about
Complete genome sequence of the hyperthermophilic chemolithoautotroph Pyrolobus fumarii type strain (1A)Cell proliferation at 122 degrees C and isotopically heavy CH4 production by a hyperthermophilic methanogen under high-pressure cultivationHeat freezes niche evolutionProtein thermodynamics can be predicted directly from biological growth ratesFunctional activity of plasmid DNA after entry into the atmosphere of earth investigated by a new biomarker stability assay for ballistic spaceflight experimentsLife in the slow lane; biogeochemistry of biodegraded petroleum containing reservoirs and implications for energy recovery and carbon managementFungal colonization of an Ordovician impact-induced hydrothermal system.Hexagonal platelet-like magnetite as a biosignature of thermophilic iron-reducing bacteria and its applications to the exploration of the modern deep, hot biosphere and the emergence of iron-reducing bacteria in early precambrian oceansMicrobial ecology of the dark ocean above, at, and below the seafloor.Hyperthermophiles in the history of life.Extracellular Electron Transfer to Fe(III) Oxides by the Hyperthermophilic Archaeon Geoglobus ahangari via a Direct Contact MechanismCoping with thermal challenges: physiological adaptations to environmental temperatures.Bacterial and archaeal diversity in an iron-rich coastal hydrothermal field in Yamagawa, Kagoshima, Japan.Selective phylogenetic analysis targeting 16S rRNA genes of hyperthermophilic archaea in the deep-subsurface hot biosphereTemporal and spatial archaeal colonization of hydrothermal vent deposits.Abundances of hyperthermophilic autotrophic Fe(III) oxide reducers and heterotrophs in hydrothermal sulfide chimneys of the northeastern Pacific Ocean.A small heat shock protein enables Escherichia coli to grow at a lethal temperature of 50°C conceivably by maintaining cell envelope integrity.Solutes determine the temperature windows for microbial survival and growth.Microbial Diversity in Extreme Marine Habitats and Their Biomolecules.Temperature differentially affects adenosine triphosphatase activity in Hsc70 orthologs from Antarctic and New Zealand notothenioid fishesMicrobial extremophiles at the limits of life.Rapid acquisition of Gigapascal-high-pressure resistance by Escherichia coli.Bacterial sulfur cycling shapes microbial communities in surface sediments of an ultramafic hydrothermal vent field.Microbial iron mats at the Mid-Atlantic Ridge and evidence that Zetaproteobacteria may be restricted to iron-oxidizing marine systems.Thermodesulfobacterium geofontis sp. nov., a hyperthermophilic, sulfate-reducing bacterium isolated from Obsidian Pool, Yellowstone National Park.Conditions for the emergence of life on the early Earth: summary and reflections.Growth of thermophilic and hyperthermophilic Fe(III)-reducing microorganisms on a ferruginous smectite as the sole electron acceptor.A Low Temperature Limit for Life on Earth.Biosignatures in chimney structures and sediment from the Loki's Castle low-temperature hydrothermal vent field at the Arctic Mid-Ocean Ridge.The potential for low-temperature abiotic hydrogen generation and a hydrogen-driven deep biosphere.Is there a common water-activity limit for the three domains of life?Minimal protein-folding systems in hyperthermophilic archaea.Aerobically respiring prokaryotic strains exhibit a broader temperature-pH-salinity space for cell division than anaerobically respiring and fermentative strains.Hyperthermophilic enzymes--stability, activity and implementation strategies for high temperature applications.The geomicrobiology of gold.Cytosine deamination and the precipitous decline of spontaneous mutation during Earth's history.Extracellular electron transfer: wires, capacitors, iron lungs, and more.An Adaptation To Life In Acid Through A Novel Mevalonate Pathway.A possible mechanism for evading temperature quantum decoherence in living matter by feshbach resonance.Effects of metal ions on stability and activity of hyperthermophilic pyrolysin and further stabilization of this enzyme by modification of a Ca2+-binding site
P2860
Q22064387-073B3D6C-D8AC-4D07-821F-476E854F0E00Q24653236-DC19C8A6-8F23-43DF-9315-085470F7E1CFQ27006928-8ACD8B0B-4A26-4470-B7A0-3CDEF335D250Q28538355-068063B0-3516-48D1-B5A1-B88A88D483E6Q28545201-A11641D6-9AE8-474A-940B-20DB1F714164Q28652391-2F4004CC-90FD-49DB-B96D-9F3696A68E30Q28661103-77443DCE-19F9-44BC-BA7B-B4C248887885Q28710330-B465FB44-592A-4B18-AC65-A678BE286B32Q28743264-96C22FBD-05AC-4A0E-963D-0798158B98D6Q28766387-5F1DDDF7-4804-4ECE-99A2-B76B104B35D3Q29028728-D246B1F9-BDC8-41C6-B4F0-DAA16A816C87Q30431296-D18012C4-DE9C-4CA4-BB0C-810EFAC092FEQ31144161-5D3725E0-1392-4171-BE35-9DEA8AB5E6EFQ33271913-62F4D8D4-1958-47FF-8B4F-532C869D756AQ33315151-086DB92D-64C7-4426-A636-221BCA2BD528Q33382019-5FB8705B-D16F-4BD5-8150-8FE26CC43A45Q33570139-E54DC32B-D71E-4454-A0C9-A41509E2E722Q33842592-BD9DB81A-02BA-4029-ACAB-8A9620A83403Q33845403-30B07563-98BD-4411-948A-F559D088D9AFQ33899676-EF4F755F-B910-46B3-BC99-A93BEEEF0C99Q34005338-A3684205-35B9-4DE5-BEEF-9FAD72B04182Q34160660-E56B4721-02B9-426A-9CD0-2E0EE6D914D9Q34213879-7E750852-BB44-4578-A1E5-6AD46CB566FFQ34466618-ED2A7C6C-93A3-461B-9134-4628DEA5369EQ34560389-3E9C0CB8-0167-4A1A-9C35-8A34B316F991Q34569774-0E1E668A-F7A7-43A9-9C98-BC9A7E815508Q34709518-7789A097-C007-49B7-B8BD-4A9714928B3EQ34805176-5409B30D-3C82-4C68-AFEA-AB710CB0B18CQ35128457-B8EC4CA9-90BD-4521-8DCE-95325D9FAB9AQ35222205-BDD2E538-EAE0-4E6F-A16C-D34698A2D4BCQ35513484-BA936236-F34A-421B-9D71-E629F4F778B0Q35697547-60671CB4-50C2-4033-9283-28C10EBFC0B8Q36187771-63E0B04B-CAAF-4662-A89D-876B9E3742FEQ36903904-EDB11518-EF60-4E04-AD27-8D5460F9E890Q37017107-CDD5111D-4542-4B2B-B766-5BB26153D4FEQ37126774-571A58B6-ED8B-492B-B574-8674800CC519Q37130975-6F71560F-FADA-4445-A9E4-AB48042B696AQ37525989-8B42A474-02DD-46E5-96E6-08B4CC74E840Q37535525-AD2489FB-0479-48A4-99DE-33B8BCAF20ECQ37713083-F7F185F5-69C7-4F23-A081-721F399D9DBE
P2860
description
2003 nî lūn-bûn
@nan
2003 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Extending the upper temperature limit for life.
@ast
Extending the upper temperature limit for life.
@en
Extending the upper temperature limit for life.
@nl
type
label
Extending the upper temperature limit for life.
@ast
Extending the upper temperature limit for life.
@en
Extending the upper temperature limit for life.
@nl
prefLabel
Extending the upper temperature limit for life.
@ast
Extending the upper temperature limit for life.
@en
Extending the upper temperature limit for life.
@nl
P356
P1433
P1476
Extending the upper temperature limit for life.
@en
P2093
Kazem Kashefi
P356
10.1126/SCIENCE.1086823
P407
P577
2003-08-01T00:00:00Z