In vitro allergen challenge of peripheral blood induces differential gene expression in mononuclear cells of asthmatic patients: inhibition of cytosolic phospholipase A2alpha overcomes the asthma-associated response.

BACKGROUND: Existing treatments for asthma are not effective in all patients and disease exacerbations are common, highlighting the need for increased understanding of disease mechanisms and novel treatment strategies. The leukotriene pathway including the enzyme responsible for arachidonic acid release from cellular phospholipids, cPLA(2)alpha, is a major contributor to asthmatic responses and an attractive target in asthma therapies. OBJECTIVE: The study reported here investigates (a) the differential effects of in vitro exposure of peripheral blood mononuclear cells (PBMCs) to allergen between asthma and healthy subjects, and (b) the contribution of cPLA(2)alpha to these differences in gene expression. METHODS: In vitro responses of asthma (N=26) and healthy (N=11) subject PBMC samples to allergen stimulation in the presence and absence of cPLA(2)alpha inhibition or 5-lipoxygenase inhibition were compared at the gene expression level using oligonucleotide arrays and at the protein level using ELISA. RESULTS: Subject samples within both asthma and healthy groups showed allergen-dependent cytokine production and allergen-dependent gene expression changes, although transcriptional profiling identified 153 genes that were modulated significantly differently by allergen between asthma and healthy subjects. Among these were genes previously associated with asthma, but the majority (about 80%) have not previously been associated with asthma. CONCLUSIONS: Transcriptional profiling elucidated novel gene expression differences between the asthmatic and healthy subject samples. Although 5-lipoxygenase inhibition did not significantly affect allergen-modulated gene expression, the inhibition of cPLA(2)alpha activity affected many of the allergen-dependent, asthma-associated gene expression changes.

Interactions of the rapsyn RING-H2 domain with dystroglycan.

Rapsyn, a peripheral membrane protein of skeletal muscle, is necessary for the formation of the highly organized structure of the vertebrate neuromuscular junction. For mice lacking rapsyn, there is a failure of postsynaptic specialization characterized by an absence of nicotinic acetylcholine receptors (nAChRs) and other integral and peripheral membrane proteins such as beta-dystroglycan and utrophin. Dystroglycan is necessary for the formation of the mature neuromuscular junction and has been shown to interact directly with rapsyn. Previous studies with rapsyn fragments and mutants, expressed in 293T cells along with nAChRs, establish that the rapsyn tetratricopeptide repeat (TPR) domain is involved in self-association and its coiled-coil domain is necessary for nAChR clustering. The function of the rapsyn RING-H2 domain, which is not necessary for rapsyn self-association or nAChR clustering, is unknown. To further characterize these domains, we have used a yeast two-hybrid assay to test for interactions at the plasma membrane between rapsyn domains and a nAChR beta-subunit fragment, the beta-dystroglycan cytoplasmic domain, or rapsyn domains. The rapsyn coiled-coil domain interacts with the nAChR beta-subunit cytoplasmic domain, but not with itself, other rapsyn domains, or beta-dystroglycan. The RING-H2 domain interacts only with the beta-dystroglycan cytoplasmic domain. Furthermore, when expressed in 293T cells, a rapsyn construct containing as few as two TPRs and the RING-H2 domain self-associates and clusters dystroglycan, but not nAChRs. These results emphasize the modular character of the rapsyn structural domains.

Role of rapsyn tetratricopeptide repeat and coiled-coil domains in self-association and nicotinic acetylcholine receptor clustering.

Rapsyn, a 43-kDa peripheral membrane protein of skeletal muscle, is essential for clustering nicotinic acetylcholine receptors (nAChR) in the postsynaptic membrane. Previous studies with rapsyn NH(2)-terminal fragments fused to green fluorescent protein, expressed in 293T cells along with nAChRs, establish the following: Rapsyn-(1-90), containing the myristoylated amino terminus and two tetratricopeptide repeats (TPRs), was sufficient for self-association at the plasma membrane; rapsyn-(1-287), containing seven TPRs, did not cluster nAChRs; whereas rapsyn-(1-360)(,) containing a coiled-coil domain (rapsyn-(298-331)), clustered nAChRs. To further analyze the role of rapsyn structural domains in self-association and nAChR clustering, we have characterized the clustering properties of additional rapsyn mutants containing deletions and substitutions within the TPR and coiled-coil domains. A mutant lacking the coiled-coil domain alone (rapsyn-(black triangle288-348)), failed to cluster nAChRs. Within the coiled-coil domain neutralization of the charged side chains was tolerated, while alanine substitutions of large hydrophobic residues resulted in the loss of nAChR clustering. Rapsyn self-association requires at least two TPRs, as a single TPR (TPR1 or TPR2 alone) was not sufficient. While TPRs 1 and 2 are sufficient for self-association, they are not necessary, as TPRs 3-7 also formed clusters similar to wild-type rapsyn. Fragments containing TPRs co-localized with full-length rapsyn, while the expressed coiled-coil or RING-H2 domain did not. These results are discussed in terms of a homology model of rapsyn, based on the three-dimensional structure of the TPR domain of protein phosphatase 5.

Mechanism of nicotinic acetylcholine receptor cluster formation by rapsyn.

Rapsyn, a peripheral membrane protein of skeletal muscle, clusters nicotinic acetylcholine receptors (nAChRs) at high density in the postsynaptic membrane. The mechanism of nAChR clustering by rapsyn was analyzed by expressing nAChRs in HEK293T cells with various fragments of mouse rapsyn fused to green fluorescent protein. Membrane targeting of rapsyn is conferred solely by its acylated N terminus, as the myristoylated N-terminal 15 amino acids of rapsyn are sufficient to target green fluorescent protein to the plasma membrane. However, neither N-terminal myristoylation nor the conserved N-terminal amino acid sequence is essential. Membrane targeting, self-association, and nAChR clustering are preserved when the first 10 amino acids of rapsyn were replaced by those of src, which also contains a consensus sequence for N-myristoylation, or by those of GAP43, which contains a palmitoylation sequence. Rapsyn1-90, containing two tetratrichopeptide repeats is sufficient for self-association. Rapsyn1-360, lacking the cysteine rich domain, clusters nAChRs, while rapsyn1-287, containing seven tetratrichopeptide repeats, does not cluster nAChRs. We identified rapsyn298-331 as a potential coiled-coil domain, and established that mutations disrupting coiled-coil propensity prevent nAChR clustering. Thus the structural domains of rapsyn necessary for membrane targeting, self-association, and nAChR clustering are distinct, with nAChR-rapsyn interaction mediated by a previously unrecognized coiled-coil motif.

Identification by in vitro mutagenesis of the interaction of two segments of C2MstC1, a chimera of cytochromes P450 2C2 and P450 2C1.

A hybrid cytochrome P450, C2MstC1, with 306 N-terminal amino acids derived from cytochrome P450 2C2 sequence and 184 C-terminal amino acids from cytochrome P450 2C1 acquires a novel progesterone 21-hydroxylase activity which is absent in the parent enzymes. Extension of the cytochrome P450 2C2 sequence to residue 382 reduced progesterone hydroxylase activity to 5% of that of C2MstC1, while further extension to residue 411 or 462 increased activity back to about 30 or 40%, respectively. In the chimera with cytochrome P450 2C2 sequence to residue 382, substitution of cytochrome P450 2C1 amino acids at positions 368, 369, and 374 increased progesterone hydroxylase activity to a level equivalent to that of C2MstC1. In the chimera with cytochrome P450 2C2 sequence extending to residue 411, substitutions of P450 2C1 amino acids at positions 386 and 388, in addition those at 368, 369, and 374, were required to obtain activities equivalent to that of C2MstC1, which suggests an interaction between these two regions. The lauric acid hydroxylase activities of all chimeras and mutant cytochromes P450 differed by 2-fold or less, demonstrating that the changes in progesterone hydroxylase activity reflected altered interactions with the substrate. Alignment of cytochrome P450 2C1 sequence with cytochromes P450cam, P450BM-3, and P450terp predicts that residues 368/369 and 386/388 are in adjacent antiparallel strands of the same beta-sheet, in agreement with the experimental data suggesting an interaction between these two regions.

Preference for aromatic substitutions at tryptophan-120, which is highly conserved and a potential mediator of electron transfer in cytochrome P450 2C2.

A proposal that tryptophan-120 of P450 2C2 might mediate electron transfer has been tested by substitution of a series of aliphatic and aromatic residues at this position. Activity in transfected COS1 cells expressing enzymes substituted with the aromatic residues, tyrosine, phenylalanine, and histidine, was 25% to 60% of wild type. Activities in enzymes containing serine, arginine, or aliphatic amino acid substitutions were less than 10%, except for alanine (25%). Alanine is the only naturally occurring substitution for tryptophan at this position in mammalian cytochromes P450 and is present in the electron pathway proposed on the basis of the crystal structure of cytochrome c and cytochrome c peroxidase. The preference for aromatic residues or the small aliphatic amino acid, alanine, at position 120 is consistent with a role for this tryptophan in electron transfer.