Distribution of protein folds in the three superkingdoms of life.
about
MANET: tracing evolution of protein architecture in metabolic networksGenome Sequence of the Radioresistant Bacterium Deinococcus radiodurans R1Genome of the extremely radiation-resistant bacterium Deinococcus radiodurans viewed from the perspective of comparative genomicsAn evolutionarily structured universe of protein architectureBiochemical and structural characterization of apolipoprotein A-I binding protein, a novel phosphoprotein with a potential role in sperm capacitation.Structural characterization of genomes by large scale sequence-structure threadingThe rarity of gene shuffling in conserved genesNatural history of S-adenosylmethionine-binding proteinsArchaea: the first domain of diversified lifeEarly bioenergetic evolutionIdentification of unknown protein function using metabolite cocktail screening.Defining the TRiC/CCT interactome links chaperonin function to stabilization of newly made proteins with complex topologiesThe ASTRAL compendium for protein structure and sequence analysisStructural annotation of Mycobacterium tuberculosis proteomeMapping small molecule binding data to structural domainsViral proteins acquired from a host converge to simplified domain architecturesNew metrics for comparative genomicsThe nonconserved wrapping of conserved protein folds reveals a trend toward increasing connectivity in proteomic networksAb initio protein structure prediction on a genomic scale: application to the Mycoplasma genitalium genomeExploring dynamics of protein structure determination and homology-based prediction to estimate the number of superfamilies and folds.Nothing about protein structure classification makes sense except in the light of evolution.Phylogeny vs genome reshuffling: horizontal gene transferModeling protein network evolution under genome duplication and domain shufflingEstimating the probability for a protein to have a new fold: A statistical computational model.Comprehensive analysis of co-occurring domain sets in yeast proteins.On the detection of functionally coherent groups of protein domains with an extension to protein annotation.Selecting folded proteins from a library of secondary structural elements.Evolution of protein domain promiscuity in eukaryotes.The evolutionary history of protein domains viewed by species phylogeny.Phylogeny determined by protein domain content.Comparative genome analysis of the pathogenic spirochetes Borrelia burgdorferi and Treponema pallidumGTOP: a database of protein structures predicted from genome sequences.Genomic evidence that the intracellular proteins of archaeal microbes contain disulfide bonds.Systems biology perspectives on minimal and simpler cells.Structural features and the persistence of acquired proteins.Selecting protein targets for structural genomics of Pyrobaculum aerophilum: validating automated fold assignment methods by using binary hypothesis testingStructural characterization of the human proteome.Chalcone isomerase family and fold: no longer unique to plants.Detection of protein fold similarity based on correlation of amino acid propertiesANNIE: integrated de novo protein sequence annotation.
P2860
Q21284246-8C7ACE50-B844-4D12-9724-5DD9DD31F03DQ22065550-6D588874-C613-4D04-9128-3A9502085BC8Q24548476-E5A04733-5D61-4F23-B245-1BF47D4E5647Q24561613-58BE6E58-FB86-4F76-B5C7-13C76CB895B0Q24642343-C7293C76-3ACC-49B8-A2DB-E6FD915C3D67Q24802710-B9326EF4-2EFF-495E-93E5-F2646205DA6DQ24812477-97136292-8E2F-4A03-B62F-398F96DF1DD6Q24816614-252DB066-11B4-48A0-81BC-6079CBE048DCQ26824361-E9D17289-4581-4005-9B49-01874B5BF18FQ27011350-3EEBD294-5C67-4A8E-A89C-456BBE50F706Q27671828-EDE8EF00-5C17-48AD-A7B3-0F6739C77A91Q27967631-1EFB5EB7-03A3-4C40-AC99-9F694927C13DQ28139937-32275319-9239-4665-A663-0B0549A85126Q28477725-F882CFE1-F056-4511-9BD0-C5D4BFDFEC29Q28710345-5B6DC0CE-DF00-4A0A-81E4-69F96DBEFD2CQ28732259-489A9B95-46F2-4B17-9F16-FB0E51558A62Q28763948-331B78FD-F1E9-4C9E-8B02-419ADD94CF02Q28776171-2CA5A461-AD70-4B01-9F55-A54F3D9BF228Q30330160-210388FE-B9E6-4080-B572-100976F5B611Q30353443-8050E3AD-BDEB-4F61-8E3A-9B95096A0220Q30376508-D52E9030-1980-4CFE-8675-B1BDEAFDA49BQ30394741-C7B15F12-89EB-4503-B2BA-CF6532E56470Q30838604-4DC3F109-1348-4AC7-80A3-8E78919738F1Q30865991-01351BFD-0750-4096-95B0-B27314451582Q33287350-90E27209-BC49-47E8-8D58-6DFF8E76C3F4Q33302712-3DFB18C1-100B-4B14-8144-22FBE225A6A2Q33309329-9A00F3C8-00ED-45EE-BB30-49367D32ECE9Q33317131-990C2CBA-8776-454F-988E-DEB9257E2746Q33521193-1CB8D1A4-8937-4D3B-90F2-D75381AFE2B1Q33595175-5FA010F3-867F-4CD5-B0B6-DCFCE8E4AD60Q34003688-C9ED0FA3-F351-4E5B-8FAF-8CBF9D05F64AQ34010578-B3164A1C-C309-45E7-A0C9-EDC79EF17E5AQ34075149-E26656C8-88F8-4874-AFE5-6437DF659D9DQ34297826-EB8B121A-7CB1-4172-8DAB-5CEBED0E64F0Q34458709-226D1878-A746-4A15-BBDE-19A1F0FE6DC5Q35073856-70CF968B-2DB8-43AA-B419-AE222411A928Q35806623-B1AD8A44-1CCA-4226-8843-A0A7C75DCAF7Q36526463-D6596E12-8231-44A1-8EC0-99BF5C1D6217Q36743900-B1599576-019C-4D7B-8E7E-A5DD5CE6D777Q37245658-224EF4D5-8568-4228-A5D4-2023BDF812C3
P2860
Distribution of protein folds in the three superkingdoms of life.
description
1999 nî lūn-bûn
@nan
1999 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի հունվարին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
name
Distribution of protein folds in the three superkingdoms of life.
@ast
Distribution of protein folds in the three superkingdoms of life.
@en
type
label
Distribution of protein folds in the three superkingdoms of life.
@ast
Distribution of protein folds in the three superkingdoms of life.
@en
prefLabel
Distribution of protein folds in the three superkingdoms of life.
@ast
Distribution of protein folds in the three superkingdoms of life.
@en
P2093
P1433
P1476
Distribution of protein folds in the three superkingdoms of life
@en
P2093
P577
1999-01-01T00:00:00Z