Kate Tatham

Regulation of monocyte subset proinflammatory responses within the lung microvasculature by the p38 MAPK/MK2 pathway

Margination and activation of monocytes within the pulmonary microcirculation contribute substantially to the development of acute lung injury in mice. The enhanced LPS-induced TNF expression exhibited by Gr-1high compared with Gr-1low monocytes within the lung microvasculature suggests differential roles for these subsets. We investigated the mechanisms responsible for such heterogeneity of lung-marginated monocyte proinflammatory response using a combined in vitro and in vivo approach. The monocyte subset inflammatory response was studied in vitro in mouse peripheral blood mononuclear cell-lung endothelial cell coculture and in vivo in a two-hit model of intravenous LPS-induced monocyte margination and lung inflammation in mice, by flow cytometry-based quantification of proinflammatory genes and intracellular phospho-kinases. With LPS stimulation in vitro, TNF expression was consistently higher in Gr-1high than Gr-1low monocytes, markedly enhanced by coculture with endothelial cells, and abrogated by p38 MAPK inhibitors. Expression of IL-6, inducible nitric oxide synthase (iNOS), and cyclooxygenase-2 (COX-2) was only detectable under coculture conditions, was substantially higher in Gr-1high monocytes, and was attenuated by p38 inhibition. Consistent with these differential responses, phosphorylation of p38 and its substrate MAPK-activated protein kinase 2 (MK2) was significantly higher in the Gr-1high subset. In vivo, p38 inhibitor treatment significantly attenuated LPS-induced TNF expression in “lung-marginated” Gr-1high monocytes. LPS-induced p38/MK2 phosphorylation was higher in lung-marginated Gr-1high than Gr-1low monocytes and neutrophils, mirroring TNF expression. These results indicate that the p38/MK2 pathway is a critical determinant of elevated Gr-1high subset responsiveness within the lung microvasculature, producing a coordinated proinflammatory response that places Gr-1high monocytes as key orchestrators of pulmonary microvascular inflammation and injury.

Volutrauma, but not atelectrauma, induces systemic cytokine production by lung-marginated monocytes.

Objectives:Ventilator-induced lung injury has substantive impact on mortality of patients with acute respiratory distress syndrome. Although low tidal volume ventilation has been shown to reduce mortality, clinical benefits of open-lung strategy are controversial. In this study, we investigated the impact of two distinct forms of ventilator-induced lung injury, i.e., volutrauma and atelectrauma, on the progression of lung injury and inflammation, in particular alveolar and systemic cytokine production. Design:Ex vivo study. Setting:University research laboratory. Subjects:C57BL/6 mice. Interventions:Isolated, buffer-perfused lungs were allocated to one of three ventilatory protocols for 3 hours: control group received low tidal volume (7 mL/kg) with positive end-expiratory pressure (5 cm H2O) and regular sustained inflation; high-stretch group received high tidal volume (30–32 mL/kg) with positive end-expiratory pressure (3 cm H2O) and sustained inflation; and atelectasis group received the same tidal volume as control but neither positive end-expiratory pressure nor sustained inflation. Measurements and Main Results:Both injurious ventilatory protocols developed comparable levels of physiological injury and pulmonary edema, measured by respiratory system mechanics and lavage fluid protein. High-stretch induced marked increases in proinflammatory cytokines in perfusate and lung lavage fluid, compared to control. In contrast, atelectasis had no effect on perfusate cytokines compared to control but did induce some up-regulation of lavage cytokines. Depletion of monocytes marginated within the lung microvasculature, achieved by pretreating mice with IV liposome-encapsulated clodronate, significantly attenuated perfusate cytokine levels, especially tumor necrosis factor, in the high-stretch, but not atelectasis group. Conclusions:Volutrauma (high-stretch), but not atelectrauma (atelectasis), directly activates monocytes within the pulmonary vasculature, leading to cytokine release into systemic circulation. We postulate this as a potential explanation why open-lung strategy has limited mortality benefits in ventilated critically ill patients.

In vivo compartmental analysis of leukocytes in mouse lungs

The lung has a unique structure consisting of three functionally different compartments (alveolar, interstitial, and vascular) situated in an extreme proximity. Current methods to localize lung leukocytes using bronchoalveolar lavage and/or lung perfusion have significant limitations for determination of location and phenotype of leukocytes. Here we present a novel method using in vivo antibody labeling to enable accurate compartmental localization/quantification and phenotyping of mouse lung leukocytes. Anesthetized C57BL/6 mice received combined in vivo intravenous and intratracheal labeling with fluorophore-conjugated anti-CD45 antibodies, and lung single-cell suspensions were analyzed by flow cytometry. The combined in vivo intravenous and intratracheal CD45 labeling enabled robust separation of the alveolar, interstitial, and vascular compartments of the lung. In naive mice, the alveolar compartment consisted predominantly of resident alveolar macrophages. The interstitial compartment, gated by events negative for both intratracheal and intravenous CD45 staining, showed two conventional dendritic cell populations, as well as a Ly6Clo monocyte population. Expression levels of MHCII on these interstitial monocytes were much higher than on the vascular Ly6Clo monocyte populations. In mice exposed to acid aspiration-induced lung injury, this protocol also clearly distinguished the three lung compartments showing the dynamic trafficking of neutrophils and exudative monocytes across the lung compartments during inflammation and resolution. This simple in vivo dual-labeling technique substantially increases the accuracy and depth of lung flow cytometric analysis, facilitates a more comprehensive examination of lung leukocyte pools, and enables the investigation of previously poorly defined “interstitial” leukocyte populations during models of inflammatory lung diseases.

Intravascular donor monocytes play a central role in lung transplant ischaemia-reperfusion injury

Rationale Primary graft dysfunction in lung transplant recipients derives from the initial, largely leukocyte-dependent, ischaemia-reperfusion injury. Intravascular lung-marginated monocytes have been shown to play key roles in experimental acute lung injury, but their contribution to lung ischaemia-reperfusion injury post transplantation is unknown. Objective To define the role of donor intravascular monocytes in lung transplant-related acute lung injury and primary graft dysfunction. Methods Isolated perfused C57BL/6 murine lungs were subjected to warm ischaemia (2 hours) and reperfusion (2 hours) under normoxic conditions. Monocyte retention, activation phenotype and the effects of their depletion by intravenous clodronate-liposome treatment on lung inflammation and injury were determined. In human donor lung transplant samples, the presence and activation phenotype of monocytic cells (low side scatter, 27E10+, CD14+, HLA-DR+, CCR2+) were evaluated by flow cytometry and compared with post-implantation lung function. Results In mouse lungs following ischaemia-reperfusion, substantial numbers of lung-marginated monocytes remained within the pulmonary microvasculature, with reduced L-selectin and increased CD86 expression indicating their activation. Monocyte depletion resulted in reductions in lung wet:dry ratios, bronchoalveolar lavage fluid protein, and perfusate levels of RAGE, MIP-2 and KC, while monocyte repletion resulted in a partial restoration of the injury. In human lungs, correlations were observed between pre-implantation donor monocyte numbers/their CD86 and TREM-1 expression and post-implantation lung dysfunction at 48 and 72 hours. Conclusions These results indicate that lung-marginated intravascular monocytes are retained as a ‘passenger’ leukocyte population during lung transplantation, and play a key role in the development of transplant-associated ischaemia-reperfusion injury.

An analysis of the delivery of anaesthetic training sessions in the United Kingdom

We analysed data from the electronic rota system CLWRota, covering 2,689,962 anaesthetic sessions between 01/01/2014 and 31/12/2015, in 91 UK Trusts, in order to investigate trainees’ supervision. There were 8209 trainee attachments analysed, during which 618,695 sessions were undertaken by trainees. The number of supervised sessions per week that trainees worked varied considerably (median (IQR [range]) 2.6 (1.6–3.6 [0–10]) for all grades combined), with senior trainees more likely than junior trainees to be supervised for fewer than the three sessions per week mandated by the Royal College of Anaesthetists. The number of supervised sessions was unrelated to Trusts’ size, suggesting that trainees in smaller hospitals receive the same level of supervision as in larger teaching hospitals. Analysis of a dataset of this size should be a good reflection of the delivery of anaesthesia training in the UK.

Mesenchymal stem cells enhance NOX2-dependent reactive oxygen species production and bacterial killing in macrophages during sepsis

Human mesenchymal stem/stromal cells (MSCs) have been reported to produce an M2-like, alternatively activated phenotype in macrophages. In addition, MSCs mediate effective bacterial clearance in pre-clinical sepsis models. Thus, MSCs have a paradoxical antimicrobial and anti-inflammatory response that is not understood. Here, we studied the phenotypic and functional response of monocyte-derived human macrophages to MSC exposure in vitro. MSCs induced two distinct, coexistent phenotypes: M2-like macrophages (generally elongated morphology, CD163+, acute phagosomal acidification, low NOX2 expression and limited phagosomal superoxide production) and M1-like macrophages characterised by high levels of phagosomal superoxide production. Enhanced phagosomal reactive oxygen species production was also observed in alveolar macrophages from a rodent model of pneumonia-induced sepsis. The production of M1-like macrophages was dependent on prostaglandin E2 and phosphatidylinositol 3-kinase. MSCs enhanced human macrophage phagocytosis of unopsonised bacteria and enhanced bacterial killing compared with untreated macrophages. Bacterial killing was significantly reduced by blockade of NOX2 using diphenyleneiodonium, suggesting that M1-like cells are primarily responsible for this effect. MSCs also enhanced phagocytosis and polarisation of M1-like macrophages derived from patients with severe sepsis. The enhanced antimicrobial capacity (M1-like) and inflammation resolving phenotype (M2-like) may account for the paradoxical effect of these cells in sepsis in vivo. Mesenchymal stem cells enhance bacterial killing via production of phagosomal reactive oxygen species in macrophages http://ow.ly/tigl30iGFPG

The role of ex vivo lung perfusion in lung transplantation

Whilst lung transplantation is a viable solution for end-stage lung disease, donor shortages, donor lung inflammation and perioperative lung injury remain major limitations. Ex vivo lung perfusion has emerged as the next frontier in lung transplantation to address and overcome these limitations, with multicentre clinical trials ongoing in the UK, rest of Europe and North America. Our research seeks to identify the poorly understood cellular and molecular mechanisms of primary graft dysfunction through the development of an isolated perfused lung model of transplantation and investigation of the role of pulmonary inflammation in this paradigm.

Supranormal Elevation of Systemic Oxygen Delivery in Critically Ill Patients

Multiple organ dysfunction syndrome is the leading cause of mortality in intensive care units and is precipitated by tissue hypoperfusion. The optimization of oxygen delivery to supranormal levels by infusion of fluids, red blood cells and vasoactive drugs as needed has been adopted in an effort to avoid and reverse this tissue hypoxia and resultant organ damage. Both hemodynamic (cardiac index ≥ 4.5 L/min/m2) and oxygen transport (oxygen delivery ≥ 600mls/min/m2, oxygen consumption ≥ 170mls/min/m2) targets have been extensively investigated, however supranormal elevation of oxygen delivery does not improve overall outcome in critically ill patients. Furthermore, it is often difficult to achieve targets of increased oxygen consumption, with attempts to do this proving detrimental, as demonstrated in Hayes’ work. Early resuscitation, however, appears to be beneficial and a favorable response to hemodynamic optimization may predict survival.