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Within this thesis, three main approaches for the assessment and investigation of altered hemodynamics like wall shear stress, oscillatory shear index and the arterial pulse wave velocity in atherosclerosis development and progression were conducted:
1. The establishment of a fast method for the simultaneous assessment of 3D WSS and PWV in the complete murine aortic arch via high-resolution 4D-flow MRI
2. The utilization of serial in vivo measurements in atherosclerotic mouse models using high-resolution 4D-flow MRI, which were divided into studies describing altered hemodynamics in late and early atherosclerosis
3. The development of tissue-engineered artery models for the controllable application and variation of hemodynamic and biologic parameters, divided in native artery models and biofabricated artery models, aiming for the investigation of the relationship between atherogenesis and hemodynamics
Chapter 2 describes the establishment of a method for the simultaneous measurement of 3D WSS and PWV in the murine aortic arch at, using ultra high-field MRI at 17.6T [16], based on the previously published method for fast, self-navigated wall shear stress measurements in the murine aortic arch using radial 4D-phase contrast MRI at 17.6 T [4]. This work is based on the collective work of Dr. Patrick Winter, who developed the method and the author of this thesis, Kristina Andelovic, who performed the experiments and statistical analyses. As the method described in this chapter is basis for the following in vivo studies and undividable into the sub-parts of the contributors without losing important information, this chapter was not split into the single parts to provide fundamental information about the measurement and analysis methods and therefore better understandability for the following studies. The main challenge in this chapter was to overcome the issue of the need for a high spatial resolution to determine the velocity gradients at the vascular wall for the WSS quantification and a high temporal resolution for the assessment of the PWV without prolonging the acquisition time due to the need for two separate measurements. Moreover, for a full coverage of the hemodynamics in the murine aortic arch, a 3D measurement is needed, which was achieved by utilization of retrospective navigation and radial trajectories, enabling a highly flexible reconstruction framework to either reconstruct images at lower spatial resolution and higher frame rates for the acquisition of the PWV or higher spatial resolution and lower frame rates for the acquisition of the 3D WSS in a reasonable measurement time of only 35 minutes. This enabled the in vivo assessment of all relevant hemodynamic parameters related to atherosclerosis development and progression in one experimental session. This method was validated in healthy wild type and atherosclerotic Apoe-/- mice, indicating no differences in robustness between pathological and healthy mice.
The heterogeneous distribution of plaque development and arterial stiffening in atherosclerosis [10, 12], however, points out the importance of local PWV measurements. Therefore, future studies should focus on the 3D acquisition of the local PWV in the murine aortic arch based on the presented method, in order to enable spatially resolved correlations of local arterial stiffness with other hemodynamic parameters and plaque composition.
In Chapter 3, the previously established methods were used for the investigation of changing aortic hemodynamics during ageing and atherosclerosis in healthy wild type and atherosclerotic Apoe-/- mice using the previously established methods [4, 16] based on high-resolution 4D-flow MRI. In this work, serial measurements of healthy and atherosclerotic mice were conducted to track all changes in hemodynamics in the complete aortic arch over time. Moreover, spatially resolved 2D projection maps of WSS and OSI of the complete aortic arch were generated. This important feature allowed for the pixel-wise statistical analysis of inter- and intragroup hemodynamic changes over time and most importantly – at a glance. The study revealed converse differences of local hemodynamic profiles in healthy WT and atherosclerotic Apoe−/− mice, with decreasing longWSS and increasing OSI, while showing constant PWV in healthy mice and increasing longWSS and decreasing OSI, while showing increased PWV in diseased mice. Moreover, spatially resolved correlations between WSS, PWV, plaque and vessel wall characteristics were enabled, giving detailed insights into coherences between hemodynamics and plaque composition. Here, the circWSS was identified as a potential marker of plaque size and composition in advanced atherosclerosis. Moreover, correlations with PWV values identified the maximum radStrain could serve as a potential marker for vascular elasticity. This study demonstrated the feasibility and utility of high-resolution 4D flow MRI to spatially resolve, visualize and analyze statistical differences in all relevant hemodynamic parameters over time and between healthy and diseased mice, which could significantly improve our understanding of plaque progression towards vulnerability. In future studies the relation of vascular elasticity and radial strain should be further investigated and validated with local PWV measurements and CFD.
Moreover, the 2D histological datasets were not reflecting the 3D properties and regional characteristics of the atherosclerotic plaques. Therefore, future studies will include 3D plaque volume and composition analysis like morphological measurements with MRI or light-sheet microscopy to further improve the analysis of the relationship between hemodynamics and atherosclerosis.
Chapter 4 aimed at the description and investigation of hemodynamics in early stages of atherosclerosis. Moreover, this study included measurements of hemodynamics at baseline levels in healthy WT and atherosclerotic mouse models. Due to the lack of hemodynamic-related studies in Ldlr-/- mice, which are the most used mouse models in atherosclerosis research together with the Apoe-/- mouse model, this model was included in this study to describe changing hemodynamics in the aortic arch at baseline levels and during early atherosclerosis development and progression for the first time. In this study, distinct differences in aortic geometries of these mouse models at baseline levels were described for the first time, which result in significantly different flow- and WSS profiles in the Ldlr-/- mouse model. Further basal characterization of different parameters revealed only characteristic differences in lipid profiles, proving that the geometry is highly influencing the local WSS in these models. Most interestingly, calculation of the atherogenic index of plasma revealed a significantly higher risk in Ldlr-/- mice with ongoing atherosclerosis development, but significantly greater plaque areas in the aortic arch of Apoe-/- mice. Due to the given basal WSS and OSI profile in these two mouse models – two parameters highly influencing plaque development and progression – there is evidence that the regional plaque development differs between these mouse models during very early atherogenesis.
Therefore, future studies should focus on the spatiotemporal evaluation of plaque development and composition in the three defined aortic regions using morphological measurements with MRI or 3D histological analyses like LSFM. Moreover, this study offers an excellent basis for future studies incorporating CFD simulations, analyzing the different measured parameter combinations (e.g., aortic geometry of the Ldlr-/- mouse with the lipid profile of the Apoe-/- mouse), simulating the resulting plaque development and composition. This could help to understand the complex interplay between altered hemodynamics, serum lipids and atherosclerosis and significantly improve our basic understanding of key factors initiating atherosclerosis development.
Chapter 5 describes the establishment of a tissue-engineered artery model, which is based on native, decellularized porcine carotid artery scaffolds, cultured in a MRI-suitable bioreactor-system [23] for the investigation of hemodynamic-related atherosclerosis development in a controllable manner, using the previously established methods for WSS and PWV assessment [4, 16]. This in vitro artery model aimed for the reduction of animal experiments, while simultaneously offering a simplified, but completely controllable physical and biological environment. For this, a very fast and gentle decellularization protocol was established in a first step, which resulted in porcine carotid artery scaffolds showing complete acellularity while maintaining the extracellular matrix composition, overall ultrastructure and mechanical strength of native arteries. Moreover, a good cellular adhesion and proliferation was achieved, which was evaluated with isolated human blood outgrowth endothelial cells. Most importantly, an MRI-suitable artery chamber was designed for the simultaneous cultivation and assessment of high-resolution 4D hemodynamics in the described artery models. Using high-resolution 4D-flow MRI, the bioreactor system was proven to be suitable to quantify the volume flow, the two components of the WSS and the radStrain as well as the PWV in artery models, with obtained values being comparable to values found in literature for in vivo measurements. Moreover, the identification of first atherosclerotic processes like intimal thickening is achievable by three-dimensional assessment of the vessel wall morphology in the in vitro models. However, one limitation is the lack of a medial smooth muscle cell layer due to the dense ECM. Here, the utilization of the laser-cutting technology for the generation of holes and / or pits on a microscale, eventually enabling seeding of the media with SMCs showed promising results in a first try and should be further investigated in future studies. Therefore, the proposed artery model possesses all relevant components for the extension to an atherosclerosis model which may pave the way towards a significant improvement of our understanding of the key mechanisms in atherogenesis.
Chapter 6 describes the development of an easy-to-prepare, low cost and fully customizable artery model based on biomaterials. Here, thermoresponsive sacrificial scaffolds, processed with the technique of MEW were used for the creation of variable, biomimetic shapes to mimic the geometric properties of the aortic arch, consisting of both, bifurcations and curvatures. After embedding the sacrificial scaffold into a gelatin-hydrogel containing SMCs, it was crosslinked with bacterial transglutaminase before dissolution and flushing of the sacrificial scaffold. The hereby generated channel was subsequently seeded with ECs, resulting in an easy-to-prepare, fast and low-cost artery model. In contrast to the native artery model, this model is therefore more variable in size and shape and offers the possibility to include smooth muscle cells from the beginning. Moreover, a custom-built and highly adaptable perfusion chamber was designed specifically for the scaffold structure, which enabled a one-step creation and simultaneously offering the possibility for dynamic cultivation of the artery models, making it an excellent basis for the development of in vitro disease test systems for e.g., flow-related atherosclerosis research. Due to time constraints, the extension to an atherosclerosis model could not be achieved within the scope of this thesis. Therefore, future studies will focus on the development and validation of an in vitro atherosclerosis model based on the proposed bi- and three-layered artery models.
In conclusion, this thesis paved the way for a fast acquisition and detailed analyses of changing hemodynamics during atherosclerosis development and progression, including spatially resolved analyses of all relevant hemodynamic parameters over time and in between different groups. Moreover, to reduce animal experiments, while gaining control over various parameters influencing atherosclerosis development, promising artery models were established, which have the potential to serve as a new platform for basic atherosclerosis research.
Atherosclerosis is accepted to be a chronic inflammatory disease of the arterial vessel wall. Several cellular subsets of the immune system are involved in its initiation and progression, such as monocytes, macrophages, T and B cells. Recent research has demonstrated that dendritic cells (DCs) contribute to atherosclerosis, too. DCs are defined by their ability to sense and phagocyte antigens, to migrate and to prime other immune cells, such as T cells. Although all DCs share these functional characteristics, they are heterogeneous with respect to phenotype and origin. Several markers have been used to describe DCs in different lymphoid and non-lymphoid organs; however, none of them has proven to be unambiguous. The expression of surface molecules is highly variable depending on the state of activation and the surrounding tissue. Furthermore, DCs in the aorta or the atherosclerotic plaque can be derived from designated precursor cells or from monocytes. In addition, DCs share both their marker expression and their functional characteristics with other myeloid cells like monocytes and macrophages. The repertoire of aortic DCs in healthy and atherosclerotic mice has just recently started to be explored, but yet there is no systemic study available, which describes the aortic DC compartment. Because it is conceivable that distinct aortic DC subsets exert dedicated functions, a detailed description of vascular DCs is required. The first part of this thesis characterizes DC subsets in healthy and atherosclerotic mice. It describes a previously unrecognized DC subset and also sheds light on the origin of vascular DCs. In recent years, microRNAs (miRNAs) have been demonstrated to regulate several cellular functions, such as apoptosis, differentiation, development or proliferation. Although several cell types have been characterized extensively with regard to the miRNAs involved in their regulation, only few studies are available that focus on the role of miRNAs in DCs. Because an improved understanding of the regulation of DC functions would allow for new therapeutic options, research on miRNAs in DCs is required. The second part of this thesis focuses on the role of the miRNA cluster miR- 17~92 in DCs by exploring its functions in healthy and atherosclerotic mice. This thesis clearly demonstrates for the first time an anti-inflammatory and atheroprotective role for the miR17-92 cluster. A model for its mechanism is suggested.
Role of Hypoxia-Inducible Factor (HIF) 1α in Dendritic Cells in Immune Regulation of Atherosclerosis
(2013)
Atherosclerosis is the underlying cause of cardiovascular diseases and a major threat to human health worldwide. It involves not only accumulation of lipids in the vessel wall but a chronic inflammatory response mediated by highly specific cellular and molecular responses. Macrophages and dendritic cells (DCs) play an essential role in taking up modified lipids and presenting them to T and B lymphocytes, which promote the immune response. Enhanced activation, migration and accumulation of inflammatory cells at the local site leads to formation of atherosclerotic plaques.
Atherosclerotic plaques become hypoxic due to reduced oxygen diffusion and high metabolic demand of accumulated cells. The various immune cells experience hypoxic conditions locally and inflammatory stimuli systemically, thus up-regulating Hypoxia-inducible factor 1α. Though the role of HIF1α in macrophages and lymphocytes has been elucidated, its role in DCs still remains controversial, especially with respect to atherosclerosis. In this project work, the role of HIF1α in DCs was investigated by using a cell specific knockout mouse model where HIF1α was deleted in CD11c+ cells.
Aortic root sections from atherosclerotic mice showed presence of hypoxia and up-regulation of HIF1α which co-localized with CD11c+ cells. Atherosclerotic splenic DCs also displayed enhanced expression of HIF1α, proving non-hypoxic stimulation of HIF1α due to systemic inflammation. Conditional knockout (CKO) mice lacking HIF1α in CD11c+ cells, under baseline conditions did not show changes in immune responses suggesting effects of HIF1α only under inflammatory conditions. When these mice were crossed to the Ldlr-/- line and placed on 8 weeks of high fat diet, they developed enhanced plaques with higher T-cell infiltration as compared to the wild-type (WT) controls. The plaques were of a complex phenotype, defined by increased percent of smooth muscle cells (SMCs) and necrotic core area and reduced percent of macrophages and DCs. The mice also displayed enhanced T-cell activation and a Th1 bias in the periphery.
The CKO DCs themselves exhibited increased expression of IL 12 and a higher capacity to proliferate and polarize naive T cells to the Th1 phenotype in vitro. The DCs also showed decreased expression of STAT3, in line with the inhibitory effects of STAT3 on DC activation seen in previous studies. When STAT3 was overexpressed in DCs in vitro, IL 12 was down-regulated, but its expression increased significantly on STAT3 inhibition using a mutant vector. In addition, when STAT3 was overexpressed in DCs in vivo using a Cre regulated lentiviral system, the mice showed decreased plaque formation compared to controls. Interestingly, the effects of STAT3 modulation were similar in WT and CKO mice, intending that STAT3 lies downstream of HIF1α. Finally, using a chromatin immunoprecipitation assay (ChIP), it was confirmed that HIF1α binds to hypoxia responsive elements (HREs) in the Stat3 gene promoter thus regulating its expression. When DCs lack HIF1α, STAT3 expression is not stimulated and hence IL 12 production by DCs is uninhibited. This excessive IL 12 can activate naive T cells and polarize them to the Th1 phenotype, thereby enhancing atherosclerotic plaque progression.
This project thus concludes that HIF1α restrains DC activation via STAT3 generation and prevents excessive production of IL 12 that helps to keep inflammation and atherosclerosis under check.
Cardiovascular diseases represent the leading cause of death worldwide, with myocardial infarction and strokes being the most common complications. In both cases, the appearance of an enlarged artery wall as a consequence of a growing plaque is responsible for the disturbance of the blood flow. The formation of plaques is driven by a chronic inflammatory condition known as atherosclerosis, characterized by an initial step of endothelial cell (EC) dysfunction followed by the recruitment of circulating immune cells into the tunica intima of the vessel. Accumulation of lipids and cells lead to the formation of atheromatous plaques that will define the cardiovascular outcome of an individual.
The role of the immune system in the progression of atherosclerosis has been widely recognized. By far, macrophages constitute the most abundant cell type in lesions and are known to be the major source of the lipid-laden foam cell pool during the course of the disease. However, other immune cells types, including T cells, dendritic cells (DCs) or mast cells, among others, have been described to be present in human and mouse plaques. How these populations can modulate the atherogenic process is dependent on their specialized function.
DCs constitute a unique population with the ability to bridge innate and adaptive immune responses, mainly by their strong capacity to present antigens bound to a major histocompatibility complex (MHC) molecule. Given their ability to polarize T cells and secrete cytokines, their role in atherosclerosis has gained attention for the development of new therapeutic approaches that could impact lesion growth. Hence, knowing the effect of a specific subset is an initial key step to evaluate its potential for clinical purposes. For example, the basic leucine zipper ATF-like 3 transcription factor (Batf3) controls the development of conventional dendritic cells type 1 (cDCs1), characterized by the expression of the surface markers CD8 and CD103. Initially, they were described to promote both T-helper 1 (Th1) and regulatory T cell (Treg) responses, known to accelerate and to protect against atherosclerosis, respectively. The first part of this thesis aimed to elucidate the potential role of Batf3-dependent DCs in atherosclerosis and concluded that even though systemic immune responses were mildly altered they do not modify the course of the disease and may not represent an attractive candidate for clinical studies.
DCs also have the ability to impact lesion growth through the release of a broad range of cytokines, which can either directly impact atherosclerotic plaques by modulating resident cells, or by further polarizing T cell responses. Among others, interleukin (IL) 23, a member of the IL-12 family of cytokines, has received much attention during the past year due to its connection to autoimmunity.
IL-23 is known to induce pathogenicity of Th17 cells and is responsible for the development of several autoimmune diseases including multiple sclerosis, psoriasis or rheumatoid arthritis. Interestingly, these patients often present with an accelerated course of atherosclerosis and thus, are at higher risk of developing cardiovascular events. Several epidemiological studies have pointed toward a possible connection between IL-23 and its receptor IL-23R in atherosclerosis, although their exact contribution remains to be elucidated. The second part of this thesis showed that resident antigen-presenting cells (APCs) in the aorta produced IL-23 during the steady state but this secretion was greatly enhanced after incubation with oxidized low-density lipoprotein (oxLDL). Furthermore, disruption of the IL-23R signaling led to decreased relative necrotic plaque area in lesions of Ldlr-/-Il23r-/- mice fed a high-fat diet (HFD) for 6 and 12 weeks compared to Ldlr-/- controls. A proposed mechanism involves that increased IL-23 production in the context of atherosclerosis may promote the pathogenicity of IL-23-responding T cells, especially IL-23R+ γδ T cells in the aortic root. Response to IL-23 might increase the release of granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-17 and alter the pro- and anti-inflammatory balance of cytokines in the aortic root. Altogether, these data showed that the IL-23 / IL-23R axis play a role in plaque stability.
Allogeneic hematopoietic cell transplantation (Allo-HCT) is the main and only treatment for many malignant and non-malignant haematological disorders. Even though the treatment has improved through the years and patient life expectancy has increased, graft versus host disease (GvHD) is still considered the main obstacle and one of the main reasons for increased mortality. Furthermore, improved patient’s survival and life expectancy brought into question the late post-HCT complications. The leading cause of late death after allo-HCT is the relapse of primary disease as well as chronic GvHD (cGvHD). However, a clear relationship was also described with pulmonary complications, endocrine dysfunction and infertility, and cataracts in post-HCT patients. In the last years big concern regarding a cumulative cardiovascular incidence in long-term survivors has been raised. Severe cardiovascular disease (CVD) is caused by atherosclerosis which is considered a chronic inflammatory disease of blood vessels. As such, it takes a long time from endothelial damage, as the onset event, and followed plaque formation to a manifestation of severe consequences, such as stroke, coronary heart disease, or peripheral arterial disease. Endothelial damage is well documented in patients post-HCT. In the context of allo-HCT, the endothelial damage is induced by the conditioning regimen with or without total body irradiation (TBI). Furthermore, endothelial cells (ECs) have been documented as a target of GvHD and increased concentration of circulating endothelial cells (CEC) coinciding with an increase in the number of circulating alloreactive T cells. According to 2021 ESC Guidelines on CVD prevention, the main atherosclerotic CVD (ASCVD) risk factors are blood apolipoprotein B (ApoB)-containing lipoproteins (of which low-density lipoprotein (LDL) is the most abundant), high blood pressure, cigarette smoking and diabetes mellitus (DM). GvHD is considered a high-risk factor for the onset of dyslipidaemia, hypertension, and DM. Overall, the risk of premature cardiovascular death is 2.7 fold increased in comparison to the general population, while the cumulative incidence of cardiovascular complications was shown to be up to 47% at ten years after reduced intensity conditioning (RIC), post-HCT. However, up to date, there are no available studies elucidating the interconnection between GvHD and atherosclerosis. The goal of this study was, therefore, to investigate the involvement of GvHD in the progression of atherosclerosis as well as to elucidate whether cytotoxic, CD8+ T cells that were shown to play a significant role in endothelial damage during the course of skin GvHD on one hand, and inducers of formation of unstable plaque on the other, are involved in this interconnection. For that purpose we established a novel minor histocompatibility anti gens (miHAg) allo-HCT Western diet (WD)-induced atherosclerosis mouse model. We were able to show that GvHD has a significant impact on atherosclerosis development in B6.Ldlr−/− recipient mice even in the absence of overt clinical disease activity. It seems that the impact is at least partly induced by CD8+ T cells, that showed significantly increased infiltration of aortic lesions in mice facing subclinical GvHD. As studies have shown in regular atherosclerotic mouse models as well as in humans, these CD8+ T cells exhibited not only increased expression of genes involved in activation, survival and differentiation to cytotoxic phenotype, but also some genes pointing out their exhaustion, that were absent in CD4+ T cell cluster. When anti-CD8β antibody was applied once per week along with WD feeding for eight weeks, the plaque formation was significantly reduced in aorta and aortic root pointing out the importance of these cells in an alloreactivity induced lesion formation. Furthermore, anti-CD8β treatment led to significantly decreased necrotic core formation followed by overall increase in plaque stability. Strikingly, bone marrow plus T cells (BMT) recipients fed WD showed significantly increased serum cholesterol levels in comparison to bone marrow (BM) (a group lacking alloreactive T cells that induce GvHD). This effect was reversed when anti-CD8β treatment was applied, suggesting, at least partly, an impact of alloreactive CD8+ T cells on cholesterol levels. Expression of genes responsible for lipid metabolism pointed out the tendency of the liver to regulate the increased cholesterol levels, however, the mechanism behind this phenotype still remains to be revealed. On the other hand, the impact of obesity, induced by chronic high-fat diet (HFD) feeding, has been shown to be an independent risk factor for gastrointestinal GvHD. Similarly, in major histocompatibility complex (MHC) disparate allo-HCT mouse model, we have noticed that even short-term WD intake leads to a significant decrease in survival of mice post-HCT. When the concentration of transplanted alloreactive T cells was reduced, the survival was improved, pointing out the involvement of these cells in the pathogenesis. Additionally, bioluminescence imaging (BLI) during initiation and effector phase of acute GvHD (aGvHD) revealed increased infiltration of alloreactive T cells in mice fed WD. Studies in an obesity model, we could confirm the involvement of specifically CD4+ T cells in WD induced impact, as the relative number of these cells was significantly increased in small intestine on day six post-HCT in mice fed WD. This increased intestinal infiltration was preceded by increase in the number of alloreactive T cells expressing intestine homing receptor (α4β7 integrin) in peripheral lymph nodes (LNs). Even though the number of T cells was not changed in the spleen of WD fed mice, the subset of CD4+ and CD8+ T cells that were highly secreting TNFα was increased as well as the expression of genes regulating pro-inflammatory cytokines such as IL-6 and interferon (IFN)γ pointing out significant WD-induced inflammation. Moreover, slight tendency towards increased intestinal permeability and load of translocated luminal bacteria, that we observed, could induce severe endotoxemia and dysregulated systemic immune response that could lead to detrimental induction of cell death. Justifying our speculations, we noted increased levels of transaminases and an increase in lactate dehydrogenase (LDH) levels (pointing out significant tissue damages). However, the exact mechanism behind this detrimental WD impact still remains to be elucidated.
Atherosclerosis is considered a chronic inflammatory disease of the arterial vessel wall which is not only modulated by innate and adaptive immune responses but also by factors of the blood coagulation system.
In general hypercoagulability seems to increase the development and progression of experimental atherosclerosis in mice on an atherogenic background. In addition, the great majority of coagulation proteins including coagulation factor XII (FXII) have been detected in early and advanced human atherosclerotic lesions supporting the cross-link between the coagulation system and atherosclerosis. Moreover, FXII has been detected in close proximity to macrophages, foam cells and smooth muscle cells in these lesions and has been demonstrated to be functionally active in human plaques. Although these data indicate that factor XII may play a role in atherogenesis a direct contribution of FXII to atherogenesis has not been addressed experimentally to date. Furthermore, clinical studies examining the function of FXII in vascular disease have yielded conflicting results.
Hence, in order to investigate the function of coagulation factor XII in atherosclerosis apolipoprotein E and FXII-deficient (F12\(^{-/-}\) apoE\(^{-/-}\)) mice were employed. Compared to F12\(^{+/+}\)apoE\(^{-/-}\) controls, atherosclerotic lesion formation was reduced in F12\(^{-/-}\)apoE\(^{-/-}\) mice, associated with diminished systemic T-cell activation and Th1-cell polarization after 12 weeks of high fat diet. Moreover, a significant decrease in plasma levels of complement factor C5a was evidenced in F12\(^{-/-}\)apoE\(^{-/-}\) mice. Interestingly, C5a increased the production of interleukin-12 (IL-12) in dendritic cells (DCs) and enhanced their capacity to trigger antigen-specific interferon-gamma (IFNγ) production in OTII CD4\(^+\) T cells in vitro. Importantly, a reduction in frequencies of IL-12 expressing splenic DCs from atherosclerotic F12\(^{-/-}\)apoE\(^{-/-}\) versus F12\(^{+/+}\)apoE\(^{-/-}\) mice was observed in vivo, accompanied by a diminished splenic Il12 transcript expression and significantly reduced IL-12 serum levels.
Consequently, these data reveal FXII to play an important role in atherosclerotic lesion formation and to promote DC-induced and systemic IL 12 expression as well as pro-inflammatory T-cell responses likely at least in part via the activation of the complement system.
Motivation and Aim:
Cardiovascular disease has been the leading cause of mortality and morbidity throughout the world. In developed countries, cardiovascular diseases are already responsible for a majority of deaths and will become the pre-eminent health problem worldwide (1,2). Rupture of atherosclerotic plaque accounts for approximately 70% of fatal acute myocardial infarction and sudden heart deaths. Conventional criterias for the diagnosis of “vulnerable plaques” are calcified nodules, yellow appearance of plaque, a thin cap, a large lipid core, severe luminal stenosis, intraplaque hemorrhage, inflammation, thrombogenicity, and plaque injury (3-5).
Noninvasive diagnosis of vulnerable plaque still remains a great challenge and a huge research prospect, which triggered us to investigate the feasibility of PET imaging on the evaluation of atherosclerosis. Nuclear imaging of atherosclerosis, especially co-registered imaging modalities, could provide a promising diagnostic tool including both anatomy and activities to identify vulnerable atherosclerotic plaque or early detection of inflammatory endothelium at risk. Furthermore, the development of specific imaging tracers for clinical applications is also a challenging task. The aim of this work was to assess the potential of novel PET imaging probes associated with intra-plaque inflammation on animal models and in human respectively.
Methods
In this work, several molecular imaging modalities were employed for evaluation of atherosclerosis. They included Positron emission tomography / Computed tomography (PET/CT) for human studies, and micro-PET, autoradiography and high-resolution magnetic resonance imaging (MRI) for animal studies. Radiotracers for PET imaging included the glucose analogue 18F-Fluorodeoxyglucose (18F-FDG), the somatostatin receptor avide tracer 68Ga-DOTATATE, and the Gallium-68 labeled fucoidan (68Ga-Fucoidan), which was developed as a PET tracer to detect endothelial P-selectin, which overexpressed at early stage of atherosclerosis and endothelial overlying activated plaque. Tracer’s capabilities were firstly assessed on cellular level in vitro. Subsequently, Animal studies were conducted in two animal models: 1, Apolipoprotein E (ApoE-/-) mice having severe atherosclerotic plaque; 2, Lipopolysaccharide (LPS) -induced mice for receiving acute vascular inflammation. Corresponding analyses on protein and histological level were conducted as well to confirm our results.
In human study, 16 patients with neuroendocrine tumors (NETs) were investigated on imaging vascular inflammation. These patients had undergone both 68Ga-DOTATATE PET/CT and 18F-FDG PET/CT for staging or restaging within 6 weeks. 16 patients were randomized into two groups: high-risk group and low-risk group. Uptake ratio of both tracers from two groups were compared and correlated with common cardiovascular risk factors.
Results and Conclusion
In murine study, the expression of somatostatin receptor 2, which is the main bio-target of 68Ga-DOTATATE on macrophage/monocyte was confirmed by flow cytometry and immunohistochemistry. Prospectively, high specific accumulation of 68Ga-DOTATATE to the macrophage within the plaques was observed in aorta lesions by autoradiography and by micro-PET. In study with 68Ga-fucoidan, a strong expression of P-selectin on active endothelium overlying on inflamed plaque but weaker on inactive plaques was confirmed. Specific focal uptake of 68Ga-fucoidan were detected at aorta segments by micro-PET, and correlated with high-resolution magnetic resonance imaging (MRI), which was used to characterize the morphology of plaques. 68Ga-fucoidan also showed a greater affinity to active inflamed plaque in comparison of inactive fibrous plaque, which was assessed by autoradiography. Specificity of 68Ga-DOTATATE and 68Ga-fucoidan were confirmed by ex-vivo blocking autoradiography and in vivo blocking PET imaging respectively.
In human study, focal uptake of both 18F-FDG and 68Ga-DOTATATE was detected. Analyzing concordance of two tracers’ uptake ratio, Out of the 37 sites with highest focal 68Ga-DOTATATE uptake, 16 (43.2%) also had focal 18F-FDG uptake. Of 39 sites with highest 18F-FDG uptake, only 11 (28.2%) had a colocalized 68Ga-DOTATATE accumulation. Correlated tracers’ uptake and calcium burden and risk factors, Mean target-to-background ratio (TBR) of 68Ga-DOTATATE correlated significantly with the presence of calcified plaques (r=0.52), hypertension (r=0.60), age (r=0.56) and uptake of 18F-FDG (r=0.64). TBRmean of 18F-FDG correlated significantly only with hypertension (r=0.58; p<0.05). Additionally, TBRmean of 68Ga-DOTATATE is significant higher in the high risk group while TBRmean of 18F-FDG is not.
In conclusion, we evaluated vascular inflammation of atherosclerosis non-invasively using the two PET tracers: 68Ga-DOTATATE and 68Ga-Fucoidan. 68Ga-DOTATATE show specific affinity to infiltrated macrophage within the plaques. 68Ga-Fucoidan may hold the potential to discriminate between active and inactive atherosclerotic plaques in terms of variant accumulation on different-types of plaques. PET as leading molecular imaging technique provides superiority in assessing cellular activity, which is pivotal for understanding internal activity of atherosclerotic plaques. Since diagnosis of atherosclerosis is a complex and multi-dimensional task. More integrated imaging technology such as PET/MRI, faster imaging algorithm, more efficient radiotracer are required for further development of atherosclerosis imaging,
Atherosclerosis is an active and progressive condition where the vascular cell adhesion molecules as VCAM-1 play a vital role controlling the recruitment of immune cells within the early and advanced plaques. Therefore targeting of VCAM-1 molecules with specific contrast agent bears the possibility to monitor the VCAM-1 expression, visualize the plaque progression starting at the early alterations, and help to establish early prevention of atherosclerosis before the origin of the thrombus formation, of which late recognition leads to myocardial infarction. Furthermore noninvasive magnetic resonance imaging (MRI) offers the benefit of combining the molecular and anatomic data and would thus enable specific detection of VCAM-1 targeted iron oxide contrast agent within inflammatory process of atherosclerosis. This thesis exactly presents the VCAM-1 concept as a suitable molecular approach and the potential of specific ultrasmall superparamagnetic iron oxide (USPIO) conjugated to the VCAM-1 binding peptide over unspecific non-targeted USPIO particles for evaluation of atherosclerosis. This work firstly demonstrated that selection of VCAM-1 molecules offers a good and potential strategy for imaging of atherosclerosis, as these vascular cell adhesion molecules are highly expressed in the early phase of inflammation and also continuously up-regulated within the advanced plaques. Secondly, this thesis showed the proof of principle and capability of the newly designed USPIO contrast agent conjugated to the specific cyclic peptide for VCAM-1 recognition. The experimental studies including ultra-high field MRI enabled further ex vivo and in vivo detection of applied USPIO-VCAM-1 particles within the aortic root region of early and advanced atherosclerotic plaques of 12 and 30 week old apolipoprotein E deficient (ApoE-/-) mice. Using a combination of histology and electron microscopy, this study for the first time pointed to distribution of targeted USPIO-VCAM-1 particles within plaque cells expressing VCAM-1 not only in luminal regions but also in deeper medial smooth muscle cell areas. Hence functionalized USPIO particles targeting VCAM-1 molecules allow specific and sensitive detection of early and advanced plaques at the molecular level, giving the new possibilities for early recognition of atherosclerotic plaques before the appearance of advanced and prone to rupture lesions. In contrast to the functionalized USPIO-VCAM-1, utilized non-targeted USPIO particles did not succeed in early plaque 6 identification limiting visualization of atherosclerosis to advanced forms in atherosclerotic ApoE-/- mice.
Background Transgenic mouse models are increasingly used to study the pathophysiology of human cardiovascular diseases. The aortic pulse wave velocity (PWV) is an indirect measure for vascular stiffness and a marker for cardiovascular risk. Results This work presents three MR-methods that allow the determination of the PWV in the descending murine aorta by analyzing blood flow waveforms, arterial distension waveforms, and a method that uses the combination of flow and distension waveforms. Systolic flow pulses were recorded with a temporal resolution of 1 ms applying phase velocity encoding. In a first step, the MR methods were validated by pressure waveform measurements on pulsatile elastic vessel phantoms. In a second step, the MR methods were applied to measure PWVs in a group of five eight-month-old apolipoprotein E deficient (ApoE(-/-)) mice and an age matched group of four C57Bl/6J mice. The ApoE(-/-) group had a higher mean PWV than the C57Bl/6J group. Depending on the measurement technique, the differences were or were not statistically significant. Conclusions The findings of this study demonstrate that high field MRI is applicable to non-invasively determine and distinguish PWVs in the arterial system of healthy and diseased groups of mice.
Influence of interleukin-6-type cytokine oncostatin M on murine aortic vascular smooth muscle cells
(2018)
Oncostatin M (OSM) is a cytokine of the interleukin-6 family and released in the early
phase of inflammation by neutrophils, activated macrophages, dendritic cells, and T
lymphocytes. Its roles in physiology and disease are not entirely understood yet. It
has been shown recently that substantial amounts of OSM are found in atherosclerotic
plaques.
The first part of this thesis addresses the effects of OSM on vascular smooth muscle
cells (VSMCs). This cell type is known to contribute to atherogenesis and expresses
the type I and type II OSM receptor complexes. This study revealed that OSM is a
strong inducer of an array of genes which have recently been shown to play important
roles in atherosclerosis. Investigation of VSMCs isolated from OSMRbeta-deficient
(Osmr-/-) mice proved that the regulation of these target genes is entirely dependent
on the activation of the type II OSMR complex. In addition to OSM, other cytokines
expressed by T lymphocytes were found to contribute to plaque development. According
to earlier publications, the influence of IL-4, IL-13, and IL-17 on the progression of
plaques were discussed controversially. Nevertheless, for the regulation of investigated
atherosclerotic target genes and receptor complexes in VSMCs, they seemed to play a
minor role compared to OSM. Only the expression of the decoy receptor IL-13Ralpha2 - a
negative feedback mechanism for IL-13-mediated signalling - was strongly induced after
treatment with all mentioned cytokines, especially when VSMCs were primed with OSM
before stimulation.
The second part of this thesis focuses on the role of OSM during the progression of
atherosclerosis in vivo. Therefore, Ldlr-/-Osmr-/- mice were generated by crossing Ldlr-/-
mice - a typical mouse model for atherosclerosis - with Osmr-/- mice. These double-deficient
mice together with Ldlr-/-Osmr+/+ mice were set on cholesterol rich diet (Western
diet, WD) for 12 weeks before they were sacrificed. Determination of body and
organ weight, staining of aortas and aortic roots as well as gene expression profiling
strongly suggested that Ldlr-/-Osmr-/- mice are less susceptible for plaque development
and weight gain compared to Ldlr-/-Osmr+/+ mice. However, further experiments and
additional controls (C57Bl/6 and Osmr-/- mice) on WD are necessary to clarify the
underlying molecular mechanisms.
Taken together, the interleukin-6-type cytokine OSM is a strong inducer of an array of
target genes involved in de-differentiation and proliferation of VSMCs, a process known
to contribute substantially to atherogenesis. Further in vivo studies will help to clarify
the role of OSM in atherosclerosis.