an increase in spinal p38 phosphorylation and this phosphorylation (activation) was prevented when spinal p38b, but not p38a, was down-regulated. Thus, spinal p38b, probably in microglia, plays a significant role in spinal nociceptive processing and represents a potential target for pain therapy.
Peripheral inflammation initiates changes in spinal nociceptive processing leading to hyperalgesia. Previously, we demonstrated that among 102 lipid species detected by LC-MS/MS analysis in rat spinal cord, the most notable increases that occur after intraplantar carrageenan are metabolites of 12-lipoxygenases (12-LOX), particularly hepoxilins (HXA 3 and HXB 3 ). Thus, we examined involvement of spinal LOX enzymes in inflammatory hyperalgesia. In the current work, we found that intrathecal (IT) delivery of the LOX inhibitor nordihydroguaiaretic acid prevented the carrageenan-evoked increase in spinal HXB 3 at doses that attenuated the associated hyperalgesia. Furthermore, IT delivery of inhibitors targeting 12-LOX (CDC, Baicalein), but not 5-LOX (Zileuton) dosedependently attenuated tactile allodynia. Similarly, IT delivery of 12-LOX metabolites of arachidonic acid 12(S)-HpETE, 12(S)-HETE, HXA 3 , or HXB 3 evoked profound, persistent tactile allodynia, but 12(S)-HpETE and HXA 3 produced relatively modest, transient heat hyperalgesia. The pronociceptive effect of HXA 3 correlated with enhanced release of Substance P from primary sensory afferents. Importantly, HXA 3 triggered sustained mobilization of calcium in cells stably overexpressing TRPV1 or TRPA1 receptors and in acutely dissociated rodent sensory neurons. Constitutive deletion or antagonists of TRPV1 (AMG9810) or TRPA1 (HC030031) attenuated this action. Furthermore, pretreatment with antihyperalgesic doses of AMG9810 or HC030031 reduced spinal HXA 3 -evoked allodynia. These data indicate that spinal HXA 3 is increased by peripheral inflammation and promotes initiation of facilitated nociceptive processing through direct activation of TRPV1 and TRPA1 at central terminals.eicosanoid | pain | central sensitization T issue injury and inflammation are associated with hyperalgesia mediated by facilitated spinal nociceptive processing that can be modulated by lipids derived from arachidonic acid (AA) and other polyunsaturated fatty acids (PUFA), including eicosanoids synthesized via three enzymatic pathways: (i) cyclooxygenase (COX)-prostaglandins (PG); (ii) 5-, 12-, and 12/15-lipoxygenases (LOX)-leukotrienes, hydroxyeicosatetraenoic acids (HETEs), hepoxilins (HXA 3 and HXB 3 ), lipoxins, resolvins, and protectins; and (iii) cytochrome P450-epoxyeicosatrienoic acids and HETEs (1). Substantial evidence indicates that peripheral injury or direct activation of spinal dorsal horn receptors [Neurokinin 1 (NK1), AMPA, and NMDA] increases eicosanoid formation and that spinal delivery of COX inhibitors reduces the associated hyperalgesia (2, 3). Recently, we reported that paw carrageenan increases spinal production of both COX and 12-LOX metabolites of AA, including 12(S)-HETE in cerebrospinal fluid (CSF) and hepoxilins in the lumbar spinal cord (4).Several groups point to a peripheral role for 5-and 12-LOX in nociception, as shown by antihyperalgesic actions of LOX inhibitors administered via systemic routes (5-9). It has been suggested that spinal 12-LOX may play a r...
Phospholipase A 2 (PLA 2 ) forms are expressed in spinal cord, and inhibiting spinal PLA 2 induces a potent antihyperalgesia. Here, we examined the antihyperalgesic effects after systemic and i.t. delivery of four compounds constructed with a common motif consisting of a 2-oxoamide with a hydrocarbon tail and a four-carbon tether. These molecules were characterized for their ability to block group IVA calcium-dependent PLA 2 (cPLA 2 ) and group VIA calcium-independent PLA 2 (iPLA 2 ) in inhibition assays using human recombinant enzyme. The rank ordering of potency in blocking group IVA cPLA 2 was AX048 (ethyl 4-[(2-oxohexadecanoyl)amino]butanoate), AX006 (4-[(2-oxohexadecanoyl)amino]butanoic acid), and AX057 (tert-butyl 4-[(2-oxohexadecanoyl)amino]butanoate) Ͼ AX010 (methyl 4-[(2-oxohexadecanoyl)amino]butanoate) and for inhibiting group VIA iPLA 2 was AX048, AX057 Ͼ AX006, and AX010. No agent altered recombinant cyclooxygenase activity. In vivo, i.t. (30 g) and systemic (0.2-3 mg/kg i.p.) AX048 blocked carrageenan hyperalgesia and after systemic delivery in a model of spinally mediated hyperalgesia induced by i.t. substance P (SP). The other agents were without activity. In rats prepared with lumbar i.t. loop dialysis catheters, SP evoked spinal prostaglandin E 2 (PGE 2 ) release. AX048 alone inhibited PGE 2 release. Intrathecal SR141617, a cannabinoid CB1 inhibitor at doses that blocked the effects of i.t. anandamide had no effect upon i.t. AX048. These results suggest that AX048 is the first systemically bioavailable compound with a significant affinity for group IVA cPLA 2 , which produces a potent antihyperalgesia. The other agents, although demonstrating enzymatic activity in cell-free assays, appear unable to gain access to the intracellular PLA 2 toward which their action is targeted.
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