Ribbon diagram of the Viet04 trimer. The three monomers are colored blue, green, and gray. The receptor binding site on one monomer is highlighted.

The HA homotrimer is responsible for viral binding to host receptors containing glycans (complex sugar chains) terminated by sialic acids; avian viruses preferentially bind to sugar receptors with sialic acid in an α2-3 linkage, whereas human-adapted viruses prefer sialic acids in an α2-6 linkage. The researchers utilized a number of technologies to study the structure–function relationship of an HA from a highly pathogenic H5N1 influenza virus, A/Vietnam/1203/2004 (Viet04). Functional HA trimers were produced in a baculovirus expression system, eliminating the difficulty and hazard of extracting the HA from live influenza viruses. Three hundred and eighty-four crystallization conditions were tested using less than 6 µL of protein material. The most promising condition based on crystal quality was translated to sitting-drop conditions, and subsequent optimization of these conditions yielded diffraction-quality crystals. The Viet04 HA structure was then solved by molecular replacement to 2.95-Å resolution from data collected at ALS Beamline 8.2.2.

The resulting Viet04 HA trimer structure is very similar to other avian, human, and swine HAs, with a globular head containing the receptor binding domain and a vestigial esterase domain, and a membrane proximal domain with its distinctive, central alpha-helical stalk and HA1/HA2 cleavage site. Comparison of human, avian, and swine HA structures revealed that the Viet04 HA is more closely related to human 1918 H1 HA than to the other HA structures, including a related 1997 duck H5 HA (A/Duck/Singapore/3/1997).

The same HA protein can also be used to analyze HA receptor specificity using a recently described technique involving a glycan microarray—a glass slide imprinted with hundreds of different glycan chains to systematically analyze their binding properties. Glycan microarray analysis of Viet04 HA revealed a preference for binding to avian α2-3 sialic acid receptors. The introduction of mutations that can convert H1 serotype HAs to human α2-6 receptor specificity only enhanced or reduced affinity for avian-type receptors. However, the introduction of mutations at positions 226 and 228, which are known to convert avian H2 and H3 HAs to human receptor specificity, permitted binding to natural human biantennary α2-6 glycans.

Top: Glycan microarray analysis of the wild-type Viet04 reveals avian preference. Bottom: Mutations at positions 226 and 228 result in a reduction in preference for avian receptor analogs and an increase in human biantennary glycans.

Thus, these mutations on the H5 HA not only reduced avidity to avian sialosides, they increased specificity for human α2-6–linked biantennary N-linked glycans, which could serve as receptors on lung epithelial cells. These combined effects could allow the Viet04 virus to escape entrapment by mucins in the lungs and increase binding to susceptible human epithelial cells. These mutations therefore provide only one possible route by which H5 viruses could gain a foothold in the human population, but other mutations are likely required to facilitate the complete switch in receptor specificity that appears to be critical for human-to-human transmission.

Research conducted by J. Stevens, O. Blixt, J.C. Paulson, and I.A. Wilson (The Scripps Research Institute); T.M. Tumpey (Centers for Disease Control and Prevention); and J.K. Taubenberger (Armed Forces Institute of Pathology).

Research funding: National Institutes of Health and Skaggs Institute for Chemical Biology. Operation of the ALS is supported by the U.S. Department of Energy, Office of Basic Energy Sciences (BES).

ALSNews Vol. 278, July 25, 2007