Potent programmable antiviral against dengue virus in primary human cells by Cas13b RNP with short spacer and delivery by VLP.

With sequencing as a standard frontline protocol to identify emerging viruses such Zika virus and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), direct utilization of sequence data to program antivirals against the viruses could accelerate drug development to treat their infections. CRISPR-Cas effectors are promising candidates that could be programmed to inactivate viral genetic material based on sequence data, but several challenges such as delivery and design of effective CRISPR RNA (crRNA) need to be addressed to realize practical use. Here, we showed that virus-like particle (VLP) could deliver PspCas13b-crRNA ribonucleoprotein (RNP) in nanomolar range to efficiently suppress dengue virus infection in primary human target cells. Shortening spacer length could significantly enhance RNA-targeting efficiency of PspCas13b in mammalian cells compared to the natural length of 30 nucleotides without compromising multiplex targeting by a crRNA array. Our results demonstrate the potentials of applying PspCas13b RNP to suppress RNA virus infection, with implications in targeting host RNA as well.

PmEEA1, the early endosomal protein is employed by YHV for successful infection in Penaeus monodon.

Yellow head disease (YHD) is an infectious disease of Penaeus monodon which is caused by the yellow head virus (YHV). YHV infection invariably leads to 100% shrimp mortality within 3-5 days. Currently, an effective method to prevent or cure shrimp from YHV infection has not been elucidated. Therefore, the molecular mechanism underlying YHV infection should be examined. In this study, early endosome antigen 1 (EEA1) protein that was involved in the tethering step of the vesicle and early endosome fusion was investigated during YHV infection. The open reading frame of P. monodon EEA1 (PmEEA1) was cloned and sequenced (3000 bp). It encoded a putative protein of 999 amino acids and contained the zinc finger C2H2 domain signature at the N-terminus and the FYVE domain at the C-terminus. Suppression of PmEEA1 by specific dsRNA in shrimp showed inhibition of YHV replication after 48 h post YHV injection (hpi). On the other hand, shrimp received only NaCl without any dsRNA showed high YHV levels at approximately one hundred thousand times at 24 hpi and 48 hpi. Moreover, silencing of PmEEA1 by specific dsRNA followed by YHV challenge demonstrated a delay in shrimp mortality from 60 hpi to 168 hpi when compared to the control. These results indicated that YHV required PmEEA1 for trafficking within the infected cells, strongly suggesting that PmEEA1 may be a potential target to control and prevent YHV infection in P. monodon.

Successful yellow head virus infection of Penaeus monodon requires clathrin heavy chain.

Viral disease caused by the Yellow head virus (YHV) had great impact on economic loss in the aquaculture industry. Prevention or curing YHV disease is still not possible due to the lack of understanding of the basic mechanisms of YHV infection. In this report, the endocytosis inhibitors (chlorpromazine (CPZ), amiloride and methyl-ß-cyclodextrin (MßCD)) were used to identify the cellular entry pathway of YHV. Pretreating shrimp with CPZ but not amiloride or MßCD followed by YHV challenge resulted in a significant reduction of YHV levels, suggesting that YHV entered the shrimp cells via clathrin-mediated endocytosis. Next, the major component of the clathrin-coated vesicle, Penaeus monodon clathrin heavy chain (PmCHC) was cloned and characterized. The complete coding sequence of PmCHC is 5055 bp encoding a putative protein of 1684 amino acids. Specific silencing of PmCHC mRNA by dsRNA-PmCHC showed an inhibition of YHV replication for 48 h post YHV injection as well as exhibiting a delay in shrimp mortality. These results indicated that PmCHC was an essential component for YHV infection of shrimp cells.

A simple one-step method for producing dsRNA from E. coli to inhibit shrimp virus replication.

While dsRNA has been used experimentally to inhibit replication and thus disease caused by several shrimp viruses, it can be tedious, time consuming and costly to produce. Here we describe a simple method for obtaining long-hairpin dsRNA from RNase III-minus HT115 Escherichia coli cells following its expression from a plasmid containing a RNA promoter. All the method requires is for bacterial cells to be fixed briefly in 75% ethanol in phosphate buffer saline (PBS) before suspension in 150mM NaCl. When injected into the haemal sinuses of shrimp, hairpin dsRNA specific to the PmRab7 gene prepared by this method was found to inhibit PmRab7 mRNA expression as effectively as hairpin dsRNA purified using TRIzol reagent. Shrimp injection of either dsRNA-PmRab7 or hairpin dsRNA specific to yellow head virus (YHV) prepared similarly also inhibited YHV replication effectively. Based on these findings, this simple and cheap method of producing dsRNA should be adaptable to various commercial-scale applications of RNA interference (RNAi) in shrimp.