A novel method to analyze leukocyte rolling behavior in vivo

Leukocyte endothelial cell interaction is a fundamentally important process in many disease states. Current methods to analyze such interactions include the parallel-plate flow chamber and intravital microscopy. Here, we present an improvement of the traditional intravital microscopy that allows leukocyte-endothelial cell interaction to be studied from the time the leukocyte makes its initial contact with the endothelium until it adheres to or detaches from the endothelium. The leukocyte is tracked throughout the venular tree with the aid of a motorized stage and the rolling and adhesive behavior is measured off-line. Because this method can involve human error, methods to automate the tracking procedure have been developed. This novel tracking method allows for a more detailed examination of leukocyte-endothelial cell interactions

In vivo imaging approaches in animal models of rheumatoid arthritis

The interaction of activated leukocytes with the rheumatoid synovial environment is a key process in arthritis. Understanding this process will play an important role in designing effective treatments. In vivo imaging approaches combined with molecular genetics in animal models provide important tools to address these issues. The present review will focus on approaches to in vivo imaging, with particular attention to approaches that are proving useful for, or have promise for, research on animal models of rheumatoid arthritis. These approaches will probably shed light on the specific local mechanisms involved in chronic inflammation and provide real time monitoring approaches to follow cellular and molecular events related to disease development

Microcirculation and inflammation in a numerical simulation approach

Inflammation is the response of the organism to eradicate the agent of lesion or infection in order to achieve hemostasis. This response requires the migration of specific leukocyte populations from the blood circulation towards the inflamed area. Leukocyte recruitment constitutes a complex cellular process by which leukocytes are first recruited to the endothelial vascular wall of post-capillary venules across which they further extravasate into the interstitial tissue. Recruitment is mediated via cell-cell interactions between the leukocyte and the endothelium and occurs through a multi-step cascade: tethering, rolling, slow rolling, arrest, crawling, adhesion and transmigration. However, whether or not the leukocytes adhere to the endothelium depends not only on the chemical forces generated by adhesion molecules on leukocytes and endothelial cells, but also on the physical forces that act on those cells. It has been suggested that fluid shear stress resulting from blood flow also regulates leukocyte activity which makes the fluid dynamic environment of the circulation to be considered an important aspect for leukocyte recruitment and migration during the inflammatory response. Most of the studies on the inflammatory response and in particular on leukocyte recruitment are based on animal models and involve, among others, the quantification of inflammatory mediators and cellular players, and/or the analysis of the leukocyte-endothelial cell interactions by intravital microscopy. However, the contribution of hemodynamics for leukocyte recruitment has been seldom addressed in those studies. This is mostly due to the fact that the study of hemodynamics in in vivo animal models is not straightforward and moreover, that several hemodynamic parameters cannot be experimentally determined due to technical constraints. In this work, we reasoned that these limitations could be circumvented by the development and use of numerical simulations to describe leukocyte recruitment. Many of the processes, which take place in living organisms, can be expressed as mathematical equations. This applies to leukocyte recruitment, for which scarce numerical models existed before the beginning of this work. Importantly, these mathematical simulations were performed without considering simultaneously all the players in the process, namely the vessel, the blood flow and the leukocytes. Moreover, most of these studies were two dimensional, assumed blood as a Newtonian fluid with constant viscosity and did not take into account in vivo experimental data. Taken this, our major goal with this work was to understand the contribution of hemodynamics to leukocyte recruitment in inflammation. For such purpose, we aimed here at developing numerical simulations that more adequately reproduced this process. For such, we set up animal models of inflammation to obtain the experimental data required for the development of those numerical simulations. Finally, we used these models to investigate the role of hemodynamics in leukocyte recruitment in inflammation. First, we considered the simpler case of a numerical simulation that assumed leukocytes to be rigid spheres and blood, a non-Newtonian fluid. For such, we initially developed an animal model of inflammation in Wistar rats using a lipopolysaccharide (LPS) as an inflammatory agent. Blood samples were collected for determination of TNF-α levels to ensure the triggering of the inflammatory process. Importantly, the number of rolling and adherent leukocytes in post-capillary venules was monitored using an intravital microscopy approach. As expected, our results showed that there is an increase in TNF-α concentrations after 15 minutes of LPS administration and a significant increase in the number of rolling and adherent leukocytes. The recorded intravital microcopy images, along with other recorded parameters, were then used, in collaboration with a group of mathematicians, to develop a numerical model capable of describing leukocyte recruitment in the microcirculation. To evaluate the contribution of hemodynamics, the localized velocity fields and shear stresses on the surface of leukocytes and near the vessel wall contact points have been computed in two discrete situations, namely as a single leukocyte or when a cluster of them are recruited towards the vessel wall. In the first situation, our numerical results showed the presence of one region of maximum shear stress on the surface of the leuko- cyte close to the endothelial wall and of two regions of minimum shear stress on the op- posite side of the cell. The different areas of shear stress observed in the surface of the leukocyte may be important in directing it towards the endothelial wall during an inflammatory response. The identification of a region of maximum shear stress is consistent with the molecular mechanisms that govern leukocyte rolling because it may actually cor- respond to the area that supports the interaction with the endothelium. On the other hand, the relatively lower shear stress regions may correlate with leukocyte surface areas where binding to the endothelium is not occurring at the moment, thus enabling the roll- ing of the cell along the endothelium. It was also observed that the shear stress at the endothelium gets higher as a cluster of leukocytes moves in the main stream. This sug- gests that the presence of a cluster of leukocytes may potentiate leukocyte rolling, as the increase in the shear stress promoted by the recruited leukocytes may support the migra- tion and recruitment of additional cells. Despite closely simulating leukocyte recruitment, our initial numerical simulation consid- ered the simple case of leukocytes as rigid spheres. However, while circulating leukocytes maintain an approximately spherical shape, rolling leukocytes are known to deform. In order to account for the leukocyte deformability changes that occur during its recruit- ment in inflammation, we needed to assess the deformability profile of the leukocytes under flow and therefore, to “directly” observe them regardless of the other blood cells. For such, intravital microscopy was performed in the mouse cremaster of a transgenic mice strain (Lys-EGFP-ki) in which fluorescent neutrophils can be individually tracked. By using PAF as an inflammatory agent, the analysis of the leukocyte-endothelial cell interac- tions showed a continuous increase in the number of rolling and adherent neutrophils up to 4 hours after the introduction of the inflammatory stimuli, thus confirming the devel- opment of an inflammatory response. As the properties of the red blood cells modulate blood flow properties, erythrocyte deformability was also addressed in this model. A con- tinuous decrease of this parameter was observed throughout time. The decrease in the erythrocyte deformability will most probably lead to an increase in the blood viscosity and to the decrease of the blood flow velocity. These conditions should facilitate the mi- gration of leukocytes from the mainstream to the endothelial wall and promote leukocyte slow rolling and adhesion during the inflammatory response. Importantly, in the intravital microcopy images obtained with this latter model, we clearly observed the deformation of neutrophils along the endothelial wall during rolling, as well as the formation of tethers. As such, in these images, leukocyte trajectories were tracked and their velocities and diameters were measured and further applied to the numerical simulations. Using a recent validated mathematical model describing the coupled defor- mation-flow of an individual leukocyte and the respective experimental results, numerical simulations of the recruitment of an individual leukocyte and of two leukocytes under different velocities were performed, considering a constant blood viscosity. The mathe- matical models obtained showed that under conditions of increased velocity the cell movement is accelerated along the endothelial layer, favouring the dissociation of leuko- cyte-endothelium interactions at designated attraction points. These observations lead us to propose that, in order to attain an efficient inflammatory response, the blood flow ve- locity needs so as to decrease to facilitate slow rolling and subsequent adhesion. These results are corroborated by the decrease in the erythrocyte deformability observed in our animal model, which will ultimately have an impact on the blood flow velocity. Our results further showed that in the vicinity of an adherent leukocyte there is an early slight decel- eration of the rolling leukocyte when compared with the case of an individual leukocyte. As such, these observations strongly suggest that the presence of an adherent cell in the vicinity should decrease the velocity of another leukocyte that is being recruited, thus promoting its slow rolling, and contributing to its capture by the endothelial cells. Altogether, our experimental data and numerical simulations support our working hy- pothesis that the hemodynamic properties of the flow and of the cells in circulation should play an essential role in the margination and rolling of the leukocytes to the endo- thelial wall, which in turn will impact the success of the inflammatory response. In partic- ular, our results strongly suggest that changes in hemodynamic conditions, such as de- creased flow velocities and the increase of the shear stress, will contribute to target leu- kocytes to the endothelial wall. Given our results, we propose that any change in the he- modynamic properties will certainly influence the outcome of the inflammatory response. As such, the adherence of the leukocytes to the endothelium should depend not only on the relative magnitude of the chemical forces generated by the interaction of adhesion molecules between leukocytes and endothelial cells, but also on the physical forces that act on the leukocytes. In this respect, our results suggest that alterations in the blood flow, for example in the flow velocity, will occur during an inflammatory process, thus potentiating the recruitment of more leukocytes towards the inflamed area and contrib- uting to a successful inflammatory response. Overall, the numerical simulations allowed us to better understand the contribution of the hemodynamic properties of the flow to the progression of an inflammatory response and to deepen our knowledge on leukocyte recruitment in inflammation. Importantly, our work provided numerical tools that can be used for the subsequent study and modulation of the hemodynamic parameters involved in an inflammatory response. In particular, these numerical simulations will surely enable us, in the near future, to determine or es- timate a large set of parameters which are unlikely to be recoverable by in vivo experi- ments. Moreover, our methods will allow us to analyze how the parameters evolve over time. Altogether our results further reinforce the notion that the improvement and de- velopment of animal models and numerical tools will certainly provide the medical and biological community with useful tools to study leukocyte recruitment in inflammation. By closely reproducing the microcirculation and the inflammatory process, these tools will be critical for a better comprehension of the inflammatory process and of the mecha- nisms underlying a multitude of inflammatory pathological conditions

Imaging leukocyte trafficking in vivo with two-photon-excited endogenous tryptophan fluorescence

We describe a new method for imaging leukocytes in vivo by exciting the endogenous protein fluorescence in the ultraviolet (UV) spectral region where tryptophan is the major fluorophore. Two-photon excitation near 590 nm allows noninvasive optical sectioning through the epidermal cell layers into the dermis of mouse skin, where leukocytes can be observed by video-rate microscopy to interact dynamically with the dermal vascular endothelium. Inflammation significantly enhances leukocyte rolling, adhesion, and tissue infiltration. After exiting the vasculature, leukocytes continue to move actively in tissue as observed by time-lapse microscopy, and are distinguishable from resident autofluorescent cells that are not motile. Because the new method alleviates the need to introduce exogenous labels, it is potentially applicable for tracking leukocytes and monitoring inflammatory cellular reactions in humans

The role of calcium signaling analysis in myeloid leukocyte activation and interactions in inflammation

Inflammation is the pathophysiologic basis of many diseases that are main causes of mortality. Caused by environmental or microbial factors, inflammation leads to the destruction of tissue around the primary focus and expands to other tissues when not resolved in a timely manner. The body’s mechanism for inflammation resolution is based on an interplay of immune cells that first drive a pro-inflammatory response necessary for recruiting neutrophils and macrophages that phagocytose debris and dendritic cells that relay information to lymphocytes that build up the body’s adaptive immunity. Neutrophils are key to this process as they are the first cell type to recognize damage and pathogen associated molecular patterns (DAMPs and PAMPs). Eventually, they undergo necrosis amplifying the chemokine and cytokine gradient needed for added neutrophil swarming and other cells’ recruitment. In addition to the release of chemokine cues, neutrophil necrosis results in the release of reactive oxygen species that is an additional mediator of tissue damage. Although the literature hints at a cellular interplay as mechanism to prevent excessive neutrophil-induced tissue damage, there is to date no tool to investigate intravital leukocyte activation patterns in vivo in this setting. For this purpose, we turned to calcium (Ca++) signaling since it is known to be involved in most aspects of cellular function. By using myeloid leukocyte specific Ca++ reporter strains together with in vivo two-photon and spinning disk confocal microscopy in a sterile inflammation mouse model, we developed an image analysis algorithm of frequency spectra that offers the following insights: macrophages react to sterile inflammation by Ca++ transients in a distinct spatiotemporal pattern and neutrophils vary their intracellular dynamics during the migration cascade in a Gαi-protein-coupled receptor dependent manner. Furthermore, during resolution of inflammation we observed tissue macrophages (TMs) physically contacting injury-bound neutrophils with their dendrites and instructing them to withdraw. Ca++ signal analysis displays that both cell types undergo cellular activation adjustments during interaction. Finally, we uncovered that the HMGB1-TLR4 axis is responsible for TM dendrite formation and that LFA-1 mediates neutrophil interaction with these dendrites. Therefore, we have uncovered a mechanism how tissue inflammation is limited through macrophage-neutrophil interactions

ADAM8 signaling drives neutrophil migration and ARDS severity

Acute respiratory distress syndrome (ARDS) results in catastrophic lung failure and has an urgent, unmet need for improved early recognition and therapeutic development. Neutrophil influx is a hallmark of ARDS and is associated with the release of tissue-destructive immune effectors, such as matrix metalloproteinases (MMPs) and membrane-anchored metalloproteinase disintegrins (ADAMs). Here, we observed using intravital microscopy that Adam8–/– mice had impaired neutrophil transmigration. In mouse pneumonia models, both genetic deletion and pharmacologic inhibition of ADAM8 attenuated neutrophil infiltration and lung injury while improving bacterial containment. Unexpectedly, the alterations of neutrophil function were not attributable to impaired proteolysis but resulted from reduced intracellular interactions of ADAM8 with the actin-based motor molecule Myosin1f that suppressed neutrophil motility. In 2 ARDS cohorts, we analyzed lung fluid proteolytic signatures and identified that ADAM8 activity was positively correlated with disease severity. We propose that in acute inflammatory lung diseases such as pneumonia and ARDS, ADAM8 inhibition might allow fine-tuning of neutrophil responses for therapeutic gain

Behavioral immune landscapes of inflammation.

Transcriptional or proteomic profiling of individual cells have revolutionized interpretation of biological phenomena by providing cellular landscapes of healthy and diseased tissues. These approaches, however, fail to describe dynamic scenarios in which cells can change their biochemical properties and downstream “behavioral” outputs every few seconds or minutes. Here, we used 4D live imaging to record tens to hundreds of morpho-kinetic parameters describing the dynamism of individual leukocytes at sites of active inflammation. By analyzing over 100,000 reconstructions of cell shapes and tracks over time, we obtained behavioral descriptors of individual cells and used these high-dimensional datasets to build behavioral landscapes. These landscapes recognized leukocyte identities in the inflamed skin and trachea, and inside blood vessels uncovered a continuum of neutrophil states, including a large, sessile state that was embraced by the underlying endothelium and associated with pathogenic inflammation. Behavioral in vivo screening of thousands of cells from 24 different mouse mutants identified the kinase Fgr as a driver of this pathogenic state, and genetic or pharmacological interference of Fgr protected from inflammatory injury. Thus, behavioral landscapes report unique biological properties of dynamic environments at high cellular, spatial and temporal resolution.pre-print4302 K