Post-ischemic cyclooxygenase-2 expression is regulated by the extent of cerebral blood flow reduction in non-human primates

Synthesis and evaluation of a radioiodinated lumiracoxib derivative for the imaging of cyclooxygenase-2 expression

INTRODUCTION

Despite extensive attempts to develop cyclooxygenase (COX)-2 imaging radiotracers, no suitable positron emission tomography (PET)/single photon emission computed tomography (SPECT) tracers are currently available for in vivo imaging of COX-2 expression. The aims of this study were to synthesize and evaluate a radioiodinated derivative of lumiracoxib, 2-[(2-fluoro-6-iodophenyl)-amino]-5-methylphenylacetic acid (FIMA), which is structurally distinct from other drugs in the class and has weakly acidic properties, as a SPECT tracer for imaging COX-2 expression.

METHODS

The COX inhibitory potency was assessed by measuring COX-catalyzed oxidation with hydrogen peroxide. Cell uptake characteristics of (125)I-FIMA were assessed in control and linterfero/interferon-gamma-stimulated macrophages. The biodistribution of (125)I-FIMA was determined by the ex vivo tissue counting method in rats.

RESULTS

The COX-2 inhibitory potency of FIMA (IC(50)=2.46 microM) was higher than that of indomethacin (IC(50)=20.9 microM) and was comparable to lumiracoxib (IC(50)=0.77 microM) and diclofenac (IC(50)=0.98 microM). The IC(50) ratio (COX-1/COX-2=182) indicated FIMA has a high isoform selectivity for COX-2. (125)I-FIMA showed a significantly higher accumulation in COX-2 induced macrophages than in control macrophages, which decreased with nonradioactive FIMA in a concentration dependent manner. The biodistribution study showed rapid clearance of (125)I-FIMA from the blood and most organs including the liver and kidneys. No significant in vivo deiodination was observed with radioiodinated FIMA.

CONCLUSIONS

FIMA showed high inhibitory potency and selectivity for COX-2. Radioiodinated FIMA showed specific accumulation into COX-2 induced macrophages, no significant in vivo deiodination and rapid blood clearance. Radioiodinated FIMA deserves further investigation as a SPECT radiopharmaceutical for imaging COX-2 expression.

Contributions of cyclooxygenase-2 to neuroplasticity and neuropathology of the central nervous system

Cyclooxygenase (COX) enzymes, or prostaglandin-endoperoxide synthases (PTGS), are heme-containing bis-oxygenases that catalyze the first committed reaction in metabolism of arachidonic acid (AA) to the potent lipid mediators, prostanoids and thromboxanes. Two isozymes of COX enzymes (COX-1 and COX-2) have been identified to date. This review will focus specifically on the neurobiological and neuropathological consequences of AA metabolism via the COX-2 pathway and discuss the potential therapeutic benefit of COX-2 inhibition in the setting of neurological disease. However, given the controversy surrounding the use of COX-2 selective inhibitors with respect to cardiovascular health, it will be important to move beyond COX to identify which down-stream effectors are responsible for the deleterious and/or potentially protective effects of COX-2 activation in the setting of neurological disease. Important advances toward this goal are highlighted herein. Identification of unique effectors in AA metabolism could direct the development of new therapeutics holding significant promise for the prevention and treatment of neurological disorders.

Synthesis and evaluation of radioiodinated cyclooxygenase-2 inhibitors as potential SPECT tracers for cyclooxygenase-2 expression

Although several COX-2 inhibitors have recently been radiolabeled, their potential for imaging COX-2 expression remains unclear. In particular, the sulfonamide moiety of COX-2 inhibitors may cause slow blood clearance of the radiotracer, due to its affinity for carbonic anhydrase (CA) in erythrocytes. Thus, we designed a methyl sulfone-type analogue, 5-(4-iodophenyl)-1-[4-(methylsulfonyl)phenyl]-3-trifluoromethyl-1H-pyrazole (IMTP). In this study, the potential of radioiodinated IMTP was assessed in comparison with a (125)I-labeled celecoxib analogue with a sulfonamide moiety ((125)I-IATP).

METHODS

The COX inhibitory potency was assessed by measuring COX-catalyzed oxidation by hydrogen peroxide. The biodistribution of (125)I-IMTP and (125)I-IATP was determined by the ex vivo tissue counting method in rats. Distribution of the labeled compounds to rat blood cells was measured.

RESULTS

The COX-2 inhibitory potency of IMTP (IC(50) = 5.16 microM) and IATP (IC(50) = 8.20 microM) was higher than that of meloxicam (IC(50) = 29.0 microM) and comparable to that of SC-58125 (IC(50) = 1.36 microM). The IC(50) ratios (COX-1/COX-2) indicated the high isoform selectivity of IMTP and IATP for COX-2. Significant levels of (125)I-IMTP and (125)I-IATP were observed in the kidneys and the brain (organs known to express COX-2). The blood clearance of (125)I-IMTP was much faster than that of (125)I-IATP. Distribution of (125)I-IATP to blood cells (88.0%) was markedly higher than that of (125)I-IMTP (18.1%), which was decreased by CA inhibitors.

CONCLUSIONS

Our results showed a high inhibitory potency and selectivity of IMTP for COX-2. The substitution of a sulfonamide moiety to a methyl sulfone moiety effectively improved the blood clearance of the compound, indicating the loss of the cross reactivity with CA in (125)I-IMTP. (123)I-IMTP may be a potential SPECT radiopharmaceutical for COX-2 expression.

Neuronal prostaglandin endoperoxide synthase 2 responses to oxygen and glucose deprivation are mediated by mitogen-activated protein kinase ERK1/2

Prostanoids in the central nervous system define an important linkage between blood pressure and hormonal responses to hypotension/ischemia. Prostaglandin endoperoxide synthase (PGHS)-2, the inducible isoform of this enzyme, is induced by cerebral hypoperfusion/ischemia. To investigate the mechanism of the PGHS-2 gene expression in response to cerebral hypoperfusion/ischemia in neurons, we used a cell culture model (human SK-N-AS cells) to mimic the oxygen and glucose deprivation (OGD) that usually results from ischemia. Whereas OGD stimulated robust increases in PGHS-2 mRNA abundance, neither oxygen nor glucose deprivation alone was effective. Our data demonstrated that induction of both PGHS-2 mRNA and protein reached peak levels ( approximately 10 fold) after 6 h OGD. This was partially blocked by the inhibition of mitogen-activated protein kinase (MAPK) p38, and was almost completely blocked by the inhibition of extracellular signal-related kinases 1/2 (ERK1/2 or p44/42), another MAPK. These results indicate that PGHS-2 gene expression is induced by oxygen and glucose deprivation synergistically in neurons, and this induction is mediated by one or more members of the MAPK family.

Bilateral induction of the S-100A9 gene in response to spreading depression is modulated by the cyclooxygenase-2 activity

Cyclooxygenase-2 (COX-2) was reported to be induced in the infarcted human brain. Spreading depression (SD) is thought to play a role in this induction. In this study, we correlated the expression of SD-associated genes with COX-2 production in brains after SD. Rats were divided into 3 groups: rats that did not undergo SD (group I saline controls, n=7), rats that underwent unilateral SD as a result of KCl application (group II, n=9), and rats that were pretreated with the selective COX-2 inhibitor, JTE-522 3 h before the induction of SD (group III, n=7). The expression of the SD-associated genes, S-100A9, and mitogen-activated proteinkinase phosphatase (cpg21) was analyzed 2 h later using a cDNA array. In group II, COX-2 and cpg21 mRNA expression, as determined by RT-PCR, were significantly upregulated in the hemisphere undergoing SD. While the expression of S-100A9 mRNA was bilaterally upregulated in these animals, this expression was significantly reduced in group III, and was accompanied by reduced bilateral production of PGE(2). Thus, the bilateral induction of expression of the S-100A9 gene in response to SD was associated with COX-2 activation.