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- J-8841-2015 (1)
This thesis considers a model of a scalar partial differential equation in the presence of a singular source term, modeling the interaction between an inviscid fluid represented by the Burgers equation and an arbitrary, finite amount of particles moving inside the fluid, each one acting as a point-wise drag force with a particle related friction constant.
\begin{align*}
\partial_t u + \partial_x (u^2/2) &= \sum_{i \in N(t)} \lambda_i \Big(h_i'(t)-u(t,h_i(t)\Big)\delta(x-h_i(t))
\end{align*}
The model was introduced for the case of a single particle by Lagoutière, Seguin and Takahashi, is a first step towards a better understanding of interaction between fluids and solids on the level of partial differential equations and has the unique property of considering entropy admissible solutions and the interaction with shockwaves.
The model is extended to an arbitrary, finite number of particles and interactions like merging, splitting and crossing of particle paths are considered.
The theory of entropy admissibility is revisited for the cases of interfaces and discontinuous flux conservation laws, existing results are summarized and compared, and adapted for regions of particle interactions. To this goal, the theory of germs introduced by Andreianov, Karlsen and Risebro is extended to this case of non-conservative interface coupling.
Exact solutions for the Riemann Problem of particles drifting apart are computed and analysis on the behavior of entropy solutions across the particle related interfaces is used to determine physically relevant and consistent behavior for merging and splitting of particles. Well-posedness of entropy solutions to the Cauchy problem is proven, using an explicit construction method, L-infinity bounds, an approximation of the particle paths and compactness arguments to obtain existence of entropy solutions. Uniqueness is shown in the class of weak entropy solutions using almost classical Kruzkov-type analysis and the notion of L1-dissipative germs.
Necessary fundamentals of hyperbolic conservation laws, including weak solutions, shocks and rarefaction waves and the Rankine-Hugoniot condition are briefly recapitulated.
The main focus of this thesis was the processing of different calcium and magnesium phosphate cements together with an optimization of mechanical and biological properties. Therefore, different manufacturing techniques like 3D powder printing and centrifugally casting were employed for the fabrication of reinforced or biomedically improved implants.
One of the main problems during 3D powder printing is the low green strength of many materials, especially when they are only physically bonded and do not undergo a setting reaction. Such materials need post-treatments like sintering to exhibit their full mechanical performance. However, the green bodies have to be removed from the printer requiring a certain stability. With the help of fiber reinforcement, the green strength of printed gypsum samples could be increased by the addition of polymeric and glass fibers within the printing process. The results showed that fiber reinforcement during 3D powder printing is possible and opens up diverse opportunities to enhance the damage tolerance of green bodies as well as directly printed samples. The transfer to biomedically relevant materials like calcium and magnesium phosphate cements and biocompatible fibers would be the next step towards reinforced patient-specific implants.
In a second approach, centrifugally casting derived from construction industries was established for the fabrication of hollow bioceramic cylinders. The aim was the replacement of the diaphysis of long bones, which exhibit a tubular structure with a high density of cortical bone on the fringe. By centrifugation, cement slurries with and without additives could be fabricated to tubes. As a first establishment, the processing parameters regarding the material (e.g. cement composition) as well as the set-up (e.g. rotation times) had to be optimized for each system. In respect of mechanics, such tubes can keep up with 3D powder printed tubes, although the mechanical performance of 3D printed tubes is strongly dependent on printing directions. Additionally, some material compositions like dual setting systems cannot be fabricated by 3D powder printing. Therefore, a transfer of such techniques to centrifugally casting enabled the fabrication of tubular structures with an extremely high damage tolerance due to high deformation ability. A similar effect was achieved by fiber (mesh) addition, as already shown for 3D powder printing. Another possibility of centrifugally casting is the combination of different materials resulting in graded structures to adjust implant degradation or bone formation. This became especially apparent for the incorporation of the antibiotic vancomycin, which is used for the treatment of bacterial implant infections. A long-term release could be achieved by the entrapment of the drug between magnesium phosphate cement layers. Therefore, the release of the drug could be regulated by the degradation of the outer shell, which supports the release into an acidic bacterial environment. The centrifugally casting technique exhibited to be a versatile tool for numerous materials and applications including the fabrication of non-centrosymmetric patient-specific implants for the reconstruction of human long bones.
The third project aimed to manufacture strontium-substituted magnesium phosphate implants with improved biological behavior by 3D powder printing. As the promoting effect of strontium on bone formation and the inhibitory impact on bone resorption is already well investigated, the incorporation of strontium into a degradable magnesium phosphate cement promised a fast integration and replacement of the implant. Porous structures were obtained with a high pore interconnectivity that is favorable for cell invasion and bone ingrowth. Despite the porosity, the mechanical performance was comparable to pure magnesium phosphate cement with a high reliability of the printed samples as quantitatively determined by Weibull statistics. However, the biological testing was impeded by the high degradation rate and the relating ion release. The high release of phosphate ions into surrounding media and the detachment of cement particles from the surface inhibited osteoblast growth and activity. To distinguish those two effects, a direct and indirect cell seeding is always required for degradable materials. Furthermore, the high phosphate release compared to the strontium release has to be managed during degradation such that the adverse effect of phosphate ions does not overwhelm the bone promoting effect of the strontium ions.
The manufacturing techniques presented in this thesis together with the material property improvement offer a diverse tool box for the fabrication of patient-specific implants. This includes not just the individual implant shape but also the application like bone growth promotion, damage tolerance and local drug delivery. Therefore, this can act as the basis for further research on specific medical indications.
Single-molecule fluorescence microscopy in live \(Trypanosoma\) \(brucei\) and model membranes
(2018)
The eukaryotic parasite Trypanosoma brucei has evolved sophisticated strategies to escape
the host immune response and maintain a persistent infection inside a host. One central
feature of the parasite’s defense mechanism relies on the shielding function of their surface
protein coat. This coat is composed of a dense arrangement of one type of glycosylphosphatidylinositol
(GPI)-anchored variant surface glycoproteins (VSGs) which impair the
identification of epitopes of invariant surface proteins by the immune system. In addition
to the importance of understanding the function of the VSG coat and use it as a potential
target to efficiently fight the parasite, it is also crucial to study its biophysical properties as it is not yet understood sufficiently. This is due to the fact that microscopic investigations
on living trypanosomes are limited to a great extent by the intrinsic motility of the parasite.
In the present study, state-of-the-art single-molecule fluorescence microscopy (SMFM)
is introduced as a tool for biophysical investigations in the field of trypanosome research.
The work encompasses studies of VSG dynamics under the defined conditions of an
artificial supported lipid bilayer (SLB). First, the impact of the lateral protein density on
VSG diffusion was systematically studied in SLBs. Ensemble fluorescence after photobleaching
(FRAP) and complementary single-particle tracking experiments revealed that a
molecular crowding threshold (MCT) exists, above which a density dependent decrease
of the diffusion coefficient is measured. A relative quantification of reconstituted VSGs
illustrated that the VSG coat of living trypanosomes operates very close to its MCT and
is optimized for high density while maintaining fluidity. Second, the impact of VSG
N-glycosylation on VSG diffusion was quantitatively investigated. N-glycosylation was
shown to contribute to preserving protein mobility at high protein concentrations. Third,
a detailed analysis of VSG trajectories revealed that two distinct populations of freely
diffusing VSGs were present in a SLB, which is in agreement with the recent finding, that
VSGs are able to adopt two main structurally distinct conformations. The results from
SLBs were further complemented by single-particle tracking experiments of surface VSGs
on living trypanosomes. A high mobility and free diffusion were measured on the cell
surface, illustrating the overall dynamic nature of the VSG coat. It was concluded that
the VSG coat on living trypanosomes is a protective structure that combines density and
mobility, which is supported by the conformational flexibility of VSGs. These features are
elementary for the persistence of a stable infection in the host.
Different hydrogel embedding methods are presented, that facilitated SMFM in immobilized,
living trypanosomes. The hydrogels were found to be highly cytocompatible for one
hour after cross-linking. They exhibited low autofluorescence properties in the spectral
range of the investigations, making them suitable for super-resolution microscopy (SRM).
Exemplary SRM on living trypanosomes illustrated that the hydrogels efficiently immobilized
the cells on the nanometer lever. Furthermore, the plasma membrane organization was studied in living trypanosomes. A statistical analysis of a tracer molecule inside the
inner leaflet of the plasma membrane revealed that specific membrane domains exist, in
which the tracer appeared accumulated or diluted. It was suggested that this distribution
was caused by the interaction with proteins of the underlying cytoskeleton.
In conclusion, SMFM has been successfully introduced as a tool in the field of trypanosome
research. Measurements in model membranes facilitated systematic studies of VSG dynamics
on the single-molecule level. The implementation of hydrogel immobilization
allowed for the study of static structures and dynamic processes with high spatial and
temporal resolution in living, embedded trypanosomes for the first time.
Previous work of our group has established a role of sphingomyelinases in the regulation
of T cell responses to TCR or pathogen stimulation, and this became particularly
evident at the level of actin cytoskeletal dynamics. The formation of lipid membrane
microdomains is crucial for receptor clustering and signal induction, and therefore,
ceramide accumulation by membrane sphingomyelin breakdown is needed for signalling-
complex-assembly. Pathogen-induced overshooting of SMase activation substantially
impacted the formation of membrane protrusions, with T cell spreading as well as
a front/rear polarisation upon CD3/CD28 co-stimulation [103]. On the other hand, NSM
activation is part of the physiological TCR signal [67], indicating that a spatiotemporally
balanced NSM activation is crucial for its physiological function. It involves actin cytoskeletal
reorganisation and T cell polarisation. These two functions are also of central
importance in directional T cell migration and motility in tissues.
This thesis aims on defining the role of NSM in compartmentalisation of the T cell
membrane in polarisation and migration. Therefore, functional studies on the impact of
NSM activity in these processes had to be complemented by the development of tools
to study ceramide compartmentalisation in living T cells.
Involvement of neuronal nitric oxide synthase (NOS-I) PDZ interactions in neuropsychiatric disorders
(2018)
Neuronal nitric oxide (NO) synthase (NOS-I) and its adaptor protein (NOS1AP) have been repeatedly and consistently associated with neuropsychiatric disorders in several genetic association and linkage studies, as well as functional studies. NOS-I has an extended PDZ domain which enables it to interact with postsynaptic density protein 95 (PSD-95) bringing NOS-I in close proximity to NMDA receptors. This interaction allows NMDA receptor activity dependent calcium-influx to activate NOS-I, linking NO synthesis to regulation of glutamatergic signaling pathways. NOS1AP is a PDZ-domain ligand of NOS-I and has been proposed to compete with PSD-95 for NOS-I interaction. Studies performed on post-mortem brain tissues have shown increased expression of NOS1AP in patients with schizophrenia and bipolar disorder, suggesting that increased NOS-I/NOS1AP interactions might be involved in neuropsychiatric disorders possibly through disruption of NOS-I PDZ interactions. Therefore, I have investigated the involvement of NOS-I in different endophenotypes of neuropsychiatric disorders by targeting its specific PDZ interactions in vitro and in vivo. To this end, I used recombinant adeno-associated virus (rAAV) vectors expressing NOS1AP isoforms/domains (NOS1AP-L: full length NOS1AP; NOS1AP-LC20: the last 20 amino acids of NOS1AP-L, containing the PDZ interaction motif suggested to stabilize interaction with NOS-I; NOS1AP-LΔC20: NOS1AP-L lacking the last 20 amino acids; NOS1AP-S: the short isoform of NOS1AP), residues 396-503 of NOS1AP-L (NOS1AP396-503) encoding the full NOS-I interaction domain, and N-terminal 133 amino acids of NOS-I (NOS-I1-133) encoding for the extended PDZ-domain.
Neuropsychiatric disorders involve morphological brain changes including altered dendritic
development and spine plasticity. Hence, I have examined dendritic morphology in primary cultured hippocampal and cortical neurons upon overexpression of constructed rAAV vectors. Sholl analysis revealed that overexpression of NOS1AP-L and NOS1AP-LΔC20 mildly reduced dendritic length/branching. Moreover, overexpression of all NOS1AP isoforms/domains resulted in highly altered spine plasticity including significant reduction in the number of mature spines and increased growth of filopodia. These findings suggest that NOS1AP affects dendritic growth
and development of dendritic spines, which may involve both, increased NOS-I/NOS1AP interaction as well as interaction of NOS1AP with proteins other than NOS-I. Interestingly, the observed alterations in dendritic morphology were reminiscent of those observed in post-mortem brains of patients with neuropsychiatric disorders.
Given the dendritic alterations in vitro, I have examined, whether disruption of NOS-I PDZ interaction would also result in behavioral deficits associated with neuropsychiatric disorders. To this end, rAAV vectors expressing NOS1AP-L, NOS1AP396-503, NOS-I1-133, and mCherry were stereotaxically delivered to the dorsal hippocampus of 6-week-old male C57Bl/6J mice. One week after surgery, mice were randomly separated into two groups. One of those groups underwent three weeks of chronic mild stress (CMS). Afterwards all mice were subjected to a comprehensive behavioral analysis. The findings revealed that overexpression of the constructs did not result in phenotypes related to anxiety or depression, though CMS had an anxiolytic effect independent of the injected construct. Mice overexpressing NOS-I1-133, previously shown to disrupt NOS-I/PSD-95 interaction, showed impaired spatial memory, sensorimotor gating, social interaction, and increased locomotor activity. NOS1AP overexpressing mice showed mild impairments in sensorimotor gating and spatial working memory and severely impaired social interaction. NOS1AP396-503 overexpressing mice also showed impaired social interaction but enhanced sensorimotor gating and reduced locomotor activity. Taken together, these behavioral findings indicate an involvement of NOS-I PDZ interactions in phenotypes associated with positive symptoms and cognitive deficits of psychotic disorders.
In summary, this study revealed an important contribution of NOS-I protein interactions in the development of endophenotypic traits of neuropsychiatric disorders, in particular schizophrenia,
at morphological and behavioral levels. These findings might eventually aid to a better
understanding of NOS-I-dependent psychopathogenesis, and to develop pharmacologically relevant treatment strategies.
Melanoma and Merkel cell carcinoma (MCC) are highly aggressive cancers of the skin that frequently escape immune recognition and acquire resistance to chemotherapeutic agents, which poses a major obstacle to successful cancer treatment. Recently, a new class of therapeutics targeting the programmed cell death-1 (PD-1) immune checkpoint receptor has shown remarkable efficacy in the treatment of both cancers. Blockade of PD-1 on T cells activates cancer-specific immune responses that can mediate tumor regression. The data presented in this Ph.D. thesis demonstrates that PD-1 is also expressed by subsets of cancer cells in melanoma and MCC. Moreover, this work identifies PD-1 as a novel tumor cell-intrinsic growth receptor, even in the absence of T cell immunity. PD-1 is expressed by tumorigenic cell subsets in melanoma patient samples and established human and murine cell lines that also co-express ABCB5, a marker of immunoregulatory tumor- initiating cells in melanoma. Consistently, melanoma-expressed PD-1 downmodulates T effector cell functions and increases the intratumoral frequency of tolerogenic myeloid- derived suppressor cells. PD-1 inhibition on melanoma cells by RNA interference, blocking antibodies, or mutagenesis of melanoma-PD-1 signaling motifs suppresses tumor growth in immunocompetent, immunocompromised, and PD-1-deficient tumor graft recipient mice. Conversely, melanoma-specific PD-1 overexpression enhances tumorigenicity, including in mice lacking adaptive immunity. Engagement of melanoma- PD-1 by its ligand PD-L1 promotes tumor growth, whereas melanoma-PD-L1 inhibition or knockout of host-PD-L1 attenuates growth of PD-1-positive melanomas. Mechanistically, the melanoma-PD-1 receptor activates mTOR signaling mediators, including ribosomal protein S6. In a proof-of-concept study, tumoral expression of phospho-S6 in pretreatment tumor biopsies correlated with clinical responses to anti-PD-1 therapy in melanoma patients. In MCC, PD-1 is similarly co-expressed by ABCB5+ cancer cell subsets in clinical tumor specimens and established human cell lines. ABCB5 renders MCC cells resistant to the standard-of-care chemotherapeutic agents, carboplatin and etoposide. Antibody-mediated ABCB5 blockade reverses chemotherapy resistance and inhibits tumor xenograft growth by enhancing chemotherapy-induced tumor cell killing. Furthermore, engagement of MCC-expressed PD-1 by its ligands, PD-L1 and PD-L2, promotes proliferation and activates MCC-intrinsic mTOR signaling. Consistently, antibody- mediated PD-1 blockade inhibits MCC tumor xenograft growth and phosphorylation of mTOR effectors in immunocompromised mice. In summary, these findings identify cancer cell-intrinsic functions of the PD-1 pathway in tumorigenesis and suggest that blocking melanoma- and MCC-expressed PD-1 might contribute to the striking clinical efficacy of anti-PD-1 therapy. Additionally, these results establish ABCB5 as a previously unrecognized chemoresistance mechanism in MCC.
In the first part of this thesis, the synthesis of a series of bistriarylamine (bisTAA) compounds was presented. On the one hand, the substitution pattern of the TAA at the benzene bridging unit was varied from meta- to para-position (pX and mX), on the other hand, the energetic position of the bridging unit was tuned by use of two electron-donating or electron-accepting substituents X (with X = OMe, Me, Cl, CN, NO2) in 2,5-position. In case of the meta-series, compounds with X in 4,6-position were synthesized (mX46). The photophysical and electrochemical properties of the neutral compounds were investigated.
The cationic mixed valence (MV) bisTAA compounds could be generated by oxidation. Thermally induced hole transfer (HT) in the groud state was investigated by temperature depending ESR spectroscopy. While the HT rate k and HT barrier ΔG in mX are unaffected by the substituents X, k and ΔG in the pX series increase simultaneously with increasing electron-donating strength of X. This, at first contradictory observation can be explained by an increasingly important solvent dynamic effect and an additional, effective barrier. The optically induced HT was examined by UV/Vis/NIR spectroscopy. The pX-series revealed an increase of the electronic coupling V, and correspondingly a decrease of ΔG, with an increase of the electron donating character of X. For mX, a spectroscopic determination of these parameters was not possible. mX46 showed an intermediate behavior, MV compounds with strong electron-donating X, obtained coupling of similar magnitude as pX, which could be explained by means of DFT calculations, with regard to the molecular orbitals.
In the second part of this work, the synthesis of a series of dyads with triarylamine (TAA) as a donor and naphthalene diimide (NDI) as an acceptor was presented. Again, the substitution pattern of the redox centers at the benzene bridging unit was varied in the form of a meta- or para-position (pXNDI or mXNDI) and the energetic position of the bridging unit was varied by X (with X = OMe, Me, Cl, CN, NO2) attached in the 2,5-position. Additionally, compound mOMe46NDI with methoxy substitution in 4,6-position was synthesized. The photophysical and electrochemical properties of these compounds were investigated. The electron transfer (ET) processes of charge separation (CS) and charge recombination (CR) of these were investigated by means of transient absorption (TA) spectroscopy in toluene. This was not possible for the nitro-compounds p-/mNO2NDI, since they decomposed under irradiation. In addition to that, the CR of pXNDI was not detectable by ns-setup, which is why the focus was given to the mXNDI series (with X = OMe–CN).The CS was examined by fs-TA spectroscopy, where the formation of a CS state could be detected. The rise time of the CS states decreases with increasing electron-withdrawing substituents X. CR was examined with ns-TA spectroscopy and shows a biexponential decay behavior, which is caused by singlet-triplet equilibrium in the CS state. By applying an external magnetic field, the decay behavior was decisively changed and the singlet-triplet splitting could be determined. This finding could also be confirmed by simulating the decay curves.
In both parts of this work, the decisive influence of the benzene bridging unit on the appearing ET processes became obvious. For the HT in the ground state of the MV compound, as well as for the ET in the exited states of the DA compounds, the highest transfer rates were found for the para-series pX and pXNDI, and much smaller rates for the meta-series mX and mXNDI. The meta46-compounds mX46 and mOMeNDI46 showed an intermediate behavior in both parts of this work.
Coagulase-negative staphylococci, particularly Staphylococcus epidermidis, have been recognised as an important cause of health care-associated infections due to catheterisation, and livestock-associated infections. The colonisation of indwelling medical devices is achieved by the formation of biofilms, which are large cell-clusters surrounded by an extracellular matrix. This extracellular matrix consists mainly of PIA (polysaccharide intercellular adhesin), which is encoded by the icaADBC-operon. The importance of icaADBC in clinical strains provoking severe infections initiated numerous investigations of this operon and its regulation within the last two decades. The discovery of a long transcript being located next to icaADBC, downstream of the regulator gene icaR, led to the hypothesis of a possible involvement of this transcript in the regulation of biofilm formation (Eckart, 2006). Goal of this work was to characterise this transcript, named ncRNA IcaZ, in molecular detail and to uncover its functional role in S. epidermidis.
The ~400 nt long IcaZ is specific for ica-positive S. epidermidis and is transcribed in early- and mid-exponential growth phase as primary transcript. The promotor sequence and the first nucleotides of icaZ overlap with the 3' UTR of the preceding icaR gene, whereas the terminator sequence is shared by tRNAThr-4, being located convergently to icaZ. Deletion of icaZ resulted in a macroscopic biofilm-negative phenotype with highly diminished PIA-biofilm. Biofilm composition was analysed in vitro by classical crystal violet assays and in vivo by confocal laser scanning microscopy under flow conditions to display biofilm formation in real-time. The mutant showed clear defects in initial adherence and decreased cell-cell adherence, and was therefore not able to form a proper biofilm under flow in contrast to the wildtype. Restoration of PIA upon providing icaZ complementation from plasmids revealed inconsistent results in the various mutant backgrounds.
To uncover the functional role of IcaZ, transcriptomic and proteomic analysis was carried out, providing some hints on candidate targets, but the varying biofilm phenotypes of wildtype and icaZ mutants made it difficult to identify direct IcaZ mRNA targets. Pulse expression of icaZ was then used as direct fishing method and computational target predictions were executed with candidate mRNAs from aforesaid approaches. The combined data of these analyses suggested an involvement of icaR in IcaZ-mediated biofilm control. Therefore, RNA binding assays were established for IcaZ and icaR mRNA. A positive gel shift was maintained with icaR 3' UTR and with 5'/3' icaR mRNA fusion product, whereas no gel shift was obtained with icaA mRNA. From these assays, it was assumed that IcaZ regulates icaR mRNA expression in S. epidermidis. S. aureus instead lacks ncRNA IcaZ and its icaR mRNA was shown to undergo autoregulation under so far unknown circumstances by intra- or intermolecular binding of 5' UTR and 3' UTR (Ruiz de los Mozos et al., 2013). Here, the Shine-Dalgarno sequence is blocked through 5'/3' UTR base pairing and RNase III, an endoribonuclease, degrades icaR mRNA, leading to translational blockade. In this work, icaR mRNA autoregulation was therefore analysed experimentally in S. epidermidis and results showed that this specific autoregulation does not take place in this organism. An involvement of RNase III in the degradation process could not be verified here. GFP-reporter plasmids were generated to visualise the interaction, but have to be improved for further investigations.
In conclusion, IcaZ was found to interact with icaR mRNA, thereby conceivably interfering with translation initiation of repressor IcaR, and thus to promote PIA synthesis and biofilm formation. In addition, the environmental factor ethanol was found to induce icaZ expression, while only weak or no effects were obtained with NaCl and glucose. Ethanol, actually is an ingredient of disinfectants in hospital settings and known as efficient effector for biofilm induction. As biofilm formation on medical devices is a critical factor hampering treatment of S. epidermidis infections in clinical care, the results of this thesis do not only contribute to better understanding of the complex network of biofilm regulation in staphylococci, but may also have practical relevance in the future.
Platelets, small anucleated blood cells responsible for hemostasis, interact at sights of injury with several exposed extracellular matrix (ECM) proteins through specific receptors. Ligand binding leads to activation, adhesion and aggregation of platelets. Already megakaryocytes (MKs), the immediate precursor cells in bone marrow (BM), are in constant contact to these ECM proteins (ECMP). The interaction of ECMP with MKs is, in contrast to platelets, less well understood. It is therefore important to study how MKs interact with sinusoids via the underlying ECMP. This thesis addresses three major topics to elucidate these interactions and their role in platelet biogenesis.
First, we studied the topology of ECMP within BM and their impact on proplatelet formation (PPF) in vitro. By establishing a four-color immunofluorescence microscopy we localized collagens and other ECMP and determined their degree of contact towards vessels and megakaryocytes (MKs). In in vitro assays we could demonstrate that Col I mediates increased MK adhesion, but inhibits PPF by collagen receptor GPVI. By immunoblot analyses we identified that the signaling events underyling this inhibition are different from those in platelet activation at the Src family kinase level.
Second, we determined the degree of MK-ECM interaction in situ using confocal laser scanning microscopy of four-color IF-stained femora and spleen sections. In transgenic mouse models lacking either of the two major collagen receptors we could show that these mice have an impaired association of MKs to collagens in the BM, while the MK count in spleen increased threefold. This might contribute to the overall unaltered platelet counts in collagen receptor-deficient mice.
In a third approach, we studied how the equilibrium of ECMP within BM is altered after irradiation. Collagen type IV and laminin-α5 subunits were selectively degraded at the sinusoids, while the matrix degrading protease MMP9 was upregulated in MKs. Platelet numbers decreased and platelets became hyporesponsive towards agonists, especially those for GPVI activation.
Taken together, the results indicate that MK-ECM interaction differs substantially from the well-known platelet-ECM signaling. Future work should further elucidate how ECMP can be targeted to ameliorate the platelet production and function defects, especially in patients after BM irradiation.
Improved treatment options for the degenerative joint disease osteoarthritis (OA) are of major interest, since OA is one of the main sources of disability, pain, and socioeconomic burden worldwide [202]. According to epidemiological data, already 27 million people suffer from OA in the US [23]. Moreover, the WHO expects OA to be the fourth most common cause of disability in 2020 [203], illustrating the need for effective and long-lasting therapy options of severe cartilage defects. Despite numerous clinically available products for the treatment of cartilage defects [62], the development of more cartilage-specific materials is still at the beginning.
Hyaluronic acid (HA) is a major component of the cartilaginous extracellular matrix (ECM) and inherently creates a cell-friendly niche by providing cell attachment and migration sites. Furthermore, it is known that the functional groups of HA are well suited for chemical modification. These characteristics render HA an attractive material for hydrogel-based tissue engineering approaches. Poly(glycidol) (PG) as chemical crosslinker basically features similar chemical characteristics as the widely used poly(ethylene glycol) (PEG), but provides additional side groups at each repeating unit that can be further chemically functionalized. With the introduction of PG as multifunctional crosslinker for HA gels, a higher cross-linking density and, accordingly, a greater potential for biomimetic functionalization may be achieved. However, despite the mentioned potential benefits, PG has not been used for cartilage regeneration approaches so far.
The initial aim of the study was to set up and optimize a HA-based hydrogel for the chondrogenic differentiation of mesenchymal stromal cells (MSCs), using different amounts and variations of cross-linkers. Therefore, the hydrogel composition was optimized by the utilization of different PEG diacrylate (PEGDA) concentrations to cross-link thiol-modified HA (Glycosil, HA-SH) via Michael addition. We aimed to generate volumestable scaffolds that simultaneously enable a maximum of ECM deposition. Histological and biochemical analysis showed 0.4% PEGDA as the most suitable concentration for these requirements (Section 5.1.2).
In order to evaluate the impact of a differently designed cross-linker on MSC chondrogenesis, HA-SH was cross-linked with PEGTA (0.6%) and compared to PEGDA (0.4%) in a next step. Following this, acrylated PG (PG-Acr) as multifunctional cross-linker alternative to acrylated PEG was evaluated. It provides around five times more functional groups when utilized in PG-Acr (0.6%) HA-SH hydrogels compared to PEGTA (0.6%) HA-SH hydrogels, thus enabling higher degrees of biomimetic functionalization. Determination of cartilage-specific ECM components showed no substantial differences between both cross-linkers while the deposition of cartilaginous matrix appeared more homogeneous in HA-SH PG-Acr gels. Taken together, we were able to successfully increase the possibilities for biomimetic functionalization in the developed HA-SH hydrogel system by the introduction of PG-Acr as cross-linker without negatively affecting MSC chondrogenesis (Section 5.1.3).
The next part of this thesis focused extensively on the biomimetic functionalization of PG-Acr (0.6%) cross-linked HA-SH hydrogels. Here, either biomimetic peptides or a chondrogenic growth factor were covalently bound into the hydrogels.
Interestingly, the incorporation of a N-cadherin mimetic (HAV), a collagen type II binding (KLER), or a cell adhesion-mediating peptide (RGD) yielded no improvement of MSC chondrogenesis. For instance, the covalent binding of 2.5mM HAV changed morphology of cell nuclei and reduced GAG production while the incorporation of 1.0mM RGD impaired collagen production. These findings may be attributed to the already supportive conditions of the employed HA-based hydrogels for chondrogenic differentiation. Most of the previous studies reporting positive peptide effects on chondrogenesis have been carried out in less supportive PEG hydrogels or in significantly stiffer MeHA-based hydrogels [99, 101, 160]. Thus, the incorporation of peptides may be more important under unfavorable conditions while inert gel systems may be useful for studying single peptide effects (Section 5.2.1).
The chondrogenic factor transforming growth factor beta 1 (TGF-b1) served as an example for growth factor binding to PG-Acr. The utilization of covalently bound TGF-b1 may thereby help overcome the need for repeated administration of TGF-b1 in in vivo applications, which may be an advantage for potential clinical application. Thus, the effect of covalently incorporated TGF-b1 was compared to the effect of the same amount of TGF-b1 without covalent binding (100nM TGF-b1) on MSC chondrogenesis. It was successfully demonstrated that covalent incorporation of TGF-b1 had a significant positive effect in a dose-dependent manner. Chondrogenesis of MSCs in hydrogels with covalently bound TGF-b1 showed enhanced levels of chondrogenesis compared to hydrogels into which TGF-b1 was merely mixed, as shown by stronger staining for GAGs, total collagen, aggrecan and collagen type II. Biochemical evaluation of GAG and collagen amounts, as well as Western blot analysis confirmed the histological results. Furthermore, the positive effect of covalently bound TGF-b1 was shown by increased expression of chondrogenic marker genes COL2A1, ACAN and SOX9. In summary, covalent growth factor incorporation utilizing PG-Acr as cross-linker demonstrated significant positive effects on chondrogenic differentiation of MSCs (Section 5.2.2).
In general, PG-Acr cross-linked HA hydrogels generated by Michael addition represent a versatile hydrogel platform due to their high degree of acrylate functionality. These hydrogels may further offer the opportunity to combine several biological modifications, such as the incorporation of biomimetic peptides together with growth factors, within one cell carrier.
A proof-of-principle experiment demonstrated the suitability of pure PG gels for studying single peptide effects. Here, the hydrogels were generated by the utilization of thiol-ene-click reaction. In this setting, without the supportive background of hyaluronic acid, MSCs showed enhanced chondrogenic differentiation in response to the incorporation of 1.0mM HAV. This was demonstrated by staining for GAGs, the cartilage-specific ECM molecules aggrecan and type II collagen, and by increased GAG and total collagen amounts shown by biochemical analysis. Thus, pure PG gels exhibit the potential to study the effects and interplay of peptides and growth factors in a highly modifiable, bioinert hydrogel environment.
The last section of the thesis was carried out as part of the EU project HydroZONES that aims to develop and generate zonal constructs. The importance of zonal organization has attracted increased attention in the last years [127, 128], however, it is still underrepresented in tissue engineering approaches so far. Thus, the feasibility of zonal distribution of cells in a scaffold combining two differently composed hydrogels was investigated. A HA-SH(FMZ) containing bottom layer was generated and a pure PG top layer was subsequently cast on top of it, utilizing both times thiol-ene-click reaction. Indeed, stable, hierarchical constructs were generated that allowed encapsulated MSCs to differentiate chondrogenically in both zones as shown by staining for GAGs and collagen type II, and by quantification of GAG amount. Thus, the feasibility of differently composed zonal hydrogels utilizing PG as a main component was successfully demonstrated (Section 5.4).
With the first-time utilization and evaluation of PG-Acr as versatile multifunctional cross-linker for the preparation of Michael addition-generated HA-SH hydrogels in the context of cartilage tissue engineering, a highly modifiable HA-based hydrogel system was introduced. It may be used in future studies as an easily applicable and versatile toolbox for the generation of biomimetically functionalized hydrogels for cell-based cartilage regeneration. The introduction of reinforcement structures to enhance mechanical resistance may thereby further increase the potential of this system for clinical applications.
Additionally, it was also demonstrated that thiol-ene clickable hydrogels can be used for the generation of cell-laden, pure PG gels or for the generation of more complex, coherent zonal constructs. Furthermore, thiol-ene clickable PG hydrogels have already been further modified and successfully been used in 3D bioprinting experiments [204]. 3D bioprinting, as part of the evolving biofabrication field [205], offers the possibilities to generate complex and hierarchical structures, and to exactly position defined layers, yet at the same time alters the requirements for the utilized hydrogels [159, 206–209]. Since a robust chondrogenesis of MSCs was demonstrated in the thiol-ene clickable hydrogel systems, they may serve as a basis for the development of hydrogels as so called bioinks which may be utilized in more sophisticated biofabrication processes.