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The aim of the study was to investigate the role of the CX3C chemokine FKN in the role of platelet adhesion. The presence of the FKN receptor CX3CR1 in platelets is demonstrated and G-protein dependent activation of platelets with soluble FKN results in the increased adhesion of platelets to collagen and fibrinogen under flow 228 and adhesion of leucocytes to firmly attached platelets 231. Whether membrane-bound FKN is capable to promote the direct adhesion of platelets in flowing blood analogue to leucocytes was completely unknown. The adhesion mechanisms of FKN in mediating the adhesion of leucocytes under flow are well characterised and represent a novel unique mechanism of leucocyte capture and firm adhesion: FKN is responsible for immediate arrest of flowing CX3CR1 expressing leucocytes without the participation of additional adhesion receptors and ligands. This is in contrast to the classical leucocyte adhesion pathways, which are multistep processes involving leucocyte arrest, rolling and subsequent cell activation prior to firm arrest. In leucocytes, the FKN – CX3CR1 axis is sufficient to allow rapid arrest of leucocytes at low shear flow conditions 67, 101, 115, 122, 261. The set of data from this study demonstrates that immobilised FKN was capable to mediate the adhesion of platelets under low shear conditions, whereas there was no interaction in the absence of shear flow. In the presence of vWf in the adhesion matrix, FKN mediated the potent increased adhesion of platelets. This was in parts due to the activation of flowing platelets via CX3CR1 and the augmented translocation of platelets on FKN via the vWf receptor GPIbα. With respect to platelet activation, the function of endothelial FKN was comparable to leucocytes: in both cell types, the FKN dependent activation is mediated by its cognate receptor CX3CR1. This is in contrast to the adhesive capacity: in leucocytes, FKN dependent adhesion is mediated by CX3CR1, whereas in platelets, the adhesive capacity was mostly mediated by the vWf receptor GPIbα with only minor contribution from CX3CR1. In platelets, activation and adhesion by FKN were mediated by two distinct receptors, whereas in leucocytes, CX3CR1 is solely responsible for FKN dependent activation and adhesion. The presented results point out to a role of platelets in early stage of atherosclerosis. The in vivo expression of both, FKN and vWf is regulated by TNF-α, which is released in early stages of inflammation. The presence of vWf and FKN in the endothelial lining of blood vessels during these conditions is sufficient to initiate the capturing and translocation of platelets on the tunica interna. The rolling of platelets on the endothelium can induce endothelial damage and inflammation of the vessel, which might advance to the generation of clinically significant atherosclerotic plaques and fibrous atheroma.
Aging and age-related diseases are becoming more and more important for our society and our health care system. Alzheimer's disease (AD) is a disorder that destroys some parts of the brain and is characterized by global cognitive decline including a progressive irreversible loss of memory, orientation, and reasoning. “Healthy aging”, therefore, is one of the major aims for modern medicine. Apoptosis, or programmed cell death, plays an important role for example in fetal development, as well as for learning processes. T-lymphocytes usually undergo apoptosis in order to terminate an acute inflammation. The aim of this thesis was to explore the changes in the apoptotic mechanism of peripheral lymphocytes from Alzheimer’s disease (AD) patients in contrast to physiological aging. The experiments were conducted with lymphocytes of healthy volunteers of different ages, AD patients and young and aged mice. Moreover, transgenic mice carrying familiar AD-related mutations were examined. The aging study of peripheral cells of ‘healthy’-aged volunteers revealed an age-related increase of basal apoptosis. In addition, spontaneous apoptosis as well as apoptosis induced by oxidative stress (ROS) or by Fas engagement were enhanced in aging. A closer look at the subcellular basis of the lymphocytes (e.g. B-, NK-, CD4+-, and CD8+-T cells) determined that all lymphocyte subsets were affected by aging. Therefore, it could be concluded that the regulation of apoptosis is generally impaired in lymphocytes of aged persons. The increased susceptibility to oxidative stress supports the ‘Free radical theory of aging’ that claims the radicals to be the cause for the aging-process. In mice an increase of basal, spontaneous and ROS-induced apoptosis was detected in T cells from the spleen, as well. An oral treatment over two weeks with the Ginkgo biloba extract EGb761 showed a clear reduction of ROS-induced apoptosis in the treated group. Interestingly, basal and spontaneous apoptosis, e.g. physiological apoptosis, were not effected by the plant extract. This is an important benefit for therapy since physiological apoptosis has a great relevance in the elimination of cancer-cells for example. In conclusion, the antidementive drug EGb761 reduces specifically ROS-induced apoptosis that a plays an important role in aging as shown in this thesis. Based on the data found in healthy aging, lymphocytes from AD patients were assessed for apoptosis. The cells show enhanced levels of basal, spontaneous, and Fas-induced apoptosis. In subsequent experiments it was demonstrated that mainly the T cells were responsible for the findings. However, the NK-cells provided an important impact as well. In concordance with AD-affected neurons, peripheral lymphocytes of AD patients show clear signs of apoptotic cell death. In addition, basal apoptosis of T cells and the CD4/CD8-ratio showed a correlation with the severity of the dementia. Therefore, it could be speculated that apoptosis is due to activation-induced cell death (AICD) that occurs in acute and chronic activation of adaptive immunity. In AD there is a chronic neuroinflammation in the CNS triggering degeneration of neural tissue. In order to explore this, the experimental model of lymphocyte’s activation was established in healthy aging first. The study included the detection of various events of lymphocyte’s activation on the basis of the T cell subsets (CD4+ and CD8+). The inducibility to mitogenic stimulation clearly decreased in both subsets in aging. In contrast, T lymphocytes from AD patients showed an enhanced activation subsequent to mitogenic stimulation compared with age-matched nondemented persons. Only proliferation of CD8+ T cells was clearly reduced in AD. This data could be clues that an increased generation of memory T cells due to chronic neuroinflammation might be evident in AD. Memory T lymphocytes show increased inducibility upon mitogenic activation. Interestingly, CD8+ memory T cells display decreased prolifertive capacity. Due to activation, cells die by apoptosis later on. It could be concluded that AD patients display an increased amount of memory T cells compared to controls. The data implicate that there could be a cross talk between inflammatory within the brain and inflammatory cells of the periphery. This is an interesting point since the brain used to be assumed as immune-privileged zone. According to the experiment, the information of the diseased brain is transferred to white blood cells. The connection of those two compartments might raise the opportunity to observe and probably to influence easily not-accessible regions like the brain. Transgenic mice carrying mutations in familiar AD-relevant genes (Amyloid-Precursor-Protein, Presenilin-1, respectively) displayed enhanced levels of apoptotic T cells from the spleen, as well. It seems that those mutated proteins influence the regulation of apoptosis. Probably, they are involved in the increased cell death of T- and NK-cells, as well. Animals overexpressing Presenilin-1 showed reduced levels of apoptotic cell death. It was demonstrated with molecuar biology tools that Presenilin-1, processed during apoptosis, has an anti-apoptotic effect.