Investigation of the human antibody response to influenza virus infection has been largely limited to serology, with relatively little analysis at the molecular level. The 1918 H1N1 influenza virus pandemic was the most severe of the modern era 1 . Recent work has recovered the gene sequences of this unusual strain 2 , so that the 1918 pandemic virus could be reconstituted to display its unique virulence phenotypes 3,4 . However, little is known about adaptive immunity to this virus. We took advantage of the 1918 virus sequencing and the resultant production of recombinant 1918 hemagglutinin (HA) protein antigen to characterize at the clonal level neutralizing antibodies induced by natural exposure of survivors to the 1918 pandemic virus. In our study, each of 32 individuals tested that were born in or before 1915 exhibited seroreactivity with 1918 virus, nearly 90 years after the pandemic. Seven of 8 donor samples tested had circulating B cells that secreted antibodies that bound 1918 HA. We isolated B cells from subjects and generated five monoclonal antibodies that exhibited potent neutralizing activity against 1918 virus from three separate donors. These antibodies also cross-reacted with the genetically similar HA of a 1930 swine H1N1 influenza strain, but not with HAs of more contemporary human influenza viruses. The antibody genes exhibited an unusually Correspondence should be addressed to JEC (James.Crowe@vanderbilt.edu), CFB (Chris.Basler@mssm.edu) or ELA (Eric.Altschuler@umdnj.edu). Supplementary Information is linked to the online version of the paper at www.nature.com/nature.Author Contributions XY and TT contributed equally to this work. XY, PAM, MDH and FSH made and cloned the mAbs, sequenced antibody genes, and performed IF experiments, CJK performed biosensor studies, TMT, CP, and LAP designed and performed in vivo studies, OM sequenced the HA genes of the H1N1 viruses used in this study and performed ELISA assays with these viruses. PVA assisted with HAI and neutralization assays and with cloning of recombinant HA molecules. JS and IAW provided recombinant HA; ELA led the clinical recruitment, ELA, CFB and JEC conceived of the experimental plan. CFB and JEC wrote the manuscript. All authors discussed the results and commented on the manuscript.Antibody nucleotide sequences are deposited in GenBank, accession numbers EU169674 through EU169679 and EU825947 through EU825950.Reprints and permissions information is available at npg.nature.com/reprints and permissions.The authors declare no competing financial interests. NIH Public Access Author ManuscriptNature. Author manuscript; available in PMC 2010 April 3. . We collected transformed cells from the wells corresponding to supernates exhibiting the highest levels of specific binding to the 1918 HA (derived from five donors) and fused them to the HMMA2.5 nonsecreting myeloma partner 7 using an electrofusion technique 8 . We isolated 17 unique hybridoma cell lines that secreted antibodies reactive with the 1918 HA from cell lines derived fro...
We sought to develop and optimize a hybridoma-based technology for generating human hybridomas that secrete virus-specific monoclonal antibodies for clinical diagnosis and therapy. We developed a novel electrofusion protocol for efficiently fusing Epstein-Barr virus (EBV)-transformed human B cells with myeloma partners. We tested seven myeloma cell lines and achieved highest efficiency when the HMMA 2.5 line was used. We optimized the electrofusion process by improving cell treatments before and after electrofusion as well as varying cell ratios, fusion medium and other experimental parameters. Our fusion efficiency increased remarkably to 0.43%, a significant improvement over the efficiency of previous PEG-based or other electrofusion methods. Using the optimized protocol, we obtained human hybridomas that secrete fully human monoclonal antibodies against two major human respiratory pathogens: respiratory syncytial virus (RSV) and an influenza H3N2 vaccine virus strain. In conclusion, we have developed an efficient and routine approach for the generation of human hybridomas secreting functional human virus-specific monoclonal antibodies.
Saccharomyces cerevisiae opi3 mutant strains do not have the phospholipid N-methyltransferase that catalyzes the two terminal methylations in the phosphatidylcholine (PC) biosynthetic pathway. This results in a build up of the intermediate phosphatidylmonomethylethanolamine, causing a temperature-sensitive growth phenotype. An Arabidopsis cDNA library was used to isolate three overlapping plasmids that complemented the temperature-sensitive phenotype. Phospholipid analysis showed that the presence of the cloned cDNA caused a 65-fold reduction in the level of phosphatidylmonomethylethanolamine and a significant, though not equivalent, increase in the production of PC. Sequence analysis established that the cDNA was not homologous to OPI3 or to CHO2, the only other yeast phospholipid N-methyltransferase, but was similar to several other classes of methyltransferases. S-adenosyl-Met:phospho-base N-methyltransferase assays revealed that the cDNA catalyzed the three sequential methylations of phospho-ethanolamine to form phospho-choline. Phospho-choline is converted to PC by the CDP-choline pathway, explaining the phenotype conferred upon the yeast mutant strain by the cDNA. In accordance with this the gene has been named AtNMT1. The identification of this enzyme and the failure to isolate a plant phospholipid N-methyltransferase suggests that there are fundamental differences between the pathways utilized by yeast and by some plants for synthesis of PC.
The 2009 pandemic influenza A (H1N1) virus exhibits hemagglutinin protein sequence homology with the 1918 pandemic influenza virus. We found that human monoclonal antibodies recognized the Sa antigenic site on the head domains of both 1918 and 2009 hemagglutinins, a site that is hypervariable due to immune selection. These antibodies exhibited high potency against the 2009 virus in vitro, and one exerted a marked therapeutic effect in vivo.
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