PDBsum entry 3eeb

Toxin

PDB id

3eeb

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Contents

			Protein chains

					205 a.a. *

			Ligands

					IHP ×2

			Metals

					_NA ×2

			Waters ×224

* Residue conservation analysis

PDB id:

3eeb

Links

Name:

Toxin

Title:

Structure of the v. Cholerae rtx cysteine protease domain

Structure:

Rtx toxin rtxa. Chain: a, b. Fragment: residues 3442-3650. Engineered: yes

Source:

Vibrio cholerae. Organism_taxid: 666. Strain: n16961. Gene: rtxa, vc1451. Expressed in: escherichia coli. Expression_system_taxid: 562.

Resolution:

2.10Å

R-factor:

0.202

R-free:

0.243

Authors:

P.J.Lupardus,A.Shen,M.Bogyo,K.C.Garcia

Key ref:

P.J.Lupardus et al. (2008). Small molecule-induced allosteric activation of the Vibrio cholerae RTX cysteine protease domain. Science, 322, 265-268. PubMed id: 18845756 DOI: 10.1126/science.1162403

Date:

04-Sep-08

Release date:

21-Oct-08

PROCHECK

	Headers

	References

Protein chains

Q9KS12 (MARTX_VIBCH) - Multifunctional-autoprocessing repeats-in-toxin from Vibrio cholerae serotype O1 (strain ATCC 39315 / El Tor Inaba N16961)

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:

Seq: Struc:					4558 a.a. 205 a.a.

Key:

PfamA domain

Secondary structure

CATH domain



		Enzyme reactions

Enzyme class 2:

E.C.2.3.1.- - ?????

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

Enzyme class 3:

E.C.3.4.22.- - ?????

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

Enzyme class 4:

E.C.6.3.2.- - ?????

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

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.

DOI no: 10.1126/science.1162403	Science 322:265-268 (2008)
PubMed id: 18845756

Small molecule-induced allosteric activation of the Vibrio cholerae RTX cysteine protease domain.
P.J.Lupardus, A.Shen, M.Bogyo, K.C.Garcia.

ABSTRACT

Vibrio cholerae RTX (repeats in toxin) is an actin-disrupting toxin that is autoprocessed by an internal cysteine protease domain (CPD). The RTX CPD is efficiently activated by the eukaryote-specific small molecule inositol hexakisphosphate (InsP6), and we present the 2.1 angstrom structure of the RTX CPD in complex with InsP6. InsP6 binds to a conserved basic cleft that is distant from the protease active site. Biochemical and kinetic analyses of CPD mutants indicate that InsP6 binding induces an allosteric switch that leads to the autoprocessing and intracellular release of toxin-effector domains.

Selected figure(s)



	Figure 2. Fig. 2. The InsP[6]-binding and active sites. (A) Electrostatic surface potential of the CPD as viewed from above the InsP[6]-binding site. Blue denotes a positively charged surface; red denotes a negatively charged surface. InsP[6] is shown in the binding site as a stick model. (B) Close-up view of the InsP[6]-binding site. Side chains that directly interact with InsP[6] are labeled and shown as yellow sticks. The electron density for InsP[6] (2F[obs] – F[calc]) is contoured at 2 . (C) Surface topology of the CPD active site. The P1 substrate pocket, C140, and H91 are highlighted in orange, yellow, and blue, respectively. The N terminus is shown as a yellow ribbon, terminating at Ile5 and highlighting the threading of this region along the surface of the core domain. The remaining residues not visible at the N terminus are depicted as a yellow dashed line to illustrate the approximate positioning of the chain during catalysis. (D) Close-up view of the P1 substrate pocket. Amino acids that line the pocket are labeled and colored orange. InsP[6] is shown as in (B) to demonstrate the position of the catalytic site with respect to the InsP[6]-binding site.		Figure 3. Fig. 3. β-Flap mutations decouple CPD autocatalysis and RTX activity from InsP[6] binding. (A) Comparison of autocleavage efficiency (AC[50]) versus InsP[6] binding (K[d]) measured by SPR for mutations in the InsP[6]-binding site (left table) and β-flap (right tables, top and bottom). The β-flap region of the CPD is rainbow-colored, starting with blue at the N-terminal end. The β-flap, catalytic site, and visible InsP[6]-interacting side chains are shown as sticks. Data are expressed as mean ± SD. ND, not determinable. (B) Western blot analysis of RTX in supernatant harvested from log-phase V. cholerae cultures. Supernatants from V. cholerae strains harboring either an intact rtxA gene (wt), a null mutation in rtxA ( rtxA), or point mutations in the region encoding the CPD domain of RTX (C140A is catalytic-dead; R182Q/K183N is mutated at two InsP[6]-binding residues; and W192A is a β-flap mutation) were blotted using an anti-CPD antibody. (C) Actin crosslinking induced upon incubation of V. cholerae with HFF cells. V. cholerae strains used in (A) were incubated with HFFs for 90 min, then the HFF cells were lysed. Actin crosslinking was visualized by SDS-PAGE and Western blotting by using an actin-specific antibody. The crosslinked forms of actin are labeled to the right.

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

22218294

E.Deu, M.Verdoes, and M.Bogyo (2012).
New approaches for dissecting protease functions to improve probe development and drug discovery.

Nat Struct Mol Biol, 19, 9.

23151626

S.S.Bhaskaran, and C.E.Stebbins (2012).
Structure of the catalytic domain of the Salmonella virulence factor SseI.

Acta Crystallogr D Biol Crystallogr, 68, 1613-1621.

PDB codes:

4g29 4g2b

21317893

A.Shen, P.J.Lupardus, M.M.Gersch, A.W.Puri, V.E.Albrow, K.C.Garcia, and M.Bogyo (2011).
Defining an allosteric circuit in the cysteine protease domain of Clostridium difficile toxins.

Nat Struct Mol Biol, 18, 364-371.

PDB code:

3pee

21310640

J.D.Durrant, and J.A.McCammon (2011).
BINANA: a novel algorithm for ligand-binding characterization.

J Mol Graph Model, 29, 888-893.

20539873

A.Shen (2010).
Allosteric regulation of protease activity by small molecules.

Mol Biosyst, 6, 1431-1443.

21095570

A.W.Puri, P.J.Lupardus, E.Deu, V.E.Albrow, K.C.Garcia, M.Bogyo, and A.Shen (2010).
Rational design of inhibitors and activity-based probes targeting Clostridium difficile virulence factor TcdB.

Chem Biol, 17, 1201-1211.

PDB code:

3pa8

20143368

C.Ottmann, P.Hauske, and M.Kaiser (2010).
Activation instead of inhibition: targeting proenzymes for small-molecule intervention.

Chembiochem, 11, 637-639.

20154666

J.A.Zorn, and J.A.Wells (2010).
Turning enzymes ON with small molecules.

Nat Chem Biol, 6, 179-188.

20811381

M.Drag, and G.S.Salvesen (2010).
Emerging principles in protease-based drug discovery.

Nat Rev Drug Discov, 9, 690-701.

20628577

M.Egerer, and K.J.Satchell (2010).
Inositol hexakisphosphate-induced autoprocessing of large bacterial protein toxins.

PLoS Pathog, 6, e1000942.

21095563

M.Gersch, and S.A.Sieber (2010).
Disarming Clostridium difficile.

Chem Biol, 17, 1165-1166.

19914276

P.W.Majerus, D.B.Wilson, C.Zhang, P.J.Nicholas, and M.P.Wilson (2010).
Expression of inositol 1,3,4-trisphosphate 5/6-kinase (ITPK1) and its role in neural tube defects.

Adv Enzyme Regul, 50, 365-372.

20017116

R.L.Rich, and D.G.Myszka (2010).
Grading the commercial optical biosensor literature-Class of 2008: 'The Mighty Binders'.

J Mol Recognit, 23, 1.

20430892

R.Mittal, S.Y.Peak-Chew, R.S.Sade, Y.Vallis, and H.T.McMahon (2010).
The acetyltransferase activity of the bacterial toxin YopJ of Yersinia is activated by eukaryotic host cell inositol hexakisphosphate.

J Biol Chem, 285, 19927-19934.

19278654

A.N.Bondar, C.del Val, and S.H.White (2009).
Rhomboid protease dynamics and lipid interactions.

Structure, 17, 395-405.

19956581

A.Shen, P.J.Lupardus, M.Morell, E.L.Ponder, A.M.Sadaghiani, K.C.Garcia, and M.Bogyo (2009).
Simplified, enhanced protein purification using an inducible, autoprocessing enzyme tag.

PLoS One, 4, e8119.

19465933

A.Shen, P.J.Lupardus, V.E.Albrow, A.Guzzetta, J.C.Powers, K.C.Garcia, and M.Bogyo (2009).
Mechanistic and structural insights into the proteolytic activation of Vibrio cholerae MARTX toxin.

Nat Chem Biol, 5, 469-478.

PDB code:

3gcd

19606820

A.W.Puri, and M.Bogyo (2009).
Using small molecules to dissect mechanisms of microbial pathogenesis.

ACS Chem Biol, 4, 603-616.

19679084

A.del Sol, C.J.Tsai, B.Ma, and R.Nussinov (2009).
The origin of allosteric functional modulation: multiple pre-existing pathways.

Structure, 17, 1042-1050.

19473994

C.Pop, and G.S.Salvesen (2009).
Human caspases: activation, specificity, and regulation.

J Biol Chem, 284, 21777-21781.

19892984

D.W.Wolan, J.A.Zorn, D.C.Gray, and J.A.Wells (2009).
Small-molecule activators of a proenzyme.

Science, 326, 853-858.

19434753

J.Pei, and N.V.Grishin (2009).
The Rho GTPase inactivation domain in Vibrio cholerae MARTX toxin has a circularly permuted papain-like thiol protease fold.

Proteins, 77, 413-419.

19309740

J.Pei, P.J.Lupardus, K.C.Garcia, and N.V.Grishin (2009).
CPDadh: a new peptidase family homologous to the cysteine protease domain in bacterial MARTX toxins.

Protein Sci, 18, 856-862.

19620709

K.Prochazkova, L.A.Shuvalova, G.Minasov, Z.Voburka, W.F.Anderson, and K.J.Satchell (2009).
Structural and molecular mechanism for autoprocessing of MARTX toxin of Vibrio cholerae at multiple sites.

J Biol Chem, 284, 26557-26568.

PDB code:

3fzy

19553670

R.N.Pruitt, B.Chagot, M.Cover, W.J.Chazin, B.Spiller, and D.B.Lacy (2009).
Structure-function analysis of inositol hexakisphosphate-induced autoprocessing in Clostridium difficile toxin A.

J Biol Chem, 284, 21934-21940.

PDB code:

3ho6

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.