@phdthesis{Fazeli2010,
  author    = {Fazeli, Gholamreza},
  title     = {Signaling in the induction of genomic damage by endogenous compounds},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-55634},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2010},
  abstract  = {Reactive oxygen species (ROS) are continuously generated in cells and are involved in physiological processes including signal transduction but also their damaging effects on biological molecules have been well described. A number of reports in the literature implicate excessive oxidative stress and/or inadequate antioxidant defense in the pathogenesis of cancer, atherosclerosis, chronic and age related disorders. Several studies have indicated that activation of the renin-angiotensin-aldosterone-system can lead to the formation of ROS. Epidemiological studies have revealed higher renal cell cancer incidences and also higher cancer mortalities in hypertensive individuals. Recently, our group has shown that perfusion of the isolated mouse kidney with Ang II or treatment of several cell lines with Ang II leads to formation of DNA damage and oxidative base modifications. Here, we tried to scrutinize the pathway involved in genotoxicity of Ang II. We confirmed the genotoxicity of Ang II in two kidney cell lines of human origin. Ang II treatment led to the production of superoxide anions which we could hinder when we used the membrane permeable superoxide dismutase (SOD) mimetic TEMPOL. One of the enzymes which is activated in the cells after Ang II treatment and is able to produce ROS is NADPH oxidase. We demonstrated the activation of NADPH oxidase in response to Ang II by upregulation of its p47 subunit using RT-PCR. Also, pPhosphorylation of p47 subunit of NADPH oxidase after Ang II treatment was enhanced. Using two inhibitors we showed that NADPH oxidase inhibition completely prevents DNA damage by Ang II treatment. To differentiate between Nox2 and Nox4 isoforms of NADPH oxidase subunits in the genotoxicity of Ang II, we performed siRNA inhibition and found a role only for Nox4, while Nox2 was not involved. Next, we investigated PKC as a potential activator of NADPH oxidase. We showed that PKC becomes phosphorylated after Ang II treatment and also that inhibition of PKC hinders Ang II from damaging the cells. Our results from using several inhibitors of different parts of the pathway revealed that PKC activation in this pathway is dependent on the action of PLC on membrane phospholipids and production of IP3. IP3 binds to its receptor at endoplasmic reticulum (ER), opening a channel which allows calcium efflux into the cytoplasm. In this manner, both ER calcium stores and extracellular calcium cooperate so that Ang II can exert its genotoxic effect. PLC is activated by AT1R stimulation. We could also show that the genotoxicity of Ang II is mediated via AT1R signaling using the AT1R antagonist candesartan. In conclusion, here we have shown that Ang II is able to damage genomic damage in cell lines of kidney origin. The observed damage is associated with production of ROS. A decrease in Ang II-induced DNA damage was observed after inhibition of G-proteins, PLC, PKC and NADPH oxidase and interfering with intra- as well as extracellular calcium signaling. This leads to the following preliminary model of signaling in Ang II-induced DNA damage: binding of Ang II to the AT1 receptor activates PLC via stimulation of G-proteins, resulting in the activation of PKC in a calcium dependent manner which in turn, activates NADPH oxidase. NADPH oxidase with involvement of its Nox4 subunit then produces reactive oxygen species which cause DNA damage. Dopamine content and metabolism in the peripheral lymphocytes of PD patients are influenced by L-Dopa administration. The PD patients receiving a high dose of L-Dopa show a significantly higher content of dopamine in their lymphocytes compared to PD patients who received a low dose of L-Dopa or the healthy control. Central to many of the processes involved in oxidative stress and oxidative damage in PD are the actions of monoamine oxidase (MAO), the enzyme which is responsible for the enzymatic oxidation of dopamine which leadsing to production of H2O2 as a by-product. We investigated whether dopamine oxidation can cause genotoxicity in lymphocytes of PD patents who were under high dose L-Dopa therapy and afterward questioned the occurrence of DNA damage after dopamine treatment in vitro and tried to reveal the mechanism by which dopamine exerts its genotoxic effect. The frequency of micronuclei in peripheral blood lymphocytes of the PD patients was not elevated compared to healthy age-matched individuals, although the formation of micronuclei revealed a positive correlation with the daily dose of L-Dopa administration in patients who received L-Dopa therapy together with dopamine receptor agonists. In vitro, we describe an induction of genomic damage detected as micronucleus formation by low micromolar concentrations in cell lines with of different tissue origins. The genotoxic effect of dopamine was reduced by addition of the antioxidants TEMPOL and dimethylthiourea which proved the involvement of ROS production in dopamine-induced DNA damage. To determine whether oxidation of dopamine by MAO is relevant in its genotoxicity, we inhibited MAO with two inhibitors, trans-2-phenylcyclopropylamine hydrochloride (PCPA) and Ro 16-6491 which both reduced the formation of micronuclei in PC-12 cells. We also studied the role of the dopamine transporter (DAT) and dopamine type 2 receptor (D2R) signaling in the genotoxicity of dopamine. Inhibitors of the DAT, GBR-12909 and nomifensine, hindered dopamine-induced genotoxicity. These results were confirmed by treatment of MDCK and MDCK-DAT cells, the latter containing the human DAT gene, with dopamine. Only MDCK-DAT cells showed elevated chromosomal damage and dopamine uptake. Although stimulation of D2R with quinpirole in the absence of dopamine did not induce genotoxicity in PC-12 cells, interference with D2R signaling using D2R antagonist and inhibition of G-proteins, phosphoinositide 3 kinase and extracellular signal-regulated kinases reduced dopamine-induced genotoxicity and affected the ability of DAT to take up dopamine. Furthermore, the D2R antagonist sulpiride inhibited the dopamine-induced migration of DAT from cytosol to cell membrane. Overall, the neurotransmitter dopamine causes DNA damage and oxidative stress in vitro. There are also indications that high dose L-Dopa therapy might lead to oxidative stress. Dopamine exerts its genotoxicity in vitro upon transport into the cells and oxidization oxidation by MAO. Transport of dopamine by DAT has the central role in this process. D2R signaling is involved in the genotoxicity of dopamine by affecting activation and cell surface expression of DAT and hence modulating dopamine uptake. We provided evidences for receptor-mediated genotoxicity of two compounds with different mechanism of actions. The involvement of these receptors in many human complications urges more investigations to reveal whether abnormalities in the endogenous compounds-mediated signaling can play a role in the initiation of new conditions like carcinogenesis.},
  subject      = {Angiotensin II},
  language  = {en}
}