An inactivated PDCoV vaccine induces robust neutralizing antibodies and immune protection in pigs lasting for three months.

Porcine deltacoronavirus (PDCoV), a novel enteropathogenic coronavirus, causes diarrhea mainly in suckling piglets and has the potential to infect humans. Whereas, there is no commercially available vaccine which can effectively prevent this disease. In this study, to ascertain the duration of immune protection of inactivated PDCoV vaccine, suckling piglets were injected subcutaneously with inactivated PDCoV vaccine using a prime/boost strategy at 3 and 17-day-old. Neutralizing antibody assay showed that the level of the inactivated PDCoV group was still ≥1:64 at three months after prime vaccination. The three-month-old pigs were orally challenged with PDCoV strain CZ2020. Two pigs in challenge control group showed mild to severe diarrhea at 10-11 day-post-challenge (DPC), while the inactivated PDCoV group had no diarrhea. High levels of viral shedding, substantial intestinal villus atrophy, and positive straining of viral antigens in ileum were detected in challenge control group, while the pigs in inactivated PDCoV group exhibited significantly reduced viral load, minor intestinal villi damage and negative straining of viral antigens. These results demonstrated that PDCoV was pathogenic against three-month-old pigs and inactivated PDCoV vaccine can provide effective protection in pigs lasting for three months.

Comparison of pathogenicity of porcine deltacoronavirus CZ2020 from cell culture and intestinal contents in 27-day-old piglets.

Porcine deltacoronavirus (PDCoV) is an emenging swine enteropathogenic coronavirus that can cause high mortality rate. It affects pigs of all ages, but most several in neonatal piglets. Little is known regarding the pathogenicity of PDCoV against 27-day-old piglets. In this study, 27-day-old piglets were experimentally infected with PDCoV CZ2020 from cell culture, the challenged piglets do not have obvious symptoms from 1 to 7 days post-challenge (DPC), while viral shedding was detected in rectal swab at 1 DPC. Tissues of small intestines displayed slight macroscopic and microscopic lesions with no viral antigen detection. On the other hand, 27-day-old piglets were infected with PDCoV from intestinal contents, the piglets developed mild to severe diarrhea, shedding increasing from 2 to 7 DPC, and developed macroscopic and microscopic lesions in small intestines with clear viral antigen confirmed by immunohistochemistry staining. Indicating the small intestine was still the major target organ in PDCoV-challenged pigs at the age of 27-day-old. Diarrhea caused by PDCoV from intestinal contents in 27-day-old piglets is less reported. Thus, our results might provide new insights into the pathogenesis of PDCoV.

The autoregulatory feedback loop of microRNA-21/programmed cell death protein 4/activation protein-1 (MiR-21/PDCD4/AP-1) as a driving force for hepatic fibrosis development.

Sustained activation of hepatic stellate cells (HSCs) leads to hepatic fibrosis, which is characterized by excessive collagen production, and for which there is no available drug clinically. Despite tremendous progress, the cellular activities underlying HSC activation, especially the driving force in the perpetuation stage, are only partially understood. Recently, microRNA-21 (miR-21) has been found to be prevalently up-regulated during fibrogenesis in different tissues, although its detailed role needs to be further elucidated. In the present study, miR-21 expression was examined in human cirrhotic liver samples and in murine fibrotic livers induced by thioacetamide or carbon tetrachloride. A dramatic miR-21 increase was noted in activated HSCs. We further found that miR-21 maintained itself at constant high levels by using a microRNA-21/programmed cell death protein 4/activation protein-1 (miR-21/PDCD4/AP-1) feedback loop. Disrupting this loop with miR-21 antagomir or AP-1 inhibitors significantly suppressed fibrogenic activities in HSCs and ameliorated liver fibrosis. In contrast, reinforcing this loop with small interfering RNA (siRNA) against PDCD4 promoted fibrogenesis in HSCs. Further analysis indicated that the up-regulated miR-21 promoted the central transforming growth factor-ß (TGF-ß) signaling pathway underlying HSC activation. In summary, we suggest that the miR-21/PDCD4/AP-1 autoregulatory loop is one of the main driving forces for hepatic fibrosis progression. Targeting this aberrantly activated feedback loop may provide a new therapeutic strategy and facilitate drug discovery against hepatic fibrosis.

Corona-directed nucleic acid delivery into hepatic stellate cells for liver fibrosis therapy.

Strategies to modify nanoparticles with biological ligands for targeted drug delivery in vivo have been widely studied but met with limited clinical success. A possible reason is that, in the blood circulation, serum proteins could rapidly form a layer of protein "corona" on the vehicle surface, which might block the modified ligands and hamper their targeting functions. We speculate that strategies for drug delivery can be designed based upon elegant control of the corona formation on the vehicle surfaces. In this study, we demonstrate a retinol-conjugated polyetherimine (RcP) nanoparticle system that selectively recruited the retinol binding protein 4 (RBP) in its corona components. RBP was found to bind retinol, and direct the antisense oligonucleotide (ASO)-laden RcP carrier to hepatic stellate cells (HSC), which play essential roles in the progression of hepatic fibrosis. In both mouse fibrosis models, induced by carbon tetrachloride (CCl4) and bile duct ligation (BDL), respectively, the ASO-laden RcP particles effectively suppressed the expression of type I collagen (collagen I), and consequently ameliorated hepatic fibrosis. Such findings suggest that this delivery system, designed to exploit the power of corona proteins, can serve as a promising tool for targeted delivery of therapeutic agents for the treatment of hepatic fibrosis.

The effect of targeted delivery of anti-TNF-α oligonucleotide into CD169+ macrophages on disease progression in lupus-prone MRL/lpr mice.

Systemic blockade of TNF-α via monoclonal antibodies and soluble receptors has shown considerable effects against several typical autoimmune disorders, but remains unconvincing for the treatment of lupus. Based on our previous study, a CD169(+) macrophage-specific therapy using TNF-α antisense oligonucleotides (ASO) was tested for its efficacy in MRL/lpr lupus-prone mice. ASO-containing cationic agarose hydrogel were injected into mice subcutaneously. Tissue distribution and cellular localization of ASO were determined. The therapeutic effects and possible mechanism were further studied in MRL/lpr lupus-prone mice. The results showed that specifically accumulation of the anti-TNF-α ASO in CD169(+) macrophages could significantly reduce TNF-α expression in CD169(+) macrophages and inhibit lymphocytes over-proliferation, finally resulted in the relief of the lupus-like symptoms of the animals. The nucleic acid drug based on CD169(+) macrophage-specific TNF-α regulation represents a potential therapeutic approach that may be valuable for lupus therapy.