Model of the Toxic Complex of Anthrax: Responsive Conformational Changes in Both the Lethal Factor and the Protective Antigen Heptamer

Overview

Journal Protein Sci

Specialty Biochemistry

Date 2006 Sep 1

PMID 16943448

Citations 15

Authors

Florence Tama

Gang Ren

Charles L Brooks 3rd

Alok K Mitra

Affiliations

Soon will be listed here.

Abstract

The toxic complex of anthrax is formed when the monomeric protective antigen (PA) (83 kDa), while bound to its cell-surface receptor, is first converted to PA63 heptamers (PA63h) following N-terminal proteolytic cleavage, and then lethal (LF) (90 kDa) or edema factor (EF) binds to the heptamer. We report a "pseudoatomic" model for the complex of PA63h and full-length LF determined by applying the normal-mode flexible fitting procedure to a approximately 18 A cryo-electron microscopy (EM) density map of the complex. The model describes the interacting surface that buries a total area of approximately 10,140 A2 comprising approximately 40% charged, and approximately 30% each of polar and hydrophobic residues. For the heptamer, the buried surface, composed of approximately 110 residues, involves primarily three monomers and includes for two, similar stretches of the polypeptide chain from domain 1. For LF, the interface again involves approximately 110 residues, mostly from the N-terminal domain I (LF(N)), and the structurally homologous C-terminal domain IV. Most interestingly, bound LF displays a marked conformational change resulting from a "collapse" of domains I, III, and IV on domain II, with the largest movement of approximately 9 A noted for domain I. On the other hand, primarily, rigid-body movements, larger than approximately 10 A for three PA63 monomers, cause the hourglass-shaped heptamer lumen to enlarge by as much as approximately 50% near the middle of the molecule. Such concerted structural rearrangements in LF and the heptamer can facilitate ingress of the ligand into the heptamer lumen prior to unfolding and release through the PA63h channel formed in the acidic late endosomal membrane.

Citing Articles

Cryo-EM structure of the fully-loaded asymmetric anthrax lethal toxin in its heptameric pre-pore state.

Antoni C, Quentin D, Lang A, Aktories K, Gatsogiannis C, Raunser S PLoS Pathog. 2020; 16(8):e1008530.

PMID: 32810181 PMC: 7462287. DOI: 10.1371/journal.ppat.1008530.

Structure of anthrax lethal toxin prepore complex suggests a pathway for efficient cell entry.

Fabre L, Santelli E, Mountassif D, Donoghue A, Biswas A, Blunck R J Gen Physiol. 2016; 148(4):313-24.

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Collective variable approaches for single molecule flexible fitting and enhanced sampling.

Vashisth H, Skiniotis G, Brooks 3rd C Chem Rev. 2014; 114(6):3353-65.

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Conformational States of macromolecular assemblies explored by integrative structure calculation.

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