Gary Weisinger

PK 11195 attenuates kainic acid-induced seizures and alterations in peripheral-type benzodiazepine receptor (PBR) protein components in the rat brain

Peripheral‐type benzodiazepine receptors (PBR) are located in glial cells in the brain and in peripheral tissues. Mitochondria form the primary location for PBR. Functional PBR appear to require at least three components: an isoquinoline binding protein, a voltage‐dependent anion channel, and an adenine nucleotide carrier. In the present study, rats received intraperitoneal kainic acid injections, which are known to cause seizures, neurodegeneration, hyperactivity, gliosis, and a fivefold increase in PBR ligand binding density in the hippocampus. In the forebrain of control rats, hippocampal voltage‐dependent anion channel and adenine nucleotide carrier abundance was relatively low, while isoquinoline binding protein abundance did not differ between hippocampus and the rest of the forebrain. One week after kainic acid injection, isoquinoline binding protein abundance was increased more than 20‐fold in the hippocampal mitochondrial fraction. No significant changes were detected regarding hippocampal voltage‐dependent anion channel and adenine nucleotide carrier abundance. Pre‐treatment with the isoquinoline PK11195, a specific PBR ligand, attenuated the occurrence of seizures, hyperactivity, and increases in isoquinoline binding protein levels in the hippocampus, which usually follow kainic acid application. These data suggest that isoquinoline binding protein may be involved in these effects of kainic acid injections.

The 5 lipoxygenase system in the vasculature: Emerging role in health and disease

Activation of the 5 lipoygenase (5LO) system within the vascular bed requires the presence of several cell types with distinct transcellular cross-talk mechanisms, resulting in the generation of 5LO produced metabolites and increased expression of receptors for these metabolites in vascular cells. The key products in this system, the leukotriens LTB4, LTC4 and LTD4, are potent mediators of vascular inflammation initiated by white blood cells and sustained or propagated thereafter through amplified metabolite generation and direct effects in endothelial and vascular smooth muscle cells. Leukotrienes act to enhance cell permeability and increase oxidative stress, vascular smooth muscle cell migration and arterial tone. 5LO activation is highly regulated, and is apparently both model/species-specific and region-specific. 5LO activation is also linked to plaque progression, plaque stability, activation of matrix metalloproteinases, propensity to coronary and cerebrovascular events and the evolution of aortic aneurysms. Genetic variants in the 5LO activating protein are strongly linked to increased cardiovascular risk and may serve as useful markers for future therapy targeting down regulation of 5LO expression and activity as a means to combat cardiovascular disease.

Aldosterone up‐regulates 12‐ and 15‐lipoxygenase expression and LDL oxidation in human vascular smooth muscle cells

Several lines of evidence suggest that aldosterone excess may have detrimental effects in the cardiovascular system, independent of its interaction with the renal epithelial cells. Here we examined the possibility that aldosterone modulates 12‐ and/or 15‐lipoxygenase (LO) expression/activity in human vascular smooth muscle cells (VSMC), in vitro, thereby potentially contributing to both vascular reactivity and atherogenesis. Following 24 h treatment of VSMC with aldosterone (1 nmol/L), there was a ∼2‐fold increase in the generation rate of 12 hydroxyeicosatetraenoic acid (12‐HETE), 70% increase in platelet type 12‐LO mRNA expression (P < 0.001) along with a ∼3‐fold increase in 12‐LO protein expression, which were blocked by the mineralocorticoid receptor (MR) antagonists spironolactone (100 nmol/L) and eplerelone (100 nmol/ml). Additionally, aldosterone (1 nmol/L; 24 h) increased the production of 15‐HETE (50%; P < 0.001) and the expression of 15‐LO type 2 mRNA (50%; P < 0.05) (in VSMC). Aldosterone also increased the 12‐ and 15‐LO type 2 mRNA expression in a line of human aortic smooth muscle cells (T/G HA‐VSMC) (60% and 50%, respectively). Aldosterone‐induced 12‐ and 15‐LO type 2 mRNA expressions were blocked by the EGF‐receptor antagonist AG 1478 and by the MAPK‐kinase inhibitor UO126. Aldosterone‐treated VSMC also showed increased LDL oxidation, (∼2‐fold; P < 0.001), which was blocked by spironolactone. In conclusion, aldosterone increased 12‐ and 15‐LO expression in human VSMC, in association with increased 12‐ and 15‐HETE generation and enhanced LDL oxidation and may directly augment VSMC contractility, hypertrophy, and migration through 12‐HETE and promote LDL oxidation via the pro‐oxidative properties of these enzymes. J. Cell. Biochem. 108: 1203–1210, 2009.

Anti-thyroid cancer properties of a novel isoflavone derivative, 7-(O)-carboxymethyl daidzein conjugated to N-t-Boc-hexylenediamine in vitro and in vivo

The incidence of thyroid cancer is up to 3 folds higher in women than in men, suggesting that estrogenic effects may be involved in the pathogenesis of this malignancy. Here, we explore whether or not human thyroid cancer cell growth can be curbed by a novel isoflavone derivative generated in our laboratory, the N-t-Boc-hexylenediamine derivative of 7-(O)-carboxymethyl daidzein (cD-tboc). With the exception of the follicular cancer cell line WRO, estrogen receptor (ER)α mRNA was only marginally expressed in cell lines derived from papillary (NPA), follicular (MRO), anaplastic thyroid carcinoma (ARO) such that the expression of estrogen receptor (ER) βmRNA was more abundant than that of ERα mRNA in these cell types. Estradiol-17β (E2; 0.03-300nmol/l) per se increased proliferation in all four cell-types. The ERβ-specific agonist DPN increased [(3)H]-thymidine incorporation in all four thyroid cancer cell lines, whereas the ERα-specific agonist PPT increased growth only in NPA and WRO. By contrast, cD-tboc, derived from the weak estrogen daidzein, did not cause cell growth and dose-dependently diminished cell growth in all four cell lines via apoptosis and not necrosis, as detected by the release of histone-DNA fragments. The cytotoxic growth inhibitory effect of cD-tboc in these cells was modulated by E2 and the general caspase inhibitor Z-VAD-FMK, and the magnitude of this salvage was cell type-and dose-dependent. When nude mice carrying ARO thyroid xenografts were treated with cD-tboc, tumor volume decreased significantly, and no apparent toxicity was observed. These results suggest that cD-tboc may be a promising agent for therapy of thyroid carcinoma either alone or in combination with existing cytotoxic drugs.

Growth inhibition of human thyroid carcinoma and goiter cells in vitro by the isoflavone derivative 7-(O)-carboxymethyl daidzein conjugated to N-t-boc-hexylenediamine.

BACKGROUND Estrogens may enhance thyroid cancer cell growth. We have recently reported that a novel isoflavone-derived anti-estrogenic compound developed in our laboratory, the N-t-boc-hexylenediamine derivative of 7-(O)-carboxymethyl daidzein (cD-tboc), can induce apoptosis and retard growth in human thyroid carcinoma cell lines through inhibitory interaction on estrogen receptor β. Here we tested the hypothesis that cD-tboc can likewise retard cell growth in cultured human thyroid papillary carcinoma cells, normal thyroid cells, and goiter cells removed during thyroidectomy. METHODS In vitro experiments in cultured human thyroid normal, goiter, and papillary thyroid carcinoma (PTC) cells were performed. Estrogen receptors α and β (ERα and ERβ), DNA synthesis and creatine kinase (a marker of estrogenic genomic response), and the effects of cD-tboc on DNA synthesis in cultured human PTC cells were assessed. RESULTS First, all cell types thus harvested and grown in culture expressed both ERα and ERβ, with a variably higher abundance of ERβ over ERα seen in the goiter and PTC cells, but not in the normal thyroid cells. Second, DNA synthesis and creatine kinase were increased in response to estradiol-17β (E2), the ERα agonist propyl-pyrazole-trisphenol as well as the ERβ agonist diarylpropionitrile. Third, cD-tboc dose-dependently inhibited DNA synthesis in cultured human PTC cells (-65%) and to a lesser extent in goiter cells (∼-30%). CONCLUSION This study provides the first evidence that cD-tboc can act to inhibit growth in primary cultures of human PTC cells and goiter cells removed during thyroidectomy. Whether this can be utilized for the treatment of human thyroid cancer and/or goiter remains to be explored.