Promoter motifs essential to the differential transcription of structural and non-structural genes of the white spot syndrome virus

Genome editing of WSSV CRISPR/Cas9 and immune activation extends the survival of infected Penaeus vannamei

White spot syndrome virus (WSSV) is an exceptionally harmful virus that generally causes high levels of mortality in cultured shrimp. Attempts at viral suppression have been made to control the disease and have achieved limited efficiency. Recent advances in genome editing technology using CRISPR/Cas9 have led to potential innovations to prevent or treat many viral diseases. In this study, a CRISPR/Cas9 system was applied to WSSV genome cleavage to suppress WSSV infection in shrimp. The U6 promoter sequence was identified. A chimeric DNA vector consisting of the shrimp U6 promoter with gRNA expression sequences specific to two sites of the WSSV genome and the WSSV ribonucleotide reductase promoter with the Cas9 DNA sequence in pAC-sgRNA-Cas9 was constructed. The expression of gRNAs specific to the WSSV genome and Cas9 was determined in primary cultured hemocyte cells and in shrimp tissue via RT‒PCR. The efficacy of CRISPR/Cas9-WSSV for WSSV genome cleavage was determined in vitro and against WSSV-infected Penaeus vannamei. The reaction of synthetic gRNAs and recombinant Cas9 was able to cleave WSSV DNA amplicons, and shrimp that received CRISPR/Cas9-WSSV presented significantly lower WSSV DNA. In addition to interfering with viral DNA propagation, CRISPR/Cas9-WSSV encapsulated with IHHNV-VLP also stimulated an immune-related gene response. Treatment with CRISPR/Cas9-WSSV against WSSV challenge resulted in a significantly longer survival period. This finding has led to the development and application of a CRISPR/Cas9 system for WSSV infectious disease control, which could be used for managing shrimp aquaculture in the future.

Nanocontainer designed from an infectious hypodermal and hematopoietic necrosis virus (IHHNV) has excellent physical stability and ability to deliver shrimp tissues

Background

A virus-like particle (VLP) is an excellent tool for a compound delivery system due to its simple composition, symmetrical structure and self-assembly. Its surface modification both chemically and genetically is established, leading to the target-specific delivery and improved encapsulation efficiency. However, its physical stabilities against many harsh conditions that guarantee long term storage and oral administration have been much less studied.

Methods

IHHNV-VLPs were reconstructed from recombinant IHHNV capsid protein in E. coli. Their physical properties against three strong physical conditions including long term storage (0–30 days) in 4 °C, physical stabilities against broad ranged pH (4–9) and against three types of digestive enzymes were tested. Disassembly and reassembly of VLPs for encapsidating an enhanced green fluorescent protein tagged plasmid DNA (EGFP-VLPs) were controlled by the use of reducing agent (DTT) and calcium specific chelating agent (EGTA). Lastly, delivering ability of EGFP-VLPs was performed in vivo by intramuscular injection and traced the expression of GFP in the shrimp tissues 24 hr post-injection.

Results

Upon its purification, IHHNV-VLPs were able to be kept at 4 °C up to 30 days with only slight degradation. They were very stable in basic condition (pH 8–9) and to a lesser extent in acidic condition (pH 4–6) while they could stand digestions of trypsin and chymotrypsin better than pepsin. As similar with many other non-enveloped viruses, the assembly of IHHNV-VLPs was dependent on both disulfide bridging and calcium ions which allowed us to control disassembly and reassembly of these VLPs to pack EGFP plasmid DNA. IHHNV-VLPs could deliver EGFP plasmids into shrimp muscles and gills as evident by RT-PCR and confocal microscopy demonstrating the expression of GFP in the targeted tissues.

Discussion

There are extensive data in which capsid proteins of the non-enveloped viruses in the form of VLPs are constructed and used as nano-containers for therapeutic compound delivery. However, the bottleneck of its application as an excellent delivery container for oral administration would rely solely on physical stability and interacting ability of VLPs to the host cells. These properties are retained for IHHNV-VLPs reported herein. Thus, IHHNV-VLPs would stand as a good applicable nanocontainer to carry therapeutic agents towards the targeting tissues against ionic and digestive conditions via oral administration in aquaculture field.

Encapsulation and delivery of plasmid DNA by virus-like nanoparticles engineered from Macrobrachium rosenbergii nodavirus

Virus-like particles (VLPs) are potential candidates in developing biological containers for packaging therapeutic or biologically active agents. Here, we expressed Macrobrachium rosenbergii nodavirus (MrNv) capsid protein (encoding amino acids M1-N371 with 6 histidine residuals) in an Escherichia coli BL21(DE3). These easily purified capsid protein self-assembled into VLPs, and disassembly/reassembly could be controlled in a calcium-dependent manner. Physically, MrNv VLPs resisted to digestive enzymes, a property that should be advantageous for protection of active compounds against harsh conditions. We also proved that MrNv VLPs were capable of encapsulating plasmid DNA in the range of 0.035-0.042 mol ratio (DNA/protein) or 2-3 plasmids/VLP (assuming that MrNV VLPs is T=1, i made up of 60 capsid monomers). These VLPs interacted with cultured insect cells and delivered loaded plasmid DNA into the cells as shown by green fluorescent protein (GFP) reporter. With many advantageous properties including self-encapsulation, MrNv VLPs are good candidates for delivery of therapeutic agents.

Identification of the core sequence elements in Penaeus stylirostris densovirus promoters

In silico analysis of three Penaeus stylirostris densovirus (PstDNV) promoters, designated P2, P11, and P61, revealed sequence motifs including the TATA box, downstream promoter element (DPE), GC- and A-rich regions, inverted repeat, activation sequence-1 like (ASL) box, and a conserved guanosine (G) at +24. To delineate the regulatory role of these motifs on promoter activity, deletion constructs were made in a promoter assay vector, pGL3 Basic, that contains a luciferase reporter gene. Luciferase assay showed that P2 had the highest promoter activity followed by P11 and P61 in Sf9 cells. The deletions of inverted repeat, DPE, and GC-rich regions in P2 had the highest negative impact on this promoter. Deletions of DPE, G at the +24, and ASL box in P11 had the highest negative impact on this promoter activity. In P61, DPE and G at +24 are the two key regulators of transcriptional activity. Identification of the key transcriptional regulators is important in understanding the PstDNV pathogenesis in shrimp. This information is also valuable in constructing shrimp viral promoter-based vectors for protein expression in insect cell culture system as well as in shrimp.