The stepwise evolution of early life driven by energy conservation
about
The last universal common ancestor: emergence, constitution and genetic legacy of an elusive forerunnerNitrite-reductase and peroxynitrite isomerization activities of Methanosarcina acetivorans protoglobinOn the free energy that drove primordial anabolismOn the origin of biochemistry at an alkaline hydrothermal ventOne step beyond a ribosome: The ancient anaerobic coreHydrogen, metals, bifurcating electrons, and proton gradients: the early evolution of biological energy conservationEarly bioenergetic evolutionAcetate Metabolism in Anaerobes from the Domain ArchaeaArchaeal protoglobin structure indicates new ligand diffusion paths and modulation of haem-reactivityStructure and Haem-Distal Site Plasticity in Methanosarcina acetivorans ProtoglobinAn unconventional pathway for reduction of CO2 to methane in CO-grown Methanosarcina acetivorans revealed by proteomicsPotential Role of Acetyl-CoA Synthetase (acs) and Malate Dehydrogenase (mae) in the Evolution of the Acetate Switch in Bacteria and ArchaeaAn origin-of-life reactor to simulate alkaline hydrothermal ventsTowards a computational model of a methane producing archaeumThe drive to life on wet and icy worldsEarly evolution without a tree of lifeThe origin of modern terrestrial lifeThe physiology and habitat of the last universal common ancestorComparative genomic analyses of copper transporters and cuproproteomes reveal evolutionary dynamics of copper utilization and its link to oxygen.Genome beginnings: rooting the tree of lifeMetabolic reconstruction of the archaeon methanogen Methanosarcina Acetivorans.Ligation tunes protein reactivity in an ancient haemoglobin: kinetic evidence for an allosteric mechanism in Methanosarcina acetivorans protoglobin.Structural Bases for the Regulation of CO Binding in the Archaeal Protoglobin from Methanosarcina acetivoransEvolutionary ecology during the rise of dioxygen in the Earth's atmosphere.Phototrophic Fe(II) oxidation in an atmosphere of H2: implications for Archean banded iron formations.Energy Metabolism during Anaerobic Methane Oxidation in ANME Archaea.Proton gradients at the origin of life.Luminescent ruthenium probe for the determination of acetyl phosphate in complex biological matrices.Physiology, phylogeny, and LUCAThe origin of heredity in protocells.Iron catalysis at the origin of life.Evolution. Energy at life's origin.Archaeal phylogenomics provides evidence in support of a methanogenic origin of the Archaea and a thaumarchaeal origin for the eukaryotes.The role of metal ions in biological oxidation - the past and the presentAcetyl Phosphate as a Primordial Energy Currency at the Origin of Life
P2860
Q21093196-FADE7BB5-E352-4CA8-9627-6DDCF03F01EBQ21132054-F6257EFB-D3D0-4996-ADDD-CAE1101730E3Q24646008-81AC1C08-D3BB-4BEA-9709-2205EC2B966EQ24648668-9F45474D-F2A1-4B81-BCB1-140734556C7CQ26751466-3F1F8BBE-0491-4B12-A922-710BDEFB781DQ27006000-22953C09-A184-4A41-A881-CB25E27057CDQ27011350-3BFF12B9-07A1-4AD2-B8B4-8A20531C217BQ27025611-CB78213D-E92C-4C51-B122-6C84D22EC201Q27649521-D7937F8D-3AB0-43E1-9187-9E0C21C55C5CQ27678687-0EEE9858-E685-45AF-B47F-3E4D81C1A96AQ28273832-285493B1-FFD9-4481-B15D-9645420A5842Q28645817-8CA8B1F4-AE09-4281-8138-E150FCB3F828Q28651014-6E2B8311-277C-4251-ADE5-F3616676622FQ28657421-6AF50AE6-2383-4A21-938C-24D19748E881Q28658605-ADDCA129-F730-40E6-A290-45250117E808Q28741296-405D11D0-D79A-438D-B78B-8890B9065C41Q28755444-6710C6C0-BBCC-4446-9C1F-EC2514F2CB27Q29391568-3A8CFFA8-6DAF-4816-8403-68DE3684030CQ33312936-A3149D94-A2FB-4F8A-B4F3-E01C58916D5BQ33477246-97CB97FF-1159-43F8-AC15-B2CF96EBD807Q33821345-7CCC4ADD-7B34-4C09-9989-3B040C85417AQ34221518-9FF98FDB-645E-470D-8A63-278E086D263EQ35654546-D2C510AF-5859-4AB2-994B-9DB513CE7D5CQ37022720-0EB29A51-B796-4346-BB96-0F923403FE31Q37390961-D85FFEB6-3C00-4141-9A4A-03E30096430AQ39188810-A5735065-FD3F-4455-B243-3C77D14EA7C0Q39306264-37C56E55-2531-4696-A4D8-AE5C5CBE0EDEQ39642489-566256B0-0EC8-4958-8482-67AE3B034F87Q42141060-29E56CF8-3434-4C94-918F-3101D45D3F5CQ46276794-7763390A-02F3-4A04-BD55-8F876B736FCDQ47216711-30F77081-A503-4D67-B781-42035450CC4AQ47635785-BA01CE25-CAB8-4E61-B2FB-3D873D945E2EQ51653182-6248BCA8-7EAC-4446-8D3F-70E6B535A9F9Q55980796-F10C3A7C-6793-42DC-8F05-15FA9FD9CEADQ57006255-50CD89D2-2D0D-4242-A718-6D5A75535941
P2860
The stepwise evolution of early life driven by energy conservation
description
2006 nî lūn-bûn
@nan
2006 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
name
The stepwise evolution of early life driven by energy conservation
@ast
The stepwise evolution of early life driven by energy conservation
@en
The stepwise evolution of early life driven by energy conservation
@nl
type
label
The stepwise evolution of early life driven by energy conservation
@ast
The stepwise evolution of early life driven by energy conservation
@en
The stepwise evolution of early life driven by energy conservation
@nl
prefLabel
The stepwise evolution of early life driven by energy conservation
@ast
The stepwise evolution of early life driven by energy conservation
@en
The stepwise evolution of early life driven by energy conservation
@nl
P3181
P356
P1476
The stepwise evolution of early life driven by energy conservation
@en
P2093
Christopher H House
James G Ferry
P304
P3181
P356
10.1093/MOLBEV/MSK014
P407
P577
2006-06-01T00:00:00Z