Doctoral Degrees (Molecular Biology and Human Genetics)
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Browsing Doctoral Degrees (Molecular Biology and Human Genetics) by Subject "AKAP"
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- ItemInvestigations of the role of myomegalin in the phosphorylation of cardiac myosin binding protein C(Stellenbosch : University of Stellenbosch, 2010-12) Uys, Gerrida Mathilda; Moolman-Smook, Johanna Catharina; University of Stellenbosch. Faculty of Health Sciences. Dept. of Biomedical Sciences.ENGLISH ABSTRACT: Hypertrophic cardiomyopathy (HCM) is the most common inherited cardiac muscle disorder worldwide. The disease is characterized by extreme variability in the amount of hypertrophy that develops in different patients in response to sarcomeric protein-encoding gene mutations. The underlying defect in HCM is altered contractility of the sarcomere, primarily due to a defective sarcomere. Although numerous disease-causing genes have been identified for HCM, the factors that modify the amount of hypertrophy that develops in a given person are still unknown, it can be hypothesized that molecules that affect contractility can act as modifiers of the hypertrophic signal, and therefore influence the development of hypertrophy. Cardiac contractility is regulated by dynamic phosphorylation of proteins within the sarcomere by kinases such as cAMP-activated protein kinase A (PKA). Because speed and energy efficiency of cardiac muscle contraction has to be regulated in order to match the body’s needs, PKA is anchored close to its targets by A-kinase anchoring proteins (AKAPs) to enable spatio-temporal control of phosphorylation. Cardiac myosin binding protein-C (cMyBPC) and cardiac troponin I (cTNI) are HCM-causing sarcomeric proteins which regulate contractility in response to PKA phosphorylation. In a previous study, our laboratory identified a phosphodiesterase 4D-interacting protein as ligand of the N-terminal of cMyBPC via a yeast-two-hybrid (Y2H) cardiac library screen. This protein is also known in the literature as myomegalin (MMGL) isoform 4. Because phosphodiesterases and PKA are sometimes anchored by the same anchoring protein (AKAP), we hypothesized that MMGL isoform 4 acts as an AKAP by anchoring PKA to the phosphorylatable N-terminal of cMyBPC, and tested this by direct protein-protein interaction analyses in a yeast-based system. The MMGL cDNA was cloned into a bait vector, which was directly assessed for interaction with two distinct PKA regulatory-subunit preys. We further investigated the function of MMGL itself by using the Y2H bait to screen a cardiac cDNA library for novel MMGL interactors. All the prey clones identified via these Y2H analyses were subsequently sequenced to determine their identity. Based on their identities and subcellular localization, all putative Y2H MMGL-prey interactions were further assessed by additional, separate biochemical techniques viz. in vivo co-immunoprecipitation and in vivo 3D co-localization. The interactions between MMGL and its known PKA-phosphorylatable sarcomeric ligands were also investigated under conditions of β-adrenergic stress, by quantitatively measuring levels of co-localization before and upon addition of the β-adrenergic agonist isoproterenol. Furthermore, in order to evaluate the role of MMGL in cMyBPC phosphorylation, we assessed the expression of the different phosphorylation isoforms of cMyBPC, with and without β-adrenergic stimulation, in the context of siRNA-mediated MMGL knockdown. We further hypothesized that MMGL and PKA may serve as modifiers of the hypertrophic phenotype. This was tested by conducting a single nucleotide polymorphism (SNP) genotyping study of the genes encoding MMGL and the regulatory subunits of PKA viz. PDE4DIP, PRKAR1A and PRKAR2A, respectively, and comparing genotypic data with clinical phenotypic traits in a family-based association study. A panel of 353 individuals, including genetically and clinically affected as well as unaffected HCM individuals, was identified. All these individuals were screened for the presence or absence of all three South African HCM founder mutations, and blood was collected and DNA extracted. Genotypes at multiple SNPs in each gene were determined by subjecting the DNA samples to TaqMan® allelic discrimination technology. Statistical analysis using quantitative transmission disequilibrium testing (QTDT) was done in order to establish whether the difference in genotype in these three genes might have an effect on HCM phenotype. Our results showed that MMGL interacted with both PKA regulatory subunits as well as with other cardiac proteins that are PKA targets, including the sarcomeric protein cTNI. It was confirmed that two regulatory subunits of PKA (PRKAR1A and PRKAR2A), cardiac ankyrin repeat protein (CARP), copper metabolism gene MURR1 domain 4 (COMMD4), α-enolase (ENO1), β-enolase (ENO3) and cTNI are novel interactors of MMGL. In order to classify a protein as an AKAP, interaction with one of PKA’s regulatory subunits are prerequisite; MMGL showed interaction with both, confirming our hypothesis of MMGL being an AKAP, moreover, classifying it as a novel dual-specific sarcomeric AKAP. The identities of the AKAPs involved in the phosphorylation of cMyBPC and cTNI had been unknown; our results indicate that MMGL is the AKAP involved in the phosphorylation of both these PKA targets. We also showed that quantitatively more interaction occurs between MMGL and its sarcomeric ligands cMyBPC and cTNI under β-adrenergic stress. This implicates that under elevated cAMP levels, PKA is dynamically recruited by MMGL to the PKA targets cMyBPC and cTNI, presumably to mediate cardiac stress responses and leading to increased cardiac contractility. Furthermore, siRNA-mediated knockdown of MMGL lead to a reduction of cMyBPC levels under conditions of β-adrenergic stress, indicating that MMGL-assisted phosphorylation is requisite for protection of cMyBPC against proteolytic cleavage. The SNP modifier study indicated that one variant in PDE4DIP (rs1664005) showed strong association with numerous clinical hypertrophy traits, including maximal interventricular septum thickness, as well as a number of other composite score traits. Two variants in PRKAR1A (rs11651687 and rs3785906) also showed strong association with some of these clinical hypertrophy traits. These results therefore suggest that variants in these two genes may act as modifiers of the HCM phenotype. In conclusion, this study ascribes a novel function to MMGL isoform 4: it meets all criteria for classification as an AKAP and appears to be involved in the phosphorylation of cMyBPC as well as cTNI; hence MMGL is likely to be an important component in the regulation of cardiac contractility, and by extension, in the development of hypertrophy. This has further implications for understanding the patho-aetiology of mutations in cMyBPC and cTNI, and raises the question of whether MMGL might itself be considered a candidate HCM-causing factor.