Duck-Yeon Lee

Small-Molecule Antioxidant Proteome-Shields in Deinococcus radiodurans

For Deinococcus radiodurans and other bacteria which are extremely resistant to ionizing radiation, ultraviolet radiation, and desiccation, a mechanistic link exists between resistance, manganese accumulation, and protein protection. We show that ultrafiltered, protein-free preparations of D. radiodurans cell extracts prevent protein oxidation at massive doses of ionizing radiation. In contrast, ultrafiltrates from ionizing radiation-sensitive bacteria were not protective. The D. radiodurans ultrafiltrate was enriched in Mn, phosphate, nucleosides and bases, and peptides. When reconstituted in vitro at concentrations approximating those in the D. radiodurans cytosol, peptides interacted synergistically with Mn2+ and orthophosphate, and preserved the activity of large, multimeric enzymes exposed to 50,000 Gy, conditions which obliterated DNA. When applied ex vivo, the D. radiodurans ultrafiltrate protected Escherichia coli cells and human Jurkat T cells from extreme cellular insults caused by ionizing radiation. By establishing that Mn2+-metabolite complexes of D. radiodurans specifically protect proteins against indirect damage caused by gamma-rays delivered in vast doses, our findings provide the basis for a new approach to radioprotection and insight into how surplus Mn budgets in cells combat reactive oxygen species.

Molecular Mechanism of the Reduction of Cysteine Sulfinic Acid of Peroxiredoxin to Cysteine by Mammalian Sulfiredoxin

Among many proteins with cysteine sulfinic acid (Cys-SO2H) residues, the sulfinic forms of certain peroxiredoxins (Prxs) are selectively reduced by sulfiredoxin (Srx) in the presence of ATP. All Srx enzymes contain a conserved cysteine residue. To elucidate the mechanism of the Srx-catalyzed reaction, we generated various mutants of Srx and examined their interaction with PrxI, their ATPase activity, and their ability to reduce sulfinic PrxI. Our results suggest that three surface-exposed amino acid residues, corresponding to Arg50, Asp57, and Asp79 of rat Srx, are critical for substrate recognition. The presence of the sulfinic form (but not the reduced form) of PrxI induces the conserved cysteine of Srx to take the γ-phosphate of ATP and then immediately transfers the phosphate to the sulfinic moiety of PrxI to generate a sulfinic acid phosphoryl ester (Prx-Cys-S(=O)\batchmode \documentclass[fleqn,10pt,legalpaper]{article} \usepackage{amssymb} \usepackage{amsfonts} \usepackage{amsmath} \pagestyle{empty} \begin{document} \(\mathrm{OPO}_{3}^{2-}\) \end{document}). This ester is reductively cleaved by a thiol molecule (RSH) such as GSH, thioredoxin, and dithiothreitol to produce a disulfide-S-monoxide (Prx-Cys-S(=O)-S-R). The disulfide-S-monoxide is further reduced through the oxidation of three thiol equivalents to complete the catalytic cycle and regenerate Prx-Cys-SH.

Novel Protective Mechanism against Irreversible Hyperoxidation of Peroxiredoxin Nα-TERMINAL ACETYLATION OF HUMAN PEROXIREDOXIN II

Peroxiredoxins (Prxs) are a group of peroxidases containing a cysteine thiol at their catalytic site. During peroxidase catalysis, the catalytic cysteine, referred to as the peroxidatic cysteine (CP), cycles between thiol (CP-SH) and disulfide (–S–S–) states via a sulfenic (CP-SOH) intermediate. Hyperoxidation of the CP thiol to its sulfinic (CP-SO2H) derivative has been shown to be reversible, but its sulfonic (CP-SO3H) derivative is irreversible. Our comparative study of hyperoxidation and regeneration of Prx I and Prx II in HeLa cells revealed that Prx II is more susceptible than Prx I to hyperoxidation and that the majority of the hyperoxidized Prx II formation is reversible. However, the hyperoxidized Prx I showed much less reversibility because of the formation of its irreversible sulfonic derivative, as verified with CP-SO3H-specific antiserum. In an attempt to identify the multiple hyperoxidized spots of the Prx I on two-dimensional PAGE analysis, an N-acetylated Prx I was identified as part of the total Prx I using anti-acetylated Lys antibody. Using peptidyl-Asp metalloendopeptidase (EC 3.4.24.33) peptide fingerprints, we found that Nα-terminal acetylation (Nα-Ac) occurred exclusively on Prx II after demethionylation. Nα-Ac of Prx II blocks Prx II from irreversible hyperoxidation without altering its affinity for hydrogen peroxide. A comparative study of non-Nα-acetylated and Nα-terminal acetylated Prx II revealed that Nα-Ac of Prx II induces a significant shift in the circular dichroism spectrum and elevation of Tm from 59.6 to 70.9 °C. These findings suggest that the structural maintenance of Prx II by Nα-Ac may be responsible for preventing its hyperoxidation to form CP-SO3H.

ERp16, an Endoplasmic Reticulum-resident Thiol-disulfide Oxidoreductase: BIOCHEMICAL PROPERTIES AND ROLE IN APOPTOSIS INDUCED BY ENDOPLASMIC RETICULUM STRESS*

We have characterized the properties and putative role of a mammalian thioredoxin-like protein, ERp16 (previously designated ERp18, ERp19, or hTLP19). The predicted amino acid sequence of the 172-residue human protein contains an NH2-terminal signal peptide, a thioredoxin-like domain with an active site motif (CGAC), and a COOH-terminal endoplasmic reticulum (ER) retention sequence (EDEL). Analyses indicated that the mature protein (comprising 146 residues) is generated by cleavage of the 26-residue signal peptide and is localized in the lumen of the ER. Biochemical experiments with the recombinant mature protein revealed it to be a thioldisulfide oxidoreductase. Its redox potential was about -165 mV; its active site cysteine residue Cys66 was nucleophilic with a pKa value of ∼6.6; it catalyzed the formation, reduction, and isomerization of disulfide bonds, with the unusual CGAC active site motif being responsible for these activities; and it existed as a dimer and underwent a redox-dependent conformational change. The observations that the redox potential of ERp16 (-165 mV) was within the range of that of the ER (-135 to -185 mV) and that ERp16 catalyzed disulfide isomerization of scrambled ribonuclease A suggest a role for ERp16 in protein disulfide isomerization in the ER. Expression of ERp16 in HeLa cells inhibited the induction of apoptosis by agents that elicit ER stress, including brefeldin A, tunicamycin, and dithiothreitol. In contrast, expression of a catalytically inactive mutant of ERp16 potentiated such apoptosis, as did depletion of ERp16 by RNA interference. Our results suggest that ERp16 mediates disulfide bond formation in the ER and plays an important role in cellular defense against prolonged ER stress.

Efficient Generation of β-Globin-Expressing Erythroid Cells using Stromal Cell-Derived Induced Pluripotent Stem Cells From Patients With Sickle Cell Disease.

Human embryonic stem (ES) cells and induced pluripotent stem (iPS) cells represent an ideal source for in vitro modeling of erythropoiesis and a potential alternative source for red blood cell transfusions. However, iPS cell‐derived erythroid cells predominantly produce ε‐ and γ‐globin without β‐globin production. We recently demonstrated that ES cell‐derived sacs (ES sacs), known to express hemangioblast markers, allow for efficient erythroid cell generation with β‐globin production. In this study, we generated several iPS cell lines derived from bone marrow stromal cells (MSCs) and peripheral blood erythroid progenitors (EPs) from sickle cell disease patients, and evaluated hematopoietic stem/progenitor cell (HSPC) generation after iPS sac induction as well as subsequent erythroid differentiation. MSC‐derived iPS sacs yielded greater amounts of immature hematopoietic progenitors (VEGFR2 + GPA−), definitive HSPCs (CD34 + CD45+), and megakaryoerythroid progenitors (GPA + CD41a+), as compared to EP‐derived iPS sacs. Erythroid differentiation from MSC‐derived iPS sacs resulted in greater amounts of erythroid cells (GPA+) and higher β‐globin (and βS‐globin) expression, comparable to ES sac‐derived cells. These data demonstrate that human MSC‐derived iPS sacs allow for more efficient erythroid cell generation with higher β‐globin production, likely due to heightened emergence of immature progenitors. Our findings should be important for iPS cell‐derived erythroid cell generation. Stem Cells 2017;35:586–596

Solution NMR Structure of Selenium-binding Protein from Methanococcus vannielii

Selenium is an important nutrient. The lack of selenium will suppress expression of various enzymes that will lead to cell abnormality and diseases. However, high concentrations of free selenium are toxic to the cell because it adversely affects numerous cell metabolic pathways. In Methanonoccus vannielii, selenium transport in the cell is established by the selenium-binding protein, SeBP. SeBP sequesters selenium during transport, thus regulating the level of free selenium in the cell, and delivers it specifically to the selenophosphate synthase enzyme. In solution, SeBP is an oligomer of 8.8-kDa subunits. It is a symmetric pentamer. The solution structure of SeBP was determined by NMR spectroscopy. Each subunit of SeBP is composed of an α-helix on top of a 4-stranded twisted β-sheet. The stability of the five subunits stems mainly from hydrophobic interactions and supplemented by hydrogen bond interactions. The loop containing Cys59 has been shown to be important for selenium binding, is flexible, and adopts multiple conformations. However, the cysteine accessibility is restricted in the structure, reducing the possibility of the binding of free selenium readily. Therefore, a different selenium precursor or other factors might be needed to facilitate opening of this loop to expose Cys59 for selenium binding.

Regulation of the actin-activated MgATPase activity of Acanthamoeba myosin II by phosphorylation of serine 639 in motor domain loop 2

Significance Myosin II from the soil amoeba Acanthamoeba castellanii is a member of the largest of the 35 classes of the superfamily of molecular motors that, together with actin filaments, convert the energy of hydrolysis of ATP into force or motion that drives numerous cellular and intracellular processes. In this paper we show that the actin-activated ATPase of Acanthamoeba myosin II is regulated by phosphorylation of a specific serine in a region of the myosin motor domain that is known to be at the myosin–actin interface. No other myosin has been shown to be regulated in this way. It had been proposed previously that only filamentous forms of Acanthamoeba myosin II have actin-activated MgATPase activity and that this activity is inhibited by phosphorylation of up to four serine residues in a repeating sequence in the C-terminal nonhelical tailpiece of the two heavy chains. We have reinvestigated these issues using recombinant WT and mutant myosins. Contrary to the earlier proposal, we show that two nonfilamentous forms of Acanthamoeba myosin II, heavy meromyosin and myosin subfragment 1, have actin-activated MgATPase that is down-regulated by phosphorylation. By mass spectroscopy, we identified five serines in the heavy chains that can be phosphorylated by a partially purified kinase preparation in vitro and also are phosphorylated in endogenous myosin isolated from the amoebae: four serines in the nonhelical tailpiece and Ser639 in loop 2 of the motor domain. S639A mutants of both subfragment 1 and full-length myosin had actin-activated MgATPase that was not inhibited by phosphorylation of the serines in the nonhelical tailpiece or their mutation to glutamic acid or aspartic acid. Conversely, S639D mutants of both subfragment 1 and full-length myosin were inactive, irrespective of the phosphorylation state of the serines in the nonhelical tailpiece. To our knowledge, this is the first example of regulation of the actin-activated MgATPase activity of any myosin by modification of surface loop 2.

Increased activity of TNAP compensates for reduced adenosine production and promotes ectopic calcification in the genetic disease ACDC

Patient-derived induced pluripotent stem cells reveal treatment strategies for a rare genetic form of arterial calcification. Understanding vascular calcification ACDC is a rare genetic vascular calcification disease caused by loss of CD73, a secreted enzyme that converts adenosine monophosphate (AMP) to adenosine. Cells from ACDC patients have a compensatory increase in the phosphatase TNAP, which primarily catalyzes the conversion of pyrophosphate to inorganic phosphate but can also convert AMP to adenosine. Jin et al. generated induced pluripotent stem cells (iPSCs) from ACDC patients. Although in culture, these cells generated adenosine from AMP, the cells had decreased amounts of pyrophosphate, which inhibits calcification. ACDC patient–derived cells showed increased activation of the mTOR pathway, which promotes calcification. When injected into mice, the ACDC patient–derived iPSCs formed calcified teratomas. Treating mice bearing these teratomas with an adenosine receptor agonist, the mTOR inhibitor rapamycin, or etidronate (a drug that is structurally similar to pyrophosphate) reduced calcification in the teratomas, suggesting multiple potential strategies for treating ectopic calcification in ACDC patients and thereby alleviating the pain and peripheral ischemia associated with the disease. ACDC (arterial calcification due to deficiency of CD73) is an autosomal recessive disease resulting from loss-of-function mutations in NT5E, which encodes CD73, a 5′-ectonucleotidase that converts extracellular adenosine monophosphate to adenosine. ACDC patients display progressive calcification of lower extremity arteries, causing limb ischemia. Tissue-nonspecific alkaline phosphatase (TNAP), which converts pyrophosphate (PPi) to inorganic phosphate (Pi), and extracellular purine metabolism play important roles in other inherited forms of vascular calcification. Compared to cells from healthy subjects, induced pluripotent stem cell–derived mesenchymal stromal cells (iMSCs) from ACDC patients displayed accelerated calcification and increased TNAP activity when cultured under conditions that promote osteogenesis. TNAP activity generated adenosine in iMSCs derived from ACDC patients but not in iMSCs from control subjects, which have CD73. In response to osteogenic stimulation, ACDC patient–derived iMSCs had decreased amounts of the TNAP substrate PPi, an inhibitor of extracellular matrix calcification, and exhibited increased activation of AKT, mechanistic target of rapamycin (mTOR), and the 70-kDa ribosomal protein S6 kinase (p70S6K), a pathway that promotes calcification. In vivo, teratomas derived from ACDC patient cells showed extensive calcification and increased TNAP activity. Treating mice bearing these teratomas with an A2b adenosine receptor agonist, the mTOR inhibitor rapamycin, or the bisphosphonate etidronate reduced calcification. These results show that an increase of TNAP activity in ACDC contributes to ectopic calcification by disrupting the extracellular balance of PPi and Pi and identify potential therapeutic targets for ACDC.

Interactions of the acidic domain and SRF interacting motifs with the NKX3.1 homeodomain.

NKX3.1 is a prostate tumor suppressor belonging to the NK-2 family of homeodomain (HD) transcription factors. NK-2 family members often possess a stretch of 10-15 residues enriched in acidic amino acids, the acidic domain (AD), in the flexible, disordered region N-terminal to the HD. Interactions between the N-terminal region of NKX3.1 and its homeodomain affect protein stability and DNA binding. CD spectroscopy measuring the thermal unfolding of NKX3.1 constructs showed a 2 degrees C intramolecular stabilization of the HD by the N-terminal region containing the acidic domain (residues 85-96). CD of mixtures of various N-terminal peptides with a construct containing just the HD showed that the acidic domain and the following region, the SRF interacting (SI) motif (residues 99-105), was necessary for this stabilization. Phosphorylation of the acidic domain is known to slow proteasomal degradation of NKX3.1 in prostate cells, and NMR spectroscopy was used to measure and map the interaction of the HD with phosphorylated and nonphosphorylated forms of the AD peptide. The interaction with the phosphorylated AD peptide was considerably stronger (K(d) = 0.5 +/- 0.2 mM), resulting in large chemical shift perturbations for residues Ser150 and Arg175 in the HD, as well as a 2 degrees C increase in the HD thermal stability compared to that of the nonphosphorylated form. NKX3.1 constructs with AD phosphorylation site threonine residues (89 and 93) mutated to glutamate were 4 degrees C more stable than HD alone. Using polymer theory, effective concentrations for interactions between domains connected by flexible linkers are predicted to be in the millimolar range, and thus, the weak intramolecular interactions observed here could conceivably modulate or compete with stronger, intermolecular interactions with the NKX3.1 HD.

Sirt1 carboxyl-domain is an ATP-repressible domain that is transferrable to other proteins

Sirt1 is an NAD+-dependent protein deacetylase that regulates many physiological functions, including stress resistance, adipogenesis, cell senescence and energy production. Sirt1 can be activated by energy deprivation, but the mechanism is poorly understood. Here, we report that Sirt1 is negatively regulated by ATP, which binds to the C-terminal domain (CTD) of Sirt1. ATP suppresses Sirt1 activity by impairing the CTDs ability to bind to the deacetylase domain as well as its ability to function as the substrate recruitment site. ATP, but not NAD+, causes a conformational shift to a less compact structure. Mutations that prevent ATP binding increase Sirt1s ability to promote stress resistance and inhibit adipogenesis under high-ATP conditions. Interestingly, the CTD can be attached to other proteins, thereby converting them into energy-regulated proteins. These discoveries provide insight into how extreme energy deprivation can impact Sirt1 activity and underscore the complex nature of Sirt1 structure and regulation.