Structural studies of small RNA phages

Structural studies of small RNA phages

Lars Liljas, Uppsala UniversityStructure and Function of Large Molecular Assemblies

Erice, June 12, 2006

Phages: all kinds of shapes

P2

T4

MS2 X174

Phage MS2 infects E. coli

The virus particles attach to bacterial f-pili

Maturation Coat (0) Replicase (0)Lysis (+1)

Maturation-lysis CoatRead-through (A1)

Replicase

130 1308 1335 1724 1761 33951 3569

1678 1902

62 1305 1325 1743 2353 4119

4220

1

2331

MS2

Q •Coat protein binding site

RNA of leviviruses codes for 3-4 RNA of leviviruses codes for 3-4 proteins proteins

The genetic maps of The genetic maps of LevivirusLevivirus phage MS2 and phage MS2 and AllolevivirusAllolevivirus phage Q phage Q

MS2: function of components

• RNA: single-stranded positive sense• A-protein: attachment and entry• Coat protein: protein coat, translational repression

and RNA recognition• Replicase subunit: forms active RNA-dependent

RNA polymerase with host proteins• Lysis protein: lyses bacterial cell wall to release

new virions

MS2: components

• How is assembly controlled?

• What determines the specificity in the binding of coat protein to the translational operator/assembly initiation site in RNA?

• What is the position and conformation of the A protein?

• How is the replicase working?

The replicase

• The RNA polymerase is formed by – Replicase subunit (coded by viral RNA)– Elongation factors EF-Tu and EF-Ts– Ribosomal protein S1 (- strand synthesis)

The replicase

RNA polymerase

EF-Tu - EF-Ts complexKawashima et al., 1996

Poliovirus, Thompson & Peersen, 2004

Levivirus capsid structures

Phage Resolution Particles

MS2 2.2 Å Phage and recombinant VLP

Q 3.5 Å Phage and recombinant VLP

fr 3.5 Å Phage

GA 3.4 Å Phage

PP7 3.7 Å Phage

PRR1 3.5 Å Recombinant VLP

Department of Cell and Molecular Biology, Uppsala UniversityKarin ValegårdKerstin Fridborg Roshan GolmohammadiSjoerd van den WormElin GrahnKaspars TarsCharlotte HelgstrandMagnus JohanssonPavel Plevka

Department of Molecular Biology, Latvian University, RigaMaija Bundule

School of Biology, University of LeedsNicola StonehousePeter StockleyWilf Horn

Small RNA phages

The virus particle is formed by • 90 coat protein dimers (180 subunits, T = 3) • 1 copy of A-protein• RNA molecule

MS2 particle

The coat protein dimer has a central sheet facing the interior. Helices and a hairpin form the outer surface

MS2 particle

B/A

CC

Role of A-proteinAttachment to pili is due to the A-protein

A fragment of the A-protein enters bacterium with viral RNA

The A-protein, 393 aa, has no sequence similarity to other proteins

Attempts to isolate (soluble) protein has failed

Role of A-protein

Where is the A-protein?How does the binding trigger release of the RNA?

Particle has holes at 5-fold and 3-fold axesPart of the A-protein might be exposed in one of these holes

Position of A-protein

Phage PRR1, Johansson et al., in prep. (Poster 26)

Fivefold and threefold axes surrounded by flexible loops

Forms the protective coatTranslational repressorRecognition of packaging signal in RNA

Role of coat protein

MS2 capsid (one A/B dimer) viewed from outside

Coat protein binding to RNA

A hairpin in the RNA is used both as a translational operator for the replicase and a packaging signal

-5 U U A A -4 G C G C -10 A G C -1 U A +1 A U C G -15 A U +4

A protein Coat Replicase

Lysis

Operator hairpin

Coat protein binding to RNA

-5 U U A A -4 G C G C -10 A G C -1 U A +1 A U C G -15 A U +4

N PyA A N N’ N N’Pu N N’ N N’ N N’ N N’ N N’

In MS2, four positions in single-stranded regions are recognized with specificity

RNA bindingCrystals of recombinant capsids can be soaked with RNA hairpins, which enter the particles and bind to the coat protein

• One RNA hairpin binds to a dimer

• Binding to AB dimer is asymmetric

RNA binding

MS2 capsid (one A/B dimer) viewed from inside

Single-stranded regions of the RNA binds to three conserved sites in the protein

RNA recognition in MS2

What is determining the specificity?

How are differences in specificity between different phages achieved?

RNA recognition in MS2

-5 U U A A -4 G C G C-10 A G C -1 U A +1 A U C G -15 A U +4

A pocket with specificity for A

RNA recognition in

MS2: A-4

-5 U U A A -4 G C G C-10 A G C -1 U A +1 A U C G -15 A U +4

The same pocket in the other subunit with specificity for A or G

RNA recognition in

MS2: A-10

-5 U U A A -4 G C G C-10 A G C -1 U A +1 A U C G -15 A U +4

A-10

G-10

C-10

RNA recognition in

MS2: A-10

-5 U U A A -4 G C G C-10 A G C -1 U A +1 A U C G -15 A U +4

A binding site with specificity forU or C

RNA recognition in MS2: U-5

Of 9 natural and variant bases tested, 8 bind similar to wildtype U although the affinity differs by several orders of magnitude

U-5: 1A-5: 0.01

C-5: 10

RNA recognition in MS2: U-5

-5 U U A A -4 G C G C -10 A G C -1 U A +1 A U C G -15 A U +4

The base of A-7 has no direct contact with the proteinThis base has effects on the conformation that are important for binding

RNA recognition in MS2: A-7

RNA binding: specificity

-5 U U A A -4 G C G C-10 A G C -1 U A +1 A U C G -15 A U +4

The RNA-binding surface of the coat protein is very conserved, but Q coat protein binds to a hairpin with different structure

A U A +8 C G U A G C U A +1 A C G G C

MS2 Q

RNA binding

specificity

Mature Q particles have disulfides (-->) blocking the entry of RNA segments.

Mutations of two residues in MS2 leads to binding also of Q hairpin

MS2

Q

RNA binding: specificity

A U A G

U

C C :

TYR

Conformation of loop very similar and the protein-RNA contacts are conserved but the basepairs are shifted

A A G:C A:U

U TYR

MS2 hairpin Q hairpin

RNA binding: specificity

-5 U U A A -4 G C G C -10 A G C -1 U A +1 A U C G -15 A U +4

Phage PRR1 has still another variant of hairpin structure

A U A C G U A G C U A +1 A C G G C

MS2 Q PRR1

C G U A A G C G C A A U U A +1 A U C G C G

Assembly of MS2 particles

Dimers assemble into correctly formed T=3 particles

Two similar dimer conformations allow formation of quasi-equivalent contacts

Subunit packing in MS2

B/A

CC

In leviviruses, RNA stimulates assembly:•RNA binding to dimer - induces “assembly mode”•Strong binding to one site (“initiation site”) - controls encapsidation of correct RNA

Role of RNA in subunit packing

Control of quasiequivalence in other viruses

In many small viruses, a flexible part of the coat protein is used to control the packing of subunits – used as order-disorder switches

Control of quasi-equivalence

Leviviruses have no arms and order/disorder switches - assembly is controlled by the contact surfaces

Conclusions

The observed specificity of coat protein binding to the viral RNA is explained by the structure of the complex

The coat protein is able to form T=3 capsids without using an arm and order/disorder switches