SelK is a novel ER stress-regulated protein and protects HepG2 cells from ER stress agent-induced apoptosis

Selenoprotein K (SelK), an endoplasmic reticulum (ER) resident protein, its biological function has been less-well studied. To investigate the role of SelK in the ER stress response, effects of SelK gene silence and ER stress agents on expression of SelK and cell apoptosis in HepG2 cells were studied. The results showed that SelK was regulated by ER stress agents, Tunicamycin (Tm) and β-Mercaptoethanol (β-ME), in HepG2 cells. Moreover, the SelK gene silence by RNA interference could significantly aggravate HepG2 cell death and apoptosis induced by the ER stress agents. These results suggest that SelK is an ER stress-regulated protein and plays an important role in protecting HepG2 cells from ER stress agent-induced apoptosis.     

Thyroid hormone deiodinases revisited: insights from lungfish: a review

In vertebrates, hormones released from the thyroid gland travel in the circulation to target tissues where they may be processed by deiodinating enzymes into more active or inactive iodothyronines. In mammals, there are three deiodinating enzymes described. Type1 (D1), which primarily occurs in the liver, converts reverse T3 into T2 for clearance. It also converts T4 into T3. This production of T3 is believed to contribute to the bulk of circulating T3 in mammals. The type2 (D2) enzyme may be found in many other tissues where it converts T4 to T3, which is then transferred to the receptors in the nucleus of the same cell, i.e. does not contribute to the circulating T3. The type3 (D3) enzyme converts T3 into T2. The expression of the genes for these three enzymes and/or the activity of the enzymes have been studied in several non-mammalian groups of vertebrates. From agnathans to birds, D2 and D3 appear to occur universally, with the possible exception of squamate reptiles (lack D2?). D1 has not been found in amphibians, lungfish or agnathans. All three enzymes are selenoproteins, in which a selenocysteine is found in the active centre. The nucleotide code for translation of a selenocysteine is UGA, which under normal circumstances is a stop codon. In order for UGA to code for selenocysteine, there must be a SECIS element in the 3′UTR of the mRNA. Any disruption of the SECIS will result in a truncated protein in the region of its active centre. It is suggested that such alternative splicing may be a mode of altering the expression of deiodinases in particular tissues to change the response of such tissues to thyroid hormones under differing circumstances such as stages of development.     

Role of the type 2 iodothyronine deiodinase (D2) in the control of thyroid hormone signaling

Background

Thyroid hormone signaling is critical for development, growth and metabolic control in vertebrates. Although serum concentration of thyroid hormone is remarkable stable, deiodinases modulate thyroid hormone signaling on a time- and cell-specific fashion by controlling the activation and inactivation of thyroid hormone.

Scope of the review

This review covers the recent advances in D2 biology, a member of the iodothyronine deiodinase family, thioredoxin fold‐containing selenoenzymes that modify thyroid hormone signaling in a time- and cell-specific manner.

Major conclusions

D2-catalyzed T3 production increases thyroid hormone signaling whereas blocking D2 activity or disruption of the Dio2 gene leads to a state of localized hypothyroidism. D2 expression is regulated by different developmental, metabolic or environmental cues such as the hedgehog pathway, the adrenergic- and the TGR5-activated cAMP pathway, by xenobiotic molecules such as flavonols and by stress in the endoplasmic reticulum, which specifically reduces de novo synthesis of D2 via an eIF2a-mediated mechanism. Thus, D2 plays a central role in important physiological processes such as determining T3 content in developing tissues and in the adult brain, and promoting adaptive thermogenesis in brown adipose tissue. Notably, D2 is critical in the T4-mediated negative feed-back at the pituitary and hypothalamic levels, whereby T4 inhibits TSH and TRH expression, respectively. Notably, ubiquitination is a major step in the control of D2 activity, whereby T4 binding to and/or T4 catalysis triggers D2 inactivation by ubiquitination that is mediated by the E3 ubiquitin ligases WSB-1 and/or TEB4. Ubiquitinated D2 can be either targeted to proteasomal degradation or reactivated by deubiquitination, a process that is mediated by the deubiquitinases USP20/33 and is important in adaptive thermogenesis.

General significance

Here we review the recent advances in the understanding of D2 biology focusing on the mechanisms that regulate its expression and their biological significance in metabolically relevant tissues. This article is part of a Special Issue entitled Thyroid hormone signalling.     

Selenoprotein P protects endothelial cells from oxidative damage by stimulation of glutathione peroxidase expression and activity

A major fraction of the essential trace element selenium circulating in human blood plasma is present as selenoprotein P (SeP). As SeP associates with endothelial membranes, the participation of SeP in selenium-mediated protection against oxidative damage was investigated, using the human endothelial cell line Ea.hy926 as a model system. Hepatocyte-derived SeP prevented tert-butylhydroperoxide (t-BHP)-induced oxidative cell death of Ea.hy926 cells in a similar manner as did sodium selenite, counteracting a t-BHP-induced loss of cellular membrane integrity. Protection was detected after at least 10 h of SeP supplementation and it peaked at 24 h. SeP time-dependently stimulated the expression of cytosolic glutathione peroxidase (cGPx) and increased the enzymatic activities of glutathione peroxidase (GPx) and thioredoxin reductase (TR). The cGPx inhibitor mercaptosuccinate as well as the γ-glutamylcysteine synthetase inhibitor buthionine sulfoximine counteracted the SeP-mediated protection, while the TR inhibitors cisplatin and auranofin had no effect. The presented data suggest that selenium supplementation by SeP prevents oxidative damage of human endothelial cells by restoring expression and enzymatic activity of GPx.     

Mice Lacking Selenoprotein P and Selenocysteine Lyase Exhibit Severe Neurological Dysfunction,Neurodegeneration, and Audiogenic Seizures

Selenoproteins are a unique family of proteins, characterized by the co-translational incorporation of selenium as selenocysteine, which play key roles in antioxidant defense. Among selenoproteins, selenoprotein P (Sepp1) is particularly distinctive due to the fact that it contains multiple selenocysteine residues and has been postulated to act in selenium transport. Within the brain, Sepp1 delivers selenium to neurons by binding to the ApoER2 receptor. Upon feeding a selenium-deficient diet, mice lacking ApoER2 or Sepp1 develop severe neurological dysfunction and exhibit widespread brainstem neurodegeneration, indicating an important role for ApoER2-mediated Sepp1 uptake in normal brain function. Selenocysteine lyase (Scly) is an enzyme that plays an important role in selenium homeostasis, in that it catalyzes the decomposition of selenocysteine and allows selenium to be recycled for additional selenoprotein synthesis. We previously reported that constitutive deletion of Scly results in neurological deficits only when mice are challenged with a low selenium diet. To gain insight into the relationship between Sepp1 and Scly in selenium metabolism, we created novel transgenic mice constitutively lacking both genes (Scly^−/−Sepp1^−/−) and characterized the neurobehavioral phenotype. We report that deletion of Scly in conjunction with Sepp1 further aggravates the phenotype of Sepp1^−/− mice, as these mice needed supraphysiological selenium supplementation to survive, and surviving mice exhibited impaired motor coordination, audiogenic seizures, and brainstem neurodegeneration. These findings provide the first in vivo evidence that Scly and Sepp1 work cooperatively to maintain selenoprotein function in the mammalian brain.     

High Error Rates in Selenocysteine Insertion in Mammalian Cells Treated with the Antibiotic Doxycycline,Chloramphenicol, or Geneticin

Antibiotics target bacteria by interfering with essential processes such as translation, but their effects on translation in mammalian cells are less well characterized. We found that doxycycline, chloramphenicol, and Geneticin (G418) interfered with insertion of selenocysteine (Sec), which is encoded by the stop codon, UGA, into selenoproteins in murine EMT6 cells. Treatment of EMT6 cells with these antibiotics reduced enzymatic activities and Sec insertion into thioredoxin reductase 1 (TR1) and glutathione peroxidase 1 (GPx1). However, these proteins were differentially affected due to varying errors in Sec insertion at UGA. In the presence of doxycycline, chloramphenicol, or G418, the Sec-containing form of TR1 decreased, whereas the arginine-containing and truncated forms of this protein increased. We also detected antibiotic-specific misinsertion of cysteine and tryptophan. Furthermore, misinsertion of arginine in place of Sec was commonly observed in GPx1 and glutathione peroxidase 4. TR1 was the most affected and GPx1 was the least affected by these translation errors. These observations were consistent with the differential use of two Sec tRNA isoforms and their distinct roles in supporting accuracy of Sec insertion into selenoproteins. The data reveal widespread errors in inserting Sec into proteins and in dysregulation of selenoprotein expression and function upon antibiotic treatment.     

Selenium and copper status - potential signposts for neurological remission after traumatic spinal cord injury

IntroductionTraumatic Spinal Cord Injury (TSCI) is a severe incident resulting in loss of motor and sensory function caused by complex pathological mechanisms including massive oxidative stress and extensive inflammatory processes. The essential trace elements selenium (Se) and copper (Cu) play crucial roles as part of the antioxidant defense.HypothesisRemission after TSCI is associated with characteristic dynamics of early changes in serum Cu and Se status.Study designSingle-center prospective observational study.Patients and methodsSerum samples from TSCI patients were analyzed (n = 52); 21 recovered and showed a positive abbreviated injury score (AIS) conversion within 3 months (G1), whereas 21 had no remission (G0). Ten subjects with vertebral fractures without neurological impairment served as control (C). Different time points (at admission, and after 4, 9, 12, and 24 h) were analyzed for total serum Se and Cu concentrations by total reflection X-ray fluorescence, and for Selenoprotein P (SELENOP) and Ceruloplasmin (CP) by sandwich ELISA.ResultsAt admission, CP and SELENOP concentrations were higher in the remission group (G1) than in the non-remission group (G0). Within 24 h, there were marginal changes in Se, SELENOP, Cu and CP concentrations in the groups of controls (C) and G0. In contrast, these parameters decreased significantly in G1. Binary logistic regression analysis including Cu and Se levels at admission in combination with Se and CP levels after 24 h allowed a prediction for potential remission, with an area under the curve (AUC) of 87.7% (CI: 75.1%–100.0%).ConclusionThese data indicate a strong association between temporal changes of the Se and Cu status and the clinical outcome after TSCI. The dynamics observed may reflect an ongoing redistribution of the trace elements in favor of a better anti-inflammatory response and a more successful neurological regeneration.