Serum Proteomic Predictors of Calcification of Solitary Cysticercus Granuloma.

Solitary cysticercus granulomas (SCG), prevalent among Indian patients with new-onset seizures, either resolve completely or transform into calcified granulomas. This study aimed to identify serum proteins through liquid chromatography-tandem mass spectrometry that could predict calcification of SCGs in 20 patients with SCG with at least 6-months of follow-up. At a median follow-up of 14 months, the SCG had calcified (n = 5), resolved (n = 11), or persisted (n = 4). Two serum proteins, ECM1 and MST1, were present in significantly higher serum concentrations, and AZGP1 in significantly lower concentration in subjects with calcifying SCGs than in those with lesions that resolved or persisted. On multivariate analysis, only ECM1 (odds ratio: 1.7, 95% CI: 0-2.8) and MST1 (odds ratio: 3.3, 95% CI: 0-4.1) were independent predictors of calcification of SCG. Combining elevated levels of serum ECM1 and MST1 had a sensitivity of 100% and specificity of 100% in differentiating granulomas that calcified from those that resolved/persisted. Increased expression of serum ECM1 and MST1 in patients with SCG might predict calcification.

Ceramide-activated phosphatase mediates fatty acid-induced endothelial VEGF resistance and impaired angiogenesis.

Endothelial dysfunction, including endothelial hyporesponsiveness to prototypical angiogenic growth factors and eNOS agonists, underlies vascular pathology in many dysmetabolic states. We investigated effects of a saturated free fatty acid, palmitic acid (PA), on endothelial cell responses to VEGF. PA-pretreated endothelial cells had markedly diminished Akt, eNOS, and ERK activation responses to VEGF, despite normal VEGFR2 phosphorylation. PA inhibited VEGF-induced angiogenic cord formation in Matrigel, and PA-treated endothelial cells accumulated early species (C16) ceramide. The serine palmitoyltransferase inhibitor myriocin reversed these defects. Protein phosphatase 2A (PP2A) became more eNOS-associated in PA-treated cells; the PP2A inhibitor okadaic acid reversed PA-induced signaling defects. Mice fed a diet high in saturated fat for 2 to 3 weeks had impaired i) aortic Akt and eNOS phosphorylation to infused VEGF, ii) ear angiogenic responses to intradermal adenoviral-VEGF injection, and iii) vascular flow recovery to hindlimb ischemia as indicated by laser Doppler and αVß3 SPECT imaging. High-fat feeding did not impair VEGF-induced signaling or angiogenic responses in mice with reduced serine palmitoyltransferase expression. Thus, de novo ceramide synthesis is required for these detrimental PA effects. The findings demonstrate an endothelial VEGF resistance mechanism conferred by PA, which comprises ceramide-induced, PP2A-mediated dephosphorylation of critical activation sites on enzymes central to vascular homeostasis and angiogenesis. This study defines potential molecular targets for preservation of endothelial function in metabolic syndrome.

Pharmacologic modulators of soluble guanylate cyclase/cyclic guanosine monophosphate in the vascular system - from bench top to bedside.

Guanosine-dependent cyclic nucleotide second messenger signaling has been implicated as a pivotal mediator of vascular function under both homeostatic eutrophic conditions as well as in the inimical environs of injury and/or disease. This biological system is highly regulated through reciprocal, complimentary, and often redundant upstream and downstream molecular and cellular elements and feedback controls. Key endogenous factors of the guanosine-dependent cyclic nucleotide cascade include upstream gaseous activating ligands (nitric oxide, carbon monoxide), downstream substrates (cGMP-gated ion channels, cGMP-dependent protein kinases), and cGMP hydrolyzing phosphodiesterases. This intricate system also has capacity to "cross-talk" with parallel adenosine-dependent cyclic nucleotide machinery. Numerous complexes of ligands, enzymes, cofactors, and substrates present significant targets for pharmacologic modulation at the cellular, genetic, and/or molecular level eventuating therapeutically as constructive functional responses observed in vascular physiology and/or pathophysiology. Interestingly, emerging evidence based largely on transgenic mouse models challenges the historically accepted concept that this signaling system functions principally as a therapeutic modality in cardiac and vascular tissues. The general purpose of this update is to provide current information on recently described neoteric agents that impact multifaceted and critical cGMP-dependent signaling in the vascular system. Emphasis will be placed on novel agents that exert significant and often multiple actions on upstream and downstream sites and are capable of eliciting robust effects on guanosine-dependent cellular actions. Individual sections will be devoted to agents that rely on an intact and functional cyclase heme and those that operate independently of the sGC heme. Attention will be placed on the physiologic and pathophysiologic clinical manifestations of these pharmacologic regimens. This review will conclude with some thoughts for future directions for study and continued discovery of novel sGC/cGMP controllers in the vascular system at the basic science and clinical levels.

Analysis of nuclear transport signals in the human apurinic/apyrimidinic endonuclease (APE1/Ref1).

The mammalian abasic-endonuclease1/redox-factor1 (APE1/Ref1) is an essential protein whose subcellular distribution depends on the cellular physiological status. However, its nuclear localization signals have not been studied in detail. We examined nuclear translocation of APE1, by monitoring enhanced green fluorescent protein (EGFP) fused to APE1. APE1's nuclear localization was significantly decreased by deleting 20 amino acid residues from its N-terminus. Fusion of APE1's N-terminal 20 residues directed nuclear localization of EGFP. An APE1 mutant lacking the seven N-terminal residues (ND7 APE1) showed nearly normal nuclear localization, which was drastically reduced when the deletion was combined with the E12A/D13A double mutation. On the other hand, nearly normal nuclear localization of the full-length E12A/D13A mutant suggests that the first 7 residues and residues 8-13 can independently promote nuclear import. Both far-western analyses and immuno-pull-down assays indicate interaction of APE1 with karyopherin alpha 1 and 2, which requires the 20 N-terminal residues and implicates nuclear importins in APE1's nuclear translocation. Nuclear accumulation of the ND7 APE1(E12A/D13A) mutant after treatment with the nuclear export inhibitor leptomycin B suggests the presence of a previously unidentified nuclear export signal, and the subcellular distribution of APE1 may be regulated by both nuclear import and export.

Nitric oxide prevents aldose reductase activation and sorbitol accumulation during diabetes.

Increased glucose utilization by aldose reductase (AR) has been implicated in the development of diabetes complications. However, the mechanisms that regulate AR during diabetes remain unknown. Herein we report that several nitric oxide (NO) donors prevent ex vivo synthesis of sorbitol in erythrocytes obtained from diabetic or nondiabetic rats. Compared with erythrocytes of nondiabetic rats, the AR activity in the erythrocytes of diabetic rats was less sensitive to inhibition by NO donors or by AR inhibitors-sorbinil or tolrestat. Treatment with N(G)-nitro-L-arginine methyl ester (L-NAME), an inhibitor of NO synthesis, enhanced AR activity and sorbitol accumulation in tissues of nondiabetic rats. Application of transdermal nitroglycerin patches or treatment with L-arginine did not inhibit AR activity or sorbitol accumulation in the tissues of nondiabetic animals. Treatment with L-NAME increased, whereas treatment with L-arginine or nitroglycerine patches decreased AR activity and sorbitol content in tissues of diabetic rats. These observations suggest that NO maintains AR in an inactive state and that this repression is relieved in diabetic tissues. Thus, increasing NO availability may be a useful strategy for inhibiting the polyol pathway and preventing the development of diabetes complications.