Extensive eosinophil degranulation and peroxidase-mediated oxidation of airway proteins do not occur in a mouse ovalbumin-challenge model of pulmonary inflammation.

Paradigms of eosinophil effector function in the lungs of asthma patients invariably depend on activities mediated by cationic proteins released from secondary granules during a process collectively referred to as degranulation. In this study, we generated knockout mice deficient for eosinophil peroxidase (EPO) to assess the role(s) of this abundant secondary granule protein in an OVA-challenge model. The loss of EPO had no effect on the development of OVA-induced pathologies in the mouse. The absence of phenotypic consequences in these knockout animals extended beyond pulmonary histopathologies and airway changes, as EPO-deficient animals also displayed OVA-induced airway hyperresponsiveness after provocation with methacholine. In addition, EPO-mediated oxidative damage of proteins (e.g., bromination of tyrosine residues) recovered in bronchoalveolar lavage from OVA-treated wild-type mice was <10% of the levels observed in bronchoalveolar lavage recovered from asthma patients. These data demonstrate that EPO activities are inconsequential to the development of allergic pulmonary pathologies in the mouse and suggest that degranulation of eosinophils recruited to the lung in this model does not occur at levels comparable to those observed in humans with asthma.

Eosinophil major basic protein-1 does not contribute to allergen-induced airway pathologies in mouse models of asthma.

The relationship between eosinophils and the development of Ag-induced pulmonary pathologies, including airway hyper-responsiveness, was investigated using mice deficient for the secondary granule component, major basic protein-1 (mMBP-1). The loss of mMBP-1 had no effect on OVA-induced airway histopathologies or inflammatory cell recruitment. Lung function measurements of knockout mice demonstrated a generalized hyporeactivity to methacholine-induced airflow changes (relative to wild type); however, this baseline phenotype was observable only with methacholine; no relative airflow changes were observed in response to another nonspecific stimulus (serotonin). Moreover, OVA sensitization/aerosol challenge of wild-type and mMBP-1(-/-) mice resulted in identical dose-response changes to either methacholine or serotonin. Thus, the airway hyper-responsiveness in murine models of asthma occurs in the absence of mMBP-1.

Identification of a new murine eosinophil major basic protein (mMBP) gene: cloning and characterization of mMBP-2.

We have identified a new eosinophil major basic protein gene family member in the mouse and have given it the designation murine major basic protein-2 (mMBP-2). The gene was initially characterized as a unique expressed sequence tag (EST) clone having significant identity to the previously recognized member of this gene family, mMBP-1. The EST was used to screen and isolate mMBP-2 from a bone marrow cDNA library. In addition, a genomic clone of mMBP-2 was isolated and this gene was shown to be physically linked to within 100 kb of mMBP-1 on the central region of mouse chromosome 2. Progressive similarity alignment of the deduced mMBP-2 open reading frame demonstrates the apparent conservation of the "pre-pro-mature" protein structure found in the other known mammalian MBPs. Mature mMBP-2 maintains the cationic nature associated with these proteins with a predicted pI of 9.95. However, unlike the human MBPs, which display a three orders of magnitude charge difference [hMBP-1 (pI 11.4) vs. hMBP-2 (pI 8.7)], mMBP-2 is only slightly less cationic than mMBP-1 (pI 10.5). Expression studies demonstrate that transcription of the mMBP-2 gene parallels mMBP-1 and is confined to hematopoietic compartments engaged in eosinophilopoiesis. Moreover, using mMBP-1 knockout mice and immunohistochemistry with an antisera that recognizes both mMBP-1 and -2, we demonstrate that mMBP-2 protein expression is restricted to eosinophil lineage-committed cells.

Interleukin-5 expression in the lung epithelium of transgenic mice leads to pulmonary changes pathognomonic of asthma.

We have generated transgenic mice that constitutively express murine interleukin (IL)-5 in the lung epithelium. Airway expression of this cytokine resulted in a dramatic accumulation of peribronchial eosinophils and striking pathologic changes including the expansion of bronchus-associated lymphoid tissue (BALT), goblet cell hyperplasia, epithelial hypertrophy, and focal collagen deposition. These changes were also accompanied by eosinophil infiltration of the airway lumen. In addition, transgenic animals displayed airway hyperresponsiveness to methacholine in the absence of aerosolized antigen challenge. These findings demonstrate that lung-specific IL-5 expression can induce pathologic changes characteristic of asthma and may provide useful models to evaluate the efficacy of potential respiratory disease therapies or pharmaceuticals.

Reversal of the interferon-sensitive phenotype of a vaccinia virus lacking E3L by expression of the reovirus S4 gene.

The vaccinia virus (VV) E3L gene, which encodes a potent inhibitor of the interferon (IFN)-induced, double-stranded RNA (dsRNA)-dependent protein kinase, PKR, is thought to be involved in the IFN-resistant phenotype of VV. The E3L gene products, p25 and p20, act as inhibitors of PKR, presumably by binding and sequestering activator dsRNA from the kinase. In this study we demonstrate that VV with the E3L gene specifically deleted (vP1080) was sensitive to the antiviral effects of IFN and debilitated in its ability to rescue vesicular stomatitis virus from the antiviral effects of IFN. Infection of L929 cells with E3L-minus virus led to rRNA degradation typical of activation of the 2'-5'-oligoadenylate synthetase/RNase L system, and extracts of infected cells lacked the PKR-inhibitory activity characteristic of wild-type VV. The reovirus S4 gene, which encodes a dsRNA-binding protein (sigma 3) that can also inhibit PKR activation by binding and sequestering activator dsRNA, was inserted into vP1080. The resultant virus (vP1112) was partially resistant to the antiviral effects of IFN in comparison with vP1080. Further studies demonstrated that transient expression of the reovirus sigma 3 protein rescued E3L-minus VV replication in HeLa cells. In these studies, rescue by sigma 3 mutants correlated with their ability to bind dsRNA. Finally, vP112 was also able to rescue the replication of the IFN-sensitive virus vesicular stomatitis virus in a manner similar to that of wild-type VV. Together, these results suggest that the reovirus S4 gene can replace the VV E3L gene with respect to interference with the IFN-induced antiviral activity.

Site-directed mutagenic analysis of reovirus sigma 3 protein binding to dsRNA.

The S4 gene of reovirus encodes a double-stranded RNA-binding protein, sigma 3, that can inhibit activation of the interferon-induced dsRNA-dependent protein kinase, PKR. In this study, we attempted to localize the region of sigma 3 involved in dsRNA-binding by constructing deletion and point mutations, expressing the mutated proteins in COS cells, and testing the ability of the native mutated proteins to bind dsRNA-agarose. Transfection of S4 into COS cells resulted in expression of two forms of sigma 3, a full-length protein, and a protein containing a small truncation at the amino-terminal end. The truncation is likely due to a proteolytic event. Deletions of as few as 10 amino acids from the amino-terminal end of the protein or 10 amino acids from the carboxyl-terminal end of the protein resulted in loss of dsRNA-binding activity. A putative dsRNA-binding domain has previously been localized to an 85 amino acid region located between amino acids 234 and 297 (Miller, J. E., and Samuel, C. E., J. Virol. 66, 5347-5356 1992). Mutagenesis of basic residues located within two distinct motifs of this region showed that some basic residues are absolutely required for binding to dsRNA while others can be changed with little effect.