Comparative evaluation of antimicrobial activity of human granulysin, bovine and porcine NK-lysins against Shiga toxin-producing Escherichia coli O157:H7

Biernbaum, Erika N.; Dassanayake, Rohana P.; Nicholson, Eric M.; Kudva, Indira T.

doi:10.1371/journal.pone.0292234

Cited by 2 publications

(1 citation statement)

References 36 publications

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“…New therapeutic approaches and strategies have recently been developed to manage STEC infections in recent years. For example, therapeutic peptides interfere with intracellular Stx trafficking and successfully prevent Stx2 toxicity (Rahal et al 2015), (Biernbaum et al 2023;Li et al 2016;Lino et al 2011;Prada-Prada et al 2020;Stearns-Kurosawa et al 2011;Watanabe-Takahashi et al 2021). For example, Ac-PPP-tet and TVP contain four Pro-Pro-Pro-Arg-Arg-Arg-Arg motifs.…”

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confidence: 99%

Structural basis to identify a target site in Shiga toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

Prabhudesai,

Shaikh,

Ashwinbhai

et al. 2024

Bull Natl Res Cent

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Background Certain peptides that bind Shiga toxin 2 (Stx2) have been reported to treat Shiga toxin-producing Escherichia coli (STEC) infections. However, their mechanisms of action remain unknown. STEC infections lead to serious diseases, such as hemolytic uremic syndrome, in humans. Antibiotic therapy is usually not recommended because of the major challenges of antibiotic resistance and SOS repair. Currently, there is no human vaccine for STEC infection, leaving rehydration therapy as the recommended supportive therapy. Therefore, there is a need for targeted therapeutic intervention to inhibit STEC growth. The purpose of this study was to evaluate the interaction of five known peptides with Stx2 to identify a more suitable peptide based on structural changes. These peptides have been used to inhibit the growth of STEC. Results The current study demonstrated that only tetravalent peptide (TVP) out of 5 common peptides interrupted the Y77-E259 interaction of Stx2, making it active by exposing active site, which ultimately leads to STEC cell death. We also demonstrated that amino acids R170 and F171 of Stx2 in the docked complex of Stx2 and TVP form a helix-loop-helix (HLH). This might lead to the differential expression of genes regulated by Stx2 and ultimately inhibit STEC growth. However, in the case of Stx2-ribosomal P-stalk, these residues did not form HLH. The 3D refined model of TVP showed a low MolProbity score and low energy zones in the ANOLEA profile compared to the original one. Moreover, the low radius of gyration of the refined TVP suggests that it is more compact than the original TVP. Therefore, TVP is a suitable drug candidate for the inhibition of STEC growth. However, the low antigenicity of TVP makes it unsuitable as a drug candidate. We also evaluated three antibiotics that have been used as active ingredients in FDA-approved peptides. Only Oritavancin diphosphate showed strong polar interactions with Y77-E259 and also had the highest binding affinity. Conclusions Potential drug candidates that inhibit or interrupt the interaction between Y77-E259 and have high antigenicity, low toxicity, and no allergenicity should be explored against the growth of STEC.

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confidence: 99%

Structural basis to identify a target site in Shiga toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

Prabhudesai,

Shaikh,

Ashwinbhai

et al. 2024

Bull Natl Res Cent

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Structural basis to identify a target site in Shiga-toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

Prabhudesai,

Shaikh,

Ashwinbhai

et al. 2023

Preprint

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Background: Certain peptides that can bind to Shiga toxin 2 (Stx2) have been reported to treat Shiga toxin-producing E. coli (STEC) infections. However, their mechanisms of action remain unknown. We used the PEP-FOLD server to predict the 3-D structure of the five peptides that have been used against STEC growth. The modelled structures were docked with Stx2 using ClusPro server. The physiochemical properties of therapeutic peptides were computed using the ‘peptides’ package of the RStudio and ProtParam tool. Results:Of these five therapeutic peptides, one tetravalent peptide (TVP) was shortlisted based on its interaction with the active sites of Stx2. The structure of stx2-TVP complex was evaluated using the ERRAT, iMODS, and Procheck servers. The 3D refined model of TVP was generated using Galaxyserver and evaluated using ERRAT, ANOLEA, and QMEAN. PyMOL was used to visualize the docking complexes. The current study demonstrated that blocking Y77-E259 and Y114-E167 interactions is required to inhibit STEC growth. Of the five therapeutic peptides used in this study, only MAPPPRRRRA (TVP) blocked the interaction between Y77 and E259 residues of the A1 subunit of Stx2, making it active and ultimately leading to STEC cell death. However, all therapeutic peptides showed strong polar interactions with Y77 and E259, but they did not block the Y77-E259 or Y114-E167 interactions. We also demonstrated that helix-loop-helix formation near the ribosome-binding site of Stx2 might lead to the differential gene expression regulated by Stx2. The 3D refined model of TVP showed a positive G-factor, high QMEAN score, low MolProbity score, and low energy zones in the ANOLEA profile compared to original TVP. Moreover, the low radius of gyration in the refined TVP during the molecular simulation suggests that it is more compact than the original TVP. However, the low antigenicity of TVP makes it an unsuitable drug candidate. We also evaluated three antibiotics that have been used as active ingredients in FDA-approved peptides. Only Oritavancin diphosphate showed strong polar interactions with Y77-E259 and also had the highest binding affinity. Conclusions: This study identified a new target (Y77-E259) for inhibitor discovery against STEC growth.

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Comparative evaluation of antimicrobial activity of human granulysin, bovine and porcine NK-lysins against Shiga toxin-producing Escherichia coli O157:H7

Cited by 2 publications

References 36 publications

Structural basis to identify a target site in Shiga toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

Structural basis to identify a target site in Shiga toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

Structural basis to identify a target site in Shiga-toxin for the inhibitor discovery against growth of Shiga toxin-producing E. coli

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