Isolation, identification and genetic evolution analysis of porcine epidemic diarrhea virus SNJ-P strain in Sichuan Province

Purpose: To investigate the epidemic variation of porcine epidemic diarrhea virus (PEDV) strains in Sichuan Province, and to analyze the causes of poor vaccination effect. Methods: Piglet intestinal samples were collected from a pig farm in Sichuan Province for PCR detection, virus purification, determination of virus titer and virus infection experiments. Whole genome sequencing of isolated strains was determined. The S gene sequence of the isolated strain was compared with the strains from other regions and vaccine strains, and the phylogenetic tree was established. The amino acid site variation of S protein between the isolated strain and the classical vaccine strain CV777 was compared. Results: A PEDV strain was successfully isolated and named as PEDV SNJ-P. The determination of virus titer was 1..107.5/100 L. Animal infection experiments showed that the isolated strain could cause diarrhea, dehydration and other symptoms and lead to death in piglets. Genome sequencing and phylogenetic tree analysis showed that the whole gene of PEDV SNJ-P strain was 28003 bp, and the genotype of the strain was S non-INDEL type. The strains were closely related to the strains of PEDV-WS, CH/JLDH/2016 and CH/HNLH/2015 isolated from China, and were relatively distant with the same type vaccine strain, and were far from the classical vaccine strain. Compared with the classical vaccine strain CV777, the S protein of SNJ-P strain had multiple amino acid mutations, deletions and insertions. Conclusion: Due to the continuous variation of strains, SNJ-P strain is far from the vaccine strain, and the current vaccines cannot provide effective protection. The results of this study are expected to provide reference for the study of PEDV strains and vaccine development in China.

RVG Peptide-Functionalized Favipiravir Nanoparticle Delivery System Facilitates Antiviral Therapy of Neurotropic Virus Infection in a Mouse Model.

Neurotropic viruses severely damage the central nervous system (CNS) and human health. Common neurotropic viruses include rabies virus (RABV), Zika virus, and poliovirus. When treating neurotropic virus infection, obstruction of the blood-brain barrier (BBB) reduces the efficiency of drug delivery to the CNS. An efficient intracerebral delivery system can significantly increase intracerebral delivery efficiency and facilitate antiviral therapy. In this study, a rabies virus glycopeptide (RVG) functionalized mesoporous silica nanoparticle (MSN) packaging favipiravir (T-705) was developed to generate T-705@MSN-RVG. It was further evaluated for drug delivery and antiviral treatment in a VSV-infected mouse model. The RVG, a polypeptide consisting of 29 amino acids, was conjugated on the nanoparticle to enhance CNS delivery. The T-705@MSN-RVG caused a significant decrease in virus titers and virus proliferation without inducing substantial cell damage in vitro. By releasing T-705, the nanoparticle promoted viral inhibition in the brain during infection. At 21 days post-infection (dpi), a significantly enhanced survival ratio (77%) was observed in the group inoculated with nanoparticle compared with the non-treated group (23%). The viral RNA levels were also decreased in the therapy group at 4 and 6 dpi compared with that of the control group. The T-705@MSN-RVG could be considered a promising system for CNS delivery for treating neurotropic virus infection.

Application of Nanopore Sequencing in the Detection of Foodborne Microorganisms.

Foodborne pathogens have become the subject of intense interest because of their high incidence and mortality worldwide. In the past few decades, people have developed many methods to solve this challenge. At present, methods such as traditional microbial culture methods, nucleic acid or protein-based pathogen detection methods, and whole-genome analysis are widely used in the detection of pathogenic microorganisms in food. However, these methods are limited by time-consuming, cumbersome operations or high costs. The development of nanopore sequencing technology offers the possibility to address these shortcomings. Nanopore sequencing, a third-generation technology, has the advantages of simple operation, high sensitivity, real-time sequencing, and low turnaround time. It can be widely used in the rapid detection and serotyping of foodborne pathogens. This review article discusses foodborne diseases, the principle of nanopore sequencing technology, the application of nanopore sequencing technology in foodborne pathogens detection, as well as its development prospects.

Functionalized Nanoparticles in Prevention and Targeted Therapy of Viral Diseases With Neurotropism Properties, Special Insight on COVID-19.

Neurotropic viruses have neural-invasive and neurovirulent properties to damage the central nervous system (CNS), leading to humans' fatal symptoms. Neurotropic viruses comprise a lot of viruses, such as Zika virus (ZIKV), herpes simplex virus (HSV), rabies virus (RABV), and severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2). Effective therapy is needed to prevent infection by these viruses in vivo and in vitro. However, the blood-brain barrier (BBB) usually prevents macromolecules from entering the CNS, which challenges the usage of the traditional probes, antiviral drugs, or neutralizing antibodies in the CNS. Functionalized nanoparticles (NPs) have been increasingly reported in the targeted therapy of neurotropic viruses due to their sensitivity and targeting characteristics. Therefore, the present review outlines efficient functionalized NPs to further understand the recent trends, challenges, and prospects of these materials.