Engineering of Cytolethal Distending Toxin B by Its Reducing Immunogenicity and Maintaining Stability as a New Drug Candidate for Tumor Therapy; an In Silico Study

The cytolethal distending toxin (CDT), , is one of the bacterial toxins that have recently been considered for targeted therapies, especially in cancer therapies. CDT is an A-B2 exotoxin. Its catalytic subunit (CdtB) is capable of inducing DNA double strand breaks, cell cycle arrest and apoptosis in...

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Veröffentlicht in:	Toxins 2021-11, Vol.13 (11), p.785
Hauptverfasser:	Keshtvarz, Maryam, Mahboobi, Mahdieh, Kieliszek, Marek, Miecznikowski, Antoni, Sedighian, Hamid, Rezaei, Milad, Haghighi, Mohammad Ali, Zareh, Zahra, Rezaei, Ehsan
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Sprache:	eng
Schlagworte:	Amino acid sequence Amino acids Antibodies Antigenicity Antineoplastic Agents - chemistry Apoptosis Bacterial Toxins - chemistry Bacterial Toxins - genetics Binding sites Cancer therapies Cell cycle Computer applications Computer Simulation Cytolethal distending toxin Deoxyribonuclease DNA damage Dynamic stability Epitopes Exotoxins Haemophilus ducreyi - chemistry Haemophilus ducreyi - genetics Homology Immune system Immunogenicity Immunosuppressive agents Immunotherapy Immunotoxins Kinases Lymphocytes Lymphocytes B Medical research Molecular dynamics Mutants Mutation Nuclease Nucleotide sequence Phosphatase Phosphorylation Prostate cancer Protein Engineering Proteins Residues stability Stability analysis Structural stability Toxicity Toxins tumor therapy Tumors
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creator	Keshtvarz, Maryam Mahboobi, Mahdieh Kieliszek, Marek Miecznikowski, Antoni Sedighian, Hamid Rezaei, Milad Haghighi, Mohammad Ali Zareh, Zahra Rezaei, Ehsan
description	The cytolethal distending toxin (CDT), , is one of the bacterial toxins that have recently been considered for targeted therapies, especially in cancer therapies. CDT is an A-B2 exotoxin. Its catalytic subunit (CdtB) is capable of inducing DNA double strand breaks, cell cycle arrest and apoptosis in host eukaryotic cells. The sequence alignment indicates that the CdtB is structurally homologyr to phosphatases and deoxyribonucleases I (DNase I). Recently, it has been found that CdtB toxicity is mainly related to its nuclease activity. The immunogenicity of CDT can reduce its effectiveness in targeted therapies. However, the toxin can be very useful if its immunogenicity is significantly reduced. Detecting hotspot ectopic residues by computational servers and then mutating them to eliminate B-cell epitopes is a promising approach to reduce the immunogenicity of foreign protein-based therapeutics. By the mentioned method, in this study, we try to reduce the immunogenicity of the CdtB- protein sequence. This study initially screened residue of the CdtB is B-cell epitopes both linearly and conformationally. By overlapping the B-cell epitopes with the excluded conserve residues, and active and enzymatic sites, four residues were allowed to be mutated. There were two mutein options that show reduced antigenicity probability. Option one was N19F, G74I, and S161F with a VaxiJen score of 0.45 and the immune epitope database (IEDB) score of 1.80, and option two was N19F, G74I, and S161W with a VaxiJen score of 0.45 and IEDB score of 1.88. The 3D structure of the proposed sequences was evaluated and refined. The structural stability of native and mutant proteins was accessed through molecular dynamic simulation. The results showed that the mutations in the mutants caused no considerable changes in their structural stability. However, mutant 1 reveals more thermodynamic stability during the simulation. The applied approaches in this study can be used as rough guidelines for finding hot spot immunogen regions in the therapeutic proteins. Our results provide a new version of CdtB that, due to reduced immunogenicity and increased stability, can be used in toxin-based drugs such as immunotoxins.
doi_str_mv	10.3390/toxins13110785
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CDT is an A-B2 exotoxin. Its catalytic subunit (CdtB) is capable of inducing DNA double strand breaks, cell cycle arrest and apoptosis in host eukaryotic cells. The sequence alignment indicates that the CdtB is structurally homologyr to phosphatases and deoxyribonucleases I (DNase I). Recently, it has been found that CdtB toxicity is mainly related to its nuclease activity. The immunogenicity of CDT can reduce its effectiveness in targeted therapies. However, the toxin can be very useful if its immunogenicity is significantly reduced. Detecting hotspot ectopic residues by computational servers and then mutating them to eliminate B-cell epitopes is a promising approach to reduce the immunogenicity of foreign protein-based therapeutics. By the mentioned method, in this study, we try to reduce the immunogenicity of the CdtB- protein sequence. This study initially screened residue of the CdtB is B-cell epitopes both linearly and conformationally. By overlapping the B-cell epitopes with the excluded conserve residues, and active and enzymatic sites, four residues were allowed to be mutated. There were two mutein options that show reduced antigenicity probability. Option one was N19F, G74I, and S161F with a VaxiJen score of 0.45 and the immune epitope database (IEDB) score of 1.80, and option two was N19F, G74I, and S161W with a VaxiJen score of 0.45 and IEDB score of 1.88. The 3D structure of the proposed sequences was evaluated and refined. The structural stability of native and mutant proteins was accessed through molecular dynamic simulation. The results showed that the mutations in the mutants caused no considerable changes in their structural stability. However, mutant 1 reveals more thermodynamic stability during the simulation. The applied approaches in this study can be used as rough guidelines for finding hot spot immunogen regions in the therapeutic proteins. 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CDT is an A-B2 exotoxin. Its catalytic subunit (CdtB) is capable of inducing DNA double strand breaks, cell cycle arrest and apoptosis in host eukaryotic cells. The sequence alignment indicates that the CdtB is structurally homologyr to phosphatases and deoxyribonucleases I (DNase I). Recently, it has been found that CdtB toxicity is mainly related to its nuclease activity. The immunogenicity of CDT can reduce its effectiveness in targeted therapies. However, the toxin can be very useful if its immunogenicity is significantly reduced. Detecting hotspot ectopic residues by computational servers and then mutating them to eliminate B-cell epitopes is a promising approach to reduce the immunogenicity of foreign protein-based therapeutics. By the mentioned method, in this study, we try to reduce the immunogenicity of the CdtB- protein sequence. This study initially screened residue of the CdtB is B-cell epitopes both linearly and conformationally. 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subjects	Amino acid sequence Amino acids Antibodies Antigenicity Antineoplastic Agents - chemistry Apoptosis Bacterial Toxins - chemistry Bacterial Toxins - genetics Binding sites Cancer therapies Cell cycle Computer applications Computer Simulation Cytolethal distending toxin Deoxyribonuclease DNA damage Dynamic stability Epitopes Exotoxins Haemophilus ducreyi - chemistry Haemophilus ducreyi - genetics Homology Immune system Immunogenicity Immunosuppressive agents Immunotherapy Immunotoxins Kinases Lymphocytes Lymphocytes B Medical research Molecular dynamics Mutants Mutation Nuclease Nucleotide sequence Phosphatase Phosphorylation Prostate cancer Protein Engineering Proteins Residues stability Stability analysis Structural stability Toxicity Toxins tumor therapy Tumors
title	Engineering of Cytolethal Distending Toxin B by Its Reducing Immunogenicity and Maintaining Stability as a New Drug Candidate for Tumor Therapy; an In Silico Study
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