High non-specific T lymphocyte response to the adjuvanted H1N1 vaccine in comparison with the H1N1/H3N2/B-Brisbane vaccine without adjuvant.

Shortly after the report of pandemic 2009 influenza A (H1N1), vaccine manufacturers, in conjunction with public agencies, started developing a H1N1 vaccine. In 2009, various approaches were implemented around the globe. The United States and Australia finally approved only non-adjuvanted H1N1 influenza vaccines, whereas Canada and the EU also approved adjuvanted vaccines. In 2010, seasonal influenza vaccine without adjuvant was again widely accepted in both hemispheres. The addition of adjuvant to the vaccine enhances the immunogenity of the vaccine in the presence of a relatively low amount of antigen. However, it might also induce undesirable non-specific immune response. For this reason, we conducted a prospective observational study to monitor T cell absolute count and H1N1-specific immunogenicity after 2009 and 2010 immunization. Fourteen healthy volunteers received the monovalent H1N1 AS03 adjuvanted influenza vaccine (3.5 µg of H1N1 and squalene-based adjuvant) in October 2009. The immunization was associated with a significant increase in T lymphocyte absolute count (P < 0.0001), reaching abnormal values in 57% of subjects. During this period, none of the subject showed any manifestation of severe viral infection or inflammation. Acute infection by CMV or EBV viruses was also excluded. In October 2010, the same subjects received a seasonal non-adjuvanted influenza vaccine (15 µg of each: H1N1, H3N2, and B-Brisbane). However, after 2010 immunization, no change in T lymphocyte absolute count was observed. H1N1-induced immunogenicity was good for both vaccines. Our results suggest a pronounced non-specific T cell response after AS03-adjuvanted 2009 H1N1 vaccination.

Jasmonic acid inducible aspartic proteinase inhibitors from potato.

A new cDNA clone coding for an aspartic proteinase inhibitor homologue was isolated from a potato tuber cDNA library. Southern blot analysis was used to study the structural diversity of the aspartic proteinase inhibitor gene family in several species of the Solanaceae. The existence of sequence-homologous genes was confirmed in the genomic DNA of different potato cultivars (Solanum tuberosum L. cv. Désirée, Pentland Squire and Igor), tomato (Lycopersicon esculentum Mill.), aubergine (S. melongena L.) and a wild type of bittersweet (S. dulcamara L.). Northern blot hybridization of total RNA, isolated from leaves under non-stress conditions, of different solanaceous species and of potato tubers showed that the gene transcripts encoding aspartic proteinase inhibitors occur mainly in potato tubers. The presence of several cathepsin D inhibitor isoforms has been detected at the protein level. At least four isoforms were isolated by affinity chromatography on cathepsin D-Sepharose and characterized. Additionally, exogenous treatment of potato plantlets by jasmonic acid (JA) over a wide range of concentrations (0-100 microM) was performed in a stem node culture in vitro. We demonstrated that the expression of aspartic proteinase inhibitor mRNA was drastically induced in potato shoots at concentrations of 50-100 microM JA.

The amino acid sequence of a novel inhibitor of cathepsin D from potato.

The amino acid sequence of a cathepsin D inhibitor isolated from potato is described. It was determined by analysis of peptides generated by use of the glycine-specific proteinase PPIV. The order of the peptides was established by examination of tryptic peptides derived from the two cyanogen bromide peptides. The inhibitor comprises 187 amino acid residues, and has a calculated Mr of 20,450.