To the editor:
Class I phosphoinositide 3-kinases (PI3Ks) play a critical role in regulating chemoattractant-induced migration of neutrophils.1 However, Puri et al have demonstrated that PI3K activity in vascular endothelium also contributes to the accumulation of these cells in tissues, as evidenced by the reduced ability of PI3K-deficient blood vessels to support rolling adhesion of WT neutrophils in response to the proinflammatory cytokine tissue necrosis factor α (TNFα; 20 ng).2,3 By contrast, a recent publication by Liu et al suggests that endothelial PI3K activity is not essential for this process.4 Although both studies used chimeric animals in which PI3Kγ or PI3Kδ activity was present in neutrophils but absent in endothelium, it was speculated that the observed discrepancies were attributable to the amount of TNFα used to induce inflammation (500 ng vs 20 ng). We wish to point out that the use of transmitted light microscopy and electrocautery tissue dissection by Liu et al may account for these inconsistencies rather than differences in cytokine concentrations.
To confirm our hypothesis, we used WT or p110γ−/− animals that were irradiated and reconstituted with WT fetal liver cells from mice expressing GFP in granulocytes, and evaluated neutrophil behavior in the microcirculation of cremaster muscle stimulated with TNFα (1000 ng). The absence of endothelial PI3Kγ activity was associated with a 5-fold increase in neutrophil rolling velocities, findings consistent with those of Puri et al (54.8 ± 4.2 μm/s vs 10.2 ± 0.6 μm/s in WT animals, P < .001, data represent means ± SEM, n = 80 cells per genotype). Moreover, the number of neutrophils extravasating into tissue was dramatically decreased in PI3Kγ chimeric animals as compared with WT counterparts (25 ± 2 cells vs 65 ± 2 cells, respectively, P < .001, Figure 1A,B,D). By contrast, the use of electrocautery rather than mechanical tissue dissection (microscissor) caused robust cell migration in PI3Kγ chimeric animals (79 ± 8 cells, P < .001, Figure 1B-D), results consistent with that of Liu et al.
The contribution of endothelial class I PI3K activity to neutrophil trafficking and E-selectin surface distribution. Representative intravital fluorescence photomicrographs depicting neutrophil adhesion and transmigration across cremaster muscle (CM) venules in (A) WT mice and chimeric animals using (B) mechanical dissection and (C) tissue cautery 6 hours after administration of TNFα (1000 ng). Photomicrographs were acquired using an Axiotech vario microscope (Carl Zeiss MicroImaging, Thornwood, NY) fitted with a 20× water-immersion objective (LUMPlanFl, 0.5 NA; Olympus America, Center Valley, PA) coupled to a piezo driver enabling viewing in the z-axis (∼1 μm sequential sections; total 75 μm), an iXon low-light camera and IQ image acquisition software (both from Andor Technology, South Windsor, CT). To distinguish intra- versus extra-vessel cells, fluorescein isothiocyanate (FITC)–dextran (Sigma-Aldrich, St Louis, MO) was administered intravenously. Data sets were flattened along the z-axis as maximum intensity projections to enable determination of the total number of cells that had migrated into a 150 × 200 μm region on either side of the vessel wall. (D) Quantitation of the number of the migrated cells 6 hours after administration of TNF α (1000 ng,n = 3 mice per genotype). Data represent means plus or minus SEM; * indicates P less than .001. (E) Electron micrographs of immunogold-labeled E-selectin or PECAM-1 expressed on HUVECs pretreated with vehicle control or isoform-specific inhibitor (IC87114; ICOS Corp, Bothell, WA; 2 μM). Gold particles (10 nm) appear as dark dots. Electron micrographs were obtained using a CM10 transmission electron microscope (Philips Research, Briarcliff, NY). Quantification of (F) E-selectin or (G) PECAM-1 expression on endothelium in terms of the number of gold particles found in discrete groupings under the conditions described in panel E. Blockade of p110δ resulted in a 55% reduction in groupings containing 3 or more gold particles per unit area with a reduction of all groupings by 40%. Inclusion in a discrete grouping required that gold particles be no more than 30 nm apart. The percentage of gold particles that existed singly, or in groupings of 2 or 3 and more over a defined distance of 97 μm was calculated from each micrograph. Data represent means plus or minus SEM; * indicates P less than .05.
The contribution of endothelial class I PI3K activity to neutrophil trafficking and E-selectin surface distribution. Representative intravital fluorescence photomicrographs depicting neutrophil adhesion and transmigration across cremaster muscle (CM) venules in (A) WT mice and chimeric animals using (B) mechanical dissection and (C) tissue cautery 6 hours after administration of TNFα (1000 ng). Photomicrographs were acquired using an Axiotech vario microscope (Carl Zeiss MicroImaging, Thornwood, NY) fitted with a 20× water-immersion objective (LUMPlanFl, 0.5 NA; Olympus America, Center Valley, PA) coupled to a piezo driver enabling viewing in the z-axis (∼1 μm sequential sections; total 75 μm), an iXon low-light camera and IQ image acquisition software (both from Andor Technology, South Windsor, CT). To distinguish intra- versus extra-vessel cells, fluorescein isothiocyanate (FITC)–dextran (Sigma-Aldrich, St Louis, MO) was administered intravenously. Data sets were flattened along the z-axis as maximum intensity projections to enable determination of the total number of cells that had migrated into a 150 × 200 μm region on either side of the vessel wall. (D) Quantitation of the number of the migrated cells 6 hours after administration of TNF α (1000 ng,n = 3 mice per genotype). Data represent means plus or minus SEM; * indicates P less than .001. (E) Electron micrographs of immunogold-labeled E-selectin or PECAM-1 expressed on HUVECs pretreated with vehicle control or isoform-specific inhibitor (IC87114; ICOS Corp, Bothell, WA; 2 μM). Gold particles (10 nm) appear as dark dots. Electron micrographs were obtained using a CM10 transmission electron microscope (Philips Research, Briarcliff, NY). Quantification of (F) E-selectin or (G) PECAM-1 expression on endothelium in terms of the number of gold particles found in discrete groupings under the conditions described in panel E. Blockade of p110δ resulted in a 55% reduction in groupings containing 3 or more gold particles per unit area with a reduction of all groupings by 40%. Inclusion in a discrete grouping required that gold particles be no more than 30 nm apart. The percentage of gold particles that existed singly, or in groupings of 2 or 3 and more over a defined distance of 97 μm was calculated from each micrograph. Data represent means plus or minus SEM; * indicates P less than .05.
Mechanistically, Puri et al speculated that class I PI3K activity in endothelium contributes to neutrophil trafficking into tissues by regulating the surface distribution but not expression of E-selectin, an adhesion molecule that mediates the rolling of these cells on the inflamed vessel wall. This is supported in the recent publication by Setiadi et al demonstrating that the physical clustering of E-selectin on cytokine-stimulated endothelium is essential for this process.5 Indeed, isoform-specific blockade of class I PI3K activity does alter E-selectin clustering of on the surface of TNFα-stimulated human umbilical cord vein endothelial cells (HUVECs; Cambrex Bio Science, Walkersville, MD; Figure 1E,F). By contrast, the surface distribution of PECAM-1, an adhesion molecule constitutively expressed on vascular endothelium, remained unchanged (Figure 1E,G), as did that of PSGL-1, a selectin ligand present on the surface of neutrophils (data not shown). These findings, in conjunction with the report by Sediati et al, provide a potential mechanism by which class I PI3Ks contribute to the proadhesive state of inflamed endothelium.
In conclusion, our data reaffirm the validity of the results by Puri et al and illustrate the importance of using appropriate imaging and surgical techniques when evaluating intracellular signaling pathways that play a critical role in neutrophil trafficking.
Authorship
This work was supported by National Heart, Lung, and Blood Institute grant HL075805-01A2 (T.G.D.).
Contributions: T.R. performed experiments and contributed to the writing of the manuscript. N.D. and J.C. performed experiments and analyzed data. T.G.D. designed research, performed experiments, and wrote the manuscript.
Conflict-of-interest disclosure: The authors declare no competing financial interests.
Correspondence: Thomas G. Diacovo, Columbia University Medical Center, 1130 St Nicolas Ave, Room 924, New York, NY 10032; e-mail: td2142@columbia.edu.
References
National Institutes of Health
