Signal-recognition particle (SRP)-dependent targeting of translating ribosomes to membranes is a multistep quality-control process. Ribosomes that are translating weakly hydrophobic signal sequences can be rejected from the targeting reaction even after they are bound to the SRP. Here we show that the early complex, formed by Escherichia coli SRP and its receptor FtsY with ribosomes translating the incorrect cargo EspP, is unstable and rearranges inefficiently into subsequent conformational states, such that FtsY dissociation is favored over successful targeting. The N-terminal extension of EspP is responsible for these defects in the early targeting complex. The cryo-electron microscopy structure of this 'false' early complex with EspP revealed an ordered M domain of SRP protein Ffh making two ribosomal contacts, and the NG domains of Ffh and FtsY forming a distorted, flexible heterodimer. Our results provide a structural basis for SRP-mediated signal-sequence selection during recruitment of the SRP receptor

A Raine

Aileen Ariosa

AT Brunger

B Lauring

B Weiche

BC Cross

BS Schuwirth

C Schaffitzel

Christiane Schaffitzel

CY Janda

D Braig

DM Freymann

E Miyazaki

EF Pettersen

G Montoya

G Tang

Guy Schoehn

H Tian

HC Lee

Imre Berger

JA Doudna

JB Heymann

JH Peterson

JJ Flanagan

K Knoops

K Nagai

K Shen

Karine Huard

KR Rosendal

Kèvin Knoops

LF Estrozi

M del Alamo

M Halic

M Valle

MA Poritz

Manikandan Karuppasamy

N Bradshaw

N Fischer

Ottilie von Loeffelholz

P Peluso

PA Penczek

PB Rosenthal

PF Egea

PJ Focia

QA Valent

R Gilmore

RJ Keenan

RL Szabady

RT Batey

S Angelini

SF Ataide

SH Scheres

Shu-ou Shan

SO Shan

T Connolly

T Hainzl

T Powers

TR Shaikh

VQ Lam

W Holtkamp

X Zhang

Xin Zhang

PubMed

International audienceSignal-recognition particle (SRP)-dependent targeting of translating ribosomes to membranes is a multistep quality-control process. Ribosomes that are translating weakly hydrophobic signal sequences can be rejected from the targeting reaction even after they are bound to the SRP. Here we show that the early complex, formed by Escherichia coli SRP and its receptor FtsY with ribosomes translating the incorrect cargo EspP, is unstable and rearranges inefficiently into subsequent conformational states, such that FtsY dissociation is favored over successful targeting. The N-terminal extension of EspP is responsible for these defects in the early targeting complex. The cryo-electron microscopy structure of this 'false' early complex with EspP revealed an ordered M domain of SRP protein Ffh making two ribosomal contacts, and the NG domains of Ffh and FtsY forming a distorted, flexible heterodimer. Our results provide a structural basis for SRP-mediated signal-sequence selection during recruitment of the SRP receptor

von Loeffelholz, Ottilie

Knoops, Kèvin

Ariosa, Aileen

Zhang, Xin

Karuppasamy, Manikandan

Huard, Karine

Schoehn, Guy

Berger, Imre

Shan, Shu-Ou

Schaffitzel, Christiane

HAL-CEA

Structural basis of signal sequence surveillance and selection by the SRP-FtsY complex.

Shan, Shu-ou

Caltech Authors - Main

SUPPLEMENTARY INFORMATION 
 
 
 
 
 
TITLE: 
Structural Basis of Signal Sequence Surveillance and Selection by the SRP-SR Complex 
 
 
 
 
 
AUTHORS and AFFILIATIONS 
Ottilie von Loeffelholz1,2, Kèvin Knoops1,2,6, Aileen Ariosa3,6, Xin Zhang3,4, Manikandan 
Karuppasamy1,2, Karine Huard1,2, Guy Schoehn1,2,5, Imre Berger1,2, Shu-ou Shan3, Christiane 
Schaffitzel1,2 
 
 
 
 
 
1 European Molecular Biology Laboratory (EMBL), Grenoble Outstation, 38042 Grenoble, France 
2 Unit of Virus Host-Cell Interactions, Université Joseph Fourier (UJF)-EMBL-Centre National de la Recherche 
Scientifique (CNRS), UMI 3265, 38042 Grenoble, France 
3 Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, CA 91125, 
United States 
4 Department of Molecular and Experimental Medicine, The Scripps Research Institute, La Jolla, CA 90037, 
United States 
5 CNRS-CEA (Commissariat à l'énergie atomique et aux énergies alternatives)-UJF - Institut de Biologie 
Structurale-Jean-Pierre Ebel, UMR 5075, 38027 Grenoble, France 
6 These authors contributed equally to this work. 
Correspondence should be addressed to: S.S., sshan@caltech.edu; C.S., schaffitzel@embl.fr 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
  
 
 
 
Supplementary Figure 1: In vitro translocation of EspP signal sequence variants and SRP 
binding to ribosomal complexes. (a) In vitro co-translational targeting and translocation through 
microsomal membranes. The EspP signal sequence variants were fused N-terminally to the signal 
peptidase cleavage site and to the mature region of pre-Prolactin. Translocation of the preprotein leads 
to cleavage of the signal sequence. (b) Coomassie-stained SDS-PAGE gel showing binding of single-
chain SRP (scSRP) to 70S, RNCFtsQ, and RNCEspP analyzed by ribosomal pelleting. The protein band 
corresponding to scSRP is highlighted by an arrow. In all experiments, except the 70S control, 
ribosomes were incubated with a five-fold molar excess of scSRP in the absence of nucleotides. 
 
 
 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Supplementary Figure 2: Computational Sorting of the RNCEspP-SRP-FtsY data set. The dataset 
was sorted for compositional and conformational heterogeneity to obtain four subgroups: Particles 
were separated for the ratcheted (EMDB ID 136356) and for the not-ratcheted ribosome conformation 
(EMBD ID 105657) as well as for the presence and the absence of SRP and FtsY (scSRP) at the exit of 
the ribosomal tunnel. Upper row: resulting maps after computational sorting 44. Second row: 
Additional views of the non-ratcheted (left) and ratcheted (right) RNCEspP-SRP-FtsY complexes. The 
first view (1st and 3rd image) on the ribosomal tunnel exit shows a second connection of the SRP to the 
ribosome formed by the Ffh M-domain. The second view (2nd and 4th image) is on the exit of the 
ribosomal tunnel and the SRP-FtsY complex. Both SRP-FtsY containing maps have a second 
ribosomal connection formed by the M-domain (second row, 1st and 3rd image) and a non-symmetric 
NG-domain arrangement. The map of the not ratcheted RNCEspP-SRP-FtsY conformation 
corresponding to 36% of the dataset was refined to higher resolution. 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Supplementary Figure 3: Resolution of the RNCEspP-SRP-FtsY reconstruction. The FSC function 
was calculated between two independent three-dimensional reconstructions of the RNCEspP-SRP-FtsY 
complex (continuous blue line). A set of 46,945 particles was split randomly into two equal halves to 
calculate the two reconstructions. FSC=0.5 indicates a resolution of 12.2 Å (dotted green line), and 
FSC=0.143 56 indicates a resolution of 8.3 Å (dotted purple line). 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Supplementary Figure 4: Conformational rearrangements of the targeting complex assessed by 
placement of the the RNCFtsQ-SRP atomic model into the EM density of the ‘false’ early complex. 
(a,b) The atomic model of the E. coli SRP bound to the translating ribosome (PDB ID: 2J28)17 was 
placed into the EM density. Conformational changes of the Ffh NG-domain leading to a detachment 
from ribosomal protein L23 are indicated by black arrows. The detachment of the 4.5S RNA from the 
ribosomal protein L32 of the large ribosomal subunit is indicated by an orange arrow. The position in 
the EM density where the FtsY NG-domain is placed is highlighted by a purple arrow. The 
experimental density is depicted in light grey, 4.5S RNA in orange, the signal sequence in red, the Ffh 
M-domain in yellow, the Ffh NG-domain in greenyellow, the 50S rRNA in dark gray, L29 in wheat 
and L23 in orange. 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
 
 
 
 
 
 
 
 
Supplementary Figure 5: Comparison of (a) the M-domain in the RNCEspP-SRP-FtsY ‘false’ early 
complex and (b) the M-domain in the RNCFtsQ-SRP-FtsY early complex (EMDB ID: 1762)20. 
Left: Close-up on the exit of the ribosomal tunnel and the M-domain of the RNC-SRP-FtsY complex 
in a surface representation. Right: Slice through the RNC-SRP-FtsY EM reconstruction. Ribosomal 
RNA helix h59 and the 4.5S SRP RNA are labelled for orientation. The arrow heads indicate the 
position of the signal-sequence binding part of the M-domain. 
 
 
 
 
 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
Supplementary Figure 6: Conformational heterogeneity in the RNCEspP-SRP-FtsY 
reconstruction. (a) Variance map of the RNCEspP-SRP-FtsY reconstruction calculated from 
hypergeometrically stratified resampled volumes in SPARX. After elimination of particles with low 
correlation coefficient, 45,200 particles were used for the hypergeometrically stratified resampling to 
calculate the 3D average- and variance maps58. Left: view on the ribosomal tunnel exit site of the 50S 
and the SRP-FtsY complex; middle: crown view with the SRP-FtsY complex; right: view on the 
ribosomal tunnel exit showing the second connection of the SRP to the ribosome formed by the Ffh M-
domain. Highly homogeneous regions (lower voxel variances) are coloured in blue, flexible or 
heterogeneous regions (higher voxel variances) are displayed in red. The surface representations were 
prepared in Chimera59. (b-f) Two different conformations of the ‘false’ early complex obtained by 
heterogeneity analysis using Xmipp. (b,c): A heterogeneity analysis using mlf_refine3d from Xmipp57 
resulted in two EM reconstructions showing distinct conformations of the SRP-FtsY complex. In both 
EM reconstructions, the M-domain contacts rRNA helix 59. Arrows point to the connecting density 
between the Ffh G- and M- domains. (d,e) The EM density reveals two different Ffh/FtsY NG-domain 
conformations. (f) Overlay of the two maps shown in (d) and (e). In both conformations, the Ffh NG-
domain is shifted towards the M-domain, and the NG-domains do not adopt a pseudo-symmetric V-
shape. 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546
 
 
 
 
 
 
 
 
 
 
 
 
 SRP 
Binding 
Kd (nM) 
Early 
Complex 
Kd (nM) 
Early – Closed 
Rearrangement
 ke-c (s-1) 
Closed  Complex 
Assembly  
kon x 10
3
 (M-1s-1)  
RNCEspP [1] 13 311 0.04 ± 0.01 9.2 ± 1.1  
RNCFtsQ [2] 1 80 ~ 0.3 ~ 1000 
 
 
 
 
 
 
 
 
 
 
 
Supplementary Table 1: Comparison of kinetic and thermodynamic data of EspP as a non-SRP 
substrate with FtsQ as a bona-fide SRP substrate. 
[1] Data from this study as reported in Figures 1d, 2b and 5c. 
[2] The data for the RNCFtsQ targeting complexes were originally reported in Zhang, X., Schaffitzel, 
C., Ban, N. & Shan, S.O. Multiple conformational switches in a GTPase complex control co-
translational protein targeting. Proc. Natl. Acad. Sci. USA 106, 1754-1759 (2009). 
 
Nature Structural & Molecular Biology: doi:10.1038/nsmb.2546


Structural basis of signal sequence surveillance and selection by the SRP–FtsY complex

Signal-recognition particle (SRP)-dependent targeting of translating ribosomes to membranes is a multistep quality-control process. Ribosomes that are translating weakly hydrophobic signal sequences can be rejected from the targeting reaction even after they are bound to the SRP. Here we show that the early complex, formed by Escherichia coli SRP and its receptor FtsY with ribosomes translating the incorrect cargo EspP, is unstable and rearranges inefficiently into subsequent conformational states, such that FtsY dissociation is favored over successful targeting. The N-terminal extension of EspP is responsible for these defects in the early targeting complex. The cryo-electron microscopy structure of this 'false' early complex with EspP revealed an ordered M domain of SRP protein Ffh making two ribosomal contacts, and the NG domains of Ffh and FtsY forming a distorted, flexible heterodimer. Our results provide a structural basis for SRP-mediated signal-sequence selection during recruitment of the SRP receptor.</p

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Structural basis of signal sequence surveillance and selection by the SRP-FtsY complex

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Nature Structural & Molecular Biology

Structural basis of signal sequence surveillance and selection by the SRP–FtsY complex

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