Vascular disruption is one of the pathological hallmarks in acute respiratory distress syndrome. Bone marrow (BM)-derived circulating endothelial progenitor cells (EPCs) and lung tissue-resident EPCs have been considered to play a pivotal role in pulmonary vascular repair; however, which population is predominant in local pulmonary vasculogenesis remains to be clarified. We therefore examined the origin of EPCs participating in the regenerative process of pulmonary vascular endothelial cells (PVECs) in experimental acute respiratory distress syndrome. Lung samples from mice administered LPS intratracheally were investigated for cell dynamics and EPC functions. Quantitative flow cytometric analysis demonstrated that the number of PVECs decreased by roughly 20% on Day 1 and then recovered on Day 7 of LPS challenge. Bromodeoxyuridine-incorporation assays and immunofluorescence microscopy demonstrated that proliferating PVECs preferentially located in the capillary vessels. Experiments using BM chimera mice revealed that most of the regenerating PVECs were tissue-resident cells, and BM-derived cells hardly engrafted as PVECs. The population of circulating putative phenotypical EPCs decreased during the first week after LPS challenge. The regenerating PVECs were characterized by high colony-forming and vasculogenic capacities, intracellular reactive oxygen species scavenging and aldehyde dehydrogenase activites, and enhanced gene expression of Abcb1b (a drug-resistant gene), suggesting that the population of PVECs included tissue-resident EPCs activated during regenerative process of PVECs. The proliferating PVECs expressed CD34, Flk-1/KDR, and c-kit more strongly and Prom1/CD133 less strongly on the surface than nonproliferating PVECs. Our findings indicated that lung tissue-resident EPCs predominantly contribute to pulmonary vascular repair after endotoxin-induced injury.
Background and objective: Chronic thromboembolic pulmonary hypertension (CTEPH) is a progressive disease in some patients, despite improved treatments. Microvasculopathy has been implicated in the poor outcomes of patients with CTEPH. A reduction in the diffusing capacity for carbon monoxide (DL CO ) was previously suggested to indicate microvasculopathy in CTEPH patients; therefore, we assessed DL CO /alveolar ventilation (DL CO /V A ) as a prognostic and pathophysiological marker in CTEPH. Methods: We performed a retrospective cohort study of 214 CTEPH patients consecutively diagnosed between 1986 and 2011. After exclusion of 24 patients because of missing DL CO data or severe obstructive impairment, the mortality rates of medically treated patients classified with normal or decreased DL CO values were compared, and prognostic factors were determined. The relationship between long-term surgical outcomes and DL CO /V A was also investigated. Results: Ninety-one inoperable patients were treated medically, two of whom underwent balloon pulmonary angioplasty. Ninety-nine underwent pulmonary endarterectomy. The 5-year survival rate of medically treated patients was significantly lower in patients with decreased DL CO /V A than in those with normal values (61.4% vs 90.4%, P = 0.017). Decreased preoperative DL CO /V A was associated with a smaller percent decrease in post-operative pulmonary vascular resistance, but not with the extent of proximal thrombi; these results may support our hypothesis that DL CO reflects microvascular involvement. Conclusion: Decreased DL CO /V A was associated with poor outcomes of medically treated CTEPH patients; and may be useful for identifying high-risk patients,
Exposure to hypoxia induces changes in the structure and functional phenotypes of the cells composing the pulmonary vascular wall from larger to most peripheral vessels. Endothelial progenitor cells (EPCs) may be involved in vascular endothelial repair. Resident EPCs with a high proliferative potential are found in the pulmonary microcirculation. However, their potential location, identification, and functional role have not been clearly established. We investigated whether resident EPCs or bone marrow (BM)-derived EPCs play a major role in hypoxic response of pulmonary vascular endothelial cells (PVECs). Mice were exposed to hypoxia. The number of PVECs transiently decreased followed by an increase in hypoxic animals. Under hypoxic conditions for 1 wk, prominent bromodeoxyuridine incorporation was detected in PVECs. Some Ki67-positive cells were detected among PVECs after 1 wk under hypoxic conditions, especially in the capillaries. To clarify the origin of proliferating endothelial cells, we used BM chimeric mice expressing green fluorescent protein (GFP). The percentage of GFP-positive PVECs was low and constant during hypoxia in BM-transplanted mice, suggesting little engraftment of BM-derived cells in lungs under hypoxia. Proliferating PVECs in hypoxic animals showed increased expression of CD34, suggesting hypoxia-induced gene expression and cell surface antigen of EPC or stem/progenitor cells markers. Isolated PVECs from hypoxic mice showed colony- and tube-forming capacity. The present study indicated that hypoxia could induce proliferation of PVECs, and the origin of these cells might be tissue-resident EPCs.
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