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Erstcharakterisierung des Vitamin K-Epoxid-Reduktase Komplex 1-like 1 ProteinsHünerberg, Mirja Maaret January 2009 (has links)
Würzburg, Univ., Diss., 2009.
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Erstcharakterisierung des Vitamin K-Epoxid-Reduktase Komplex 1-like 1 Proteins / Characterization of the Vitamin K-Epoxide Reductase Komplex 1-like 1 ProteinHünerberg, Mirja Maaret January 2009 (has links) (PDF)
Im Jahre 2004 wurden in unserem Labor zwei Gene einer neuen Proteinfamilie kloniert, deren Charakterisierung seither im Gange ist. Das eine Protein, VKORC1, konnte durch Mutationsanalysen und biochemische Untersuchungen als eine zentrale Komponente des so genannten Vitamin K-Zyklus identifiziert werden. Vitamin K wird für die γ-Carboxylierung der Vitamin K-abhängigen Proteine wie z.B. der Gerinnungsfaktoren II, VII, IX und X als Cofaktor der γ-Glutamyl-Carboxylase benötigt. Da Vitamin K essentiell ist, wird seine Epoxidform vom Organismus wieder in eine physiologisch aktive Hydrochinon-Form überführt. Für diese Reaktion wird die Vitamin K-Epoxid-Reduktase (VKORC1) benötigt. Mutationen in VKORC1 führen einerseits zu einem erblich bedingten Mangel an Vitamin K-abhängigen Gerinnungsfaktoren vom Typ 2 (VKCFD2) mit starken Blutungen durch eine nicht oder nur unvollständig ablaufende Blutgerinnung. Das VKORC1 ist andererseits auch das Ziel von Medikamenten der Coumaringruppe, der sog. Vitamin K-Antagonisten, die zur Verhinderung einer unzeitigen Gerinnung eingesetzt werden. In höheren Dosen wird diese Substanzklasse als Rattenbekämpfungsmittel eingesetzt. Bei manchen Rattenpopulationen, aber auch bei einigen Patienten, ist die Wirksamkeit der Coumarine durch bestimmte Mutationen im VKORC1-Protein, welche eine Warfarinresistenz hervorrufen, erheblich eingeschränkt. Zu diesem VKORC1 existiert ein paraloges Protein, das Vitamin K-Epoxid-Reduktase Komplex 1-like 1 Protein (VKORC1L1), dessen Funktion bislang unbekannt ist und welches Gegenstand der vorliegenden Arbeit war. Es wurden unterschiedliche Methoden angewandt, um das VKORC1L1-Protein zu charakterisieren und seine mögliche Funktion(en) aufzuklären. Zum einen sollte die Herstellung einer Knockout-Maus dazu dienen, durch den erhaltenen Phänotyp Hinweise auf die mögliche physiologische Aufgabe zu erhalten. Allerdings gelangten die Versuche nur bis zur Generierung der Chimären, so dass dieses Teilprojekt nicht zum Abschluss gebracht werden konnte. Die biochemische Charakterisierung des Proteins zeigte eine Expression des VKORC1L1-Gens in allen untersuchten Geweben, wobei keine starke Expression für ein bestimmtes Gewebe ermittelt werden konnte. Es konnte gezeigt werden, dass das Protein Vitamin K-Epoxid auf gleiche Weise wie das VKORC1 recyceln kann und durch Warfarin gehemmt wird. Einige der in eingeführten VKORC1L1 Mutationen vermitteln darüber hinaus eine Warfarinresistenz. Des Weiteren wurden Enzymkinetiken für die Spezies Maus und Ratte sowie für die Stachelmaus erstellt. Die erhaltenen Werte für die Michaelis-Menten-Konstante und die Maximalgeschwindigkeit sind untereinander sehr ähnlich und sprechen für eine Oxido-Reduktase-Aktivität des VKORC1L1-Proteins. Bioinformatische Analysen konzentrierten sich auf die Aufklärung von konservierten Aminosäureresten im VKORC1L1. Dadurch konnten funktionell wichtige Positionen des Proteins ermittelt werden. Ein evolutiver Stammbaum konnte weiterhin zeigen, dass die paralogen Proteine VKORC1 und VKORC1L1 sehr wahrscheinlich aus einem gemeinsamen Vorläuferprotein bei der Entwicklung der Wirbeltiere aus einer Duplikation entstanden sind und nach der Entstehung der Landwirbeltiere ihre spezifischen Funktionen ausgebildet haben. Ein Homologievergleich zwischen den humanen Chromosomen 7 und 16 und den jeweiligen Chromosomen verschiedener Spezies zeigte, dass sich nach der Duplikation die Gene für das VKORC1 und das VKORC1L1 bei fast allen betrachteten Spezies unabhängig voneinander auf verschiedenen Chromosomen evolutiv entwickelt haben. Dies ist ein weiteres Indiz dafür, dass die Duplikation schon sehr lange zurück liegt. / In 2004 two genes of a new protein family were cloned in our institute. Since then the characterization of this protein family is in progress. Through mutation and biochemical analyses one protein, VKORC1, could be identified as a central component of the so-called vitamin K cycle. Vitamin K is required as a cofactor of the γ-glutamyl carboxylase for the γ-carboxylation of the vitamin K-dependent proteins such as the coagulation factors II, VII, IX and X. As vitamin K is essential, the epoxide form is again transferred by the organism into a physiologically active hydrochinone form. For this reaction vitamin K epoxide reductase (VKORC1) is necessary. On the one hand mutations in VKORC1 lead to a hereditary combined deficiency of vitamin K-dependent clotting factors of type 2 (VKCFD2) with heavy bleedings because of missing or insufficient blood coagulation. On the other hand VKORC1 is also the target of medical treatment with the coumarin derivative group, the so-called vitamin K antagonists, which are used for preventing untimely coagulation. In higher doses this class of substances is used as rodenticides. In some rat populations as well as in case of some human patients the efficiency of the coumarins is considerably reduced through specific mutations in the VKORC1 protein leading to a warfarin resistance. There is a paralogue protein to VKORC1, the vitamin K epoxide reductase complex 1-like 1 protein (VKORC1L1), the function of which is not known so far and which is the subject of this study. Different methods have been applied in order to characterize the VKORC1L1-protein and to explain its potential functions. One the one hand, the creation of a knockout mouse was to give information on potential physiological tasks through its specific phenotype. The experiments, however, were only successful as far as the creation of chimeras was concerned. Thus, this part of the project could not be completed totally. The biochemical characterization showed an expression of the VKORC1L1-gene in all tissues examined. It was, however, not possible to find a strong expression for a specific tissue. We were able to show that the protein can recycle vitamin K epoxide in the same way as VKORC1 and that it is inhibited by warfarin. Some of the mutations within the VKORC1L1 lead to a warfarin resistance. Moreover, enzyme kinetics were applied for the mouse, rat and acomys species. The calculated values of the Michaelis-Menten constant and of the maximal speed Vmax are very similar to each other and support an oxido-reductase activity for the VKORC1L1-protein. Bioinformatic analyses were focused on the explanation of the conserved amino acids within VKORC1L1. So, functionally important positions could be determined. Moreover, an evolutionary life tree showed that the paralogue proteins VKORC1 and VKORC1L1 have probably been arisen from a common precursor protein by duplication when vertebrates developed and formed its specific functions after the tetrapod vertebrates came into being. A homological comparison between the human chromosomes 7 and 16 and the corresponding chromosomes of different species showed that the duplication of the genes for VKORC1 and VKORC1L1 evolved independently of each other on different chromosomes within all species examined. This is a further indication that the duplication took place a long time ago.
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High Field EPR and ENDOR Investigations on Radicals and Metal Centers in Subunit R2 Wild Type and Mutant Class Ia Ribonucleotide ReductaseAschaffenburg 02 October 2001 (has links) (PDF)
No description available.
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Oxidace ellipticinu lidskými cytochromy P450 exprimovanými v prokaryotním a eukaryotním systému / Oxidation of ellipticine by human cytochromes P450 expressed in prokaryotic and eukaryotic systemsVejvodová, Lucie January 2013 (has links)
Ellipticine is an alkaloid with antitumor activity, whose mechanism of action is based on intercalation into DNA, inhibition of topoisomerase II and formation of covalent adducts with DNA, after its enzymatic activation by cytochromes P450 and/or peroxidases. Ellipticine is oxidized by cytochromes P450 to form up to five metabolites (7-hydroxy-, 9-hydroxy, 12- hydroxy-, 13-hydroxyellipticine and N2 -oxide ellipticine). 9-Hydroxy- and 7- hydroxyellipticine are considered to be detoxification metabolites, whereas 12-hydroxy-, 13- hydroxyellipticine and N2 -oxide of ellipticine are considered as activation metabolites, which are responsible for formation of covalent DNA adducts. The aim of this thesis was to examine the efficiency of human recombinant cytochromes P450 expressed in eukaryotic (SupersomesTM ) and two prokaryotic expression systems (Bactosomes) in oxidation of ellipticine. Cytochromes P450 expressed in prokaryotic systems differed in the amounts of "coexpressed" NADPH:CYP reductase. The resulting ellipticine metabolites were analyzed by HPLC. The results obtained in this thesis demonstrate that human cytochromes P450 2C9/2D6/2C19 expressed in prokaryotic or eukaryotic systems oxidize ellipticine to form up to four metabolites: 9-hydroxy-, 12-hydroxy-, 13-hydroxyellipticine and N2 -oxide...
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Endotheliale Stickstoffmonoxidsynthase-vermittelte Effekte von HMG-CoA-Reduktase-Inhibitoren und körperlicher Aktivität im experimentellen SchlaganfallmodellGertz, Karen 25 April 2005 (has links)
HMG-CoA-Reduktasehemmer, sogenannte Statine, und regelmäßige körperliche Aktivität sind mit vermindertem Auftreten zerebrovaskulärer Ereignisse und Zunahme der endothelialen Stickstoffmonoxidsynthase (eNOS) assoziiert. Die Erhöhung der eNOS-mRNA ist mit verbessertem zerebralen Blutfluß und Neuroprotektion bei einer zerebralen Ischämie verbunden. Vor dem Hintergrund, daß Thrombosen und Thrombembolien die häufigste Ursache zerebro- und kardiovaskulärer Ereignisse darstellen, sind NO-vermittelte antithrombotische Effekte jedoch kaum untersucht. Ebenso wenig ist über mögliche Absetzeffekte nach Beendigung einer Statintherapie bekannt. Daher untersuchten wir, ob die Statine Atorva- und Rosuvastatin eNOS-abhängig zu Neuroprotektion führen und verglichen die Effekte mit einem zweiten eNOS-regulierenden Mechanismus: der regelmäßigen körperlichen Aktivität. Dazu quantifizierten wir nach entsprechender Vorbehandlung eNOS auf mRNA- und Proteinebene aus Aorten, Hirngewebe sowie Thrombozyten und bestimmten die Läsionsvolumina im experimentellen Schlaganfallmodell. Außerdem untersuchten wir nach Statingabe Thrombozytenfunktionsparameter sowie Blutungszeit und Thrombusformation in vivo. Zwei bzw. vier Tage nach Absetzen der Statinbehandlung wiederholten wir die eNOS-Messungen, Schlaganfallexperimente und Gerinnungsanalysen. Wir fanden nach Statinvorbehandlung cholesterinunabhängig eine Zunahme der eNOS, was mit Neuroprotektion im Schlaganfallmodell und verminderter Gerinnungsaktivität verbunden war. Nach Absetzen der Behandlung kam es jedoch zu einer drastischen Abnahme der eNOS, was mit deutlichem Anstieg der Thrombozytenmarker im Plasma und schnellem Verlust der beobachteten positiven Effekte auf Läsionsgröße und Gerinnungssystem einherging. Regelmäßige körperliche Aktivität führt ebenfalls eNOS-abhängig zu verbessertem zerebralen Blutfluß und kleineren Läsionsvolumina bei zerebraler Ischämie. Diese Ergebnisse sind mit den Daten nach Statingabe vergleichbar. Wir demonstrieren einen Klasseneffekt der Statine für eNOS-vermittelte Neuroprotektion im zerebralen Ischämiemodell. Durch die zusätzliche gerinnungshemmende Wirkung könnte diese Wirkstoffklasse neue Ansätze zur prophylaktischen Schlaganfallbehandlung unabhängig vom Cholesterinspiegel eröffnen. Ein Absetzen der Statinbehandlung kann jedoch zu einer Zunahme der Schlaganfallgröße führen und sollte möglicherweise bei Risikopatienten vermieden werden. Regelmäßiges körperliches Training führt zu vergleichbarer Erhöhung der eNOS sowie Neuroprotektion und bietet damit eine sinnvolle Verknüpfung aus prophylaktischer Schlaganfallbehandlung und Rehabilitation. / HMG-CoA-reductase inhibitors, so called statins and regular physical activity are associated with less cerebrovascular events and increase of endothelial nitric oxide synthase (eNOS). Raise of eNOS-mRNA results in cerebral blood flow (CBF) augmentation which refers neuroprotection after ischemic stroke. It is known that thromboses cause the most cerebrovascular events, but nitric oxide (NO) dependent antithrombotic effects are poor examined. In addition there are little information about effects after withdrawal of statin treatment. That is why we investigated Atorva- and Rosuvastatin regarding eNOS dependent neuroprotection and compared the effects with regular physical activity, the second eNOS enhancing mechanism. Therefore after corresponding pretreatment we quantified eNOS-mRNA and protein from aortas, brain tissue and thrombocytes and determined lesion volume after experimental middle cerebral artery occlusion (MCAo). Furthermore after statin treatment we measured marker of thrombocyte activation, as well as bleeding time and thrombus formation in vivo. Two and four days after withdrawal of statin treatment we repeated eNOS measurements, neuroprotection studies and coagulation analyses. We found eNOS upregulation independent from serum cholesterol level after statin pretreatment and this was associated with neuroprotection after ischemic stroke and decreased platelet activation. But after withdrawal of statin treatment eNOS expression was downregulated, which went along with clear upregulation of platelet activation and a rapid loss of the observed positive effects on lesion volume and hemostasis. Regular physical activity leads to an increase of eNOS, which we could correlate with CBF augmentation and improved outcome after MCAo. These results were comparable to the data after statin treatment. We demonstrate a class effect of statins for eNOS-dependent neuroprotection in our ischemia modell. Because of the additional antithrombotic effects statins may present a new approach to prophylactic stroke treatment independent from cholesterol level. Withdrawal of statin treatment may refer increased cerebral lesion volume and should be avoided in patients with risk for cerebrovascular events. Regular physical activity results in comparable eNOS dependent neuroprotection and offers a useful combination between prophylactic stroke treatment and rehabilitation.
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Genetische Faktoren der humanen CholesterinbiosyntheseBaier, Jan 22 October 2012 (has links) (PDF)
Background: Genome-wide association studies (GWAs) have identified almost one hundred genetic loci associated with variances in human blood lipid phenotypes including very low-density lipoprotein cholesterol, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, total cholesterol and triglycerides. Nevertheless the revealed loci only explain a small fraction of heritability and therefore a subtile phenotype of cholesterol homoestasis was examined in our study for the very first time.
Methods and Results: Using a multi-stage approach of a GWA, firstly, a genome-wide analysis (Affymetrix 500K GeneChip) for serum lanosterol and serum total cholesterol using LC-MS/MS was conducted in 1495 participants of the KORA-S3/F3 cohort with subsequent replication in two additional independent samples of the the KORA-S3/F3 cohort (n = 1157) and CARLA cohort (n = 1760). Two genetic variants, SNP rs7703051 and rs17562686, in the HMGCR locus were significantly associated with serum lanosterol and showed similar effects of elevated serum lanosterol for each minor allele (combined n = 4412: p = 1,4 x 10-10, +7,1% and p = 4,3 x 10-6, +7,8%). Furthermore, rs7703051 showed a nominal statistical significance to serum cholesterol (p = 0,04). A combined analysis of both SNPs demonstrated that observed associations of rs17562686 can be partly explained by LD with rs7703051 being the primary polymorphism in that study. Nevertheless, rs17562686 shows consistent independent effects on serum lanosterol, thus being associated to a lipid phenotype for the very first time. The following SNP-fine mapping of the HMGCR locus was carried out in the CARLA cohort with subsequent validation in the LE-Heart cohort (n = 1895). The recently published SNP rs3846662 being in tight LD with rs7703051 could be associated with variances of serum lanosterol in both cohorts and functional in vivo studies of gen expression using qRT-PCR assays demonstrated a highly significant association of higher expression of alternatively spliced HMGCR mRNA lacking exon 13 with homozygosity for the rs3846662 major allele in 51 human liver samples (p < 0,01) and 958 human PBMCs (p = 2,1 x 10-7). The overall HMGCR gen expression was not affected. Further investigation of in vivo HMG-CoA reductase enzyme activity in both human samples (n = 48 and n = 55) using anionic exchange column chromatography and scintillation counting of [3-14C]-HMG-CoA and [5-3H]-mevalonolacton did not show any significant results. In addition there was not any association in the LE-Heart cohort between these SNPs and the development of CAD. Finally, rs7703051 could be replicated for already published total cholesterol (combined n = 4412) and rs3846662 for LDL-cholesterol (LE-Heart n = 1895). Since fine mapping in CARLA showed several SNPs throughout the HMGCR locus being in LD with rs17562686 we performed a DNA sequencing of the extended 5´-HMGCR promotor region in six human liver samples. A unknown SNP was discovered in the promotor but could not be associated with any of the examined phenotypes mentioned above. The minor allele of SNP rs5909 situated next to the stop codon and being in high LD with rs17562686 was associated with elevated serum lanosterol and slightly reduced HMGCR gen expression, but further studies including the above mentioned as well as measurement of 3’-UTR transcript lengths using qRT-PCR assays did not produce significant results.
Conclusion: The phenotype serum lanosterol could be associated with genetic polymorphisms (e.g. rs7703051) in the HMGCR locus. Therefore already published associations of HMGCR with total cholesterol and LDL-cholesterol can be explained by variances of cholesterol homeostasis. The SNP rs17562686 could be associated with a phenotype of human blood lipids for the very first time. Subsequent gen expression analyses demonstrated a highly significant association of rs3846662 with variant patterns of HMGCR alternative splicing. A significant effect of alternatively spliced protein on enzyme activity and a association of these SNPs with CAD could not be shown.
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Funktionelle Charakterisierung potentieller Pathogenitätsfaktoren aus Pseudomonas aeruginosa mittels biochemischer und evolutiver Methoden / functional characterization of potential pathogenicity factors from Pseudomonas aeruginosa by biochemical and evolutionary methodsAdams, Thorsten 27 January 2005 (has links)
No description available.
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Funktionelle Genomanalyse des Purinverwerters Clostridium acidurici 9a / Functional genome analysis of the purine-utilizing bacterium Clostridium acidurici 9aHartwich, Katrin 05 December 2012 (has links)
No description available.
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Fluorescence in blue light (FLU): Functional analysis of its structural domains for light and dark-dependent control of ALA synthesisHou, Zhiwei 06 January 2020 (has links)
Fluorescence in blue light (FLU) ist ein negativer Feedbackregulator der Chlorophyllbiosynthese, welcher an der Dunkelrepression der 5-Aminolävulinsäure (ALA)-Synthese beteiligt ist. FLU ist Teil eines Komplexes, der die Enzyme umfasst, welche an der Katalyse der finalen Schritte der Chlorophyllbiosynthese beteiligt sind. Drei funktionelle Domänen wurden für das Arabidopsis FLU Protein postuliert: eine Tetratricopeptid-Wiederholungsdomäne (TPR) befindet sich am C-Terminus; eine Transmembrandomäne (TM) ist am N-Terminus lokalisiert; eine Coiled-coil-Domäne (linker) liegt dazwischen. Die TPR-Domäne von FLU Domäne interagiert mit dem C-terminalen Ende der Glutamyl-tRNA Reduktase (GluTR), dem geschwindigkeitsbestimmenden Enzym der ALA-Synthese.
Diese Arbeit zur Erweiterung des Wissen über die Funktion von FLU im Licht sowie über die Rolle der funktionellen Domänen von FLU bei der Inaktivierung der ALA-Synthese bei. / Fluorescence in blue light (FLU), a negative feedback regulator of chlorophyll biosynthesis, is involved in dark repression of 5-aminolevulinic acid (ALA) synthesis. FLU is part of a complex comprising the enzymes catalyzing the final steps of chlorophyll synthesis. Three functional domains were proposed in the Arabidopsis FLU protein: a tetratricopeptide repeat (TPR) domain is at the C-terminus; a transmembrane domain (TM) is at the N-terminus; a coiled-coil domain (linker) is in between. The TPR(FLU) domain interacts with the C-terminal end of glutamyl-tRNA reductase (GluTR), the rate-limiting enzyme of ALA synthesis.
This thesis contributes to the extended knowledge about the function of FLU in light as well as the role of the structural domains of FLU in the inactivation of ALA synthesis.
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Genetische Faktoren der humanen CholesterinbiosyntheseBaier, Jan 10 October 2012 (has links)
Background: Genome-wide association studies (GWAs) have identified almost one hundred genetic loci associated with variances in human blood lipid phenotypes including very low-density lipoprotein cholesterol, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, total cholesterol and triglycerides. Nevertheless the revealed loci only explain a small fraction of heritability and therefore a subtile phenotype of cholesterol homoestasis was examined in our study for the very first time.
Methods and Results: Using a multi-stage approach of a GWA, firstly, a genome-wide analysis (Affymetrix 500K GeneChip) for serum lanosterol and serum total cholesterol using LC-MS/MS was conducted in 1495 participants of the KORA-S3/F3 cohort with subsequent replication in two additional independent samples of the the KORA-S3/F3 cohort (n = 1157) and CARLA cohort (n = 1760). Two genetic variants, SNP rs7703051 and rs17562686, in the HMGCR locus were significantly associated with serum lanosterol and showed similar effects of elevated serum lanosterol for each minor allele (combined n = 4412: p = 1,4 x 10-10, +7,1% and p = 4,3 x 10-6, +7,8%). Furthermore, rs7703051 showed a nominal statistical significance to serum cholesterol (p = 0,04). A combined analysis of both SNPs demonstrated that observed associations of rs17562686 can be partly explained by LD with rs7703051 being the primary polymorphism in that study. Nevertheless, rs17562686 shows consistent independent effects on serum lanosterol, thus being associated to a lipid phenotype for the very first time. The following SNP-fine mapping of the HMGCR locus was carried out in the CARLA cohort with subsequent validation in the LE-Heart cohort (n = 1895). The recently published SNP rs3846662 being in tight LD with rs7703051 could be associated with variances of serum lanosterol in both cohorts and functional in vivo studies of gen expression using qRT-PCR assays demonstrated a highly significant association of higher expression of alternatively spliced HMGCR mRNA lacking exon 13 with homozygosity for the rs3846662 major allele in 51 human liver samples (p < 0,01) and 958 human PBMCs (p = 2,1 x 10-7). The overall HMGCR gen expression was not affected. Further investigation of in vivo HMG-CoA reductase enzyme activity in both human samples (n = 48 and n = 55) using anionic exchange column chromatography and scintillation counting of [3-14C]-HMG-CoA and [5-3H]-mevalonolacton did not show any significant results. In addition there was not any association in the LE-Heart cohort between these SNPs and the development of CAD. Finally, rs7703051 could be replicated for already published total cholesterol (combined n = 4412) and rs3846662 for LDL-cholesterol (LE-Heart n = 1895). Since fine mapping in CARLA showed several SNPs throughout the HMGCR locus being in LD with rs17562686 we performed a DNA sequencing of the extended 5´-HMGCR promotor region in six human liver samples. A unknown SNP was discovered in the promotor but could not be associated with any of the examined phenotypes mentioned above. The minor allele of SNP rs5909 situated next to the stop codon and being in high LD with rs17562686 was associated with elevated serum lanosterol and slightly reduced HMGCR gen expression, but further studies including the above mentioned as well as measurement of 3’-UTR transcript lengths using qRT-PCR assays did not produce significant results.
Conclusion: The phenotype serum lanosterol could be associated with genetic polymorphisms (e.g. rs7703051) in the HMGCR locus. Therefore already published associations of HMGCR with total cholesterol and LDL-cholesterol can be explained by variances of cholesterol homeostasis. The SNP rs17562686 could be associated with a phenotype of human blood lipids for the very first time. Subsequent gen expression analyses demonstrated a highly significant association of rs3846662 with variant patterns of HMGCR alternative splicing. A significant effect of alternatively spliced protein on enzyme activity and a association of these SNPs with CAD could not be shown.
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