An optimized confocal intravital microscopy protocol for long-term live imaging of murine F-actin organization during naïve lymphocyte migration.

Actin plays a crucial role during cell motility, but the organization of F-actin filaments during lymphocyte migration has not been visualized in vivo. Here, we present a 4D imaging platform using high-resolution confocal intravital microscopy to precisely determine the F-actin filament profile during lymphocyte transendothelial migration and interstitial migration. This protocol allows prolonged live imaging by laser scanning microscopy with advanced spatial resolution compared with the traditional multi-photon intravital microscopy techniques. For complete details on the use and execution of this protocol, please refer to Yan et al. (2019).

In Vivo F-Actin Filament Organization during Lymphocyte Transendothelial and Interstitial Migration Revealed by Intravital Microscopy.

Actin is essential for many cellular processes including cell motility. Yet the organization of F-actin filaments during lymphocyte transendothelial migration (TEM) and interstitial migration have not been visualized. Here we report a high-resolution confocal intravital imaging technique with LifeAct-GFP bone marrow reconstituted mice, which allowed visualization of lymphocyte F-actin in vivo. We find that naive lymphocytes preferentially cross high endothelial venules (HEVs) using paracellular rather than the transcellular route. During both modes of transmigration F-actin levels rise at the lymphocyte leading edge as the cell engages the TEM site. Once the lymphocytes breach the endothelium, they briefly reside in HEV pockets before crossing into the parenchyma. During interstitial migration dynamic actin-based protrusions rapidly form and collapse to help drive motility. Using a panel of inhibitors, we established roles for actin regulators and myosin II in lymphocyte TEM. This study provides further insights into lymphocyte TEM and interstitial migration in vivo.

Platelet activation and platelet-leukocyte aggregation elicited in experimental colitis are mediated by interleukin-6.

There is growing evidence for an interdependence of inflammation, coagulation, and thrombosis in acute and chronic inflammatory diseases. Inflammatory bowel diseases (IBD) are associated with a hypercoagulable state and an increased risk of thromboembolism. Although the IBD-associated prothrombogenic state has been linked to the inflammatory response, the mediators that link these 2 conditions remain unclear. Recent evidence suggests that interleukin-6 (IL-6) may be important in this regard. The objective of this study was to more fully define the contribution of IL-6 to the altered platelet function that occurs during experimental colitis. The number of immature and mature platelets, activated platelets, and platelet-leukocyte aggregates were measured in wild-type and IL-6 mice with dextran sodium sulfate (DSS)-induced colonic inflammation. DSS treatment of WT mice was associated with significant increases in the number of both immature and mature platelets, activated platelets, and platelet-leukocyte aggregates. These platelet responses to DSS were not observed in IL-6 mice. Chronic IL-6 infusion (through an Alzet pump) in WT mice reproduced all of the platelet abnormalities observed in DSS-colitic mice. IL-6-infused mice also exhibited an acceleration of thrombus formation in arterioles, similar to DSS. These findings implicate IL-6 in the platelet activation and enhanced platelet-leukocyte aggregate formation associated with experimental colitis, and support a role for this cytokine as a mediator of the enhanced thrombogenesis in IBD.

Platelet abnormalities during colonic inflammation.

Patients with inflammatory bowel disease are susceptible to microvascular thrombosis and thromboembolism. The increased incidence of thrombosis is accompanied by enhanced coagulation and abnormalities in platelet function. Clinical studies have revealed thrombocytosis, alterations in platelet activation, enhanced platelet-leukocyte interactions, and elevated plasma levels of prothrombotic cytokines. This study was directed toward determining whether the thrombocytosis, altered platelet functions, and enhanced platelet-leukocyte interactions observed in patients with inflammatory bowel disease can be recapitulated in the dextran sodium sulfate and T-cell transfer models of murine colonic inflammation. Flow cytometry was used to characterize platelet function in heparin-anticoagulated whole blood of control mice and in mice with colonic inflammation. Platelets were identified by characteristic light scattering and membrane expression of CD41. Thiazole orange labeling was used to differentiate between immature and mature platelets. Platelet activation was monitored using the expression of an activation epitope of GPIIb/IIIa integrin. The combination of CD41, CD45.2, Gr-1, F4/80, and isotype control antibodies was used to detect and quantify aggregates of leukocytes, neutrophils, and monocytes with platelets. Our results indicated that colonic inflammation is associated with thrombocytosis, leukocytosis, and the appearance of immature platelets. An increased number of circulating activated platelets was detected in colitic mice, along with the formation of aggregates of leukocytes (PLA), neutrophils (PNA), and monocytes (PMA) with platelets. Selectin blockade with fucoidin inhibited dextran sodium sulfate-induced PLA formation. The findings of this study indicate that many features of the altered platelet function detected in human inflammatory bowel disease can be reproduced in animal models of colonic inflammation.