Your search keyword '"SELENOCYSTEINE"' showing total 2,323 results

1. Bacterial selenocysteine synthase structure revealed by single-particle cryoEM

Author

Serrão, Vitor Hugo Balasco, Minari, Karine, Pereira, Humberto D'Muniz, and Thiemann, Otavio Henrique

Subjects

Biochemistry and Cell Biology, Biological Sciences, Infectious Diseases, SelA, Selenocysteine, Selenocysteine synthase, Single-particle analysis, tRNA[Ser]Sec

Abstract

The 21st amino acid, selenocysteine (Sec), is synthesized on its dedicated transfer RNA (tRNASec). In bacteria, Sec is synthesized from Ser-tRNA[Ser]Sec by Selenocysteine Synthase (SelA), which is a pivotal enzyme in the biosynthesis of Sec. The structural characterization of bacterial SelA is of paramount importance to decipher its catalytic mechanism and its role in the regulation of the Sec-synthesis pathway. Here, we present a comprehensive single-particle cryo-electron microscopy (SPA cryoEM) structure of the bacterial SelA with an overall resolution of 2.69 Å. Using recombinant Escherichia coli SelA, we purified and prepared samples for single-particle cryoEM. The structural insights from SelA, combined with previous in vivo and in vitro knowledge, underscore the indispensable role of decamerization in SelA's function. Moreover, our structural analysis corroborates previous results that show that SelA adopts a pentamer of dimers configuration, and the active site architecture, substrate binding pocket, and key K295 catalytic residue are identified and described in detail. The differences in protein architecture and substrate coordination between the bacterial enzyme and its counterparts offer compelling structural evidence supporting the independent molecular evolution of the bacterial and archaea/eukarya Ser-Sec biosynthesis present in the natural world.

Published

2024

2. Metabolic engineering of Escherichia coli for seleno-methylselenocysteine production.

Author

Yang, Hulin, Wang, Shizhuo, Zhao, Meiyi, Liao, Yonghong, Wang, Fenghuan, and Yin, Xian

Subjects

*ESCHERICHIA coli, *SELENOCYSTEINE, *CYSTEINE, *SODIUM selenite, *SERINE

Abstract

Selenium (Se) is an essential trace element for life. Seleno-methylselenocysteine (SeMCys) can serve as a Se supplement with anticarcinogenic activity and can improve cognitive deficits. We engineered Escherichia coli for microbial production of SeMCys. The genes involved in the synthesis of SeMCys were divided into three modules–the selenocysteine (SeCys) synthesis, methyl donor synthesis and SMT modules–and expressed in plasmids with different copy numbers. The higher copy number of the SeCys synthesis module facilitated SeMCys production. The major routes for SeCys degradation were then modified. Deletion of the cysteine desulfurase gene csdA or sufS improved SeMCys production the most, and the strain that knocked out both genes doubled SeMCys production. The addition of serine in the mid-logarithmic growth phase significantly improved SeMCys synthesis. When the serine synthetic pathway was enhanced, SeMCys production increased by 12.5 %. Fed-batch culture for sodium selenite supplementation in the early stationary phase improved SeMCys production to 3.715 mg/L. This is the first report of the metabolic engineering of E. coli for the production of SeMCys and provide information on Se metabolism. • Higher copy number of the SeCys synthesis module facilitated SeMCys production. • Cysteine desulfurase CsdA and SufS are involved in the degradation of SeCys. • The enhanced Ser synthetic pathway increased SeMCys synthesis. [ABSTRACT FROM AUTHOR]

Published

2024

3. Thioredoxin reductase inhibition and glutathione depletion mediated by glaucocalyxin A promote intracellular disulfide stress in gastric cancer cells.

Author

Wang, Ling, Sun, Shibo, Liu, Haowen, Zhang, Qiuyu, Meng, Yao, Sun, Fan, Zhang, Jianjun, Liu, Haiyan, Xu, Weiping, Ye, Zhiwei, Zhang, Jie, Sun, Bingbing, and Xu, Jianqiang

Subjects

*CYTOSKELETAL proteins, *STOMACH cancer, *THIOREDOXIN, *CANCER cells, *REDUCING agents, *DITERPENES

Abstract

Thioredoxin reductase 1 (TXNRD1) has been identified as one of the promising chemotherapeutic targets in cancer cells. Therefore, a novel TXNRD1 inhibitor could accelerate chemotherapy in clinical anticancer research. In this study, glaucocalyxin A (GlauA), a natural diterpene extracted from Rabdosia japonica var. glaucocalyx, was identified as a novel inhibitor of TXNRD1. We found that GlauA effectively inhibited recombinant TXNRD1 and reduced its activity in gastric cancer cells without affecting the enzyme's expression level. Mechanistically, the selenocysteine residue (U498) of TXNRD1 was irreversibly modified by GlauA through a Michael addition. Additionally, GlauA formed a covalent adduct with glutathione (GSH) and disrupted cellular redox balance by depleting cellular GSH. The inhibition of TXNRD1 and depletion of GSH by GlauA conferred its cytotoxic effects in spheroid culture and Transwell assays in AGS cells. The disulfide stress induced cytotoxicity of GlauA could be mitigated by adding reducing agents, such as DTT and β‐ME. Furthermore, the FDA‐approval drug auranofin, a TXNRD1 inhibitor, triggered oligomerization of the cytoskeletal protein Talin‐1 in AGS cells, indicating that inhibiting TXNRD1 triggered disulfide stress. In conclusion, this study uncovered GlauA as an efficient inhibitor of TXNRD1 and demonstrated the potential of TXNRD1 inhibition as an effective anticancer strategy by disrupting redox homeostasis and inducing disulfide stress. [ABSTRACT FROM AUTHOR]

Published

2024

4. Modular Polymerase Synthesis and Internal Protein Domain Swapping via Dual Opposed Frameshifts in the Ebola Virus L Gene.

Author

Stubbs, David B., Ruzicka, Jan A., and Taylor, Ethan W.

Subjects

EBOLA virus, REPORTER genes, SELENOCYSTEINE, PROTEIN domains, SEQUENCE analysis, SELENOPROTEINS

Abstract

Sequence analysis of the Zaire ebolavirus (EBOV) polymerase (L gene) mRNA, using online tools, identified a highly ranked −1 programmed ribosomal frameshift (FS) signal including an ideal slippery sequence heptamer (UUUAAAA), with an overlapping coding region featuring two tandem UGA codons, immediately followed by an RNA region that is the inverse complement (antisense) to a region of the mRNA of the selenoprotein iodothyronine deiodinase II (DIO2). This antisense interaction was confirmed in vitro via electrophoretic gel shift assay, using cDNAs at the EBOV and DIO2 segments. The formation of a duplex between the two mRNAs could trigger the ribosomal frameshift, by mimicking the enhancing role of a pseudoknot structure, while providing access to the selenocysteine insertion sequence (SECIS) element contained in the DIO2 mRNA. This process would allow the −1 frame UGA codons to be recoded as selenocysteine, forming part of a C-terminal module in a low abundance truncated isoform of the viral polymerase, potentially functioning in a redox role. Remarkably, 90 bases downstream of the −1 FS site, an active +1 FS site can be demonstrated, which, via a return to the zero frame, would enable the attachment of the entire C-terminal of the polymerase protein. Using a construct with upstream and downstream reporter genes, spanning a wildtype or mutated viral insert, we show significant +1 ribosomal frameshifting at this site. Acting singly or together, frameshifting at these sites (both of which are highly conserved in EBOV strains) could enable the expression of several modified isoforms of the polymerase. The 3D modeling of the predicted EBOV polymerase FS variants using the AI tool, AlphaFold, reveals a peroxiredoxin-like active site with arginine and threonine residues adjacent to a putative UGA-encoded selenocysteine, located on the back of the polymerase "hand". This module could serve to protect the viral RNA from peroxidative damage. [ABSTRACT FROM AUTHOR]

Published

2024

5. Overcoming Challenges with Biochemical Studies of Selenocysteine and Selenoproteins.

Author

Cain, Antavius and Krahn, Natalie

Subjects

*ESSENTIAL amino acids, *CHEMICAL properties, *GENETIC translation, *SELENOCYSTEINE, *BIOCHEMISTRY, *SELENOPROTEINS

Abstract

Selenocysteine (Sec) is an essential amino acid that distinguishes itself from cysteine by a selenium atom in place of a sulfur atom. This single change imparts distinct chemical properties to Sec which are crucial for selenoprotein (Sec-containing protein) function. These properties include a lower pKa, enhanced nucleophilicity, and reversible oxidation. However, studying Sec incorporation in proteins is a complex process. While we find Sec in all domains of life, each domain has distinct translation mechanisms. These mechanisms are unique to canonical translation and are composed of Sec-specific enzymes and an mRNA hairpin to drive recoding of the UGA stop codon with Sec. In this review, we highlight the obstacles that arise when investigating Sec insertion, and the role that Sec has in proteins. We discuss the strategic methods implemented in this field to address these challenges. Though the Sec translation system is complex, a remarkable amount of information has been obtained and specialized tools have been developed. Continued studies in this area will provide a deeper understanding on the role of Sec in the context of proteins, and the necessity that we have for maintaining this complex translation machinery to make selenoproteins. [ABSTRACT FROM AUTHOR]

Published

2024

6. Selenocysteine methyltransferase SMT catalyzed the synthesis of Se-methylselenocysteine to regulate the accumulation of glucosinolates and sulforaphane in broccoli.

Author

Qi Wu, Junwei Wang, Yuxiao Tian, Chunyan Zhou, Shuxiang Mao, Qiuyun Wu, and Ke Huang

Subjects

*SELENOCYSTEINE, *METHYLTRANSFERASES, *GLUCOSINOLATES, *SULFORAPHANE, *BROCCOLI

Abstract

Selenocysteine methyltransferase (SMT) is a key enzyme involved in the Se metabolism pathway, and it is responsible for the catalysis of Se-methylselenocysteine (SeMSC) compound formation. Previous studies showed that selenium treatment activated SMT expression and promoted the accumulation of glucosinolates (GSLs) and sulforaphane, but the roles and functional mechanisms of SMT in mediating GSLs and sulforaphane synthesis remain unclear. In this study, we identified the BoSMT gene in broccoli and uncovered its roles in mediating GSLs biosynthesis. Transgenic assays revealed that BoSMT is involved in SeMSC biosynthesis in broccoli. More importantly, the contents of GSLs and sulforaphane were significantly increased in the BoSMT-overexpressing broccoli lines but decreased in the knockdown lines, suggesting that BoSMT played a positive role in regulating GSLs and sulforaphane synthesis. Further evidence indicated that BoSMT-mediated overaccumulation of GSLs and sulforaphane might be due to the increase in the endogenous SeMSC content. Compared with the mock (water) treatment, selenite-induced significantly increases of the SeMSC content in the BoSMT-knockdown plants partially compensated the phenotype of GSLs and sulforaphane loss. Compared with the mock treatment, exogenous SeMSC treatment significantly increased the contents of GSL and sulforaphane and activated GSL synthesis-related gene expression, suggesting that SeMSC acted as a positive regulator for GSL and sulforaphane production. Our findings provided novel insights into selenium-mediated GSLs and sulforaphane accumulation. The genetic manipulation of BoSMT might be a useful strategy for improving the dietary nutritional values of broccoli. [ABSTRACT FROM AUTHOR]

Published

2024

7. Selenoprotein deficiency disorder predisposes to aortic aneurysm formation.

Author

Schoenmakers, Erik, Marelli, Federica, Jørgensen, Helle, Visser, W, Moran, Carla, Groeneweg, Stefan, Avalos, Carolina, Jurgens, Sean, Figg, Nichola, Finigan, Alison, Wali, Neha, Agostini, Maura, Wardle-Jones, Hannah, Lyons, Greta, Rusk, Rosemary, Gopalan, Deepa, Twiss, Philip, Visser, Jacob, Goddard, Martin, Nashef, Samer, Heijmen, Robin, Clift, Paul, Sinha, Sanjay, Pirruccello, James, Ellinor, Patrick, Busch-Nentwich, Elisabeth, Ramirez-Solis, Ramiro, Murphy, Michael, Persani, Luca, Bennett, Martin, and Chatterjee, Krishna

Subjects

Humans, Male, Mice, Animals, Zebrafish, Selenocysteine, Muscle, Smooth, Vascular, Aortic Aneurysm, Selenoproteins, Myocytes, Smooth Muscle

Abstract

Aortic aneurysms, which may dissect or rupture acutely and be lethal, can be a part of multisystem disorders that have a heritable basis. We report four patients with deficiency of selenocysteine-containing proteins due to selenocysteine Insertion Sequence Binding Protein 2 (SECISBP2) mutations who show early-onset, progressive, aneurysmal dilatation of the ascending aorta due to cystic medial necrosis. Zebrafish and male mice with global or vascular smooth muscle cell (VSMC)-targeted disruption of Secisbp2 respectively show similar aortopathy. Aortas from patients and animal models exhibit raised cellular reactive oxygen species, oxidative DNA damage and VSMC apoptosis. Antioxidant exposure or chelation of iron prevents oxidative damage in patients cells and aortopathy in the zebrafish model. Our observations suggest a key role for oxidative stress and cell death, including via ferroptosis, in mediating aortic degeneration.

Published

2023

8. Selenium Discrepancies in Fetal Bovine Serum: Impact on Cellular Selenoprotein Expression.

Author

Parant, François, Mure, Fabrice, Maurin, Julien, Beauvilliers, Léana, Chorfa, Chaïma, El Jamali, Chaymae, Ohlmann, Théophile, and Chavatte, Laurent

Subjects

*SELENOPROTEINS, *SELENIUM, *BOS, *TRACE elements, *THIOREDOXIN, *CELL culture, *RESEARCH personnel

Abstract

Selenium is an essential trace element in our diet, crucial for the composition of human selenoproteins, which include 25 genes such as glutathione peroxidases and thioredoxin reductases. The regulation of the selenoproteome primarily hinges on the bioavailability of selenium, either from dietary sources or cell culture media. This selenium-dependent control follows a specific hierarchy, with "housekeeping" selenoproteins maintaining constant expression while "stress-regulated" counterparts respond to selenium level fluctuations. This study investigates the variability in fetal bovine serum (FBS) selenium concentrations among commercial batches and its effects on the expression of specific stress-related cellular selenoproteins. Despite the limitations of our study, which exclusively used HEK293 cells and focused on a subset of selenoproteins, our findings highlight the substantial impact of serum selenium levels on selenoprotein expression, particularly for GPX1 and GPX4. The luciferase reporter assay emerged as a sensitive and precise method for evaluating selenium levels in cell culture environments. While not exhaustive, this analysis provides valuable insights into selenium-mediated selenoprotein regulation, emphasizing the importance of serum composition in cellular responses and offering guidance for researchers in the selenoprotein field. [ABSTRACT FROM AUTHOR]

Published

2024

9. Foliar selenium biofortification of soybean: the potential for transformation of mineral selenium into organic forms.

Author

Mrština, Tomáš, Praus, Lukáš, Száková, Jiřina, Kaplan, Lukáš, and Tlustoš, Pavel

Subjects

BIOFORTIFICATION, ANIMAL feeds, SOYFOODS, FOOD industry, SOYBEAN, SELENIUM

Abstract

Introduction: Selenium (Se) deficiency, stemming from malnutrition in humans and animals, has the potential to disrupt many vital physiological processes, particularly those reliant on specific selenoproteins. Agronomic biofortification of crops through the application of Se-containing sprays provides an efficient method to enhance the Se content in the harvested biomass. An optimal candidate for systematic enrichment, guaranteeing a broad trophic impact, must meet several criteria: (i) efficient accumulation of Se without compromising crop yield, (ii) effective conversion of mineral Se fertilizer into usable organically bound Se forms (Seorg), (iii) acceptance of a Se-enriched crop as livestock feed, and (iv), interest from the food processing industry in utilization of Se-enriched outputs. Hence, priority should be given to high-protein leafy crops, such as soybean. Methods: A three-year study in the Czech Republic was conducted to investigate the response of field-grown soybean plants to foliar application of Na2SeO4 solutions (0, 15, 40, and 100 g/ha Se); measured outcomes included crop yield, Se distribution in aboveground biomass, and the chemical speciation of Se in seeds. Results and Discussion: Seed yield was unaffected by applied SeO4 2-, with Se content reaching levels as high as 16.2 mg/kg. The relationship between SeO4 2-dose and Se content in seeds followed a linear regression model. Notably, the soybeans demonstrated an impressive 73% average recovery of Se in seeds. Selenomethionine was identified as the predominant species of Se in enzymatic hydrolysates of soybean, constituting up to 95% of Seorg in seeds. Minor Se species, such as selenocystine, selenite, and selenate, were also detected. The timing of Se spraying influenced both plant SeO4 2- biotransformation and total content in seeds, emphasizing the critical importance of optimizing the biofortification protocol. Future research should explore the economic viability, long-term ecological sustainability, and the broad nutritional implications of incorporating Se-enriched soybeans into food for humans and animals. [ABSTRACT FROM AUTHOR]

Published

2024

10. Engineered mRNA-ribosome fusions for facile biosynthesis of selenoproteins.

Author

Thaenert, Anna, Sevostyanova, Anastasia, Chung, Christina Z., Vargas-Rodriguez, Oscar, Melmkov, Sergey V., and Söll, Dieter

Subjects

*SELENOPROTEINS, *BIOSYNTHESIS, *STOP codons, *BACTERIAL proteins, *MESSENGER RNA

Abstract

Ribosomes are often used in synthetic biology as a tool to produce desired proteins with enhanced properties or entirely new functions. However, repurposing ribosomes for producing designer proteins is challenging due to the limited number of engineering solutions available to alter the natural activity of these enzymes. In this study, we advance ribosome engineering by describing a novel strategy based on functional fusions of ribosomal RNA (rRNA) with messenger RNA (mRNA). Specifically, we create an mRNA-ribosome fusion called RiboU, where the 16S rRNA is covalently attached to selenocysteine insertion sequence (SECIS), a regulatory RNA element found in mRNAs encoding selenoproteins. When SECIS sequences are present in natural mRNAs, they instruct ribosomes to decode UGA codons as selenocysteine (Sec, U) codons instead of interpreting them as stop codons. This enables ribosomes to insert Sec into the growing polypeptide chain at the appropriate site. Our work demonstrates that the SECIS sequence maintains its functionality even when inserted into the ribosome structure. As a result, the engineered ribosomes RiboU interpret UAG codons as Sec codons, allowing easy and site-specific insertion of Sec in a protein of interest with no further modification to the natural machinery of protein synthesis. To validate this approach, we use RiboU ribosomes to produce three functional target selenoproteins in Escherichia coli by site-specifically inserting Sec into the proteins' active sites. Overall, our work demonstrates the feasibility of creating functional mRNA-rRNA fusions as a strategy for ribosome engineering, providing a novel tool for producing Sec-containing proteins in live bacterial cells. [ABSTRACT FROM AUTHOR]

Published

2024

11. Ancient Loss of Catalytic Selenocysteine Spurred Convergent Adaptation in a Mammalian Oxidoreductase.

Author

Rees, Jasmin, Sarangi, Gaurab, Cheng, Qing, Floor, Martin, Andrés, Aida M, Miguel, Baldomero Oliva, Villà-Freixa, Jordi, Arnér, Elias S J, and Castellano, Sergi

Subjects

*SELENOCYSTEINE, *SELENOPROTEINS, *GLUTATHIONE peroxidase, *GENETIC code, *AMINO acids, *CATALYTIC domains, *CONVERGENT evolution

Abstract

Selenocysteine, the 21st amino acid specified by the genetic code, is a rare selenium-containing residue found in the catalytic site of selenoprotein oxidoreductases. Selenocysteine is analogous to the common cysteine amino acid, but its selenium atom offers physical–chemical properties not provided by the corresponding sulfur atom in cysteine. Catalytic sites with selenocysteine in selenoproteins of vertebrates are under strong purifying selection, but one enzyme, glutathione peroxidase 6 (GPX6), independently exchanged selenocysteine for cysteine <100 million years ago in several mammalian lineages. We reconstructed and assayed these ancient enzymes before and after selenocysteine was lost and up to today and found them to have lost their classic ability to reduce hydroperoxides using glutathione. This loss of function, however, was accompanied by additional amino acid changes in the catalytic domain, with protein sites concertedly changing under positive selection across distant lineages abandoning selenocysteine in glutathione peroxidase 6. This demonstrates a narrow evolutionary range in maintaining fitness when sulfur in cysteine impairs the catalytic activity of this protein, with pleiotropy and epistasis likely driving the observed convergent evolution. We propose that the mutations shared across distinct lineages may trigger enzymatic properties beyond those in classic glutathione peroxidases, rather than simply recovering catalytic rate. These findings are an unusual example of adaptive convergence across mammalian selenoproteins, with the evolutionary signatures possibly representing the evolution of novel oxidoreductase functions. [ABSTRACT FROM AUTHOR]

Published

2024

12. Mechanism of Action of Antitumor Au(I) N-Heterocyclic Carbene Complexes: A Computational Insight on the Targeting of TrxR Selenocysteine.

Author

Tolbatov, Iogann, Umari, Paolo, and Marrone, Alessandro

Subjects

*GIBBS' energy diagram, *SELENOCYSTEINE, *CARBENES, *DENSITY functional theory, *THIOREDOXIN, *ANTINEOPLASTIC agents

Abstract

The targeting of human thioredoxin reductase is widely recognized to be crucially involved in the anticancer properties of several metallodrugs, including Au(I) complexes. In this study, the mechanism of reaction between a set of five N-heterocyclic carbene Au(I) complexes and models of the active Sec residue in human thioredoxin reductase was investigated by means of density functional theory approaches. The study was specifically addressed to the kinetics and thermodynamics of the tiled process by aiming at elucidating and explaining the differential inhibitory potency in this set of analogous Au(I) bis-carbene complexes. While the calculated free energy profile showed a substantially similar reactivity, we found that the binding of these Au(I) bis-carbene at the active CysSec dyad in the TrxR enzyme could be subjected to steric and orientational restraints, underlining both the approach of the bis-carbene scaffold and the attack of the selenol group at the metal center. A new and detailed mechanistic insight to the anticancer activity of these Au(I) organometallic complexes was thus provided by consolidating the TrxR targeting paradigm. [ABSTRACT FROM AUTHOR]

Published

2024

13. Overcoming Challenges with Biochemical Studies of Selenocysteine and Selenoproteins

Author

Antavius Cain and Natalie Krahn

Subjects

selenocysteine, biochemistry, selenoprotein, selenium, redox, translation, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Selenocysteine (Sec) is an essential amino acid that distinguishes itself from cysteine by a selenium atom in place of a sulfur atom. This single change imparts distinct chemical properties to Sec which are crucial for selenoprotein (Sec-containing protein) function. These properties include a lower pKa, enhanced nucleophilicity, and reversible oxidation. However, studying Sec incorporation in proteins is a complex process. While we find Sec in all domains of life, each domain has distinct translation mechanisms. These mechanisms are unique to canonical translation and are composed of Sec-specific enzymes and an mRNA hairpin to drive recoding of the UGA stop codon with Sec. In this review, we highlight the obstacles that arise when investigating Sec insertion, and the role that Sec has in proteins. We discuss the strategic methods implemented in this field to address these challenges. Though the Sec translation system is complex, a remarkable amount of information has been obtained and specialized tools have been developed. Continued studies in this area will provide a deeper understanding on the role of Sec in the context of proteins, and the necessity that we have for maintaining this complex translation machinery to make selenoproteins.

Published

2024

14. Biosynthesis, Engineering, and Delivery of Selenoproteins.

Author

Wright, David E. and O'Donoghue, Patrick

Subjects

*SELENOPROTEINS, *BIOSYNTHESIS, *SYNTHETIC biology, *GENETIC code, *PHYTOPATHOGENIC fungi, *SELENOCYSTEINE

Abstract

Selenocysteine (Sec) was discovered as the 21st genetically encoded amino acid. In nature, site-directed incorporation of Sec into proteins requires specialized biosynthesis and recoding machinery that evolved distinctly in bacteria compared to archaea and eukaryotes. Many organisms, including higher plants and most fungi, lack the Sec-decoding trait. We review the discovery of Sec and its role in redox enzymes that are essential to human health and important targets in disease. We highlight recent genetic code expansion efforts to engineer site-directed incorporation of Sec in bacteria and yeast. We also review methods to produce selenoproteins with 21 or more amino acids and approaches to delivering recombinant selenoproteins to mammalian cells as new applications for selenoproteins in synthetic biology. [ABSTRACT FROM AUTHOR]

Published

2024

15. Demonstration of the Formation of a Selenocysteine Selenenic Acid through Hydrolysis of a Selenocysteine Selenenyl Iodide Utilizing a Protective Molecular Cradle.

Author

Goto, Kei, Kimura, Ryutaro, Masuda, Ryosuke, Karasaki, Takafumi, and Sase, Shohei

Subjects

*SELENOCYSTEINE, *ALKALINE hydrolysis, *CHEMICAL amplification, *IODIDES, *GLUTATHIONE peroxidase

Abstract

Selenocysteine selenenic acids (Sec–SeOHs) and selenocysteine selenenyl iodides (Sec–SeIs) have long been recognized as crucial intermediates in the catalytic cycle of glutathione peroxidase (GPx) and iodothyronine deiodinase (Dio), respectively. However, the observation of these reactive species remained elusive until our recent study, where we successfully stabilized Sec–SeOHs and Sec–SeIs using a protective molecular cradle. Here, we report the first demonstration of the chemical transformation from a Sec–SeI to a Sec–SeOH through alkaline hydrolysis. A stable Sec–SeI derived from a selenocysteine methyl ester was synthesized using the protective cradle, and its structure was determined by crystallographic analysis. The alkaline hydrolysis of the Sec–SeI at −50 °C yielded the corresponding Sec–SeOH in an 89% NMR yield, the formation of which was further confirmed by its reaction with dimedone. The facile and nearly quantitative conversion of the Sec–SeI to the Sec–SeOH not only validates the potential involvement of this process in the catalytic mechanism of Dio, but also highlights its utility as a method for producing a Sec–SeOH. [ABSTRACT FROM AUTHOR]

Published

2023

16. Foliar selenium biofortification of soybean: the potential for transformation of mineral selenium into organic forms

Author

Tomáš Mrština, Lukáš Praus, Jiřina Száková, Lukáš Kaplan, and Pavel Tlustoš

Subjects

Glycine max L., sodium selenate, Se recovery, selenium species, selenomethionine, selenocysteine, Plant culture, SB1-1110

Abstract

IntroductionSelenium (Se) deficiency, stemming from malnutrition in humans and animals, has the potential to disrupt many vital physiological processes, particularly those reliant on specific selenoproteins. Agronomic biofortification of crops through the application of Se-containing sprays provides an efficient method to enhance the Se content in the harvested biomass. An optimal candidate for systematic enrichment, guaranteeing a broad trophic impact, must meet several criteria: (i) efficient accumulation of Se without compromising crop yield, (ii) effective conversion of mineral Se fertilizer into usable organically bound Se forms (Seorg), (iii) acceptance of a Se-enriched crop as livestock feed, and (iv), interest from the food processing industry in utilization of Se-enriched outputs. Hence, priority should be given to high-protein leafy crops, such as soybean.MethodsA three-year study in the Czech Republic was conducted to investigate the response of field-grown soybean plants to foliar application of Na2SeO4 solutions (0, 15, 40, and 100 g/ha Se); measured outcomes included crop yield, Se distribution in aboveground biomass, and the chemical speciation of Se in seeds.Results and DiscussionSeed yield was unaffected by applied SeO42-, with Se content reaching levels as high as 16.2 mg/kg. The relationship between SeO42-dose and Se content in seeds followed a linear regression model. Notably, the soybeans demonstrated an impressive 73% average recovery of Se in seeds. Selenomethionine was identified as the predominant species of Se in enzymatic hydrolysates of soybean, constituting up to 95% of Seorg in seeds. Minor Se species, such as selenocystine, selenite, and selenate, were also detected. The timing of Se spraying influenced both plant SeO42- biotransformation and total content in seeds, emphasizing the critical importance of optimizing the biofortification protocol. Future research should explore the economic viability, long-term ecological sustainability, and the broad nutritional implications of incorporating Se-enriched soybeans into food for humans and animals.

Published

2024

17. The C-terminal selenenylsulfide of extracellular/non-reduced thioredoxin reductase endows this protein with selectivity to small-molecule electrophilic reagents under oxidative conditions

Author

Huijun Qin, Chenchen Guo, Bozhen Chen, Hui Huang, Yaping Tian, and Liangwei Zhong

Subjects

thioredoxin reductase, selenocysteine, site-directed mutagenesis, protein complex, computer modeling, protein chemistry, Biology (General), QH301-705.5

Abstract

Mammalian cytosolic thioredoxin reductase (TrxR1) serves as an antioxidant protein by transferring electrons from NADPH to various substrates. The action of TrxR1 is achieved via reversible changes between NADPH-reduced and non-reduced forms, which involves C-terminal selenolthiol/selenenylsulfide exchanges. TrxR1 may be released into extracellular environment, where TrxR1 is present mainly in the non-reduced form with active-site disulfide and selenenylsulfide bonds. The relationships between extracellular TrxR1 and tumor metastasis or cellular signaling have been discovered, but there are few reports on small-molecule compounds in targeted the non-reduced form of TrxR1. Using eight types of small-molecule thiol-reactive reagents as electrophilic models, we report that the selenenylsulfide bond in the non-reduced form of TrxR1 functions as a selector for the thiol-reactive reagents at pH 7.5. The non-reduced form of TrxR1 is resistant to hydrogen peroxide/oxidized glutathione, but is sensitive to certain electrophilic reagents in different ways. With 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) and S-nitrosoglutathione (GSNO), the polarized selenenylsulfide bond breaks, and selenolate anion donates electron to the dynamic covalent bond in DTNB or GSNO, forming TNB-S-Se-TrxR1 complex or ON-Se-TrxR1 complex. The both complexes lose the ability to transfer electrons from NADPH to substrate. For diamide, the non-reduced TrxR1 actually prevents irreversible damage by this oxidant. This is consistent with the regained activity of TrxR1 through removal of diamide via dialysis. Diamide shows effective in the presence of human cytosolic thioredoxin (hTrx1), Cys residue(s) of which is/are preferentially affected by diamide to yield disulfide, hTrx1 dimer and the mixed disulfide between TrxR1-Cys497/Sec498 and hTrx1-Cys73. In human serum samples, the non-reduced form of TrxR1 exists as dithiothreitol-reducible polymer/complexes, which might protect the non-reduced TrxR1 from inactivation by certain electrophilic reagents under oxidative conditions, because cleavage of these disulfides can lead to regain the activity of TrxR1. The details of the selective response of the selenenylsulfide bond to electrophilic reagents may provide new information for designing novel small-molecule inhibitors (drugs) in targeted extracellular/non-reduced TrxR1.

Published

2024

18. Optimized methyl donor and reduced precursor degradation pathway for seleno-methylselenocysteine production in Bacillus subtilis

Author

Xian Yin, Meiyi Zhao, Yu Zhou, Hulin Yang, Yonghong Liao, and Fenghuan Wang

Subjects

Seleno-methylselenocysteine, Methylmethionine, Selenocysteine, Serine, Bacillus subtilis, Microbiology, QR1-502

Abstract

Abstract Background Seleno-methylselenocysteine (SeMCys) is an effective component of selenium supplementation with anti-carcinogenic potential that can ameliorate neuropathology and cognitive deficits. In a previous study, a SeMCys producing strain of Bacillus subtilis GBACB was generated by releasing feedback inhibition by overexpression of cysteine-insensitive serine O-acetyltransferase, enhancing the synthesis of S-adenosylmethionine as methyl donor by overexpression of S-adenosylmethionine synthetase, and expressing heterologous selenocysteine methyltransferase. In this study, we aimed to improve GBACB SeMCys production by synthesizing methylmethionine as a donor to methylate selenocysteine and by inhibiting the precursor degradation pathway. Results First, the performance of three methionine S-methyltransferases that provide methylmethionine as a methyl donor for SeMCys production was determined. Integration of the NmMmt gene into GBACB improved SeMCys production from 20.7 to 687.4 μg/L. Next, the major routes for the degradation of selenocysteine, which is the precursor of SeMCys, were revealed by comparing selenocysteine hyper-accumulating and non-producing strains at the transcriptional level. The iscSB knockout strain doubled SeMCys production. Moreover, deleting sdaA, which is responsible for the degradation of serine as a precursor of selenocysteine, enhanced SeMCys production to 4120.3 μg/L. Finally, the culture conditions in the flasks were optimized. The strain was tolerant to higher selenite content in the liquid medium and the titer of SeMCys reached 7.5 mg/L. Conclusions The significance of methylmethionine as a methyl donor for SeMCys production in B. subtilis is reported, and enhanced precursor supply facilitates SeMCys synthesis. The results represent the highest SeMCys production to date and provide insight into Se metabolism.

Published

2023

19. LRP8‐mediated selenocysteine uptake is a targetable vulnerability in MYCN‐amplified neuroblastoma

Author

Hamed Alborzinia, Zhiyi Chen, Umut Yildiz, Florencio Porto Freitas, Felix C E Vogel, Julianna Patricia Varga, Jasmin Batani, Christoph Bartenhagen, Werner Schmitz, Gabriele Büchel, Bernhard Michalke, Jashuo Zheng, Svenja Meierjohann, Enrico Girardi, Elisa Espinet, Andrés F Flórez, Ancely Ferreira dos Santos, Nesrine Aroua, Tasneem Cheytan, Julie Haenlin, Lisa Schlicker, Thamara N Xavier da Silva, Adriana Przybylla, Petra Zeisberger, Giulio Superti‐Furga, Martin Eilers, Marcus Conrad, Marietta Fabiano, Ulrich Schweizer, Matthias Fischer, Almut Schulze, Andreas Trumpp, and José Pedro Friedmann Angeli

Subjects

ferroptosis, neuroblastoma, selenocysteine, selenoprotein, synthetic lethality, Medicine (General), R5-920, Genetics, QH426-470

Abstract

Abstract Ferroptosis has emerged as an attractive strategy in cancer therapy. Understanding the operational networks regulating ferroptosis may unravel vulnerabilities that could be harnessed for therapeutic benefit. Using CRISPR‐activation screens in ferroptosis hypersensitive cells, we identify the selenoprotein P (SELENOP) receptor, LRP8, as a key determinant protecting MYCN‐amplified neuroblastoma cells from ferroptosis. Genetic deletion of LRP8 leads to ferroptosis as a result of an insufficient supply of selenocysteine, which is required for the translation of the antiferroptotic selenoprotein GPX4. This dependency is caused by low expression of alternative selenium uptake pathways such as system Xc−. The identification of LRP8 as a specific vulnerability of MYCN‐amplified neuroblastoma cells was confirmed in constitutive and inducible LRP8 knockout orthotopic xenografts. These findings disclose a yet‐unaccounted mechanism of selective ferroptosis induction that might be explored as a therapeutic strategy for high‐risk neuroblastoma and potentially other MYCN‐amplified entities.

Published

2023

20. Bacterial selenocysteine synthase structure revealed by single-particle cryoEM

Author

Vitor Hugo Balasco Serrão, Karine Minari, Humberto D'Muniz Pereira, and Otavio Henrique Thiemann

Subjects

Selenocysteine, Selenocysteine synthase, SelA, tRNA[Ser]Sec, Single-particle analysis, Biology (General), QH301-705.5

Abstract

The 21st amino acid, selenocysteine (Sec), is synthesized on its dedicated transfer RNA (tRNASec). In bacteria, Sec is synthesized from Ser-tRNA[Ser]Sec by Selenocysteine Synthase (SelA), which is a pivotal enzyme in the biosynthesis of Sec. The structural characterization of bacterial SelA is of paramount importance to decipher its catalytic mechanism and its role in the regulation of the Sec-synthesis pathway. Here, we present a comprehensive single-particle cryo-electron microscopy (SPA cryoEM) structure of the bacterial SelA with an overall resolution of 2.69 Å. Using recombinant Escherichia coli SelA, we purified and prepared samples for single-particle cryoEM. The structural insights from SelA, combined with previous in vivo and in vitro knowledge, underscore the indispensable role of decamerization in SelA's function. Moreover, our structural analysis corroborates previous results that show that SelA adopts a pentamer of dimers configuration, and the active site architecture, substrate binding pocket, and key K295 catalytic residue are identified and described in detail. The differences in protein architecture and substrate coordination between the bacterial enzyme and its counterparts offer compelling structural evidence supporting the independent molecular evolution of the bacterial and archaea/eukarya Ser-Sec biosynthesis present in the natural world.

Published

2024

21. Deciphering the Role of Selenoprotein M.

Author

Nunes, Lance G. A., Cain, Antavius, Comyns, Cody, Hoffmann, Peter R., and Krahn, Natalie

Subjects

SELENOPROTEINS, CHEMICAL properties, POISONS, REACTIVE oxygen species, THIOREDOXIN, SELENOCYSTEINE

Abstract

Selenocysteine (Sec), the 21st amino acid, is structurally similar to cysteine but with a sulfur to selenium replacement. This single change retains many of the chemical properties of cysteine but often with enhanced catalytic and redox activity. Incorporation of Sec into proteins is unique, requiring additional translation factors and multiple steps to insert Sec at stop (UGA) codons. These Sec-containing proteins (selenoproteins) are found in all three domains of life where they often are involved in cellular homeostasis (e.g., reducing reactive oxygen species). The essential role of selenoproteins in humans requires us to maintain appropriate levels of selenium, the precursor for Sec, in our diet. Too much selenium is also problematic due to its toxic effects. Deciphering the role of Sec in selenoproteins is challenging for many reasons, one of which is due to their complicated biosynthesis pathway. However, clever strategies are surfacing to overcome this and facilitate production of selenoproteins. Here, we focus on one of the 25 human selenoproteins, selenoprotein M (SELENOM), which has wide-spread expression throughout our tissues. Its thioredoxin motif suggests oxidoreductase function; however, its mechanism and functional role(s) are still being uncovered. Furthermore, the connection of both high and low expression levels of SELENOM to separate diseases emphasizes the medical application for studying the role of Sec in this protein. In this review, we aim to decipher the role of SELENOM through detailing and connecting current evidence. With multiple proposed functions in diverse tissues, continued research is still necessary to fully unveil the role of SELENOM. [ABSTRACT FROM AUTHOR]

Published

2023

22. Optimized methyl donor and reduced precursor degradation pathway for seleno-methylselenocysteine production in Bacillus subtilis.

Author

Yin, Xian, Zhao, Meiyi, Zhou, Yu, Yang, Hulin, Liao, Yonghong, and Wang, Fenghuan

Subjects

*BACILLUS subtilis, *TITERS, *SELENOCYSTEINE, *BIOSURFACTANTS, *METHIONINE, *ADENOSYLMETHIONINE, *SERINE, *METHYLTRANSFERASES

Abstract

Background: Seleno-methylselenocysteine (SeMCys) is an effective component of selenium supplementation with anti-carcinogenic potential that can ameliorate neuropathology and cognitive deficits. In a previous study, a SeMCys producing strain of Bacillus subtilis GBACB was generated by releasing feedback inhibition by overexpression of cysteine-insensitive serine O-acetyltransferase, enhancing the synthesis of S-adenosylmethionine as methyl donor by overexpression of S-adenosylmethionine synthetase, and expressing heterologous selenocysteine methyltransferase. In this study, we aimed to improve GBACB SeMCys production by synthesizing methylmethionine as a donor to methylate selenocysteine and by inhibiting the precursor degradation pathway. Results: First, the performance of three methionine S-methyltransferases that provide methylmethionine as a methyl donor for SeMCys production was determined. Integration of the NmMmt gene into GBACB improved SeMCys production from 20.7 to 687.4 μg/L. Next, the major routes for the degradation of selenocysteine, which is the precursor of SeMCys, were revealed by comparing selenocysteine hyper-accumulating and non-producing strains at the transcriptional level. The iscSB knockout strain doubled SeMCys production. Moreover, deleting sdaA, which is responsible for the degradation of serine as a precursor of selenocysteine, enhanced SeMCys production to 4120.3 μg/L. Finally, the culture conditions in the flasks were optimized. The strain was tolerant to higher selenite content in the liquid medium and the titer of SeMCys reached 7.5 mg/L. Conclusions: The significance of methylmethionine as a methyl donor for SeMCys production in B. subtilis is reported, and enhanced precursor supply facilitates SeMCys synthesis. The results represent the highest SeMCys production to date and provide insight into Se metabolism. [ABSTRACT FROM AUTHOR]

Published

2023

23. Benzophenanthridine Alkaloid Chelerythrine Elicits Necroptosis of Gastric Cancer Cells via Selective Conjugation at the Redox Hyperreactive C-Terminal Sec 498 Residue of Cytosolic Selenoprotein Thioredoxin Reductase.

Author

Liu, Minghui, Sun, Shibo, Meng, Yao, Wang, Ling, Liu, Haowen, Shi, Wuyang, Zhang, Qiuyu, Xu, Weiping, Sun, Bingbing, and Xu, Jianqiang

Subjects

*PHENANTHRIDINE, *STOMACH cancer, *CANCER cells, *THIOREDOXIN, *ALKALOIDS, *SITE-specific mutagenesis

Abstract

Targeting thioredoxin reductase (TXNRD) with low-weight molecules is emerging as a high-efficacy anti-cancer strategy in chemotherapy. Sanguinarine has been reported to inhibit the activity of TXNRD1, indicating that benzophenanthridine alkaloid is a fascinating chemical entity in the field of TXNRD1 inhibitors. In this study, the inhibition of three benzophenanthridine alkaloids, including chelerythrine, sanguinarine, and nitidine, on recombinant TXNRD1 was investigated, and their anti-cancer mechanisms were revealed using three gastric cancer cell lines. Chelerythrine and sanguinarine are more potent inhibitors of TXNRD1 than nitidine, and the inhibitory effects take place in a dose- and time-dependent manner. Site-directed mutagenesis of TXNRD1 and in vitro inhibition analysis proved that chelerythrine or sanguinarine is primarily bound to the Sec498 residue of the enzyme, but the neighboring Cys497 and remaining N-terminal redox-active cysteines could also be modified after the conjugation of Sec498. With high similarity to sanguinarine, chelerythrine exhibited cytotoxic effects on multiple gastric cancer cell lines and suppressed the proliferation of tumor spheroids derived from NCI-N87 cells. Chelerythrine elevated cellular levels of reactive oxygen species (ROS) and induced endoplasmic reticulum (ER) stress. Moreover, the ROS induced by chelerythrine could be completely suppressed by the addition of N-acetyl-L-cysteine (NAC), and the same is true for sanguinarine. Notably, Nec-1, an RIPK1 inhibitor, rescued the chelerythrine-induced rapid cell death, indicating that chelerythrine triggers necroptosis in gastric cancer cells. Taken together, this study demonstrates that chelerythrine is a novel inhibitor of TXNRD1 by targeting Sec498 and possessing high anti-tumor properties on multiple gastric cancer cell lines by eliciting necroptosis. [ABSTRACT FROM AUTHOR]

Published

2023

24. Comparative analysis of CO2 reduction by soluble Escherichia coli formate dehydrogenase H and its selenocysteine-to-cysteine substitution variant

Author

Feilong Li, Silvan Scheller, and Michael Lienemann

Subjects

Formate dehydrogenase, Molybdenum, Selenocysteine, Carbon dioxide reduction, Metalloenzyme, Technology

Abstract

Metal-dependent formate dehydrogenases (Me-FDHs) are highly active CO2-reducing enzymes operating at low redox potentials and employ either molybdenum or tungsten to reduce the bound substrate. This makes them suitable for electrochemical applications such as fossil-free production of commodity chemicals utilizing renewable energy. Electrocatalytic CO2 reduction by cathode-immobilized Me-FDHs has been recently demonstrated and rational protein engineering can be used to optimize Me-FDHs for various carbon reduction reactions. In the present study, CO2 reduction by soluble monomeric Escherichia coli formate dehydrogenase H (EcFDH-H) was demonstrated and the function of its nucleophilic selenocysteine residue as a transient ligand of a centrally bound molybdenum atom was investigated. Kinetic analysis of the wildtype enzyme revealed maximum CO2 reduction rates of 44 ± 6 s−1 at pH 5.8 that was decreased to 19% and 0% in the case of selenocysteine substitution with the structural homologues cysteine and serine, respectively. Further selenocysteine-to-cysteine substitution effects included an increased acid tolerance as well as stronger inhibition by nitrate and azide indicating a shift of the Mo oxidation state from IV to VI. Conversely, a destabilizing effect on the oxidized Mo(VI) center could be assigned to the native selenocysteine residue that may facilitate the observed efficient CO2 reduction by rapid transition between Mo oxidation states. Taken together, the performed characterization of EcFDH-H as a catalyst for CO2 reduction and the selenocysteine substitution analysis furthers the understanding of the active-site structure of Me-FDHs and thereby supports the development of more efficient biocatalysts for CO2 reduction.

Published

2023

25. LRP8‐mediated selenocysteine uptake is a targetable vulnerability in MYCN‐amplified neuroblastoma.

Author

Alborzinia, Hamed, Chen, Zhiyi, Yildiz, Umut, Freitas, Florencio Porto, Vogel, Felix C E, Varga, Julianna Patricia, Batani, Jasmin, Bartenhagen, Christoph, Schmitz, Werner, Büchel, Gabriele, Michalke, Bernhard, Zheng, Jashuo, Meierjohann, Svenja, Girardi, Enrico, Espinet, Elisa, Flórez, Andrés F, dos Santos, Ancely Ferreira, Aroua, Nesrine, Cheytan, Tasneem, and Haenlin, Julie

Abstract

Ferroptosis has emerged as an attractive strategy in cancer therapy. Understanding the operational networks regulating ferroptosis may unravel vulnerabilities that could be harnessed for therapeutic benefit. Using CRISPR‐activation screens in ferroptosis hypersensitive cells, we identify the selenoprotein P (SELENOP) receptor, LRP8, as a key determinant protecting MYCN‐amplified neuroblastoma cells from ferroptosis. Genetic deletion of LRP8 leads to ferroptosis as a result of an insufficient supply of selenocysteine, which is required for the translation of the antiferroptotic selenoprotein GPX4. This dependency is caused by low expression of alternative selenium uptake pathways such as system Xc−. The identification of LRP8 as a specific vulnerability of MYCN‐amplified neuroblastoma cells was confirmed in constitutive and inducible LRP8 knockout orthotopic xenografts. These findings disclose a yet‐unaccounted mechanism of selective ferroptosis induction that might be explored as a therapeutic strategy for high‐risk neuroblastoma and potentially other MYCN‐amplified entities. Synopsis: The low‐density lipoprotein receptor (LRP8) was identified as a critical suppressor of ferroptosis in MYCN‐amplified neuroblastoma. Blocking selenium/selenocysteine uptake mechanisms via LRP8 offers a selective strategy to induce ferroptosis and disrupt GPX4 function. Ferroptosis, a cell death modality, is gaining interest as a therapeutic approach against challenging tumors.GPX4 is crucial for suppressing ferroptosis, but suitable in vivo inhibitors are lacking, limiting translation to cancer therapies.Genome‐wide and single‐cell CRISPR‐activation screens reveal LRP8 as a critical ferroptosis suppressor in MYCN‐amplified neuroblastoma.Blocking selenium/selenocysteine uptake via LRP8 disrupts GPX4 function and selectively induces ferroptotic cell death.LRP8 dependency emerges as the result of the low system Xc− activity suggesting that targeting LRP8 could be explore in other entities such as AML and lymphoma. [ABSTRACT FROM AUTHOR]

Published

2023

26. An efficient selenium transport pathway of selenoprotein P utilizing a high-affinity ApoER2 receptor variant and being independent of selenocysteine lyase.

Author

Ayako Mizuno, Takashi Toyama, Atsuya Ichikawa, Naoko Sakai, Yuya Yoshioka, Yukina Nishito, Renya Toga, Hiroshi Amesaka, Takayuki Kaneko, Kotoko Arisawa, Ryouhei Tsutsumi, Yuichiro Mita, Shun-ichi Tanaka, Noriko Noguchi, and Yoshiro Saito

Subjects

*SELENOPROTEINS, *SELENIUM, *SELENOCYSTEINE, *PROTEOLYSIS, *APOLIPOPROTEIN E, *BLOOD proteins

Abstract

Selenoprotein P (SeP, encoded by the SELENOP gene) is a plasma protein that contains selenium in the form of selenocysteine residues (Sec, a cysteine analog containing selenium instead of sulfur). SeP functions for the transport of selenium to specific tissues in a receptor-dependent manner. Apolipoprotein E receptor 2 (ApoER2) has been identified as a SeP receptor. However, diverse variants of ApoER2 have been reported, and the details of its tissue specificity and the molecular mechanism of its efficiency remain unclear. In the present study, we found that human T lymphoma Jurkat cells have a high ability to utilize selenium via SeP, while this ability was low in human rhabdomyosarcoma cells. We identified an ApoER2 variant with a high affinity for SeP in Jurkat cells. This variant had a dissociation constant value of 0.67 nM and a highly glycosylated O-linked sugar domain. Moreover, the acidification of intracellular vesicles was necessary for selenium transport via SeP in both cell types. In rhabdomyosarcoma cells, SeP underwent proteolytic degradation in lysosomes and transported selenium in a Sec lyase–dependent manner. However, in Jurkat cells, SeP transported selenium in Sec lyase–independent manner. These findings indicate a preferential selenium transport pathway involving SeP and highaffinity ApoER2 in a Sec lyase–independent manner. Herein, we provide a novel dynamic transport pathway for selenium via SeP. [ABSTRACT FROM AUTHOR]

Published

2023

27. Selenocysteine Formation by Enterococcus faecium ABMC-05 Follows a Mechanism That Is Not Dependent on Genes sel A and sel D but on Gene cys K.

Author

Escobar-Ramírez, Meyli Claudia, Rodríguez-Serrano, Gabriela Mariana, Zúñiga-León, Eduardo, García-Montes, Mario Adolfo, Pérez-Escalante, Emmanuel, and González-Olivares, Luis Guillermo

Subjects

SELENOCYSTEINE, ENTEROCOCCUS faecium, INDUCTIVELY coupled plasma atomic emission spectrometry, GENE expression, LACTIC acid bacteria, ENTEROCOCCUS

Abstract

Lactic acid bacteria (LAB) resist sodium selenite of concentrations greater than 100 mg/L in fermentation media. Selenium affects the growth rate, but once the microorganism absorbs selenium, this element is converted through a complex mechanism into selenocysteine and then into a selenoprotein structure. This study verified the presence of selenocysteine in Enterococcus faecium ABMC-05. The microorganism was cultivated in a medium enriched with a minimum inhibitory concentration of sodium selenite (184 mg/L). The concentration of selenium absorbed and the bioconversion into selenocysteine were determined by inductively coupled plasma optical emission spectrometry (ICP-OES) and reverse-phase high-performance chromatography (RP-HPLC), respectively. The presence of the selD, selA, and cysK genes was determined by amplifying the 16S rDNA through polymerase chain reaction (PCR). The microorganism accumulated inorganic selenium, and part was transformed into selenocysteine. The growth curves were atypical for a lactic acid bacterium with a stationary phase greater than 70 h. Determining the genetic expression showed only the presence of the cysK gene and the absence of the selD and the selA genes. The results demonstrate that this microorganism produces selenocysteine through a mechanism independent of the SelA and SelD pathways in contrast to other LAB. [ABSTRACT FROM AUTHOR]

Published

2023

28. Biological and Catalytic Properties of Selenoproteins.

Author

Chaudière, Jean

Subjects

*SELENOPROTEINS, *GLUTATHIONE peroxidase, *SELENOCYSTEINE, *ANAEROBIC bacteria, *CELL metabolism, *GENETIC code

Abstract

Selenocysteine is a catalytic residue at the active site of all selenoenzymes in bacteria and mammals, and it is incorporated into the polypeptide backbone by a co-translational process that relies on the recoding of a UGA termination codon into a serine/selenocysteine codon. The best-characterized selenoproteins from mammalian species and bacteria are discussed with emphasis on their biological function and catalytic mechanisms. A total of 25 genes coding for selenoproteins have been identified in the genome of mammals. Unlike the selenoenzymes of anaerobic bacteria, most mammalian selenoenzymes work as antioxidants and as redox regulators of cell metabolism and functions. Selenoprotein P contains several selenocysteine residues and serves as a selenocysteine reservoir for other selenoproteins in mammals. Although extensively studied, glutathione peroxidases are incompletely understood in terms of local and time-dependent distribution, and regulatory functions. Selenoenzymes take advantage of the nucleophilic reactivity of the selenolate form of selenocysteine. It is used with peroxides and their by-products such as disulfides and sulfoxides, but also with iodine in iodinated phenolic substrates. This results in the formation of Se-X bonds (X = O, S, N, or I) from which a selenenylsulfide intermediate is invariably produced. The initial selenolate group is then recycled by thiol addition. In bacterial glycine reductase and D-proline reductase, an unusual catalytic rupture of selenium–carbon bonds is observed. The exchange of selenium for sulfur in selenoproteins, and information obtained from model reactions, suggest that a generic advantage of selenium compared with sulfur relies on faster kinetics and better reversibility of its oxidation reactions. [ABSTRACT FROM AUTHOR]

Published

2023

29. Selenocysteine Substitution in a Class I Ribonucleotide Reductase.

Author

Stubbe, JoAnne, Nocera, Daniel, and Greene, Brandon

Subjects

Amino Acid Substitution, Models, Molecular, Protein Conformation, Ribonucleotide Reductases, Selenocysteine

Abstract

Ribonucleotide reductases (RNRs) employ a complex radical-based mechanism during nucleotide reduction involving multiple active site cysteines that both activate the substrate and reduce it. Using an engineered allo-tRNA, we substituted two active site cysteines with distinct function in the class Ia RNR of Escherichia coli for selenocysteine (U) via amber codon suppression, with efficiency and selectivity enabling biochemical and biophysical studies. Examination of the interactions of the C439U α2 mutant protein with nucleotide substrates and the cognate β2 subunit demonstrates that the endogenous Y122• of β2 is reduced under turnover conditions, presumably through radical transfer to form a transient U439• species. This putative U439• species is formed in a kinetically competent fashion but is incapable of initiating nucleotide reduction via 3-H abstraction. An analogous C225U α2 protein is also capable of radical transfer from Y122•, but the radical-based substrate chemistry partitions between turnover and stalled reduction akin to the reactivity of mechanism-based inhibitors of RNR. The results collectively demonstrate the essential role of cysteine redox chemistry in the class I RNRs and establish a new tool for investigating thiyl radical reactivity in biology.

Published

2019

30. Selenocysteine Substitution in a Class I Ribonucleotide Reductase

Author

Greene, Brandon L, Stubbe, JoAnne, and Nocera, Daniel G

Subjects

Biochemistry and Cell Biology, Biological Sciences, Amino Acid Substitution, Models, Molecular, Protein Conformation, Ribonucleotide Reductases, Selenocysteine, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Ribonucleotide reductases (RNRs) employ a complex radical-based mechanism during nucleotide reduction involving multiple active site cysteines that both activate the substrate and reduce it. Using an engineered allo-tRNA, we substituted two active site cysteines with distinct function in the class Ia RNR of Escherichia coli for selenocysteine (U) via amber codon suppression, with efficiency and selectivity enabling biochemical and biophysical studies. Examination of the interactions of the C439U α2 mutant protein with nucleotide substrates and the cognate β2 subunit demonstrates that the endogenous Y122• of β2 is reduced under turnover conditions, presumably through radical transfer to form a transient U439• species. This putative U439• species is formed in a kinetically competent fashion but is incapable of initiating nucleotide reduction via 3'-H abstraction. An analogous C225U α2 protein is also capable of radical transfer from Y122•, but the radical-based substrate chemistry partitions between turnover and stalled reduction akin to the reactivity of mechanism-based inhibitors of RNR. The results collectively demonstrate the essential role of cysteine redox chemistry in the class I RNRs and establish a new tool for investigating thiyl radical reactivity in biology.

Published

2019

31. Application of Selenocysteine Increased Soil Nitrogen Content, Enzyme Activity, and Microbial Quantity in Camellia oleifera Abel. Forests.

Author

Li, Jian, Tang, Wei, Lu, Sheng, Wang, Ye, Kuang, Zuoying, and Yuan, Jun

Subjects

NITROGEN in soils, SELENIUM, CAMELLIA oleifera, FOREST soils, SELENOCYSTEINE, NITRITE reductase, ACID soils

Abstract

The effect mechanism of inorganic selenium on soil fertility has been effectively explained, but the effect of selenocysteine as organic selenium on the soil of Camellia oleifera Abel. forests has not been reported. In this study, the soil of a C. oleifera forests under natural conditions was taken as the control, and four treatments, namely selenocysteine (SeCys), cysteine + sodium selenite (Cys + Se), urea + sodium selenite (Ur + Se), and cysteine (Cys), were set up through a pot experiment to analyze the effects of different treatments on the physicochemical properties and biological characteristics of soil in C. oleifera forests. The results showed that SeCys significantly increased the soil total nitrogen content, nitrate nitrogen, and ammonium nitrogen contents compared with the treatment with inorganic selenium. In addition, the application of SeCys improved the activities of soil urease, soil acid phosphatase, soil nitrate reductase, and soil nitrite reductase on day 24 of culture, while under Cys + Se treatment, the activities of these four enzymes showed significant effects on day 32. The effect of SeCys on increasing the number of soil bacteria and fungi was significantly higher than that of other treatments and increased by 800% and 217%, respectively, compared with the control. SeCys also had significant effects on selenium and nitrogen content of Camellia oleifera seedlings. Correlation analysis showed that soil microbial biomass carbon and nitrogen were significantly correlated with soil enzyme activity, suggesting that SeCys could promote enzyme activity in C. oleifera forests by increasing the microbial number and improving microbial metabolism. The results indicated that SeCys could be used as an ingredient in new high-efficiency fertilizers. [ABSTRACT FROM AUTHOR]

Published

2023

32. Morphological and Physiological Indicators and Transcriptome Analyses Reveal the Mechanism of Selenium Multilevel Mitigation of Cadmium Damage in Brassica juncea.

Author

Li, Linling, Wang, Shiyan, Wu, Shuai, Rao, Shen, Li, Li, Cheng, Shuiyuan, and Cheng, Hua

Subjects

BRASSICA juncea, TRANSCRIPTOMES, CADMIUM, SELENIUM, AGRICULTURE, POLLUTANTS

Abstract

Cadmium (Cd) is a common agricultural soil pollutant, which does serious harm to the environment and the human body. In this study, Brassica juncea was treated with different concentrations of CdCl2 and Na2SeO3. Then, physiological indexes and transcriptome were measured to reveal the mechanisms by which Se reduces the inhibition and toxicity of Cd in B. juncea. The results showed that Se alleviated the inhibitive Cd effects on seedling biomass, root length, and chlorophyll, and promoted the adsorption of Cd by pectin and lignin in the root cell wall (CW). Se also alleviated the oxidative stress induced by Cd, and reduced the content of MDA in cells. As a result, SeCys and SeMet alleviated the transport of Cd to the shoots. Transcriptome data showed that the bivalent cation transporter MPP and ABCC subfamily participated in the separation of Cd in vacuoles, CAL1 was related to the chelation of Cd in the cytoplasm of cells, and ZIP transporter 4 reduced the transport of Cd to the shoots. These results indicated that Se alleviated the damage of Cd in plants and decreased its transport to the shoots by improving the antioxidant system, enhancing the ability of the CW to adsorb Cd, reducing the activity of Cd transporters, and chelating Cd. [ABSTRACT FROM AUTHOR]

Published

2023

33. Biosynthesis, Engineering, and Delivery of Selenoproteins

Author

David E. Wright and Patrick O’Donoghue

Subjects

amber codon, aminoacyl-tRNA synthetases, elongation factor, genetic code expansion, opal codon, selenocysteine, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Selenocysteine (Sec) was discovered as the 21st genetically encoded amino acid. In nature, site-directed incorporation of Sec into proteins requires specialized biosynthesis and recoding machinery that evolved distinctly in bacteria compared to archaea and eukaryotes. Many organisms, including higher plants and most fungi, lack the Sec-decoding trait. We review the discovery of Sec and its role in redox enzymes that are essential to human health and important targets in disease. We highlight recent genetic code expansion efforts to engineer site-directed incorporation of Sec in bacteria and yeast. We also review methods to produce selenoproteins with 21 or more amino acids and approaches to delivering recombinant selenoproteins to mammalian cells as new applications for selenoproteins in synthetic biology.

Published

2023

34. Incorporation of Ni2+, Co2+, and Selenocysteine into the Auxiliary Fe‑S Cluster of the Radical SAM Enzyme HydG

Author

Rao, Guodong, Alwan, Katherine B, Blackburn, Ninian J, and Britt, R David

Subjects

Inorganic Chemistry, Chemical Sciences, Bacterial Proteins, Catalytic Domain, Cobalt, Cysteine, Iron-Sulfur Proteins, Nickel, Selenocysteine, Shewanella, Physical Chemistry (incl. Structural), Other Chemical Sciences, Inorganic & Nuclear Chemistry, Inorganic chemistry, Macromolecular and materials chemistry

Abstract

The radical SAM enzyme HydG generates CO- and CN--containing Fe complexes that are involved in the bioassembly of the [FeFe] hydrogenase active cofactor, the H-cluster. HydG contains a unique 5Fe-4S cluster in which the fifth "dangler" Fe and the coordinating cysteine molecule have both been shown to be essential for its function. Here, we demonstrate that this dangler Fe can be replaced with Ni2+ or Co2+ and that the cysteine can be replaced with selenocysteine. The resulting HydG variants were characterized by electron paramagnetic resonance and X-ray absorption spectroscopy, as well as subjected to a Tyr cleavage assay. Both Ni2+ and Co2+ are shown to be exchange-coupled to the 4Fe-4S cluster, and selenocysteine substitution does not alter the electronic structure significantly. XAS data provide details of the coordination environments near the Ni, Co, and Se atoms and support a close interaction of the dangler metal with the FeS cluster via an asymmetric SeCys bridge. Finally, while we were unable to observe the formation of novel organometallic species for the Ni2+ and Co2+ variants, the selenocysteine variant retains the activity of wild type HydG in forming [Fe(CO)x(CN)y] species. Our results provide more insights into the unique auxiliary cluster in HydG and expand the scope of artificially generated Fe-S clusters with heteroatoms.

Published

2019

35. Functional Profiling Identifies Determinants of Arsenic Trioxide Cellular Toxicity

Author

Sobh, Amin, Loguinov, Alex, Yazici, Gulce Naz, Zeidan, Rola S, Tagmount, Abderrahmane, Hejazi, Nima S, Hubbard, Alan E, Zhang, Luoping, and Vulpe, Chris D

Subjects

Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Hematology, Cancer, Rare Diseases, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Antineoplastic Agents, Arsenic Trioxide, CRISPR-Cas Systems, Cell Survival, Dose-Response Relationship, Drug, Gene Editing, Gene Expression Profiling, Gene Expression Regulation, Leukemic, HEK293 Cells, Humans, K562 Cells, Leukemia, Myelogenous, Chronic, BCR-ABL Positive, Signal Transduction, Sodium Selenite, Time Factors, Transcriptome, arsenic, selenium, CRISPR screen, selenocysteine, Toxicology, Pharmacology and pharmaceutical sciences

Abstract

Arsenic exposure is a worldwide health concern associated with an increased risk of skin, lung, and bladder cancer but arsenic trioxide (AsIII) is also an effective chemotherapeutic agent. The current use of AsIII in chemotherapy is limited to acute promyelocytic leukemia (APL). However, AsIII was suggested as a potential therapy for other cancer types including chronic myeloid leukemia (CML), especially when combined with other drugs. Here, we carried out a genome-wide CRISPR-based approach to identify modulators of AsIII toxicity in K562, a human CML cell line. We found that disruption of KEAP1, the inhibitory partner of the key antioxidant transcription factor Nrf2, or TXNDC17, a thioredoxin-like protein, markedly increased AsIII tolerance. Loss of the water channel AQP3, the zinc transporter ZNT1 and its regulator MTF1 also enhanced tolerance to AsIII whereas loss of the multidrug resistance protein ABCC1 increased sensitivity to AsIII. Remarkably, disruption of any of multiple genes, EEFSEC, SECISBP2, SEPHS2, SEPSECS, and PSTK, encoding proteins involved in selenocysteine metabolism increased resistance to AsIII. Our data suggest a model in which an intracellular interaction between selenium and AsIII may impact intracellular AsIII levels and toxicity. Together this work revealed a suite of cellular components/processes which modulate the toxicity of AsIII in CML cells. Targeting such processes simultaneously with AsIII treatment could potentiate AsIII in CML therapy.

Published

2019

36. Prospects for Anti-Tumor Mechanism and Potential Clinical Application Based on Glutathione Peroxidase 4 Mediated Ferroptosis.

Author

Chen, Mingliang, Shi, Zhihao, Sun, Yuqiu, Ning, Haoran, Gu, Xinyu, and Zhang, Lei

Subjects

*GLUTATHIONE peroxidase, *CLINICAL medicine, *IRON, *DRUG development, *SELENOCYSTEINE, *DRUG resistance in cancer cells

Abstract

Ferroptosis, characterized by excessive iron accumulation and lipid peroxidation, is a novel form of iron-dependent cell death, which is morphologically, genetically, and biochemically distinct from other known cell death types, such as apoptosis, necrosis, and autophagy. Emerging evidence shows that glutathione peroxidase 4 (GPX4), a critical core regulator of ferroptosis, plays an essential role in protecting cells from ferroptosis by removing the product of iron-dependent lipid peroxidation. The fast-growing studies on ferroptosis in cancer have boosted a perspective on its use in cancer therapeutics. In addition, significant progress has been made in researching and developing tumor therapeutic drugs targeting GPX4 based on ferroptosis, especially in acquired drug resistance. Selenium modulates GPX4-mediated ferroptosis, and its existing form, selenocysteine (Sec), is the active center of GPX4. This review explored the structure and function of GPX4, with the overarching goal of revealing its mechanism and potential application in tumor therapy through regulating ferroptosis. A deeper understanding of the mechanism and application of GPX4-mediated ferroptosis in cancer therapy will provide new strategies for the research and development of antitumor drugs. [ABSTRACT FROM AUTHOR]

Published

2023

37. Harnessing selenocysteine to enhance microbial cell factories for hydrogen production.

Author

Patel, Armaan, Mulder, David W., Söll, Dieter, and Krahn, Natalie

Subjects

HYDROGEN production, SELENOCYSTEINE, MICROBIAL cells, RENEWABLE energy sources, HYDROGENASE, OXYGEN detectors

Abstract

Hydrogen is a clean, renewable energy source, that when combined with oxygen, produces heat and electricity with only water vapor as a biproduct. Furthermore, it has the highest energy content by weight of all known fuels. As a result, various strategies have engineered methods to produce hydrogen efficiently and in quantities that are of interest to the economy. To approach the notion of producing hydrogen from a biological perspective, we take our attention to hydrogenases which are naturally produced in microbes. These organisms have the machinery to produce hydrogen, which when cleverly engineered, could be useful in cell factories resulting in large production of hydrogen. Not all hydrogenases are efficient at hydrogen production, and those that are, tend to be oxygen sensitive. Therefore, we provide a new perspective on introducing selenocysteine, a highly reactive proteinogenic amino acid, as a strategy towards engineering hydrogenases with enhanced hydrogen production, or increased oxygen tolerance. [ABSTRACT FROM AUTHOR]

Published

2022

38. Theoretical Investigations on the Sensing Mechanism of Phenanthroimidazole Fluorescent Probes for the Detection of Selenocysteine.

Author

Tang, Zhe, Wang, Xiaochen, Liu, Runze, and Zhou, Panwang

Subjects

*FLUORESCENT probes, *TIME-dependent density functional theory, *SELENOCYSTEINE, *INTRAMOLECULAR proton transfer reactions, *INTRAMOLECULAR charge transfer, *CHARGE transfer, *FLUORESCENCE quenching

Abstract

The level of selenocysteine (Sec) in the human body is closely related to a variety of pathophysiological states, so it is important to study its fluorescence sensing mechanism for designing efficient fluorescent probes. Herein, we used time-dependent density functional theory to investigate the fluorescence sensing mechanism of phenanthroimidazole derivates A4 and B4 for the detection of Sec, which are proposed to be designed based on excited state intramolecular proton transfer (ESIPT) and intramolecular charge transfer (ICT) mechanisms. The calculation results show that the fluorescence quenching mechanism of A4 and B4 is due to the photo-induced electron transfer (PET) process with the sulfonate group acts as the electron acceptor. Subsequently, A4 and B4 react with Sec, the sulfonate group is substituted by hydroxyl groups, PET is turned off, and significant fluorescence enhancement of the formed A3 and B3 is observed. The theoretical results suggest that the fluorescence enhancement mechanism of B3 is not based on ICT mechanism, and the charge transfer phenomenon was not observed by calculating the frontier molecular orbitals, and proved to be a local excitation mode. The reason for the fluorescence enhancement of A3 based on ESIPT is also explained by the calculated potential energy curves. [ABSTRACT FROM AUTHOR]

Published

2022

39. IRMPD spectroscopy of deprotonated selenocysteine - The 21st proteinogenic amino acid.

Author

Corinti, Davide, Berden, Giel, Oomens, Jos, Martinez-Haya, Bruno, Fornarini, Simonetta, and Crestoni, Maria Elisa

Subjects

*SELENOCYSTEINE, *MOLECULAR dynamics, *AMINO acids, *MASS spectrometry, *ISOMERS

Abstract

The effect of deprotonation on the structure and stability of the 21st proteinogenic amino acid selenocysteine, generated as bare deprotonated species by electrospray ionization, has been investigated by infrared multiple photon dissociation (IRMPD) spectroscopy over an extended frequency range (700-3600 cm−1), encompassing both the fingerprint and X–H (X = C, N, O) stretching ranges. IRMPD spectra, interpreted by anharmonic DFT calculations, provide evidence of a thermally averaged ion population of two types of low-lying canonical conformers deprotonated at the selenol (Se–H) group and involved in different H-bonding motifs. The broadened and diffuse band structures observed in the H-stretching range are well interpreted by Born-Oppenheimer molecular dynamics computations that provide a valuable description of the flexible backbone arrangements of Sec and of the proton sharing dynamics in the Se–HO and Se–HN moieties. Other prototropic isomers, deprotonated at the carboxylic group or with a zwitterionic structure, should not be significantly populated, according to their higher free energy and calculated IR spectra inconsistent with experimental evidence. [Display omitted] • The structure of isolated deprotonated amino acid selenocysteine was unveiled. • The deprotonation site on the selenol group was assessed. • IR ion spectroscopy was used over an extended frequency range (700–3600 cm⁻1). • Anharmonic IR calculations confirmed the presence of several conformers. • BOMD computations accurately interpret diffuse IR band structures. [ABSTRACT FROM AUTHOR]

Published

2024

40. Deciphering the Role of Selenoprotein M

Author

Lance G. A. Nunes, Antavius Cain, Cody Comyns, Peter R. Hoffmann, and Natalie Krahn

Subjects

selenocysteine, SELENOM, redox protein, selenoprotein, oxidoreductase, Therapeutics. Pharmacology, RM1-950

Abstract

Selenocysteine (Sec), the 21st amino acid, is structurally similar to cysteine but with a sulfur to selenium replacement. This single change retains many of the chemical properties of cysteine but often with enhanced catalytic and redox activity. Incorporation of Sec into proteins is unique, requiring additional translation factors and multiple steps to insert Sec at stop (UGA) codons. These Sec-containing proteins (selenoproteins) are found in all three domains of life where they often are involved in cellular homeostasis (e.g., reducing reactive oxygen species). The essential role of selenoproteins in humans requires us to maintain appropriate levels of selenium, the precursor for Sec, in our diet. Too much selenium is also problematic due to its toxic effects. Deciphering the role of Sec in selenoproteins is challenging for many reasons, one of which is due to their complicated biosynthesis pathway. However, clever strategies are surfacing to overcome this and facilitate production of selenoproteins. Here, we focus on one of the 25 human selenoproteins, selenoprotein M (SELENOM), which has wide-spread expression throughout our tissues. Its thioredoxin motif suggests oxidoreductase function; however, its mechanism and functional role(s) are still being uncovered. Furthermore, the connection of both high and low expression levels of SELENOM to separate diseases emphasizes the medical application for studying the role of Sec in this protein. In this review, we aim to decipher the role of SELENOM through detailing and connecting current evidence. With multiple proposed functions in diverse tissues, continued research is still necessary to fully unveil the role of SELENOM.

Published

2023

41. Benzophenanthridine Alkaloid Chelerythrine Elicits Necroptosis of Gastric Cancer Cells via Selective Conjugation at the Redox Hyperreactive C-Terminal Sec498 Residue of Cytosolic Selenoprotein Thioredoxin Reductase

Author

Minghui Liu, Shibo Sun, Yao Meng, Ling Wang, Haowen Liu, Wuyang Shi, Qiuyu Zhang, Weiping Xu, Bingbing Sun, and Jianqiang Xu

Subjects

thioredoxin reductase, chelerythrine, sanguinarine, necroptosis, gastric cancer, selenocysteine, Organic chemistry, QD241-441

Abstract

Targeting thioredoxin reductase (TXNRD) with low-weight molecules is emerging as a high-efficacy anti-cancer strategy in chemotherapy. Sanguinarine has been reported to inhibit the activity of TXNRD1, indicating that benzophenanthridine alkaloid is a fascinating chemical entity in the field of TXNRD1 inhibitors. In this study, the inhibition of three benzophenanthridine alkaloids, including chelerythrine, sanguinarine, and nitidine, on recombinant TXNRD1 was investigated, and their anti-cancer mechanisms were revealed using three gastric cancer cell lines. Chelerythrine and sanguinarine are more potent inhibitors of TXNRD1 than nitidine, and the inhibitory effects take place in a dose- and time-dependent manner. Site-directed mutagenesis of TXNRD1 and in vitro inhibition analysis proved that chelerythrine or sanguinarine is primarily bound to the Sec498 residue of the enzyme, but the neighboring Cys497 and remaining N-terminal redox-active cysteines could also be modified after the conjugation of Sec498. With high similarity to sanguinarine, chelerythrine exhibited cytotoxic effects on multiple gastric cancer cell lines and suppressed the proliferation of tumor spheroids derived from NCI-N87 cells. Chelerythrine elevated cellular levels of reactive oxygen species (ROS) and induced endoplasmic reticulum (ER) stress. Moreover, the ROS induced by chelerythrine could be completely suppressed by the addition of N-acetyl-L-cysteine (NAC), and the same is true for sanguinarine. Notably, Nec-1, an RIPK1 inhibitor, rescued the chelerythrine-induced rapid cell death, indicating that chelerythrine triggers necroptosis in gastric cancer cells. Taken together, this study demonstrates that chelerythrine is a novel inhibitor of TXNRD1 by targeting Sec498 and possessing high anti-tumor properties on multiple gastric cancer cell lines by eliciting necroptosis.

Published

2023

42. Dual incorporation of non-canonical amino acids enables production of post-translationally modified selenoproteins

Author

Pearl Morosky, Cody Comyns, Lance G. A. Nunes, Christina Z. Chung, Peter R. Hoffmann, Dieter Söll, Oscar Vargas-Rodriguez, and Natalie Krahn

Subjects

selenoproteins, acetyl-lysine, post-translational modifications, genetic code expansion, selenocysteine, synthetic biology, Biology (General), QH301-705.5

Abstract

Post-translational modifications (PTMs) can occur on almost all amino acids in eukaryotes as a key mechanism for regulating protein function. The ability to study the role of these modifications in various biological processes requires techniques to modify proteins site-specifically. One strategy for this is genetic code expansion (GCE) in bacteria. The low frequency of post-translational modifications in bacteria makes it a preferred host to study whether the presence of a post-translational modification influences a protein’s function. Genetic code expansion employs orthogonal translation systems engineered to incorporate a modified amino acid at a designated protein position. Selenoproteins, proteins containing selenocysteine, are also known to be post-translationally modified. Selenoproteins have essential roles in oxidative stress, immune response, cell maintenance, and skeletal muscle regeneration. Their complicated biosynthesis mechanism has been a hurdle in our understanding of selenoprotein functions. As technologies for selenocysteine insertion have recently improved, we wanted to create a genetic system that would allow the study of post-translational modifications in selenoproteins. By combining genetic code expansion techniques and selenocysteine insertion technologies, we were able to recode stop codons for insertion of Nε-acetyl-l-lysine and selenocysteine, respectively, into multiple proteins. The specificity of these amino acids for their assigned position and the simplicity of reverting the modified amino acid via mutagenesis of the codon sequence demonstrates the capacity of this method to study selenoproteins and the role of their post-translational modifications. Moreover, the evidence that Sec insertion technology can be combined with genetic code expansion tools further expands the chemical biology applications.

Published

2023

43. Site-Specific Incorporation of Selenocysteine Using an Expanded Genetic Code and Palladium-Mediated Chemical Deprotection

Author

Liu, Jun, Zheng, Feng, Cheng, Rujin, Li, Shanshan, Rozovsky, Sharon, Wang, Qian, and Wang, Lei

Subjects

Codon, Terminator, Escherichia coli, Escherichia coli Proteins, Genetic Code, Glutathione Peroxidase, HeLa Cells, Humans, Models, Molecular, Palladium, Protein Biosynthesis, Protein Engineering, Selenocysteine, Selenoproteins, Thioredoxins, Glutathione Peroxidase GPX1, Hela Cells, Chemical Sciences, General Chemistry

Abstract

Selenoproteins containing the 21st amino acid selenocysteine (Sec) exist in all three kingdoms of life and play essential roles in human health and development. The distinct low p Ka, high reactivity, and redox property of Sec also afford unique routes to protein modification and engineering. However, natural Sec incorporation requires idiosyncratic translational machineries that are dedicated to Sec and species-dependent, which makes it challenging to recombinantly prepare selenoproteins with high Sec specificity. As a consequence, the function of half of human selenoproteins remains unclear, and Sec-based protein manipulation has been greatly hampered. Here we report a new general method enabling the site-specific incorporation of Sec into proteins in E. coli. An orthogonal tRNAPyl-ASecRS was evolved to specifically incorporate Se-allyl selenocysteine (ASec) in response to the amber codon, and the incorporated ASec was converted to Sec in high efficiency through palladium-mediated cleavage under mild conditions compatible with proteins and cells. This approach completely obviates the natural Sec-dedicated factors, thus allowing various selenoproteins, regardless of Sec position and species source, to be prepared with high Sec specificity and enzyme activity, as shown by the preparation of human thioredoxin and glutathione peroxidase 1. Sec-selective labeling in the presence of Cys was also demonstrated on the surface of live E. coli cells. The tRNAPyl-ASecRS pair was further used in mammalian cells to incorporate ASec, which was converted into Sec by palladium catalyst in cellulo. This robust and versatile method should greatly facilitate the study of diverse natural selenoproteins and the engineering of proteins in general via site-specific introduction of Sec.

Published

2018

44. Harnessing selenocysteine to enhance microbial cell factories for hydrogen production

Author

Armaan Patel, David W. Mulder, Dieter Söll, and Natalie Krahn

Subjects

Selenocysteine, cell factories, biofuel, allo-tRNA, Selenoprotein, C1 microbes, Chemistry, QD1-999

Abstract

Hydrogen is a clean, renewable energy source, that when combined with oxygen, produces heat and electricity with only water vapor as a biproduct. Furthermore, it has the highest energy content by weight of all known fuels. As a result, various strategies have engineered methods to produce hydrogen efficiently and in quantities that are of interest to the economy. To approach the notion of producing hydrogen from a biological perspective, we take our attention to hydrogenases which are naturally produced in microbes. These organisms have the machinery to produce hydrogen, which when cleverly engineered, could be useful in cell factories resulting in large production of hydrogen. Not all hydrogenases are efficient at hydrogen production, and those that are, tend to be oxygen sensitive. Therefore, we provide a new perspective on introducing selenocysteine, a highly reactive proteinogenic amino acid, as a strategy towards engineering hydrogenases with enhanced hydrogen production, or increased oxygen tolerance.

Published

2022

45. Site-selective photocatalytic functionalization of peptides and proteins at selenocysteine.

Author

Dowman, Luke J., Kulkarni, Sameer S., Alegre-Requena, Juan V., Giltrap, Andrew M., Norman, Alexander R., Sharma, Ashish, Gallegos, Liliana C., Mackay, Angus S., Welegedara, Adarshi P., Watson, Emma E., van Raad, Damian, Niederacher, Gerhard, Huhmann, Susanne, Proschogo, Nicholas, Patel, Karishma, Larance, Mark, Becker, Christian F. W., Mackay, Joel P., Lakhwani, Girish, and Huber, Thomas

Subjects

PEPTIDES, SELENOCYSTEINE, CHEMICAL modification of proteins, SELENOPROTEINS, DRUG discovery, PROTEINS

Abstract

The importance of modified peptides and proteins for applications in drug discovery, and for illuminating biological processes at the molecular level, is fueling a demand for efficient methods that facilitate the precise modification of these biomolecules. Herein, we describe the development of a photocatalytic method for the rapid and efficient dimerization and site-specific functionalization of peptide and protein diselenides. This methodology, dubbed the photocatalytic diselenide contraction, involves irradiation at 450 nm in the presence of an iridium photocatalyst and a phosphine and results in rapid and clean conversion of diselenides to reductively stable selenoethers. A mechanism for this photocatalytic transformation is proposed, which is supported by photoluminescence spectroscopy and density functional theory calculations. The utility of the photocatalytic diselenide contraction transformation is highlighted through the dimerization of selenopeptides, and by the generation of two families of protein conjugates via the site-selective modification of calmodulin containing the 21st amino acid selenocysteine, and the C-terminal modification of a ubiquitin diselenide. The modification of peptides and proteins for application in drug discovery and chemical biology is currently a rapidly growing field of research. Here, the authors report a photocatalytic diselenide contraction method for the dimerization and site-specific functionalisation of peptides and protein. [ABSTRACT FROM AUTHOR]

Published

2022

46. Metabolism of Selenium, Selenocysteine, and Selenoproteins in Ferroptosis in Solid Tumor Cancers.

Author

Shimada, Briana K., Swanson, Sydonie, Toh, Pamela, and Seale, Lucia A.

Subjects

*SELENOPROTEINS, *SELENOCYSTEINE, *SELENIUM, *THIOREDOXIN, *CANCER cells

Abstract

A potential target of precision nutrition in cancer therapeutics is the micronutrient selenium (Se). Se is metabolized and incorporated as the amino acid selenocysteine (Sec) into 25 human selenoproteins, including glutathione peroxidases (GPXs) and thioredoxin reductases (TXNRDs), among others. Both the processes of Se and Sec metabolism for the production of selenoproteins and the action of selenoproteins are utilized by cancer cells from solid tumors as a protective mechanism against oxidative damage and to resist ferroptosis, an iron-dependent cell death mechanism. Protection against ferroptosis in cancer cells requires sustained production of the selenoprotein GPX4, which involves increasing the uptake of Se, potentially activating Se metabolic pathways such as the trans-selenation pathway and the TXNRD1-dependent decomposition of inorganic selenocompounds to sustain GPX4 synthesis. Additionally, endoplasmic reticulum-resident selenoproteins also affect apoptotic responses in the presence of selenocompounds. Selenoproteins may also help cancer cells adapting against increased oxidative damage and the challenges of a modified nutrient metabolism that result from the Warburg switch. Finally, cancer cells may also rewire the selenoprotein hierarchy and use Se-related machinery to prioritize selenoproteins that are essential to the adaptations against ferroptosis and oxidative damage. In this review, we discuss both the evidence and the gaps in knowledge on how cancer cells from solid tumors use Se, Sec, selenoproteins, and the Se-related machinery to promote their survival particularly via resistance to ferroptosis. [ABSTRACT FROM AUTHOR]

Published

2022

47. Improving Fmoc Solid Phase Synthesis of Human Beta Defensin 3.

Author

Walewska, Aleksandra, Kosikowska-Adamus, Paulina, Tomczykowska, Marta, Jaroszewski, Bartosz, Prahl, Adam, and Bulaj, Grzegorz

Subjects

*ANTIMICROBIAL peptides, *MELANOCORTIN receptors, *PEPTIDES, *CYTOKINE receptors, *DISULFIDES, *POTASSIUM channels, *SOLID-phase synthesis

Abstract

Human β-defensin 3, HBD-3, is a 45-residue antimicrobial and immunomodulatory peptide that plays multiple roles in the host defense system. In addition to interacting with cell membranes, HBD-3 is also a ligand for melanocortin receptors, cytokine receptors and voltage-gated potassium channels. Structural and functional studies of HBD-3 have been hampered by inefficient synthetic and recombinant expression methods. Herein, we report an optimized Fmoc solid-phase synthesis of this peptide using an orthogonal disulfide bonds formation strategy. Our results suggest that utilization of an optimized resin, coupling reagents and pseudoproline dipeptide building blocks decrease chain aggregation and largely improve the amount of the target peptide in the final crude material, making the synthesis more efficient. We also present an alternative synthesis of HBD-3 in which a replacement of a native disulfide bridge with a diselenide bond improved the oxidative folding. Our work enables further biological and pharmacological characterization of HBD-3, hence advancing our understanding of its therapeutic potential. [ABSTRACT FROM AUTHOR]

Published

2022

48. Virtual 2D map of cyanobacterial proteomes.

Author

Mohanta, Tapan Kumar, Mohanta, Yugal Kishore, Avula, Satya Kumar, Nongbet, Amilia, and Al-Harrasi, Ahmed

Subjects

*AMINO acids, *PROTEOMICS, *ISOELECTRIC point, *SELENOCYSTEINE, *MOLECULAR weights

Abstract

Cyanobacteria are prokaryotic Gram-negative organisms prevalent in nearly all habitats. A detailed proteomics study of Cyanobacteria has not been conducted despite extensive study of their genome sequences. Therefore, we conducted a proteome-wide analysis of the Cyanobacteria proteome and found Calothrix desertica as the largest (680331.825 kDa) and Candidatus synechococcus spongiarum as the smallest (42726.77 kDa) proteome of the cyanobacterial kingdom. A Cyanobacterial proteome encodes 312.018 amino acids per protein, with a molecular weight of 182173.1324 kDa per proteome. The isoelectric point (pI) of the Cyanobacterial proteome ranges from 2.13 to 13.32. It was found that the Cyanobacterial proteome encodes a greater number of acidic-pI proteins, and their average pI is 6.437. The proteins with higher pI are likely to contain repetitive amino acids. A virtual 2D map of Cyanobacterial proteome showed a bimodal distribution of molecular weight and pI. Several proteins within the Cyanobacterial proteome were found to encode Selenocysteine (Sec) amino acid, while Pyrrolysine amino acids were not detected. The study can enable us to generate a high-resolution cell map to monitor proteomic dynamics. Through this computational analysis, we can gain a better understanding of the bias in codon usage by analyzing the amino acid composition of the Cyanobacterial proteome. [ABSTRACT FROM AUTHOR]

Published

2022

49. High-Resolution Ribosome Profiling Reveals Gene-Specific Details of UGA Re-Coding in Selenoprotein Biosynthesis.

Author

Bohleber, Simon, Fradejas-Villar, Noelia, Zhao, Wenchao, Reuter, Uschi, and Schweizer, Ulrich

Subjects

*BIOSYNTHESIS, *SELENOPROTEINS, *RIBOSOMES, *SELENOCYSTEINE, *TRANSFER RNA, *GENETIC code, *MESSENGER RNA

Abstract

Co-translational incorporation of selenocysteine (Sec) into selenoproteins occurs at UGA codons in a process in which translational elongation competes with translational termination. Selenocysteine insertion sequence-binding protein 2 (SECISBP2) greatly enhances Sec incorporation into selenoproteins by interacting with the mRNA, ribosome, and elongation factor Sec (EFSEC). Ribosomal profiling allows to study the process of UGA re-coding in the physiological context of the cell and at the same time for all individual selenoproteins expressed in that cell. Using HAP1 cells expressing a mutant SECISBP2, we show here that high-resolution ribosomal profiling can be used to assess read-through efficiency at the UGA in all selenoproteins, including those with Sec close to the C-terminus. Analysis of ribosomes with UGA either at the A-site or the P-site revealed, in a transcript-specific manner, that SECISBP2 helps to recruit tRNASec and stabilize the mRNA. We propose to assess the effect of any perturbation of UGA read-through by determining the proportion of ribosomes carrying UGA in the P-site, pUGA. An additional, new observation is frameshifting that occurred 3′ of the UGA/Sec codon in SELENOF and SELENOW in SECISBP2-mutant HAP1 cells, a finding corroborated by reanalysis of neuron-specific Secisbp2R543Q-mutant brains. [ABSTRACT FROM AUTHOR]

Published

2022

50. Unconventional genetic code systems in archaea.

Author

Kexin Meng, Chung, Christina Z., Söll, Dieter, and Krahn, Natalie

Subjects

ARCHAEBACTERIA, GENETIC code, EXTREME environments, SELENOCYSTEINE, AMINO acids

Abstract

Archaea constitute the third domain of life, distinct from bacteria and eukaryotes given their ability to tolerate extreme environments. To survive these harsh conditions, certain archaeal lineages possess unique genetic code systems to encode either selenocysteine or pyrrolysine, rare amino acids not found in all organisms. Furthermore, archaea utilize alternate tRNA-dependent pathways to biosynthesize and incorporate members of the 20 canonical amino acids. Recent discoveries of new archaeal species have revealed the co-occurrence of these genetic code systems within a single lineage. This review discusses the diverse genetic code systems of archaea, while detailing the associated biochemical elements and molecular mechanisms. [ABSTRACT FROM AUTHOR]

Published

2022