Dengue virus: molecular basis of cell entry and pathogenesis, 25-27 June 2003, Vienna, Austria.

Multivalent dengue vaccines now in late stage development pose unique vaccine safety challenges in that primary or secondary vaccine failures might place vaccines at risk to antibody-dependent enhanced (ADE) wild-type dengue infections. This conference was organized to address this unique vaccine safety issue. New data were presented on the structure of dengue and other flaviviruses, the cellular receptors of dengue virus for biologically relevant cells, dengue viral cell entry mechanisms and mechanisms underlying in vivo protection, neutralization and enhancement of dengue virus infection. It was concluded that a targeted research program should aim to develop an in vitro test to characterize persons immunized with dengue vaccines as completely or partially protected. Achievement of this aim will require a better understanding of the basic mechanisms by which dengue viruses recognize, attach, enter and infect relevant human cells and how antibodies protect against dengue infections.

Molecular determinants of virulence of West Nile virus in North America.

West Nile virus (WNV) is a mosquito-borne flavivirus that until very recently had not been found in the Americas. In 1999, there was an outbreak of West Nile encephalitis in New York and surrounding areas, involving 62 human cases, including 7 fatalities. The virus has subsequently become established in the United States of America (U.S.) with 4156 human cases, including 284 deaths, in 2002. The WNV strains found in the U.S. are members of "lineage I", a genetic grouping that includes viruses from Europe, Asia and Africa. Molecular epidemiologic studies indicate that two genetic variants of WNV emerged in 2002. The major genetic variant is found in most parts of the U.S., while the minor genetic variant has been identified only on the southeast coast of Texas. Investigation of WNV in mouse and hamster models demonstrated that strains from the U.S. are highly neurovirulent and neuroinvasive in these laboratory rodents. Other strains, such as Ethiopia 76a from lineage I, are not neuroinvasive and represent important viruses which can be used to elucidate the molecular basis of virulence and attenuation of WNV. To identify putative molecular determinants of virulence and attenuation, we have undertaken comparative nucleotide sequencing of Ethiopia 76a and strains from the U.S. The results show that the two viruses differ by 5 amino acids in the envelope (E) protein, including loss of the glycosylation site. Comparison of our panel of 27 WNV strains suggests that E protein glycosylation is a major determinant of the mouse neuroinvasive phenotype.