Refine
Has Fulltext
- yes (50) (remove)
Is part of the Bibliography
- yes (50)
Year of publication
Document Type
- Doctoral Thesis (50) (remove)
Language
- English (50) (remove)
Keywords
- DNS-Schädigung (5)
- G-Protein gekoppelte Rezeptoren (5)
- DNA damage (4)
- Fluoreszenz-Resonanz-Energie-Transfer (4)
- GPCR (4)
- Oxidativer Stress (4)
- Biotransformation (3)
- DNA-Schaden (3)
- FRET (3)
- Pneumolysin (3)
Institute
- Institut für Pharmakologie und Toxikologie (50) (remove)
Sonstige beteiligte Institutionen
In patients suffering from end-stage renal disease who are treated by hemodialysis genomic damage as well as cancer incidence is elevated. One possible cause for the increased genomic damage could be the accumulation of genotoxic substances in the blood of patients. Two possible sources for those toxins have to be considered. The first possibility is that substances from dialysers, the blood tubing system or even contaminated dialysis solutions may leach into the blood of the patients during dialysis. Secondly, the loss of renal filtration leads to an accumulation of substances which are normally excreted by the kidney. If those substances possess toxic potential, they are called uremic toxins. Several of these uremic toxins are potentially genotoxic. Within this thesis several exemplary uremic toxins have been tested for genotoxic effects (homocysteine, homocysteine-thiolactone,leptine, advanced glycated end-products). Additionally, it was analysed whether substances are leaching from dialysers or blood tubing and whether they cause effects in in vitrotoxicity testing. The focus of chemical analytisis was on bisphenol A (BPA), the main component of plastics used in dialysers and dialyser membranes.
Azoles are important chemicals used as antifungal agents in agriculture and human medicine, but also as cytostatic drugs in tumour chemotherapy. Antifungal activities are based on inhibition of lanosterol-14α-demethylase (CYP51). CYP51 catalyses the oxidative removal of the methyl group # 32 of lanosterol to produce follicular fluid meiosis activating steroid (FF-MAS). For fungi the later resulting ergosterol is an essential compound of the cell membrane. Exposed fungi lack ergosterol, which leads to a collapse of the cell membrane. In mammals cholesterol, the downstream product of lanosterol-14α-demethylation necessary for the synthesis of bile acids, mineral corticoids, glucocorticoids and sex steroids, can be supplemented with food intake. However FF-MAS and the resulting T-MAS (testis meiosis activating steroids), the direct products of the CYP51 reaction, act as meiosis-activating steroids on ovaries and testes and are not supplemented with food intake. Inhibition of CYP51 in humans may therefore affect the endocrine system and is an unwanted side effect of azoles. Aromatase (CYP19) catalyses the demethylation of testosterone to estradiol and is inhibited by azoles. Reduction of estrogen levels by CYP19 inhibition is the working principle of cytostatic drugs used in breast cancer therapy but is considered an unwanted side effect for azoles used to treat fungal infections. A favourable fungicide or antifungal drug should be a strong inhibitor of fungal CYP51. In contrast human CYP51 and human CYP19 should not be inhibited by an azole fungicide or antifungal agent. The favourable cytostatic drug should show a high potency towards human CYP19. Neither human CYP51 nor fungal CYP51 should be inhibited by a cytostatic drug. The aim of this work was to assess: are fungicides and antifungal drugs strong inhibitors of fungal CYP51? In return do they not inhibit human CYP51 and human CYP19? Do cytostatic drugs strongly inhibit human CYP19? And in return do they not inhibit human CYP51 or fungal CYP51? Inhibitory potencies of 22 azole compounds used for the three purposes were tested in four inhibition assays: i) on commercially available human CYP19 utilising a fluorescent pseudo substrate dibenzylfluorescein (DBF) ii) on CYP19 utilising testosterone as substrate iii) on human CYP51 and iv) Candida albicans CYP51 utilising lanosterol as substrate. Product formation was measured by liquid chromatography – tandem mass spectrometry utilising photospray ionisation (APPI). A functional human CYP51 was available from BD Gentest Cooperation. A functional enzyme complex comprising of the Candida albicans lanosterol-14α-demethylase and the Candida tropicalis oxidoreductase was expressed in the baculovirus system. When comparing inhibitory potencies on CYP19, human CYP51 and Candida albicans CYP51 a number of agents show desirable patterns of inhibition e.g. the two cytostatic drugs, or two antifungal agents used in human medicine, fluconazole and itraconazole, and a wide variety of the fungicides, e.g. cyproconazole and hexaconazole. Undesirable patterns of inhibition were exhibited by a number of compounds, e.g. prochloraz, bifonazole, ketoconazole and miconazole. Seven compounds show a more complex picture of inhibitory potencies though. To get a picture of residue levels of azoles in food in a model case an LC-ESI-MS/MS method was developed for the determination of azole compounds in wine. All residues were below the maximum residue levels set by authorities. To classify the inhibitory potencies on the different enzyme systems IC50 values obtained were compared to exposure levels measured in farmers, maximum plasma concentrations in humans reported after exposure to antifungal drugs and to acceptable daily intake levels set by authorities. Based on the findings presented, the following conclusions can be drawn. The risk for agricultural workers set by exposure to azole fungicides with respect to human CYP51 and CYP19 can be regarded as negligible when safety measures are adhered to. As a matter of principle however, the usage of bifonazole, miconazole and ketoconazole has to be viewed with caution in respect to the high level of inhibition of human CYP51 and/or CYP19. Under the assumption that the acceptable daily intake amounts set by authorities for azole compounds are not exceeded the residues do not pose a threat to consumer safety judged by our findings. Inhibition of CYP19 with the consequence of a reduction of estradiol levels has to be regarded as a possible disrupting effect of the hormone balance. The relevance of FF-MAS and T-MAS in the endocrine system however still has to be evaluated completely bringing with it the question of how much importance has to be attached to the inhibition of human CYP51.
The biotransformation of 1,1,1,3,3-pentafluoropropane was investigated in rats and in in vitro systems. First, the metabolites were identified in vivo using GC/MS and 19F NMR analysis. The main metabolite was identified as trifluoroacetic acid, the minor metabolite as 3,3,3-trifluoropropionic acid and as a cleavage product, inorganic fluoride was found. As the in vitro system, liver microsomes from rat and human samples and rat liver homogenates were used. Trifluoroacetic acid and 3,3,3 trifluoropropionic acid were confirmed in vitro as metabolic intermediates, following biotransformation of 1,1,1,3,3-pentafluoropropane by the cytochrome P-450-system. Studies, designed for clarifying the cardiotoxicity of 1,1,1,3,3-pentafluoropropane were driven by the hypothesis that 3,3,3-trifluoropropionic acid is the toxic agent. This was based on the lethal toxicity, which was observed in previous in vivo experiments. In addition, the point of its structural similarity to toxic agents as for example monofluoroacetic acid or of possible metabolic intermediates like difluoroacrylic acid with known toxicity were considered to support this assumption. However, trifluoroacetic acid was neglected as the sought-after toxic agent because of its different toxic effects, known from literature. Investigations on the biotransformation of 3,3,3-trifluoropropionic acid were performed and resulted in no metabolic activity and in poor elimination of 3,3,3-trifluoropropionic acid in vivo. The histopathological effects on the heart, which were observed in the 90-day oral toxicity study of 1,1,1,3,3-pentafluoropropane in rats, namely mononuclear inflammatory cell infiltrations and degenerated myocardial fibers, were not observed after a 28 day repeated exposure of up to 10 mg/kg b.w. of 3,3,3-trifluoropropionic acid. However, a single high dose of 3,3,3-trifluoropropionic acid lead to severe toxicological effects. The difference in the observed toxic effects after a single and repeated administration may be due to adaptive mechanisms in rats. The toxicological effects included clinical signs like ataxia, coma and cramps. The conditions of the rats suggested possible inhibition of the energy supply to the organism. Furthermore, the interference of 3,3,3-trifluoropropionic acid in the functionality of the organism was investigated. Experiments were performed in vitro in rat liver and heart mitochondria to investigate effects on the mitochondrial ß-oxidation. However, the transformation of the substrate [U14C] palmitic acid in the ß oxidation pathway was not inhibited by 3,3,3-trifluoropropionic acid. In addition, no cytotoxicity of 3,3,3 trifluoropropionic acid was observed in the cell culture systems. The main effect after a single dose of 3,3,3-trifluoropropionic acid was seen in clinical pathology and metabonomic analysis. The decrease in blood glucose is considered to have the most far-reaching consequences for the toxicity of 3,3,3-trifluoropropionic acid. If considering this change as the primary effect after a single dose, secondary effects, for example, the above-mentioned clinical signs could be explained. In addition, the observed high level of ketone bodies might have been responsible for life-threatening possible ketoacidosis. In general, ketoacidosis occurs after an imbalance between glycolysis, lipolysis, TCA cycle activity and respiratory function. Based on the results, ß-oxidation of fatty acids was not affected, and due to the decrease in glucose levels and the high levels of acetyl CoA, glycolysis was considered not to be impaired. Increased amounts of acetyl CoA might be a result of insufficient activity of the TCA cycle. However, the inhibition of the TCA cycle can be based on the impairment of specific enzymes and/or on the involvement of messenger substrates like insulin. Supporting the first mentioned aspect are decreased levels of TCA cycle intermediates, like α-ketoglutarate or citrate, as seen in 1H-NMR spectra of urine. However, the second aspect would explain the drop in blood glucose with the impairment of glucose transporters or the impairment of the insulin balance. If a single dose of 3,3,3-trifluoropropionic acid had stimulated the insulin release, glycolysis would be activated, and high amounts of acetyl CoA would be produced. In case of impaired use by the TCA cycle, levels of ketone bodies would be increased. Experiments were designed to characterize the direct effect of 3,3,3-trifluoropropionic acid on rat insulinoma-derived INS-1 cells as possible increase in insulin release. Further investigations are necessary to answer in which step of the metabolic pathway 3,3,3-trifluoropropionic acid interferes or finally which specific enzyme is inhibited or activated by 3,3,3-trifluoropropionic acid, leading to the drop in blood glucose and finally in lethal toxicity.
Anxiety and depressive disorders result from a complex interplay of genetic and environmental factors and are common mutual comorbidities. On the level of cellular signaling, regulator of G protein signaling 2 (Rgs2) has been implicated in human and rodent anxiety as well as rodent depression. Rgs2 negatively regulates G protein-coupled receptor (GPCR) signaling by acting as a GTPase accelerating protein towards the Gα subunit.
The present study investigates, whether mice with a homozygous Rgs2 deletion (Rgs2-/-) show behavioral alterations as well as an increased susceptibility to stressful life events related to human anxiety and depressive disorders and tries to elucidate molecular underlying’s of these changes.
To this end, Rgs2-/- mice were characterized in an aversive-associative learning paradigm to evaluate learned fear as a model for the etiology of human anxiety disorders. Spatial learning and reward motivated spatial learning were evaluated to control for learning in non-aversive paradigms. Rgs2 deletion enhanced learning in all three paradigms, rendering increased learning upon deletion of Rgs2 not specific for aversive learning. These data support reports indicating increased long-term potentiation in Rgs2-/- mice and may predict treatment response to conditioning based behavior therapy in patients with polymorphisms associated with reduced RGS2 expression. Previous reports of increased innate anxiety were corroborated in three tests based on the approach-avoidance conflict. Interestingly, Rgs2-/- mice showed novelty-induced hypo-locomotion suggesting neophobia, which may translate to the clinical picture of agoraphobia in humans and reduced RGS2 expression in humans was associated with a higher incidence of panic disorder with agoraphobia. Depression-like behavior was more distinctive in female Rgs2-/- mice. Stress resilience, tested in an acute and a chronic stress paradigm, was also more distinctive in female Rgs2-/- mice, suggesting Rgs2 to contribute to sex specific effects of anxiety disorders and depression.
Rgs2 deletion was associated with GPCR expression changes of the adrenergic, serotonergic, dopaminergic and neuropeptide Y systems in the brain and heart as well as reduced monoaminergic neurotransmitter levels. Furthermore, the expression of two stress-related microRNAs was increased upon Rgs2 deletion. The aversive-associative learning paradigm induced a dynamic Rgs2 expression change. The observed molecular changes may contribute to the anxious and depressed phenotype as well as promote altered stress reactivity, while reflecting an alter basal stress level and a disrupted sympathetic tone. Dynamic Rgs2 expression may mediate changes in GPCR signaling duration during memory formation.
Taken together, Rgs2 deletion promotes increased anxiety-like and depression-like behavior, altered stress reactivity as well as increased cognitive function.
Introduction: Colon cancer is one of the major human malignancies worldwide, and much effort has been applied to understand the process of colon carcinogenesis, as well as the role of potential treatments and co-therapeutical agents against it. A growing body of evidence suggests that the use of fluoxetine (FLX), an antidepressant belonging to the selective serotonin reuptake inhibitors (SSRIs), may be associated with a reduced colon cancer risk. However, controversial opinions have been published and an identification of the mechanisms of the activity of FLX on colon cells would help in the clarification of this controversy. Objectives: Using several in vitro and in vivo-based methods and analyses, we aimed to verify whether FLX has antioxidant, pro-oxidant or DNA-damaging potential in standard toxicological assays; to check whether and how FLX could prevent and reduce colon preneoplastic lesions; to ascertain whether FLX has any oncostatic potential against colon tumors; and, to investigate whether FLX activity could be comparable with a known and current applied chemotherapeutic agent against colon cancer. Results: FLX did not have any antioxidant potential in our experiments. Although it did not induce reactive oxygen species (ROS) generation or DNA-damage in fibroblast and colon tumor cell lines, FLX reduced dysplasia and proliferation in two different carcinogen models. Further, a significant decrease in colon stromal reactivity and angiogenesis was found in both carcinogen-induced preneoplasia models. In a xenograft model of colon cancer, FLX shrank tumors, reduced tumor proliferation, arrested cancer cells at the G0/G1 cell-cycle phase, and took ROS generation under control. Such effects were detected together with an intracellular acidification and loss of mitochondrial membrane potential in FLX-treated cells. Modulating mitochondrial respiratory chain, HIF-1 expression and Akt/mTOR signaling pathway, FLX was found to reduce colon tumors similar to the widely used chemotherapeutic agent 5-Fluoracil activity. Conclusion: Our collective data suggest that FLX is a remarkable chemopreventive and oncostatic agent against colon preneoplastic lesions and tumors, acting without DNA-damage or ROS generation.
G protein coupled receptor kinases (GRK) phosphorylate and thereby desensitize G protein coupled receptors (GPCR) including β-adrenergic receptors (βAR), which are critical regulators of cardiac function. We identified the Raf kinase inhibitor protein (RKIP) as an endogenous inhibitor of GRK2 that leads to increased cardiac contractility via βAR activation. RKIP binds to the N-terminus (aa1-185) of GRK2, which is important for the GRK2/receptor interaction. Thereby it interferes with the GRK2/receptor interaction without interference with cytosolic GRK2 target activation. In this project, the RKIP/GRK interface was investigated to develop strategies that simulate the effects of RKIP on βAR.
RKIP binding to different isoforms of GRK expressed in the heart was analyzed by protein interaction assays using full-length and N-termini of GRK2, GRK3 and GRK5: 1-53, 54-185 and 1-185. Co-immunoprecipitation (Co-IPs) and pull-down assays revealed that RKIP binds to the peptides of GRK2 and GRK3 but not to the ones of GRK5, which suggests the existence of several binding sites of RKIP within the N-termini of GRK2 and GRK3. To analyze whether the peptides of GRK2 and GRK3 are able to simulate the RKIP mediated interference of the GRK2/receptor interaction, we analyzed the β2-AR phosphorylation in the absence and presence of the peptides. Interestingly, N-termini (aa1-185) of GRK2 and GRK3 reduced β2AR phosphorylation to a comparable extent as RKIP. In line with reduced receptor phosphorylation, the peptides also reduced isoproterenol-stimulated receptor internalization as shown by [3H] CGP-12177 radioligand binding assay and fluorescence microscopy compared to control cells. Subsequently, these peptides increased downstream signaling of β2AR, i.e. the phosphorylation of the PKA substrate phosducin. In an attempt to elucidate the mechanism behind the observed effects, Co-IPs were performed in order to investigate whether the peptides bind directly to the β2-AR and block its phosphorylation by GRK2. Indeed, GRK2 1-185 and GRK3 1-185 could bind the receptor, suggesting that this way GRK2 is prevented from inhibiting the receptor. To investigate the physiological effect of GRK2 1-185, GRK3 1-185 and GRK5 1-185, their effect on neonatal mouse cardiomyocyte contractility and hypertrophy was analyzed. After long-term isoproterenol stimulation, in the presence of GRK2 1 185 and GRK3 1-185 the cross-sectional area of the cardiomyocytes showed no significant increase in comparison to the unstimulated control cells. In addition, upon isoproterenol stimulation, GRK2 1-185 and GRK3 1-185 increased the beat rate in cardiomyocytes, mimicking RKIP while the base impedance, an indicator of viability, remained stable.
The N-termini (1-185) of GRK2 and GRK3 simulated RKIP’s function and had a significant influence on β2AR phosphorylation, on its downstream signaling and internalization, could bind β2-AR, increased beat rate and did not significantly induce hypertrophy, suggesting that they may serve as a model for the generation of new and more specific targeting strategies for GRK mediated receptor regulation.
ERK1/2 are known key players in the pathophysiology of heart failure, but the members of the ERK cascade, in particular Raf1, can also protect the heart from cell death and ischemic injury. An additional autophosphorylation (ERK1 at Thr208, ERK2 at Thr188) empowers ERK1/2 translocation to the nucleus and phosphorylation of nuclear targets which take part in the development of cardiac hypertrophy. Thereby, targeting this additional phosphorylation is a promising pharmacological approach.
In this thesis, an in silico model of ERK cascade in the cardiomyocyte is introduced. The model is a semi-quantitive model and its behavior was tested with different softwares (SQUAD and CellNetAnalyzer). Different phosphorylation states of ERK1/2 as well as different stimuli can be reproduced. The different types of stimuli include hypertrophic as well as non-hypertrophic stimuli. With the introduced in-silico model time courses and synergistic as well as antagonistic receptor stimuli combinations can be predicted. The simulated time courses were experimentally validated. SQUAD was mainly used to make predictions about time courses and thresholds, whereas CNA was used to analyze steady states and feedback loops.
Furthermore, new targets of ERK1/2 which partially contribute, also in the formation of cardiac hypertrophy, were identified and the most promising of them were illuminated. Important further targets are Caspase 8, GAB2, Mxi-2, SMAD2, FHL2 and SPIN90.
Cardiomyocyte gene expression data sets were analyzed to verify involved components and to find further significantly altered genes after induced hypertrophy with TAC (transverse aortic constriction). Changes in the ultrastructure of the cardiomyocyte are the final result of induced hypertrophy.
Synthesis of Dualsteric Ligands for Muscarinic Acetylcholine Receptors and Cholinesterase Inhibitors
(2017)
The study is dealing with the synthesis and pharmacological investigation of newly designed dualsteric ligands of muscarinic acetylcholine receptors belonging to the superfamily of G protein-coupled receptors. Such bipharmacophoric ligands combine the advantages of the orthosteric binding site (high-affinity) and of the topographically distinct allosteric binding site (subtype-selectivity) resulting in compounds with reduced side effects. This opens the way to a new therapeutic approach in the treatment of e.g. chronic pain, drug withdrawal, Parkinson`s and Alzheimer`s disease. Furthermore, the newly synthesized dualsteric compounds were pharmacologically investigated in order to get a better understanding of the activation and signaling processes in muscarinic acetylcholine receptors, especially with regard to partial agonism.
The development of the “dynamic ligand binding” concept offers new perspectives for ligand binding and signaling at G protein-coupled receptors. GPCRs are no longer considered as simple on/off switches. Dualsteric ligands can bind in a dualsteric pose, reflecting an active receptor state as well as in a purely allosteric binding pose, characterized by an inactive receptor state resulting in partial agonism. The degree of partial agonism depends on the ratio of active versus inactive receptor populations. On this basis, orthosteric/orthosteric hybrid ligands consisting of the antagonist atropine and scopolamine, respectively, as well as of the agonist iperoxo and isoxazole, respectively, linked via different alkyl chain length were synthesized in order to investigate partial agonism (Figure 1).
Figure 1: Structures of the synthesized iperoxo/isoxazole-atropine/scopolamine-hybrids.
Furthermore, different sets of quaternary and tertiary homodimers consisting either of two iperoxo or two acetylcholine units were synthesized in order to study their extent on partial agonism (Figure 2). The two agonists were connected by varying alkyl chain length. Binding studies on CHO-hM2 cells of the quaternary compounds revealed that dimerization of the agonist results in a loss of potency. The iperoxo-dimers reached higher maximum effects on the Gi- as well as on the Gs pathway in comparison to the acetylcholine-dimers. Besides the choice of the orthosteric building block (potency of the agonist), the alkyl chain length is also crucial for the degree of partial agonism.
Figure 2: Structures of the synthesized quat./tert. iperoxo/acetylcholine-homodimers.
Quinolone-based hybrids connected to the superagonist iperoxo and to the endogenous ligand acetylcholine, respectively, linked through an alkyl chain of different length were synthesized in order to develop further partial agonists (Figure 3). FRET studies confirmed M1 subtype-selectivity as well as linker dependent receptor response. The greatest positive FRET signal was observed with quinolone-C6-iper resulting from a positive cooperativity between the two separated moieties, alloster and orthoster. However, the corresponding hybrids with a longer linker led to an inverse FRET signal indicating a different binding mode, e.g. purely allosteric, in contrast to the shorter linked hybrids. Furthermore, the flexible alkyl spacer was replaced by a rigidified linker resulting in the hybrid quinolone-rigid-iperoxo (Figure 3). FRET studies on the M1 receptor showed reduced FRET kinetics, resulting from interactions between the bulky linker and the aromatic lid, located between the orthosteric and allosteric binding site. A bitopic binding mode of the rigidified hybrid is presumed. For further clarity, mutational studies are necessary.
Figure 3: M1-selective hybrid compounds.
Another aim of this work was the design and synthesis of new hybrid compounds, acting as agonists at the M1 and M2 receptor and as inhibitors for AChE and BChE in the context of M. Alzheimer. Several sets of hybrid compounds consisting of different pharmacophoric units (catalytic active site: phthalimide, naphthalimide, tacrine; peripheric anionic site: iperoxo, isoxazole) linked through a polymethylene chain of varying length were synthesized. Tac-C10-iper (Figure 4), consisting of tacrine and the superagonist iperoxo linked by a C10 polymethylene spacer, was found to have excellent anticholinesterase activity for both AChE (pIC50 = 9.81) and BChE (pIC50 = 8.75). Docking experiments provided a structural model to rationalize the inhibitory power towards AChE. Additionally, the tacrine related hybrids showed affinity to the M1 and M2 receptor. Such compounds, addressing more than one molecular target are favorable for multifactorial diseases such as Alzheimer.
Figure 4: Structure of the most active compound regarding anticholinesterase activity.
In summary, the choice of the pharmacophoric units, their connecting point as well as the nature, length, and flexibility of the linker play an important role for the activity of designed bivalent ligands. A shorter linker length cannot bridge both binding sites simultaneously in contrast to longer linker chains. On the other hand, too long linker chains can result in unwanted steric interactions. Further investigations with respect to structural variations of hybrid compounds, with or without quaternary ammonium groups, are necessary in the light of drug development.
The CXC chemokine receptor 4 (CXCR4) and the atypical chemokine receptor 3 (ACKR3) are seven transmembrane receptors that are involved in numerous pathologies, including several types of cancers. Both receptors bind the same chemokine, CXCL12, leading to significantly different outcomes. While CXCR4 activation generally leads to canonical GPCR signaling, involving Gi proteins and β‐arrestins, ACKR3, which is predominantly found in intracellular vesicles, has been shown to signal via β‐arrestin‐dependent signaling pathways. Understanding the dynamics and kinetics of their activation in response to their ligands is of importance to understand how signaling proceeds via these two receptors.
In this thesis, different Förster resonance energy transfer (FRET)‐based approaches have been combined to individually investigate the early events of their signaling cascades. In order to investigate receptor activation, intramolecular FRET sensors for CXCR4 and ACKR3 were developed by using the pair of fluorophores cyan fluorescence protein and fluorescence arsenical hairpin binder. The sensors, which exhibited similar functional properties to their wild‐type counterparts, allowed to monitor their ligand-induced conformational changes and represent the first RET‐based receptor sensors in the field of chemokine receptors. Additional FRET‐based settings were also established to investigate the coupling of receptors with G proteins, rearrangements within dimers, as well as G protein activation. On one hand, CXCR4 showed a complex activation mechanism in response to CXCL12 that involved rearrangements in the transmembrane domain of the receptor followed by rearrangements between the receptor and the G protein as well as rearrangements between CXCR4 protomers, suggesting a role of homodimers in the activation course of this receptor. This was followed by a prolonged activation of Gi proteins, but not Gq activation, via the axis CXCL12/CXCR4. In contrast, the structural rearrangements at each step of the signaling cascade in response to macrophage migration inhibitory factor (MIF) were dynamically and kinetically different and no Gi protein activation via this axis was detected. These findings suggest distinct mechanisms of action of CXCL12 and MIF on CXCR4 and provide evidence for a new type of sequential signaling events of a GPCR. Importantly, evidence in this work revealed that CXCR4 exhibits some degree of constitutive activity, a potentially important feature for drug development. On the other hand, by cotransfecting the ACKR3 sensor with K44A dynamin, it was possible to increase its presence in the plasma membrane and measure the ligand‐induced activation of this receptor. Different kinetics of ACKR3 activation were observed in response to CXCL12 and three other agonists by means of using the receptor sensor developed in this thesis, showing that it is a valuable tool to study the activation of this atypical receptor and pharmacologically characterize ligands. No CXCL12‐induced G protein activation via ACKR3 was observed even when the receptor was re-localized to the plasma membrane by means of using the mutant dynamin. Altogether, this thesis work provides the temporal resolution of signaling patterns of two chemokine receptors for the first time as well as valuable tools that can be applied to characterize their activation in response to pharmacologically relevant ligands.