Transplantation of human embryonic stem cell-derived alveolar epithelial type II cells abrogates acute lung injury in mice.

Respiratory diseases are a major cause of mortality and morbidity worldwide. Current treatments offer no prospect of cure or disease reversal. Transplantation of pulmonary progenitor cells derived from human embryonic stem cells (hESCs) may provide a novel approach to regenerate endogenous lung cells destroyed by injury and disease. Here, we examine the therapeutic potential of alveolar type II epithelial cells derived from hESCs (hES-ATIICs) in a mouse model of acute lung injury. When transplanted into lungs of mice subjected to bleomycin (BLM)-induced acute lung injury, hES-ATIICs behaved as normal primary ATIICs, differentiating into cells expressing phenotypic markers of alveolar type I epithelial cells. Without experiencing tumorigenic side effects, lung injury was abrogated in mice transplanted with hES-ATIICs, demonstrated by recovery of body weight and arterial blood oxygen saturation, decreased collagen deposition, and increased survival. Therefore, transplantation of hES-ATIICs shows promise as an effective therapeutic to treat acute lung injury.

A pure population of lung alveolar epithelial type II cells derived from human embryonic stem cells.

Alveolar epithelial type II (ATII) cells are small, cuboidal cells that constitute approximately 60% of the pulmonary alveolar epithelium. These cells are crucial for repair of the injured alveolus by differentiating into alveolar epithelial type I cells. ATII cells derived from human ES (hES) cells are a promising source of cells that could be used therapeutically to treat distal lung diseases. We have developed a reliable transfection and culture procedure, which facilitates, via genetic selection, the differentiation of hES cells into an essentially pure (>99%) population of ATII cells (hES-ATII). Purity, as well as biological features and morphological characteristics of normal ATII cells, was demonstrated for the hES-ATII cells, including lamellar body formation, expression of surfactant proteins A, B, and C, alpha-1-antitrypsin, and the cystic fibrosis transmembrane conductance receptor, as well as the synthesis and secretion of complement proteins C3 and C5. Collectively, these data document the successful generation of a pure population of ATII cells derived from hES cells, providing a practical source of ATII cells to explore in disease models their potential in the regeneration and repair of the injured alveolus and in the therapeutic treatment of genetic diseases affecting the lung.

A novel role for neural crest cells in thymus organogenesis

Classical ablation studies have shown that neural crest cells (NCC) are critical for thymus organogenesis, though their role in this process has never been determined. We have used a mouse model deficient in NCC near the thymus rudiment to investigate the role of NCC in thymus organogenesis. Splotch mice exhibit a lack of NCC migration due to mutation in the gene encoding the transcription factor Pax 3. Homozygous mutants, designated Pax3Sp/Sp, display a range of phenotypes including spina bifida, cardiac outflow tract deformities, and craniofacial deformities. Pax3Sp/Sp, mice have also been reported to have hypoplastic and abnormal thymi, which is consistent with the expected result based on the classical ablation studies. However, in contrast to the dogma, we find that the thymus lobes in Pax3Sp/Sp, mice are even larger in size than those of littermate controls, although they fail to migrate and are therefore ectopic. Differentiation of the thymic epithelial compartments occurs normally, including the ability to import hematopoietic precursors, until the embryos die at embryonic day E13.0. We also investigated the patterning of the third pharyngeal pouch which gives rise to both the thymus and the parathyroid. Using RNA probes to detect expression of transcription factors exclusively expressed in the ventral, thymus- or dorsal, parathyroidfated domains of the E11.5 third pouch, we show that the parathyroid domain is restricted and the thymus-fated domain is expanded in Pax3Sp/Sp, embryos. Furthermore, mixing of the boundary between these domains occurs at E12.0. These results necessitate reconsideration of the previously accepted role for NCC in thymus organogenesis. NCC are not required for outgrowth of the thymus up to E13.0, and most strikingly, we have discovered a novel role for NCC in establishing parathyroid versus thymus fate boundaries in the third pharyngeal pouch. ^

Effects of asbestos and silica on superoxide anion production in the guinea pig alveolar macrophage

Asbestos and silica are important industrial hazards. Exposure to these dusts can result in pulmonary fibrosis and, in the case of asbestos, cancer. Although the hazards of asbestos and silica exposure have long been known, the pathogenesis of dust-related disease is not well understood. Both silica and asbestos are thought to alter the function of the alveolar macrophage, but the nature of the biochemical alteration is unknown. Therefore, this study examined the effect of asbestos and silica on the activation pathway of the guinea pig alveolar macrophage. Activation of macrophages by physiological agents results in stimulation of phospholipase C causing phosphatidyl inositol turnover and intracellular calcium mobilization. Phosphatidyl inositol turnover produces diacylglycerol which activates protein kinase C causing superoxide anion production.^ Chrysotile stimulated alveolar macrophages to produce superoxide anion. This stimulation proceeded via phospholipase C, since chrysotile stimulated phosphatidyl inositol turnover and intracellular calcium mobilization. The possible involvement of a coupling protein was evaluated by pretreating cells with pertussis toxin. Pertussis toxin pretreatment partially inhibited chrysotile stimulation, suggesting that chrysotile activates a coupling protein in an non-classical manner. Potential binding sites for chrysotile stimulation were examined using a series of nine lectins. Chrysotile-stimulated superoxide anion production was blocked by pretreatment with lectins which bound to N-acetylglucosamine, but not by lectins which bound to mannose, fucose, or N-acetylgalactosamine. In addition, incubation with the N-acetylglucosamine polymer, chitin, inhibited chrysotile-stimulated superoxide anion production, suggesting that chrysotile stimulated superoxide anion production by binding to N-acetylglucosamine residues.^ On the other hand, silica did not stimulate superoxide anion production. The effect of silica on agonist stimulation of this pathway was examined using two stimulants of superoxide anion production, N-formyl-nle-leu-phe (FNLP, which stimulates through phospholipase C) and phorbol-12,13-dibutyrate (which directly activates protein kinase C). Sublethal doses of silica inhibited FNLP-stimulated superoxide anion production, but did not affect phorbol-12,13-dibutyrate-stimulated superoxide anion production, suggesting that the site of inhibition precedes protein kinase C. This inhibition was not due to cell membrane damage, since cell permeability to calcium-45 and rubidium-86 was not increased. It is concluded that chrysotile binds to N-acetylglucosamine residues on macrophage surface glycoproteins to stimulate the physiological pathway resulting in superoxide anion production. In contrast, silica does not stimulate superoxide anion production, but it did inhibit FNLP-stimulated superoxide anion production. ^

Differential stress response and susceptibility to oxidative injury in alveolar macrophages from C57BL/6J and C3H/HeJ mice following oxidant exposure

Studies have demonstrated a variable response to ozone among individuals and animal species and strains. For instance, C57BL/6J mice have a greater inflammatory response to ozone exposure than C3H/HeJ mice. In these studies, I utilized these strain differences in an effort to derive a mechanistic explanation to the variable strain sensitivity to ozone exposure. Therefore, alveolar macrophages (AM) from C57BL/6J and C3H/HeJ mice were exposed in vitro to hydrogen peroxide ($\rm H\sb2O\sb2$), heat and acetyl ceramide or in vivo to ozone. Necrosis and DNA fragmentation in macrophages from the two murine strains were determined to assess cytotoxicity following these treatments. In addition, synthesis and expression of the stress proteins, stress protein 72 (SP72) and heme oxygenase (HO-1), were examined following treatments. The in vitro experiments were conducted to eliminate the possibility of in vivo confounders (i.e., differences in breathing rates in the two strains) and thus directly implicate some inherent difference between cells from the two murine strains. $\rm H\sb2O\sb2$ and heat caused greater cytotoxicity in AM from C57BL/6J than C3H/HeJ mice and DNA fragmentation was a particularly sensitive indicator of cell injury. Similarly, AM from C57BL/6J mice were more sensitive to ozone exposure than cells from C3H/HeJ mice. Exposure to either 1 or 0.4 ppm ozone caused greater cytotoxicity in macrophages from C57BL/6J mice compared to macrophages from C3H/HeJ mice. The increased sensitivity of AM to injury was associated with decreased synthesis and expression of stress proteins. AM from C57BL/6J mice synthesized and expressed significantly less stress proteins in response to heat and ozone than AM from C3H/HeJ mice. Heat treatment resulted in greater synthesis and expression of SP72. In addition, macrophages from C57BL/6J mice expressed lower amounts of HO-1 than macrophages from C3H/HeJ mice following 0.4 ppm ozone exposure. Therefore, AM from C57BL/6J mice are more susceptible to oxidative injury than AM from C3H/HeJ mice which might be due to differential expression of stress proteins in these cells. ^

Mechanism of silica -induced apoptosis in human alveolar macrophages

The mechanisms involved in the development of pulmonary silicosis have not been well defined, however most current evidence implicates a central role for alveolar macrophages in this process. We propose that the fibrotic potential of a particulate depends upon its ability to cause apoptosis in alveolar macrophage (AM). The overall goal of this study was to determine the mechanism of silica-induced apoptosis of AM. Human AM were treated with fibrogenic, poorly fibrogenic and nonfibrogenic model particulates, such as, silica, amorphous silica and titanium dioxide, respectively (equal surface area). Treatment with silica resulted in apoptosis in human AM as observed by morphology, DNA fragmentation and Cell Death ELISA assays. In contrast, amorphous silica and titanium dioxide demonstrated no significant apoptotic potential. To elucidate the possible mechanism by which silica causes apoptosis, we investigated the role of the scavenger receptor (SR) in silica-induced apoptosis. Cells were pretreated with and without SR ligand binding inhibitors, polyinosinic acid (Poly I), fucoidan and high density lipoprotein (HDL), prior to silica treatment. Pretreatment with Poly I and fucoidan resulted in significant inhibition of silica-induced apoptosis suggesting that silica-induced AM apoptosis is mediated via the SR. Further, we examined the involvement of interleukin converting enzyme (ICE) family of proteases in silica-mediated apoptosis. Silica activated ICE, Ich-1L, cpp32 beta and cleavage of PARP. Taken together, these results suggested that (1) fibrogenic particulates, such as, silica caused apoptosis of alveolar macrophages, (2) this apoptotic potential of fibrogenic particulates may be a critical factor in initiating an inflammatory response resulting in fibrosis, (3) silica-induced apoptosis of alveolar macrophages may be due to the interaction of silica particulates with the SR, and (4) silica-induced apoptosis involves the activation of the ICE family of proteases. An understanding of the molecular events involved in fibrogenic particulate-induced apoptosis may provide a useful insight into the mechanism involved in particulate-induced fibrosis. ^