Genetically Engineered Organization: Protein Template, Biological Recognition Sites, and Nanoparticles

Franziska Jehle; Carmen Valverde-Tercedor; Victoria Reichel; Maria A. Carillo; Mathieu Bennet; Erika Günther; Richard Wirth; Frank Mickoleit; Raz Zarivach; Dirk Schüler; Kerstin G. Blank; Damien Faivre

doi:10.1002/admi.201600285

Genetically Engineered Organization: Protein Template, Biological Recognition Sites, and Nanoparticles

Franziska Jehle
, Carmen Valverde-Tercedor
, Victoria Reichel
, Maria A. Carillo
, Mathieu Bennet
, Erika Günther
, Richard Wirth
, Frank Mickoleit
, Raz Zarivach
, Dirk Schüler
, Kerstin G. Blank
, Damien Faivre^*

^*Šī darba korespondējošais autors

Max Planck Institute of Colloids and Interfaces
Helmholtz Centre Potsdam - German Research Centre for Geosciences
University of Bayreuth
Ben-Gurion University of the Negev

Zinātniskās darbības rezultāts: Devums žurnālam › Zinātniskais raksts (žurnālā) › koleģiāli recenzēts

6 Atsauces (Scopus)

Kopsavilkums

Nanoparticles and their assemblies exhibit properties that can be used for a wide range of applications. However, creating multifunctional assemblies has remained challenging. Inspired by magnetotactic bacteria, genetically engineered single building blocks from magnetosome chains are used and complemented by additional components to form fluorescent assemblies of nanoparticles of varying types. This strategy is illustrated by the use of a protein from magnetotactic bacteria (MamK) known to form filaments in vivo and in vitro. A fusion protein of MamK and the fluorescent protein mCherry is recombinantly expressed and isolated using a hexahistidine tag that is subsequently used to bind functionalized gold nanoparticles to polymerized MamK_mCherry_His₆ filaments. The versatility of this modular approach is further exemplified by the concomitant addition of biological or synthetic magnetic nanoparticles functionalized with a nanobody directed against mCherry. The as-formed structures are fluorescent and can be actuated by an external magnetic field. This study shows again how nature's strategies can be applied for designing multifunctional materials.

Oriģinālvaloda	Angļu
Raksta numurs	1600285
Žurnāls	Advanced Materials Interfaces
Sējums	4
Izdevuma numurs	1
DOIs	https://doi.org/10.1002/admi.201600285
Publikācijas statuss	Publicēts - 9 janv. 2017
Ārēji publicēts	Jā

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Jehle, F., Valverde-Tercedor, C., Reichel, V., Carillo, M. A., Bennet, M., Günther, E., Wirth, R., Mickoleit, F., Zarivach, R., Schüler, D., Blank, K. G., & Faivre, D. (2017). Genetically Engineered Organization: Protein Template, Biological Recognition Sites, and Nanoparticles. Advanced Materials Interfaces, 4(1), Zinātniskais raksts 1600285. https://doi.org/10.1002/admi.201600285

@article{55b6713ee46946c9aba02d0a64a653de,

title = "Genetically Engineered Organization: Protein Template, Biological Recognition Sites, and Nanoparticles",

abstract = "Nanoparticles and their assemblies exhibit properties that can be used for a wide range of applications. However, creating multifunctional assemblies has remained challenging. Inspired by magnetotactic bacteria, genetically engineered single building blocks from magnetosome chains are used and complemented by additional components to form fluorescent assemblies of nanoparticles of varying types. This strategy is illustrated by the use of a protein from magnetotactic bacteria (MamK) known to form filaments in vivo and in vitro. A fusion protein of MamK and the fluorescent protein mCherry is recombinantly expressed and isolated using a hexahistidine tag that is subsequently used to bind functionalized gold nanoparticles to polymerized MamK\_mCherry\_His6 filaments. The versatility of this modular approach is further exemplified by the concomitant addition of biological or synthetic magnetic nanoparticles functionalized with a nanobody directed against mCherry. The as-formed structures are fluorescent and can be actuated by an external magnetic field. This study shows again how nature's strategies can be applied for designing multifunctional materials.",

keywords = "biomimetic chains, magnetic nanoparticles, magnetosomes, magnetotactic bacteria, MamK",

author = "Franziska Jehle and Carmen Valverde-Tercedor and Victoria Reichel and Carillo, \{Maria A.\} and Mathieu Bennet and Erika G{\"u}nther and Richard Wirth and Frank Mickoleit and Raz Zarivach and Dirk Sch{\"u}ler and Blank, \{Kerstin G.\} and Damien Faivre",

note = "Publisher Copyright: {\textcopyright} 2016 WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2017",

month = jan,

day = "9",

doi = "10.1002/admi.201600285",

language = "English",

volume = "4",

journal = "Advanced Materials Interfaces",

issn = "2196-7350",

publisher = "John Wiley and Sons Ltd",

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TY - JOUR

T1 - Genetically Engineered Organization

T2 - Protein Template, Biological Recognition Sites, and Nanoparticles

AU - Jehle, Franziska

AU - Valverde-Tercedor, Carmen

AU - Reichel, Victoria

AU - Carillo, Maria A.

AU - Bennet, Mathieu

AU - Günther, Erika

AU - Wirth, Richard

AU - Mickoleit, Frank

AU - Zarivach, Raz

AU - Schüler, Dirk

AU - Blank, Kerstin G.

AU - Faivre, Damien

PY - 2017/1/9

Y1 - 2017/1/9

N2 - Nanoparticles and their assemblies exhibit properties that can be used for a wide range of applications. However, creating multifunctional assemblies has remained challenging. Inspired by magnetotactic bacteria, genetically engineered single building blocks from magnetosome chains are used and complemented by additional components to form fluorescent assemblies of nanoparticles of varying types. This strategy is illustrated by the use of a protein from magnetotactic bacteria (MamK) known to form filaments in vivo and in vitro. A fusion protein of MamK and the fluorescent protein mCherry is recombinantly expressed and isolated using a hexahistidine tag that is subsequently used to bind functionalized gold nanoparticles to polymerized MamK_mCherry_His6 filaments. The versatility of this modular approach is further exemplified by the concomitant addition of biological or synthetic magnetic nanoparticles functionalized with a nanobody directed against mCherry. The as-formed structures are fluorescent and can be actuated by an external magnetic field. This study shows again how nature's strategies can be applied for designing multifunctional materials.

AB - Nanoparticles and their assemblies exhibit properties that can be used for a wide range of applications. However, creating multifunctional assemblies has remained challenging. Inspired by magnetotactic bacteria, genetically engineered single building blocks from magnetosome chains are used and complemented by additional components to form fluorescent assemblies of nanoparticles of varying types. This strategy is illustrated by the use of a protein from magnetotactic bacteria (MamK) known to form filaments in vivo and in vitro. A fusion protein of MamK and the fluorescent protein mCherry is recombinantly expressed and isolated using a hexahistidine tag that is subsequently used to bind functionalized gold nanoparticles to polymerized MamK_mCherry_His6 filaments. The versatility of this modular approach is further exemplified by the concomitant addition of biological or synthetic magnetic nanoparticles functionalized with a nanobody directed against mCherry. The as-formed structures are fluorescent and can be actuated by an external magnetic field. This study shows again how nature's strategies can be applied for designing multifunctional materials.

KW - biomimetic chains

KW - magnetic nanoparticles

KW - magnetosomes

KW - magnetotactic bacteria

KW - MamK

UR - https://www.scopus.com/pages/publications/85008311808

U2 - 10.1002/admi.201600285

DO - 10.1002/admi.201600285

M3 - Article

AN - SCOPUS:85008311808

SN - 2196-7350

VL - 4

JO - Advanced Materials Interfaces

JF - Advanced Materials Interfaces

IS - 1

M1 - 1600285

ER -

Genetically Engineered Organization: Protein Template, Biological Recognition Sites, and Nanoparticles

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