Denaturation and unfolding of human anaphylatoxin C3a: an unusually low covalent stability of its native disulfide bonds.

The complement C3a anaphylatoxin is a major molecular mediator of innate immunity. It is a potent activator of mast cells, basophils and eosinophils and causes smooth muscle contraction. Structurally, C3a is a relatively small protein (77 amino acids) comprising a N-terminal domain connected by 3 native disulfide bonds and a helical C-terminal segment. The structural stability of C3a has been investigated here using three different methods: Disulfide scrambling; Differential CD spectroscopy; and Reductive unfolding. Two uncommon features regarding the stability of C3a and the structure of denatured C3a have been observed in this study. (a) There is an unusual disconnection between the conformational stability of C3a and the covalent stability of its three native disulfide bonds that is not seen with other disulfide proteins. As measured by both methods of disulfide scrambling and differential CD spectroscopy, the native C3a exhibits a global conformational stability that is comparable to numerous proteins with similar size and disulfide content, all with mid-point denaturation of [GdmCl](1/2) at 3.4-5M. These proteins include hirudin, tick anticoagulant protein and leech carboxypeptidase inhibitor. However, the native disulfide bonds of C3a is 150-1000 fold less stable than those proteins as evaluated by the method of reductive unfolding. The 3 native disulfide bonds of C3a can be collectively and quantitatively reduced with as low as 1mM of dithiothreitol within 5 min. The fragility of the native disulfide bonds of C3a has not yet been observed with other native disulfide proteins. (b) Using the method of disulfide scrambling, denatured C3a was shown to consist of diverse isomers adopting varied extent of unfolding. Among them, the most extensively unfolded isomer of denatured C3a is found to assume beads-form disulfide pattern, comprising Cys(36)-Cys(49) and two disulfide bonds formed by two pair of consecutive cysteines, Cys(22)-Cys(23) and Cys(56)-Cys(57), a unique disulfide structure of polypeptide that has not been documented previously.

GENE EXPRESSION IN CHRONIC MYELOGENOUS LEUKEMIA

The goal of the present work was to identify and characterize gene sequences that are preferentially expressed in CML in an effort to better understand the molecular basis of the disease. As high abundance mRNAs generally encode proteins that are phenotypically characteristic of cells, positive-negative screening of a CML cDNA library was used to identify cDNA clones containing sequences preferentially transcribed in CML. One cDNA sequence that fulfilled this criterion, C-A3, has been characterized in some detail. It represents a small mRNA ((TURN)496 nucleotides) that is highly abundant ((TURN)2% of the poly(A('+))RNA) in cells from the chronic phase of CML. In situ hybridization to whole cells indicates the principal leukocytes that express C-A3 sequences are eosinophils, basophils and immature myelocytes. Surprisingly, CML patients with high numbers of myeloblasts do not have an abundance of C-A3 transcripts, although transcript levels remain elevated in patients with lymphoblasts. In AML, high transcript levels are only found sporadically and occasionally different sized transcripts can be detected. Sequences from the 3' end of the C-A3 message are present in 2-5 copies per haploid genome. The 3' end of C-A3 localizes to bands 8q21.1 and 8q23 by in situ chromosomal hybridization. This is a region that is often involved in hematopoietic malignancies. Restriction digests of human genomic DNA show a correlation between the presence of a 2.3 kb Hind III fragment and certain types of leukemia. All of the leukemic DNAs tested had this fragment. In comparison, only one of five normal DNAs had a band this size. Analysis of the nucleotide sequence indicates that C-A3 probably encodes a small, hydrophobic peptide which may be part of a larger protein. ^

The contribution of A3 adenosine receptor signaling to pulmonary inflammation and mucus secretion in the mouse

Adenosine has been implicated in chronic lung diseases such as asthma and COPD. Most physiological actions of adenosine are mediated through G-protein coupled adenosine receptors. Four subtypes of adenosine receptors have been identified, A1, A2A, A2B, and A 3. However, the specific roles of the various adenosine receptors in processes central to asthma and COPD are not well understood in part due to the lack of adequate animal models that examine the effect of adenosine on the development of lung disease. In this study we have investigated the expression and function of the A3 adenosine receptor in pulmonary eosinophilia and mucus production/secretion in adenosine deaminase (ADA)-deficient mice in which adenosine levels are elevated. ADA-deficient mice develop features of asthma and COPD, including lung eosinophilia and mucus hyperplasia in association with elevated lung adenosine levels. The A3 receptor was found to be expressed in eosinophils and mucus producing cells in the airways of ADA-deficient. Disruption of A3 receptor signaling in ADA-deficient mice by genetic removal of the receptor or treatment with MRS 1523, a selective A3 adenosine receptor antagonist, prevented airway eosinophilia and mucus production. Although eosinophils were decreased in the airways of ADA-deficient mice with disrupted A3 receptor signaling, elevations in circulating and lung interstitial eosinophils persisted, suggesting signaling through the A3 receptor is needed for the migration of eosinophils into the airways. Further examination of the role of the A3 receptor in mucus biology demonstrated that the A3 receptor is neither required nor is overexpression of the receptor in clara cells sufficient for mucus production in naive mice. Transgenic overexpression of the A3 receptor did elucidate a role for the A3 receptor in the secretion of mucus into the airways of ovalbumin challenged mice. These findings identify an important role for the A3 adenosine receptor in regulating lung eosinophilia and mucus secretion in inflammatory lung diseases. Therefore, the A3 adenosine receptor may represent a novel therapeutic target for the treatment and prevention of asthma. ^

Evaluation of the C5a anaphylatoxin and its receptor (CD88) in allergic lung disease

Allergic asthma is characterized by airflow obstruction, airway hyperresponsiveness (AHR) and chronic airway inflammation. We and others have reported that complement component C3 and the anaphylatoxin C3a receptor promote while C5 protects against the development of the biological and physiological hallmarks of allergic lung disease in mice. In this study, we assessed if the protective responses could be mediated by C5a, an activation-induced C5 cleavage product. Mice with ablation of the C5a receptor (C5aR) either by genetic deletion or by pharmacological blockade exhibited significantly exacerbated AHR compared to allergen-challenged wild-type (WT) mice. However, there were no significant differences in many of the other hallmarks of asthma such as airway infiltration by eosinophils or lymphocytes, pulmonary IL-4-producing cell numbers, goblet cell metaplasia, mucus secretion or total serum IgE levels. In contrast to elevated AHR, numbers of IL-5 and IL-13 producing pulmonary cells, and IL-5 and IL-13 protein levels, were significantly reduced in allergen-challenged C5aR-/- mice compared to allergen-challenged WT mice. Administration of a specific cysteinyl leukotriene receptor 1 (cysLT1R) antagonist before each allergen-challenge abolished AHR in C5aR-/- as well as in WT mice. Pretreatment with a C3aR antagonist dose-dependently reduced AHR in allergen-challenged WT and C5aR-/- mice. Additionally, allergen-induced upregulation of pulmonary C3aR expression was exaggerated in C5aR-/- mice compared to WT mice. In summary, deficiency or antagonism of C5aR in a mouse model of pulmonary allergy increased AHR, which was reversed or reduced by blockade of the cysLT1R and C3aR, respectively. In conclusion, this study suggests that C5a and C5aR mediate protection against AHR by suppressing cysLT and C3aR signaling pathways, which are known to promote AHR. This also supports important and opposing roles of complement components C3a/C3aR and C5a/C5aR in AHR. ^

Does exhaled nitric oxide predict asthma exacerbation in children?

Asthma is a chronic complex disorder of the respiratory tract that affects millions of people globally, a large percentage of which are children. Triggered by a host of factors such as allergens and changes in temperature, the pathophysiologic and clinical indices vary among patients and have contributed to difficulties in overall management of asthma. Shortly after exhaled nitric oxide (eNO) was discovered in higher concentrations in asthma patients, it was shown to be superior to other markers such as PEFR, FEV1 and sputum eosinophils in screening asthma patients. Studies have also noted promising results regarding the use of eNO to predict asthma exacerbation in adults while in children, asthma symptoms have been observed to be good predictors of asthma exacerbation. Currently however, the potential of eNO as a predictor of asthma exacerbation in children is yet to be examined. The objective of this study was to assess eNO potential to predict asthma exacerbation in children by examining the relationship between eNO and changes in pulmonary function, asthma symptoms and rescue medication use.^ The primary study "Air Toxics and Asthma in Children" (ATAC), recruited children aged 9 to 14 years with labile persistent asthma diagnosed at least one year earlier. The data obtained from 30 study participants, included exhaled nitric oxide concentration, PEFR, FEV1, asthma symptoms and frequency of emergency medication use.^ Descriptive statistics, Pearson's and Spearman's correlation tests were followed by a simple linear regression in which eNO was the independent (predictor) variable while FEV1, PEFR, asthma symptoms and frequency of emergency medication use were the dependent (outcome) variables.^ Results showed that eNO was associated with percent change in FEV1, day time wheeze, night time shortness of breath, but correlated only weakly with PEFR, amplitude percent of mean PEFR, FEV1, percent change in FEV1 and asthma symptoms.^ Further research is imperative to better define the role of eNO and understand intrinsic pathologic mechanisms towards asthma management in children.^