Hypoxia-Inducible Factor α Subunits Regulate Tie2-Expressing Macrophages That Influence Tumor Oxygen and Perfusion in Murine Breast Cancer.

Tie2-expressing monocytes/macrophages (TEMs) are a distinct subset of proangiogenic monocytes selectively recruited to tumors in breast cancer. Because of the hypoxic nature of solid tumors, we investigated if oxygen, via hypoxia-inducible transcription factors HIF-1α and HIF-2α, regulates TEM function in the hypoxic tumor microenvironment. We orthotopically implanted PyMT breast tumor cells into the mammary fat pads of syngeneic LysMcre, HIF-1α fl/fl /LysMcre, or HIF-2α fl/fl /LysMcre mice and evaluated the tumor TEM population. There was no difference in the percentage of tumor macrophages among the mouse groups. In contrast, HIF-1α fl/fl /LysMcre mice had a significantly smaller percentage of tumor TEMs compared with control and HIF-2α fl/fl /LysMcre mice. Proangiogenic TEMs in macrophage HIF-2α-deficient tumors presented significantly more CD31+ microvessel density but exacerbated hypoxia and tissue necrosis. Reduced numbers of proangiogenic TEMs in macrophage HIF-1α-deficient tumors presented significantly less microvessel density but tumor vessels that were more functional as lectin injection revealed more perfusion, and functional electron paramagnetic resonance analysis revealed more oxygen in those tumors. Macrophage HIF-1α-deficient tumors also responded significantly to chemotherapy. These data introduce a previously undescribed and counterintuitive prohypoxia role for proangiogenic TEMs in breast cancer which is, in part, suppressed by HIF-2α.

Macrophage colony-stimulating factor augments Tie2-expressing monocyte differentiation, angiogenic function, and recruitment in a mouse model of breast cancer.

Reports demonstrate the role of M-CSF (CSF1) in tumor progression in mouse models as well as the prognostic value of macrophage numbers in breast cancer patients. Recently, a subset of CD14+ monocytes expressing the Tie2 receptor, once thought to be predominantly expressed on endothelial cells, has been characterized. We hypothesized that increased levels of CSF1 in breast tumors can regulate differentiation of Tie2- monocytes to a Tie2+ phenotype. We treated CD14+ human monocytes with CSF1 and found a significant increase in CD14+/Tie2+ positivity. To understand if CSF1-induced Tie2 expression on these cells improved their migratory ability, we pre-treated CD14+ monocytes with CSF1 and used Boyden chemotaxis chambers to observe enhanced response to angiopoietin-2 (ANG2), the chemotactic ligand for the Tie2 receptor. We found that CSF1 pre-treatment significantly augmented chemotaxis and that Tie2 receptor upregulation was responsible as siRNA targeting Tie2 receptor abrogated this effect. To understand any augmented angiogenic effect produced by treating these cells with CSF1, we cultured human umbilical vein endothelial cells (HUVECs) with conditioned supernatants from CSF1-pre-treated CD14+ monocytes for a tube formation assay. While supernatants from CSF1-pre-treated TEMs increased HUVEC branching, a neutralizing antibody against the CSF1R abrogated this activity, as did siRNA against the Tie2 receptor. To test our hypothesis in vivo, we treated PyMT tumor-bearing mice with CSF1 and observed an expansion in the TEM population relative to total F4/80+ cells, which resulted in increased angiogenesis. Investigation into the mechanism of Tie2 receptor upregulation on CD14+ monocytes by CSF1 revealed a synergistic contribution from the PI3 kinase and HIF pathways as the PI3 kinase inhibitor LY294002, as well as HIF-1α-deficient macrophages differentiated from the bone marrow of HIF-1αfl/fl/LysMcre mice, diminished CSF1-stimulated Tie2 receptor expression.

Both cAMP and cGMP are required for maximal ciliary beat stimulation in a cell-free model of bovine ciliary axonemes.

Previously, we have shown that the ATPase-dependent motion of cilia in bovine bronchial epithelial cells (BBEC) can be regulated through the cyclic nucleotides, cAMP via the cAMP-dependent protein kinase (PKA) and cGMP via the cGMP-dependent protein kinase (PKG). Both cyclic nucleotides cause an increase in cilia beat frequency (CBF). We hypothesized that cAMP and cGMP may act directly at the level of the ciliary axoneme in BBEC. To examine this, we employed a novel cell-free system utilizing detergent-extracted axonemes. Axoneme movement was whole-field analyzed digitally with the Sisson-Ammons video analysis system. A suspension of extracted axonemes remains motionless until the addition of 1 mM ATP that establishes a baseline CBF similar to that seen when analyzing intact ciliated BBEC. Adding 10 microM cAMP or 10 microM cGMP increases CBF beyond the established ATP baseline. However, the cyclic nucleotides did not stimulate CBF in the absence of ATP. Therefore, the combination of cAMP and cGMP augments ATP-driven CBF increases at the level of isolated axoneme.

Ethanol increases phosphodiesterase 4 activity in bovine bronchial epithelial cells.

Ethanol exposure in airway epithelium increases cyclic AMP (cAMP)-dependent protein kinase (PKA) activity. Activation of PKA and cyclic guanosine monophosphate (cGMP)-dependent protein kinase (PKG) has been shown to increase ciliary beat frequency (CBF) in bovine bronchial epithelial cells (BBECs). We have shown that biologically relevant concentrations of ethanol stimulate increases in CBF in a nitric oxide-dependent manner, mediated through elevated cAMP levels and subsequent PKA activation. This ethanol-driven rapid and transient increase in CBF occurs 15 to 30 min after exposure to 100 mM ethanol. However, after prolonged exposure to 100 mM ethanol (>/=6 h), CBF and the catalytic activity of PKA return to baseline levels. We hypothesize that cyclic nucleotide-dependent phosphodiesterase (PDE) activity attenuates the duration of ethanol-stimulated ciliary motility. The effect of ethanol on the PDE activity in BBECs was determined through direct assay of catalytic activity. When BBECs were incubated with 100 mM ethanol, significant increases in cAMP levels occurred within 1 h, with corresponding increases in PKA activity. Treatment of BBECs with 100 mM ethanol increased cAMP-PDE activity significantly by 4 h. 3-Isobutyl-1-methylxanthine, Ro 20-1724, and rolipram inhibited ethanol-stimulated cAMP-PDE activity. These agents inhibited ethanol-stimulated cAMP-PDE activity and increased the magnitude of ethanol-stimulated PKA activity observed under the same conditions. These findings support the idea that acute exposure (<6 h) to ethanol increases cAMP levels, and the associated increase in PKA activation is regulated by cAMP-dependent PDE, specifically PDE4. Other compensatory mechanisms however, may be responsible for the down-regulation of PKA, which occurs after chronic epithelial exposure (>/=6 h) to ethanol.

Ethanol stimulates ciliary beating by dual cyclic nucleotide kinase activation in bovine bronchial epithelial cells.

Previously, we have shown that ethanol (EtOH) stimulates a rapid increase in the ciliary beat frequency (CBF) of bovine bronchial epithelial cells (BBECs) via the activation of PKA. We have also shown that inhibitors of nitric oxide synthase block EtOH-stimulated increases in CBF. We hypothesize that EtOH acutely stimulates CBF via the activation of both PKA and PKG pathways. Using chemiluminescence detection of nitric oxide (NO), we directly measured increases in NO production in BBECs treated with 100 mmol/L of EtOH beginning at 25 minutes. Pretreatment of BBECs with guanylyl cyclase inhibitors, ODQ or LY83583, resulted in the inhibition of EtOH-stimulated CBF. Low concentrations (1 nmol/L) of cyclic nucleotide analogues do not stimulate CBF increases. However, a combination of both 1 nmol/L of 8Br-cAMP and 8Br-cGMP stimulates a significant increase over baseline CBF. This effect could be blocked by pretreating BBECs with inhibitors of either PKA or PKG. Very high concentrations of either 8Br-cAMP or 8Br-cGMP (> or =100 micromol/L) were required to cross-activate both PKA and PKG. This suggests that cross-activation of PKA by cGMP is not occurring at the concentrations (1 nmol/L) capable of stimulating CBF. 8-pCPT-cGMPS, an antagonist analogue to cGMP, blocked EtOH-stimulated PKA activity increases. These data support that EtOH-stimulated increases in CBF require the dual activation of both PKA (via cAMP) and PKG (via NO).