Associate Provost for Research Boston University Medical Campus
NHLBI - National Heart, Lung & Blood	Research Resources

Abstract

Abstract: DESCRIPTION (provided by applicant): Influenza A virus (IAV) is a major threat due to evasion of adaptive immunity through genetic variation. Innate defenses, including surfactant protein D (SP-D) are critical in the early phase IAV infection. Our core hypothesis is that SP-D inhibits IAV infectivity directly and also reduces inflammatory responses during IAV infection through effects on respiratory epithelium and polymorphonuclear neutrophils (PMNs). We aim to determine how these effects relate and which is most important. Aim 1 will examine how SP-D modulates infection of respiratory epithelium in vitro and in vivo. We will make use of SP-D-resistant and -sensitive IAV strains and conditionally SP-D gene-deleted (SP-D-/-) mice to clarify how SP-D inhibits IAV replication and how this relates to reduction of inflammatory responses by SP-D. In vitro studies of IAV infection in respiratory epithelial cells will determine in detail how SP-D modulates the viral life cycle and cell signaling. Aim 2 will make use of a panel of recombinantly modified forms of SP-D to determine which molecular features of SP-D are critical for antiviral and anti-inflammatory activities. These recombinant SP-D variants will be tested both in vitro (in human respiratory cell culture) and in vivo using instillation and genetic rescue to correct abnormalities in the antiviral response of conditional SP-D -/- mice. Our hypothesis is that multimerzation and saccharide binding properties of SP-D are both important in determining its antiviral and anti-inflammatory effects, and that the constructs will help separate out these effects. Aim 3 will determine how SP-D downregulates PMN influx during IAV infection and the contribution of PMNs to lung injury or control of viral replication in vivo. In vitro studies with human PMNs will determine how SP-D modulates the uptake of IAV by PMNs and how SP-D modulates respiratory burst responses of lAV-infected PMNs. SP-D can either increase or reduce respiratory burst responses of lAV-treated PMNs in vitro depending on sequence of addition of SP-D and IAV to the cells. The role of specific PMN receptors for IAV and SP-D in these effects will be evaluated. Aim 4 will evaluate two other innate immune proteins that have antiviral activity in their own right but also bind to, and modify function of SP-D. These are scavenger receptor rich glycoprotein 340 (gp340) and human neutrophil defensins (HNPs). These studies should elucidate important aspects of defense against IAV and be relevant to treatment and prevention strategies.

Thesaurus Terms:
immunity, influenza, lectin, pulmonary surfactant, virus infection mechanism
collagen, genetic polymorphism, genetic susceptibility, inflammation, intermolecular interaction, leukocyte activation /transformation, medical complication, neutrophil, phagocyte, phospholipid, protein binding, protein isoform, protein structure function, recombinant protein, respiratory infection, virus replication
clinical research, human subject, laboratory mouse

Institution:	BOSTON MEDICAL CENTER
	ONE BOSTON MEDICAL CENTER PLACE
	BOSTON, MA 02118
Fiscal Year:	2006
Department:
Project Start:	12-DEC-2001
Project End:	31-MAR-2011
ICD:	NATIONAL HEART, LUNG, AND BLOOD INSTITUTE
IRG:	LCMI