Restorative benefits of transplanting human mesenchymal stromal cells overexpressing arginine decarboxylase genes after spinal cord injury.

BACKGROUND AIMS: Mesenchymal stromal cells (MSCs) promote functional recovery in central nervous system (CNS) injury. Neuroprotective effects of MSCs are being tested in clinical trials for the treatment of CNS injury; however, the underlying mechanisms remain unclear. Arginine decarboxylase (ADC) is a rate-limiting enzyme of agmatine synthesis and is known to exist in the CNS of mammals. The present study investigated whether transplantation of ADC-overexpressing human MSCs (ADC-hMSCs) after spinal cord injury (SCI) could increase the production of neurotrophic factors and promote cell survival, differentiation, axonal regeneration and the restoration of functional recovery. METHODS: Retroviral human ADC was constructed with the use of an LXSN vector. After compression injury in thoracic level 9, PKH26-labeled ADC-hMSCs were transplanted into the dorsolateral funiculus 1 mm rostral and caudal to the lesion site. The tissues were sampled at 2, 4 and 10 weeks after SCI. RESULTS: Behavioral analysis revealed that locomotor functions of the ADC-hMSC group were significantly restored. Histological analysis showed that the fibrotic scar volume was smaller in the ADC-hMSC-injected group than in any other group. Brain-derived neurotrophic factor level was significantly higher in the ADC-hMSC-injected group than in any other group throughout 10 weeks. Terminal deoxynucleotidyl transferase-mediated nick-end labeling assay showed decreased cell death, and co-localization analysis showed significant increase in the number of neurons and oligodendrocytes originating from transplanted hMSCs when they had been transduced with the ADC gene. CONCLUSIONS: The results suggested that ADC-hMSCs are a more suitable candidate than hMSCs for stem cell therapy after SCI.

Prokaryote-expressed M2e protein improves H9N2 influenza vaccine efficacy and protection against lethal influenza A virus in mice.

BACKGROUND: Influenza vaccines are prepared annually based on global epidemiological surveillance data. However, since there is no method by which to predict the influenza strain that will cause the next pandemic, the demand to develop new vaccination strategies with broad cross-reactivity against influenza viruses are clearly important. The ectodomain of the influenza M2 protein (M2e) is an attractive target for developing a vaccine with broad cross-reactivity. For these reasons, we investigated the efficacy of an inactivated H9N2 virus vaccine (a-H9N2) mixed with M2e (1xM2e or 4xM2e) proteins expressed in Escherichia coli, which contains the consensus of sequence the extracellular domain of matrix 2 (M2e) of A/chicken/Vietnam/27262/09 (H5N1) avian influenza virus, and investigated its humoral immune response and cross-protection against influenza A viruses. RESULTS: Mice were intramuscularly immunized with a-H9N2, 1xM2e alone, 4xM2e alone, a-H9N2/1xM2e, or a-H9N2/4xM2e. Three weeks post-vaccination, mice were challenged with lethal homologous (A/ chicken /Korea/ma163/04, H9N2) or heterosubtypic virus (A/Philippines/2/82, H3N2 and A/aquatic bird/Korea/maW81/05, H5N2). Our studies demonstrate that the survival of mice immunized with a-H9N2/1xM2e or with a-H9N2/4xM2e (100% survival) was significantly higher than that of mouse-adapted H9N2 virus-infected mice vaccinated with 1xM2e alone or with 4xM2e alone (0% survival). We also evaluated the protective efficacy of the M2e + vaccine against infection with mouse-adapted H5N2 influenza virus. Protection from death in the control group (0% survival) was similar to that of the 1×M2e alone and 4xM2e alone-vaccinated groups (0% survival). Only 40% of mice vaccinated with vaccine alone survived challenge with H5N2, while the a-H9N2/1×M2e and a-H9N2/4×M2e groups showed 80% and 100% survival following mouse-adapted H5N2 challenge, respectively. We also examined cross-protection against human H3N2 virus and found that the a-H9N2/1×M2e group displayed partial cross-protection against H3N2 (40% survival), whereas vaccine alone, 1×M2e alone, 4×M2e alone, or H9N2/1×M2e groups showed incomplete protection (0% survival) in response to challenge with a lethal dose of human H3N2 virus. CONCLUSIONS: Taken together, these results suggest that prokaryote-expressed M2e protein improved inactivated H9N2 virus vaccine efficacy and achieved cross-protection against lethal influenza A virus infection in mice.