William Hutchins

D-4F, an apoA-1 mimetic, decreases airway hyperresponsiveness, inflammation, and oxidative stress in a murine model of asthma

Asthma is characterized by oxidative stress and inflammation of the airways. Although proinflammatory lipids are involved in asthma, therapies targeting them remain lacking. Ac-DW F KA F YDKVAEK F KEA F NH2 (4F) is an apolipoprotein (apo)A-I mimetic that has been shown to preferentially bind oxidized lipids and improve HDL function. The objective of the present study was to determine the effects of 4F on oxidative stress, inflammation, and airway resistance in an established murine model of asthma. We show here that ovalbumin (OVA)-sensitization increased airway hyperresponsiveness, eosinophil recruitment, and collagen deposition in lungs of C57BL/6J mice by a mechanism that could be reduced by 4F. OVA sensitization induced marked increases in transforming growth factor (TGF)β-1, fibroblast specific protein (FSP)-1, anti-T15 autoantibody staining, and modest increases in 4-hydroxynonenal (4-HNE) Michaels adducts in lungs of OVA-sensitized mice. 4F decreased TGFβ-1, FSP-1, anti-T15 autoantibody, and 4-HNE adducts in the lungs of the OVA-sensitized mice. Eosinophil peroxidase (EPO) activity in bronchial alveolar lavage fluid (BALF), peripheral eosinophil counts, total IgE, and proinflammatory HDL (p-HDL) were all increased in OVA-sensitized mice. 4F decreased BALF EPO activity, eosinophil counts, total IgE, and p-HDL in these mice. These data indicate that 4F reduces pulmonary inflammation and airway resistance in an experimental murine model of asthma by decreasing oxidative stress.

Histopathology of experimentally induced asthma in a murine model of sickle cell disease

Asthma is a comorbid condition associated with increased rates of pain, acute chest syndrome, and premature death in human sickle cell disease (SCD). We developed an experimental asthma model in SCD and control mice expressing either normal human or murine hemoglobin to determine its effect on mortality and lung pathology. To induce lung inflammation, experimental mice were sensitized to ovalbumin (OVA) by subcutaneous OVA implantation (Sen), allowed 2 weeks to recover, and then divided into 2 groups, each receiving over a subsequent 10-day period the same dosage of aerosolized OVA but 2 different levels of exposure: 15 minutes (LoSen) and 30 minutes (HiSen). During recovery, 10% of SCD mice died compared with no deaths in control mice. An additional 30% of HiSen SCD mice died during aerosolization compared with 10% in LoSen SCD. Histologic indices of lung inflammation (eg, eosinophil recruitment, airway and vessel wall thickening, and immunoreactive TGFbeta and fsp-1) and bronchial alveolar lavage fluid eosinophil peroxidase activity differentially increased in sensitized mice compared with unsensitized mice. Our findings indicate SCD mice with experimentally induced asthma are more susceptible to death and pulmonary inflammation compared with control mice, suggesting that asthma contributes significantly to morbidity and mortality in SCD.

Effects of Experimental Asthma on Inflammation and Lung Mechanics in Sickle Cell Mice

Experimental asthma increases eosinophil and collagen deposition in the lungs of sickle cell disease (SCD) mice to a greater extent than in control mice. However, the effects of asthma on inflammation and airway physiology remain unclear. To determine effects of asthma on pulmonary inflammation and airway mechanics in SCD mice, hematopoietic stem cell transplantation was used to generate chimeric SCD and hemoglobin A mice. Experimental asthma was induced by sensitizing mice with ovalbumin (OVA). Airway mechanics were assessed using forced oscillation techniques. Mouse lungs were examined histologically and physiologically. Cytokine, chemokine, and growth factors in bronchoalveolar lavage fluid were determined by multiplex. IgE was quantified by ELISA. LDH was quantified using a colorimetric enzymatic assay. At baseline (nonsensitized), chimeric SCD mice developed hemolytic anemia with sickled red blood cells, mild leukocytosis, and increased vascular endothelial growth factor and IL-13 compared with chimeric hemoglobin A mice. Experimental asthma increased perialveolar eosinophils, plasma IgE, and bronchoalveolar lavage fluid IL-1β, IL-4, IL-6, and monocyte chemotactic protein 1 in chimeric hemoglobin A and SCD mice. IFN-γ levels were reduced in both groups. IL-5 was preferentially increased in chimeric SCD mice but not in hemoglobin A mice. Positive end-expiratory pressures and methacholine studies revealed that chimeric SCD mice had greater resistance in large and small airways compared with hemoglobin A mice at baseline and after OVA sensitization. SCD alone induces a baseline lung pathology that increases large and small airway resistance and primes the lungs to increased inflammation and airway hyperresponsiveness after OVA sensitization.

Mitochondrial big conductance KCa channel and cardioprotection in infant rabbit heart.

Chronic hypoxia increases resistance to myocardial ischemia in infants. Activation of the mitochondrial big conductance Ca2+-sensitive K channel (mitoBKCa) has been shown to be protective in adult hearts; however, its role in infant hearts is unknown. Hearts from normoxic or hypoxic infant rabbits were perfused with a mitoKCa opener, NS1619, or blocker Paxilline before ischemia and reperfusion. Hypoxic hearts were more resistant to ischemia than normoxic hearts as manifested by a reduction in infarct size (9 ± 5% versus 14 ± 5%) and an increase in recovery of left ventricular developed pressure (LVDP) (69 ± 7% versus 51 ± 2%). NS1619 decreased infarct size in normoxic hearts from 14 ± 5% to 10 ± 5% and increased recovery of LVDP from 51 ± 2% to 65 ± 4%, but it had no effect on hypoxic hearts. Paxilline did not affect normoxic or hypoxic hearts. Activation of mitoBKCa protects normoxic infant rabbit hearts; however, cardioprotection by chronic hypoxia in infant rabbits does not appear involve mitoBKCa.

On the pathway of an animal model for restless legs syndrome

Restless legs syndrome (RLS) is a chronic sleep motor disorder that affects up to 10% of the general population. Except for periodic leg movements (PLM), which can be found in the great majority of RLS patients, no objective hematochimic or neurophysiological markers are available to prove the diagnosis, which is based on clinical standard criteria. Nowadays, the aetiopathogenesis of the syndrome is unknown. In a consistent sample of patients affected by the idiopathic form, the disease is inherited as an autosomal dominant trait related to an unidentified locus, while each symptomatic form is probably linked to a specific cause. Although of possible different origins, both the primary and secondary forms may share the same pathogenetic mechanism, which, even if unclear, could be characterised by a neurological dysfunction of the dopaminergic system. Several issues, including strong efficacy of dopamine-agonist treatments, support this theory, which is currently considered the main pathogenetic hypothesis. Most of the past studies tried to clarify the RLS mechanism using the neurophysiological, biochemical and neuroimaging techniques applied to the field of human research. Now the time has come to accept the challenge in creating an animal model of RLS, which may emerge as a decisive step in understanding RLS pathogenesis, and to develop and test new therapies. Even though there have been a few significant efforts, a valid animal model of RLS still does not exist. In past pioneering studies, the authors attempted to induce restless motor behaviour in animals by different strategies: antidopaminergic pharmacological interventions, spinal or cerebral lesions of specific regions involved in the motor control and in dopamine regulation, and selective deletion of genes coding for dopamine receptors. Rodents (mice and rats) were always chosen by the authors as the animals for their experiments. The current tendency in achieving an RLS model is generally represented by simulation of a symptomatic condition of RLS or by a direct interference of the dopaminergic system. In this regard, the pharmacological method had the intention to reproduce the neuroleptic-induced acathisia, the spinal lesional model was based on the hypothesis of myelopathic- related PLM, and the hypothalamic lesion tested the motor consequence of A11 dopaminergic neurons. Preliminary studies are underway to replicate the pregnancy-related form of RLS by using a hormonal intervention, and the iron-deficiency secondary form by using specific iron-free diets. Today, modern technologies are available to easily replicate in animals most of the symptomatic RLS conditions. In addition, more than a few well validated animal models of different diseases known to be related to RLS or PLM, for instance, Parkinsons disease, rheumatoid arthritis and renal failure, could also be exploited in addressing this topic. The real obstacle in achieving an RLS model is the absence of a certain diagnostic marker to recognise if the animal that underwent the different experimental procedures has developed the RLS condition or not. Concerning this issue, possible specific endpoints are represented by the increase in locomotor activity, which are ascertainable by different techniques, such as openfield or run-wheel activity, or by sleep fragmentation, in which the circadian shift can be verified by applying polysomnography on the animal. PLM are probably the only specific and reliable markers available to recognise and quantify experimentally induced RLS. Despite a few authors who reported the presence of limb-phasic, pseudoperiodic activity during sleep in old or in lesioned rats, the existence of spontaneous or provoked PLM in animals is still debated. Eventually, the PLM features in an animal could be markedly different compared to human ones. To recognise and characterise PLM in animals, three more essential steps are required: a method to record directly, as in humans, the activity of the tibialis anterior (TA) muscles, a consistent amount of normative control data on the TA activity in healthy animals, and reliable analysis to distinguish the generic phasic muscular activity to a possible unambiguous PLM pattern. This review includes a summary and a critical discussion of the previous tentative RLS models, proposals for other possible animal models, and firstly the preliminary normative data on TA activity during sleep in normal rodents.