Ricin: an ancient toxicant, but still an evergreen

Nanostructured aptasensors for ricin detection and tumor therapy: exploring aptamer-protein interactions and conformational stability in biological complexities

Aptamers are distinctive single-stranded oligonucleotides derived through in vitro evolution, and exhibit exceptional ability in binding to target proteins. Structural modifications of aptamers can profoundly regulate their interactions with proteins, thereby influencing associated cellular behavior. Recent research focused on modulating aptamer-protein interaction in complex biological environments to regulate various biological processes. However, in such crowded conditions, aptamer conformation and stability are susceptible to nuclease degradation, which can impair stable binding to target. Ricin is recognized as a significant biological toxin protein, distinguished by its widespread availability, remarkable dissemination, and resilience including wide pH tolerance, remarkable thermostability, and solubility. RTA is an enzymatic subunit of ricin, that can inactivate approximately 2000 ribosomes per minute, rapidly halting protein synthesis, making it a powerful candidate for tumor therapy. By leveraging the potent cytotoxicity of ricin, coupled with the targeting precision of aptamers and the versatility of nanomaterials, a powerful approach emerges for both targeted tumor therapy and highly sensitive detection of ricin. Although there have been some insightful reports on aptamers applied in ricin detection, a systematic discussion remains limited. In this context, we provide an in-depth overview of techniques used to analyze aptamer-ricin interactions and explore the potential of ricin-aptamer interactions in clinical diagnosis.

Immuno-PCR in the Analysis of Food Contaminants

Food safety is a significant issue of global concern. Consumer safety and government regulations drive the need for the accurate analysis of food contaminants, residues and other chemical constituents of concern. Traditional methods for the detection of food contaminants often present challenges, including lengthy processing times and food matrix interference; they often require expensive equipment, skilled personnel or have limitations in sensitivity or specificity. Developing novel analytical methods that are sensitive, specific, accurate and rapid is therefore crucial for ensuring food safety and the protection of consumers. The immuno-polymerase chain reaction (IPCR) method offers a promising solution in the analysis of food contaminants by combining the specificity of conventional immunological methods with the exponential sensitivity of PCR amplification. This review evaluates the current state of IPCR methods, describes a variety of existing IPCR formats and explores their application in the analysis of food contaminants, including pathogenic bacteria and their toxins, viruses, mycotoxins, allergens, polycyclic aromatic hydrocarbons, polychlorinated biphenyls, phthalic acid esters, pesticides, antibiotics and other food contaminants. Depending on the type of analyte, either sandwich or competitive format IPCR methods are predominantly used. This review also examines limitations of current IPCR methods and explores potential advancements for future implementation in the field of food safety.

A Rapid and Modular Nanobody Assay for Plug-and-Play Antigen Detection

Rapid and portable antigen detection is essential for managing infectious diseases and responding to toxic exposures, yet current methods face significant limitations. Highly sensitive platforms like the Enzyme-Linked Immunosorbent Assay (ELISA) are time- and cost-prohibitive for point-of-need detection, while portable options like lateral flow assays (LFAs) require systemic overhauls for new targets. Furthermore, the complex infrastructure, high production costs, and extended timelines for assay development constrain manufacturing of traditional diagnostic platforms in low-resource settings. To address these challenges, we describe the Rapid and Modular Nanobody Assay (RAMONA) as a versatile antigen detection platform that leverages nanobody-coiled coil fusion proteins for modular integration with downstream readout methods. RAMONA merges the portability of LFAs with the benefits of nanobodies, such as their smaller size, improved solubility, and compatibility with cell-free protein synthesis systems, enabling on-demand biomanufacturing and rapid adaptation for diverse targets. We demonstrate assay generalizability through the detection of three distinct protein targets, robustness across various temperatures and incubation periods, and compatibility with saliva samples and cell-free synthesis. Detection occurs in under 30 minutes, with results strongly and positively correlating to ELISA data while requiring minimal resources. Moreover, RAMONA supports multiplexed detection of three antigens simultaneously using orthogonal capture probes. By overcoming several limitations of traditional immunoassays, RAMONA represents a significant advancement in rapid, adaptable, and field-deployable antigen detection technologies.

In silico structural and mechanistic sights into the N-glycosidase mechanism of Shiga toxin

Shiga toxin is the leading cause of food poisoning in the world. It is structurally similar to the plant type II ribosome-inactivating proteins (RIPs) and retains N-glycosidase activity. It acts specifically by depurinating the specific adenine A4605 of human 28S rRNA, ultimately inhibiting translation. Recent outbreaks and increasing demands for lab-scale meat assert the necessity for producing toxoids. In the current study, we have carried out the comparative structural and functional analysis of Shiga with ricin for N-glycosidase activity. Primary structural analysis indicates that Shiga is more flexible than ricin and one active site residue Gly121 (ricin), has been mutated to Ser (Shiga). Tertiary structure analysis confirms the conserved active site residue confirmation. Further, molecular dynamic studies indicate that the mutated Ser residue of Shiga imparts flexibility besides interacting with the conserved GAGA loop of 28s rRNA and contributes free energy of -5.39 kcal/mol. We have observed a decreasing trend line of average free binding energy with an average of -23 kcal/mol. The residue interaction network indicates that Arg is the key residue that protonates and initiates the N-glycosidase activity. Overall, these structural studies provide molecular insights into the N-glycosidase mechanism and serve as a prospect for the development of toxoids.

Ricin intoxication by lethal dose of castor seeds ingestion: a case report

INTRODUCTION

Ricin intoxication is a serious condition with symptoms ranging from mild gastroenteritis to fatal outcomes due to shock and multi-organ failure. Intoxication from the ingestion of castor seeds is uncommon. However, its diagnosis is crucial, particularly with a clear history of exposure to castor seeds, regardless of the route of exposure (enteral or parenteral). Prompt diagnosis is essential to monitor and manage the patient effectively and to prevent potentially fatal outcomes. We report a case where ingestion of castor seeds resulted in gastroenteritis severe enough to necessitate emergency medical care.

CASE REPORT

We present the case of a 47-year-old Belgian woman of Moroccan descent, previously healthy who was admitted to the emergency department with symptoms of colicky abdominal pain, diarrhea, and vomiting following the ingestion of six castor beans. The patient was diagnosed with ricin intoxication, admitted for observation, and received symptomatic treatment. She was discharged home after a complete recovery three days later.

CONCLUSION

Our report underscores the clinical manifestations, hemodynamic changes, laboratory findings, and treatment of intoxication due to castor seed ingestion. It contributes to the limited literature on castor seed poisoning in humans, with a specific focus on cases in Belgium. This report aims to raise awareness among clinicians about this condition and emphasizes the importance of a comprehensive history-taking to prevent misdiagnosis and malpractice.

Investigating diversity and similarity between CBM13 modules and ricin-B lectin domains using sequence similarity networks

BACKGROUND

The CBM13 family comprises carbohydrate-binding modules that occur mainly in enzymes and in several ricin-B lectins. The ricin-B lectin domain resembles the CBM13 module to a large extent. Historically, ricin-B lectins and CBM13 proteins were considered completely distinct, despite their structural and functional similarities.

RESULTS

In this data mining study, we investigate structural and functional similarities of these intertwined protein groups. Because of the high structural and functional similarities, and differences in nomenclature usage in several databases, confusion can arise. First, we demonstrate how public protein databases use different nomenclature systems to describe CBM13 modules and putative ricin-B lectin domains. We suggest the introduction of a novel CBM13 domain identifier, as well as the extension of CAZy cross-references in UniProt to guard the distinction between CAZy and non-CAZy entries in public databases. Since similar problems may occur with other lectin families and CBM families, we suggest the introduction of novel CBM InterPro domain identifiers to all existing CBM families. Second, we investigated phylogenetic, nomenclatural and structural similarities between putative ricin-B lectin domains and CBM13 modules, making use of sequence similarity networks. We concluded that the ricin-B/CBM13 superfamily may be larger than initially thought and that several putative ricin-B lectin domains may display CAZyme functionalities, although biochemical proof remains to be delivered.

CONCLUSIONS

Ricin-B lectin domains and CBM13 modules are associated groups of proteins whose database semantics are currently biased towards ricin-B lectins. Revision of the CAZy cross-reference in UniProt and introduction of a dedicated CBM13 domain identifier in InterPro may resolve this issue. In addition, our analyses show that several proteins with putative ricin-B lectin domains show very strong structural similarity to CBM13 modules. Therefore ricin-B lectin domains and CBM13 modules could be considered distant members of a larger ricin-B/CBM13 superfamily.

Ferrostatin‑1 alleviates liver injury via decreasing ferroptosis following ricin toxin poisoning in rat

Ricin is a highly toxic plant toxin that can cause multi-organ failure, especially liver dysfunction, and is a potential bioterrorism agent. Despite the serious public health challenge posed by ricin, effective therapeutic for ricin-induced poisoning is currently unavailable. Therefore, it is important to explore the mechanism of ricin poisoning and develop appropriate treatment protocols accordingly. Previous studies have shown that lipid peroxidation and iron accumulation are associated with ricin poisoning. Ferroptosis is an iron-dependent form of cell death caused by excessive accumulation of lipid peroxide. The role and mechanism of ferroptosis in ricin poisoning are unclear and require further study. We investigated the effect of ferroptosis on ricin-induced liver injury and further elucidated the mechanism. The results showed that ferroptosis occurred in the liver of ricin-intoxicated rats, and Ferrostatin‑1 could ameliorate hepatic ferroptosis and thus liver injury. Ricin induced liver injury by decreasing hepatic reduced glutathione and the protein level of glutathione peroxidase 4 and Solute Carrier Family 7 Member 11, increasing iron, malondialdehyde and reactive oxygen species, and mitochondrial damage, whereas Ferrostatin‑1 pretreatment increased hepatic reduced glutathione and the protein level of glutathione peroxidase 4 and Solute Carrier Family 7 Member 11, decreased iron, malondialdehyde, and reactive oxygen species, and ameliorated mitochondrial damage, thereby alleviated liver injury. These results suggested that ferroptosis exacerbated liver injury after ricin poisoning and that inhibition of ferroptosis may be a novel strategy for the treatment of ricin poisoning.