Compositional genomes: prebiotic information transfer in mutually catalytic noncovalent assemblies.
about
The last universal common ancestor: emergence, constitution and genetic legacy of an elusive forerunnerQuasispecies in population of compositional assembliesEvolution before genesEvolution of oil droplets in a chemorobotic platform.Origin of evolution versus origin of life: a shift of paradigmFrom self-assembled vesicles to protocellsThree subsets of sequence complexity and their relevance to biopolymeric information.Current Ideas about Prebiological CompartmentalizationBridging nonliving and living matterSignatures of arithmetic simplicity in metabolic network architectureThe Routes of Emergence of Life from LUCA during the RNA and Viral World: A ConspectusMolecular complementarity between simple, universal molecules and ions limited phenotype space in the precursors of cellsPrebiotic chemistry: geochemical context and reaction screeningSynthetic constructs in/for the environment: managing the interplay between natural and engineered BiologyA new replicator: a theoretical framework for analysing replicationCoevolution of compositional protocells and their environmentSunlight-initiated chemistry of aqueous pyruvic acid: building complexity in the origin of life.The origin of large molecules in primordial autocatalytic reaction networksSerial transfer can aid the evolution of autocatalytic sets.Lack of evolvability in self-sustaining autocatalytic networks constraints metabolism-first scenarios for the origin of life.Spontaneous chiral symmetry breaking in early molecular networksComposing life.Excess mutual catalysis is required for effective evolvability.Chromosome Replication in Escherichia coli: Life on the Scales.A model for the emergence of cooperation, interdependence, and structure in evolving networks.Looked at life from both sides nowDroplets: unconventional protocell model with life-like dynamics and room to grow.Transferable Measurements of Heredity in Models of the Origins of Life.Basic autonomy as a fundamental step in the synthesis of life.Self-reproducing catalyst drives repeated phospholipid synthesis and membrane growthSustainability of Transient Kinetic Regimes and Origins of Death.Evolutionary self-organization in complex fluids.The capabilities of chaos and complexity.The eukaryotic cell originated in the integration and redistribution of hyperstructures from communities of prokaryotic cells based on molecular complementarity.Motility at the origin of life: its characterization and a model.Is life unique?Chemical Evolution and the Evolutionary Definition of Life.Prebiotic network evolution: six key parameters.Life's Late Digital Revolution and Why It Matters for the Study of the Origins of Life.Tactic, reactive, and functional droplets outside of equilibrium.
P2860
Q21093196-AB4E5835-1853-42BF-A81B-16B2AA95B520Q21146731-E0C495B6-E34F-41C2-9A32-EE4D3314D795Q21563666-58C95989-8BDE-437A-9C31-7F9F5BA80F9FQ24289321-94B6023E-FAF6-47EC-A99E-C35C63D6A6F5Q24595894-DD65A740-7090-4118-BF79-C1D211059F33Q24630809-538EA129-56F9-4690-B22C-BDF5EDF08664Q24814228-FB57F3B2-82AB-45DE-9CFA-1433EB9E1FFCQ28085556-87F22B5A-7809-4BE6-9AE6-ECA718C52ED8Q28209437-09D0CBE6-3B2E-49A3-AD63-8E39039405D6Q28473485-DF0EF223-4E5B-422A-A48E-C3A7C3FCAC87Q28647182-A8F9AC21-A525-4A3E-BC21-6CFB8702C873Q28649901-D44EC4ED-31DC-4F09-AED8-6FF3D0D6520DQ28655012-CDABEC51-B621-460D-B723-7AEFC60851C9Q28729206-7C845244-CE19-41BC-A60D-D812BCDB358FQ28748167-5B274587-9C59-45D1-996E-05429ECD924FQ28757847-6195070A-7607-473D-B7F1-A1D555C44267Q30722723-D9173E55-5665-41EE-952E-547499F7E888Q33352834-EC1901BC-9A0F-47F2-BC6F-51B4CBE8B434Q33665095-1265164D-FFB5-4E1E-97FE-6199B93E33E7Q33667800-8DBC17B9-D789-456F-8241-AF1005B6642DQ33951709-8F3DA4BF-1BDF-4244-B216-13F8E79D4C74Q34188557-A5118C05-C7C6-4581-B820-36A71A98AAEEQ34278876-36FE0139-581A-4F52-BF3C-CFDAD5D44885Q34295716-9D533D36-6576-4077-B6AA-6D2C35EE898DQ34616211-12DBAA2F-4308-41B8-8684-E6BFE1E84316Q34829539-1F6C1CBF-C5CD-496C-A3BA-3E56CBBA01DFQ34829682-4AD3E085-1C32-4A06-A6D7-5E32B305B111Q35812981-2DA3E966-56B9-4AFB-BA98-1455EBB4D646Q35831892-2A4FCFCC-8B40-4971-AABB-99F85935DC41Q35845703-695C6944-9303-4588-9823-5A92A6DE2FEDQ36555143-BDDF2B83-F61C-48AE-B5E2-72CF356D38E2Q36741718-09B08FFF-D618-44C6-97E6-87052B22BAD7Q37427431-46CB7419-4D55-4D81-AAD3-BA2516AC2EF0Q37542984-FBB72763-B450-4E26-85F7-ED4028CB3A35Q38078444-5D3317E2-2C48-41A2-9021-4F9EE45007C4Q38266333-A7B84300-AA44-4702-8AB4-BF807EE11739Q38287840-D0464915-90FE-48B8-BC85-41A585C83A22Q38613603-5A9B35DF-07BF-4397-936D-C157E42DA702Q38637325-43E02314-2A89-477F-8E7F-1CC80BC6F14AQ38854303-691FA05C-264A-463B-AF72-471F1012C15C
P2860
Compositional genomes: prebiotic information transfer in mutually catalytic noncovalent assemblies.
description
2000 nî lūn-bûn
@nan
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
2000年论文
@zh
2000年论文
@zh-cn
name
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@ast
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@en
type
label
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@ast
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@en
prefLabel
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@ast
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@en
P2093
P2860
P356
P1476
Compositional genomes: prebiot ...... alytic noncovalent assemblies.
@en
P2093
P2860
P304
P356
10.1073/PNAS.97.8.4112
P407
P577
2000-04-01T00:00:00Z