3s2s Citations

Get phases from arsenic anomalous scattering: de novo SAD phasing of two protein structures crystallized in cacodylate buffer.

<div class='caption-title'>The plot of theoretical f prime and f double prime for arsenic and selenium.</div>
<div class='caption-title'>Anomalous difference Fourier map calculated with final phases at 5 σ.</div>
<div class='caption-title'>Electron density is shown around Cys136 in smPncA (A,C,E,G) and Cys264 in Casp6 (B,D,F,H).</div>
Liu X, Zhang H, Wang XJ, Li LF, Su XD
OpenAccess logo PLoS One 6 e24227 (2011)
Cited: 17 times
EuropePMC logo PMID: 21912678

Abstract

The crystal structures of two proteins, a putative pyrazinamidase/nicotinamidase from the dental pathogen Streptococcus mutans (SmPncA) and the human caspase-6 (Casp6), were solved by de novo arsenic single-wavelength anomalous diffraction (As-SAD) phasing method. Arsenic (As), an uncommonly used element in SAD phasing, was covalently introduced into proteins by cacodylic acid, the buffering agent in the crystallization reservoirs. In SmPncA, the only cysteine was bound to dimethylarsinoyl, which is a pentavalent arsenic group (As (V)). This arsenic atom and a protein-bound zinc atom both generated anomalous signals. The predominant contribution, however, was from the As anomalous signals, which were sufficient to phase the SmPncA structure alone. In Casp6, four cysteines were found to bind cacodyl, a trivalent arsenic group (As (III)), in the presence of the reducing agent, dithiothreitol (DTT), and arsenic atoms were the only anomalous scatterers for SAD phasing. Analyses and discussion of these two As-SAD phasing examples and comparison of As with other traditional heavy atoms that generate anomalous signals, together with a few arsenic-based de novo phasing cases reported previously strongly suggest that As is an ideal anomalous scatterer for SAD phasing in protein crystallography.

Articles - 3s2s mentioned but not cited (3)

  1. Get phases from arsenic anomalous scattering: de novo SAD phasing of two protein structures crystallized in cacodylate buffer. Liu X, Zhang H, Wang XJ, Li LF, Su XD. PLoS One 6 e24227 (2011)
  2. Biochemical characterization of a new nicotinamidase from an unclassified bacterium thriving in a geothermal water stream microbial mat community. Zapata-Pérez R, Martínez-Moñino AB, García-Saura AG, Cabanes J, Takami H, Sánchez-Ferrer Á. PLoS One 12 e0181561 (2017)
  3. Elucidating arsenic-bound proteins in the protein data bank: data mining and amino acid cross-validation through Raman spectroscopy. Nayek U, Acharya S, Abdul Salam AA. RSC Adv 13 36261-36279 (2023)


Reviews citing this publication (1)

  1. Small Molecule Active Site Directed Tools for Studying Human Caspases. Poreba M, Szalek A, Kasperkiewicz P, Rut W, Salvesen GS, Drag M. Chem Rev 115 12546-12629 (2015)

Articles citing this publication (13)

  1. Proximity-Directed Labeling Reveals a New Rapamycin-Induced Heterodimer of FKBP25 and FRB in Live Cells. Lee SY, Lee H, Lee HK, Lee SW, Ha SC, Kwon T, Seo JK, Lee C, Rhee HW. ACS Cent Sci 2 506-516 (2016)
  2. A multipronged approach for compiling a global map of allosteric regulation in the apoptotic caspases. Dagbay K, Eron SJ, Serrano BP, Velázquez-Delgado EM, Zhao Y, Lin D, Vaidya S, Hardy JA. Methods Enzymol 544 215-249 (2014)
  3. Crystal structure of a complex of NOD1 CARD and ubiquitin. Ver Heul AM, Gakhar L, Piper RC, Subramanian R. PLoS One 9 e104017 (2014)
  4. Serendipitous SAD Solution for DMSO-Soaked SOCS2-ElonginC-ElonginB Crystals Using Covalently Incorporated Dimethylarsenic: Insights into Substrate Receptor Conformational Flexibility in Cullin RING Ligases. Gadd MS, Bulatov E, Ciulli A. PLoS One 10 e0131218 (2015)
  5. Caspase-6 Undergoes a Distinct Helix-Strand Interconversion upon Substrate Binding. Dagbay KB, Bolik-Coulon N, Savinov SN, Hardy JA. J Biol Chem 292 4885-4897 (2017)
  6. A QM/MM study of the catalytic mechanism of nicotinamidase. Sheng X, Liu Y. Org Biomol Chem 12 1265-1277 (2014)
  7. Activation of Caspase-6 Is Promoted by a Mutant Huntingtin Fragment and Blocked by an Allosteric Inhibitor Compound. Ehrnhoefer DE, Skotte NH, Reinshagen J, Qiu X, Windshügel B, Jaishankar P, Ladha S, Petina O, Khankischpur M, Nguyen YTN, Caron NS, Razeto A, Meyer Zu Rheda M, Deng Y, Huynh KT, Wittig I, Gribbon P, Renslo AR, Geffken D, Gul S, Hayden MR. Cell Chem Biol 26 1295-1305.e6 (2019)
  8. Caspases from scleractinian coral show unique regulatory features. Shrestha S, Tung J, Grinshpon RD, Swartz P, Hamilton PT, Dimos B, Mydlarz L, Clark AC. J Biol Chem 295 14578-14591 (2020)
  9. Combined Whole-Cell High-Throughput Functional Screening for Identification of New Nicotinamidases/Pyrazinamidases in Metagenomic/Polygenomic Libraries. Zapata-Pérez R, García-Saura AG, Jebbar M, Golyshin PN, Sánchez-Ferrer Á. Front Microbiol 7 1915 (2016)
  10. Structure and Electron-Transfer Pathway of the Human Methionine Sulfoxide Reductase MsrB3. Javitt G, Cao Z, Resnick E, Gabizon R, Bulleid NJ, Fass D. Antioxid Redox Signal 33 665-678 (2020)
  11. The pentatricopeptide repeat protein Rmd9 recognizes the dodecameric element in the 3'-UTRs of yeast mitochondrial mRNAs. Hillen HS, Markov DA, Wojtas ID, Hofmann KB, Lidschreiber M, Cowan AT, Jones JL, Temiakov D, Cramer P, Anikin M. Proc Natl Acad Sci U S A 118 e2009329118 (2021)
  12. Structure of the replication regulator Sap1 reveals functionally important interfaces. Jørgensen MM, Ekundayo B, Zaratiegui M, Skriver K, Thon G, Schalch T. Sci Rep 8 10930 (2018)
  13. Conformational transitions of caspase-6 in substrate-induced activation process explored by perturbation-response scanning combined with targeted molecular dynamics. Huang S, Mei H, Lu L, Kuang Z, Heng Y, Xu L, Liang X, Qiu M, Pan X. Comput Struct Biotechnol J 19 4156-4164 (2021)


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