Combined therapy (Rho-A-kinase inhibitor and chitosan/collagen porous scaffold) provides a supportive environment for endogenous regenerative processes after spinal cord trauma.

Due to the complexity of pathological processes in spinal cord injury (SCI), it is increasingly recognized that combined strategies are more effective than single treatments. The aim of the present study was to enhance neural tissue regeneration and axon regrowth using Rho-A-kinase inhibitor (Y-27632) in a rat SCI model (Th9 compression) and to bridge the lesion with a chitosan/collagen porous scaffold (ChC-PS) applied two weeks after SCI. In addition, to see the synergic effect of Y-27632 and ChC-PS, we combined these single therapeutic strategies to enhance the regenerative capacity of injured spinal cord tissue. The animals survived eight weeks. Application of Y-27632 modulated the inhibitory milieu by specifically targeting gray and white matter integrity, glial fibrillary acidic protein (GFAP)-immunoreactivity, and the outgrowth of neurofilaments and growth-associated protein-43 (GAP-43) immunoreactive axons across the lesion sites, leading to significant positive functional outcome from day 20 to 56. Compared to single treatments, combined Y-27632/ChC-PS therapy was more effective in neurofilaments and GAP-43 expression and GFAP immunoreactivity in the perilesional area of dorsal, lateral and ventral columns, and in enhancing the gray and white matter integrity throughout the cranio-caudal extent. The findings indicate that combined therapy provides a supportive environment for endogenous regenerative processes.

Immune response of mice to non-adapted avian influenza A virus.

Human infections with avian influenza A viruses (IAVs) without or with clinical symptoms of disease were recently reported from several continents, mainly in high risk groups of people, who came into the contact with infected domestic birds or poultry. It was shown that avian IAVs are able to infect humans directly without previous adaptation, however, their ability to replicate and to cause a disease in this new host can differ. No spread of these avian IAVs among humans has been documented until now, except for one case described in Netherlands in the February of 2003 in people directly involved in handling IAV (H7N7)-infected poultry. The aim of our work was to examine whether a low pathogenic avian IAV can induce a virus-specific immune response of biological relevancy, in spite of its restricted replication in mammals. As a model we used a low pathogenic virus A/Duck/Czechoslovakia/1956 (H4N6) (A/Duck), which replicated well in MDCK cells and produced plaques on cell monolayers, but was unable to replicate productively in mouse lungs. We examined how the immune system of mice responds to the intranasal application of this non-adapted avian virus. Though we did not prove the infectious virus in lungs of mice following A/Duck application even after its multiple passaging in mice, we detected virus-specific vRNA till day 8 post infection. Moreover, we detected virus-specific mRNA and de novo synthesized viral nucleoprotein (NP) and membrane protein (M1) in lungs of mice on day 2 and 4 after exposure to A/Duck. Virus-specific antibodies in sera of these mice were detectable by ELISA already after a single intranasal dose of A/Duck virus. Not only antibodies specific to the surface glycoprotein hemagglutinin (HA) were induced, but also antibodies specific to the NP and M1 of IAV were detected by Western blot and their titers increased after the second exposure of mice to this virus. Importantly, antibodies neutralizing virus A/Duck were proved in mouse immune sera after the second dose of virus and a slight increase of mRNA expression of immune mediators tumor necrosis factor alpha (TNF-α) and IP10 has been observed in lungs of these mice 48 hr after the infection. These observations correspond to the limited replication ability of the virus in mice and provided an important information about its ability to induce virus-specific antibodies, including those neutralizing virus, even without the previous virus adaptation to the new mammalian host. Such antibodies could consequently influence the immune potential of exposed individuals and their defensive capability against the newly emerged, even more virulent IAV.

Virus-neutralizing antibody response of mice to consecutive infection with human and avian influenza A viruses.

In this work we simulated in a mouse model a naturally occurring situation of humans, who overcame an infection with epidemic strains of influenza A, and were subsequently exposed to avian influenza A viruses (IAV). The antibody response to avian IAV in mice previously infected with human IAV was analyzed. We used two avian IAV (A/Duck/Czechoslovakia/1956 (H4N6) and the attenuated virus rA/Viet Nam/1203-2004 (H5N1)) as well as two human IAV isolates (virus A/Mississippi/1/1985 (H3N2) of medium virulence and A/Puerto Rico/8/1934 (H1N1) of high virulence). Two repeated doses of IAV of H4 or of H5 virus elicited virus-specific neutralizing antibodies in mice. Exposure of animals previously infected with human IAV (of H3 or H1 subtype) to IAV of H4 subtype led to the production of antibodies neutralizing H4 virus in a level comparable with the level of antibodies against the human IAV used for primary infection. In contrast, no measurable levels of virus-neutralizing (VN) antibodies specific to H5 virus were detected in mice infected with H5 virus following a previous infection with human IAV. In both cases the secondary infection with avian IAV led to a significant increase of the titer of VN antibodies specific to the corresponding human virus used for primary infection. Moreover, cross-reactive HA2-specific antibodies were also induced by sequential infection. By virtue of these results we suggest that the differences in the ability of avian IAV to induce specific antibodies inhibiting virus replication after previous infection of mice with human viruses can have an impact on the interspecies transmission and spread of avian IAV in the human population.

Heterosubtypic protective immunity against influenza A virus induced by fusion peptide of the hemagglutinin in comparison to ectodomain of M2 protein.

Several types of influenza vaccines are available, but due to the highly unpredictable variability of influenza virus surface antigens (hemagglutinin (HA) and neuraminidase) current vaccines are not sufficiently effective against broad spectrum of the influenza viruses. An innovative approach to extend the vaccine efficacy is based on the selection of conserved influenza proteins with a potential to induce inter-subtype protection against the influenza A viruses. A promising new candidate for the preparation of broadly protective vaccine may be a highly conserved N-terminal part of HA2 glycopolypeptide (HA2 gp) called fusion peptide. To study its capacity to induce a protective immune response, we immunized mice with the fusion peptide (aa 1-38 of HA2 gp). The protective ability of fusion peptide was compared with the ectodomain aa 2-23 of M2 protein (eM2) that is antigenically conserved and its immunogenic properties have already been well documented. Corresponding peptides (both derived from A/Mississippi/1/85 (H3N2) virus) were synthesized and conjugated to the keyhole limpet hemocyanin (KLH) and used for the immunization of mice. Both antigens induced a significant level of specific antibodies. Immunized mice were challenged with the lethal dose of homologous (H3N2) or heterologous A/PR/8/34 (H1N1) influenza A viruses. Immunization with the fusion peptide led to the 100% survival of mice infected with 1 LD50 of homologous as well as heterologous virus. Survival rate decreased when infectious dose was raised to 2 LD50. The immunization with eM2 induced effective cross-protection of mice infected even with 3 LD50 of both challenge viruses. The lower, but still effective protection induced by the fusion peptide of HA2 gp suggested that besides ectodomain of M2, fusion peptide could also be considered as a part of cross-protective influenza vaccine. To our knowledge, this is the first report demonstrating that active immunization with the conjugated fusion peptide of HA2 gp provided the effective production of antibodies, what contributed to the cross-protection against influenza infection.

Trends in development of the influenza vaccine with broader cross-protection.

Influenza A viruses cause in humans acute respiratory infections, which spread yearly in the form of epidemics or pandemics. A high variability and broad host specificity of influenza A viruses are the main reasons of repeated influenza infections. Therefore, no effective prevention against influenza is available today. The main problem of insufficient protection efficacy is that virus-neutralizing antibodies induced by current vaccines are closely strain-specific and the vaccines need to be updated each year. Therefore, various novel approaches to vaccine preparation have been developed with the aim to widen the spectrum of their efficacy. These approaches comprise using new adjuvants as components of the inactivated vaccines, new techniques of live attenuated vaccine preparation (reverse genetics), and new vaccine design focused on the conserved antigens of influenza A viruses inducing protective immunity not only against the influenza viruses antigenically similar (homologous) to vaccine strains, but also against heterologous viruses, even of different subtypes. In this review examples of new approaches to the induction of intersubtype immunity against influenza and their utilization in vaccine preparation are described.

Broadly cross-reactive monoclonal antibodies against HA2 glycopeptide of Influenza A virus hemagglutinin of H3 subtype reduce replication of influenza A viruses of human and avian origin.

The reactivity of monoclonal antibodies (MAbs) prepared to the HA2 glycopeptide (gp) of A/Dunedin/4/73 (H3N2) hemagglutinin was tested against influenza A viruses of H3, H4, and H7 subtypes. Only one (CF2) out of six MAbs reacted with influenza A viruses of all three subtypes (H3, H4 and H7). The inter-subtype reactivity of this MAb (CF2) is in accord with the highly conservative sequence in the previously defined MAb-binding site I, i.e. the aa 1-38 of N-terminus of HA2 gp. MAb CF2 as well as inter-subtype cross-reactive MAb IIF4, recognizing the binding site II of HA2 gp, were tested for their effect on replication of influenza A viruses. Both these MAbs reduced the number of plaques of viruses of homologous (H3) as well as heterologous (H4) virus subtypes, the latter less efficiently. The potential of these MAbs to influence in vivo replication of influenza A viruses of various subtypes is discussed.