Modular origins of biological electron transfer chains [Biophysics and Computational Biology]
Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda
National Academy of Sciences
Published 2018
National Academy of Sciences
Published 2018
Publication Date: |
2018-02-10
|
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Publisher: |
National Academy of Sciences
|
Print ISSN: |
0027-8424
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Electronic ISSN: |
1091-6490
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Topics: |
Biology
Medicine
Natural Sciences in General
|
Published by: |
_version_ | 1836398787650650113 |
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autor | Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda |
beschreibung | Oxidoreductases catalyze electron transfer reactions that ultimately provide the energy for life. A limited set of ancestral protein-metal modules are presumably the building blocks that evolved into this diverse protein family. However, the identity of these modules and their path to modern oxidoreductases is unknown. Using a comparative structural analysis... |
citation_standardnr | 6161625 |
datenlieferant | ipn_articles |
feed_id | 113 |
feed_publisher | National Academy of Sciences |
feed_publisher_url | http://www.nasonline.org/ |
insertion_date | 2018-02-10 |
journaleissn | 1091-6490 |
journalissn | 0027-8424 |
publikationsjahr_anzeige | 2018 |
publikationsjahr_facette | 2018 |
publikationsjahr_intervall | 7984:2015-2019 |
publikationsjahr_sort | 2018 |
publisher | National Academy of Sciences |
quelle | PNAS - Proceedings of the National Academy of Sciences |
relation | http://www.pnas.org/content/115/6/1280.short?rss=1 |
search_space | articles |
shingle_author_1 | Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda |
shingle_author_2 | Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda |
shingle_author_3 | Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda |
shingle_author_4 | Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda |
shingle_catch_all_1 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] Oxidoreductases catalyze electron transfer reactions that ultimately provide the energy for life. A limited set of ancestral protein-metal modules are presumably the building blocks that evolved into this diverse protein family. However, the identity of these modules and their path to modern oxidoreductases is unknown. Using a comparative structural analysis... Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda National Academy of Sciences 0027-8424 00278424 1091-6490 10916490 |
shingle_catch_all_2 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] Oxidoreductases catalyze electron transfer reactions that ultimately provide the energy for life. A limited set of ancestral protein-metal modules are presumably the building blocks that evolved into this diverse protein family. However, the identity of these modules and their path to modern oxidoreductases is unknown. Using a comparative structural analysis... Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda National Academy of Sciences 0027-8424 00278424 1091-6490 10916490 |
shingle_catch_all_3 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] Oxidoreductases catalyze electron transfer reactions that ultimately provide the energy for life. A limited set of ancestral protein-metal modules are presumably the building blocks that evolved into this diverse protein family. However, the identity of these modules and their path to modern oxidoreductases is unknown. Using a comparative structural analysis... Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda National Academy of Sciences 0027-8424 00278424 1091-6490 10916490 |
shingle_catch_all_4 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] Oxidoreductases catalyze electron transfer reactions that ultimately provide the energy for life. A limited set of ancestral protein-metal modules are presumably the building blocks that evolved into this diverse protein family. However, the identity of these modules and their path to modern oxidoreductases is unknown. Using a comparative structural analysis... Hagai Raanan, Douglas H. Pike, Eli K. Moore, Paul G. Falkowski, Vikas Nanda National Academy of Sciences 0027-8424 00278424 1091-6490 10916490 |
shingle_title_1 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
shingle_title_2 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
shingle_title_3 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
shingle_title_4 | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
timestamp | 2025-06-30T23:32:38.167Z |
titel | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
titel_suche | Modular origins of biological electron transfer chains [Biophysics and Computational Biology] |
topic | W WW-YZ TA-TD |
uid | ipn_articles_6161625 |