Immunostimulating RNA Delivered by P1500 PEGylated Cationic Liposomes Limits Influenza Infection in C57Bl/6 Mice.

The emergence of highly pathogenic viruses and a high speed of infection spread put forward the problem of the development of novel antivirals and their delivery vehicles. In this study, we investigated the antiviral effect of the previously identified immunostimulatory 19-bp dsRNA (isRNA) with 3'-nucleotide overhangs, which stimulates interferon α synthesis when delivered using cationic liposomes consisting of 1,26-bis(cholest-5-en-3ß-yloxycarbonylamino)-7,11,16,20-tetraazahexacosan tetrahydrochloride and lipid-helper dioleoylphosphatidylethanolamine and its PEGylated formulation P1500 in vitro and in vivo. In vitro data showed that isRNA/2X3-DOPE complexes protected L929 cells from encephalomyocarditis virus infection, while isRNA/P1500 complexes were not active, which correlates with their lower transfection activity in cell culture. Comparison of the interferon-inducing activity of isRNA in BALB/c, CBA and C57Bl/6 mice showed that PEGylated liposomes significantly enhance the interferon-inducing activity of isRNA in vivo. The antiviral efficacy of the isRNA in vivo was considerably affected by the delivery system. The cationic liposomes 2X3-DOPE did not enhance the antiviral properties of isRNA in vivo. Similar liposomes equipped with a PEGylated lipoconjugate provided a pronounced anti-influenza effect of the isRNA in vivo. Administration of isRNA to C57Bl/6 led to a decrease in virus titers in the lungs and a significant decrease in the severity of the infection. Administration of a similar formulation to BALB/c mice caused only a mild antiviral effect at the initial stages of the infection. The data show that isRNA in combination with the PEGylated delivery system can be considered an effective means of suppressing influenza A infection.

Oncolytic virus efficiency inhibited growth of tumour cells with multiple drug resistant phenotype in vivo and in vitro.

BACKGROUND: Tumour resistance to a wide range of drugs (multiple drug resistant, MDR) acquired after intensive chemotherapy is considered to be the main obstacle of the curative treatment of cancer patients. Recent work has shown that oncolytic viruses demonstrated prominent potential for effective treatment of diverse cancers. Here, we evaluated whether genetically modified vaccinia virus (LIVP-GFP) may be effective in treatment of cancers displaying MDR phenotype. METHODS: LIVP-GFP replication, transgene expression and cytopathic effects were analysed in human cervical carcinomas KB-3-1 (MDR-), KB-8-5 (MDR+) and in murine melanoma B-16 (MDR-), murine lymphosarcomas RLS and RLS-40 (MDR+). To investigate the efficacy of this therapy in vivo, we treated immunocompetent mice bearing murine lymphosarcoma RLS-40 (MDR+) (6- to 8-week-old female CBA mice; n = 10/group) or melanoma B-16 (MDR-) (6- to 8-week-old female C57Bl mice; n = 6/group) with LIVP-GFP (5 × 10(7) PFU of virus in 0.1 mL of IMDM immediately and 4 days after tumour implantation). RESULTS: We demonstrated that LIVP-GFP replication was effective in human cervical carcinomas KB-3-1 (MDR-) and KB-8-5 (MDR+) and in murine melanoma B-16 (MDR-), whereas active viral production was not detected in murine lymphosarcomas RLS and RLS-40 (MDR+). Additionally, it was found that in tumour models in immunocompetent mice under the optimized regimen intratumoural injections of LIVP-GFP significantly inhibited melanoma B16 (33 % of mice were with complete response after 90 days) and RLS-40 tumour growth (fourfold increase in tumour doubling time) as well as metastasis. CONCLUSION: The anti-tumour activity of LIVP-GFP is a result of direct oncolysis of tumour cells in case of melanoma B-16 because the virus effectively replicates and destroys these cells, and virus-mediated activation of the host immune system followed by immunologically mediated destruction of of tumour cells in case of lymphosarcoma RLS-40. Thus, the recombinant vaccinia virus LIVP-GFP is able to inhibit the growth of malignant cells with the MDR phenotype and tumour metastasis when administered in the early stages of tumour development.

Artificial ribonucleases inactivate a wide range of viruses using their ribonuclease, membranolytic, and chaotropic-like activities.

Artificial ribonucleases (aRNases) are small compounds catalysing RNA cleavage. Recently we demonstrated that aRNases readily inactivate various viruses in vitro. Here, for three series of aRNases (1,4-diazabicyclo [2.2.2]octane-based and peptide-like compounds) we show that apart from ribonuclease activity the aRNases display chaotropic-like and membranolytic activities. The levels of membranolytic and chaotropic-like activities correlate well with the efficiency of various viruses inactivation (enveloped, non-enveloped, RNA-, DNA-containing). We evaluated the impact of these activities on the efficiency of virus inactivation and found: i) the synergism between membranolytic and chaotropic-like activities is sufficient for the inactivation of enveloped viruses (influenza A, encephalitis, vaccinia viruses) for 1,4-diazabicyclo [2.2.2]octane based aRNases, ii) the inactivation of non-enveloped viruses (encephalomyocarditis, acute bee paralysis viruses) is totally dependent on the synergism of chaotropic-like and ribonuclease activities, iii) ribonuclease activity plays a leading role in the inactivation of RNA viruses by aRNases Dp12F6, Dtr12 and K-D-1, iv) peptide-like aRNases (L2-3, K-2) being effective virus killers have a more specific mode of action. Obtained results clearly demonstrate that aRNases represent a new class of broad-spectrum virus-inactivating agents.

Influenza virus inactivated by artificial ribonucleases as a prospective killed virus vaccine.

The inactivation of viral particles with agents causing minimal damage to the structure of surface epitopes is a well-established approach for the production of killed virus vaccines. Here, we describe new agents for the inactivation of influenza virus, artificial ribonucleases (aRNases), which are chemical compounds capable of cleaving RNA molecules. Several aRNases were identified, exhibiting significant virucidal activity against the influenza A virus and causing a minimal effect on the affinity of monoclonal antibodies for the inactivated virus. Using a murine model of the influenza virus infection, a high protective activity of the aRNase-inactivated virus as a vaccine was demonstrated. The results of the experiments demonstrate the efficacy of novel chemical agents in the preparation of vaccines against influenza and, perhaps, against other infections caused by RNA viruses.

Inactivation of the tick-borne encephalitis virus by RNA-cleaving compounds.

The tick-borne encephalitis virus (TBEV) is an RNA-containing enveloped virus, which poses a major threat to the well-being and health of humans. In this study, we describe an approach to the inactivation of TBEV, which involves the degradation of viral RNA by artificial ribonucleases (aRNases, small organic compounds that exhibit ribonuclease activity in vitro). We demonstrate that the incubation of TBEV with aRNases lead to the total inactivation of the virus as indicated by the plaque formation assay data, but retain the viral immunogenic properties, as shown by the ELISA data. We propose that a possible mechanism of TBEV inactivation with aRNase, which includes: i) formation of local breaks in the lipid membrane of the virus caused by aRNase, ii) penetration of aRNase into the viral capsid, iii) degradation of genomic RNA by aRNase. These data suggest that the proposed approach can be used in the production of killed-virus vaccine.

Chimeric antibodies against tick-borne encephalitis virus.

Two chimeric antibodies (ch) 13D6 and 10C2 against the glycoprotein E of tick-borne encephalitis virus (TBEV) were constructed by fusing variable regions of murine monoclonal antibodies (Mabs) 13D6 and 10C2 to human constant regions. Monovalent analogues of these antibodies in format of single-chain antibodies (scFv or sc) were developed, as well. The ch13D6, ch10C2, sc13D6 and sc10C2 exhibited binding characteristics similar to parental Mabs. Only the ch13D6 and sc13D6 were able to neutralize TBEV infectivity in vitro. The in vitro neutralization provided by ch13D6 suggests that this antibody can be further developed into a potent prophylaxis and therapy for tick-borne encephalitis (TBE) infection.

Female scent signals enhance the resistance of male mice to influenza.

BACKGROUND: The scent from receptive female mice functions as a signal, which stimulates male mice to search for potential mating partners. This searching behavior is coupled with infection risk due to sniffing both scent marks as well as nasal and anogenital areas of females, which harbor bacteria and viruses. Consideration of host evolution under unavoidable parasitic pressures, including helminthes, bacteria, viruses, etc., predicts adaptations that help protect hosts against the parasites associated with mating. METHODS AND FINDINGS: We propose that the perception of female signals by BALB/c male mice leads to adaptive redistribution of the immune defense directed to protection against respiratory infection risks. Our results demonstrate migration of macrophages and neutrophils to the upper airways upon exposure to female odor stimuli, which results in an increased resistance of the males to experimental influenza virus infection. This moderate leukocyte intervention had no negative effect on the aerobic performance in male mice. CONCLUSIONS: Our data provide the first demonstration of the adaptive immunological response to female odor stimuli through induction of nonspecific immune responses in the upper respiratory tract.

A study of systems for delivering antigens and plasmid DNA for intranasal immunization against tick-borne encephalitis virus.

Our previous studies indicated the possibility for some neurotropic viruses to spread into the brain of immune animals through the olfactory pathway. Thus, nasal mucosa in the olfactory region is likely to be a promising target for mucosal immunization to protect the CNS from neurotropic viral infections. THE MAIN IDEA OF THE RESEARCH: Intranasal immunization inducing mucosal and systemic immune responses blocks the propagation of neurotropic virus into the brain via the olfactory pathway and neutralizes the multiplication of virus in visceral organs, allowing more effective protection against neurotropic infections transmitted by bloodsucking arthropods to be achieved. Thus, study of the efficiency of delivery systems for intranasal immunization against tick-borne encephalitis (TBE) virus is an urgent task in the development of anti-TBE mucosal vaccine. To study intranasal immunization against TBE virus, we have chosen four delivery systems (DSs), namely, (i) biodegradable microparticles, (ii) cationic liposomes, and live attenuated (iii) bacterial and (iv) viral vectors. The gene of TBE virus protein E was inserted into the pcDNA3 plasmid (designated as pcDNA3/E-TBE). Three types of delivery system for plasmid DNA were developed and studied in vitro. The first system, artificial virus-like microparticles (VLP), consists of polyglycan-spermidine complexes that cover pcDNA3/E-TBE DNA. The second system is cationic liposomes with DNA of the plasmid pcDNA3/E-TBE. The third system is an attenuated Salmonella strain containing pcDNA3/E-TBE. The fourth system is a recombinant vaccinia strain with inserted genes of TBE virus proteins C, prM, E, NS1, NS2a, NS2b, and NS3. The DSs were tested in COS-7 and CV-1 cell lines and macrophages by ELISA of cell lysate. The results obtained showed the expression of the E gene in transfected cells, thereby demonstrating that these DSs are suitable for mucosal immunization. High levels of immune response shifted to the Th1 type were detected in BALB/c mice following intranasal immunization with recombinant vaccinia-TBE strain and VLP-pcDNA3/E-TBE. The mice immunized intranasally with recombinant vaccinia-TBE strains were completely protected against intraperitoneal challenge with TBE virus strain Sofjin, whereas intranasal immunization with killed TBE vaccine failed to induce a significant level of protection.