Kaiserslautern - Fachbereich Chemie
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In dieser Arbeit wurden photoaktive Übergangsmetallkomplexe mit häufig vorkommenden Metallen wie Chrom, Vanadium und Kupfer untersucht. Hierbei wurden ausgewählte Exemplare mit besonders interessanten photophysikalischen und photochemischen Eigenschaften in Bezug auf praktische Anwendungen spektroskopisch charakterisiert. Über statische und insbesondere zeitaufgelöste FTIR- und Lumineszenzspektroskopie wurde ein tieferes Verständnis der Dynamik nach Lichtanregung erzielt. Das Hauptziel dieser Forschung besteht darin seltene und teure Elemente wie Ruthenium und Iridium gegen häufigere Metalle zu ersetzen.
In diesem Zusammenhang wurden mononukleare, oktaedrische Chrom(III)- und Vanadium(III)-Komplexe mit Polypyridylliganden, die im Arbeitskreis von Prof. Dr. Katja Heinze synthetisiert wurden, spektroskopisch charakterisiert. Diese Systeme zeigen vielversprechende Lumineszenzeigenschaften mit einer roten bzw. nahinfraroten Phosphoreszenz, wobei bei tiefen Temperaturen besonders hohe Quantenausbeuten und längere Lebensdauern beobachtet werden konnten.
Außerdem wurden einkernige Chrom(0)-, Molybdän(0)- und Wolfram(0)-Komplexe spektroskopisch charakterisiert, die allesamt im Arbeitskreis von Prof. Dr. Biprajit Sarkar synthetisiert wurden. Es sind mononukleare Komplexe mit Pyridyl-Carben-Liganden und Carbonyl-Coliganden mit einer dualen Phosphoreszenz (Emissionsbande im roten und nahinfraroten Bereich), wobei sich die niederenergetische Bande interessanterweise bis 1300 nm erstreckt. Außerdem zeigen die drei Komplexe bei intensiver Bestrahlung mit sichtbarem oder UV-Licht in organischer Lösung eine photochemische Reaktivität.
Als weitere vielversprechende Luminophore (sichtbare Emission) wurden Kupfer(I)-Komplexe analysiert, die für organische Leuchtdioden relevant sind. Einerseits wurden zweikernige Systeme mit einer zentralen Cu2I2-Einheit untersucht, die sich durch eine Fluorierung an den Phosphin-Hilfsliganden von den Derivaten aus Vorarbeiten unterscheiden. Die Systeme wurden im Arbeitskreis von Prof. Dr. Stefan Bräse zur Verbesserung der Löslichkeit im Vergleich zu unfluorierten Derivaten entwickelt. Die spektroskopischen Befunde dieser Arbeit zeigen, dass insbesondere die Einführung von Trifluormethylgruppen nicht nur die Löslichkeit, sondern auch die Stabilität verbessert. Andererseits wurden vierkernige Komplexe mit näherungsweise oktaedrischen Cu4X4-Clustern (X = I, Br, Cl) charakterisiert, wobei sich teilweise eine stark thermochrome Lumineszenz mit zwei klar separierten roten bzw. blauen Phosphoreszenzbanden ergab. Der Ursprung dieser Thermochromie konnte erstmalig auf experimentellem Weg den starken strukturellen Veränderung innerhalb des Cu4X4-Clusters zugeordnet werden.
Außerdem sind Kupfer(I)-Komplexe vielversprechende Kandidaten zur Verwendung als Photosensibilisatoren. Bei einem vom Arbeitskreis von Dr. Michael Karnahl zu Verfügung gestellten Kupfer(I)-Einkerner mit einem Liganden mit ausgedehntem 𝜋-System ergab sich ein langlebiger, nicht-strahlender Triplett-Zustand. In einem verwandten Projekt wurden ein- und zweikernige Kupfer(I)-Komplexe untersucht, die im Arbeitskreis von Dr. Claudia Bizzarri synthetisiert wurden. Der Fokus lag hierbei auf dem Einfluss einer Dimerisierung (kovalente Verbindung zweier mononuklearer Komplexe) oder einer Protonierung eines Liganden auf die photophysikalischen Eigenschaften.
Metal-directed self-assembly with metals such as Pd(II) and Pt(II), that prefer a square
planar coordination geometry, has been showing remarkable potential to construct
supramolecular architectures such as helices, tubes, locks and cages. Some of these
complexes have also been shown to assemble by means of metal-metal interactions and,
more remarkably, the luminescent properties of certain complexes can also be used for
sensing. For instance, Pt(II) and Pd(II) complexes display strong phosphorescence which
is strongly reduced in the presence of oxygen. The work developed for this thesis is
divided into three main chapters dealing with the different properties of Pd(II) and Pt(II)
metal complexes.
Chapter I was mainly developed at Technische Universität Kaiserslautern with a short
partnership with the Kekulé-Institut für Organische Chemie und Biochemie at the
Universität Bonn and addressed the construction of coordination macrocycles and cages
from suitable Pd(II) sources and cyclopeptide-derived ligands. Cyclopeptide derived
hollow coordination compounds were obtained through Pd(II)-directed self-assembly.
Specifically, the treatment of the pyridine containing cyclopeptides CP1 and CP2 with
[Pd(en)(NO3)2] afforded the metallamacrocycle CP12Pd2 and the cage CP22Pd3. These
products were characterized by means of NMR spectroscopy and mass spectrometry. The
reaction between CP1 and [Pd(CH3CN)4](BF4)2] afforded, according to ESI-MS and NMR
measurements, a complex with the composition CP16Pd3 and the smaller cage CP14Pd2.
Binding studies indicated that CP12Pd2 incorporated different dicarboxylates, sodium 1,3-
benzenedisulfonate (BDS), and sodium 2,6-naphthalenedisulfonate (NDS) into its cavity.
In the case of BDS a 1:1 complex was formed that had a log Ka of 4.8 ± 0.2 in D2O/CD3OD,
1:1 (v/v). In the case of NDS, binding was slow on the NMR time-scale and involved the
binding of two guest molecules as confirmed by a crystal structure of the complex.
Based on these first examples of Pd(II)-containing cyclopeptide-derived coordination
compounds, future work should focus on the design of molecular architectures that can,
for example, be used as receptors for biorelevant guests.
In Chapter II, the aggregation abilities and photophysical properties of Pt(II) complexes
bearing tridentate-azolate-based ligands and cyclopeptides with peripheral pyridyl
moieties were investigated. This project was the result of a short-term secondment
developed at the Institut de Science et d'Ingénierie Supramoléculaires in Strasbourg.
Efforts were made at creating luminescent cyclopeptide-derived Pt(II) complexes by
coordinating CP1 or CP2 to suitable Pt(II)-containing precursors. The coordination of both
peptides to a known Pt(II) complex afforded insoluble products that could not be
characterized further. To circumvent these solubility issues, the synthesis of the
analogous cyclopeptide complexes containing more polar ligands was attempted.
Although mass spectrometry provided evidence for the formation of the target
complexes PtDeg-CP1 and PtDeg-CP2 in the crude reaction mixtures, the
products could not be isolated in pure form. The impure samples of PtDeg-CP1 and PtDegCP2 both exhibited orange emission.
Further work is necessary to improve the preparation of such complexes. Only then can
the characterization of their photophysical properties and self-assembling behavior be
addressed.
Chapter III was the result of a project executed at Micronit Micro Technologies B.V. in
Enschede, in which a microfluidic device with oxygen sensing abilities was produced from
nanoparticles containing Pt(II)-porphyrins. To this end, microfluidic devices containing
the Pt(II) complex PtTPTBPF incorporated in different polymeric matrices were
prepared and their oxygen sensing abilities characterized. It was shown that chips
containing the Pt(II) complex incorporated into OXNANO nanoparticles were highly
sensitive to oxygen, easy to fabricate, and allowed reliable oxygen quantification. Chips
made by using other polymeric matrices such as PDMS, Elastosil®E43 or polystyrene were
less suitable for the measurements.
The OXNANO-containing chips furthermore allowed measuring the oxygen consumption
of HUVEC cells in a biological assay even in repeated measurements. Future studies
should now involve using these chips for monitoring in real time small scale biological
processes.
The present thesis investigates the interaction of size selected transition metal cluster cations with \(N_2\) adsorbate molecules under cryogenic conditions. A tandem cryo ion trap mass spectrometer facilitates the recording of the adsorption kinetics of gases onto size selected transition metals clusters under isothermal cryo conditions. The combination with a tunable OPO/OPA laser system allows for the recording of Infrared-(Multiple) Photodissociation (IR-(M)PD) spectra of the resulting cluster adsorbate complexes. The comparison of the experimental results with DFT modelling allows for structural assignments and the evaluation of the clusters’ electronic properties. We apply the combination of these methods on rhodium, rhodium-iron alloy and tantalum clusters and present the results in seven research studies. The IR-(M)PD spectra of rhodium cluster adsorbate complexes indicate co-existing isomers and a spin quench with increasing number of adsorbed \(N_2\). Adsorption kinetics allowed to assign clusters with rough and smooth surfaces and to find features of adsorption reluctance. Calculated spin valley curves reveal a spin quench upon \(N_2\) adsorption onto the \(Rh_5^+\) cluster. Band shifts in the IR-(M)PD spectra of sequential \(N_2\) adsorption onto the \(Rh_6^+\) cluster are interpreted in terms of adsorbate induced charge dilution, which is supported by DFT calculations. Our combined approach reveals alloy like mixed rhodium iron clusters with adsorption site dependent \(N_2\) stretching vibrations, where \(N_2\) preferentially adsorbs onto rhodium sites. The \(Ta_4^+\) cluster facilitates the cleavage of the initial two \(N_2\) adsorbate molecules. By help of IR-(M)PD spectroscopy and DFT modelling we are able to assign a novel AEAS (across edge-above surface) mechanism and to assign an activated side-on intermediate of the third adsorbate molecule. The investigation sequential \(N_2\) adsorption onto the \(Ta_5^+\) cluster does not reveal any evidence for \(N_2\) activation. DFT modelling reveals low spin states.
With a yearly production of about 39 million tons, brewer’s spent grain (BSG) is the
most abundant brewing industry byproduct. Because it is rich in fiber and protein, it is commonly
used as cattle feed but could also be used within the human diet. Additionally, it contains many
bioactive substances such as hydroxycinnamic acids that are known to be antioxidants and potent
inhibitors of enzymes of glucose metabolism. Therefore, our study aim was to prepare different
extracts—A1-A7 (solid-liquid extraction with 60% acetone); HE1-HE6 (alkaline hydrolysis followed
by ethyl acetate extraction) and HA1-HA3 (60% acetone extraction of alkaline residue)—from various
BSGs which were characterized for their total phenolic (TPC) and total flavonoid (TFC) contents,
before conducting in vitro studies on their effects on the glucose metabolism enzymes α-amylase,
α-glucosidase, dipeptidyl peptidase IV (DPP IV), and glycogen phosphorylase α (GPα). Depending
on the extraction procedures, TPCs ranged from 20–350 μg gallic acid equivalents/mg extract
and TFCs were as high as 94 μg catechin equivalents/mg extract. Strong inhibition of glucose
metabolism enzymes was also observed: the IC50 values for α-glucosidase inhibition ranged from
67.4 ± 8.1 μg/mL to 268.1 ± 29.4 μg/mL, for DPP IV inhibition they ranged from 290.6 ± 97.4 to
778.4 ± 95.5 μg/mL and for GPα enzyme inhibition from 12.6 ± 1.1 to 261 ± 6 μg/mL. However, the
extracts did not strongly inhibit α-amylase. In general, the A extracts from solid-liquid extraction
with 60% acetone showed stronger inhibitory potential towards α-glucosidase and GPα than other
extracts whereby no correlation with TPC or TFC were observed. Additionally, DPP IV was mainly
inhibited by HE extracts but the effect was not of biological relevance. Our results show that BSG
is a potent source of α-glucosidase and GPα inhibitors, but further research is needed to identify
these bioactive compounds within BSG extracts focusing on extracts from solid-liquid extraction
with 60% acetone.
Colorectal cancer (CRC) is among the most frequent cancer entities worldwide. Multiple factors are causally associated with CRC development, such as genetic and epigenetic alterations,
inflammatory bowel disease, lifestyle and dietary factors. During malignant transformation,the cellular energy metabolism is reprogrammed in order to promote cancer cell growth and
proliferation. In this review, we first describe the main alterations of the energy metabolism found in CRC, revealing the critical impact of oncogenic signaling and driver mutations in key metabolic
enzymes. Then, the central role of mitochondria and the tricarboxylic acid (TCA) cycle in this process is highlighted, also considering the metabolic crosstalk between tumor and stromal cells in the
tumor microenvironment. The identified cancer-specific metabolic transformations provided new therapeutic targets for the development of small molecule inhibitors. Promising agents are in clinical
trials and are directed against enzymes of the TCA cycle, including isocitrate dehydrogenase, pyruvate dehydrogenase kinase, pyruvate dehydrogenase complex (PDC) and α-ketoglutarate dehydrogenase
(KGDH). Finally, we focus on the α-lipoic acid derivative CPI-613, an inhibitor of both PDC and KGDH, and delineate its anti-tumor effects for targeted therapy.
The consumption of red meat is associated with an increased risk for colorectal cancer (CRC). Multiple lines of evidence suggest
that heme iron as abundant constituent of red meat is responsible for its carcinogenic potential. However, the underlying
mechanisms are not fully understood and particularly the role of intestinal inflammation has not been investigated. To address
this important issue, we analyzed the impact of heme iron (0.25 μmol/g diet) on the intestinal microbiota, gut inflammation
and colorectal tumor formation in mice. An iron-balanced diet with ferric citrate (0.25 μmol/g diet) was used as reference.
16S rRNA sequencing revealed that dietary heme reduced α-diversity and caused a persistent intestinal dysbiosis, with a
continuous increase in gram-negative Proteobacteria. This was linked to chronic gut inflammation and hyperproliferation of
the intestinal epithelium as attested by mini-endoscopy, histopathology and immunohistochemistry. Dietary heme triggered
the infiltration of myeloid cells into colorectal mucosa with an increased level of COX-2 positive cells. Furthermore, flow
cytometry-based phenotyping demonstrated an increased number of T cells and B cells in the lamina propria following heme
intake, while γδ-T cells were reduced in the intraepithelial compartment. Dietary heme iron catalyzed formation of fecal
N-nitroso compounds and was genotoxic in intestinal epithelial cells, yet suppressed intestinal apoptosis as evidenced by
confocal microscopy and western blot analysis. Finally, a chemically induced CRC mouse model showed persistent intestinal
dysbiosis, chronic gut inflammation and increased colorectal tumorigenesis following heme iron intake. Altogether, this study
unveiled intestinal inflammation as important driver in heme iron-associated colorectal carcinogenesis
The consumption of red meat is probably carcinogenic to humans and is associated with an increased risk to develop colorectal cancer (CRC). Red meat contains high amounts of heme iron, which is thought to play a causal role in tumor formation. In this study, we investigated the genotoxic and cytotoxic effects of heme iron (i.e., hemin) versus inorganic iron in human colonic epithelial cells (HCEC), human CRC cell lines and murine intestinal organoids. Hemin catalyzed the formation of reactive oxygen species (ROS) and induced oxidative DNA damage as well as DNA strand breaks in both HCEC and CRC cells. In contrast, inorganic iron hardly affected ROS levels and only slightly increased DNA damage. Hemin, but not inorganic iron, caused cell death and reduced cell viability. This occurred preferentially in
non-malignant HCEC, which was corroborated in intestinal organoids. Both hemin and inorganic iron were taken up into HCEC and CRC cells, however with differential kinetics and efficiency. Hemin caused stabilization and nuclear translocation of Nrf2, which induced heme oxygenase-1 (HO-1) and ferritin heavy chain (FtH). This was not observed after inorganic iron treatment. Chemical inhibition or genetic knockdown of HO-1 potentiated hemin-triggered ROS
generation and oxidative DNA damage preferentially in HCEC. Furthermore, HO-1 abrogation strongly augmented the cytotoxic effects of hemin in HCEC, revealing its pivotal function in colonocytes and highlighting the toxicity of free intracellular heme iron. Taken together, this study demonstrated that hemin, but not inorganic iron, induces ROS and DNA damage, resulting in a preferential cytotoxicity in non-malignant intestinal epithelial cells. Importantly, HO-1
conferred protection against the detrimental effects of hemin.
Abstract: Colorectal cancer (CRC) is a frequently occurring malignant disease with still low survival rates, highlighting the need for novel therapeutics. Merosesquiterpenes are secondary metabolites from marine sponges, which might be useful as antitumor agents. To address this issue, we made use of a compound library comprising 11 isolated merosesquiterpenes. The most cytotoxic compounds were smenospongine > ilimaquinone ≈ dactylospontriol as shown in different human CRC cell lines. Alkaline Comet assays and γH2AX immunofluorescence microscopy demonstrated DNA strand break formation in CRC cells. Western blot analysis revealed an activation of the DNA damage response with CHK1 phosphorylation, stabilization of p53 and p21, which occurred both in CRC cells with p53 knockout and in p53-mutated CRC cells. This resulted in cell cycle arrest followed by a strong increase in the subG1 population, indicative of apoptosis, and typical morphological alterations. In consistency, cell death measurements showed apoptosis following exposure to merosesquiterpenes. Gene expression studies and analysis of caspase cleavage revealed mitochondrial apoptosis via BAX, BIM and caspase-9 as main cell death pathway. Interestingly, the compounds were equally effective in p53-wildtype and p53-mutant CRC cells. Finally, the cytotoxic activity of the merosesquiterpenes was corroborated in intestinal tumor organoids, emphasizing their potential for CRC chemotherapy.
Subject of this thesis is the investigation of photo-induced ultrafast elementary processes within the electronic excited-state manifold in mass-selected multinuclear coinage metal complexes (CMCs) in the gas phase. The chief objective is to ascertain how the intramolecular deactivation dynamics and gas phase reactivity are influenced by so-called metallophilic interactions between multiple d^10/d^8 metal centers, which in turn give rise to metal-delocalized electronic transitions. To this end, suitable molecular precursor ions were transferred into the gas phase by electrospray ionization (ESI) and subsequently isolated, activated, and finally analyzed in a Paul-type quadrupole ion trap (QIT) mass spectrometer. The QIT is modified to accept UV/Vis/NIR irradiation from a femtosecond laser setup. By combining several ion trap-based ion activation techniques and electronic photodissociation (PD) spectroscopy, the fragmentation pathways, as well as intrinsic optical properties (electronic PD spectra) of ionic CMCs are explored. In addition, the unconventional time-resolved transient photodissociation (t-PD) method, based on a femtosecond pump-probe excitation scheme, was employed for the first time on CMC ions in isolation, in order to elucidate their intrinsic photodynamics. This thesis mainly comprises five publications, covering the mass spectrometric and laser spectroscopic characterization of multinuclear Ag(I), Au(I), and Pt(II) based ionic complexes.
We have investigated urine samples after coffee consumption using targeted and untargeted
approaches to identify furan and 2-methylfuran metabolites in urine samples by UPLC-qToF.
The aim was to establish a fast, robust, and time-saving method involving ultra-performance
liquid chromatography-quantitative time-of-flight tandem mass spectrometry (UPLC-qToF-MS/MS).
The developed method detected previously reported metabolites, such as Lys-BDA, and others that
had not been previously identified, or only detected in animal or in vitro studies. The developed
UPLC-qToF method detected previously reported metabolites, such as lysine-cis-2-butene-1,4-dial
(Lys-BDA) adducts, and others that had not been previously identified, or only detected in animal
and in vitro studies. In sum, the UPLC-qToF approach provides additional information that may be
valuable in future human or animal intervention studies.