195 research outputs found

    From variome to phenome : pathogenesis, diagnosis and management of ectopic mineralization disorders

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    Ectopic mineralization - inappropriate biomineralization in soft tissues - is a frequent finding in physiological aging processes and several common disorders, which can be associated with significant morbidity and mortality. Further, pathologic mineralization is seen in several rare genetic disorders, which often present life-threatening phenotypes. These disorders are classified based on the mechanisms through which the mineralization occurs: metastatic or dystrophic calcification or ectopic ossification. Underlying mechanisms have been extensively studied, which resulted in several hypotheses regarding the etiology of mineralization in the extracellular matrix of soft tissue. These hypotheses include intracellular and extracellular mechanisms, such as the formation of matrix vesicles, aberrant osteogenic and chondrogenic signaling, apoptosis and oxidative stress. Though coherence between the different findings is not always clear, current insights have led to improvement of the diagnosis and management of ectopic mineralization patients, thus translating pathogenetic knowledge (variome) to the phenotype (phenome). In this review, we will focus on the clinical presentation, pathogenesis and management of primary genetic soft tissue mineralization disorders. As examples of dystrophic calcification disorders Pseudoxanthoma elasticum, Generalized arterial calcification of infancy, Keutel syndrome, Idiopathic basal ganglia calcification and Arterial calcification due to CD73 (NT5E) deficiency will be discussed. Hyperphosphatemic familial tumoral calcinosis will be reviewed as an example of mineralization disorders caused by metastatic calcification

    Pharmacogenomics in children: advantages and challenges of next generation sequencing applications

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    Pharmacogenetics is considered as a prime example of how personalized medicine nowadays can be put into practice. However, genotyping to guide pharmacological treatment is relatively uncommon in the routine clinical practice. Several reasons can be found why the application of pharmacogenetics is less than initially anticipated, which include the contradictory results obtained for certain variants and the lack of guidelines for clinical implementation. However, more reproducible results are being generated, and efforts have been made to establish working groups focussing on evidence-based clinical guidelines. For another pharmacogenetic hurdle, the speed by which a pharmacogenetic profile for a certain drug can be obtained in an individual patient, there has been a revolution in molecular genetics through the introduction of next generation sequencing (NGS), making it possible to sequence a large number of genes up to the complete genome in a single reaction. Besides the enthusiasm due to the tremendous increase of our sequencing capacities, several considerations need to be made regarding quality and interpretation of the sequence data as well as ethical aspects of this technology. This paper will focus on the different NGS applications that may be useful for pharmacogenomics in children and the challenges that they bring on

    The ABCC6 transporter : what lessons can be learnt from other ATP-binding cassette transporters?

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    ABC transporters represent a large family of ATP-driven transmembrane transporters involved in uni- or bidirectional transfer of a large variety of substrates. Divided in seven families, they represent 48 transporter proteins, several of which have been associated with human disease. Among the latter is ABCC6, a unidirectional exporter protein primarily expressed in liver and kidney. ABCC6 deficiency has been shown to cause the ectopic mineralization disorder pseudoxanthoma elasticum (PXE), characterized by calcification and fragmentation of elastic fibers, resulting in oculocutaneous and cardiovascular symptoms. Unique in the group of connective tissue disorders, the pathophysiological relation between the ABCC6 transporter and ectopic mineralization in PXE remains enigmatic, not in the least because of lack of knowledge on the substrate(s) of ABCC6 and its unusual expression pattern. Because many features, including structure and transport mechanism, are shared by many ABC transporters, it is worthwhile to evaluate if and to what extent the knowledge on the physiology and pathophysiology of these other transporters may provide useful clues toward understanding the (patho)physiological role of ABCC6 and how its deficiency may be dealt with

    Novel clinical and etiopathogenetic findings in Pseudoxanthoma elasticum

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    Soft tissue calcification in the human body can be considered part of a process of continuous  degeneration  which  we  tend  to  designate  as  “aging”.  Being  an  example  of technological wit and superb bio-engineering second to none, even the decay of this corpus can hardly be considered a random or passive event. On the contrary, calcium precipitation is regulated quite tightly by an intruiging interplay between stimulatory proteins and inhibitory factors. Thus, it has been foreseen man not to be turned into a chalk pillar in his prime years, but rather to endure a much slower process of gradual mineralization. But when this brilliant regulatory opus starts failing, the reign of human pathology is entered, confronting the body with ectopic mineralization disorders. One of the archetypes of such disease is pseudoxanthoma elasticum or PXE, in which ectopic mineralization of elastic fibres causes skin, ocular and cardiovascular complications. Despite its identification more than two centuries ago, PXE has – as many genetic disorders – always been surrounded by a haze of mystery. It is the aim of this thesis to contribute to the clinical, molecular and histopathological characterization of this fascinating disease. Through careful characterization of the PXE patient cohort followed at the Ghent Center for Medical Genetics, we were able to emphasize important clinical features, such as stroke and peripheral artery disease, as well as identifying novel phenotypical features in patients and carriers, among which were abdominal calcifications and testicular microlithiasis. Also the question of a limited or subclinical phenotype in PXE carriers was addressed and we showed them to be more prone to cardiovascular disease, next to limited ophthalmological symptoms represented by comets and comet tails. In an exploratory pilot study among over 200 consecutive ischemic stroke patients, ABCC6 hotspot analysis yielded a significant increase in ABCC6 mutations compared to a healthy reference population. This signified another example of heterozygous carriers being prone to cardiovascular and/or cerebrovascular disease and introduced the ABCC6 gene in stroke research. In single and multi-center studies, this thesis contributed to the characterization and expansion of the ABCC6 mutation spectrum, as well as the exclusion of genotype-phenotype correlations. The applied molecular strategy for mutation analysis of the ABCC6 gene proved to be an efficient and cost-effective method, yielding the highest mutation detection rate so far. Also, the continuous discussion on the mode of inheritance and in particular the existence of an autosomal dominant form of PXE could be addressed constructively. Throughout the clinical follow-up of PXE patients, we applied novel fundus imaging techniques, such as autofluorescence and infrared imaging, with substantial improvement of the diagnostic capacities of limited or subtle lesions in fundo. Through collaborative efforts, the importance of electrophysiological abnormalities – subdivided in three retinopathy phenotypes – was brought to attention. Within the span of this PhD thesis, a novel phenotype was identified and characterized both clinically and molecularly. This novel autosomal recessive disorder was coined the PXE-like syndrome, because of its resemblance with classic PXE, and was proven to be caused by mutations in the GGCX gene. Encoding the gamma-carboxylase, an enzyme important in the vitamin K (VK)-cycle, this observation implicated VK and proteins depending on this vitamin – among which are several inhibitors of mineralization – in the pathogenesis of the PXE-like syndrome and hence PXE. Through various immunohistochemical and ELISA methods, VK-dependent inhibitors of calcification were shown to be inactive or defective in these syndromes, leading to ectopic mineralization in the PXE-like syndrome but also in PXE patients. These observations could be attributed to the GGCX mutations in the PXE-like syndrome. The observation of extremely low VK serum levels – an essential co-factor for protein carboxylation in the VK-cycle – in PXE patients explained why the VK-cycle is defective in PXE. The exact link with the impaired ABCC6 transporter remains unclear, although it is tempting to think of VK or one of its associated molecules as the substrate of ABCC6. Also, these findings hold out the prospect of VK suppletion as a treatment for PXE. As such, the findings summarized in this thesis have elaborated the clinical and molecular knowledge of PXE and related disorders, and have opened novel avenues for further fundamental and applied research in the field of ectopic mineralization. Above all, they have benefitted patients and their family though a more efficient molecular diagnosis, a more to-the- point follow-up and the prospect of a treatment for their burdensome disease

    Hereditary Connective Tissue Diseases in Young Adult Stroke: A Comprehensive Synthesis

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    Though the genetic background of ischaemic and haemorrhagic stroke is often polygenetic or multifactorial, it can in some cases result from a monogenic disease, particularly in young adults. Besides arteriopathies and metabolic disorders, several connective tissue diseases can present with stroke. While some of these diseases have been recognized for decades as causes of stroke, such as the vascular Ehlers-Danlos syndrome, others only recently came to attention as being involved in stroke pathogenesis, such as those related to Type IV collagen. This paper discusses each of these connective tissue disorders and their relation with stroke briefly, emphasizing the main clinical features which can lead to their diagnosis

    The role of vitamin K and its related compounds in Mendelian and acquired ectopic mineralization disorders

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    Ectopic mineralization disorders comprise a broad spectrum of inherited or acquired diseases characterized by aberrant deposition of calcium crystals in multiple organs, such as the skin, eyes, kidneys, and blood vessels. Although the precise mechanisms leading to ectopic calcification are still incompletely known to date, various molecular targets leading to a disturbed balance between pro- and anti-mineralizing pathways have been identified in recent years. Vitamin K and its related compounds, mainly those post-translationally activated by vitamin K-dependent carboxylation, may play an important role in the pathogenesis of ectopic mineralization as has been demonstrated in studies on rare Mendelian diseases, but also on highly prevalent disorders, like vascular calcification. This narrative review compiles and summarizes the current knowledge regarding the role of vitamin K, its metabolism, and associated compounds in the pathophysiology of both monogenic ectopic mineralization disorders, like pseudoxanthoma elasticum or Keutel syndrome, as well as acquired multifactorial diseases, like chronic kidney disease. Clinical and molecular aspects of the various disorders are discussed according to the state-of-the-art, followed by a comprehensive literature review regarding the role of vitamin K in molecular pathophysiology and as a therapeutic target in both human and animal models of ectopic mineralization disorders

    Perturbation of specific pro-mineralizing signalling pathways in human and murine pseudoxanthoma elasticum

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    BACKGROUND: Pseudoxanthoma elasticum (PXE) is characterized by skin (papular lesions), ocular (subretinal neovascularisation) and cardiovascular manifestations (peripheral artery disease), due to mineralization and fragmentation of elastic fibres in the extracellular matrix (ECM). Caused by mutations in the ABCC6 gene, the mechanisms underlying this disease remain unknown. The knowledge on the molecular background of soft tissue mineralization largely comes from insights in vascular calcification, with involvement of the osteoinductive Transforming Growth Factor beta (TGFbeta) family (TGFbeta1-3 and Bone Morphogenetic Proteins [BMP]), together with ectonucleotides (ENPP1), Wnt signalling and a variety of local and systemic calcification inhibitors. In this study, we have investigated the relevance of the signalling pathways described in vascular soft tissue mineralization in the PXE knock-out mouse model and in PXE patients. METHODS: The role of the pro-osteogenic pathways BMP2-SMADs-RUNX2, TGFbeta-SMAD2/3 and Wnt-MSX2, apoptosis and ER stress was evaluated using immunohistochemistry, mRNA expression profiling and immune-co-staining in dermal tissues and fibroblast cultures of PXE patients and the eyes and whiskers of the PXE knock-out mouse. Apoptosis was further evaluated by TUNEL staining and siRNA mediated gene knockdown. ALPL activity in PXE fibroblasts was studied using ALPL stains. RESULTS: We demonstrate the upregulation of the BMP2-SMADs-RUNX2 and TGFbeta-2-SMAD2/3 pathway, co-localizing with the mineralization sites, and the involvement of MSX2-canonical Wnt signalling. Further, we show that apoptosis is also involved in PXE with activation of Caspases and BCL-2. In contrast to vascular calcification, neither the other BMPs and TGFbetas nor endoplasmic reticulum stress pathways seem to be perturbed in PXE. CONCLUSIONS: Our study shows that we cannot simply extrapolate knowledge on cell signalling in vascular soft tissue calcification to a multisystem ectopic mineralisation disease as PXE. Contrary, we demonstrate a specific set of perturbed signalling pathways in PXE patients and the knock-out mouse model. Based on our findings and previously reported data, we propose a preliminary cell model of ECM calcification in PX

    Novel deletions causing pseudoxanthoma elasticum underscore the genomic instability of the ABCC6 region

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    Mutations in ABCC6 cause pseudoxanthoma elasticum (PXE), a heritable disease that affects elastic fibers. Thus far, >200 mutations have been characterized by various PCR-based techniques (primarily direct sequencing), identifying up to 90% of PXE-causing alleles. This study wanted to assess the importance of deletions and insertions in the ABCC6 genomic region, which is known to have a high recombinational potential. To detect ABCC6 deletions/insertions, which can be missed by direct sequencing, multiplex ligation-dependent probe amplification (MLPA) was applied in PXE patients with an incomplete genotype. MLPA was performed in 35 PXE patients with at least one unidentified mutant allele after exonic sequencing and exclusion of the recurrent exon 23-29 deletion. Six multi-exon deletions and four single-exon deletions were detected. Using MLPA in addition to sequencing, we expanded the ABCC6 mutation spectrum with 9 novel deletions and characterized 25% of unidentified disease alleles. Our results further illustrate the instability of the ABCC6 genomic region and stress the importance of screening for deletions in the molecular diagnosis of PXE. Journal of Human Genetics (2010) 55, 112-117; doi: 10.1038/jhg.2009.132; published online 15 January 201
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