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Main Authors: Michira, Brenda B, Wang, Yi, Mwangi, James, Wang, Kexin, Asmamaw, Demeke, Tadese, Dawit Adisu, Gao, Jinai, Khalid, Mehwish, Lu, Qiu-Min, Lai, Ren, Li, Juan
Format: Artículo científico
Language:en
Published: Microorganisms 2024
Online Access:https://pubmed.ncbi.nlm.nih.gov/39770850/
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author Michira, Brenda B
Wang, Yi
Mwangi, James
Wang, Kexin
Asmamaw, Demeke
Tadese, Dawit Adisu
Gao, Jinai
Khalid, Mehwish
Lu, Qiu-Min
Lai, Ren
Li, Juan
author_facet Michira, Brenda B
Wang, Yi
Mwangi, James
Wang, Kexin
Asmamaw, Demeke
Tadese, Dawit Adisu
Gao, Jinai
Khalid, Mehwish
Lu, Qiu-Min
Lai, Ren
Li, Juan
Michira, Brenda B
Wang, Yi
Mwangi, James
Wang, Kexin
Asmamaw, Demeke
Tadese, Dawit Adisu
Gao, Jinai
Khalid, Mehwish
Lu, Qiu-Min
Lai, Ren
Li, Juan
collection PubMed - marine biology
contents A Tachyplesin Antimicrobial Peptide from Theraphosidae Spiders with Potent Antifungal Activity Against . Michira, Brenda B Wang, Yi Mwangi, James Wang, Kexin Asmamaw, Demeke Tadese, Dawit Adisu Gao, Jinai Khalid, Mehwish Lu, Qiu-Min Lai, Ren Li, Juan The venoms of Theraphosidae spiders have evolved into diverse natural pharmacopeias through selective pressures. is a global health threat that frequently causes life-threatening meningitis and fungemia, particularly in immunocompromised patients. In this study, we identify a novel anti- peptide, QS18 (QCFKVCFRKRCFTKCSRS), from the venom gland of China's native spider species by utilizing bioinformatic tools. QS18 shares over 50% sequence similarity with tachyplesin peptides, previously identified only in horseshoe crab hemocytes, expanding the known repertoire of the tachyplesin family to terrestrial arachnids. The oxidative folding of QS18 notably enhances its antifungal activity and stability, resulting in a minimum inhibitory concentration of 1.4 µM. The antimicrobial mechanism of QS18 involves cell membrane disruption. QS18 exhibits less than 5% hemolysis in human erythrocytes, indicating microbial selectivity and a favorable safety profile for therapeutic use. Furthermore, mouse model studies highlight QS18's ability as an antifungal agent with notable anti-inflammatory activity. Our study demonstrates QS18 as both a promising template for spider venom peptide research and a novel candidate for the development of peptide antifungals.
format Artículo científico
id pubmed_39770850
institution PubMed
language en
publishDate 2024
publisher Microorganisms
record_format pubmed
spellingShingle A Tachyplesin Antimicrobial Peptide from Theraphosidae Spiders with Potent Antifungal Activity Against .
Michira, Brenda B
Wang, Yi
Mwangi, James
Wang, Kexin
Asmamaw, Demeke
Tadese, Dawit Adisu
Gao, Jinai
Khalid, Mehwish
Lu, Qiu-Min
Lai, Ren
Li, Juan
A Tachyplesin Antimicrobial Peptide from Theraphosidae Spiders with Potent Antifungal Activity Against . Michira, Brenda B Wang, Yi Mwangi, James Wang, Kexin Asmamaw, Demeke Tadese, Dawit Adisu Gao, Jinai Khalid, Mehwish Lu, Qiu-Min Lai, Ren Li, Juan The venoms of Theraphosidae spiders have evolved into diverse natural pharmacopeias through selective pressures. is a global health threat that frequently causes life-threatening meningitis and fungemia, particularly in immunocompromised patients. In this study, we identify a novel anti- peptide, QS18 (QCFKVCFRKRCFTKCSRS), from the venom gland of China's native spider species by utilizing bioinformatic tools. QS18 shares over 50% sequence similarity with tachyplesin peptides, previously identified only in horseshoe crab hemocytes, expanding the known repertoire of the tachyplesin family to terrestrial arachnids. The oxidative folding of QS18 notably enhances its antifungal activity and stability, resulting in a minimum inhibitory concentration of 1.4 µM. The antimicrobial mechanism of QS18 involves cell membrane disruption. QS18 exhibits less than 5% hemolysis in human erythrocytes, indicating microbial selectivity and a favorable safety profile for therapeutic use. Furthermore, mouse model studies highlight QS18's ability as an antifungal agent with notable anti-inflammatory activity. Our study demonstrates QS18 as both a promising template for spider venom peptide research and a novel candidate for the development of peptide antifungals.
title A Tachyplesin Antimicrobial Peptide from Theraphosidae Spiders with Potent Antifungal Activity Against .
url https://pubmed.ncbi.nlm.nih.gov/39770850/