Structures of archaeal DNA segregation machinery reveal bacterial and eukaryotic linkages
Autor: | Irene W. Ng, Porsha L. R. Shaw, Maria A. Schumacher, Naga Babu Chinnam, Nam K. Tonthat, Anne K. Kalliomaa-Sanford, J. E. Lee, Fernando A. Rodriguez-Castañeda, Madhuri T. Barge, Daniela Barillà |
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Rok vydání: | 2015 |
Předmět: |
Chromosomal Proteins
Non-Histone Chromosomes Archaeal Archaeal Proteins Amino Acid Motifs Centromere Computational biology Autoantigens DNA-binding protein Sulfolobus Chromosome segregation Kluyveromyces chemistry.chemical_compound Chromosome Segregation A-DNA Genetics Multidisciplinary CENPA Bacteria biology DNA Superhelical Superhelix biology.organism_classification Protein Structure Tertiary DNA Archaeal chemistry Nucleic Acid Conformation Centromere Protein A DNA |
Zdroj: | Science. 349:1120-1124 |
ISSN: | 1095-9203 0036-8075 |
DOI: | 10.1126/science.aaa9046 |
Popis: | Plasmid partitioning superstructure system Partitioning and sharing DNA between dividing cells is critical for all domains of life. Prokaryotes must share certain plasmids as well as their genomic DNA to survive. Schumacher et al. studied the partition system that segregates a conjugative plasmid in the prokaryote Sulfolobus. The system consists of three proteins. AspA spreads along the plasmid DNA to create a protein-DNA superhelix. The ParA motor protein is linked to the protein-DNA superhelix through the ParB protein, which has structural similarities to eukaryotic centromere segregating proteins. Science , this issue p. 1120 |
Databáze: | OpenAIRE |
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