toxin complex
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2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Ea Kristine Clarisse Tulin ◽  
Chiaki Nakazawa ◽  
Tomomi Nakamura ◽  
Shion Saito ◽  
Naoki Ohzono ◽  
...  

AbstractLectins are proteins with the ability to recognize and bind to specific glycan structures. These molecules play important roles in many biological systems and are actively being studied because of their ability to detect glycan biomarkers for many diseases. Hemagglutinin (HA) proteins from Clostridium botulinum type C neurotoxin complex; HA1, HA2, and HA3 are lectins that aid in the internalization of the toxin complex by binding to glycoproteins on the cell surface. HA1 mutants have been previously reported, namely HA1 W176A/D271F and HA1 N278A/Q279A which are specific to galactose (Gal)/N-acetylgalactosamine (GalNAc) and N-acetylneuraminic acid (Neu5Ac) sugars, respectively. In this study, we utilized HA1 mutants and expressed them in complex with HA2 WT and HA3 WT to produce glycan detecting tools with high binding affinity. Particularly, two types were made: Gg and Rn. Gg is an Alexa 488 conjugated lectin complex specific to Gal and GalNAc, while Rn is an Alexa 594 conjugated lectin complex specific to Neu5Ac. The specificities of these lectins were identified using a glycan microarray followed by competitive sugar inhibition experiments on cells. In addition, we confirmed that Gg and Rn staining is clearly different depending on cell type, and the staining pattern of these lectins reflects the glycans present on the cell surface as shown in enzyme treatment experiments. The availability of Gg and Rn provide us with new promising tools to study Gal, GalNAc, and Neu5Ac terminal epitopes which can aid in understanding the functional role of glycans in physiological and pathological events.


2021 ◽  
Author(s):  
Akihiro Kawamoto ◽  
Tomohito Yamada ◽  
Toru Yoshida ◽  
Takayuki Kato ◽  
Hideaki Tsuge

Abstract Besides two large cytotoxins (TcdA and TcdB), certain Clostridioides difficile strains also produce a binary toxin, called C. difficile toxin (CDT) composed of an enzymatic subunit involved in actin ADP-ribosylation (CDTa) and translocation pore (CDTb) that delivers CDTa into host cells through receptor-mediated endocytosis. CDTb is proposed to be a di-heptamer, but its physiological heptameric structure has not been reported to date. Here, we report the CDTa-bound CDTb-pore (heptamer) as a physiological complexes using cryo-EM. The high-resolution structure of the CDTa-bound CDTb-pore at 2.56-Å resolution revealed that CDTa binding to CDTb-pore induces partial unfolding and tilting of the first CDTa a-helix, and the translocation. In the CDTb-pore, the NSS-loop exists in “in” and “out” conformations, suggesting their involvement in substrate translocation through formation of weak, non-specific interactions. This structural information provides insights into drug design against hypervirulent C. difficile strains.


Author(s):  
Ihda Zuyina Ratna Sari ◽  
Silvia Apriliana

Anthrax is a neglected zoonotic disease that remains a global issue because it can cause regular epidemics. Anthrax affects not only health systems but also social-economic conditions, safety, and welfare of the people. This paper aimed to give an overview of human anthrax, prevalence, and prevention in Indonesia. A literature search was performed using search engines such as Google Scholar, Crossref, Mendeley, PLoS One, Elsevier, dan the Ministry of Health official website. The literature used were published between 2015-2020. Anthrax is caused by Bacillus anthracis that affects animals and humans. The virulence factors of these bacteria are determined by the tripartite toxin complex and poly-γ-D-glutamic acid capsule. Anthrax in humans can be found in four forms, namely cutaneous, gastrointestinal, inhalational, and injection anthrax. Each form of anthrax can develop into meningitis and sepsis. Anthrax treatment is commonly done by administering antibiotics. In Indonesia, 14 provinces have been declared anthrax endemic areas. The prevalence of human anthrax in Indonesia is fluctuating and most of it is cutaneous anthrax. Prevention and control of anthrax can be done mainly by vaccination, obeying the rules or standard operating procedures of the authorities, multisectoral cooperation, strengthening anthrax surveillance, increasing resources for diagnosis, increasing public knowledge, and awareness.


2020 ◽  
Vol 27 (3) ◽  
pp. 288-296 ◽  
Author(s):  
Tomohito Yamada ◽  
Toru Yoshida ◽  
Akihiro Kawamoto ◽  
Kaoru Mitsuoka ◽  
Kenji Iwasaki ◽  
...  
Keyword(s):  

Toxins ◽  
2019 ◽  
Vol 12 (1) ◽  
pp. 19 ◽  
Author(s):  
Maria B. Nowakowska ◽  
François P. Douillard ◽  
Miia Lindström

The botulinum neurotoxin (BoNT) has been extensively researched over the years in regard to its structure, mode of action, and applications. Nevertheless, the biological roles of four proteins encoded from a number of BoNT gene clusters, i.e., OrfX1-3 and P47, are unknown. Here, we investigated the diversity of orfX-p47 gene clusters using in silico analytical tools. We show that the orfX-p47 cluster was not only present in the genomes of BoNT-producing bacteria but also in a substantially wider range of bacterial species across the bacterial phylogenetic tree. Remarkably, the orfX-p47 cluster was consistently located in proximity to genes coding for various toxins, suggesting that OrfX1-3 and P47 may have a conserved function related to toxinogenesis and/or pathogenesis, regardless of the toxin produced by the bacterium. Our work also led to the identification of a putative novel BoNT-like toxin gene cluster in a Bacillus isolate. This gene cluster shares striking similarities to the BoNT cluster, encoding a bont/ntnh-like gene and orfX-p47, but also differs from it markedly, displaying additional genes putatively encoding the components of a polymorphic ABC toxin complex. These findings provide novel insights into the biological roles of OrfX1, OrfX2, OrfX3, and P47 in toxinogenesis and pathogenesis of BoNT-producing and non-producing bacteria.


2019 ◽  
Author(s):  
Daniel Roderer ◽  
Felix Bröcker ◽  
Oleg Sitsel ◽  
Paulina Kaplonek ◽  
Franziska Leidreiter ◽  
...  

AbstractToxin complex (Tc) toxins are virulence factors widespread in insect and human bacterial pathogens. Tcs are composed of three subunits: TcA, TcB and TcC. TcA facilitates receptor-toxin interaction and membrane permeation, TcB and TcC form a toxin-encapsulating cocoon. While the mechanisms of holotoxin assembly and prepore-to-pore transition have been well-described, little is known about receptor binding and cellular uptake of Tcs. Here, we identify two classes of glycans, heparins/heparan sulfates and Lewis antigens, that act as receptors for different TcAs from insect- and human pathogenic bacteria. Glycan array screening and electron cryo microscopy (cryo-EM) structures reveal that all tested TcAs bind unexpectedly with their α-helical part of the shell domain to negatively charged heparins. In addition, TcdA1 from the insect-pathogen Photorhabdus luminescens binds to Lewis antigens with micromolar affinity. A cryo-EM structure of the TcdA1-Lewis X complex reveals that the glycan interacts with the receptor-binding domain D of the toxin. Our results suggest a two-step association mechanism of Tc toxins involving glycans on the surface of host cells.


2019 ◽  
Vol 116 (46) ◽  
pp. 23083-23090 ◽  
Author(s):  
Daniel Roderer ◽  
Oliver Hofnagel ◽  
Roland Benz ◽  
Stefan Raunser

Tc toxins are modular toxin systems of insect and human pathogenic bacteria. They are composed of a 1.4-MDa pentameric membrane translocator (TcA) and a 250-kDa cocoon (TcB and TcC) encapsulating the 30-kDa toxic enzyme (C terminus of TcC). Binding of Tc toxins to target cells and a pH shift trigger the conformational transition from the soluble prepore state to the membrane-embedded pore. Subsequently, the toxic enzyme is translocated and released into the cytoplasm. A high-resolution structure of a holotoxin embedded in membranes is missing, leaving open the question of whether TcB-TcC has an influence on the conformational transition of TcA. Here we show in atomic detail a fully assembled 1.7-MDa Tc holotoxin complex from Photorhabdus luminescens in the membrane. We find that the 5 TcA protomers conformationally adapt to fit around the cocoon during the prepore-to-pore transition. The architecture of the Tc toxin complex allows TcB-TcC to bind to an already membrane-embedded TcA pore to form a holotoxin. Importantly, assembly of the holotoxin at the membrane results in spontaneous translocation of the toxic enzyme, indicating that this process is not driven by a proton gradient or other energy source. Mammalian lipids with zwitterionic head groups are preferred over other lipids for the integration of Tc toxins. In a nontoxic Tc toxin variant, we can visualize part of the translocating toxic enzyme, which transiently interacts with alternating negative charges and hydrophobic stretches of the translocation channel, providing insights into the mechanism of action of Tc toxins.


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