Electrophilic neurite outgrowth-promoting prostaglandin (NEPP) compounds protect neurons from oxidative insults. At least part of the neuroprotective action of NEPPs lies in induction of hemeoxygenase-1 (HO-1), which, along with other phase II enzymes, serve as a defense system against oxidative stress. Here, we found that, by using fluorescent tags and immunoprecipitation assays, NEPPs are taken up preferentially into neurons and bind in a thiol-dependent manner to Keap1, a negative regulator of the transcription factor Nrf2. By binding to Keap1, NEPPs prevent Keap1-mediated inactivation of Nrf2 and, thus, enhance Nrf2 translocation into the nucleus of cultured neuronal cells. In turn, Nrf2 binds to antioxidant͞ electrophile-responsive elements of the HO-1 promoter to induce HO-1 expression. Consistent with this notion, NEPP induction of an HO-1 reporter construct is prevented if the antioxidant-responsive elements are mutated. We show that NEPPs are neuroprotective both in vitro from glutamate-related excitotoxicity and in vivo in a model of cerebral ischemia͞reperfusion injury (stroke). Our results suggest that NEPPs prevent excitotoxicity by activating the Keap1͞ Nrf2͞HO-1 pathway. Because NEPPs accumulate preferentially in neurons, they may provide a category of neuroprotective compounds, distinct from other electrophilic compounds such as tertbutylhydroquinone, which activates the antioxidant-responsive element in astrocytes. NEPPs thus represent a therapeutic approach for stroke and neurodegenerative disorders.hemeoxygenase-1 ͉ middle cerebral artery occlusion ͉ neurite outgrowth-promoting prostaglandin ͉ stroke ͉ neurodegenerative diseases
Prostaglandins (PGs) such as Δ12-PGJ2 and Δ7-PGA1 methyl ester that possess a cross-conjugated dienone unit exhibit unique antitumor and antiviral activities independent of intracellular cAMP levels. These compounds are transported reversibly into cultured cells and accumulate in nuclei via covalent interaction, eliciting growth inhibition. PGA1 methyl ester, a simple cyclopentenone analog, is less potent. The unique cellular behavior of the dienone PGs correlates well with their chemical properties. The PGs react specifically with thiol nucleophiles such as glutathione. Michael addition of thiols to Δ7-PGA1 methyl ester, an alkylidenecyclopentenone derivative, occurs facilely at the endocyclic C(11) position rather than at the C(7) position. This process is reversible, and in solution phase, the adducts are in equilibrium with considerable amounts of free PG and thiols. However, the reaction of this PG with Sepharose-bound thiols, regarded to be plausible mimics of protein thiols, is irreversible, and the resulting adducts are dissociated only by alkali treatment. On the other hand, PGA1 methyl ester reacts with soluble or polymer-anchored thiols at lower rates than Δ7-PGAl methyl ester, but the resulting thiol adducts are substantially more stable than those of the dienone PGs. This tendency of the PGA1 methyl ester causes its equilibrium to shift to the adduct formation. The reversibility of the Michael reaction of PGs with thiols is consistent with their intracellular behavior and biological activities. Since glutathione adducts of PGs have no antiproliferative activities for cancer cells, the intracellular free PGs are presumed to interact with target molecules to cause cell growth inhibition. The involvement of the ATP-dependent glutathione S-conjugate export pump (GS-X pump) in the efflux of PGs is discussed. Thus, the marked difference in potency of the dienone and enone PGs is explained by considering the combined kinetic and thermodynamic properties and the action of the GS-X pump.
Previously we found that some cyclopenteone prostaglandin derivatives (PGs), referred to as neurite outgrowth-promoting PGs (NEPPs), have dual biological activities of promoting neurite outgrowth and preventing neuronal death [Satoh et al. (2000) J. Neurochem., 75, 1092-1102; Satoh et al. (2001) J. Neurochem., 77, 50-62; Satoh et al. (2002) In Kikuchi, II. (ed.), Strategenic Medical Science Against Brain Attack. Springer-Verlag, Tokyo, pp. 78-93]. To investigate possible cellular mechanisms of the neuroprotective effects, we performed oligo hybridization-based DNA array analysis with mRNA isolated from HT22, a cell line that originated from a mouse hippocampal neuron. Several transcripts up-regulated by NEPP11 were identified. Because heme oxygenase 1 (HO-1) mRNA was the most prominently induced and was earlier reported to protect neuronal and non-neuronal cells against oxidative stress, we focused on it as a possible candidate responsible for the neuroprotective effects. We found NEPP11 to induce HO-1 protein (32 kDa) in HT22 cells in both the presence and the absence of glutamate, whereas non-neuroprotective prostaglandins (PGs) Delta12-PGJ2 or PGA2 did not. Overexpression of HO-1-green fluorescence protein (GFP) fusion protein significantly protected HT22 cells against oxidative glutamate toxicity, whereas that of GFP alone did not. Furthermore, biliverdin and bilirubin, products of HO-1 enzymatic activity on heme, protected HT22 cells from oxidative glutamate toxicity. These results, together with our previous results, suggest that NEPP11 activates the expression of HO-1 and that HO-1 produces biliverdin and bilirubin, which result in the inhibition of neuronal death induced by oxidative stress. NEPP11 is the first molecular probe reported to have a neuroprotective action through induction of HO-1 in neuronal cells.
Testosterone is one of the androgens synthesized from cholesterol as a precursor in the Leydig cells of testes. Since the ionization efficiency of testosterone in matrix-assisted laser desorption ionization (MALDI) is quite low, visualization of testosterone by using MALDI-imaging mass spectrometry (MALDI-IMS) has been considered difficult. To overcome this problem, we used two types of on-tissue derivatization techniques, which were achieved by pyridine sulfur trioxide and Girard's T (GT) reagent, to introduce a polar group into testosterone molecule with the aim to increase the sensitivity. Derivatization by use of GT reagent provided excellent results, superior to those obtained with pyridine sulfur trioxide, in terms of ionization efficiency, molecular specificity, and tissue damage. In GT derivatized testis tissues of mice treated with human chorionic gonadotropin (hCG), testosterone was broadly observed both inside and outside the seminiferous tubules by using an iMScope. To evaluate our imaging results, we performed quantification experiments of underivatized testosterone extracted from hCG-treated testes and control testes using LC-MS/MS. We confirmed the 256-fold concentration change between hCG-treated tissues and control tissues. We also confirmed the 228-fold change in detected peak intensities between hCG-treated tissue sections and control tissue sections in imaging results. We consider our tissue preparation methods for IMS provide high sensitivity with high precision. In addition, high-spatial definition IMS was also available, and we confirmed testosterone had mainly accumulated on the surface of the Leydig cells. Graphical abstract Girard's T-testosterone (GT-Ts) provides the fragment ion at m/z 343.24. Clear GT-Ts signal was detected in hCG treated mouse testis not only as spectra but also as a mass image.
microolecular design can overcome the metabolic instability of Delta7-PGA1, while maintaining its antitumor potency. Saturation of the C(13)-C(14) double bond enhances the biological stability but decreases the antiproliferative activity. Configurational inversion of the isomerase-sensitive C(12) stereocenter from the natural S to the unnatural R geometry not only enhances biological stability but also significantly suppresses the growth of the tumor cells. The 12R derivatives markedly increase the induction of p21, a Cdk inhibitor, leading to sharp cell cycle arrest at the G1 phase at a dose level so low that at this dose Delta7-PGA1 methyl ester scarcely exerts an effect. These conspicuous biological properties lead to long-term suppression of tumor cell growth. The structure-stability relationship demonstrates that the stability of prostaglandins (PGs) is crucially controlled by the C(12) configuration and is unaffected by the geometry of the hydroxy-bearing C(15). The successful design of antitumor PGs resistant to enzymatic metabolism provides a new strategy applicable to creating a useful PG for cancer chemotherapy.
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