IN VIVO STUDIES OF CELL-FREE DNA AND DNASE IN A MURINE MODEL OF POLYMICROBIAL SEPSIS

Mai, Safiah Hwai Chuen

January 2016

Sepsis is a clinical syndrome characterized by the systemic activation of inflammatory and coagulation pathways in response to microbial infection of normally sterile parts of the body. Despite considerable advances in our understanding of sepsis pathophysiology, sepsis remains the leading cause of death in non-coronary intensive care units (ICU) with a global disease burden between 15 and 19 million cases per year (Dellinger et al., 2008). Severe sepsis, defined as sepsis associated with organ dysfunction is associated with mortality rates of 33% to 45%. The incidence of severe sepsis continues to increase by 1.5% per annum due to the aging population, a rise in the prevalence of comorbidities, and the wider use of immunosuppressive agents and invasive procedures (Angus et al., 2001). Over the past several decades, many potential treatments for sepsis have shown early promise, yet have failed to improve survival in over 100 Phase II and Phase III clinical trials (Marshall, 2014) suggesting that some fundamental knowledge is lacking in our understanding of sepsis pathophysiology. Emerging studies on cell-free DNA (cfDNA), DNA released extracellularly into the circulation, demonstrate that cfDNA is a crucial link between inflammation and coagulation . In various conditions characterized by excessive inflammatory responses or aberrant prothrombotic responses, cfDNA has been implicated in exacerbating disease pathology (Atamaniuk, Kopecky, Skoupy, Säemann, & Weichhart, 2012; Fuchs, Brill, & Wagner, 2012; Swystun, Mukherjee, & Liaw, 2011). In clinical sepsis, levels of cfDNA upon admission into the ICU have strong prognostic value in predicting mortality (Dwivedi et al., 2012; Saukkonen et al., 2008). However, it is unclear whether these increases in cfDNA are an epiphenomenon during sepsis progression, or whether cfDNA actively plays a role in sepsis pathophysiology. In this work, in vivo studies were conducted to characterize the role of cfDNA in sepsis, the effects of DNase administration, and the potential mechanism by which cfDNA is released during experimental sepsis. In addition, mortality studies were conducted to identify surrogate markers of death to promote the design of humane and ethical animal studies in conducting sepsis research. Polymicrobial sepsis was induced via a surgical procedure whereby the cecum is exteriorized, ligated and punctured twice to introduce a continuous source of microorganisms, a model termed cecal ligation and puncture (CLP). In our CLP sepsis model, levels of cfDNA increased in a time-dependent manner. These increases accompanied an early pro-inflammatory response marked by increased pro-inflammatory IL-6, a transient increase in anti-inflammatory IL-10, and elevated lung myeloperoxidase (MPO) activity. Septic mice with elevated cfDNA levels also had high bacterial loads in the lungs, blood, and peritoneal cavity fluid. Organ damage was also observed in mice following CLP surgery versus mice subjected to the non-septic sham control surgery marked by increased levels of creatinine and alanine aminotransferase (ALT) indicative of kidney and liver injury, respectively. Histological analyses further confirmed lung and kidney damage following CLP surgery. Changes in coagulation were also observed in septic mice as mice subjected to CLP had sustained increases in thrombin-antithrombin (TAT) complexes. In addition, plasma from CLP-operated mice had increased thrombin generation (i.e. increased endogenous thromin potential, increased peak thrombin, decreased time to peak, and decreased lag time) mediated by FXIIa and enhanced by platelets. Following CLP-induced sepsis, elevations in cfDNA levels accompanied pro-inflammatory and pro-coagulant responses. The effects of in vivo DNase treatment in septic mice were time-dependent. Early DNase treatment when cfDNA levels were low resulted in an exaggerated pro-inflammatory response marked by increased plasma IL-6 levels and increased lung damage. In contrast, delayed DNase treatment at time-points when cfDNA levels were elevated suppressed inflammation characterized by an increase in anti-inflammatory IL-10 and reductions in cfDNA, IL-6, lung MPO, and ALT activity. Furthermore, delayed DNase administration resulted in decreased bacterial load in the lungs, blood, and peritoneal cavity fluid. Delayed DNase treatment also resulted in blunted pro-coagulant responses as levels of TAT complexes were suppressed and thrombin generation from septic mouse plasma was normalized. Moreover, DNase treatment when cfDNA levels were elevated increased survival in CLP-operated mice by 80% and reduced lung and liver damage. These findings suggest that administration of DNase when cfDNA levels are elevated may reduce pro-inflammatory and pro-coagulant responses and that delayed DNase treatment may infer protection in the CLP model of sepsis. One mechanism by which cfDNA is released is via the formation of neutrophil extracellular traps (NETs). Upon inflammatory stimulation, some neutrophils release chromatin material and antimicrobial proteins (i.e. neutrophil elastase, MPO, and histones) in an active process termed NETosis. Although NETs ensnare bacteria and exert antimicrobial properties, NETs may also exert harmful effects on the host by activating inflammation and coagulation. While some in vitro evidence suggest that neutrophils are the main source of cfDNA released following inflammatory stimulation, others have reported that neutrophils are not the main source of circulating cfDNA following septic challenge. To determine whether NETs contribute to cfDNA released during CLP sepsis, genetically modified mice that are incapable of forming NETs, PAD4-/- mice, were used. Levels of cfDNA in PAD-/- mice were significantly lower than cfDNA levels in C57Bl/6 mice following CLP surgery, suggesting that NETs were a source of cfDNA in our model. Levels of IL-6, MPO, and bacterial load in the lungs, blood, and peritoneal cavity were significantly reduced, indicating that NETs exert pro-inflammatory effects in CLP sepsis. Thrombin generation was also suppressed in PAD4-/- mice which suggests that NETs contribute to thrombin generation following CLP sepsis. NETs contribute to increases in circulating cfDNA and may exacerbate pathology by driving pro-inflammatory and pro-coagulant responses in CLP-induced sepsis. Appreciating the implications of conducting research using animals, it is pertinent that researchers ensure the highest ethical standards and design animal studies in the most humane, yet scientifically rigorous manner. Using mortality studies, we validated the utility of physiological and phenotypic markers to assess disease severity and predict death in murine sepsis. Temperature via a rectal probe monitor and sepsis scoring systems which assess components such as orbital tightening, level of consciousness, and activity were effective surrogate markers of death. These tools offer a non-invasive assessment of disease progression which do not artificially exacerbate sepsis pathology and immediate information regarding any changes in the health status. Surrogate markers of death also provide reliable monitoring to meet increasing standards of ethical, humane animal research and a feasible and cost-efficient means to obtain vital signs in small rodents. We have proposed a scoring system which can be used for assessing disease severity, endpoint monitoring, and predicting death to obviate inhumane methods of using death as an endpoint in sepsis studies. In summary, cfDNA levels are elevated in CLP-induced sepsis and these elevations accompany pro-inflammatory and pro-coagulant responses. NETosis may be a mechanism by which cfDNA is released and NETs may drive inflammation and coagulation in CLP sepsis. Delayed DNase administration may suppress inflammation and coagulation and may be protective in polymicrobial sepsis. In future animal sepsis studies, surrogate markers of death and a sepsis scoring system can be used in place of death as an endpoint to raise the standards in conducting ethical, humane sepsis research. / Thesis / Doctor of Philosophy (PhD)

Sepsis

Neutrophil Extracellular Traps (NETs)

Cell-free DNA

Animal Model

Cecal Ligation and Puncture

Murine Model

Inflammation

Coagulation

Critical Care

Sepsis Therapy

Papel do receptor toll-like 9 na falência de migração dos neutrófilos na sepse / The role of toll-like receptor 9 on failure of neutrophil migration during sepsis.

Trevelin, Silvia Cellone

20 December 2010

O recrutamento de neutrófilos para o sítio da infecção é um evento crucial para o combate aos microrganismos e sobrevivência na sepse. A migração destes polimorfonucleares é dirigida através de um gradiente quimiotático por meio do reconhecimento de quimiocinas por receptores acoplados a proteína G (GPCRs), os quais são regulados por quinases específicas (GRKs). Estudos prévios demonstraram que na sepse ocorre uma falência na migração de neutrófilos para o foco infeccioso em função da dessensibilização de receptores quimiotáticos via GRKs induzida pela ativação de receptores toll-like (TLRs), TLR2 e TLR4. Apesar de a ausência de TLR9 em células dendriticas ter sido relacionada a maior sobrevivência de camundongos sépticos, o papel do TLR9 atuando diretamente em neutrófilos não foi avaliado. Objetivando preencher esta lacuna, propôs-se avaliar o papel direto de TLR9 na falência de migração de neutrófilos na sepse. Os camundongos TLR9-/- apresentaram maior sobrevivência a sepse polimicrobiana avaliada por meio do modelo de ligadura e perfuração do ceco (CLP). A deficiência de TLR9 também acarretou em aumento na migração de neutrófilos para o foco da infecção, menor seqüestro de neutrófilos no pulmão, bem como, menor número de bactérias no lavado peritoneal e sangue. A ativação de TLR9 por oligodeoxinucleotídeo contendo o dinucleotídeo CpG não metilado (ODN CpG) nos neutrófilos reduziu a quimiotaxia destes em direção a quimiocina CXCL2 e expressão do receptor quimiotático CXCR2. Além disso, neutrófilos estimulados com ODN CpG apresentaram aumento na expressão da quinase tipo 2 relacionada a receptores acoplados a proteína G (GRK2). Dessa forma, a ativação de TLR9 em neutrófilos circulantes no sangue é prejudicial na sepse por reduzir a quimiotaxia destes para o foco da infecção ao induzir a dessensibilização de CXCR2 via GRK2. / The recruitment of neutrophils to the site of infection is a crucial event for combating the microorganisms and survival on sepsis. The neutrophil migration is directed by a chemotactic gradient through the recognition of chemokines by G protein-coupled receptors (GPCRs), which are regulated by specific kinases (GRKs). Previous studies have shown a failure of neutrophil migration into infectious focus on sepsis due to chemotactic receptor desensitization via GRKs induced by activation of toll- like receptors (TLRs), TLR2 and TLR4. Despite the absence of activation of TLR9 in dendritic cells have been related to increase survival of septic mice, the role of TLR9 acting directly on neutrophils was not evaluated. We proposed to verify the direct role of TLR9 in the failure of neutrophil migration on sepsis. The TLR9 knockout mice (TLR9-/-) showed high survival to polymicrobial sepsis using cecal ligation and puncture model (CLP). TLR9-/- mice had high neutrophil migration to the focus of infection, low neutrophil sequestration in the lung, as well as, few bacteria in the peritoneal exudates and blood. The activation of TLR9 by oligodeoxinucleotide containing unmethylated dinucleotide CpG (CpG ODN) in neutrophils also reduced chemotaxis toward CXCL2 and the expression of chemokine receptor CXCR2. In addition, neutrophils stimulated with CpG ODN showed increased expression of kinase-related G protein-coupled receptor type 2 (GRK2). Thus, the activation of TLR9 in blood circulating neutrophils is harmful on sepsis by reducing their chemotaxis into the site of the infection by inducing CXCR2 desensitization via GRK2.

Cecal ligation and puncture (CLP)

chemotaxis

CXCR2

CXCR2

dessensibilização

dessensitization

GRK2

GRK2

Ligadura e perfuração do ceco (CLP)

migração de neutrófilos

neutrophil migration

polimorfonucleares

polymorphonuclear

quimiotaxia

receptor toll-like 9.

toll-like-receptor 9.

Papel do receptor toll-like 9 na falência de migração dos neutrófilos na sepse / The role of toll-like receptor 9 on failure of neutrophil migration during sepsis.

Silvia Cellone Trevelin

20 December 2010

O recrutamento de neutrófilos para o sítio da infecção é um evento crucial para o combate aos microrganismos e sobrevivência na sepse. A migração destes polimorfonucleares é dirigida através de um gradiente quimiotático por meio do reconhecimento de quimiocinas por receptores acoplados a proteína G (GPCRs), os quais são regulados por quinases específicas (GRKs). Estudos prévios demonstraram que na sepse ocorre uma falência na migração de neutrófilos para o foco infeccioso em função da dessensibilização de receptores quimiotáticos via GRKs induzida pela ativação de receptores toll-like (TLRs), TLR2 e TLR4. Apesar de a ausência de TLR9 em células dendriticas ter sido relacionada a maior sobrevivência de camundongos sépticos, o papel do TLR9 atuando diretamente em neutrófilos não foi avaliado. Objetivando preencher esta lacuna, propôs-se avaliar o papel direto de TLR9 na falência de migração de neutrófilos na sepse. Os camundongos TLR9-/- apresentaram maior sobrevivência a sepse polimicrobiana avaliada por meio do modelo de ligadura e perfuração do ceco (CLP). A deficiência de TLR9 também acarretou em aumento na migração de neutrófilos para o foco da infecção, menor seqüestro de neutrófilos no pulmão, bem como, menor número de bactérias no lavado peritoneal e sangue. A ativação de TLR9 por oligodeoxinucleotídeo contendo o dinucleotídeo CpG não metilado (ODN CpG) nos neutrófilos reduziu a quimiotaxia destes em direção a quimiocina CXCL2 e expressão do receptor quimiotático CXCR2. Além disso, neutrófilos estimulados com ODN CpG apresentaram aumento na expressão da quinase tipo 2 relacionada a receptores acoplados a proteína G (GRK2). Dessa forma, a ativação de TLR9 em neutrófilos circulantes no sangue é prejudicial na sepse por reduzir a quimiotaxia destes para o foco da infecção ao induzir a dessensibilização de CXCR2 via GRK2. / The recruitment of neutrophils to the site of infection is a crucial event for combating the microorganisms and survival on sepsis. The neutrophil migration is directed by a chemotactic gradient through the recognition of chemokines by G protein-coupled receptors (GPCRs), which are regulated by specific kinases (GRKs). Previous studies have shown a failure of neutrophil migration into infectious focus on sepsis due to chemotactic receptor desensitization via GRKs induced by activation of toll- like receptors (TLRs), TLR2 and TLR4. Despite the absence of activation of TLR9 in dendritic cells have been related to increase survival of septic mice, the role of TLR9 acting directly on neutrophils was not evaluated. We proposed to verify the direct role of TLR9 in the failure of neutrophil migration on sepsis. The TLR9 knockout mice (TLR9-/-) showed high survival to polymicrobial sepsis using cecal ligation and puncture model (CLP). TLR9-/- mice had high neutrophil migration to the focus of infection, low neutrophil sequestration in the lung, as well as, few bacteria in the peritoneal exudates and blood. The activation of TLR9 by oligodeoxinucleotide containing unmethylated dinucleotide CpG (CpG ODN) in neutrophils also reduced chemotaxis toward CXCL2 and the expression of chemokine receptor CXCR2. In addition, neutrophils stimulated with CpG ODN showed increased expression of kinase-related G protein-coupled receptor type 2 (GRK2). Thus, the activation of TLR9 in blood circulating neutrophils is harmful on sepsis by reducing their chemotaxis into the site of the infection by inducing CXCR2 desensitization via GRK2.

CXCR2

dessensibilização

GRK2

Ligadura e perfuração do ceco (CLP)

migração de neutrófilos

polimorfonucleares

quimiotaxia

receptor toll-like 9.

Cecal ligation and puncture (CLP)

chemotaxis

CXCR2

dessensitization

GRK2

neutrophil migration

polymorphonuclear

toll-like-receptor 9.

Study of the blood-brain interface and glial cells during sepsis-associated encephalopathy : from imaging to histology / Etude de l'interface sang-cerveau et des cellules gliales au cours de l'encéphalopathie associée au sepsis : de l'imagerie à l'histologie

Dhaya, Ibtihel

20 December 2017

L'encéphalopathie associée au sepsis (EAS) est définie comme un dysfonctionnement cérébral diffus induit par une réponse systémique à une infection. Chez les patients septiques, l'imagerie par résonance magnétique (IRM) a indiqué à la fois des anomalies de la substance grise (SG) et blanche (SB) associées à des troubles cognitifs graves, y compris le delirium. Pour améliorer notre compréhension des changements hémodynamiques, métaboliques et structuraux associés au sepsis, différentes séquences d'IRM ont été réalisées chez des rats ayant subi une injection ip de solution saline ou de lipopolysaccharide bactérien (LPS) 2,5h plus tôt ou une ligature et ponction caecale 24h plus tôt. Après ip LPS, l'IRM de contraste de phase a été réalisée pour étudier le flux des artères cérébrales antérieures et moyennes et le marquage des spins artériels (ASL) pour étudier la perfusion des structures cérébrales de la SB et SG. Des séquences d'imagerie par diffusion pondérée (DWI) ont été utilisées pour évaluer les changements structurels. Après la chirurgie CLP, ASL a été utilisé pour étudier les changements de la microcirculation. L'imagerie pondérée en T2, l'imagerie du tenseur de diffusion (DTI) et les statistiques spatiales basées sur les faisceaux (TBSS) ont été réalisées pour caractériser les événements structurels dans différentes structures cérébrales. Après imagerie, les animaux ont été sacrifiés et leur cerveau a été traité pour l'histologie afin de détecter l'enzyme synthétisant les prostaglandines vasoactives cyclooxygénase-2 (COX-2) et le canal hydrique astrocytaire aquaporin-4 (AQP4) dont l'expression peut être régulée à la hausse, évaluer la présence d'immunoglobulines périvasculaires (Ig) indiquant une rupture de la barrière hémato-encéphalique (BHE) et étudier la morphologie des glies puisque la microglie et l’astroglie changent de morphologie lors des conditions inflammatoires. L'IRM n'a indiqué aucun changement hémodynamique dans la substance grise après l'administration de ip LPS, alors qu'une perfusion cérébrale accrue a été montrée au niveau du corps calleux comme indiqué par l'ASL. DTI a indiqué une augmentation de la diffusion des molécules d’eau parallèlement aux fibres du corps calleux. Ces changements étaient accompagnés d'une dégradation de BHE dans la SB ainsi que la substance grise corticale et striatale adjacente tel est indiqué par la présence périvasculaire d'IgG, sans aucun changement majeur de COX-2 vasculaire ou de morphologie des glies du coprs calleux. Le dysfonctionnement du SNC induit par le sepsis a résulté en une augmentation du contraste pondéré en T2 dans le cortex, le striatum et la base du cerveau, une diminution de la perfusion sanguine dans le cortex et une augmentation de la diffusion hydrique du corps calleux et du striatum ventral. Ces changements ont été associés dans la SB à des modifications de la morphologie des glies et dans la substance grise à une expression constitutive de COX-2 et AQP4 plus faible dans le cortex cérébral. La comparaison entre CLP ayant subit ou non une IRM sous anesthésie à l'isoflurane a montré une réponse inflammatoire réduite tel est indiqué par l'expression de COX- 2, une activation réduite des glies ainsi qu’une lésion réduite de la BHE dans le CLP subissant une IRM sous anesthésie. Collectivement, nos résultats suggèrent que des changements hémodynamiques peuvent survenir en l'absence de flux altéré dans les artères irriguant le cerveau antérieur. Ensuite, l'altération de la structure de la SB est une étape précoce de la pathogenèse de l’EAS qui peut résulter soit de la dégradation de la BHE, soit de l'activation des glies. Cette étude sous-tend l'effet délétère d'une seule exposition à l'anesthésie à l'isoflurane qui peut être atténuée par une seconde exposition chez les rats ayant subi une laparotomie ainsi que les effets de l'inflammation systémique induite par le CLP sur les glies pouvant être atténués par imagerie sous anesthésie à l'isoflurane. / Sepsis-associated encephalopathy (SAE) refers to central nervous system dysfunction during the systemic inflammatory response to infection. In septic patients with encephalopathy MRI has indicated both gray and white matter abnormalities that were associated with worse cognitive outcome including delirium. To improve our understanding of sepsis-associated hemodynamic, metabolic, and structural changes, different MRI sequences were performed in rats that either underwent an i.p injection of saline or bacterial lipopolysaccharide (LPS) 2.5h earlier or cecal ligation and puncture (CLP) 24h earlier. After ip LPS, phase contrast MRI was performed to study anterior and middle cerebral arteries flow and Arterial Spin Labeling (ASL) to study perfusion of white and grey matter brain structures. Diffusion Weighted Imaging (DWI) sequences was used to assess structural changes. After CLP surgery, ASL was used to study microcirculation changes. T2-Weighted Imaging, Diffusion Tensor Imaging (DTI) and tract-based spatial statistics (TBSS) were performed to characterize structural events in different brain structures. After imaging, animals were sacrificed and their brains processed for histology to detect the vasoactive prostaglandin-synthesizing enzyme cyclooxygenase-2 (COX-2) and the astrocytic aquaporin-4 water channel (AQP4) the expression of which can be upregulated during inflammation, to assess the presence of perivascular immunoglobulins (Ig) indicating blood-brain barrier (BBB) leakage and to study glia cell morphology as both microglia and astrocytes are known to change their morphology in inflammatory conditions. Magnetic resonance rat brain imaging indicated no hemodynamic changes in the grey matter after ip LPS administration while an increased CBF was shown in corpus callosum white matter as indicated by ASL. DTI indicated increased water diffusion parallel to fibers of the corpus callosum white matter. These changes were accompanied by BBB breakdown in the white matter and adjacent cortical and striatal grey matter as indicated by the perivascular presence of IgG, but no major changes in vascular COX-2 or white matter glia cell morphology. CLP induced sepsis-associated CNS dysfunction resulted in higher T2-weighted contrast intensities in the cortex, striatum and base of the brain, decreased blood perfusion distribution to the cortex and increased water diffusion in the corpus callosum and ventral striatum compared to sham surgery. These changes were associated in the white matter with modifications in glia cells morphology and in the grey matter with lower expression of constitutive COX-2 expression and AQP4 in the cerebral cortex. The comparison between CLP that underwent or not MRI under isoflurane anesthesia indicated reduced inflammatory response as indicated by COX-2 expression, reduced glia activation and reduced BBB damage in CLP that underwent MRI under isoflurane anesthesia. Collectively, our results suggest that hemodynamic changes may occur in the absence of altered flow in forebrain irrigating arteries. Then, altered white matter structure is an early step in SAE pathogenesis that may result either from BBB breakdown or glial cells activation. This study underlies the deleterious effects of a single exposure to isoflurane anesthesia that may be mitigated by a second exposure in sham-operated rats and the effects of CLP-induced systemic inflammation on glial cells that can be attenuated by imaging under isoflurane anesthesia.

Barrière hémato-encéphalique

Diffusion hydrique

Flux sanguin cérébral

Glie

Ligature et ponction de cecum

Marquage des spins artériels

Sepsis

Arterial spin labeling

Blood-brain barrier

Cecal ligation and puncture

Cerebral blood flow

Diffusion magnetic resonance imaging

Glia

Sepsis