Qualitative and Quantitative Analysis of Embryonic Pulmonary Vessel Formation

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Qualitative and Quantitative Analysis of Embryonic Pulmonary Vessel Formation

Susan K. Schachtner, YuQin Wang, and H. Scott Baldwin

Children's Hospital of Philadelphia, Division of Pediatric Cardiology; and University of Pennsylvania, Philadelphia, Pennsylvania

Vessel formation in the lung has been described as occurring by two mechanisms: proximal, or branch, pulmonary arteries developvia angiogenesis; and distal, smaller vessels form by vasculogenesis.Connections between the proximal and distal vessels establishthe final vascular network. The preponderance of vessel formationhas been suspected to occur during the canalicular stage of lungdevelopment. To test these hypotheses, reporter gene expressionunder control of the regulatory domain of fetal liver kinase-1(flk), an early endothelial cell-specific marker, was used toevaluate mouse lungs from embryonic day 10.5 (E10.5) through 2wk postnatal age. Morphologic assessment was performed after histochemicalstaining, and quantification of vessel development by a chemiluminescentassay was compared with overall embryonic lung growth. LacZ expressionunder flk promoter control allowed: (1) early identification ofdifferentiating endothelial cells of the branch pulmonary arteries;(2) visualization of distal vessels forming in the lung mesenchyme(primary capillary network) with subsequent remodeling; (3) recognitionof early continuity between proximal and distal vessels, occurringby E10.5; and (4) assessment of developing pulmonary veins andvenous confluence. Quantitative analysis revealed increased flkregulated $beta$ -galactosidase ( $beta$ -gal) activity of 12 ng $beta$ -gal/lungat E12.5 to 3,215 ng $beta$ -gal/lung at 2 wk, which corresponded tooverall lung growth during this period as shown by an increasein total protein content per lung from 35 µg at E12.5 to 6,456µg at 2 wk after birth. We identified endothelial cell precursorsof the developing pulmonary vasculature before vessel lumen formation.Continuity between the proximal pulmonary artery and vessels formingin the distal mesenchyme was present even at the earliest stageevaluated, suggesting endothelial cell differentiation at thesite of vessel formation (i.e., vasculogenesis) as occurs withdevelopment of the aorta. Finally, we demonstrated that lung vesseldevelopment was not accentuated during the canalicular stage,but occurred at all stages and directly corresponded to overalllunggrowth.

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