A novel multiplex real-time polymerase chain reaction for the molecular diagnosis of metacestode infections in human patients

Rodent Gut Bacteria Coexisting with an Insect Gut Virus in Tapeworm Parasitic Cysts: Metagenomic Evidence of Microbial Selection in Extra-Intestinal Clinical Niches

In medicine, parasitic cysts (e.g., brain cysticerci) are believed to be sterile, and are primarily treated with antiparasitic medications, not antibiotics, which could prevent abscess formation and localized inflammation. This study quantified the microbial composition of parasitic cysts in a wild rodent, using multi-kingdom metagenomics to comprehensively assess if parasitic cysts are sterile, and further understand gut microbial translocation and adaptation in wildlife confined environments, outside the gut. Analysis was conducted on DNA from two hepatic parasitic cysts from a feline tapeworm, Hydatigera (Taenia) taeniaeformis, affecting a wild vole mouse (Microtus pennsylvanicus), and from feces, liver and peritoneal fluid of this and two other concurrent individual wild voles trapped during pest control in one of our university research vegetable gardens. Bacterial metagenomics revealed the presence of gut commensal/opportunistic species, Parabacteroides distasonis, Bacteroides (Bacteroidota); Klebsiella variicola, E. coli (Enterobacteriaceae); Enterococcus faecium and Lactobacillus acidophilus (Bacillota) inhabiting the cysts, and peritoneal fluid. Remarkably, viral metagenomics revealed various murine viral species, and unexpectedly, a virus from the insect armyworm moth (Pseudaletia/Mythimna unipuncta), known as Mythimna unipuncta granulovirus A (MyunGV-A), in both cysts, and in one fecal and one peritoneal sample from the other non-cyst voles, indicating the survival and adaption potential of the insect virus in voles. Metagenomics also revealed a significantly lower probability of fungal detection in cysts compared to that in peritoneal fluid/feces (p < 0.05), with single taxon detection in each cyst (Malassezia and Pseudophaeomoniella oleicola). The peritoneal fluid had the highest probability for fungi. In conclusion, metagenomics revealed that bacteria/viruses/fungi coexist within parasitic cysts supporting the potential therapeutic benefits of antibiotics in cystic diseases, and in inflammatory microniches of chronic diseases, such as Crohn's disease gut wall cavitating micropathologies, from which we recently isolated similar synergistic pathogenic Bacteroidota and Enterobacteriaceae, and Bacillota.

Plasma Circulating Cell-Free DNA Facilitated the Detection of an Alveolar Echinococcosis Patient Initially Misdiagnosed as Cystic Echinococcosis: A Case Report

Echinococcosis, especially alveolar echinococcosis (AE), is becoming an emerging/re-emerging disease with a growing number of cases reported globally. The diagnosis of echinococcosis is based mainly on imaging, which may be challenging when the image presentation is atypical. We reported one patient with suspected cystic echinococcosis (CE) by imaging. The cell-free DNA (cfDNA) obtained from sequencing the patient's plasma before the operation showed that this patient probably had AE with 45 reads mapped to the Echinococcus multilocularis reference genome (Read-Pairs Per Million = 0.24). The patients underwent surgery, and the pathological result showed that the patient had AE. The conventional polymerase chain reaction (PCR) of her lesion sample extraction also indicated that the infection was caused by Echinococcus multilocularis. The follow-up ultrasound after three months indicated no recurrence. We demonstrated that the differentiation of CE and AE by imaging may not be that easy, with further elaboration on the differentiation between AE and CE in different aspects. We demonstrated that it is possible to use patients' plasma cfDNA mapped to Echinococcus references before the operation to obtain the objective clue of the lesion to facilitate diagnosis.

Dual-RPA assay for rapid detection and differentiation of E.granulosus and E.multilocularis

Echinococcus granulosus (Eg) and Echinococcus multilocularis (Em) are the two most widely prevalent types of echinococcosis. Several diagnostic methods have been developed for detecting Eg and Em. However, some limitations, such as being time-consuming, needing expensive instruments, or exhibiting low sensitivity, make these methods unsuitable for on-site detection. In this study, a dual-RPA assay was established to detect and differentiate Eg and Em. The primer concentration ratio, reaction time, and reaction temperature of the dual-RPA were optimized. The result showed that the primer concentration ratio of Eg:Em was 400 nM:400 nM, and the best amplification efficiency was obtained by reacting at 38 °C for 20 min. The sensitivity, specificity, and repeatability of the assay were also tested. The assay's detection limit for both Eg and Em was 10 copies/μL. The assay showed reasonable specificity by testing ten parasitic nucleic acids. The assay's intra- and inter-batch coefficients of variation were below 10%, which indicates robust reproducibility of the assay. Finally, to validate the performance of the dual-RPA assay, it was compared with real-time PCR by using 86 clinical nucleic acid samples. The coincidence rate of Eg between dual-RPA and TaqMan real-time PCR was 96.51%, and the coincidence rate of Em between dual-RPA and TaqMan real-time PCR was 98.84%, indicating its potential for accurate clinical diagnosis. Therefore, this study established a rapid and sensitive dual-RPA assay that can rapidly detect and differentiate Eg and Em in one reaction tube and provided a new assay for the detection of echinococcosis in the field.