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Spinal muscular atrophy with respiratory distress type 1 (SMARD1) is a fatal monogenic motoneuron disease in children with unknown etiology caused by mutations in the immunoglobulin μ-binding protein 2 (IGHMBP2) gene coding for DNA/RNA ATPase/helicase. Despite detailed knowledge of the underlying genetic changes, the cellular mechanisms leading to this disease are not well understood. In the Nmd2J ("neuromuscular disorder") mouse, the mouse model for the juvenile form of SMARD1 patients, in which similar pathological features as diaphragmatic paralysis and skeletal muscle atrophy are observed. Ex vivo studies in Nmd2J mice showed that loss of the motor axon precedes atrophy of the gastrocnemius muscle and does not correlate with neurotransmission defects in the motor endplate. The already described independent myogenic anomalies in the diaphragm and heart of the Nmd2J mouse raised the question whether spinal motoneuron degeneration develops cell autonomously. Ighmbp2 is predominantly localized in the cytoplasm and seems to bind to ribosomes and polysomes, suggesting a role in mRNA metabolism.
In this Ph.D. thesis, morphological and functional analyses of isolated Ighmbp2-deficient (Ighmbp2-def.) motoneurons were performed to answer the question whether the SMARD1 phenotype results from dysregulation of protein biosynthesis. Ighmbp2-deficient motoneurons show only negligible morphological alterations with respect to a slight increase in axonal branches. This observation is consistent with only minor changes of transcriptome based on RNA sequencing data from Ighmbp2-deficient motoneurons. Only the mRNA of fibroblast growth factor receptor 1 (Fgfr1) showed significant up-regulation in Ighmbp2-deficient motoneurons. Furthermore, no global aberrations at the translational level could be detected using pulsed SILAC (Stable Isotope Labeling by Amino acids in cell culture), AHA (L-azidohomoalanine) labeling and SUnSET (SUrface SEnsing of Translation) methods. However, a reduced β-actin protein level was observed at the growth cones of Ighmbp2-deficient motoneurons, which was accompanied with a reduced level of Imp1 protein, a known β-actin mRNA interactor. Live-cell imaging studies using fluorescence recovery after photobleaching (FRAP) showed translational down-regulation of eGFPmyr-β-actin 3'UTR mRNA in the growth cones and the cell bodies, although the amount of β-actin mRNA and the total protein amount in Ighmbp2-deficient motoneurons showed no aberrations. This compartment-specific reduction of β-actin protein occurred independently of a non-existent direct IGHMBPF2 binding to β-actin mRNA. Fgfr1, which was upregulated on the RNA level, did not show an increased protein amount in Ighmbp2-deficient motoneurons, whereas a reduced amount could be detected. Interestingly, a correlation could be found between the reduced amount of the Imp1 protein and the increased Fgfr1 mRNA, since the IMP1 protein binds the FGFR1 mRNA and thus could influence the transport and translation of FGFR1 mRNA. In summary, all data suggest that Ighmbp2 deficiency leads to a local but modest disturbance of protein biosynthesis, which might contribute to the motoneuron defects of SMARD1.
Blumeria graminis, the obligate biotrophic grass powdery mildew, is a highly pathogenic fungus capable of inflicting foliar diseases and of causing severe yield losses. There is asexual and sexual propagation in the life cycle of B. graminis. In the epidemiological processes of this pathogen, both types of spores - asexual conidia and sexual ascospores – are crucial.
Conidia of B. graminis are demonstrated to perceive cuticular very-long-chain aldehydes as molecular signal substances notably promoting germination and differentiation of the infection structure (the appressorium) – the prepenetration processes – in a concentration- and chain-length-dependent manner. Conidial germination and appressorium formation are known to be dramatically impeded by the presence of free water on the host surface. However, sexually formed ascospores are reported to easily germinate immersed in water. There are abundant assays on conidial prepenetration processes. However, with respect to the stimulating effects of very-long-chain aldehydes and to the influence of the presence of free water, ascosporic prepenetration processes are still obscure.
In order to study the effects of very-long-chain aldehydes on the ascosporic prepenetration processes of wheat powdery mildew fungus B. graminis f. sp. tritici, Formvar®-based in vitro systems were applied to exclude the secondary host effects (such as host resistance) and to reproducibly provide homogeneous hydrophobic substratum surfaces. By the presence of even-numbered very-long-chain aldehydes (C22 - C30), the appressorium formation of the ascospores was notably triggered in a chain-length dependent manner. N-octacosanal (C28) was the most inducing aldehyde tested. Unlike conidia, ascospores could easily differentiate immersed in water and showed a more variable differentiation pattern even with a single germ tube differentiating an appressorium.
To evaluate the alternative management against barley powdery mildew fungus Blumeria graminis f. sp. hordei, the suppressing effects of UV-C irradiation on the developmental processes of conidia on artificial surfaces (in vitro) and on host leaf surfaces (in vivo) were assayed. In vitro and in vivo, a single dose of 100 J m-2 UV-C was adequate to decrease conidial germination to < 20 % and to reduce appressorium formation to values < 5 %. UV-C irradiation negatively affected colony pustule size and vegetative propagation. Under photoperiodic conditions of 2h light/16h dark, 6h dark/12h light or 6h dark/18h light, UV-C-treated conidia showed photoreactivation (photo-recovery). White light-mediated photoreactivation was most effective immediately after UV-C irradiation, suggesting that a prolonged phase of darkness after UV-C application increased the efficacy of management against B. graminis. UV-C irradiation increased transcript levels of three putative photolyase genes in B. graminis, indicating those were probably involved in photoreactivation processes. However, mere white light or blue light (wavelength peak, 475 nm) could not induce the up-regulation of these genes.
To determine whether visible light directly impacted the prepenetration and penetration processes of this powdery mildew pathogen, conidia of Blumeria graminis f. sp. hordei and Blumeria graminis f. sp. tritici were inoculated onto artificial surfaces and on host leaf surfaces. Samples were analyzed after incubation periods under light conditions (white light intensity and spectral quality). Increasing white light intensities directly impaired conidial prepenetration processes in vitro but not in vivo. Applying an agar layer under the wax membrane compensated for conidial water loss as a consequence of high white light irradiation. Light stimulated in vitro and in vivo the appressorium elongation of B. graminis in a wavelength-dependent manner. Red light was more effective to trigger the elongation of appressorium than blue light or green light assayed.
Taken together, the findings of this study demonstrate that 1) a host surface recognition principle based on cuticular very-long-chain aldehydes is a common feature of B. graminis f. sp. tritici ascospores and conidia; 2) the transcriptional changes of three putative photolyase genes in B. graminis are mediated in a UV-C-dependent manner; 3) light directly affected the (pre)penetration processes of B. graminis.
From the simplest single-cellular organism to the most complex multicellular life forms, genetic information in form of DNA represents the universal basis for all biological processes and thus for life itself. Maintaining the structural and functional integrity of the genome is therefore of paramount importance for every single cell. DNA itself, as an active and complex macromolecular structure, is both substrate and product of many of these biochemical processes. A cornerstone of DNA maintenance is thus established by the tight regulation of the multitude of reactions in DNA metabolism, repressing adverse side reactions and ensuring the integrity of DNA in sequence and function. The family of RecQ helicases has emerged as a vital class of enzymes that facilitate genomic integrity by operating in a versatile spectrum of nucleic acid metabolism processes, such as DNA replication, repair, recombination, transcription and telomere stability. RecQ helicases are ubiquitously expressed and conserved in all kingdoms of life. Human cells express five different RecQ enzymes, RecQ1, BLM, WRN, RecQ4 and RecQ5, which all exhibit individual as well as overlapping functions in the maintenance of genomic integrity. Dysfunction of three human RecQ helicases, BLM, WRN and RecQ4, causes different heritable cancer susceptibility syndromes, supporting the theory that genomic instability is a molecular driving force for cancer development. However, based on their inherent DNA protective nature, RecQ helicases represent a double-edged sword in the maintenance of genomic integrity. While their activity in normal cells is essential to prevent cancerogenesis and cellular aging, cancer cells may exploit this DNA protective function by the overexpression of many RecQ helicases, aiding to overcome the disadvantageous results of unchecked DNA replication and simultaneously gaining resistance against chemotherapeutic drugs. Therefore, detailed knowledge how RecQ helicases warrant genomic integrity is required to understand their implication in cancerogenesis and aging, thus setting the stage to develop new strategies towards the treatment of cancer.
The current study presents and discusses the first high-resolution X-ray structure of the human RecQ4 helicase. The structure encompasses the conserved RecQ4 helicase core, including a large fraction of its unique C- terminus. Our structural analysis of the RecQ4 model highlights distinctive differences and unexpected similarities to other, structurally conserved, RecQ helicases and permits to draw conclusions about the functional implications of the unique domains within the RecQ4 C-terminus. The biochemical characterization of various RecQ4 variants provides functional insights into the RecQ4 helicase mechanism, suggesting that RecQ4 might utilize an alternative DNA strand separation technique, compared to other human RecQ family members. Finally, the RecQ4 model permits for the first time the analysis of multiple documented RecQ4 patient mutations at the atomic level and thus provides the possibility for an advanced interpretation of particular structure-function relationships in RecQ4 pathogenesis.
Investigation of dynamic processes of prototypical class A GPCRs by single-molecule microscopy
(2020)
In this work, two projects were pursued.
In the first project, I investigated two different subtypes of opioid receptors, which play a key role as target for analgesia. A set of subtype specific fluorescent ligands for μ opioid receptor (MOR) and δ opioid receptor (DOR) was characterised and used to gain insights into the diffusion behaviour of those receptors. It was shown that the novel ligands hold photophysical and pharmacological properties making them suitable for single-molecule microscopy. Applying them to wild-type receptors expressed in living cells revealed that both sub-types possess a heterogeneous diffusion behaviour. Further- more, the fluorescent ligands for the MOR were used to investigate homodomerisation, a highly debated topic. The results reveal that only ≈ 5 % of the receptors are present as homodimers, and thus the majority is monomeric. G-protein coupled receptors (GPCRs) play a major role as drug targets. Accordingly, understanding the activation process is very important. For a long time GPCRs have been believed to be either active or inactive. In recent years several studies have shown, that the reality is more complex, involving more substates. [1, 2, 3, 4] In this work the α 2A AR was chosen to investigate the activation process on a single-molecule level, thus being able to distinguish also rare or short-lived events that are hidden in ensemble mea- surements. With this aim, the receptor was labelled intracellular with two fluorophores using supported membranes. Thus it was possible to acquire movies showing qualita- tively smFRET events. Unfortunately, the functionality of the used construct could not be demonstrated. To recover the functionality the CLIP-tag in the third intracellular loop was replaced successfully with an amber codon. This stop codon was used to insert an unnatural amino acid. Five different mutants were created and tested and the most promising candidate could be identified. First ensemble FRET measurements indicated that the functionality might be recovered but further improvements would be needed. Overall, I could show that single-molecule microscopy is a versatile tool to investigate the behaviour of typical class A GPCRs. I was able to show that MOR are mostly monomeric under physiological expression levels. Furthermore, I could establish intra- cellular labelling with supported membranes and acquire qualitative smFRET events.
The ubiquitination of proteins controls a multitude of physiological processes. This versatility of ubiquitin as a molecular signal arises from the diverse ways by which it can be attached to target proteins. Different ubiquitination patterns are then translated into different downstream consequences. Due to the enormous complexity of possible ubiquitin modifications, the ubiquitination machinery must be highly specific and tightly controlled. Ubiquitination proceeds through an enzymatic cascade, the last step of which is catalyzed by the E3 enzyme family. E3 enzymes are the crucial regulators since they dictate the specificity of substrate selection and modification.
Deregulation of the HECT-type ubiquitin ligase E6AP (UBE3A) is implicated in human papilloma virus-induced cervical tumorigenesis and several neurodevelopmental disorders. Yet the structural underpinnings of activity, regulation and specificity in this crucial ligase are incompletely understood.
One aim of this study was to unravel the role of the a1’-helix N-terminal to the HECT domain that was found to be a key element mediating regulation and oligomerization in other HECT ligases. I found that most N-terminally extended HECT domain constructs were insoluble when expressed in E. coli, indicating that additional regions N-terminal to the tested fragments may be essential to protect this highly hydrophobic helix from causing aggregation.
Another question addressed in this study was how E6AP builds ubiquitin chains. Using single-turnover experiments, I showed that ubiquitin-loaded E6AP is unable to transfer an additional ubiquitin molecule onto a stably linked ubiquitin-E6AP complex. This indicates that E6AP cannot assemble chains on its active site and may instead follow a sequential addition mechanism in which one ubiquitin molecule is transferred at a time to the target protein.
Using NMR spectroscopy and extensive mutational analyses, the determinants of ubiquitin recognition by the C-lobe of E6AP were unraveled and assigned to particular steps in the catalytic cycle. A functionally critical interface was identified that is specifically required during thioester formation between the C-terminus of ubiquitin and the ligase active site. This interface resembles the one utilized by NEDD4-type enzymes, suggesting a conserved ubiquitin binding mode across HECT ligases, independent of their linkage specificities. Moreover, I identified critical surface patches on ubiquitin and in the N- and C-terminal portions of the catalytic domain of E6AP that are important for the subsequent step of isopeptide bond formation. I also uncovered key determinants of the Lys48-linkage specificity of E6AP, both in the E6AP HECT domain and ubiquitin itself. This includes the C-terminal tail of E6AP and a hydrophilic surface region of ubiquitin in proximity to the acceptor site, Lys48. It is thus tempting to speculate that ubiquitin linkage formation by E6AP is substrate-assisted. Taken together, my results improve our mechanistic understanding of the structure-function relationship between E6AP and ubiquitin, thus providing a basis for ultimately manipulating the functions of this HECT ligase for therapeutic applications.
Gene expression and transfer of the genetic information to the next generation forms the basis of cellular life. These processes crucially rely on DNA, thus the preservation, transcription and translation of DNA is of fundamental importance for any living being. The general transcription factor TFIIH is a ten subunit protein complex, which consists of two subcomplexes: XPB, p62, p52, p44, p34, and p8 constitute the TFIIH core, CDK7, CyclinH, and MAT1 constitute the CAK. These two subcomplexes are connected via XPD. TFIIH is a crucial factor involved in both, DNA repair and transcription. The central role of TFIIH is underlined by three severe disorders linked to failure of TFIIH in these processes: xeroderma pigmentosum, Cockayne syndrome, and trichothiodystrophy. Only limited structural and functional data of TFIIH are available so far. Here, the model organism Chaetomium thermophilum was utilized with the aim to structurally and functionally characterize TFIIH. By combining the expression and purification of single TFIIH subunits with the co-expression and co-purification of dual complexes, a unique and powerful modular system of the TFIIH core subunits could be established, encompassing all proteins in high quality and fully functional. This system permits the step-wise assembly of TFIIH core, thereby making it possible to assess the influence of the intricate interaction network within TFIIH core on the overall enzymatic activities of TFIIH, which has not been possible so far. Utilizing the single subunits and dual complexes, a detailed interaction network of TFIIH core was established, revealing the crucial role of the p34 subunit as a central scaffold of TFIIH by linking the two proteins p44 and p52. Our studies also suggest that p62 constitutes the central interface of TFIIH to the environment rather than acting as a scaffold. TFIIH core complexes were assembled and investigated via electron microscopy. Preliminary data indicate that TFIIH adopts different conformational states, which are important to fulfill its functions in transcription and DNA repair. Additionally, a shortened construct of p62 was used to develop an easy-to-use, low cost strategy to overcome the crystallographic phase problem via cesium derivatization.
Knowing then defeating: The Ubiquitin activating enzyme, a promising target for cancer therapy
(2020)
Ubiquitin is a 76 amino acid long polypeptide, which is present throughout eukaryotes in a highly conserved fashion. Ubiquitin can modify proteins by becoming covalently attached to them. Eukaryotic cells employ ubiquitin to maintain and regulate fundamental cellular processes like protein degradation, the immune response and transcriptional and translational regulation. Transfer of ubiquitin to the substrate is achieved by the catalysis of three classes of enzymes namely E1, E2 and E3. Together these enzymes form a pyramidal hierarchy, where E1 stands at the apex and E3 enzymes form the base of the pathway.
The ubiquitin activating enzyme 1 (UBA1) plays a major role in ubiquitylation being the ubiquitin-dedicated E1 enzyme. In addition, it is the only enzyme in this pathway to use ATP as an energy source to catalyze two important reactions. The products of these reactions, ubiquitin adenylate and ubiquitin thioester, are the essential intermediate states of ubiquitin, for being conjugated to the target protein. With the help of X-ray crystallography and biochemical approaches, snapshots of multiple catalytic states of UBA1, where it is bound to Mg-ATP, ubiquitin and the E2 Ubc13 as substrates could be captured. With the help of these high-resolution crystal structures, deeper insights into the enzymatic mechanism of UBA1 could be attained. The resulting insights into the catalytic cycle were further validated by biochemical assays. It could be shown that ATP acts as a molecular switch to induce the enzyme’s open conformation. Ubiquitin-binding to the enzyme leads to domain rotations, which facilitate the recruitment of a cognate E2 enzyme. The interdomain communication as well as the cross-talk with the substrates and the products fuel the enzymatic cycle of UBA1.
Due to the proven efficacy of proteasome inhibitors for cancer treatment, which block degradation of proteins labeled with ubiquitin, enzymes participating in the ubiquitylation cascade have been targeted by researchers for the development of novel anti-cancer therapeutics. UBA1 inhibition has been shown to preferentially induce cell death in malignant cells, and it can also be used as a strategy to overcome resistance against proteasome inhibitors. MLN7243, an adenosyl sulfamate inhibitor developed by Millenium Pharmaceutical to specifically target UBA1, is currently in Phase-I clinical trials for the treatment of solid tumors. UBA1 could be crystallized in complex with three adenosyl sulfamate inhibitors covalently linked to ubiquitin, which are promising drug candidates for cancer therapy. The inhibitors employed, MLN7243, MLN4924 and ABPA3, show distinct specificities towards different E1 enzymes. With the help of crystal structures the specificity determinants of these inhibitors could be deciphered, which were further confirmed by inhibition assays as well as molecular dynamics simulations. Together these crystal structures provide a starting point for developing E1-specific inhibitors, which, besides their potential for medicinal purposes, are important tools to better understand the function of the ubiquitin system as well as the action of ubiquitin-like proteins.
Frizzled (FZD) are highly conserved receptors that belong to class F of the G protein-coupled receptor (GPCR) superfamily. They are involved in a great variety of processes during embryonic development, organogenesis, and adult tissue homeostasis. In particular, FZD5 is an important therapeutic target due to its involvement in several pathologies, such as tumorigenesis. Nevertheless, little is known regarding the activation of FZD receptors and the signal initiation, and their GPCR nature has been debated. In order to investigate the activation mechanism of these receptors, FRET (Förster Resonance Energy Transfer)-based biosensors for FZD5 have been developed and characterized. A cyan fluorescent protein (CFP) was fused to the C-terminus of the receptor and the specific FlAsH-binding sequence (CCPGCC) was inserted within the 2nd or the 3rd intracellular loop. Single-cell FRET experiments performed using one of these sensors, V5-mFZD5-FlAsH436-CFP, reported structural rearrangements in FZD5 upon stimulation with the endogenous ligand WNT-5A. These movements are similar to those observed in other GPCRs using the same technique, which suggests an activation mechanism for FZD reminiscent of GPCRs. Furthermore, stimulation of the FZD5 FRET-based sensor with various recombinant WNT proteins in a microplate FRET reader allowed to obtain concentration-response curves for several ligands, being possible to distinguish between full and partial agonists. This technology allowed to address the selectivity between WNTs and FZD5 using a full-length receptor in living cells. In addition, G protein FRET-based sensors revealed that WNT-5A specifically induced Gαq activation mediated by FZD5, but not Gαi activation. Other WNT proteins were also able to induce Gαq activation, but with lower efficacy than WNT-5A. In addition, a dual DAG/calcium sensor further showed that WNT-5A stimulation led to the activation of the Gαq-dependent signaling pathway mediated by FZD5, which outcome was the activation of Protein Kinase C (PKC) and the release of intracellular calcium. Altogether, these data provide evidence that the activation process of FZD5 resembles the general characteristics of class A and B GPCR activation, and this receptor also mediates the activation of the heterotrimeric Gαq protein and its downstream signaling pathway. In addition, the FZD5 receptor FRET-based sensor provides a valuable tool to characterize the pharmacological properties of WNTs and other potential ligands for this receptor.
This thesis explores the development of monoaminergic systems in the central nervous system (CNS) of zebrafish. The serotonergic cells of the hypothalamus pose the main focus of the present work. Most vertebrates except for mammals possess serotonin (5-HT) synthesising cells in more than one region of the CNS. In zebrafish such regions are, e.g. the hypothalamus, the raphe nuclei and the spinal cord. Serotonin functions as a neurotransmitter and neuromodulator in the CNS. Presumably due to its neuromodulatory tasks hypothalamic serotonergic cells are in contact with the cerebrospinal fluid (CSF), which expands the field of potential serotonergic targets tremendously. This highlights that serotonergic CSF-contacting (CSF-c) cells are vital for the execution of many functions and behaviours. Further, the hypothalamic serotonergic clusters constitute the largest population of serotonergic cells in the CNS of zebrafish. Together, these facts emphasise the need to understand the development and function of serotonergic CSF-c cells in the hypothalamus. Few studies have dealt with this subject, hence, information about the development of these cells is scarce. The zinc-finger transcription factor fezf2, and Fibroblast growth factor (Fgf)-signalling via the ETS-domain transcription factor etv5b are known to regulate serotonergic cell development in the hypothalamus (Bosco et al., 2013; Rink and Guo, 2004). However, the main Fgf ligand responsible for this mediation has not been determined prior to this work. The present thesis identifies Fgf3 as a crucial Fgf ligand. To achieve this result three independent strategies to impair Fgf3 activity have been applied to zebrafish embryos: the fgf3t24152 mutant, an fgf3 morpholino-based knock-down and the CRISPR/Cas9 technique. The investigations show that Fgf3 regulates the development of monoaminergic CSF-c cells in the hypothalamus. Additionally, Fgf3 impacts on cells expressing the peptide hormone arginine vasopressin (avp). Most interestingly, the requirement for Fgf3 by these cells follows a caudo-rostral gradient with a higher dependence on Fgf3 by caudal cells. This also seems to be the case for dopaminergic CSF-c cells in the hypothalamus (Koch et al., 2014). Moreover, etv5b a downstream target of Fgf-signalling is demonstrated to be under the control of Fgf3. With regard to serotonergic CSF-c cell development, it is shown that fgf3 is expressed several hours before tph1a and 5-HT (Bellipanni et al., 2002; Bosco et al., 2013). Together with the result that the hypothalamus is already smaller before mature serotonergic CSF-c cells appear, this argues for an early impact of Fgf3 on serotonergic specification. This hypothesis is supported by several findings in this study: the universal decrease of proliferating cells in the hypothalamus and simultaneous increase of cell death after fgf3 impairment. Complementary cell fate experiments confirm that proliferating serotonergic progenitors need Fgf3 to commit serotonergic specification. Further, these results corroborate findings of an earlier study stating that hypothalamic serotonergic progenitors require Fgf-signalling via etv5b to maintain the progenitor pool (Bosco et al., 2013). Additionally, the transcriptome of the hypothalamus has been analysed and 13 previously overlooked transcripts of Fgf ligands are expressed at developmental stages. The transcriptome analysis provides evidence for a self-compensatory mechanism of fgf3 since expression of fgf3 is upregulated as a consequence of its own impairment. Moreover, the Fgf-signalling pathway appears to be mildly affected by fgf3 manipulation. Together, Fgf-signalling and especially Fgf3 are established to be of critical importance during hypothalamic development with effects on serotonergic, dopaminergic CSF-c and avp expressing cells. Furthermore, this thesis provides two strategies to impair the tph1a gene. Both strategies will facilitate investigations regarding the function of hypothalamic serotonergic CSF-c cells. Finally, the presented findings in this study provide insights into the emergence of the posterior recess region of the hypothalamus, thereby, contributing to the understanding of the evolution of the vertebrate hypothalamus.
Bone marrow dosimetry is a topic of high interest in molecular radiotherapy. Predicting the level of hematological toxicity is one of the most important goals of nuclear medicine radiation dosimetry. To achieve this, it is necessary to quantify the absorbed dose to the active bone marrow, thus aiming at administering the most efficient therapy with a minimum level of adverse effects in the patient. The anatomical complexity of trabecular bone and bone marrow leads to the need of applying non-nuclear medicine imaging methods for determining the spatial distribution of soft tissue, adipose tissue, and bone in spongiosa.
Therefore, the two objectives of this dissertation are: i) to apply magnetic resonance imaging (MRI) for quantification of the fat volume fraction, and ii) to validate a method based on dual-energy quantitative computed tomography (DEQCT) for quantification of the trabecular bone volume fraction.
In a first step, an MRI sequence (two-point Dixon) for fat-water separation was validated in a 3 Tesla system by quantifying the fat volume fraction in a phantom and the lumbar vertebrae of volunteers and comparing with magnetic resonance spectroscopy (MRS). After successful validation, the fat volume fraction was retrospectively measured in the five lumbar vertebrae of 44 patient images acquired in the clinical routine. The two-point Dixon showed a good quantification of the fat volume fraction in the phantom experiment (-9.8% maximum relative error with respect to the nominal values). In the volunteers, a non-significant difference between MRI and MRS was found for the quantification of the fat volume fraction in volumes-of-interest with similar dimensions and position in both quantification methodologies (MRI and MRS). In the study with patient data, the marrow conversion (red → yellow marrow) was found to be age-dependent, and slower in males (0.3% per year) than in females (0.5% per year). Also, considerable variability of the fat volume fraction in patients of similar ages and the same gender was observed.
These results enable the use of two-point Dixon MRI in the quantification of the fat volume fraction in the bone marrow. Additionally, the constant marrow conversion during adulthood suggests that a patient-specific approach should replace the assumption of a constant cellularity volume fraction of 0.7 (reference man) (1,2) as proposed by the International Commission on Radiological Protection (ICRP).
In a second step, a quantification method based on DEQCT was validated in two CT systems: i) a clinical CT integrated into a SPECT/CT and ii) a dual-source computed tomography (DSCT) system. The method was applied in two phantoms: the first was used to validate the DEQCT method by the quantification of the hydroxyapatite volume fraction in three vials of 50 ml each and three different hydroxyapatite concentrations (100 mg/cm3, 200 mg/cm3, 300 mg/cm3). The second phantom was the European spine phantom (ESP), an anthropomorphic spine phantom. It was used to quantify the bone mineral content (BMC) on the whole vertebra and the hydroxyapatite volume fraction (VFHA) in the spongiosa region of each vertebra of the phantom. Lastly, the BMC of lumbar vertebrae 1 (LV1) and 2 (LV2) was measured in a patient using DEQCT and dual-energy X-ray absorptiometry (DEXA). Furthermore, the hydroxyapatite volume fraction (VFHA) and the bone volume fraction (VFB) was calculated for both the whole vertebrae and the spongiosa region of LV1 and LV2.
The measured and nominal hydroxyapatite volume fraction in the vial phantom showed a good correlation (maximum relative error: 14.2%). The quantification of the BMC on the whole vertebra and the VFHA on the spongiosa region showed larger relative errors than in the validation phantom. The quantification of BMC on LV1 and LV2 showed relative errors between DEXA and DSCT equal to 7.6% (LV1) and -8.4% (LV2). Also, the values of the VFHA (mineral bone) were smaller than the VFB. This result is consistent with the bone composition (mineral bone plus organic material).
The DEQCT method enables the quantification of hydroxyapatite (mineral bone) and bone (mineral bone plus organic material) in a clinical setting. However, the method showed an overestimation of the quantified mineral bone volume fraction. This overestimation might be related to the lack of detailed information on the CT X-ray spectra and detector sensitivity. Also, the DEQCT method showed a dependency on the CT reconstruction kernel and the chemical description of the materials to be quantified.
Based on the results of this work, the feasibility for quantifying the fat volume fraction and the bone volume fraction in the spongiosa in a clinical setting has been demonstrated/proven. Furthermore, the differences in fat volume fraction in females and males, as well as the variability of the fat volume fraction in subjects of similar ages, questions the approximation of the cellularity volume fraction by only a single ICRP reference value in bone marrow dosimetry for molecular radiotherapy. Lastly, this study presents the first approach for non-invasive quantification of the bone volume fraction (mineral bone plus organic material) for improved bone marrow dosimetry.