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Measles is an extremely contagious vaccine-preventable disease responsible
for more than 90000 deaths worldwide annually. The number of deaths has
declined from 8 million in the pre-vaccination era to few thousands every year due
to the highly efficacious vaccine. However, this effective vaccine is still unreachable
in many developing countries due to lack of infrastructure, while in developed
countries too many people refuse vaccination. Specific antiviral compounds are not
yet available. In the current situation, only an extensive vaccination approach
along with effective antivirals could help to have a measles-free future. To develop
an effective antiviral, detailed knowledge of viral-host interaction is required.
This study was undertaken to understand the interaction between MV and
the innate host restriction factor APOBEC3G (A3G), which is well-known for its
activity against human immunodeficiency virus (HIV). Restriction of MV
replication was not attributed to the cytidine deaminase function of A3G, instead,
we identified a novel role of A3G in regulating cellular gene functions. Among two
of the A3G regulated host factors, we found that REDD1 reduced MV replication,
whereas, KDELR2 hampered MV haemagglutinin (H) surface transport thereby
affecting viral release. REDD1, a negative regulator of mTORC1 signalling
impaired MV replication by inhibiting mTORC1. A3G regulated REDD1
expression was demonstrated to inversely correlate with MV replication. siRNA
mediated silencing of A3G in primary human blood lymphocytes (PBL) reduced
REDD1 levels and simultaneously increased MV titres. Also, direct depletion of
REDD1 improved MV replication in PBL, indicating its role in A3G mediated
restriction of MV. Based on these finding, a new role of rapamycin, a
pharmacological inhibitor of mTORC1, was uncovered in successfully diminishing
MV replication in Vero as well as in human PBL. The ER and Golgi resident
receptor KDELR2 indirectly affected MV by competing with MV-H for cellular
chaperones. Due to the sequestering of chaperones by KDELR2, they can no longer
assist in MV-H folding and subsequent surface expression. Taken together, the two
A3G-regulated host factors REDD1 and KDELR2 are mainly responsible for
mediating its antiviral activity against MV.
Platelets are continuously produced from megakaryocytes (MK) in the bone marrow by a cytoskeleton-driven process of which the molecular regulation is not fully understood.
As revealed in this thesis, MK/ platelet-specific Profilin1 (Pfn1) deficiency results in micro- thrombocytopenia, a hallmark of the Wiskott-Aldrich syndrome (WAS) in humans, due to accelerated platelet turnover and premature platelet release into the bone marrow. Both Pfn1-deficient mouse platelets and platelets isolated from WAS patients contained abnormally organized and hyper-stable microtubules. These results reveal an unexpected function of Pfn1 as a regulator of microtubule organization and point to a previously unrecognized mechanism underlying the platelet formation defect in WAS patients.
In contrast, Twinfilin2a (Twf2a) was established as a central regulator of platelet reactivity and turnover. Twf2a-deficient mice revealed an age-dependent macrothrombocytopenia that could be explained by a markedly decreased platelet half-life, likely due to the pronounced hyper-reactivity of \(Twf2a^{-/-}\) platelets. The latter was characterized by sustained integrin acti- vation and thrombin generation in vitro that translated into accelerated thrombus formation in vivo. To further elucidate mechanisms of integrin activation, Rap1-GTP-interacting adaptor molecule (RIAM)-null mice were generated. Despite the proposed critical role of RIAM for platelet integrin activation, no alterations in this process could be found and it was concluded that RIAM is dispensable for the activation of β1 and β3 integrins, at least in platelets. These findings change the current mechanistic understanding of platelet integrin activation.
Outside-in signaling by integrins and other surface receptors was supposed to regulate MK migration, but also the temporal and spatial formation of proplatelet protrusions. In this the- sis, phospholipase D (PLD) was revealed as critical regulator of actin dynamics and podo- some formation in MKs. Hence, the unaltered platelet counts and production in \(Pld1/2^{-/-}\) mice and the absence of a premature platelet release in the bone marrow of \(Itga2^{-/-}\) mice question the role of podosomes in platelet production and raise the need to reconsider the proposed inhibitory signaling by α2β1 integrins on proplatelet formation.
Non-muscle myosin IIA (NMMIIA) has been implicated as a downstream effector of the in- hibitory signals transmitted via α2β1 integrins. Besides Rho-GTPase signaling, also \(Mg^{2+}\) and transient receptor potential melastatin-like 7 (TRPM7) channel α-kinase are known regulators of NMMIIA activity. In this thesis, TRPM7 was identified as major regulator of \(Mg^{2+}\) homeostasis in MKs and platelets. Furthermore, decreased \([Mg^{2+}]_i\) led to deregulated NMMIIA activity and altered cytoskeletal dynamics that impaired thrombopoiesis and resulted in macrothrombocytopenia in humans and mice.
This work investigates the death and degradation of the second polar body of the nematode C. elegans in order to improve our understanding how pluripotent undifferentiated cells deal with dying cells. With the use of fluorescence microscopy this work demonstrates that both polar bodies loose membrane integrity early. The second polar body has contact to embryonic cells and gets internalized, dependent on the Rac1-ortholog CED-10.
The polar body gets degraded via LC3-associated phagocytosis. While lysosome recruitment depends on RAB-7, LC3 does not improve lysosome recruitment but still accelerates polar body degradation.
This work establishes the second polar body as a genetic model to study cell death and LC3-associated phagocytosis and has revealed further aspects of phagosome maturation and degradation.
Adipocytes are specialized cells found in vertebrates to ensure survival in terms of adaption to food deficit and abundance. However, their dysfunction accounts for the pathophysiology of metabolic diseases such as T2DM. Preliminary data generated by Mona Löffler suggested that PKD1 is involved in adipocyte function. Here, I show that PKD1 expression and activity is linked to lipid metabolism of murine adipocytes. PKD1 gene expression and activity was reduced in murine white adipose tissue upon fasting, a physiological condition which induces lipolysis. Isoproterenol-stimulated lipolysis in adipose tissue and 3T3-L1 adipocytes reduced PKD1 gene expression. Silencing ATGL in adipocytes inhibited isoproterenol-stimulated lipolysis, however, the β-adrenergic
stimulation of ATGL-silenced adipocytes lowered PKD1 expression levels as well. Adipose tissue of obese mice exhibited high PKD1 RNA levels but paradoxically lower protein levels of phosphorylated PKD1-Ser916. However, HFD generated a second
PKD1 protein product of low molecular weight in mouse adipose tissue. Furthermore, constitutively active PKD1 predominantly displayed nuclear localization in 3T3-L1 adipocytes containing many fat vacuoles. However, adipocytes
overexpressing non-functional PKD1 contained fewer lipid droplets and PKD1-KD was distributed in cytoplasm. Most importantly, deficiency of PKD1 in mouse adipose tissue caused expression of genes involved in adaptive thermogenesis such as UCP-1 and thus generated brown-like phenotype adipocytes. Thus, PKD1 is implicated in adipose tissue function and presents an interesting target for therapeutic approaches in the prevention of obesity and associated diseases.
In mammals, KSR1 functions as an essential scaffold that coordinates the assembly of RAF/MEK/ERK complexes and regulates intracellular signal transduction upon extracellular stimulation. Aberrant activation of the equivalent MAPK signaling pathway has been implicated in multiple human cancers and some developmental disorders. The mechanism of KSR1 regulation is highly complex and involves several phosphorylation/dephosphorylation steps. In the present study, a number of novel in vivo phosphorylation sites were detected in mKSR1 by use of mass spectrometry analysis. Among others, Tyr728 was identified as a unique regulatory residue phosphorylated by LCK, a Src kinase family member. To understand how phosphorylation of Tyr728 may regulate the function of KSR1 in signal transduction and cellular processes, structural modeling and biochemical studies were integrated in this work.
Computational modeling of the mKSR1(KD) protein structure revealed strong hydrogen bonding between phospho-Tyr728 and the residues surrounding Arg649. Remarkably, this pattern was altered when Tyr728 was non-phosphorylated or substituted. As confirmed by biochemical analysis, Arg649 may serve as a major anchor point for phospho-Tyr728 in order to stabilize internal structures of KSR1. In line with the protein modeling results, mutational studies revealed that substitution of Tyr728 by phenylalanine leads to a less compact interaction between KSR1 and MEK, a facilitated KSR1/B-RAF binding and an increased phosphorylation of MEK in complex with KSR1. From these findings it can be concluded that phospho-Tyr728 is involved in tightening the KSR1/MEK interaction interface and in regulating the phosphorylation of KSR1-bound MEK by either RAF or KSR1 kinases.
Beside the Tyr728, Ser722 was identified as a novel regulatory phosphorylation site. Amino acid exchanges at the relevant position demonstrated that Ser722 regulates KSR1-bound MEK phosphorylation without affecting KSR1/MEK binding per se. Due to its localization, Ser722 might consequently control the catalytic activity of KSR1 by interfering with the access of substrate (possibly MEK) to the active site of KSR1 kinase. Together with Ser722, phosphorylated Tyr728 may further positively affect the kinase activity of KSR1 as a consequence of its vicinity to the activation and catalytic loop in the KSR1(KD). As revealed by structural modeling, phospho-Tyr728 builds a hydrogen bond with the highly conserved Lys685. Consequently, phospho-Tyr728 has a stabilizing effect on internal structures involved in the catalytic reaction and possibly enhances the phosphate transfer within the catalytic cleft in KSR1. Considering these facts, it seems very likely that the LCK-dependent phosphorylation of Tyr728 plays a crucial role in the regulation of KSR1 catalytic activity.
Results of fractionation and morphology analyses revealed that KSR1 recruits LCK to cytoskeleton for its phosphorylation at Tyr728 suggesting that this residue may regulate cytoskeleton dynamics and, consequently, cell motility. Beside that, phosphorylation of Tyr728 is involved in the regulation of cell proliferation, as shown by a significantly reduced population doubling time of KSR1-Y728F cells compared to cells expressing wild type KSR1.
Taken together, tyrosine phosphorylation in KSR1 uncovers a new link between Src family kinases and MAPK signaling. Tyr728, the novel regulatory phosphorylation site in murine KSR1, may coordinate the transition between the scaffolding and the catalytic function of KSR1 serving as a control point used to fine-tune cellular responses.
Mammalian haloacid dehalogenase (HAD)-type phosphatases are an emerging family of enzymes with important functions in physiology and disease. HAD phosphatases can target diverse metabolites, lipids, DNA, and serine/threonine or tyrosine phosphorylated proteins with often high specificity (Seifried et al., 2013). These enzymes thus markedly enlarge the repertoire and substrate spectrum of mammalian phosphatases. However, the basis of HAD phosphatase substrate specificity is still elusive and a number of mammalian HAD phosphatases remain uncharacterized to date. This study characterizes the biochemical and structural properties of AUM (aspartate-based, ubiquitous, Mg2+-dependent phosphatase), a previously unexplored mammalian HAD phosphatase.
In vitro phosphatase assays of purified, recombinant AUM showed phosphatase activity towards para-nitrophenyl phosphate and adenine and guanine nucleotide di- and triphosphates. Inhibitor studies indicated that similar to other HAD superfamily members, the AUM-catalyzed dephosphorylation reaction proceeds via a pentacovalent phosphoaspartate intermediate. In line with an aspartate-based catalytic mechanism, AUM was insensitive to inhibitors of serine/threonine phosphatases. The characterization of the purified recombinant murine enzyme also revealed that AUM exists in equilibrium between dimers and tetramers.
AUM was identified as the closest, yet functionally distinct relative of chronophin, a pyridoxal 5’-phosphate and serine/threonine-directed phosphatase. Phylogenetic analyses showed that AUM and chronophin evolved via duplication of an ancestral gene at the origin of the vertebrates. In contrast to chronophin, AUM acts as a tyrosine-specific HAD-type phosphatase in vitro and in cells. To elucidate how AUM and chronophin achieve these distinct substrate preferences, comparative evolutionary analyses, biochemical approaches and structural analyses were combined. Swapping experiments of less homologous regions between AUM and chronophin were performed. The mutational analysis revealed residues important for AUM catalysis and specificity. A single differently conserved residue in the cap domain of AUM or chronophin is crucial for phosphatase specificity (AUML204, chronophinH182). The X-ray crystal structure of the AUM cap fused to the catalytic core of chronophin (CAC, PDB: 4BKM) was solved to 2.65 Å resolution. It presents the first crystal structure of the murine AUM capping domain. The detailed view of the catalytic clefts of AUM and chronophin reveals the structural basis of the divergent substrate specificities. These presented findings provide insights into the design principles of capped HAD phosphatases and show that their substrate specificity can be encoded by a small number of predictable residues. In addition, the catalytic properties of AUM were investigated, identifying a mechanism of reversible oxidation regulating the activity of AUM in vitro. AUM phosphatase activity is inhibited by oxidation and can be recovered by reduction. The underlying molecular mechanism was revealed by mutational analyses. The cysteines C35, C104 and C243, located in the AUM core domain, are responsible for the inhibition of AUM by oxidation. C293 mediates the redox-dependent tetramerization of AUM in vitro. Based on the chronophin and CAC structure, a direct impact of the oxidation of C35 on the nucleophile D34 is proposed. In addition, a redox-dependent disulfide bridge (C104, C243), connecting the core and cap domain of AUM may be important for an open/close-mechanism. This hypothesis is supported by CD spectroscopy experiments that demonstrate a structural change in AUM upon reduction. These data present the first evidence for the regulation of AUM catalysis by reversible oxidation. This finding is so far unique in the field of HAD phosphatases.
In this context, the first cell-based AUM activity assay was developed. For this, the artificial substrate pNPP was combined with the reducing agent DTT to create a specific AUM activity readout. This fractionation-based assay is the first tool to differentiate between cell lines or tissues with different AUM concentrations or activities.
Taken together, the presented biochemical characterization reveals the specificity determinants and catalytic properties of AUM. General insights into structural determinants of mammalian HAD phosphatase substrate recognition are provided and reversible oxidation as possible regulatory mechanism for AUM is proposed. These findings constitute a framework for further functional analyses to elucidate the biomedical importance of AUM.
Mammalian haloacid dehalogenase (HAD)-type phosphatases are a large and ubiquitous family of at least 40 human members. Many of them have important physiological functions, such as the regulation of intermediary metabolism and the modulation of enzyme activities, yet they are also linked to diseases such as cardiovascular or metabolic disorders and cancer.
Still, most of the mammalian HAD phosphatases remain functionally uncharacterized.
This thesis reveals novel cell biological and physiological functions of the phosphoglycolate phosphatase PGP, also referred to as AUM. To this end, PGP was functionally characterized by performing analyses using purified recombinant proteins to investigate potential protein substrates of PGP, cell biological studies using the spermatogonial cell line GC1, primary mouse lung endothelial cells and lymphocytes, and a range of biochemical techniques to characterize Pgp-deficient mouse embryos.
To characterize the cell biological functions of PGP, its role downstream of RTK- and integrin signaling in the regulation of cell migration was investigated. It was shown that PGP inactivation elevates integrin- and RTK-induced circular dorsal ruffle (CDR) formation, cell spreading and cell migration. Furthermore, PGP was identified as a negative regulator of directed lymphocyte migration upon integrin- and GPCR activation.
The underlying mechanisms were analyzed further. It was demonstrated that PGP regulates CDR formation and cell migration in a PLC- and PKC-dependent manner, and that Src family kinase activities are required for the observed cellular effects. Upon integrin- and RTK activation, phosphorylation levels of tyrosine residues 1068 and 1173 of the EGF receptor were elevated and PLCγ1 was hyper-activated in PGP-deficient cells. Additionally, PGP-inactivated lymphocytes displayed elevated PKC activity, and PKC-mediated cytoskeletal remodeling was accelerated upon loss of PGP activity. Untargeted lipidomic analyses revealed that the membrane lipid phosphatidylserine (PS) was highly upregulated in PGP-depleted cells.
These data are consistent with the hypothesis that the accumulation of PS in the plasma membrane leads to a pre-assembly of signaling molecules such as PLCγ1 or PKCs that couple the activation of integrins, EGF receptors and GPCRs to accelerated cytoskeletal remodeling.
Thus, this thesis shows that PGP can affect cell spreading and cell migration by acting as a PG-directed phosphatase.
To understand the physiological functions of PGP, conditionally PGP-inactivated mice were analyzed. Whole-body PGP inactivation led to an intrauterine growth defect with developmental delay after E8.5, resulting in a gradual deterioration and death of PgpDN/DN embryos between E9.5 and E11.5. However, embryonic lethality upon whole-body PGP inactivation was not caused by a primary defect of the (cardio-) vascular system. Rather, PGP inactivated embryos died during the intrauterine transition from hypoxic to normoxic conditions.
Therefore, the potential impact of oxygen on PGP-dependent cell proliferation was investigated. Analyses of mouse embryonic fibroblasts (MEFs) generated from E8.5 embryos and GC1 cells cultured under normoxic and hypoxic conditions revealed that normoxia (~20% O2) causes a proliferation defect in PGP-inactivated cells, which can be rescued under
hypoxic (~1% O2) conditions. Mechanistically, it was found that the activity of triosephosphate isomerase (TPI), an enzyme previously described to be inhibited by phosphoglycolate (PG) in vitro, was attenuated in PGP-inactivated cells and embryos. TPI constitutes a critical branch point between carbohydrate- and lipid metabolism because it catalyzes the isomerization of the glycolytic intermediates dihydroxyacetone phosphate (DHAP, a precursor of the glycerol backbone required for triglyceride biosynthesis) and glyceraldehyde 3’-phosphate (GADP).
Attenuation of TPI activity, likely explains the observed elevation of glycerol 3-phosphate levels and the increased TG biosynthesis (lipogenesis). Analyses of ATP levels and oxygen consumption rates (OCR) showed that mitochondrial respiration rates and ATP production were elevated in PGP-deficient cells in a lipolysis-dependent manner. However under hypoxic conditions (which corrected the impaired proliferation of PGP-inactivated cells), OCR and ATP production was indistinguishable between PGP-deficient and PGP-proficient cells. We therefore propose that the inhibition of TPI activity by PG accumulation due to loss of PGP activity shifts cellular bioenergetics from a pro-proliferative, glycolytic metabolism to a lipogenetic/lipolytic metabolism.
Taken together, PGP acts as a metabolic phosphatase involved in the regulation of cell migration, cell proliferation and cellular bioenergetics. This thesis constitutes the basis for further studies of the interfaces between these processes, and also suggests functions of PGP for glucose and lipid metabolism in the adult organism.
Abstract
Glioblastomas, primary brain tumors, represent a tumor entity with a dismal prognosis and a median survival of only about one year. Invasion into the healthy brain parenchyma contributes substantially to the malignancy of this type of brain tumor. Therefore, a better understanding of the mechanisms promoting the invasive behavior of these brain tumors is needed to identify new therapeutic targets.
Cofilin, an actin regulatory protein, has been shown to be an important regulator of the invasive behavior of tumor cells in other types of cancer and the actin cytoskeleton is involved in the formation of a variety of cellular structures important for cell migration and invasion. Cofilin is regulated by phosphorylation on a single residue, serine 3. The aim of this thesis was to examine the role of the cofilin regulatory phosphatase chronophin for glioma cell migration and invasion.
First, it was established that chronophin depletion in the cell line GBM6840 leads to an increase in the ratio of phosphorylated cofilin to total cofilin. Higher chronophin levels were correlated with a decrease in F-actin in the cell lines GBM6840 and U87 as measured in an actin spin down assay and in a flow cytometry based assay.
Furthermore, it was shown that knockdown of chronophin in two different cell lines, GBM6840 and DBTRG-05-MG, strongly increased their invasiveness in vitro. Expression of human chronophin in the cell line U87 decreased its invasiveness substantially. There was no difference in cell proliferation between GBM6840 and DBTRG-05-MG cells expressing a chronophin targeting shRNA or a control shRNA and U87 cells transfected with an empty vector or a human chronophin encoding plasmid. The increase in invasiveness after chronophin depletion could be correlated with an increase in directionality in cell migration under 2D culture conditions in the cell lines U87 and GBM6840. Moreover, treatment with the ROCK inhibitor Y-27632 decreased directionality in GBM6840 cells under 2D culture conditions and reduced the invasiveness of GBM6840 chronophin shRNA cells back to control levels.
Expression of a non-phosphorylatable cofilin mutant, the S3A mutant, was able to reduce invasiveness and to reduce directionality under 2D culture conditions back to control levels in GBM6840 chronophin shRNA cells.
This provides important evidence for the involvement of cofilin phosphoregulation in the phenotypes described above.
In vivo, when injected into NOD-SCID mice, chronophin depleted cells showed a dramatic growth reduction as compared to control and rescue cells.
Transciptomic characterization of GBM6840 cells by microarray analysis and subsequent comparison of the data with microarray profiles of normal brain tissues and different glioma entities identified two specifically chronophin regulated transcripts potentially involved in tumor progression and invasion, MXI1 and EDIL3. Moreover, c-myc was identified as a significantly altered transcription factor after chronophin deregulation based on the number of c-myc target molecules in the microarray dataset.
MXI1 is a potential negative regulator of c-myc dependent transcription, and was strongly downregulated after chronophin knockdown in GBM6840. In line with this, the activity of a c-myc reporter plasmid was increased after chronophin depletion in GBM6840 and reduced after chronophin expression in U87 cells.
However, the protein level of the c-myc protein was reduced after chronophin depletion in GBM6840.
Finally, anaylsis of the expression of proteases known to be important for glioblastoma pathogenesis revealed no major changes in protease expression between chronophin depleted and control cells.
Therefore, a comprehensive analysis of chronophin in the context of glioma pathogenesis has been performed in this thesis. It has been shown that chronophin depletion strongly enhanced invasiveness of glioma cells and that it induced transcriptomic changes potentially involved in tumor progression. The proteins regulating cofilin phosphorylation are therefore valuable therapeutic targets for anti-invasive therapy in glioblastomas. Inhibitors for kinases upstream of cofilin, e.g. LIMKs and ROCKs, are available, and might be promising agents for anti-invasive therapy.
Platelet activation and aggregation at sites of vascular injury involves massive cytoskeletal re-organization, which is required for proper platelet function. Moreover, the cytoskeleton plays central roles in megakaryo- and thrombopoiesis. Thus, cytoskeletal protein aberrations can be the underlying reason for many pathological phenotypes. Although intensive research is carried out to identify the key players involved in cytoskeletal reorganization, the signaling cascades orchestrating these complex processes are still poorly understood. This thesis investigates the role of three actin-binding proteins, Coactosin-like (Cotl) 1, Profilin (Pfn) 1 and Thymosin (T) β4, in platelet formation and function using genetically modified mice.
ADF-H-containing proteins such as Twinfilin or Cofilin are well characterized as regulators of thrombopoesis and cytoskeletal reorganization. Although Cotl1 belongs to the ADF-H protein family, lack of Cotl1 did not affect platelet count or cytoskeletal dynamics. However, Cotl1-deficiency resulted in significant protection from arterial thrombus formation and ischemic stroke in vivo. Defective GPIb-vWF interactions and altered second wave mediator release present potential reasons for the beneficial effect of Cotl1-deficiency. These results reveal an unexpected function of Cotl1 as a regulator of thrombosis and hemostasis, establishing it as a potential target for a safe therapeutic therapy to prevent arterial thrombosis or ischemic stroke.
Recent studies showed that the organization of the circumferential actin cytoskeleton modulates calpain-mediated αIIbβ3 integrin closure, thereby also controlling αIIbβ3 integrin localization. The second part of this thesis identified the actin-sequestering protein Pfn1 as a central regulator of platelet integrin function as Pfn1-deficient platelets displayed almost abolished αIIbβ3 integrin signaling. This translated into a profound protection from arterial thrombus formation and prolonged tail bleeding times in vivo which was caused by enhanced calpain-dependent integrin closure. These findings further emphasize the importance of a functional actin cytoskeleton for intact platelet function in vitro and in vivo.
Tβ4 is a moonlighting protein, acting as one of the major actin-sequestering proteins in cells of higher eukaryotes and exerting various paracrine functions including anti-inflammatory, immunomodulatory and pro-angiogenic effects. Although excessively studied, its role for cytoskeletal dynamics, the distinction between endo- and exogenous protein function and its uptake and release mechanisms are still poorly understood. Constitutive Tβ4-deficiency resulted in thrombocytopenia accompanied by a largely diminished G-actin pool in platelets and divergent effects on platelet reactivity. Pre-incubation of platelets with recombinant Tβ4 will help to understand the function of endo- and exogenous protein, which is under current investigation.
Protein kinase D1 deletion in adipocytes enhances energy dissipation and protects against adiposity
(2019)
Adaptation to alterations in nutrient availability ensures the survival of organisms. In vertebrates, adipocytes play a decisive role in this process due to their ability to store large amounts of excess nutrients and release them in times of food deprivation. In todays western world, a rather unlimited excess of nutrients leads to high-caloric food consumption in humans. Nutrient overload together with a decreased energy dissipation result in obesity as well as associated diseases such as insulin resistance, diabetes, and liver steatosis. Obesity causes a hormonal imbalance, which in combination with altered nutrient levels can aberrantly activate G-protein coupled receptors utilizing diacylglycerol (DAG) as secondary messenger. Protein kinase D (PKD) 1 is a DAG effector integrating multiple hormonal and nutritional inputs. Nevertheless, its physiological role in adipocytes has not been investigated so far. In this thesis, evidence is provided that the deletion of PKD1 in adipocytes suppresses lipogenesis as well as the accumulation of triglycerides. Furthermore, PKD1 depletion results in increased mitochondrial biogenesis as well as decoupling activity. Moreover, PKD1 deletion promotes the expression of the β3-adrenergic receptor (ADRB3) in a CCAAT/enhancer-binding protein (C/EBP)-α and δ-dependent manner. This results in elevated expression levels of beige markers in adipocytes in the presence of a β-agonist. Contrarily, adipocytes expressing a constitutive active form of PKD1 present a reversed phenotype. Additionally, PKD1 regulates adipocyte metabolism in an AMP-activated protein kinase (AMPK)-dependent manner by suppressing its activity through phosphorylation of AMPK α1/α2 subunits. Thus, PKD1 deletion results in an enhanced activity of the AMPK complex. Consistent with the in vitro findings, mice lacking PKD1 in adipocytes demonstrate a resistance to high-fat diet-induced obesity due to an elevated energy expenditure caused by trans-differentiation of white into beige adipocytes. Moreover, deletion of PKD1 in murine adipocytes improves systemic insulin sensitivity and ameliorates liver steatosis. Finally, PKD1 levels positively correlate with HOMA-IR as well as insulin levels in human subjects. Furthermore, inhibition of PKD1 in human adipocytes leads to metabolic alterations, which are comparable to the alterations seen in their murine counterparts. Taken together, these data demonstrate that PKD1 suppresses energy dissipation, drives lipogenesis, and adiposity. Therefore, increased energy dissipation induced by several complementary mechanisms upon PKD1 deletion might represent an attractive strategy to treat obesity and its related complications.
The haloacid dehalogenase (HAD) family of phosphatases is an ancient, ubiquitous group of enzymes, and their emerging role in human health and disease make them attractive targets for detailed analyses.
This thesis comprises the biochemical and structural characterization of chronophin, an HAD-type
phosphatase, which has been shown to act on Ser3-phosphorylated cofiln-1, a key regulator of actin dynamics, and on the Ser/Thr-phosphorylated steroid receptor co-activator 3 (SRC-3). Besides being a specific phosphoprotein phosphatase, chronophin also acts on the small molecule pyridoxal 5'-phosphate (PLP, vitamin B6), implying that chronophin serves as a regulator of a variety important physiological pathways. The analysis of chronophin was performed on different levels, ranging from intrinsic regulatory mechanisms, such as the allosteric regulation via dimerization or the characterization of specificity determinants, to modes of extrinsic modulation, including the association with putative interacting proteins or the generation of chronophin-specific inhibitors.
The association of the previously identified putative chronophin interactors calcium- and integrinbinding protein 1 (CIB1) and calmodulin was investigated using recombinantly expressed and purified proteins. These studies revealed that the interaction of chronophin with CIB1 or calmodulin is mutually exclusive and regulated by calcium. Neither CIB1 nor calmodulin had an effect on the in vitro chronophin phosphatase activity towards PLP or phospho-cofilin-1, but might regulate other functions of this important phosphatase.
The role of chronophin dimerization was studied by generating a constitutively monomeric variant,
which showed reduced PLP hydrolyzing activity. X-ray crystallographic studies revealed that dimerization is essential for the positioning of the substrate specificity loop in chronophin, unraveling a previously unknown mechanism of allosteric regulation through a homophilic interaction. This mechanism potentially applies to other enzymes of the C2a subfamily of HAD-type phosphatases, as all structurally characterized members show a conserved mode of dimerization.
The general determinants of substrate specificity in the C2a subfamily of HAD phosphatases were
investigated by performing domain swapping experiments with chronophin and its paralog AUM and
subsequent biochemical analyses of the hybrid proteins. The X-ray crystallographic structure
determination of the chronophin catalytic domain equipped with the AUM capping domain revealed the first partial structure of AUM. This structural information was then used in subsequent studies that analyzed the divergent substrate specificities of AUM and chronophin in an evolutionary context.
Finally, a set of four chronophin inhibitors were generated based on the structure of PLP and
characterized biochemically, showing moderate inhibitory effects with IC50-values in the micromolar range. These compounds nevertheless constitute valuable tools for future in vitro experiments, such as studies concerning the structure-function relationship of chronophin as a PLP phosphatase. In addition, the crystal structure of one inhibitor bound to chronophin could be solved. These results provide the basis for the further development of competitive chronophin inhibitors with increased specificity and potency.
The pancreas is the key organ for the maintenance of euglycemia. This is regulated in particular by α-cell-derived glucagon and β-cell-derived insulin, which are released in response to nutrient deficiency and elevated glucose levels, respectively. Although glucose is the main regulator of insulin secretion, it is significantly enhanced by various potentiators.
Platelets are anucleate cell fragments in the bloodstream that are essential for hemostasis to prevent and stop bleeding events. Besides their classical role, platelets were implemented to be crucial for other physiological and pathophysiological processes, such as cancer progression, immune defense, and angiogenesis. Platelets from diabetic patients often present increased reactivity and basal activation. Interestingly, platelets store and release several substances that have been reported to potentiate insulin secretion by β-cells. For these reasons, the impact of platelets on β-cell functioning was investigated in this thesis.
Here it was shown that both glucose and a β-cell-derived substance/s promote platelet activation and binding to collagen. Additionally, platelet adhesion specifically to the microvasculature of pancreatic islets was revealed, supporting the hypothesis of their influence on glucose homeostasis. Genetic or pharmacological ablation of platelet functioning and platelet depletion consistently resulted in reduced insulin secretion and associated glucose intolerance. Further, the platelet-derived lipid fraction was found to enhance glucose-stimulated insulin secretion, with 20-hydroxyeicosatetraenoic acid (20-HETE) and possibly also lyso-precursor of platelet-activating factor (lysoPAF) being identified as crucial factors. However, the acute platelet-stimulated insulin secretion was found to decline with age, as did the levels of platelet-derived 20-HETE. In addition to their direct stimulatory effect on insulin secretion, specific defects in platelet activation have also been shown to affect glucose homeostasis by potentially influencing islet vascular development. Taking together, the results of this thesis suggest a direct and indirect mechanism of platelets in the regulation of insulin secretion that ensures glucose homeostasis, especially in young individuals.
Abscission marks the last step of cytokinesis and gives rise to two physically separated daughter cells and a midbody remnant. This work studies abscission by examining the extent of the abscission failure in C. elegans septin and ESCRT mutants with the help of the ZF1-degradation technique. The ZF1 technique is also applied to discern a possible role for PI3K during abscission. Lastly, we test the role of proteins required for macroautophagy but not for LC3-associated phagocytosis (LAP) and show that after release into the extracellular space, the midbody is resolved via LAP.
Platelet activation and aggregation at sites of vascular injury is critical to prevent excessive blood loss, but may also lead to life-threatening ischemic diseases, such as myocardial infarction and stroke. Extracellular agonists induce platelet activation by stimulation of platelet membrane receptors. Signal transduction results in reorganization of the cytoskeleton, shape change, platelet adhesion and aggregation, cumulating in thrombus formation. Several Rho GTPases, including Rac1, Cdc42 and RhoA, are essential mediators of subsequent intracellular transduction of ITAM- and GPCR-signaling. Therefore, inhibition or knockout can result in severely defective platelet signaling.
Mice with platelet specific Rac1-deficiency are protected from arterial thrombosis. This benefit highlights further investigation of Rac1-specific functions and its potential as a new pharmacological target for prevention of cardiovascular diseases. Two newly developed synthetic compounds, NSC23766 and EHT1864, were proposed to provide highly specific inhibition of Rac1 activity, but both drugs have never been tested in Rac1-deficient cell systems to rule out potential Rac1-independent effects.
This study revealed significant off-target effects of NSC23766 and EHT1864 that occurred in a dose-dependent fashion in both wild-type and Rac1-deficient platelets. Both inhibitors individually affected resting platelets after treatment, either by altering membrane protein expression (NSC23766) or by a marked decrease of platelet viability (EHT1864). Platelet apoptosis could be confirmed by enhanced levels of phosphatidylserine exposure and decreased mitochondrial membrane potential. Phosphorylation studies of the major effector proteins of Rac1 revealed that NSC23766 and EHT1864 abolish PAK1/PAK2 activation independently of Rac1 in wild-type and knockout platelets, which may contribute to the observed off-target effects.
Additionally, this study demonstrated the involvement of Rac1 in G protein-coupled receptor-mediated platelet activation and GPIb-induced signaling. Furthermore, the data revealed that Rac1 is dispensable in the process of integrin IIb 3-mediated clot retraction.
This study unveiled that new pharmacological approaches in antithrombotic therapy with Rac1 as molecular target have to be designed carefully in order to obtain high specificity and minimize potential off-target effects.
Functional analysis of polarization and podosome formation of murine and human megakaryocytes
(2019)
In mammals, blood platelets are produced by large bone marrow (BM) precursor cells, megakaryocytes (MK) that extend polarized cell protrusions (proplateles) into BM sinusoids. Proplatelet formation (PPF) requires substantial cytoskeletal rearrangements that have been shown to involve the formation of podosomes, filamentous actin (F-actin) and integrin-rich structures. However, the exact molecular mechanisms regulating MK podosome formation, polarization and migration within the BM are poorly defined. According to current knowledge obtained from studies with other cell types, these processes are regulated by Rho GTPase proteins like RhoA and Cdc42.
In this thesis, polarization and podosome formation were investigated in MKs from genetically modified mice, as well as the cell lines K562 and Meg01 by pharmacological modulation of signaling pathways.
The first part of this thesis describes establishment of the basic assays for investigation of MK polarization. Initial data on polarization of the MK-like erythroleukemia cell line K562 revealed first insights into actin and tubulin dynamics of wild type (WT) and RhoA knock-out (RhoA-/-) K562 cells. Phorbol 12-myristate 13-acetate (PMA)-induction of K562 cells led to the expected MK-receptor upregulation but also RhoA depletion and altered polarization patterns.
The second part of this thesis focuses on podosome formation of MKs. RhoA is shown to be dispensable for podosome formation. Cdc42 is revealed as an important, but not essential regulator of MK spreading and podosome formation. Studies of signaling pathways of podosome formation reveal the importance of the tyrosine kinases Src, Syk, as well as glycoprotein (GP)VI in MK spreading and podosome formation.
This thesis provides novel insights into the mechanisms underlying polarization and podosome formation of MKs and reveals new, important information about cytoskeletal dynamics of MKs and potentially also platelets.
Mammalian phoshoglycolate phosphatase (PGP, also known as AUM) belongs to the ubiquitous HAD superfamily of phosphatases. As several other members of HAD phosphatases, the Mg2+-dependent dephosphorylation is conducted via a nucleophilic attack from a conserved aspartate residue in the catalytic cleft. The protein structure of PGP could not yet be solved entirely. Only a hybrid consisting of the PGP cap and the PDXP core (pyridoxal phosphatase, closest enzyme paralog) was crystallizable so far. PGP is able to efficiently dephosphorylate 2-phosphoglycolate, 2-phospho-L-lactate, 4-phospho-D-erythronate, and glycerol-3-phosphate in vitro which makes them likely physiological substrates. The first three substrates can be derived from metabolic side reactions (during glycolysis) and inhibit key enzymes in glycolysis and pentose phosphate pathway, the latter is situated at the intersection between glycolysis and lipogenesis. 2-phosphoglycolate can also be released in the context of repair of oxidative DNA damage. The activity of purified PGP can be reversibly inhibited by oxidation - physiologically likely in association with epidermal growth factor (EGF) signal transduction. In fact, an association between persistently lacking PGP activity (via downregulation) and the presence of hyperphosphorylated proteins after EGF stimulation has been identified. Reversible oxidation and transient inactivation of PGP may be particularly important for short-term and feedback regulatory mechanisms (as part of the EGF signaling). Furthermore, cellular proliferation in PGP downregulated cells is constantly reduced. Whole-body PGP inactivation in mice is embryonically lethal. Despite the many well-known features and functions, the knowledge about PGP is still incomplete.
In the present work the influence of reactive oxygen species (ROS) on PGP activity in cells und a possible connection between oxidative stress and the proliferation deficit of PGP downregulated cells was investigated. For the experiments, a spermatogonial cell line was used (due to the high PGP expression in testis). PGP activity can be reversibly inhibited in cellular lysates by H2O2 (as a ROS representative). Reversible oxidation could thus indeed be physiologically important. More oxidative DNA damage (by bleomycin) showed no PGP-dependent effects here. EGF stimulation (as an inducer of transient and well-controlled ROS production), low concentrations of menadione (as an oxidant) and N-acetylcysteine (as an antioxidant) were able to approximate the proliferation rate in PGP downregulated cells to that of control cells. The redox regulation of PGP could thus have an influence on cellular proliferation as a feedback mechanism - a mechanism that could not take place in PGP downregulated cells. However, the connections are probably even more complex and cannot be elucidated by a sole examination of the proliferation rate. The present results can thus only be regarded as preliminary experiments.
For a better understanding of the features and functions of PGP, this work then focused on specific regulation of enzyme activity by pharmacologically applicable small molecules. Four potent inhibitors had previously been identified in a screening campaign. In this work, three of these four inhibiting compounds could be further characterized in experiments with highly purified, recombinant murine and human PGP. Compounds #2 and #9 showed competitive inhibition properties with a markedly rising KM value with little or no change in vmax. The results were consistent for all tested protein variants: the murine and the human PGP as well as a PGP/PDXP hybrid protein. Compound #1 was the most potent and interesting PGP-inhibitory molecule: less change in KM and a constant decrease in vmax as well as a lower impact on the PGP/PDXP hybrid hint at a mixed mode of inhibition as a combination of competitive and non-competitive inhibition. The characterization of the potential inhibitors can serve as a basis for further structural analysis and studies on the complex physiological role of PGP.
Identification and characterization of TAT-5 interactors that regulate extracellular vesicle budding
(2021)
Cells from bacteria to man release extracellular vesicles (EV) such as microvesicles (MV) that carry signaling molecules like morphogens and miRNAs to control intercellular communication during health and disease. MV release also sculpts membranes, e.g. repairing damaged membranes to avoid cell death. HIV viruses also bud from the plasma membrane in a similar fashion. In order to determine the in vivo functions of MVs and regulate their release, we need to understand the mechanisms of MV release by plasma membrane budding (ectocytosis).
The conserved phospholipid flippase TAT-5 maintains the asymmetric localization of phosphatidylethanolamine (PE) in the plasma membrane and was the only known inhibitor of ESCRT-mediated ectocytosis in C. elegans. Loss of TAT-5 lipid flipping activity increased the externalization of PE and accumulation of MVs. However, it was unclear how cells control TAT-5 activity to release the right amount of MVs at the right time, since no upstream regulators of TAT-5 were known.
To identify conserved TAT-5 regulators we looked for new proteins that inhibit MV release. To do so, we first developed a degradation-based technique to specifically label MVs. We tagged a plasma membrane reporter with the endogenous ZF1 degradation tag (degron) and expressed it in C. elegans embryos. This reporter is protected from degradation inside MVs, but is degraded inside the cell. Thus, the fluorescence is selectively maintained inside MVs, creating the first MV-specific reporter. We identified four MV release inhibitors associated with retrograde recycling, including the class III PI3Kinase VPS-34, Beclin1 homolog BEC-1, DnaJ protein RME-8, and the uncharacterized Dopey homolog PAD-1. We found that VPS-34, BEC-1, RME-8, and redundant sorting nexins are required for the plasma membrane localization of TAT-5, which is important to maintain PE asymmetry and inhibit MV release. Although we confirmed that PAD-1 and the GEF-like protein MON-2 are required for endosomal recycling, they only traffic TAT-5 in the absence of sorting nexin-mediated recycling. Instead, PAD-1 is specifically required for the lipid flipping activity of TAT-5 that inhibits MV release.
Thus, our work pinpoints TAT-5 and PE as key regulators of plasma membrane budding, further supporting the model that PE externalization drives ectocytosis. In addition, we uncovered redundant intracellular trafficking pathways, which affect organelle size and revealed new regulators of TAT-5 flippase activity. These newly identified ectocytosis inhibitors provide a toolkit to test the in vivo roles of MVs. In the long term, our work will help to identify the mechanisms that govern MV budding, furthering our understanding of the mechanisms that regulate disease-mediated EV release, membrane sculpting and viral budding.
G-protein- coupled receptors (GPCRs) are the largest family of membrane confined receptors and they transduce ligand binding to downstream effects. Almost 40% of the drugs in the world target GPCRs due to their function, albeit knowing less about their activation. Understanding their dynamic behaviour in basal and activated state could prove key to drug development in the future. GPCRs are known to exhibit complex molecular mobility patterns. A plethora of studies have been and are being conducted to understand the mobility of GPCRs. Due to limitations of imaging and spectroscopic techniques commonly used, the relevant timescales are hard to access. The most commonly used techniques are electron paramagnetic resonance or double electronelectron resonance, nuclear magnetic resonance, time-resolved fluorescence, single particle tracking and fluorescence recovery after photobleaching. Among these techniques only fluorescence has the potential to probe live cells. In this thesis, I use different time-resolved fluorescence spectroscopic techniques to quantify diffusion dynamics / molecular mobility of β2-adrenergic receptor (β2-AR) in live cells. The thesis shows that β2-AR exhibits mobility over an exceptionally broad temporal range (nanosecond to second) that can be linked to its respective physiological scenario. I explain how β2-AR possesses surprisingly fast lateral mobility (~10 μm²/s) associated with vesicular transport in contrast to the prior reports of it originating from fluorophore photophysics and free fluorophores in the cytosol. In addition, β2-AR has rotational mobility (~100 μs) that makes it conform to the Saffman-Delbrück model of membrane diffusion unlike earlier studies. These contrasts are due to the limitations of the methodologies used. The limitations are overcome in this thesis by using different time-resolved fluorescence techniques of fluorescence correlation spectroscopy (FCS), time-resolved anisotropy (TRA) and polarisation resolved fullFCS (fullFCS). FCS is limited to microsecond to the second range and TRA is limited to the nanosecond range. fullFCS complements the two techniques by covering the blind spot of FCS and TRA in the microsecond range. Finally, I show how ligand stimulation causes a decrease in lateral mobility which could be a hint at cluster formation due to internalisation and how β2-AR possesses a basal oligomerisation that does not change on activation. Thus, through this thesis, I show how different complementary fluorescence techniques are necessary to overcome limitations of each technique and to thereby elucidate functional dynamics of GPCR activation and how it orchestrates downstream signalling.
Platelets are small anucleated cell fragments that originate from megakaryocytes (MKs), which are large cells located in the bone marrow (BM). MKs extend long cytoplasmic protrusions, a process which is called proplatelet formation, into the lumen of the sinusoidal vessels where platelets are sized by the bloodstream. During the process of platelet biogenesis, segments of the MK penetrate the endothelium and, through cytoskeletal remodeling inside the MK, proplatelet fragments are released. Rho GTPases, such as RhoA and RhoB, are critically involved in cytoskeletal rearrangements of both the actin and the tubulin cytoskeleton.
The first part of this thesis concentrated on the protein RhoB and its involvement in cytoskeletal organization in MKs and platelets. Single knockout (KO) mice lacking RhoB had a minor microthrombocytopenia, which means a smaller platelet size and reduced platelet number, accompanied by defects in the microtubule cytoskeleton in both MKs and platelets. In particular, tubulin organization and stability, which is regulated by posttranslational modifications of α-tubulin, were disturbed in RhoB-/- platelets. In contrast, RhoB-/- MKs produced abnormally shaped proplatelets but had unaltered posttranslational modifications of α-tubulin.
The second part focused on the influence of RhoA and RhoB on MK localization and platelet biogenesis in murine BM. Many intact RhoA-/- MKs are able to transmigrate through the endothelial layer and stay attached to the vessel wall, whereas only 1% of wildtype (wt) MKs are detectable in the intrasinusoidal space. Concomitant deficiency of RhoA and RhoB reverts this transmigration and results in macrothrombocytopenia, MK clusters around the vessel in the BM and defective MK development. The underlying mechanism that governs MKs to distinct localizations in the BM is poorly understood, thus this thesis suggests that this process may be dependent on RhoB protein levels, as RhoA deficiency is coincided with increased RhoB levels in MKs and platelets.
The third part of this thesis targeted the protein PDK1, a downstream effector of Rho GTPases, in regard to MK maturation and polarization throughout thrombopoiesis. MK- and platelet-specific KO in mice led to a significant macrothrombocytopenia, impaired actin cytoskeletal reorganization during MK spreading and proplatelet formation, with defective MK maturation. This was associated with decreased PAK activity and, subsequently, phosphorylation of its substrates LIMK and Cofilin. Together, the observations of this thesis highlight the importance of Rho GTPases and their downstream effectors on the regulation of the MK and platelet cytoskeleton.