Cell-cell interactions in regulating lung function

Tight junction barrier formation and gap junctional communication are two functions directly attributable to cell-cell contact sites. Epithelial and endothelial tight junctions are critical elements of the permeability barrier required to maintain discrete compartments in the lung. On the other hand, gap junctions enable a tissue to act as a cohesive unit by permitting metabolic coupling and enabling the direct transmission of small cytosolic signaling molecules from one cell to another. These components do not act in isolation since other junctional elements, such as adherens junctions, help regulate barrier function and gap junctional communication. Some fundamental elements related to regulation of pulmonary barrier function and gap junctional communication were presented in a Featured Topic session at the 2004 Experimental Biology Conference in Washington, DC, and are reviewed in this summary.     

Arsenic upregulates MMP-9 and inhibits wound repair in human airway epithelial cells

As part of the innate immune defense, the polarized conducting lung epithelium acts as a barrier to keep particulates carried in respiration from underlying tissue. Arsenic is a metalloid toxicant that can affect the lung via inhalation or ingestion. We have recently shown that chronic exposure of mice or humans to arsenic (10-50 ppb) in drinking water alters bronchiolar lavage or sputum proteins consistent with reduced epithelial cell migration and wound repair in the airway. In this report, we used an in vitro model to examine effects of acute exposure of arsenic (15-290 ppb) on conducting airway lung epithelium. We found that arsenic at concentrations as low as 30 ppb inhibits reformation of the epithelial monolayer following scrape wounds of monolayer cultures. In an effort to understand functional contributions to epithelial wound repair altered by arsenic, we showed that acute arsenic exposure increases activity and expression of matrix metalloproteinase (MMP)-9, an important protease in lung function. Furthermore, inhibition of MMP-9 in arsenic-treated cells improved wound repair. We propose that arsenic in the airway can alter the airway epithelial barrier by restricting proper wound repair in part through the upregulation of MMP-9 by lung epithelial cells.     

Intestinal barrier failure during experimental necrotizing enterocolitis: protective effect of EGF treatment

Necrotizing enterocolitis (NEC) is the most common intestinal disease of premature infants. Although increased mucosal permeability and altered epithelial structure have been associated with many intestinal disorders, the role of intestinal barrier function in NEC pathogenesis is currently unknown. We investigated the structural and functional changes of the intestinal barrier in a rat model of NEC. In addition, the effect of EGF treatment on intestinal barrier function was evaluated. Premature rats were divided into three groups: dam fed (DF), formula fed (NEC), or fed with formula supplemented with 500 ng/ml EGF (NEC + EGF); all groups were exposed to asphyxia/cold stress to develop NEC. Intestinal permeability, goblet cell density, mucin production, and composition of tight junction (TJ) proteins were evaluated in the terminal ileum, the site of NEC injury, and compared with the proximal jejunum, which was unaffected by NEC. Animals with NEC had significantly increased intestinal paracellular permeability compared with DF pups. Ileal goblet cell morphology, mucin production, and TJ composition were altered in animals with NEC. EGF treatment significantly decreased intestinal paracellular permeability, increased goblet cell density and mucin production, and normalized expression of two major TJ proteins, occludin and claudin-3, in the ileum. In conclusion, experimental NEC is associated with disruption of the intestinal barrier. EGF treatment maintains intestinal integrity at the site of injury by accelerating goblet cell maturation and mucin production and normalizing expression of TJ proteins, leading to improved intestinal barrier function.     

Modulation of pulmonary alveolar type II cell phenotype and communication by extracellular matrix and KGF

The alveolarepithelium consists of two cell types, alveolar type I (AT1) andalveolar type II (AT2) cells. We have recently shown that 7-day-oldcultures of AT2 cells grown on a type I collagen/fibronectin matrixdevelop phenotypic characteristics of AT1 cells, display a distinctconnexin profile, and coordinate mechanically induced intercellularCa²⁺ changes via gap junctions (25). In thisstudy, we cultured AT2 cells for 7 days on matrix supplemented withlaminin-5 and/or in the presence of keratinocyte growth factor. Underthese conditions, cultured AT2 cells display AT2 type morphology,express the AT2-specific marker surfactant protein C, and do notexpress AT1-specific cell marker aquaporin 5, all consistent withmaintenance of AT2 phenotype. These AT2-like cells also coordinatemechanically induced intercellular Ca²⁺ signaling, but,unlike AT1-like cells, do so by using extracellular nucleotidetriphosphate release. Additionally, cultured cells that retain AT2cell-specific markers express connexin profiles different from culturedcells with AT1 characteristics. The parallel changes in intercellularCa²⁺ signaling with cell differentiation suggest that cellsignaling mechanisms are an intrinsic component of lung alveolar cellphenotype. Because lung epithelial injury is accompanied byextracellular matrix and growth factor changes, followed by extensivecell division, differentiation, and migration of AT2 progenitor cells,we suggest that similar changes may be vital to the lung recovery andrepair process in vivo.

     

Transcranial Near-Infrared Laser Transmission (NILT) Profiles (800 nm): Systematic Comparison in Four Common Research Species

Background and Purpose

Transcranial near-infrared laser therapy (TLT) is a promising and novel method to promote neuroprotection and clinical improvement in both acute and chronic neurodegenerative diseases such as acute ischemic stroke (AIS), traumatic brain injury (TBI), and Alzheimer’s disease (AD) patients based upon efficacy in translational animal models. However, there is limited information in the peer-reviewed literature pertaining to transcranial near-infrared laser transmission (NILT) profiles in various species. Thus, in the present study we systematically evaluated NILT characteristics through the skull of 4 different species: mouse, rat, rabbit and human.

Results

Using dehydrated skulls from 3 animal species, using a wavelength of 800nm and a surface power density of 700 mW/cm2, NILT decreased from 40.10% (mouse) to 21.24% (rat) to 11.36% (rabbit) as skull thickness measured at bregma increased from 0.44 mm in mouse to 0.83 mm in rat and then 2.11 mm in rabbit. NILT also significantly increased (p<0.05) when animal skulls were hydrated (i.e. compared to dehydrated); but there was no measurable change in thickness due to hydration.In human calvaria, where mean thickness ranged from 7.19 mm at bregma to 5.91 mm in the parietal skull, only 4.18% and 4.24% of applied near-infrared light was transmitted through the skull. There was a slight (9.2-13.4%), but insignificant effect of hydration state on NILT transmission of human skulls, but there was a significant positive correlation between NILT and thickness at bregma and parietal skull, in both hydrated and dehydrated states.

Conclusion

This is the first systematic study to demonstrate differential NILT through the skulls of 4 different species; with an inverse relationship between NILT and skull thickness. With animal skulls, transmission profiles are dependent upon the hydration state of the skull, with significantly greater penetration through hydrated skulls compared to dehydrated skulls. Using human skulls, we demonstrate a significant correlation between thickness and penetration, but there was no correlation with skull density. The results suggest that TLT should be optimized in animals using novel approaches incorporating human skull characteristics, because of significant variance of NILT profiles directly related to skull thickness.     

Alternaria alternata serine proteases induce lung inflammation and airway epithelial cell activation via PAR2

Allergens are diverse proteins from mammals, birds, arthropods, plants, and fungi. Allergens associated with asthma (asthmagens) share a common protease activity that may directly impact respiratory epithelial biology and lead to symptoms of asthma. Alternaria alternata is a strong asthmagen in semiarid regions. We examined the impact of proteases from A. alternata on lung inflammation in vivo and on cleaving protease-activated receptor-2 (PAR(2)) in vitro. A. alternata filtrate applied to the airway in nonsensitized Balb/c mice induced a protease-dependent lung inflammation. Moreover, A. alternata filtrate applied to human bronchial epithelial cells (16HBE14o-) induced changes in intracellular Ca(2+) concentration ([Ca(2+)](i)), consistent with PAR(2) activation. These effects were blocked by heat inactivation or by serine protease inhibition of A. alternata filtrates, and mimicked by PAR(2) specific ligands SLIGRL-NH(2) or 2-furoyl-LIGRLO-NH(2), but not the PAR(1)-specific ligand TFLLR-NH(2). Desensitization of PAR(2) in 16HBE14o- cells with 2-furoyl-LIGRLO-NH(2) or trypsin prevented A. alternata-induced [Ca(2+)](i) changes while desensitization of PAR(1), PAR(3), and PAR(4) with thrombin had no effect on A. alternata-induced Ca(2+) responses. Furthermore, the Ca(2+) response to A. alternata filtrates was dependent on PAR(2) expression in stably transfected HeLa cell models. These data demonstrate that A. alternata proteases act through PAR(2) to induce rapid increases in human airway epithelial [Ca(2+)](i) in vitro and cell recruitment in vivo. These responses are likely critical early steps in the development of allergic asthma.     

The protease-activated receptor-2-specific agonists 2-aminothiazol-4-yl-LIGRL-NH2 and 6-aminonicotinyl-LIGRL-NH2 stimulate multiple signaling pathways to induce physiological responses in vitro and in vivo

Protease-activated receptor-2 (PAR₂) is one of four protease-activated G-protein-coupled receptors. PAR₂ is expressed on multiple cell types where it contributes to cellular responses to endogenous and exogenous proteases. Proteolytic cleavage of PAR₂ reveals a tethered ligand that activates PAR₂ and two major downstream signaling pathways: mitogen-activated protein kinase (MAPK) and intracellular Ca²⁺ signaling. Peptides or peptidomimetics can mimic binding of the tethered ligand to stimulate signaling without the nonspecific effects of proteases. The most commonly used peptide activators of PAR₂ (e.g. SLIGRL-NH₂ and SLIGKV-NH₂) lack potency at the receptor. However, although the potency of 2-furoyl-LIGRLO-NH₂ (2-f-LIGRLO-NH₂) underscores the use of peptidomimetic PAR₂ ligands as a mechanism to enhance pharmacological action at PAR₂, 2-f-LIGRLO-NH₂ has not been thoroughly evaluated. We evaluated the known agonist 2-f-LIGRLO-NH₂ and two recently described pentapeptidomimetic PAR₂-specific agonists, 2-aminothiazol-4-yl-LIGRL-NH₂ (2-at-LIGRL-NH₂) and 6-aminonicotinyl-LIGRL-NH₂ (6-an-LIGRL-NH₂). All peptidomimetic agonists stimulated PAR₂-dependent in vitro physiological responses, MAPK signaling, and Ca²⁺ signaling with an overall rank order of potency of 2-f-LIGRLO-NH₂ ≈ 2-at-LIGRL-NH₂ > 6-an-LIGRL-NH₂ ≫ SLIGRL-NH₂. Because PAR₂ plays a major role in pathological pain conditions and to test potency of the peptidomimetic agonists in vivo, we evaluated these agonists in models relevant to nociception. All three agonists activated Ca²⁺ signaling in nociceptors in vitro, and both 2-at-LIGRL-NH₂ and 2-f-LIGRLO-NH₂ stimulated PAR₂-dependent thermal hyperalgesia in vivo. We have characterized three high potency ligands that can be used to explore the physiological role of PAR₂ in a variety of systems and pathologies.     

Rapid expansion of human hematopoietic stem cells by automated control of inhibitory feedback signaling

Clinical hematopoietic transplantation outcomes are strongly correlated with the numbers of cells infused. Anticipated novel therapeutic implementations of hematopoietic stem cells (HSCs) and their derivatives further increase interest in strategies to expand HSCs ex vivo. A fundamental limitation in all HSC-driven culture systems is the rapid generation of differentiating cells and their secreted inhibitory feedback signals. Herein we describe an integrated computational and experimental strategy that enables a tunable reduction in the global levels and impact of paracrine signaling factors in an automated closed-system process by employing a controlled fed-batch media dilution approach. Application of this system to human cord blood cells yielded a rapid (12-day) 11-fold increase of HSCs with self-renewing, multilineage repopulating ability. These results highlight the marked improvements that control of feedback signaling can offer primary stem cell culture and demonstrate a clinically relevant rapid and relatively low culture volume strategy for ex vivo HSC expansion.     

Bordetella bronchiseptica responses to physiological reactive nitrogen and oxygen stresses

Bordetella bronchiseptica can establish prolonged airway infection consistent with a highly developed ability to evade mammalian host immune responses. Upon initial interaction with the host upper respiratory tract mucosa, B. bronchiseptica are subjected to antimicrobial reactive nitrogen species (RNS) and reactive oxygen species (ROS), effector molecules of the innate immune system. However, the responses of B. bronchiseptica to redox species at physiologically relevant concentrations (nM-microM) have not been investigated. Using predicted physiological concentrations of nitric oxide (NO), superoxide and hydrogen peroxide (H2O2) on low numbers of CFU of B. bronchiseptica, all redox active species displayed dose-dependent antimicrobial activity. Susceptibility to individual redox active species was significantly increased upon introduction of a second species at subantimicrobial concentrations. An increased bacteriostatic activity of NO was observed relative to H2O2. The understanding of Bordetella responses to physiologically relevant levels of exogenous RNS and ROS will aid in defining the role of endogenous production of these molecules in host innate immunity against Bordetella and other respiratory pathogens.