Selective HIF-1 Regulation under Nonhypoxic Conditions by the p42/p44 MAP Kinase Inhibitor PD184161.

Hypoxia-inducible factor-1 (HIF-1) is a key gene regulator for cellular adaptation to low oxygen. In addition to hypoxia, several nonhypoxic stimuli, including hormones and growth factors, are essential for cell-specific HIF-1 regulation. Our studies have highlighted angiotensin II (AngII), a vasoactive hormone, as a potent HIF-1 activator in vascular smooth muscle cells (VSMC). AngII increases HIF-1 transcriptional activity by modulating specific signaling pathways. In VSMC, p42/p44 mitogen-activated protein kinase (MAPK) pathway activation is essential for HIF-1-mediated transcription during AngII treatment. The present study shows that PD184161, a potent MEK1/2 inhibitor, is an HIF-1 blocker in Ang II-treated VSMC. Unlike PD98059, a widely-used MEK1/2 inhibitor, we found that PD184161 blocked AngII-driven HIF-1α protein induction in a dose-dependent manner. Interestingly, the effect of PD184161 was specific to nonhypoxic activators, since HIF-1α induction by hypoxia (1% O2) was unaffected under similar conditions. VSMC treatment with MG132, a proteasome inhibitor, indicated that PD184161 influenced HIF-1α protein stability. PD184161 also increased HIF-1α binding to von Hippel-Lindau tumor suppressor protein, an E3 ligase component and an indication of HIF-1α hydroxylation. Finally, we show that PD184161 blocked mitochondrial ROS (mtROS) production and cellular ATP levels, at the same time enhancing ascorbate availability in AngII-treated VSMC. Taken together, our study indicates that, independently of p42/p44 MAPK activation, PD184161 blocks mtROS generation by AngII, leading to re-establishment of cellular ascorbate levels, increased VHL binding, and decreased HIF-1α stability. Therefore, this study reveals a previously unsuspected role for PD184161 as an HIF-1 inhibitor in VSMC under nonhypoxic conditions.

Hypoxia-inducible factor-1 plays a role in phosphate-induced vascular smooth muscle cell calcification.

Medial vascular calcification is a common complication of chronic kidney disease (CKD). Although elevated inorganic phosphate stimulates vascular smooth muscle cell (VSMC) osteogenic transdifferentiation and calcification, the mechanisms involved in their calcification during CKD are not fully defined. Because hypoxic gene activation is linked to CKD and stimulates bone cell osteogenic differentiation, we used in vivo and in vitro rodent models to define the role of hypoxic signaling during elevated inorganic phosphate-induced VSMC calcification. Cell mineralization studies showed that elevated inorganic phosphate rapidly induced VSMC calcification. Hypoxia strongly enhanced elevated inorganic phosphate-induced VSMC calcification and osteogenic transdifferentiation, as seen by osteogenic marker expression. Hypoxia-inducible factor-1 (HIF-1), the key hypoxic transcription factor, was essential for enhanced VSMC calcification. Targeting HIF-1 expression in murine VSMC blocked calcification in hypoxia with elevated inorganic phosphate while HIF-1 activators, including clinically used FG-4592/Roxadustat, recreated a procalcifying environment. Elevated inorganic phosphate rapidly activated HIF-1, even in normal oxygenation; an effect mediated by HIF-1α subunit stabilization. Thus, hypoxia synergizes with elevated inorganic phosphate to enhance VSMC osteogenic transdifferentiation. Our work identifies HIF-1 as an early CKD-related pathological event, prospective marker, and potential target against vascular calcification in CKD-relevant conditions.

Inflammatory cytokines and reactive oxygen species as mediators of chronic kidney disease-related vascular calcification.

BACKGROUND: Vascular calcification, a regulated process in chronic kidney disease (CKD), requires vascular smooth muscle cell (VSMC) differentiation into osteoblast-like cells. This phenomenon can be enhanced by inflammatory cytokines and production of reactive oxygen species (ROS). In CKD rats with vascular calcification, we investigated whether inflammatory cytokines, ROS generation, and downstream signaling events are associated with CKD-related vascular calcification. METHODS: CKD was induced in male Wistar rats by renal mass ablation and vascular calcification was induced with a high calcium-phosphate diet and vitamin D supplementation (Ca/P/VitD). At week 3-6, hemodynamic parameters were determined and thoracic aorta was harvested for assessment of vascular calcification, macrophage infiltration, cytokines expression, VSMC differentiation, ROS generation, and related signaling pathway activation. RESULTS: CKD rats treated with Ca/P/VitD developed medial calcification of thoracic aorta and increased pulse pressure and aortic pulse wave velocity. VSMC differentiation was confirmed by increased bone morphogenetic protein-2 and osteocalcin expression and reduced α-smooth muscle actin expression. The expression of interleukin-1ß, interleukin-6, and tumor necrosis factor were also increased. The expression of nicotinamide adenine dinucleotide phosphate (NADPH) oxidase subunits p22(phox) and p47(phox) were increased, whereas the expression of antioxidant enzymes (SOD1, SOD2, Gpx1, and Prdx1) was reduced in CKD + Ca/P/VitD rats. Oxidized peroxiredoxin, a sensor of ROS generation, was significantly increased and ROS-sensitive signaling pathways were activated in the aorta from CKD + Ca/P/VitD rats. CONCLUSION: This study demonstrates a relationship between inflammation/ROS and arterial calcification in CKD and contributes to understanding of the complex pathways that mediate arterial calcification in CKD patients.

Uncoupling stress granule assembly and translation initiation inhibition.

Cytoplasmic stress granules (SGs) are specialized regulatory sites of mRNA translation that form under different stress conditions known to inhibit translation initiation. The formation of SG occurs via two pathways; the eukaryotic initiation factor (eIF) 2alpha phosphorylation-dependent pathway mediated by stress and the eIF2alpha phosphorylation-independent pathway mediated by inactivation of the translation initiation factors eIF4A and eIF4G. In this study, we investigated the effects of targeting different translation initiation factors and steps in SG formation in HeLa cells. By depleting eIF2alpha, we demonstrate that reduced levels of the eIF2.GTP.Met-tRNAi(Met) ternary translation initiation complexes is sufficient to induce SGs. Likewise, reduced levels of eIF4B, eIF4H, or polyA-binding protein, also trigger SG formation. In contrast, depletion of the cap-binding protein eIF4E or preventing its assembly into eIF4F results in modest SG formation. Intriguingly, interfering with the last step of translation initiation by blocking the recruitment of 60S ribosome either with 2-(4-methyl-2,6-dinitroanilino)-N-methylpropionamideis or through depletion of the large ribosomal subunits protein L28 does not induce SG assembly. Our study identifies translation initiation steps and factors involved in SG formation as well as those that can be targeted without induction of SGs.

TDRD3, a novel Tudor domain-containing protein, localizes to cytoplasmic stress granules.

Our previous work has demonstrated that the Tudor domain of the 'survival of motor neuron' protein and the Tudor domain-containing protein 3 (TDRD3) are highly similar and that they both have the ability to interact with arginine-methylated polypeptides. TDRD3 has been identified among genes whose overexpression has a strong predictive value for poor prognosis of estrogen receptor-negative breast cancers, although its precise function remains unknown. TDRD3 is a modular protein, and in addition to its Tudor domain, it harbors a putative nucleic acid recognition motif and a ubiquitin-associated domain. We report here that TDRD3 localizes predominantly to the cytoplasm, where it co-sediments with the fragile X mental retardation protein on actively translating polyribosomes. We also demonstrate that TDRD3 accumulates into stress granules (SGs) in response to various cellular stresses. Strikingly, the Tudor domain of TDRD3 was found to be both required and sufficient for its recruitment to SGs, and the methyl-binding surface in the Tudor domain is important for this process. Pull down experiments identified five novel TDRD3 interacting partners, most of which are potentially methylated RNA-binding proteins. Our findings revealed that two of these proteins, SERPINE1 mRNA-binding protein 1 and DEAD/H box-3 (a gene often deleted in Sertoli-cell-only syndrome), are also novel constituents of cytoplasmic SGs. Taken together, we report the first characterization of TDRD3 and its functional interaction with at least two proteins implicated in human genetic diseases and present evidence supporting a role for arginine methylation in the regulation of SG dynamics.

Altered fibre types in gastrocnemius muscle of high wheel-running selected mice with mini-muscle phenotypes.

Selective breeding of mice for high voluntary wheel running has favoured characteristics that facilitate sustained, aerobically supported activity, including a "mini-muscle" phenotype with markedly reduced hind limb muscle mass, increased mass-specific activities of oxidative enzymes, decreased % myosin heavy chain IIb, and, in the medial gastrocnemius, reduced twitch speed, reduced mass-specific isotonic power, and increased fatigue resistance. To evaluate whether selection has altered fibre type expression in mice with either "mini" or normal muscle phenotypes, we examined fibre types of red and white gastrocnemius. In both the medial and lateral gastrocnemius, the mini-phenotype increased activities of oxidative enzymes and decreased activities of glycolytic enzymes. In red muscle samples, the mini-phenotype markedly changed fibre types, with the % type I and type IIA fibres and the surface area of type IIA fibres increasing; in addition, mice from selected lines in general had an increased % type IIA fibres and larger type I fibres as compared with mice from control lines. White muscle samples from mini-mice showed dramatic structural alterations, with an atypical distribution of extremely small, unidentifiable fibres surrounded by larger, more oxidative fibres than normally present in white muscle. The increased proportion of oxidative fibres and these atypical small fibres together may explain the reduced mass and increased mitochondrial enzyme activities in mini-muscles. These and previous results demonstrate that extension of selective breeding beyond the time when the response of the selected trait (i.e. distance run) has levelled off can still modify the mechanistic underpinnings of this behaviour.