Cryo-EM structure of aerolysin variants reveals a novel protein fold and the pore-formation process

Iacovache, Ioan; Carlo, Sacha De; Cirauqui, Nuria; Peraro, Matteo Dal; Goot, F. Gisou van der; Zuber, Benoît

doi:10.1038/ncomms12062

Cited by 161 publications

(187 citation statements)

References 43 publications

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“…The secondary structure is pervasive in oligonucleotides, which is essential for constituting the functional domain toward the binding and recognition. Due to the extremely narrow diameter (≈1 nm), the aerolysin only offers the possibility to squeeze a linear oligonucleotide into its lumen, however, it cannot accommodate a structured oligonucleotide with large volume. Compared with the widely applied α‐hemolysin, the aerolysin lacks a wide vestibule which permits the unfolding of a structured oligonucleotide for the successive translocation through the narrowest constriction.…”

Section: Statistical Results Of the Duration And The I/i0 For Teln (Nmentioning

confidence: 99%

A General Strategy of Aerolysin Nanopore Detection for Oligonucleotides with the Secondary Structure

Liao

Cao

Ying

et al. 2018

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An aerolysin nanopore is employed as a sensitive tool for single-molecule analysis of short oligonucleotides (≤10 nucleotides), poly(ethylene glycol) (PEGs), peptides, and proteins. However, the direct analysis of long oligonucleotides with the secondary structure (e.g., G-quadruplex topology) remains a challenge, which impedes the further practical applications of the aerolysin nanopore. Here, a simple and applicable method of aerolysin nanopore is presented to achieve a direct analysis of structured oligonucleotides that are extended to 30 nucleotides long by a cation-regulation mechanism. By regulating the cation type in electrolyte solution, the structured oligonucleotides are unfolded into linear form which ensures the successive translocation. The results show that each model oligonucleotide of 5'-(TTAGGG) -3' can produce a well-resolved current blockade in its unfolded solution of MgCl . The length between 6 and 30 nucleotides long of model oligonucleotides is proportional to the duration time, showing a translocation velocity as low as 0.70-0.13 ms nt at +140 mV. This method exhibits an excellent sensitivity and a sufficient temporal resolution, provides insight into the aerolysin nanopore methodology for genetic and epigenetic biosensing, making aerolysin applicable in practical diagnosing with long and structured nucleic acids.

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Section: Statistical Results Of the Duration And The I/i0 For Teln (Nmentioning

confidence: 99%

A General Strategy of Aerolysin Nanopore Detection for Oligonucleotides with the Secondary Structure

Liao

Cao

Ying

et al. 2018

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“…They are the founding members of a large superfamily (β‐PTFs) that span all the kingdom of life (Szczesny et al, ). Studies on cryo‐electron microscopy showed that the bacterial PFTs are generally secreted as water soluble monomers and binds with target membranes and assemble into the circular oligomers, which undergoes the conformational changes that allow membrane insertion leading to pore formation and finally potential cell death (Iacovache et al, ). In the present study, the strain Ah17 harbors both aerolysin ( aer ) and hemolysin ( hly ) genes and the presence of these genes evidently supports the pathogenic nature of A. hydrophila Ah17.…”

Section: Discussionmentioning

confidence: 99%

Identification and characterization of virulent Aeromonas hydrophila Ah17 from infected Channa striata in river Cauvery and in vitro evaluation of shrimp chitosan

Samayanpaulraj

Sivaramapillai

Palani

et al. 2020

Food Science & Nutrition

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Aeromonas hydrophila, an inhabitant in the aquatic ecosystem is considered as an important foodborne bacterial zoonotic pathogen in aquaculture. The present study aimed to identify virulent A. hydrophila from naturally infected Channa striata in river Cauvery and in vitro evaluation of shrimp chitosan. Rimler Shotts (RS) and blood agar medium identified the presence of pathogenic Aeromonas sp. from the infected C. striata. A. hydrophila Ah17 was identified using 16S rRNA nucleotide sequence. Extracellular enzymes such as amylase, lipase, and protease were screened in A. hydrophila Ah17. Antibiotic susceptibility tests showed A. hydrophila Ah17 was highly resistant against β‐lactam, glycopeptide, macrolides, phosphonic, fucidin, and oxazolidinone classes of antibiotics. Virulent genes such as hemolysin (aer and hly), heat‐labile enterotoxin (act), cytotonic heat‐stable enterotoxin (ast), elastase (ahyB), and lipase (lip) were identified. Growth and the viable cell population of virulent A. hydrophila Ah17 were significantly reduced in a dose‐dependent manner against shrimp chitosan (CHS) from Penaeus indicus (P. indicus). Thus, the present study isolated virulent A. hydrophila Ah17 from the environmental source and characterized in vitro with shrimp chitosan.

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“…1a and b). 19,20 Molecular dynamics simulations on a 10 2 ns timescale were stable for both wild-type and Y221G mutant pro-aeroly-sins. After refinement using a molecular dynamics flexible fitting procedure, the best heptameric model had a cross-correlation coefficient with the cryo-EM map of 0.79.…”

Section: Arp Structurementioning

confidence: 96%

“…The aerolysin prepore goes through several conformational changes like initial rearrangements, oligomerization, the concentric barrel fold, tightly bound together by hydrophobic interactions, and then forms the final ARP with a β-barrel length of ~87 Å and a diameter of ~8.75 Å (average distance between the opposite strand backbone). 19 Structurally, the ARP has multiple charged residues in its channel wall, particularly around both openings to the pore. Negatively charged residues include E237, E252, E254, and E258 near the trans ARP entrance, and D209, D216 near the cis entrance, while positive charges contributed by K238, K242, K244, and K246 localize towards the trans barrel, while charges from R220, R282, and R288 cluster around the cis entrance.…”

Section: Arp Structurementioning

confidence: 99%

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The aerolysin nanopore: from peptidomic to genomic applications

Wang

Tian

2018

Nanoscale

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The aerolysin pore (ARP) is a newly emerging nanopore that has been extensively used for peptide and protein sensing. Recently, several groups have explored the application of ARP in detecting genetic and epigenetic markers. This brief review summarizes the current applications of ARP, progressing from peptidomic to genomic detection; the recently reported site-directed mutagenesis of ARP; and new genomic DNA sensing approaches, and their advantages and disadvantages. This review will also discuss the perspectives and future applications of ARP for nucleic acid sequencing and biomolecule sensing.

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Cryo-EM structure of aerolysin variants reveals a novel protein fold and the pore-formation process

Cited by 161 publications

References 43 publications

A General Strategy of Aerolysin Nanopore Detection for Oligonucleotides with the Secondary Structure

A General Strategy of Aerolysin Nanopore Detection for Oligonucleotides with the Secondary Structure

Identification and characterization of virulent Aeromonas hydrophila Ah17 from infected Channa striata in river Cauvery and in vitro evaluation of shrimp chitosan

The aerolysin nanopore: from peptidomic to genomic applications

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