PDBsum entry 1ra7

Transferase

PDB id

1ra7

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Contents

			Protein chain

					461 a.a. *

			Ligands

					GTP


					ACY ×7

			Waters ×263

* Residue conservation analysis

PDB id:

1ra7

Links

Name:

Transferase

Title:

Poliovirus polymerase with gtp

Structure:

Genome polyprotein. Chain: a. Fragment: RNA-directed RNA polymerase (residue 1748-2208). Synonym: p3d. Engineered: yes. Mutation: yes

Source:

Human poliovirus 1. Organism_taxid: 12081. Strain: mahoney. Gene: 3d. Expressed in: escherichia coli. Expression_system_taxid: 562.

Resolution:

2.35Å

R-factor:

0.222

R-free:

0.259

Authors:

A.A.Thompson,O.B.Peersen

Key ref:

A.A.Thompson and O.B.Peersen (2004). Structural basis for proteolysis-dependent activation of the poliovirus RNA-dependent RNA polymerase. EMBO J, 23, 3462-3471. PubMed id: 15306852 DOI: 10.1038/sj.emboj.7600357

Date:

31-Oct-03

Release date:

17-Aug-04

PROCHECK

	Headers

	References

Protein chain

P03300 (POLG_POL1M) - Genome polyprotein from Poliovirus type 1 (strain Mahoney)

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:					2209 a.a. 461 a.a.*

Key:

PfamA domain

Secondary structure

CATH domain

* PDB and UniProt seqs differ at 6 residue positions (black crosses)



		Enzyme reactions

Enzyme class 2:

E.C.2.7.7.48 - RNA-directed Rna polymerase.

[IntEnz] [ExPASy] [KEGG] [BRENDA]

Reaction:

RNA(n) + a ribonucleoside 5'-triphosphate = RNA(n+1) + diphosphate

RNA(n)	+	ribonucleoside 5'-triphosphate	=	RNA(n+1)	+	diphosphate

Enzyme class 3:

E.C.3.4.22.28 - picornain 3C.

[IntEnz] [ExPASy] [KEGG] [BRENDA]

Reaction:

Selective cleavage of Gln-|-Gly bond in the poliovirus polyprotein. In other picornavirus reactions Glu may be substituted for Gln, and Ser or Thr for Gly.

Enzyme class 4:

E.C.3.4.22.29 - picornain 2A.

[IntEnz] [ExPASy] [KEGG] [BRENDA]

Reaction:

Selective cleavage of Tyr-|-Gly bond in the picornavirus polyprotein. In other picornavirus reactions Glu may be substituted for Gln, and Ser or Thr for Gly.

Enzyme class 5:

E.C.3.6.1.15 - nucleoside-triphosphate phosphatase.

[IntEnz] [ExPASy] [KEGG] [BRENDA]

Reaction:

a ribonucleoside 5'-triphosphate + H2O = a ribonucleoside 5'-diphosphate + phosphate + H⁺

ribonucleoside 5'-triphosphate	+	H2O	=	ribonucleoside 5'-diphosphate	+	phosphate	+	H(+)

Note, where more than one E.C. class is given (as above), each may correspond to a different protein domain or, in the case of polyprotein precursors, to a different mature protein.

Molecule diagrams generated from .mol files obtained from the KEGG ftp site

reference

DOI no: 10.1038/sj.emboj.7600357	EMBO J 23:3462-3471 (2004)
PubMed id: 15306852

Structural basis for proteolysis-dependent activation of the poliovirus RNA-dependent RNA polymerase.
A.A.Thompson, O.B.Peersen.

ABSTRACT

The active RNA-dependent RNA polymerase of poliovirus, 3Dpol, is generated by cleavage of the 3CDpro precursor protein, a protease that has no polymerase activity despite containing the entire polymerase domain. By intentionally disrupting a known and persistent crystal packing interaction, we have crystallized the poliovirus polymerase in a new space group and solved the complete structure of the protein at 2.0 A resolution. It shows that the N-terminus of fully processed 3Dpol is buried in a surface pocket where it makes hydrogen bonds that act to position Asp238 in the active site. Asp238 is an essential residue that selects for the 2' OH group of substrate rNTPs, as shown by a 2.35 A structure of a 3Dpol-GTP complex. Mutational, biochemical, and structural data further demonstrate that 3Dpol activity is exquisitely sensitive to mutations at the N-terminus. This sensitivity is the result of allosteric effects where the structure around the buried N-terminus directly affects the positioning of Asp238 in the active site.

Selected figure(s)



	Figure 1. Figure 1 Overview of poliovirus 3D^pol RdRp structure. (A) Comparison of the original partial structure (yellow) with the complete structure shown with the fingers domain in red, the palm in gray, the thumb in blue, and the active site colored magenta. The N-terminal strand (residues 12 -36) of the original structure that descended toward the active site is shown in green. The two structures were superimposed using the backbone atoms of the active site GDD motif and three residues on either side of it (i.e. residues 324 -332). (B) Superimposition of the thumb domains from the original structure (yellow) and new complete structure (blue) showing that the thumb structure is largely unchanged by the two mutations (L446D and R455D) used to break Interface I and crystallize 3D^pol in a new lattice. The side chains of Phe30 and Phe34 are shown in green for the original structure and red for the new complete structure. (C) Top view of the complete 3D^pol structure highlighting the individual fingers of the fingers domain. The index finger is shown in green, the middle finger in orange, the ring finger in yellow, and the pinky finger in pink. As in (A), the palm is shown in gray, the thumb is in blue, and the active site is colored magenta. Phe30 and Phe34 are shown as sticks, Pro119 on the pinky finger is indicated with spheres, and glycines 117 and 124 are colored in cyan. (D) Bar representation of the 3D^pol sequence colored according to the structural elements shown in (C). Sections of the sequence in the palm are in gray and the numbers correspond to the first residue in a given structural motif.		Figure 3. Figure 3 Molecular details of the 3D^pol nucleotide-binding site illustrating how the buried N-terminus positions Asp238 for interactions with the 2' OH group of the bound NTP. (A) Superposition of three 3D^pol structures showing the selective 1.4 � movement of Asp238 toward the active site when the N-terminus is properly positioned. The original partial wild-type structure is in pink, the 3D^pol 68/L446A/R455D structure is in salmon, and the complete structure is colored by atom type with carbons colored according to structural motifs as in Figure 1C. Most side chains have been omitted for clarity and residues 324 -332 of the active site (magenta) were used for the superimpositions. (B) Electron density map and model of the GTP molecule bound to 3D^pol with the 2' OH group making a 2.8 � long hydrogen bond with Asp238. The GTP makes bridging interactions between the fingers and palm domains. The base is staked on Arg174 from the ring finger, the ribose interacts with Arg174 from the ring finger and Asp238 in the palm, and the triphosphate interacts with Arg163 and Lys167 from the ring finger and the backbone of the palm domain. The map is a 2.35 � resolution 2F[o] -F[c] simulated annealing (1500 K) composite omit map contoured at 1.6 around the rGTP molecule bound after soaking crystals in 10 mM GTP. (C) Stereo view showing how the buried N-terminus of 3D^pol positions Asp238 for rNTP interactions. The N-terminus forms three hydrogen bonds with the carbonyl oxygens of residues 64, 239, and 241 (magenta bonds) that act to position Asp238 for interaction with the 2' OH of rNTPs. The structures of the G1A mutant (orange), D238A mutant (teal, only residues 238 -241 are shown), and original partial structure without a buried N-terminus (red) are superimposed using the active site.

Figures were selected by the author.

Literature references that cite this PDB file's key reference

PubMed id

Reference

19875418

A.J.te Velthuis, J.J.Arnold, C.E.Cameron, S.H.van den Worm, and E.J.Snijder (2010).
The RNA polymerase activity of SARS-coronavirus nsp12 is primer dependent.

Nucleic Acids Res, 38, 203-214.

20521933

C.E.Cameron, H.Suk Oh, and I.M.Moustafa (2010).
Expanding knowledge of P3 proteins in the poliovirus lifecycle.

Future Microbiol, 5, 867-881.

20392853

C.Ferrer-Orta, M.Sierra, R.Agudo, I.de la Higuera, A.Arias, R.Pérez-Luque, C.Escarmís, E.Domingo, and N.Verdaguer (2010).
Structure of foot-and-mouth disease virus mutant polymerases with reduced sensitivity to ribavirin.

J Virol, 84, 6188-6199.

PDB codes:

3klv 3kmq 3kms 3kna 3koa

20051491

J.F.Spagnolo, E.Rossignol, E.Bullitt, and K.Kirkegaard (2010).
Enzymatic and nonenzymatic functions of viral RNA-dependent RNA polymerases within oligomeric arrays.

RNA, 16, 382-393.

20625447

J.Kerkvliet, R.Edukulla, and M.Rodriguez (2010).
Novel roles of the picornaviral 3D polymerase in viral pathogenesis.

Adv Virol, 2010, 368068.

20534860

K.Konduru, and G.G.Kaplan (2010).
Determinants in 3Dpol modulate the rate of growth of hepatitis A virus.

J Virol, 84, 8342-8347.

21060812

L.I.Levi, N.F.Gnädig, S.Beaucourt, M.J.McPherson, B.Baron, J.J.Arnold, and M.Vignuzzi (2010).
Fidelity variants of RNA dependent RNA polymerases uncover an indirect, mutagenic activity of amiloride compounds.

PLoS Pathog, 6, e1001163.

21148772

P.Gong, and O.B.Peersen (2010).
Structural basis for active site closure by the poliovirus RNA-dependent RNA polymerase.

Proc Natl Acad Sci U S A, 107, 22505-22510.

PDB codes:

3ol6 3ol7 3ol8 3ol9 3ola 3olb

20534858

S.E.Hobdey, B.J.Kempf, B.P.Steil, D.J.Barton, and O.B.Peersen (2010).
Poliovirus polymerase residue 5 plays a critical role in elongation complex stability.

J Virol, 84, 8072-8084.

19101564

B.J.Geiss, A.A.Thompson, A.J.Andrews, R.L.Sons, H.H.Gari, S.M.Keenan, and O.B.Peersen (2009).
Analysis of flavivirus NS5 methyltransferase cap binding.

J Mol Biol, 385, 1643-1654.

PDB codes:

3eva 3evb 3evc 3evd 3eve 3evf 3evg

18773930

B.P.Steil, and D.J.Barton (2009).
Cis-active RNA elements (CREs) and picornavirus RNA replication.

Virus Res, 139, 240-252.

18487072

C.C.Kok, and P.C.McMinn (2009).
Picornavirus RNA-dependent RNA polymerase.

Int J Biochem Cell Biol, 41, 498-502.

19151724

C.Castro, E.D.Smidansky, J.J.Arnold, K.R.Maksimchuk, I.Moustafa, A.Uchida, M.Götte, W.Konigsberg, and C.E.Cameron (2009).
Nucleic acid polymerases use a general acid for nucleotidyl transfer.

Nat Struct Mol Biol, 16, 212-218.

19910183

C.E.Cameron, I.M.Moustafa, and J.J.Arnold (2009).
Dynamics: the missing link between structure and function of the viral RNA-dependent RNA polymerase?

Curr Opin Struct Biol, 19, 768-774.

19403755

C.Savolainen-Kopra, E.Samoilovich, H.Kahelin, A.K.Hiekka, T.Hovi, and M.Roivainen (2009).
Comparison of poliovirus recombinants: accumulation of point mutations provides further advantages.

J Gen Virol, 90, 1859-1868.

19141436

M.Högbom, K.Jäger, I.Robel, T.Unge, and J.Rohayem (2009).
The active form of the norovirus RNA-dependent RNA polymerase is a homodimer with cooperative activity.

J Gen Virol, 90, 281-291.

19406094

P.Gong, G.Campagnola, and O.B.Peersen (2009).
A quantitative stopped-flow fluorescence assay for measuring polymerase elongation rates.

Anal Biochem, 391, 45-55.

19414569

T.C.Chen, H.Y.Chang, P.F.Lin, J.H.Chern, J.T.Hsu, C.Y.Chang, and S.R.Shih (2009).
Novel antiviral agent DTriP-22 targets RNA-dependent RNA polymerase of enterovirus 71.

Antimicrob Agents Chemother, 53, 2740-2747.

18829745

A.Arias, J.J.Arnold, M.Sierra, E.D.Smidansky, E.Domingo, and C.E.Cameron (2008).
Determinants of RNA-dependent RNA polymerase (in)fidelity revealed by kinetic analysis of the polymerase encoded by a foot-and-mouth disease virus mutant with reduced sensitivity to ribavirin.

J Virol, 82, 12346-12355.

18632861

A.Gruez, B.Selisko, M.Roberts, G.Bricogne, C.Bussetta, I.Jabafi, B.Coutard, A.M.De Palma, J.Neyts, and B.Canard (2008).
The crystal structure of coxsackievirus B3 RNA-dependent RNA polymerase in complex with its protein primer VPg confirms the existence of a second VPg binding site on Picornaviridae polymerases.

J Virol, 82, 9577-9590.

PDB codes:

3cdu 3cdw

18574240

A.Nikonov, E.Juronen, and M.Ustav (2008).
Functional characterization of fingers subdomain-specific monoclonal antibodies inhibiting the hepatitis C virus RNA-dependent RNA polymerase.

J Biol Chem, 283, 24089-24102.

18032495

D.N.Harrison, E.V.Gazina, D.F.Purcell, D.A.Anderson, and S.Petrou (2008).
Amiloride derivatives inhibit coxsackievirus B3 RNA replication.

J Virol, 82, 1465-1473.

18632862

G.Campagnola, M.Weygandt, K.Scoggin, and O.Peersen (2008).
Crystal structure of coxsackievirus B3 3Dpol highlights the functional importance of residue 5 in picornavirus polymerases.

J Virol, 82, 9458-9464.

PDB code:

3ddk

18779320

H.B.Pathak, H.S.Oh, I.G.Goodfellow, J.J.Arnold, and C.E.Cameron (2008).
Picornavirus Genome Replication: ROLES OF PRECURSOR PROTEINS AND RATE-LIMITING STEPS IN oriI-DEPENDENT VPg URIDYLYLATION.

J Biol Chem, 283, 30677-30688.

18268843

K.K.Ng, J.J.Arnold, and C.E.Cameron (2008).
Structure-function relationships among RNA-dependent RNA polymerases.

Curr Top Microbiol Immunol, 320, 137-156.

18573885

M.L.Miller, and D.L.Miller (2008).
Non-DNA-templated addition of nucleotides to the 3' end of RNAs by the mitochondrial RNA polymerase of Physarum polycephalum.

Mol Cell Biol, 28, 5795-5802.

17993457

M.Shen, Z.J.Reitman, Y.Zhao, I.Moustafa, Q.Wang, J.J.Arnold, H.B.Pathak, and C.E.Cameron (2008).
Picornavirus genome replication. Identification of the surface of the poliovirus (PV) 3C dimer that interacts with PV 3Dpol during VPg uridylylation and construction of a structural model for the PV 3C2-3Dpol complex.

J Biol Chem, 283, 875-888.

18246077

M.Vignuzzi, E.Wendt, and R.Andino (2008).
Engineering attenuated virus vaccines by controlling replication fidelity.

Nat Med, 14, 154-161.

17223130

A.A.Thompson, R.A.Albertini, and O.B.Peersen (2007).
Stabilization of poliovirus polymerase by NTP binding and fingers-thumb interactions.

J Mol Biol, 366, 1459-1474.

PDB codes:

2ily 2ilz 2im0 2im1 2im2 2im3

17686855

A.Jakubiec, G.Drugeon, L.Camborde, and I.Jupin (2007).
Proteolytic processing of turnip yellow mosaic virus replication proteins and functional impact on infectivity.

J Virol, 81, 11402-11412.

18077388

D.Garriga, A.Navarro, J.Querol-Audí, F.Abaitua, J.F.Rodríguez, and N.Verdaguer (2007).
Activation mechanism of a noncanonical RNA-dependent RNA polymerase.

Proc Natl Acad Sci U S A, 104, 20540-20545.

PDB codes:

2pus 2qj1 2r70 2r72

17409142

D.M.Strauss, and D.S.Wuttke (2007).
Characterization of protein-protein interactions critical for poliovirus replication: analysis of 3AB and VPg binding to the RNA-dependent RNA polymerase.

J Virol, 81, 6369-6378.

17567696

G.A.Belov, C.Habbersett, D.Franco, and E.Ehrenfeld (2007).
Activation of cellular Arf GTPases by poliovirus protein 3CD correlates with virus replication.

J Virol, 81, 9259-9267.

17287213

H.Malet, M.P.Egloff, B.Selisko, R.E.Butcher, P.J.Wright, M.Roberts, A.Gruez, G.Sulzenbacher, C.Vonrhein, G.Bricogne, J.M.Mackenzie, A.A.Khromykh, A.D.Davidson, and B.Canard (2007).
Crystal structure of the RNA polymerase domain of the West Nile virus non-structural protein 5.

J Biol Chem, 282, 10678-10689.

PDB codes:

2hcn 2hcs 2hfz

17554171

I.Jabafi, B.Selisko, B.Coutard, A.M.De Palma, J.Neyts, M.P.Egloff, S.Grisel, K.Dalle, V.Campanacci, S.Spinelli, C.Cambillau, B.Canard, and A.Gruez (2007).
Improved crystallization of the coxsackievirus B3 RNA-dependent RNA polymerase.

Acta Crystallogr Sect F Struct Biol Cryst Commun, 63, 495-498.

17251299

L.L.Marcotte, A.B.Wass, D.W.Gohara, H.B.Pathak, J.J.Arnold, D.J.Filman, C.E.Cameron, and J.M.Hogle (2007).
Crystal structure of poliovirus 3CD protein: virally encoded protease and precursor to the RNA-dependent RNA polymerase.

J Virol, 81, 3583-3596.

PDB codes:

2ijd 2ijf

17524144

M.S.Freistadt, J.A.Vaccaro, and K.E.Eberle (2007).
Biochemical characterization of the fidelity of poliovirus RNA-dependent RNA polymerase.

Virol J, 4, 44.

17352827

M.S.Freistadt, and K.E.Eberle (2007).
Conserved aspartic acid 233 and alanine 231 are not required for poliovirus polymerase function in replicons.

Virol J, 4, 28.

17151116

M.Sierra, A.Airaksinen, C.González-López, R.Agudo, A.Arias, and E.Domingo (2007).
Foot-and-mouth disease virus mutant with decreased sensitivity to ribavirin: implications for error catastrophe.

J Virol, 81, 2012-2024.

17537850

N.Beerens, B.Selisko, S.Ricagno, I.Imbert, L.van der Zanden, E.J.Snijder, and B.Canard (2007).
De novo initiation of RNA synthesis by the arterivirus RNA-dependent RNA polymerase.

J Virol, 81, 8384-8395.

17475199

S.P.Mestas, A.J.Sholders, and O.B.Peersen (2007).
A fluorescence polarization-based screening assay for nucleic acid polymerase elongation activity.

Anal Biochem, 365, 194-200.

17121797

S.W.Fullerton, M.Blaschke, B.Coutard, J.Gebhardt, A.Gorbalenya, B.Canard, P.A.Tucker, and J.Rohayem (2007).
Structural and functional characterization of sapovirus RNA-dependent RNA polymerase.

J Virol, 81, 1858-1871.

PDB code:

2ckw

17301146

T.L.Yap, T.Xu, Y.L.Chen, H.Malet, M.P.Egloff, B.Canard, S.G.Vasudevan, and J.Lescar (2007).
Crystal structure of the dengue virus RNA-dependent RNA polymerase catalytic domain at 1.85-angstrom resolution.

J Virol, 81, 4753-4765.

PDB codes:

2j7u 2j7w

17400557

V.S.Korneeva, and C.E.Cameron (2007).
Structure-function relationships of the viral RNA-dependent RNA polymerase: fidelity, replication speed, and initiation mechanism determined by a residue in the ribose-binding pocket.

J Biol Chem, 282, 16135-16145.

16717096

A.Jakubiec, V.Tournier, G.Drugeon, S.Pflieger, L.Camborde, J.Vinh, F.Héricourt, V.Redeker, and I.Jupin (2006).
Phosphorylation of viral RNA-dependent RNA polymerase and its role in replication of a plus-strand RNA virus.

J Biol Chem, 281, 21236-21249.

16456546

C.Ferrer-Orta, A.Arias, R.Agudo, R.Pérez-Luque, C.Escarmís, E.Domingo, and N.Verdaguer (2006).
The structure of a protein primer-polymerase complex in the initiation of genome replication.

EMBO J, 25, 880-888.

PDB codes:

2d7s 2f8e

16498624

C.H.Schein, D.E.Volk, N.Oezguen, and A.Paul (2006).
Novel, structure-based mechanism for uridylylation of the genome-linked peptide (VPg) of picornaviruses.

Proteins, 63, 719-726.

17024178

I.Imbert, J.C.Guillemot, J.M.Bourhis, C.Bussetta, B.Coutard, M.P.Egloff, F.Ferron, A.E.Gorbalenya, and B.Canard (2006).
A second, non-canonical RNA-dependent RNA polymerase in SARS coronavirus.

EMBO J, 25, 4933-4942.

16356462

J.J.Arnold, A.Bernal, U.Uche, D.E.Sterner, T.R.Butt, C.E.Cameron, and M.R.Mattern (2006).
Small ubiquitin-like modifying protein isopeptidase assay based on poliovirus RNA polymerase activity.

Anal Biochem, 350, 214-221.

16719717

J.Ortín, and F.Parra (2006).
Structure and function of RNA replication.

Annu Rev Microbiol, 60, 305-326.

17018573

M.Ellingham, D.H.Bunka, D.J.Rowlands, and N.J.Stonehouse (2006).
Selection and characterization of RNA aptamers to the RNA-dependent RNA polymerase from foot-and-mouth disease virus.

RNA, 12, 1970-1979.

16327776

M.Vignuzzi, J.K.Stone, J.J.Arnold, C.E.Cameron, and R.Andino (2006).
Quasispecies diversity determines pathogenesis through cooperative interactions in a viral population.

Nature, 439, 344-348.

16840321

O.C.Richards, J.F.Spagnolo, J.M.Lyle, S.E.Vleck, R.D.Kuchta, and K.Kirkegaard (2006).
Intramolecular and intermolecular uridylylation by poliovirus RNA-dependent RNA polymerase.

J Virol, 80, 7405-7415.

15919922

A.Nayak, I.G.Goodfellow, and G.J.Belsham (2005).
Factors required for the Uridylylation of the foot-and-mouth disease virus 3B1, 3B2, and 3B3 peptides by the RNA-dependent RNA polymerase (3Dpol) in vitro.

J Virol, 79, 7698-7706.

16300678

D.Franco, H.B.Pathak, C.E.Cameron, B.Rombaut, E.Wimmer, and A.V.Paul (2005).
Stimulation of poliovirus RNA synthesis and virus maturation in a HeLa cell-free in vitro translation-RNA replication system by viral protein 3CDpro.

Virol J, 2, 86.

15890959

G.A.Belov, M.H.Fogg, and E.Ehrenfeld (2005).
Poliovirus proteins induce membrane association of GTPase ADP-ribosylation factor.

J Virol, 79, 7207-7216.

16188890

G.Kukolj, G.A.McGibbon, G.McKercher, M.Marquis, S.Lefèbvre, L.Thauvette, J.Gauthier, S.Goulet, M.A.Poupart, and P.L.Beaulieu (2005).
Binding site characterization and resistance to a class of non-nucleoside inhibitors of the hepatitis C virus NS5B polymerase.

J Biol Chem, 280, 39260-39267.

15919933

J.E.Boerner, J.M.Lyle, S.Daijogo, B.L.Semler, S.C.Schultz, K.Kirkegaard, and O.C.Richards (2005).
Allosteric effects of ligands and mutations on poliovirus RNA-dependent RNA polymerase.

J Virol, 79, 7803-7811.

15878882

J.J.Arnold, M.Vignuzzi, J.K.Stone, R.Andino, and C.E.Cameron (2005).
Remote site control of an active site fidelity checkpoint in a viral RNA-dependent RNA polymerase.

J Biol Chem, 280, 25706-25716.

15965477

S.Crowder, and K.Kirkegaard (2005).
Trans-dominant inhibition of RNA viral replication can slow growth of drug-resistant viruses.

Nat Genet, 37, 701-709.

15955819

S.Di Marco, C.Volpari, L.Tomei, S.Altamura, S.Harper, F.Narjes, U.Koch, M.Rowley, R.De Francesco, G.Migliaccio, and A.Carfí (2005).
Interdomain communication in hepatitis C virus polymerase abolished by small molecule inhibitors bound to a novel allosteric site.

J Biol Chem, 280, 29765-29770.

PDB codes:

2brk 2brl

The most recent references are shown first. Citation data come partly from CiteXplore and partly from an automated harvesting procedure. Note that this is likely to be only a partial list as not all journals are covered by either method. However, we are continually building up the citation data so more and more references will be included with time. Where a reference describes a PDB structure, the PDB codes are shown on the right.