A-ATP Synthase

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Bovine ATP synthase chains α (grey, green, pink), β (yellow, magenta, cyan), γ (gold), δ (red), ε (wheat) (PDB code 1e79)

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Structure

The structure on the right shows the F1 motor and the axle that connects the two. ATP synthesis is composed of two rotary motors, each powered by a different fuel. The motor at the top, termed F0, an electric motor. It is embedded in a membrane (shown schematically as a gray stripe here), and is powered by the flow of hydrogen ions across the membrane. As the protons flow through the motor, they turn a circular rotor . This rotor is connected to the second motor, termed F1. The F1 motor is a chemical motor, powered by ATP. The two motors are connected together by a stator, shown on the right, so that when F0 turns, F1 turns too. A-ATP synthase is very similar to F ATP Synthase and is composed of two parts A1 and A0 which are composed of at least nine subunits A3B3C:D:E:F:H2:a:cx that function as a pair of rotary motors connected by central and peripheral stalk(s) ^[1]. The A0 domain is the hydrophobic membrane embedded ion-translocating sector that uses the H+ gradient to power ATP synthase in domain A1. A1 is catalytic and water soluble containing A and B subunits. These subunits are comparable to F-ATP synthase ATP synthase alpha/beta subunits. The A subunit of A1 is catalytic and the B subunit is regulatory, with a substrate-binding site on each. [1]

The central stalk in ATP synthase, made of gamma, delta and epsilon subunits in the mitochondrial enzyme, is the key rotary element in the enzyme's catalytic mechanism. The penetrates the catalytic (alpha beta)(3) domain and protrudes beneath it, interacting with a ring of c subunits in the membrane that drives rotation of the stalk during ATP synthesis. In ATP synthase, the central stalk interacts with the c-ring and couples the transmembrane proton motive force to catalysis in the ( (3) domain.

When operating as a generator, it uses the power of rotational motion to build ATP, or when operating as a motor, it breaks down ATP to spin the axle the opposite direction. The synthesis of ATP requires , including the binding of ADP and phosphate, the formation of the new phosphate-phosphate bond, and release of ATP. As the axle turns, it forces the motor into three different conformations that assist these difficult steps. The beta subunits have a structural role, holding everything in place. The alpha subunits are the ATP generating parts. ^[2]There are three catalytic nucleotide binding sites and three corresponding states induced by the central stalks rotation. In the Alternating catalytic model, the binding sites go through three different states. In the Open State ATP is released and ADP and Pi enters the active site. In the Loose state ADP and Pi are bound and the active site closes up around the molecules.The Tight State forces molecules together, catalyzing the formation of the phosphate bond.

Introduction

The archaeal A1A0 ATP synthase represent a class of chimeric ATPases/synthase , whose function and general structural design share characteristics both with vacuolar V1V0 ATPases and with F1Fo ATP synthases ^[3]. A1A0 ATP synthase catalyzes the formation of the energy currency ATP by a membrane-embedded electrically-driven motor. The archaeon in this study,Pyrococcushorikoshii OT3 is an anaerobic thermophile residing in oceanic deep sea vents with an optimal growth temperature of 100 degrees C. Anaerobic fermentation is its principle metabolic pathway. A hyperthermophilic, anaerobic archaeon was isolated from hydrothermal fluid samples obtained at the Okinawa Trough vents in the NE Pacific Ocean, at a depth of 1395m. The strain is obligately heterotrophic, and utilizes complex proteinaceous media (peptone, tryptone, or yeast extract), or a 21-amino-acid mixture supplemented with vitamins, as growth substrates. Sulfur greatly enhances growth. The cells are irregular cocci with a tuft of flagella, growing optimally at 98 degrees C (maximum growth temperature 102 degrees C), but capable of prolonged survival at 105 degrees C. ^[4] The specific enzymatic process in A-ATP synthase reveals novel, exceptional subunit composition and coupling stoichiometries that may reflect the differences in energy-conserving mechanisms as well as adaptation to temperatures at or above 100 degrees C. Because some archaea are rooted close to the origin in the tree of life, these unusual mechanisms are considered to have developed very early in the history of life and, therefore, may represent the first energy-conserving mechanisms. ^[1]

Structure of A-ATP synthase catalytic subunit A

Five steps inside the catalytic A-subunit are critical for catalysis. Substrate entrance, phosphate and nucleotide binding, transition-state formation, ATP formation, and product release. The vanadate bound model mimics the transition state. Orthovandate is a useful transition state analog because it can adapt both tetragonal and trigonal bipyramidal coordination geometry. The Avi structure can be compared to the As sulfate bound structure and the Apnp AMP-PNP bound structure. As is analogous to the phosphate binding (substrate) structure and Apnp is analogous to the ATP binding (product) structure^[5].

Within the catalytic A subunit there are the N-terminal domain residues 1-79, 110-116, 189-199, the non-homologous region(which region makes this subunit considerably larger than its homologs) residues 117-188, the nucleotide binding alpha-beta domain residues 80-99, 200-437, and C-terminal alpha helical bundle residues 438-588 domains. There are 16 helices and 27 strands.

P-Loop

The is the eight residue consensus sequence of amino acid residues 234-241 GPFGSGKT . The P-loop or phosphate binding loop is conserved only within the A subunits and is a loop preceded by a beta sheet and followed by an alpha helix.

occupies the ADP site. Although not at bonding distances the residues P233 G234 L417 stabilize the first vanadate in the transition state with weak nonpolar interactions. Residues K240 and T241 stabilize with polar interactions.

Residue is a polar serine molecule that interacts with the nucleotides via a hydrogen bond during catalysis. The distance between residue S238 is longest in As, shortest in Avi and intermediate in Apnp . In As a water molecule bridges the gap, which is removed in Avi. Dehydration of the transition state active site is reversed when ATP forms. In Apnp the water molecule interacts with the y-phosphate of ATP.

Comparasons to other known structures

This P-loop has an arched conformation unique to A-ATP Synthase, indicating that the mode of nucleotide binding and the catalytic mechanism is different from that of other syntheses. ^[6] The P-loop is unique in archea because it is stable compared to other similar structures. For example, in A-ATP Synthases is involved in P-Loop stabilization. Another reason why the P-Loop is so stable in A-ATP synthase is because of residue S238. It is significant in the catalytic process in moving towards the y-phosphate of ATP during catalysis, and does this with a hydrogen bond, not a conformational change in the P-loop. In "'F-ATP Synthase"' the homolog to S238 is the non polar A158. Since A158 cannot form hydrogen bonds to interact with the substrate (like s238), the P-loop undergoes a conformational change.^[5]

References

↑ ^1.0 ^1.1 Muller V, Lemker T, Lingl A, Weidner C, Coskun U, Gruber G. Bioenergetics of archaea: ATP synthesis under harsh environmental conditions. J Mol Microbiol Biotechnol. 2005;10(2-4):167-80. PMID:16645313 doi:10.1159/000091563
↑ Gibbons C, Montgomery MG, Leslie AG, Walker JE. The structure of the central stalk in bovine F(1)-ATPase at 2.4 A resolution. Nat Struct Biol. 2000 Nov;7(11):1055-61. PMID:11062563 doi:10.1038/80981
↑ Schafer IB, Bailer SM, Duser MG, Borsch M, Bernal RA, Stock D, Gruber G. Crystal structure of the archaeal A1Ao ATP synthase subunit B from Methanosarcina mazei Go1: Implications of nucleotide-binding differences in the major A1Ao subunits A and B. J Mol Biol. 2006 May 5;358(3):725-40. Epub 2006 Mar 10. PMID:16563431 doi:http://dx.doi.org/10.1016/j.jmb.2006.02.057
↑ Gonzalez JM, Masuchi Y, Robb FT, Ammerman JW, Maeder DL, Yanagibayashi M, Tamaoka J, Kato C. Pyrococcus horikoshii sp. nov., a hyperthermophilic archaeon isolated from a hydrothermal vent at the Okinawa Trough. Extremophiles. 1998 May;2(2):123-30. PMID:9672687
↑ ^5.0 ^5.1 Manimekalai MS, Kumar A, Jeyakanthan J, Gruber G. The Transition-Like State and P(i) Entrance into the Catalytic A Subunit of the Biological Engine A-ATP Synthase. J Mol Biol. 2011 Mar 16. PMID:21396943 doi:10.1016/j.jmb.2011.03.010
↑ Priya R, Kumar A, Manimekalai MS, Gruber G. Conserved Glycine Residues in the P-Loop of ATP Synthases Form a Doorframe for Nucleotide Entrance. J Mol Biol. 2011 Sep 8. PMID:21925186 doi:10.1016/j.jmb.2011.08.045

Proteopedia Page Contributors and Editors (what is this?)

Kaitlin Chase MacCulloch, Michal Harel, Alexander Berchansky

Retrieved from "http://52.214.119.220/wiki/index.php/A-ATP_Synthase"

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-<StructureSection load=1e79 size='450' side='right' caption='Bovine ATP synthase chains α (grey, green, pink), β (yellow, magenta, cyan), γ, δ (red), ε (wheat) (PDB code [[1e79]])', ([[1e79]])' scene=''>
+<StructureSection load=1e79 size='450' side='right' caption='Bovine ATP synthase chains α (grey, green, pink), β (yellow, magenta, cyan), γ (gold), δ (red), ε (wheat) (PDB code [[1e79]])' scene=''>
 [[Image:F_ATPsynthase.gif | thumb|left]]
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A-ATP Synthase

From Proteopedia

Revision as of 09:04, 5 January 2014

Structure

Introduction

Structure of A-ATP synthase catalytic subunit A

P-Loop

Comparasons to other known structures

References

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