Soluble Kit receptor blocks stem cell factor bioactivity in vitro.

Stem cell factor (SCF) is a growth factor that promotes the survival, proliferation, and differentiation of hematopoietic cells. SCF and its receptor, Kit, are normally present in both cell surface and soluble forms. Both forms of Kit can bind SCF. However, the function of soluble Kit is unknown. In order to determine if soluble Kit can modulate SCF activity, we produced a fusion protein, Kit-Fc, comprised of the extracellular domain of murine Kit and the Fc portion of human IgG(1) and investigated its ability to bind 125I-SCF and to inhibit SCF-stimulated hematopoietic colony growth in vitro. Stable cell lines expressing Kit-Fc were generated and Kit-Fc was purified to greater than 95% purity. Scatchard analysis demonstrated that Kit-Fc binds iodinated SCF with high affinity (Kd 570 pM). Kit-Fc also bound to transmembrane SCF displayed on the surface of fibroblasts. The murine mast cell line IC2 was engineered to express murine Kit on the cell surface and was demonstrated to proliferate in the presence of SCF. Kit-Fc completely blocked SCF-stimulated proliferation of IC2-Kit cells, but not IL-3-stimulated growth of IC2-Kit cells, demonstrating the specificity of Kit-Fc. We investigated the ability of Kit-Fc to block SCF-stimulated murine hematopoietic colony growth. Kit-Fc blocked SCF-stimulated erythroid colony growth as effectively as a neutralizing anti-Kit monoclonal antibody, ACK2, but did not block erythropoietin-stimulated erythroid colony growth. Likewise, Kit-Fc blocked SCF-stimulated myeloid colony growth as effectively as ACK2 antibody, but did not block IL-3- or GM-CSF-stimulated myeloid colony growth. These results indicate that a form of soluble Kit binds SCF with high affinity, and can specifically block the ability of SCF to stimulate hematopoietic colony growth, suggesting that one function of soluble Kit may be to modulate SCF bioactivity.

Vascular response to radiation injury in the rat lung.

Changes in relative left-to-right lung blood flow ratios were followed as an index of vascular radiation injury in left-hemithorax-irradiated Sprague-Dawley rats. Single doses of 11 to 21 Gy gamma radiation resulted in a dose-dependent decrease in relative blood flow to the irradiated lung from 3 to 5 weeks after exposure during the development of pneumonitis. Blood flow returned to near normal by 5 weeks after lower doses (11-13.5 Gy). After a single dose of 15 Gy the left-to-right blood flow ratio recovered to 75% of normal at 12 weeks and leveled off. Following 18 Gy irradiation a second period of reduced flow began 16 weeks after exposure. After 21 Gy irradiation flow to the irradiated side remained low for 1 year after exposure. Rats that received a single dose of 18 Gy to the left hemithorax were also treated with one or two of the following drugs: captopril, cyproheptadine, dexamethasone, diethylcarbamazine, penicillamine, or theophylline. Dexamethasone was most effective at preventing the decrease in blood flow to the irradiated lung when treatment was continued through the pneumonitis period and dose was not tapered until 8 weeks after radiation exposure. All other drugs and drug combinations were, for the most part, virtually ineffective after the pneumonitis period. There was a relatively poor correlation with earlier vascular permeability surface area product studies. This suggests that endothelial damage, as well as damage to other cell types, contributes to the development of post-irradiation fibrosis in the lung.

Pharmacological alteration of the lung vascular response to radiation.

The role of endothelial cell damage in the development of radiation injury in the lung was investigated in rats. Vascular permeability-surface area product (PS) was measured as an indicator of the degree of endothelial cell damage in lungs of rats exposed to single dose hemithorax irradiation. Hemithorax irradiation was chosen to simulate clinical radiotherapy, in which only a portion of the lung is irradiated. In addition, it provided a control lung to compare to the irradiated lung. Radiation is postulated to lead to activation of several different biochemical pathways that result in lung injury and fibrosis. Many of these pathways can be specifically blocked with drugs. Thirteen different drugs were studied. Dexamethasone, indomethacin, cromolyn, cyproheptadine, Vitamin D3, theophylline, and diethylcarbamazine were all effective at reducing lung PS on the irradiated side. Dexamethasone, Vitamin D3, and indomethacin also significantly reduced lung PS in the unirradiated lungs and in sham-irradiated rats. Captopril, cobra venom factor, penicillamine, trapidil, epsilon-amino caproic acid, and dapsone had no significant effect on lung PS after hemithorax irradiation. We conclude that the major pathways involved in early post-radiation lung injury involve prostaglandin, leukotriene, and histamine release from macrophages and mast cells. Complement activation, proteolytic enzymes, and neutrophil migration do not seem to be important mediators of early post-radiation lung injury.