Barbara J. Ebersole

Influenza Virus Evades Innate and Adaptive Immunity via the NS1 Protein

ABSTRACT Both antibodies and T cells contribute to immunity against influenza virus infection. However, the generation of strong Th1 immunity is crucial for viral clearance. Interestingly, we found that human dendritic cells (DCs) infected with influenza A virus have lower allospecific Th1-cell stimulatory abilities than DCs activated by other stimuli, such as lipopolysaccharide and Newcastle disease virus infection. This weak stimulatory activity correlates with a suboptimal maturation of the DCs following infection with influenza A virus. We next investigated whether the influenza A virus NS1 protein could be responsible for the low levels of DC maturation after influenza virus infection. The NS1 protein is an important virulence factor associated with the suppression of innate immunity via the inhibition of type I interferon (IFN) production in infected cells. Using recombinant influenza and Newcastle disease viruses, with or without the NS1 gene from influenza virus, we found that the induction of a genetic program underlying DC maturation, migration, and T-cell stimulatory activity is specifically suppressed by the expression of the NS1 protein. Among the genes affected by NS1 are those coding for macrophage inflammatory protein 1β, interleukin-12 p35 (IL-12 p35), IL-23 p19, RANTES, IL-8, IFN-α/β, and CCR7. These results indicate that the influenza A virus NS1 protein is a bifunctional viral immunosuppressor which inhibits innate immunity by preventing type I IFN release and inhibits adaptive immunity by attenuating human DC maturation and the capacity of DCs to induce T-cell responses. Our observations also support the potential use of NS1 mutant influenza viruses as live attenuated influenza virus vaccines.

Validated genomic approach to study differentially expressed genes in complex tissues.

Microarray-based genomic techniques allow the simultaneous determination of relative levels of expression of a large number of genes. Studies of the transcriptome in complex neurobiological systems are uniquely demanding due to the heterogeneous nature of these cells. Most brain regions contain a large variety of cell populations that are closely intermingled. The expression of any specific gene may be restricted to a subpopulation of cells, and changes in gene expression may occur in only a small fraction of the cells expressing that transcript. Due to this dilution effect, many genes of interest are expected to have relatively low levels of expression in tissue homogenates. Furthermore, biologically significant differences in expression may result in only small fold-changes. Therefore genomic approaches using brain dissections must be optimized to identify potentially regulated transcripts and differential expression should be confirmed using quantitative assays. We evaluated the effects of increasing tissue complexity on detection of regulated transcripts in focused microarray studies using a mouse cell line, mouse hypothalamus and mouse cortex. Regulated transcripts were confirmed by quantitative real-time PCR. As tissue complexity increased, distinguishing significantly regulated genes from background variation became increasingly more difficult. However, we found that cDNA microarray studies using regional brain dissections and appropriate numbers of replicates could identify genes showing less than 2-fold regulation and that most regulated genes identified fell within this range.

Evaluation of the role of the D2 dopamine receptor in myoclonus dystonia

A novel Val154→Ile mutation in the D2 dopamine receptor (DRD2) on chromosome 11q23 has recently been shown to be associated with myoclonus dystonia (M‐D) in one large family. Sequence analysis of the DRD2 gene in 5 M‐D patients from different families did not reveal any mutations, nor was there evidence of linkage to the 11q23 region in the DRD2 gene in four other families. Receptor binding and signal transduction assays of the DRD2 mutant and wild‐type receptors revealed identical agonist and antagonist affinities and functional responses. These studies suggest that M‐D is genetically heterogeneous. The molecular mechanisms through which the Val→Ile mutation may contribute to M‐D remain to be determined. Ann Neurol 2000;47:369–373

Conserved helix 7 tyrosine functions as an activation relay in the serotonin 5HT2C receptor

The function of the helix VII Tyr in the conserved Asn-Pro-X-X-Tyr segment of rhodopsin-like G protein coupled receptors has been investigated in many receptors. Various effects of site-directed mutation of this locus have been found, including altered coupling, sequestration and agonist affinity. We report the first constitutively active mutations of this Tyr. In the serotonin 5HT(2C) receptor, substituting Ala or Cys for Tyr resulted in a marked increase in the basal level of inositol phosphate accumulation in transfected COS-1 cells. This constitutive signaling was abolished by the inverse agonist SB206553. Introducing Phe at this locus eliminated both basal and agonist-stimulated signaling. All three mutant receptors showed an increase in binding affinity for the structurally dissimilar agonists 5-hydroxytryptamine (5HT), (+/-)-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane (DOI), and quipazine, suggesting that both the activating and inactivating mutations stabilize a high affinity state. These results implicate the conserved Tyr in the conformational rearrangements that occur during agonist complexing and receptor activation.