Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC

Hila Nudelman; Carmen Valverde-Tercedor; Sofiya Kolusheva; Teresa Perez Gonzalez; Marc Widdrat; Noam Grimberg; Hilla Levi; Or Nelkenbaum; Geula Davidov; Damien Faivre; Concepcion Jimenez-Lopez; Raz Zarivach

doi:10.1016/j.jsb.2016.03.001

Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC

Hila Nudelman
, Carmen Valverde-Tercedor
, Sofiya Kolusheva
, Teresa Perez Gonzalez
, Marc Widdrat
, Noam Grimberg
, Hilla Levi
, Or Nelkenbaum
, Geula Davidov
, Damien Faivre
, Concepcion Jimenez-Lopez^*
, Raz Zarivach

^*Šī darba korespondējošais autors

Ben-Gurion University of the Negev
University of Granada
Max Planck Institute of Colloids and Interfaces

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

40 Atsauces (Scopus)

Kopsavilkums

Magnetotactic bacteria are Gram-negative bacteria that navigate along geomagnetic fields using the magnetosome, an organelle that consists of a membrane-enveloped magnetic nanoparticle. Magnetite formation and its properties are controlled by a specific set of proteins. MamC is a small magnetosome-membrane protein that is known to be active in iron biomineralization but its mechanism has yet to be clarified. Here, we studied the relationship between the MamC magnetite-interaction loop (MIL) structure and its magnetite interaction using an inert biomineralization protein-MamC chimera. Our determined structure shows an alpha-helical fold for MamC-MIL with highly charged surfaces. Additionally, the MamC-MIL induces the formation of larger magnetite crystals compared to protein-free and inert biomineralization protein control experiments. We suggest that the connection between the MamC-MIL structure and the protein's charged surfaces is crucial for magnetite binding and thus for the size control of the magnetite nanoparticles.

Oriģinālvaloda	Angļu
Lapas (no-līdz)	244-252
Lapu skaits	9
Žurnāls	Journal of Structural Biology
Sējums	194
Izdevuma numurs	3
DOIs	https://doi.org/10.1016/j.jsb.2016.03.001
Publikācijas statuss	Publicēts - 1 jūn. 2016
Ārēji publicēts	Jā

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10.1016/j.jsb.2016.03.001

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Nudelman, H., Valverde-Tercedor, C., Kolusheva, S., Perez Gonzalez, T., Widdrat, M., Grimberg, N., Levi, H., Nelkenbaum, O., Davidov, G., Faivre, D., Jimenez-Lopez, C., & Zarivach, R. (2016). Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC. Journal of Structural Biology, 194(3), 244-252. https://doi.org/10.1016/j.jsb.2016.03.001

@article{38dd9cf90b734f30acc089d26982617c,

title = "Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC",

abstract = "Magnetotactic bacteria are Gram-negative bacteria that navigate along geomagnetic fields using the magnetosome, an organelle that consists of a membrane-enveloped magnetic nanoparticle. Magnetite formation and its properties are controlled by a specific set of proteins. MamC is a small magnetosome-membrane protein that is known to be active in iron biomineralization but its mechanism has yet to be clarified. Here, we studied the relationship between the MamC magnetite-interaction loop (MIL) structure and its magnetite interaction using an inert biomineralization protein-MamC chimera. Our determined structure shows an alpha-helical fold for MamC-MIL with highly charged surfaces. Additionally, the MamC-MIL induces the formation of larger magnetite crystals compared to protein-free and inert biomineralization protein control experiments. We suggest that the connection between the MamC-MIL structure and the protein's charged surfaces is crucial for magnetite binding and thus for the size control of the magnetite nanoparticles.",

keywords = "Biomineralization, Magnetotactic bacteria, MamC, Protein structure, Structure-activity relationships",

author = "Hila Nudelman and Carmen Valverde-Tercedor and Sofiya Kolusheva and \{Perez Gonzalez\}, Teresa and Marc Widdrat and Noam Grimberg and Hilla Levi and Or Nelkenbaum and Geula Davidov and Damien Faivre and Concepcion Jimenez-Lopez and Raz Zarivach",

note = "Publisher Copyright: {\textcopyright} 2016.",

year = "2016",

month = jun,

day = "1",

doi = "10.1016/j.jsb.2016.03.001",

language = "English",

volume = "194",

pages = "244--252",

journal = "Journal of Structural Biology",

issn = "1047-8477",

publisher = "Academic Press Inc.",

number = "3",

}

Nudelman, H, Valverde-Tercedor, C, Kolusheva, S, Perez Gonzalez, T, Widdrat, M, Grimberg, N, Levi, H, Nelkenbaum, O, Davidov, G, Faivre, D, Jimenez-Lopez, C & Zarivach, R 2016, 'Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC', Journal of Structural Biology, sēj. 194, Nr. 3, lpp. 244-252. https://doi.org/10.1016/j.jsb.2016.03.001

TY - JOUR

T1 - Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC

AU - Nudelman, Hila

AU - Valverde-Tercedor, Carmen

AU - Kolusheva, Sofiya

AU - Perez Gonzalez, Teresa

AU - Widdrat, Marc

AU - Grimberg, Noam

AU - Levi, Hilla

AU - Nelkenbaum, Or

AU - Davidov, Geula

AU - Faivre, Damien

AU - Jimenez-Lopez, Concepcion

AU - Zarivach, Raz

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Magnetotactic bacteria are Gram-negative bacteria that navigate along geomagnetic fields using the magnetosome, an organelle that consists of a membrane-enveloped magnetic nanoparticle. Magnetite formation and its properties are controlled by a specific set of proteins. MamC is a small magnetosome-membrane protein that is known to be active in iron biomineralization but its mechanism has yet to be clarified. Here, we studied the relationship between the MamC magnetite-interaction loop (MIL) structure and its magnetite interaction using an inert biomineralization protein-MamC chimera. Our determined structure shows an alpha-helical fold for MamC-MIL with highly charged surfaces. Additionally, the MamC-MIL induces the formation of larger magnetite crystals compared to protein-free and inert biomineralization protein control experiments. We suggest that the connection between the MamC-MIL structure and the protein's charged surfaces is crucial for magnetite binding and thus for the size control of the magnetite nanoparticles.

AB - Magnetotactic bacteria are Gram-negative bacteria that navigate along geomagnetic fields using the magnetosome, an organelle that consists of a membrane-enveloped magnetic nanoparticle. Magnetite formation and its properties are controlled by a specific set of proteins. MamC is a small magnetosome-membrane protein that is known to be active in iron biomineralization but its mechanism has yet to be clarified. Here, we studied the relationship between the MamC magnetite-interaction loop (MIL) structure and its magnetite interaction using an inert biomineralization protein-MamC chimera. Our determined structure shows an alpha-helical fold for MamC-MIL with highly charged surfaces. Additionally, the MamC-MIL induces the formation of larger magnetite crystals compared to protein-free and inert biomineralization protein control experiments. We suggest that the connection between the MamC-MIL structure and the protein's charged surfaces is crucial for magnetite binding and thus for the size control of the magnetite nanoparticles.

KW - Biomineralization

KW - Magnetotactic bacteria

KW - MamC

KW - Protein structure

KW - Structure-activity relationships

UR - https://www.scopus.com/pages/publications/84961156941

U2 - 10.1016/j.jsb.2016.03.001

DO - 10.1016/j.jsb.2016.03.001

M3 - Article

C2 - 26970040

AN - SCOPUS:84961156941

SN - 1047-8477

VL - 194

SP - 244

EP - 252

JO - Journal of Structural Biology

JF - Journal of Structural Biology

IS - 3

ER -

Structure-function studies of the magnetite-biomineralizing magnetosome-associated protein MamC

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