A conserved motif in transmembrane helix 1 of diphtheria toxin mediates catalytic domain delivery to the cytosol

Ratts, Ryan; Trujillo, Carolina; Bharti, Ajit; vanderSpek, Johanna C.; Harrison, Robert J.; Murphy, John R.

doi:10.1073/pnas.0504937102

Cited by 48 publications

(64 citation statements)

References 36 publications

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“…However, exactly how T domain assists translocation is unclear. Furthermore, translocation may be aided by cytoplasmic factors (25,26) Defining the structure of the membrane-inserted T domain is likely to provide insights into the mechanism of A chain translocation. The T domain is primarily comprised of 9 α-helices (TH1-9).…”

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confidence: 99%

Topography of the Hydrophilic Helices of Membrane-Inserted Diphtheria Toxin T Domain: TH1−TH3 as a Hydrophilic Tether

2006

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After low pH-triggered membrane insertion, the T domain of diphtheria toxin helps translocate the catalytic domain of the toxin across membranes. In this study the hydrophilic N-terminal helices of the T domain (TH1-TH3) were studied. Both the changes in conformation triggered by exposure to low pH and topography upon membrane insertion were studied. These experiments involved bimane or BODIPY labeling of single Cys introduced at various positions, followed by measurement of bimane emission wavelength, bimane exposure to fluorescence quenchers, and antibody binding to BODIPY groups. Upon exposure of T domain in solution to low pH it was found that the hydrophobic face of TH1, which is buried in the native state at neutral pH, became exposed to solution. When T domain was added externally to lipid vesicles at low pH, the hydrophobic face of TH1 became buried within the lipid bilayer. Helices TH2 and TH3 also inserted into the bilayer after exposure to low pH. However, in contrast to helices TH5-TH9, overall TH1-3 insertion was shallow and there was no significant change in TH1-TH3 insertion depth when the T domain switched from the shallowlyinserting (P) to deeply-inserting (TM) conformation. Binding of streptavidin to biotinylated Cys residues was used to investigate whether solution-exposed residues of membrane-inserted T domain were exposed on the external or internal surface of the bilayer. These experiments showed that when T domain is externally added to vesicles, the entire TH1-TH3 segment remains on the cis (outer) side of the bilayer. The results of this study suggest that membrane-inserted TH 1-3 form autonomous segments that neither deeply penetrate the bilayer nor interact tightly with translocation-promoting structure formed by the hydrophobic TH 5-9 sub-domain. Instead, TH1-3 may aid translocation by acting as an A chain-attached flexible tether.Diphtheria toxin (DT), a cytotoxic protein with 535 amino acid residues, is secreted by pathogenic strains of Corynebacterium diphtheriae. The three-dimensional structure of DT in solution at neutral pH was first solved by Choe et al. (4). This study showed that the toxin consists of a catalytic domain (C), a membrane-inserting translocation domain (T) and a receptor-binding domain (R). The protein is secreted as a single polypeptide chain and is then cleaved at residue 193 between the C and T domains by a protease, likely furin, to create an active form (5,6). This cleavage event yields a N-terminal A chain (equivalent to the catalytic domain) linked by a disulfide bond to a C-terminal B chain composed of the T and R domains.The killing action of DT involves several distinct steps. The first steps involve binding to a receptor (a membrane-anchored version of a heparin-binding epidermal-growth-factor-like protein (7)) on the surface of sensitive cells and subsequent receptor-mediated endocytosis. Translocation of the A chain of the toxin across the endosomal membrane and into the

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confidence: 99%

Topography of the Hydrophilic Helices of Membrane-Inserted Diphtheria Toxin T Domain: TH1−TH3 as a Hydrophilic Tether

2006

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“…The peptide TQIENLKEKG was identified by Ratts et al (2005) as a conserved 10 amino acid motif in several bacterial toxins, e.g., diphtheria toxin, anthrax edema factor, anthrax lethal factor, and botulinum toxins. This motif is part of a transmembrane helix within the toxin that facilitates translocation of the respective catalytic domains from transport vesicles into the cytoplasm where the toxin exerts its harmful effects (Falnes and Sandvig 2000).…”

Section: Introductionmentioning

confidence: 99%

Increased RNAi is related to intracellular release of siRNA via a covalently attached signal peptide

Detzer¹,

Overhoff²,

Wünsche³

et al. 2009

RNA

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In the last decade short interfering RNA (siRNA) became an important means for functional genomics and the development of gene-specific drugs. However, major technical hurdles in the application of siRNA include its cellular delivery followed by its intracellular trafficking and its release in order to enter the RNA interference (RNAi) machinery. The novel phosphorothioatestimulated cellular uptake of siRNA contrasts other known delivery systems because it involves a caveosomal pathway in which large amounts of siRNA are delivered to the perinuclear environment, leading to measurable though moderate target suppression. Limited efficacy seems to be related to intracellular trapping of siRNA. To study the role of intracellular trafficking of siRNA for biological effectiveness we studied whether a signal peptide for trans-membrane transport of bacterial protein toxins, which is covalently attached to siRNA, can promote its release from the perinuclear space into the cytoplasm and thereby enhance its biological effectiveness. We show that attachment of the peptide TQIENLKEKG to lamin A/C-directed siRNA improves target inhibition after its PS-stimulated delivery. This is related to increased efflux of the siRNA-peptide conjugate from the ER-specific perinuclear sites. In summary, this study strongly suggests that intracellular release of siRNA leads to increased biological effectiveness. Thus covalent peptide-siRNA conjugates are proposed as new tools to study the relationship between intracellular transport and efficacy of siRNA.

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“…This charge-state Brownian ratchet mechanism would be reinforced by the refolding of translocated segments into structures too large to fit back into the channel [14]. This model is sufficient to explain the translocation process without the requirement of mammalian accessory factors, although it is possible that cytosolic factors facilitate the process in vivo, as has been observed for other toxins [16].…”

Section: Translocationmentioning

confidence: 93%

Defensive strategies of Bacillus anthracis that promote a fatal disease

Mogridge

2007

Drug Discovery Today: Disease Mechanisms

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Bacillus anthracis is a Gram-positive bacterium that causes anthrax. Bacterial spores that enter the host germinate into metabolically active bacilli that disseminate throughout the body and replicate to high numbers. Two virulence factors are essential for this unrestrained growth. The first is a weakly immunogenic poly γ-D-glutamic acid capsule that surrounds the bacilli and confers resistance to phagocytosis. The second virulence factor, anthrax toxin, disrupts multiple host functions to diminish the immune response.

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A conserved motif in transmembrane helix 1 of diphtheria toxin mediates catalytic domain delivery to the cytosol

Cited by 48 publications

References 36 publications

Topography of the Hydrophilic Helices of Membrane-Inserted Diphtheria Toxin T Domain: TH1−TH3 as a Hydrophilic Tether

Topography of the Hydrophilic Helices of Membrane-Inserted Diphtheria Toxin T Domain: TH1−TH3 as a Hydrophilic Tether

Increased RNAi is related to intracellular release of siRNA via a covalently attached signal peptide

Defensive strategies of Bacillus anthracis that promote a fatal disease

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