Volume 12, Issue 3, Pages (March 2004)

Slides:

Advertisements

Similar presentations

Elena Conti, Nick P Franks, Peter Brick Structure

Advertisements

Munirathinam Sundaramoorthy, James Terner, Thomas L Poulos Structure

Volume 7, Issue 10, Pages (October 1999)

How do kinases transfer phosphoryl groups?

Volume 11, Issue 10, Pages (October 2004)

Yu Luo, Su-Chen Li, Min-Yuan Chou, Yu-Teh Li, Ming Luo Structure

Volume 12, Issue 3, Pages (March 2004)

Crystal Structure of Maltose Phosphorylase from Lactobacillus brevis

Volume 9, Issue 5, Pages (May 2001)

Crystal structure of human mitochondrial NAD(P)+-dependent malic enzyme: a new class of oxidative decarboxylases Yingwu Xu, Girija Bhargava, Hao Wu,

Chaperone-Assisted Crystallography with DARPins

Structure of RGS4 Bound to AlF4−-Activated Giα1: Stabilization of the Transition State for GTP Hydrolysis John J.G. Tesmer, David M. Berman, Alfred G.

Crystal Structure of a Vertebrate Smooth Muscle Myosin Motor Domain and Its Complex with the Essential Light Chain Roberto Dominguez, Yelena Freyzon,

Volume 10, Issue 12, Pages (December 2002)

Chloroplast NADP-malate dehydrogenase: structural basis of light-dependent regulation of activity by thiol oxidation and reduction Paul D Carr, Denis.

Volume 8, Issue 2, Pages (February 2000)

Volume 23, Issue 8, Pages (August 2015)

Volume 12, Issue 6, Pages (June 2004)

Volume 8, Issue 4, Pages (April 2001)

Volume 2, Issue 1, Pages (July 1998)

A biosynthetic thiolase in complex with a reaction intermediate: the crystal structure provides new insights into the catalytic mechanism Yorgo Modis,

The crystal structure of the bifunctional enzyme 6-phosphofructo-2-kinase/fructose-2,6- bisphosphatase reveals distinct domain homologies Charles A Hasemann,

Crystal Structure of PMM/PGM

Volume 4, Issue 5, Pages (November 1999)

Munirathinam Sundaramoorthy, James Terner, Thomas L Poulos Structure

Volume 17, Issue 3, Pages (March 2009)

Peter Trickey, Mary Ann Wagner, Marilyn Schuman Jorns, F Scott Mathews

The 1.9 Å Structure of α-N-Acetylgalactosaminidase

Volume 12, Issue 11, Pages (November 2004)

Functional and Structural Analysis of Programmed C-Methylation in the Biosynthesis of the Fungal Polyketide Citrinin Philip A. Storm, Dominik A. Herbst,

Volume 90, Issue 1, Pages (July 1997)

Daniel Peisach, Patricia Gee, Claudia Kent, Zhaohui Xu Structure

Qian Steven Xu, Rebecca B. Kucera, Richard J. Roberts, Hwai-Chen Guo

Volume 14, Issue 5, Pages (May 2006)

Volume 10, Issue 4, Pages (April 2002)

Volume 19, Issue 9, Pages (September 2011)

Crystal Structure of Carnitine Acetyltransferase and Implications for the Catalytic Mechanism and Fatty Acid Transport Gerwald Jogl, Liang Tong Cell

The Structure of Chorismate Synthase Reveals a Novel Flavin Binding Site Fundamental to a Unique Chemical Reaction John Maclean, Sohail Ali Structure

Volume 3, Issue 5, Pages (May 1999)

E. coli Dihydroorotate Dehydrogenase Reveals Structural and Functional Distinctions between Different Classes of Dihydroorotate Dehydrogenases Sofie.

Volume 4, Issue 10, Pages (October 1996)

Masaru Goto, Rie Omi, Noriko Nakagawa, Ikuko Miyahara, Ken Hirotsu

Volume 5, Issue 3, Pages (March 1997)

Volume 18, Issue 3, Pages (March 2010)

Activation Mechanism of the MAP Kinase ERK2 by Dual Phosphorylation

Volume 15, Issue 6, Pages (December 2001)

Structural Basis for Specificity in the Poxvirus Topoisomerase

Silvia Onesti, Andrew D Miller, Peter Brick Structure

Structure of the Rho Family GTP-Binding Protein Cdc42 in Complex with the Multifunctional Regulator RhoGDI Gregory R. Hoffman, Nicolas Nassar, Richard.

Volume 11, Issue 2, Pages (February 2003)

Crystal Structure of Imidazole Glycerol Phosphate Synthase

Volume 7, Issue 8, Pages (August 1999)

Solution Structure of a TBP–TAFII230 Complex

E.Radzio Andzelm, J Lew, S Taylor Structure

Active and Inactive Protein Kinases: Structural Basis for Regulation

Active and Inactive Protein Kinases: Structural Basis for Regulation

T Barrett, CG Suresh, SP Tolley, EJ Dodson, MA Hughes Structure

Human glucose-6-phosphate dehydrogenase: the crystal structure reveals a structural NADP+ molecule and provides insights into enzyme deficiency Shannon.

Pingwei Li, Gerry McDermott, Roland K. Strong Immunity

Structure of the InlB Leucine-Rich Repeats, a Domain that Triggers Host Cell Invasion by the Bacterial Pathogen L. monocytogenes Michael Marino, Laurence.

Structure of an IκBα/NF-κB Complex

Three protein kinase structures define a common motif

The Structure of Sortase B, a Cysteine Transpeptidase that Tethers Surface Protein to the Staphylococcus aureus Cell Wall Yinong Zong, Sarkis K Mazmanian,

Structural Basis for Activation of ARF GTPase

Volume 17, Issue 5, Pages (May 2009)

Andrey V Kajava, Gilbert Vassart, Shoshana J Wodak Structure

Morgan Huse, Ye-Guang Chen, Joan Massagué, John Kuriyan Cell

Volume 21, Issue 6, Pages (June 2013)

Volume 8, Issue 2, Pages (February 2000)

Volume 10, Issue 8, Pages (August 2002)

Presentation transcript:

Volume 12, Issue 3, Pages 361-370 (March 2004) Coenzyme Binding in F420-Dependent Secondary Alcohol Dehydrogenase, a Member of the Bacterial Luciferase Family Stephan W Aufhammer, Eberhard Warkentin, Holger Berk, Seigo Shima, Rudolf K Thauer, Ulrich Ermler Structure Volume 12, Issue 3, Pages 361-370 (March 2004) DOI: 10.1016/j.str.2004.02.010

Figure 1 F420-Dependent Alcohol Dehydrogenase Catalyzes the Oxidation of Isopropanol to Acetone with the Concomitant Reduction of F420 to F420H2 The enzyme is Si-face-specific with respect to the C5 atom of F420. Coenzyme F420 is composed of a deazaflavin ring, a ribitol, a phosphate, a lactate, and two or more glutamates. The rest R in F420 is shown for F420-2, the coenzyme present in Methanoculleus. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)

Figure 2 Sequence Alignment of the Bacterial Luciferase Family A larger subfamily is characterized by a nonprolyl cis peptide bond; a smaller subfamily to which SsuD belongs does not contain such a bond. Identical residues are colored in yellow, and conserved residues are colored in blue. Arrows and bars above indicate the secondary structure assignment based on the Adf structure. Residues involved in F420 binding are underlined. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)

Figure 3 Structure of Adf from Methanoculleus thermophilicus (A) Ribbon diagram of the dimer that shows the TIM barrel architecture of the monomer. The interface between the monomers is formed by three peripherical α helices and the insertion segments. (B) Stereo representation of the Cα chain of the Adf monomer. (C) Stereo plot of the Adf monomer (rotated 90° compared to [B]). The representation focuses on the conformation of the insertion regions (IS 1 to 4 in blue, sky-blue, magenta, and yellow) that are crucial for substrate binding and for the formation of the active site. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)

Figure 4 The Nonprolyl cis Peptide Bond in Adf The nonprolyl cis peptide bond between Cys72 and Ile73 is an essential constituent of a bulge that is directed toward the F420 binding site, causing a bent conformation of the deazaisoalloxazine ring. The well-conserved Asp38, which would partly interfere with a straight course of strand β3, is strongly linked to the polypeptide chain and stabilizes the bulge. These favorable interactions might compensate for the energy lost when forming the nonprolyl cis peptide bond. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)

Figure 5 Stereo Plot Showing the Interactions between the Coenzyme Molecule—F420—and the Enzyme and the Relative Positions of the F420 and Acetone Moieties of the F420-Acetone Adduct (A) F420 is bound into a 15 Å long cavity extending from the C-terminal end of the TIM barrel to the protein surface. It is linked to the protein matrix by 11 direct hydrogen bonds, mainly to main chain atoms. The negatively charged phosphate group is hydrogen bonded to the amide nitrogen of Gln126 and to the peptide nitrogens of Met175 and Gly176. The first glutamate of F420 is fixed by helix α5, as the partially positive charge of its N-terminal end interacts with the negative charge of the carboxylate group. (B) The acetone as part of the F420-acetone adduct binds into a predominantly hydrophobic pocket at the Si-face of F420. Residues His39, Glu108, and Trp43 are crucial for binding of the carbonyl oxygen of acetone. The hydroxyl oxygen of isopropanol probably binds to the same position and serves as an anchor for modeling the substrate. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)

Figure 6 Proposed Mechanism of F420-Acetone Formation and of Isopropanol Oxidation (A) The reaction between acetone and oxidized F420 can be understood on the basis of the nucleophilic attack of the C1 atom of acetone onto the C5 atom of F420. The C1 atom is electron rich, as seen in the enol or enolate tautomere of acetone. (B) Hydride transfer from the C2 atom of acetone to the C5 atom of the Si side of the F420. His39 is postulated to be the general catalytic base that abstracts a proton from isopropanol, whereas the protonated Glu108 and Trp43 stabilize the partly generated alcoholate anion in the transition state. Structure 2004 12, 361-370DOI: (10.1016/j.str.2004.02.010)