Cationic lipid/DNA complex-adjuvanted influenza A virus vaccination induces robust cross-protective immunity.

Influenza A virus is a negative-strand segmented RNA virus in which antigenically distinct viral subtypes are defined by the hemagglutinin (HA) and neuraminidase (NA) major viral surface proteins. An ideal inactivated vaccine for influenza A virus would induce not only highly robust strain-specific humoral and T-cell immune responses but also cross-protective immunity in which an immune response to antigens from a particular viral subtype (e.g., H3N2) would protect against other viral subtypes (e.g., H1N1). Cross-protective immunity would help limit outbreaks from newly emerging antigenically novel strains. Here, we show in mice that the addition of cationic lipid/noncoding DNA complexes (CLDC) as adjuvant to whole inactivated influenza A virus vaccine induces significantly more robust adaptive immune responses both in quantity and quality than aluminum hydroxide (alum), which is currently the most widely used adjuvant in clinical human vaccination. CLDC-adjuvanted vaccine induced higher total influenza virus-specific IgG, particularly for the IgG2a/c subclass. Higher levels of multicytokine-producing influenza virus-specific CD4 and CD8 T cells were induced by CLDC-adjuvanted vaccine than with alum-adjuvanted vaccine. Importantly, CLDC-adjuvanted vaccine provided significant cross-protection from either a sublethal or lethal influenza A viral challenge with a different subtype than that used for vaccination. This superior cross-protection afforded by the CLDC adjuvant required CD8 T-cell recognition of viral peptides presented by classical major histocompatibility complex class I proteins. Together, these results suggest that CLDC has particular promise for vaccine strategies in which T cells play an important role and may offer new opportunities for more effective control of human influenza epidemics and pandemics by inactivated influenza virus vaccine.

Human CD4+ T cell recent thymic emigrants are identified by protein tyrosine kinase 7 and have reduced immune function.

CD4(+) recent thymic emigrants (RTEs) comprise a clinically and immunologically important T cell population that indicates thymic output and that is essential for maintaining a diverse alphabeta-T cell receptor (TCR) repertoire of the naive CD4(+) T cell compartment. However, their frequency and function are poorly understood because no known surface markers distinguish them from older non-RTE naive CD4(+) T cells. We demonstrate that protein tyrosine kinase 7 (PTK7) is a novel marker for human CD4(+) RTEs. Consistent with their recent thymic origin, human PTK7(+) RTEs contained higher levels of signal joint TCR gene excision circles and were more responsive to interleukin (IL)-7 compared with PTK7(-) naive CD4(+) T cells, and rapidly decreased after complete thymectomy. Importantly, CD4(+) RTEs proliferated less and produced less IL-2 and interferon-gamma than PTK7(-) naive CD4(+) T cells after alphabeta-TCR/CD3 and CD28 engagement. This immaturity in CD4(+) RTE effector function may contribute to the reduced CD4(+) T cell immunity observed in contexts in which CD4(+) RTEs predominate, such as in the fetus and neonate or after immune reconstitution. The ability to identify viable CD4(+) RTEs by PTK7 staining should be useful for monitoring thymic output in both healthy individuals and in patients with genetic or acquired CD4(+) T cell immunodeficiencies.