Zika Virus Infects Human Sertoli Cells And Trespasses The Blood-Testes Barrier To Gain Entry Into The Seminiferous Epithelium

M.S. Thesis. University of Hawaiʻi at Mānoa 2017

Chemokines (CCL3, CCL4, CCL5) inhibit ATP-induced release of IL-1beta by monocytic cells

ATP and chemokines are among the first inflammatory mediators that can enter the circulation via damaged blood vessels at the site of injury, leading to an activation of the host’s immune response. The main function of chemokines is leukocyte mobilization, guiding immune cells towards the injured tissue along a chemotactic concentration gradient. In monocytes, ATP typically triggers inflammasome assembly, a multiprotein complex necessary for the maturation and secretion of IL-1beta. IL-1beta is a potent inflammatory cytokine of innate immunity, essential for pathogen defense. However, excessive IL-1beta may cause life-threatening systemic inflammation. Here, we hypothesize that chemokines control ATP-dependent secretion of monocytic IL-1beta, by engaging a cholinergic signaling pathway. LPS-primed human monocytic U937 cells were treated with chemokines in the presence or absence of nAChR antagonists or iPLA2beta inhibitors and concomitantly stimulated with the P2X7 agonist BzATP. IL-1beta concentration was determined in the cell culture supernatants. Silencing of the chemokine receptor and iPLA2b gene expression was achieved by transfecting cells with the appropriate siRNA. CCL3, CCL4, and CCL5 dose-dependently inhibited BzATP-stimulated release of IL-1beta, whereas CXCL16 was ineffective. The effect of CCL3 was confirmed for primary mononuclear leukocytes. The inhibitory effect of CCL3 was blunted after silencing CCR1 or iPLA2beta gene expression by siRNA and was sensitive to antagonists of nAChRs containing subunits alpha7 and alpha9/alpha10. U937 cells secreted small factors in response to CCL3 that mediated the inhibition of IL-1beta release. We suggest that CCL chemokines inhibit ATP-induced release of IL-1beta from U937 cells by a triple-membrane-passing mechanism involving CCR, iPLA2, release of small mediators, and nAChR subunits alpha7 and alpha9/alpha10. We speculate that whenever chemokines and ATP enter the circulation concomitantly, systemic release of IL-1beta is minimized

Microfluidic Organ‐on‐a‐Chip Technology for Advancement of Drug Development and Toxicology

In recent years, the exploitation of phenomena surrounding microfluidics has seen an increase in popularity, as researchers have found a way to use their unique properties to create superior design alternatives. One such application is representing the properties and functions of different organs on a microscale chip for the purpose of drug testing or tissue engineering. With the introduction of “organ‐on‐a‐chip” systems, researchers have proposed various methods on various organ‐on‐a‐chip systems to mimic their in vivo counterparts. In this article, a systematic approach is taken to review current technologies pertaining to organ‐on‐a‐chip systems. Design processes with attention to the particular instruments, cells, and materials used are presented

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

Biophysical Aspects of Leukocyte Transmigration through the Vascular Endothelium

Leukocyte transmigration through the vascular endothelium is a key step in the immune response, and also in progression of the cardiovascular disease atherosclerosis. Much work has previously focused on the biological aspects of leukocyte transmigration, such as cytokine exposure, junctional protein organization in the endothelium, and signaling pathways. However, in recent years, many studies have identified links between the mechanical properties of the cellular microenvironment and cell behavior. This is relevant to the cardiovascular system in two ways: (1) it is likely that the mechanical properties of vasculature depend on both vessel size (large vessels versus microvasculature) and tissue type (soft brain versus stiffer muscle or tumor), and (2) both large vessels and microvasculature stiffen in atherosclerosis. For the first time, this dissertation provides a quantitative evaluation of the biophysical effects of vasculature stiffening on endothelial cell (EC) biomechanical properties, as well as leukocyte migration and transmigration. A novel in vitro model of the vascular endothelium was created. This model mimics physiological conditions more closely than previous models, by taking into account the flexibility of the subendothelial matrix; previous models have mostly utilized glass or plastic substrates that are much stiffer than physiological. EC monolayers were formed on extracellular matrix (ECM) protein-coated hydrogels and activated with tumor necrosis factor-α or oxidized low density lipoprotein to induce an inflammatory response. We determined that three important components of the in vitro model (cell-cell adhesion, cytokine exposure, and subendothelial matrix stiffness) have significant effects on EC biomechanical properties. Next, we showed that neutrophils are mechanosensitive, as their migration is biphasic with substrate stiffness and depends on an interplay between substrate stiffness and ECM protein amount; these results suggest that any biomechanical changes which occur in vasculature may also affect the immune response. Finally, we discovered that neutrophil transmigration increases with subendothelial matrix stiffness, and we demonstrated that this effect is due to substrate stiffness-dependent EC contractile forces. These results indicate, for the first time, that the biophysical states of the endothelium and subendothelial matrix, which likely vary depending on size, location, and health of vasculature, are important regulators of the immune response

Dynamics of in silico leukocyte rolling, activation, and adhesion

BACKGROUND: We present a multilevel, agent based, in silico model that represents the dynamics of rolling, activation, and adhesion of individual leukocytes in vitro. Object-oriented software components were designed, verified, plugged together, and then operated in ways that represent the molecular and cellular mechanisms believed responsible for leukocyte rolling and adhesion. The result is an in silico analogue of an experimental in vitro system. The experimentally measured, phenotypic attributes of the analogue were compared and contrasted to those of leukocytes in vitro from three different experimental conditions. RESULTS: The individual in silico dynamics of "rolling" on simulated P-selectin, and separately on simulated VCAM-1, were an acceptable match to individual in vitro distance-time and velocity-time measurements. The analogues are also able to represent the transition from rolling to adhesion on P-selectin and VCAM-1 in the presence of GRO-α chemokine. The individual in silico and in vitro behavioral similarities translated successfully to population level measures. These behavioral similarities were enabled in part by subdividing the functionality of the analogue's surface into 600 independent, "cell"-controlled, equally capable modules of comparable functionality. CONCLUSION: The overlap in phenotypic attributes of our analogue with those of leukocytes in vitro confirm the considerable potential of our model for studying the key events that determine the behavioral outcome of individual leukocytes during rolling, activation, and adhesion. Our results provide an important foundation and framework for future in silico research into plausible causal links between well-documented, subcellular molecular level events and the variety of systemic phenotypic attributes that distinguish normal leukocyte adhesion from abnormal disease-associated adhesion

Local Oxidative and Nitrosative Stress Increases in the Microcirculation during Leukocytes-Endothelial Cell Interactions

Leukocyte-endothelial cell interactions and leukocyte activation are important factors for vascular diseases including nephropathy, retinopathy and angiopathy. In addition, endothelial cell dysfunction is reported in vascular disease condition. Endothelial dysfunction is characterized by increased superoxide (O2•−) production from endothelium and reduction in NO bioavailability. Experimental studies have suggested a possible role for leukocyte-endothelial cell interaction in the vessel NO and peroxynitrite levels and their role in vascular disorders in the arterial side of microcirculation. However, anti-adhesion therapies for preventing leukocyte-endothelial cell interaction related vascular disorders showed limited success. The endothelial dysfunction related changes in vessel NO and peroxynitrite levels, leukocyte-endothelial cell interaction and leukocyte activation are not completely understood in vascular disorders. The objective of this study was to investigate the role of endothelial dysfunction extent, leukocyte-endothelial interaction, leukocyte activation and superoxide dismutase therapy on the transport and interactions of NO, O2•− and peroxynitrite in the microcirculation. We developed a biotransport model of NO, O2•− and peroxynitrite in the arteriolar microcirculation and incorporated leukocytes-endothelial cell interactions. The concentration profiles of NO, O2•− and peroxynitrite within blood vessel and leukocytes are presented at multiple levels of endothelial oxidative stress with leukocyte activation and increased superoxide dismutase accounted for in certain cases. The results showed that the maximum concentrations of NO decreased ∼0.6 fold, O2•− increased ∼27 fold and peroxynitrite increased ∼30 fold in the endothelial and smooth muscle region in severe oxidative stress condition as compared to that of normal physiologic conditions. The results show that the onset of endothelial oxidative stress can cause an increase in O2•− and peroxynitrite concentration in the lumen. The increased O2•− and peroxynitrite can cause leukocytes priming through peroxynitrite and leukocytes activation through secondary stimuli of O2•− in bloodstream without endothelial interaction. This finding supports that leukocyte rolling/adhesion and activation are independent events