An Oscillating MinD Protein Determines the Cellular Positioning of the Motility Machinery in Archaea

Phillip Nußbaum; Solenne Ithurbide; James C. Walsh; Megha Patro; Floriane Delpech; Marta Rodriguez-Franco; Paul M.G. Curmi; Iain G. Duggin; Tessa E. F. Quax; Sonja Verena Albers

doi:10.1016/j.cub.2020.09.073

An Oscillating MinD Protein Determines the Cellular Positioning of the Motility Machinery in Archaea

Phillip Nußbaum, Solenne Ithurbide, James C. Walsh, Megha Patro, Floriane Delpech, Marta Rodriguez-Franco, Paul M.G. Curmi, Iain G. Duggin^*, Tessa E. F. Quax^*, Sonja Verena Albers^*

^*Corresponding author for this work

Molecular Microbiology

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

MinD proteins are well studied in rod-shaped bacteria such as E. coli, where they display self-organized pole-to-pole oscillations that are important for correct positioning of the Z-ring at mid-cell for cell division. Archaea also encode proteins belonging to the MinD family, but their functions are unknown. MinD homologous proteins were found to be widespread in Euryarchaeota and form a sister group to the bacterial MinD family, distinct from the ParA and other related ATPase families. We aimed to identify the function of four archaeal MinD proteins in the model archaeon Haloferax volcanii. Deletion of the minD genes did not cause cell division or size defects, and the Z-ring was still correctly positioned. Instead, one of the deletions (ΔminD4) reduced swimming motility and hampered the correct formation of motility machinery at the cell poles. In ΔminD4 cells, there is reduced formation of the motility structure and chemosensory arrays, which are essential for signal transduction. In bacteria, several members of the ParA family can position the motility structure and chemosensory arrays via binding to a landmark protein, and consequently these proteins do not oscillate along the cell axis. However, GFP-MinD4 displayed pole-to-pole oscillation and formed polar patches or foci in H. volcanii. The MinD4 membrane-targeting sequence (MTS), homologous to the bacterial MinD MTS, was essential for the oscillation. Surprisingly, mutant MinD4 proteins failed to form polar patches. Thus, MinD4 from H. volcanii combines traits of different bacterial ParA/MinD proteins.

Original language	English
Pages (from-to)	4956-4972
Number of pages	22
Journal	Current Biology
Volume	30
Issue number	24
DOIs	https://doi.org/10.1016/j.cub.2020.09.073
Publication status	Published - 21-Dec-2020

Keywords

archaea
archaeal cell biology
archaellum
cell division
chemosensory arrays
chemotaxis
motility
ParA/MinD family

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@article{0fb1f9071f694e1d9100ad2bae954ae9,

title = "An Oscillating MinD Protein Determines the Cellular Positioning of the Motility Machinery in Archaea",

abstract = "MinD proteins are well studied in rod-shaped bacteria such as E. coli, where they display self-organized pole-to-pole oscillations that are important for correct positioning of the Z-ring at mid-cell for cell division. Archaea also encode proteins belonging to the MinD family, but their functions are unknown. MinD homologous proteins were found to be widespread in Euryarchaeota and form a sister group to the bacterial MinD family, distinct from the ParA and other related ATPase families. We aimed to identify the function of four archaeal MinD proteins in the model archaeon Haloferax volcanii. Deletion of the minD genes did not cause cell division or size defects, and the Z-ring was still correctly positioned. Instead, one of the deletions (ΔminD4) reduced swimming motility and hampered the correct formation of motility machinery at the cell poles. In ΔminD4 cells, there is reduced formation of the motility structure and chemosensory arrays, which are essential for signal transduction. In bacteria, several members of the ParA family can position the motility structure and chemosensory arrays via binding to a landmark protein, and consequently these proteins do not oscillate along the cell axis. However, GFP-MinD4 displayed pole-to-pole oscillation and formed polar patches or foci in H. volcanii. The MinD4 membrane-targeting sequence (MTS), homologous to the bacterial MinD MTS, was essential for the oscillation. Surprisingly, mutant MinD4 proteins failed to form polar patches. Thus, MinD4 from H. volcanii combines traits of different bacterial ParA/MinD proteins.",

keywords = "archaea, archaeal cell biology, archaellum, cell division, chemosensory arrays, chemotaxis, motility, ParA/MinD family",

author = "Phillip Nu{\ss}baum and Solenne Ithurbide and Walsh, {James C.} and Megha Patro and Floriane Delpech and Marta Rodriguez-Franco and Curmi, {Paul M.G.} and Duggin, {Iain G.} and Quax, {Tessa E. F.} and Albers, {Sonja Verena}",

note = "Funding Information: P.N. was supported by a grant from the Federal Ministry for Economic Affairs and Energy based on a decision of the German Bundestag (ZF 4653901AJ8). F.D. received support from the CRC746 funded by the DFG (German research foundation). M.P. received funds from the DFG on grant AL1206/4-3. T.E.F.Q. was supported by the DFG (411069969). I.G.D. and S.I. were supported by the Australian Research Council (FT160100010 and DP160101076). The TEM is operated by the University of Freiburg, Faculty of Biology, as a partner unit within the Microscopy and Image Analysis Platform, Freiburg. P.N. constructed all MinD deletion mutants and performed growth experiments and the analysis of CheW localization. S.I. performed all FtsZ localization studies, cell-morphology analysis, and MinD4 truncations. J.C.W. performed all oscillation analyses. F.D. constructed expression strains and oscillation analyses. M.P. performed motility assays, the analysis of FlaD localization, and GFP western blot analysis. I.G.D. performed molecular phylogeny. T.E.F.Q. performed swimming microscopy and MFR electron microscopy. T.E.F.Q, I.G.D. and S.-V.A. wrote the manuscript. All authors conceived the experiments and contributed to writing the manuscript. The authors declare no competing interests. Funding Information: P.N. was supported by a grant from the Federal Ministry for Economic Affairs and Energy based on a decision of the German Bundestag ( ZF 4653901AJ8 ). F.D. received support from the CRC746 funded by the DFG (German research foundation). M.P. received funds from the DFG on grant AL1206/4-3 . T.E.F.Q. was supported by the DFG ( 411069969 ). I.G.D. and S.I. were supported by the Australian Research Council ( FT160100010 and DP160101076 ). The TEM is operated by the University of Freiburg, Faculty of Biology, as a partner unit within the Microscopy and Image Analysis Platform, Freiburg. Publisher Copyright: {\textcopyright} 2020 The Authors",

year = "2020",

month = dec,

day = "21",

doi = "10.1016/j.cub.2020.09.073",

language = "English",

volume = "30",

pages = "4956--4972",

journal = "Current Biology",

issn = "0960-9822",

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TY - JOUR

T1 - An Oscillating MinD Protein Determines the Cellular Positioning of the Motility Machinery in Archaea

AU - Nußbaum, Phillip

AU - Ithurbide, Solenne

AU - Walsh, James C.

AU - Patro, Megha

AU - Delpech, Floriane

AU - Rodriguez-Franco, Marta

AU - Curmi, Paul M.G.

AU - Duggin, Iain G.

AU - Quax, Tessa E. F.

AU - Albers, Sonja Verena

N1 - Funding Information: P.N. was supported by a grant from the Federal Ministry for Economic Affairs and Energy based on a decision of the German Bundestag (ZF 4653901AJ8). F.D. received support from the CRC746 funded by the DFG (German research foundation). M.P. received funds from the DFG on grant AL1206/4-3. T.E.F.Q. was supported by the DFG (411069969). I.G.D. and S.I. were supported by the Australian Research Council (FT160100010 and DP160101076). The TEM is operated by the University of Freiburg, Faculty of Biology, as a partner unit within the Microscopy and Image Analysis Platform, Freiburg. P.N. constructed all MinD deletion mutants and performed growth experiments and the analysis of CheW localization. S.I. performed all FtsZ localization studies, cell-morphology analysis, and MinD4 truncations. J.C.W. performed all oscillation analyses. F.D. constructed expression strains and oscillation analyses. M.P. performed motility assays, the analysis of FlaD localization, and GFP western blot analysis. I.G.D. performed molecular phylogeny. T.E.F.Q. performed swimming microscopy and MFR electron microscopy. T.E.F.Q, I.G.D. and S.-V.A. wrote the manuscript. All authors conceived the experiments and contributed to writing the manuscript. The authors declare no competing interests. Funding Information: P.N. was supported by a grant from the Federal Ministry for Economic Affairs and Energy based on a decision of the German Bundestag ( ZF 4653901AJ8 ). F.D. received support from the CRC746 funded by the DFG (German research foundation). M.P. received funds from the DFG on grant AL1206/4-3 . T.E.F.Q. was supported by the DFG ( 411069969 ). I.G.D. and S.I. were supported by the Australian Research Council ( FT160100010 and DP160101076 ). The TEM is operated by the University of Freiburg, Faculty of Biology, as a partner unit within the Microscopy and Image Analysis Platform, Freiburg. Publisher Copyright: © 2020 The Authors

PY - 2020/12/21

Y1 - 2020/12/21

N2 - MinD proteins are well studied in rod-shaped bacteria such as E. coli, where they display self-organized pole-to-pole oscillations that are important for correct positioning of the Z-ring at mid-cell for cell division. Archaea also encode proteins belonging to the MinD family, but their functions are unknown. MinD homologous proteins were found to be widespread in Euryarchaeota and form a sister group to the bacterial MinD family, distinct from the ParA and other related ATPase families. We aimed to identify the function of four archaeal MinD proteins in the model archaeon Haloferax volcanii. Deletion of the minD genes did not cause cell division or size defects, and the Z-ring was still correctly positioned. Instead, one of the deletions (ΔminD4) reduced swimming motility and hampered the correct formation of motility machinery at the cell poles. In ΔminD4 cells, there is reduced formation of the motility structure and chemosensory arrays, which are essential for signal transduction. In bacteria, several members of the ParA family can position the motility structure and chemosensory arrays via binding to a landmark protein, and consequently these proteins do not oscillate along the cell axis. However, GFP-MinD4 displayed pole-to-pole oscillation and formed polar patches or foci in H. volcanii. The MinD4 membrane-targeting sequence (MTS), homologous to the bacterial MinD MTS, was essential for the oscillation. Surprisingly, mutant MinD4 proteins failed to form polar patches. Thus, MinD4 from H. volcanii combines traits of different bacterial ParA/MinD proteins.

AB - MinD proteins are well studied in rod-shaped bacteria such as E. coli, where they display self-organized pole-to-pole oscillations that are important for correct positioning of the Z-ring at mid-cell for cell division. Archaea also encode proteins belonging to the MinD family, but their functions are unknown. MinD homologous proteins were found to be widespread in Euryarchaeota and form a sister group to the bacterial MinD family, distinct from the ParA and other related ATPase families. We aimed to identify the function of four archaeal MinD proteins in the model archaeon Haloferax volcanii. Deletion of the minD genes did not cause cell division or size defects, and the Z-ring was still correctly positioned. Instead, one of the deletions (ΔminD4) reduced swimming motility and hampered the correct formation of motility machinery at the cell poles. In ΔminD4 cells, there is reduced formation of the motility structure and chemosensory arrays, which are essential for signal transduction. In bacteria, several members of the ParA family can position the motility structure and chemosensory arrays via binding to a landmark protein, and consequently these proteins do not oscillate along the cell axis. However, GFP-MinD4 displayed pole-to-pole oscillation and formed polar patches or foci in H. volcanii. The MinD4 membrane-targeting sequence (MTS), homologous to the bacterial MinD MTS, was essential for the oscillation. Surprisingly, mutant MinD4 proteins failed to form polar patches. Thus, MinD4 from H. volcanii combines traits of different bacterial ParA/MinD proteins.

KW - archaea

KW - archaeal cell biology

KW - archaellum

KW - cell division

KW - chemosensory arrays

KW - chemotaxis

KW - motility

KW - ParA/MinD family

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U2 - 10.1016/j.cub.2020.09.073

DO - 10.1016/j.cub.2020.09.073

M3 - Article

C2 - 33125862

AN - SCOPUS:85096115917

SN - 0960-9822

VL - 30

SP - 4956

EP - 4972

JO - Current Biology

JF - Current Biology

IS - 24

ER -

An Oscillating MinD Protein Determines the Cellular Positioning of the Motility Machinery in Archaea

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