Evaluating Cationic Nanoparticles as Carriers of Antiviral Nucleic Acids.

Nanoparticle carriers enable the multivalent delivery of nucleic acids to cells and protect them from degradation. In this chapter, we present a comprehensive overview of four methodologies: electrophoretic mobility shift assay (EMSA), alamarBlue/CFDA-AM cell viability dyes, fluorescence microscopy, and antiviral assays, which collectively are tools to explore interactions between nucleic acids and nanoparticles, and their biological efficacy. These assays provide insights into binding potential, cytotoxicity, and antiviral efficacy of nucleic acid-based nanoparticle treatments furthering the development of effective antiviral therapeutics.

Toll­like receptor 3 ligands for breast cancer therapies (Review).

Breast cancer is the most common cause of cancer worldwide and is the leading cause of mortality for women across most of the world. Immunotherapy is a burgeoning area of cancer treatment, including for breast cancer; these are therapies that harness the power of the immune system to clear cancerous cells. Toll-like receptor 3 (TLR3) is an RNA receptor found in the endosome, and ligands that bind to TLR3 are currently being tested for their efficacy as breast cancer immunotherapeutics. The current review introduces TLR3 and the role of this receptor in breast cancer, and summarizes data on the potential use of TLR3 ligands, mainly polyinosinic:polycytidylic acid and its derivatives, as breast cancer monotherapies or, more commonly, as combination therapies with chemotherapies, other immunotherapies and cancer vaccines. The current state of TLR3 ligand breast cancer therapy research is summarized by reporting on past and current clinical trials, and notable preliminary in vitro studies are discussed. In conclusion, TLR3 ligands have robust potential in anticancer applications as innate immune stimulants, and further studies combined with innovative technologies, such as nanoparticles, may contribute to their success.

TAK-242 treatment and its effect on mechanical properties and gene expression associated with IVD degeneration in SPARC-null mice.

PURPOSE: Intervertebral disc (IVD) degeneration is accompanied by mechanical and gene expression changes to IVDs. SPARC-null mice display accelerated IVD degeneration, and treatment with (toll-like receptor 4 (TLR4) inhibitor) TAK-242 decreases proinflammatory cytokines and pain. This study examined if chronic TAK-242 treatment impacts mechanical properties and gene expression associated with IVD degeneration in SPARC-null mice. METHODS: Male and female SPARC-null and WT mice aged 7-9 months were given intraperitoneal injections with TAK-242 or an equivalent saline vehicle for 8 weeks (3x/per week, M-W-F). L2-L5 spinal segments were tested in cyclic axial tension and compression. Gene expression analysis (RT-qPCR) was performed on male IVD tissues using Qiagen RT2 PCR arrays. RESULTS: SPARC-null mice had decreased NZ length (p = 0.001) and increased NZ stiffness (p < 0.001) compared to WT mice. NZ length was not impacted by TAK-242 treatment (p = 0.967) despite increased hysteresis energy (p = 0.024). Tensile stiffness was greater in SPARC-null mice (p = 0.018), and compressive (p < 0.001) stiffness was reduced from TAK-242 treatment in WT but not SPARC-null mice (p = 0.391). Gene expression analysis found upregulation of 13 ECM and 5 inflammatory genes in SPARC-null mice, and downregulation of 2 inflammatory genes after TAK-242 treatment. CONCLUSIONS: TAK-242 had limited impacts on SPARC-null mechanical properties and did not attenuate NZ mechanical changes associated with IVD degeneration. Expression analysis revealed an increase in ECM and inflammatory gene expression in SPARCnull mice with a reduction in inflammatory expression due to TAK-242 treatment. This study provides insight into the role of TLR4 in SPARC-null mediated IVD degeneration.

Two DExD/H-box helicases, DDX3 and DHX9, identified in rainbow trout are able to bind dsRNA.

In mammals, the multifunctional DExH/D-box helicases, DDX3 and DHX9, are nucleic acid sensors with a role in antiviral immunity; their role in innate immunity in fish is not yet understood. In the present study, full-length DDX3 and DHX9 coding sequences were identified in rainbow trout (Oncorhynchus mykiss). Bioinformatic analysis demonstrated both deduced proteins were similar to those of other species, with ~80% identity to other fish species and ~70-75% identity to mammals, and both protein sequences had conserved domains found amongst all species. Phylogenetic analysis revealed clustering of DDX3 and DHX9 with corresponding proteins from other fish. Cellular localization of overexpressed DDX3 and DHX9 was performed using GFP-tagged proteins, and endogenous DDX3 localization was measured using immunocytochemistry. In the rainbow trout gonadal cell line, RTG-2, DHX9 localized mostly to the nucleus, while DDX3 was found mainly in the cytoplasm. Tissue distribution from healthy juvenile rainbow trout revealed ubiquitous constitutive expression, highest levels of DDX3 expression were seen in the liver and DHX9 levels were fairly consistent among all tissues tested. Stimulation of RTG-2 cells revealed that DDX3 and DHX9 transcripts were both significantly upregulated by treatment with the dsRNA molecule, poly I:C. A pull-down assay suggested both proteins were able to bind dsRNA. In addition to their roles in RNA metabolism, the conserved common domains found between the rainbow trout proteins and other species having defined antiviral roles, combined with the ability for the proteins to bind to dsRNA, suggest these proteins may play an important role in fish innate antiviral immunity. Future studies on both DDX3 and DHX9 function will contribute to a better understanding of teleost immunity.

In vitro transcribed dsRNA limits viral hemorrhagic septicemia virus (VHSV)-IVb infection in a novel fathead minnow (Pimephales promelas) skin cell line.

The farming of baitfish, fish used by anglers to catch predatory species, is of economic and ecological importance in North America. Baitfish, including the fathead minnow (Pimephales promelas), are susceptible to infection from aquatic viruses, such as viral hemorrhagic septicemia virus (VHSV). VHSV infections can cause mass mortality events and have the potential to be spread to novel water bodies through baitfish as a vector. In this study, a novel skin cell line derived from fathead minnow (FHMskin) is described and its use as a tool to study innate antiviral immune responses and possible therapies is introduced. FHMskin grows optimally in 10% fetal bovine serum and at warmer temperatures, 25-30 °C. FHMskin is susceptible and permissive to VHSV-IVb infection, producing high viral titres of 7.35 × 107 TCID50/mL after only 2 days. FHMskin cells do not experience significant dsRNA-induced death after treatment with 50-500 ng/mL of in vitro transcribed dsRNA for 48 h and respond to dsRNA treatment by expressing high levels of three innate immune genes, viperin, ISG15, and Mx1. Pretreatment with dsRNA for 24 h significantly protected cells from VHSV-induced cell death, 500 ng/mL of dsRNA reduced cell death from 70% to less than 15% at a multiplicity of infection of 0.1. Thus, the novel cell line, FHMskin, represents a new method for producing high tires of VHSV-IVb in culture, and for studying dsRNA-induced innate antiviral responses, with future applications in dsRNA-based antiviral therapeutics.

Understanding Viral dsRNA-Mediated Innate Immune Responses at the Cellular Level Using a Rainbow Trout Model.

Viruses across genome types produce long dsRNA molecules during replication [viral (v-) dsRNA]. dsRNA is a potent signaling molecule and inducer of type I interferon (IFN), leading to the production of interferon-stimulated genes (ISGs), and a protective antiviral state within the cell. Research on dsRNA-induced immune responses has relied heavily on a commercially available, and biologically irrelevant dsRNA, polyinosinic:polycytidylic acid (poly I:C). Alternatively, dsRNA can be produced by in vitro transcription (ivt-) dsRNA, with a defined sequence and length. We hypothesized that ivt-dsRNA, containing legitimate viral sequence and length, would be a more appropriate proxy for v-dsRNA, compared with poly I:C. This is the first study to investigate the effects of v-dsRNA on the innate antiviral response and to compare v-dsRNA to ivt-dsRNA-induced responses in fish cells, specifically rainbow trout. Previously, class A scavenger receptors (SR-As) were found to be surface receptors for poly I:C in rainbow trout cells. In this study, ivt-dsRNA binding was blocked by poly I:C and v-dsRNA, as well as SR-A competitive ligands, suggesting all three dsRNA molecules are recognized by SR-As. Downstream innate antiviral effects were determined by measuring IFN and ISG transcript levels using qRT-PCR and antiviral assays. Similar to what has been shown previously with ivt-dsRNA, v-dsRNA was able to induce IFN and ISG transcript production between 3 and 24 h, and its effects were length dependent (i.e., longer v-dsRNA produced a stronger response). Interestingly, when v-dsRNA and ivt-dsRNA were length and sequence matched both molecules induced statistically similar IFN and ISG transcript levels, which resulted in similar antiviral states against two aquatic viruses. To pursue sequence effects further, three ivt-dsRNA molecules of the same length but different sequences (including host and viral sequences) were tested for their ability to induce IFN/ISG transcripts and an antiviral state. All three induced responses similarly. This study is the first of its kind to look at the effects v-dsRNA in fish cells as well as to compare ivt-dsRNA to v-dsRNA, and suggests that ivt-dsRNA may be a good surrogate for v-dsRNA in the study of dsRNA-induced responses and potential future antiviral therapies.

Visualizing Virus-Derived dsRNA Using Antibody-Independent and -Dependent Methods.

Long double-stranded (ds) RNA molecules are produced as a byproduct of viral replication. Studying virus-derived dsRNA is important for understanding virus replication, understanding host responses to virus infections, and as a diagnostic tool for virus presence and replication. Here, we describe four different techniques for visualizing dsRNA; two antibody-dependent methods (immunoblotting and immunocytochemistry), as well as two antibody-independent methods (differential digestion and acridine orange staining). The benefits and disadvantages of each technique are also discussed.

Scavengers for bacteria: Rainbow trout have two functional variants of MARCO that bind to gram-negative and -positive bacteria.

Class A scavenger receptors (SR-As) are a family of surface-expressed receptors who bind a wide range of polyanionic ligands including bacterial components and nucleic acids and play a role in innate immunity. Macrophage receptor with collagenous structure (MARCO) is a SR-A family member that has been studied in mammals largely for its role in binding bacteria. To date there is little information about SR-As in general and MARCO specifically in fish, particularly what ligands individual SR-A family members bind remains largely unknown. In the present study two novel rainbow trout MARCO transcript variants have been identified and their sequence and putative protein domains have been analyzed. When overexpressed in CHSE-214, a cell line that appears to lack functional scavenger receptors, GFP-tagged rtMARCO-1 and rtMARCO-2 were able to bind gram-positive, and gram-negative bacteria of both mammalian and aquatic sources. rtMARCO appears to bind bacteria via its scavenger receptor cysteine-rich (SRCR) domain, because SRCR deleted rtMARCO-1 and -2 were unable to bind bacteria. rtMARCO did not show any binding to the yeast cell wall component zymosan or to double-stranded (ds)RNA. This is the first time rainbow trout MARCO sequences have been identified and the first in-depth study exploring their ligand binding profile. This study provides novel insight into the role of rainbow trout MARCO in bacterial innate immunity.

Identifying connexin expression and determining gap junction intercellular communication in rainbow trout cells.

Gap junctions are groups of membrane-bound channels that allow the passage of small molecules and ions between cells, permitting cell-cell communication. Because of their importance in cell homeostasis, gap junction presence and function were characterized in three commonly studied rainbow trout cell lines, namely RTgill-W1, RTgutGC, and RTG-2. Firstly, gap junction presence was determined by screening for gap junction protein alpha 7 and alpha 1 (GJA7 and GJA1) presence at the transcript level and GJA7 at the protein level. GJA7 was successfully identified at both the transcript and protein levels, and GJA1 was detected at the transcript level in all three cell lines. This is the first report of a GJA7 full-length transcript sequence in rainbow trout cells. Gap junction function, as determined by gap junction intercellular communication (GJIC), was examined using Lucifer yellow dye migration with the scrape and load technique; visualized by fluorescence microscopy. Phorbol 12-myristate 13-acetate (PMA), a gap junction inhibitor, was used to confirm the presence of functional gap junctions. Effects of serum deprivation on GJIC were also monitored; 24-h serum deprivation resulted in greater dye migration compared with 30-min serum deprivation. Both RTG-2 and RTgill-W1 showed significant dye migration that was inhibited by PMA while RTgutGC did not. Human foreskin fibroblast (HFF-1) cells were used as a positive control for gap junction presence and function. Taken together, our study shows that rainbow trout cells express connexin transcripts and proteins, and RTG-2 and, to a lesser extent, RTgill-W1 cells are able to perform GJIC.

Fish interferon-stimulated genes: The antiviral effectors.

Type I interferons (IFN) are the cornerstone cytokine of innate antiviral immunity. In response to a viral infection, IFN signaling results in the expression of a diverse group of genes known as interferon-stimulated genes (ISGs). These ISGs are responsible for interfering with viral replication and infectivity, helping to limit viral infection within a cell. In mammals, many antiviral effector ISGs have been identified and the antiviral mechanisms are at least partially elucidated. In fish fewer ISGs have been identified and while there is evidence they limit viral infection, almost nothing is known of their respective antiviral mechanisms. This review discusses seven ISGs common to mammals and fish and three ISGs that are unique to fish. The lack of understanding regarding fish ISG's antiviral effector functions is highlighted and draws attention to the need for research in this aspect of aquatic innate immunity.

Length-dependent innate antiviral effects of double-stranded RNA in the rainbow trout (Oncorhynchus mykiss) cell line, RTG-2.

Effectively all viruses produce long dsRNA during their replicative cycle. In mammals long dsRNA molecules induce a robust response through the production of type 1 interferon, interferon-stimulated genes (ISGs) and an antiviral state. This response is less well understood in fish. We investigated the ability of a rainbow trout cell line, RTG-2, to respond to two different lengths of in vitro transcribed dsRNA (200 bp and 1264 bp) based on the viral hemorrhagic septicemia virus genomic sequence, and high and low molecular weight poly I:C (synthetic dsRNA). To explore the innate immune response we used qRT-PCR to measure immune gene transcript levels, an ISG-promoter reporter assay, and an antiviral protection assay. We saw a significantly greater immune response in all assays in response to the longer dsRNA molecule compared to their shorter counterpart. We saw significantly more interferon and ISG transcripts, stronger induction of a protective antiviral state, and more robust activation of the ISG-promoter. This response was not found to be due to a better uptake of the longer dsRNA molecules as a cellular uptake assay showed no differences between lengths. These data suggest that dsRNA-mediated innate immune responses are length-dependent and longer molecules induce a more robust response. There were also some differences in the cells response to in vitro transcribed dsRNA compared to poly I:C. This provides important information for potential dsRNA-based antiviral therapies and vaccine adjuvants.

Sensors of Infection: Viral Nucleic Acid PRRs in Fish.

Viruses produce nucleic acids during their replication, either during genomic replication or transcription. These nucleic acids are present in the cytoplasm or endosome of an infected cell, or in the extracellular space to be sensed by neighboring cells during lytic infections. Cells have mechanisms of sensing virus-generated nucleic acids; these nucleic acids act as flags to the cell, indicating an infection requiring defense mechanisms. The viral nucleic acids are called pathogen-associated molecular patterns (PAMPs) and the sensors that bind them are called pattern recognition receptors (PRRs). This review article focuses on the most recent findings regarding nucleic acids PRRs in fish, including: Toll-like receptors (TLRs), RIG-I-like receptors (RLRs), cytoplasmic DNA sensors (CDSs) and class A scavenger receptors (SR-As). It also discusses what is currently known of the downstream signaling molecules for each PRR family and the resulting antiviral response, either type I interferons (IFNs) or pro-inflammatory cytokine production. The review highlights what is known but also defines what still requires elucidation in this economically important animal. Understanding innate immune systems to virus infections will aid in the development of better antiviral therapies and vaccines for the future.

Class-A scavenger receptor function and expression in the rainbow trout (Oncorhynchus mykiss) epithelial cell lines RTgutGC and RTgill-W1.

Class A scavenger receptors (SR-As) are cell surface receptors that bind a range of ligands, including modified low-density lipoproteins (mLDLs) and nucleic acids. Due to their ability to bind extracellular dsRNA, SR-As play an important role in the viral dsRNA initiated immune pathway. Most research on SR-As has focused on mammalian models, and there has been limited research on SR-As in fish. Thus, the presence of functional class A scavenger receptors (SR-As) were investigated in the rainbow trout cell lines, RTgutGC and RTgill-W1. SR-A ligand binding was assessed using fluorescently labeled acetylated-low density lipoprotein (acLDL) and synthetic dsRNA, polyinosinic:polycytidylic acid (poly IC), in combination with a series of known SR-A competitive ligands: fucoidan, dextran sulfate (DxSO4) and polyinosinic acid (poly I). Both cell lines were able to bind acLDL, which was blocked by SR-A competitive ligands. In RTgutGC, acLDL and poly IC competed for binding to the same surface receptor; however, in RTgill-W1 they did not. Poly IC-fluorescein binding was blocked by SR-A competitive ligands in RTgutGC but not RTgill-W1, suggesting an SR-A dependent dsRNA uptake mechanism in RTgutGC and an SR-A-independent update mechanism in RTgill-W1. Both cell lines responded to extracellular dsRNA treatment with the up-regulation of interferons (IFNs) and interferon stimulated genes (ISGs) as measured by quantitative (q)RT-PCR; however, RTgutGC expressed significantly higher transcript levels for both IFNs and ISGs compared with RTgill-W1 following extracellular poly IC treatment. Expression of SR-As, specifically a SCARA4-like sequence, was identified at the transcript level in both cell lines. These results suggest that both RTgill-W1 and RTgutGC express functional SR-As that are able to bind the classic SR-A ligand, acLDL. Although they both express SCARA4, the full SR-A expression profile; however, is likely different between the cell lines, as dsRNA uptake appears to be SR-A dependent in RTgutGC but SR-A-independent in RTgill-W1. Also, dsRNA uptake via SR-As appears to mediate a more robust antiviral response compared with a SR-A independent method of uptake. This study is the first to identify functional SR-As in rainbow trout epithelial cells, and contributes not only to a better understanding of modified LDL transport but also innate immunity in these economically important animals.