| Literature DB >> 33464680 |
Ralph Schwidetzky1, Max Lukas1, Azade YazdanYar1, Anna T Kunert2, Ulrich Pöschl2, Katrin F Domke1, Janine Fröhlich-Nowoisky2, Mischa Bonn1, Thomas Koop3, Yuki Nagata1, Konrad Meister1,4.
Abstract
Ice nucleation-active bacteria are the most efficient ice nucleators known, enabling the crystallization of water at temperatures close to 0 °C, thereby overcoming the kinetically hindered phase transition process at these conditions. Using highly specialized ice-nucleating proteiical">ns (INPs), they can cause frost damage to plants and iical">nflueical">nce the formation of clouds and precipitation iical">n the atmosphere. Iical">n nature, the bacteria are usually found iical">n aqueous eical">nvironmeical">nts contaiical">ning ions. The impact of ions on bacterial ice nucleation efficieical">ncy, however, has remained elusive. Here, we demonstrate that ions can profoundly iical">nflueical">nce the efficieical">ncy of bacterial ice nucleators iical">n a manner that follows the Hofmeister series. Weakly hydrated ions iical">nhibit bacterial ice nucleation whereas strongly hydrated ions appareical">ntly facilitate ice nucleation. Surface-specific sum-frequeical">ncy geical">neration spectroscopy and molecular dynamics simulations reveal that the differeical">nt effects are due to specific interactions of the ions with the INPs on the surface of the bacteria. Our results demonstrate that heterogeical">neous ice nucleation facilitated by bacteria strongly depeical">nds upon the nature of the ions, and specific ion-proteiical">n interactions are esseical">ntial for the complete description of heterogeical">neous ice nucleation by bacteria.Entities:
Keywords: Hofmeister series; atmospheric chemistry; bacteria; ice nucleation; nonlinear optics
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Year: 2021 PMID: 33464680 DOI: 10.1002/chem.202004630
Source DB: PubMed Journal: Chemistry ISSN: 0947-6539 Impact factor: 5.236