Membrane recognition and dynamics of the RNA Degradosome
Membrane recognition and dynamics of the RNA Degradosome
RNase E, which is the central component of the multienzyme RNA degradosome, serves as a scaffold for interaction with other enzymes involved in mRNA degradation including the DEAD-box RNA helicase RhlB. Epifluorescence microscopy under live cell conditions shows that RNase E and RhlB are membrane associated, but neither protein forms cytoskeletal-like structures as reported earlier by Taghbalout and Rothfield. We show that association of RhlB with the membrane depends on a direct protein interaction with RNase E, which is anchored to the inner cytoplasmic membrane through an MTS (Membrane Targeting Sequence). Molecular dynamics simulations show that the MTS interacts with the phospholipid bilayer by forming a stabilized amphipathic ?-helix with the helical axis oriented parallel to the plane of the bilayer and hydrophobic side chains buried deep in the acyl core of the membrane. Based on the molecular dynamics simulations, we propose that the MTS freely diffuses in the membrane by a novel mechanism in which a large number of weak contacts are rapidly broken and reformed. TIRFm (Total Internal Reflection microscopy) shows that RNase E in live cells rapidly diffuses over the entire inner membrane forming short-lived foci. Diffusion could be part of a scanning mechanism facilitating substrate recognition and cooperativity. Remarkably, RNase E foci disappear and the rate of RNase E diffusion increases with rifampicin treatment. Control experiments show that the effect of rifampicin is specific to RNase E and that the effect is not a secondary consequence of the shut off of E. coli transcription. We therefore interpret the effect of rifampicin as being due to the depletion of RNA substrates for degradation. We propose a model in which formation of foci and constraints on diffusion arise from the transient clustering of RNase E into cooperative degradation bodies.
e1004961-[23pp]
Viollier, Patrick H.
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Strahl, Henrik
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Turlan, Catherine
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Khalid, Syma
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Bond, Peter J.
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Kebalo, Jean-Marie
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Peyron, Pascale
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Poljak, Leonora
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Bouvier, Marie
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Hamoen, Leendert
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Luisi, Ben F.
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Carpousis, Agamemnon J.
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3 February 2015
Viollier, Patrick H.
38b108a3-25d6-4162-a188-e33662b43aa2
Strahl, Henrik
7c1376af-4ab6-4c87-8931-0d073a82fc66
Turlan, Catherine
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Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Bond, Peter J.
08f46940-85e8-44c4-a368-d94342a10fd6
Kebalo, Jean-Marie
5a48ee78-01d7-46e8-8991-a0214e01cb2d
Peyron, Pascale
c5df50b8-2311-4733-9743-5bb893bad00b
Poljak, Leonora
a53568de-0d57-4efd-acae-655b61f59262
Bouvier, Marie
d858943b-e591-46d7-916d-0c5156b713f0
Hamoen, Leendert
93e8420d-82ab-4cd4-95ed-1dbdd58692e1
Luisi, Ben F.
75fb3a48-d7a4-4cbf-ad81-f2ffeaaf79ff
Carpousis, Agamemnon J.
f8b5c5b1-1179-4817-9fd5-9a4a84100b89
Viollier, Patrick H., Strahl, Henrik, Turlan, Catherine, Khalid, Syma, Bond, Peter J., Kebalo, Jean-Marie, Peyron, Pascale, Poljak, Leonora, Bouvier, Marie, Hamoen, Leendert, Luisi, Ben F. and Carpousis, Agamemnon J.
(2015)
Membrane recognition and dynamics of the RNA Degradosome.
PLoS Genetics, 11 (2), .
(doi:10.1371/journal.pgen.1004961).
Abstract
RNase E, which is the central component of the multienzyme RNA degradosome, serves as a scaffold for interaction with other enzymes involved in mRNA degradation including the DEAD-box RNA helicase RhlB. Epifluorescence microscopy under live cell conditions shows that RNase E and RhlB are membrane associated, but neither protein forms cytoskeletal-like structures as reported earlier by Taghbalout and Rothfield. We show that association of RhlB with the membrane depends on a direct protein interaction with RNase E, which is anchored to the inner cytoplasmic membrane through an MTS (Membrane Targeting Sequence). Molecular dynamics simulations show that the MTS interacts with the phospholipid bilayer by forming a stabilized amphipathic ?-helix with the helical axis oriented parallel to the plane of the bilayer and hydrophobic side chains buried deep in the acyl core of the membrane. Based on the molecular dynamics simulations, we propose that the MTS freely diffuses in the membrane by a novel mechanism in which a large number of weak contacts are rapidly broken and reformed. TIRFm (Total Internal Reflection microscopy) shows that RNase E in live cells rapidly diffuses over the entire inner membrane forming short-lived foci. Diffusion could be part of a scanning mechanism facilitating substrate recognition and cooperativity. Remarkably, RNase E foci disappear and the rate of RNase E diffusion increases with rifampicin treatment. Control experiments show that the effect of rifampicin is specific to RNase E and that the effect is not a secondary consequence of the shut off of E. coli transcription. We therefore interpret the effect of rifampicin as being due to the depletion of RNA substrates for degradation. We propose a model in which formation of foci and constraints on diffusion arise from the transient clustering of RNase E into cooperative degradation bodies.
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Accepted/In Press date: 17 December 2014
Published date: 3 February 2015
Organisations:
Computational Systems Chemistry
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Local EPrints ID: 374228
URI: http://eprints.soton.ac.uk/id/eprint/374228
ISSN: 1553-7390
PURE UUID: 851a377c-c7c0-4bcf-9d3d-b58f1fad0c82
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Date deposited: 10 Feb 2015 14:04
Last modified: 15 Mar 2024 03:29
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Contributors
Author:
Patrick H. Viollier
Author:
Henrik Strahl
Author:
Catherine Turlan
Author:
Syma Khalid
Author:
Peter J. Bond
Author:
Jean-Marie Kebalo
Author:
Pascale Peyron
Author:
Leonora Poljak
Author:
Marie Bouvier
Author:
Leendert Hamoen
Author:
Ben F. Luisi
Author:
Agamemnon J. Carpousis
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