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A candidate and novel gene search to identify the PFHBII-causative geneFernandez, Pedro 12 1900 (has links)
Thesis (PhD)--Stellenbosch University, 2004. / Bibliography / ENGLISH ABSTRACT: Heart failure due to cardiomyopathy or cardiac conduction disease is a major cause of
mortality and morbidity in both developed and developing countries. Although defined as
separate clinical entities, inherited forms of cardiomyopathies and cardiac conduction
disorders have been identified that present with overlapping clinical features and/or have
common molecular aetiologies.
The objective of the present study was to identify the molecular cause of progressive familial
heart block type II (PFHBII), an inherited cardiac conduction disorder that segregates in a
South African Caucasian Afrikaner family (Brink and Torrington, 1977). The availability of
family data tracing the segregation of PFHBII meant that linkage analysis could be employed
to identify the chromosomal location of the disease-causative gene. Human Genome Project
(HGP) databases have provided additional resources to facilitate the identification of
positional candidate genes. Clinical examinations were performed on individuals of the PFHBII-affected family, and,
where available, clinical records of subjects examined in a previous study by Brink and
Torrington (1977) were re-assessed. Retrospective data suggested redefining the classification
of PFHBII. Subsequently, linkage analysis was used to test described dilated cardiomyopathy
(DCM), hypertrophic cardiomyopathy (HCM) and cardiac conduction-causative loci on
chromosomes 1, 2, 3, 6, 7, 9, 11, 14, 15 and 19 for their involvement in the development of
PFHBII. Once a locus was mapped, bioinformatics tools were applied to identify and
prioritise positional candidate genes for mutation screening.
The retrospective and prospective clinical study redefined PFHBII as a cardiac conduction
and DCM-associated disorder and simultaneously allowed more family members to be traced. Fortuitously, candidate loci linkage analysis mapped the PFHBII locus to chromosome 1q32,
to a region that overlapped a previously described DCM-associated disorder (CMD1D), by
the generation of a maximum pairwise lod score of 3.13 at D1S3753 (theta [θ]=0.0) and a
maximum multipoint lod score of 3.7 between D1S3753 and D1S414. However, genetic fine
mapping and haplotype analysis placed the PFHBII-causative locus distal to the CMD1D
locus, within a 3.9 centimorgan (cM) interval on chromosome 1q32.2-q32.3, telomeric of
D1S70 and centromeric of D1S505. Bioinformatics analyses prioritised seven candidate genes
for mutation analysis, namely, a gene encoding a potassium channel (KCNH1), an
extracellular matrix protein (LAMB3), a protein phosphatase (PPP2R5A), an adapter protein
that interacts with a cytoskeletal protein (T3JAM), a putative acyltransferase (KIAA0205) and
two genes encoding proteins possibly involved in energy homeostasis (RAMP and VWS59).
The PFHBII-causative mutation was not identified, although single sequence variations were
identified in four of the seven candidate genes that were screened. Although the molecular aetiology was not established, the present study defined the
underlying involvement of DCM in the pathogenesis of PFHBII. The new clinical
classification of PFHBII has been published (Fernandez et al., 2004) and should lead to
tracing more affected individuals in South Africa or elsewhere. The identification of a novel
disease-causative locus may point toward the future identification of a new DCM-associated
aetiology, which, in turn, might provide insights towards understanding the associated
molecular pathophysiologies of heart failure. / AFRIKAANSE OPSOMMING: Hartversaking as gevolg van kardiomiopatie of kardiale geleidingsiekte is ‘n hoof-oorsaak
van mortaliteit and morbiditeit in beide ontwikkelde en ontwikkelende lande. Alhoewel
gedefinieer as verskillende kliniese entiteite is oorerflike vorms van kardiomiopatie en
kardiale geleidingsstoornisse geïdentifiseer met oorvleuelende kliniese eienskappe en/of
molukulêre oorsake.
Die doelwit van hierdie studie was om die molukulêre oorsaak van progressiewe familiële
hartblok tipe II (PFHBII), ‘n oorerflike kardiale geleidingsstoornis, wat in ‘n Suid-Afrikaanse
Kaukasiër familie segregeer (Brink en Torrington, 1977), te identifiseer. Die beskikbaarheid
van familie data, beteken dat koppelingsanalise gebruik kan word om die chromosomale
posisie van die siekte-veroorsakende geen te identifiseer. Menslike Genoom Projek (MGP)
databanke het addisionele hulpbronne beskikbaar gestel om die identifikasie van posisionele
kandidaat gene te vergemaklik.
Kliniese ondersoeke is uitgevoer op PFHBII-geaffekteerde familielede, en waar beskikbaar is
kliniese rekords van persone, wat in ‘n vorige studie deur Brink en Torrington (1977)
geassesseer was, herontleed. Retrospektiewe data-analise het die kliniese herdefinisie van
PFHBII voorgestel. Daarna is koppelingsanalise gebruik om dilateerde kardiomiopatie
(DKM), hipertrofiese kardiomiopatie (HKM) en kardiale geleidingssiekte-veroorsakende loki
op chromosoom 1, 2, 3, 6, 7, 9, 11, 14, 15 en 19 te ondersoek vir hul moontlike bydrae tot die
ontwikkeling van PFHBII. Toe die lokus gekarteer was, is bioinformatiese ondersoeke
gebruik om posisionele kandidaat gene te identifiseer en prioritiseer vir mutasie analise.
Die retrospektiewe en prospektiewe kliniese ondersoek het PFHBII herdefinieer as ‘n
geleidingsstoornis en DKM-verbonde siekte, en terselfde tyd het dit gelei tot die opsporing van nog familielede. Toevallig het kandidaat loki-analise die PFHBII lokus op chromosoom
1q32 gekarteer, na ‘n gebied wat met ‘n voorheen-beskyfde DKM-verbonde stoornis
(CMD1D) oorvleuel, met die opwekking van ‘n makisimum paargewyse lod-getal van 3.13
by D1S3753 (theta [θ] = 0.0) en ‘n maksimum multipunt lod-getal van 3.7 tussen D1S3753 en
D1S414. Genetiese fynkartering en haplotipe-analise het die PFHBII-veroorsakende lokus
afwaards van die CMD1D lokus geplaas, in ‘n 3.9 centimorgan (cM) gebied op chromosoom
1q32.2-q32.3, telomeries van D1S70 en sentromeries van D1S505. Bioinformatiese analise
het daarnatoe gelei dat sewe kandidaat gene vir mutasie analise geprioritiseerd is, naamlik,
gene wat onderskeidelik ‘n kalium kanaal (KCNH1), ‘n ekstrasellulêre matriksproteïen
(LAMB3), ‘n proteïen fosfatase (PPP2R5A), ‘n aansluiter proteïen wat met ‘n sitoskilet
proteïen bind (T3JAM), ‘n asieltansferase (KIAA0205) en twee gene moontlik betrokke in
energie homeostase (RAMP en VWS59) enkodeer. Die PFHBII-veroorsakende geen is nie
geïdentifiseer nie, alhoewel enkele volgorde-wisselings geïdentifiseer is in vier van die sewe
geanaliseerde kandidaat gene. Alhowel die molekulêre oorsaak van die siekte nie vasgestel is nie, het die huidige studie die
onderliggende betrokkenheid van DKM in die pathogenese van PFHBII gedefinieer. Die
nuwe kliniese klassifikasie van PFHBII is gepubiliseer (Fernandez et al., 2004) en sal lei tot
die identifisering van nog geaffekteerde persone in Suid Afrika of in ander lande. Die
identifikasie van ‘n nuwe siekte-verbonde lokus mag lei tot die toekomstige identifikasie van
‘n nuwe DKM-verbonde genetiese oorsaak wat, opsig self, dalk insig kan gee in die
molekulêre patofisiologie van hartversaking.
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Identification of novel sarcomeric modifiers of hypertrophy in hypertrophic cardiomyopathy using the yeast two-hybrid systemTodd, Carol 03 1900 (has links)
Thesis (MScMedSc)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Left ventricular hypertrophy (LVH) occurs when the cardiomyocytes in the left ventricle become enlarged by increasing in mass in response to haemodynamic pressure overload. This can either be attributed to a normal physiological response to exercise or can be the result of a maladaptive process or disease state, such as chronic hypertension. Hypertrophic cardiomyopathy (HCM) is the most common form of Mendelian-inherited cardiac disease. A defining characteristic thereof is primary LVH that occurs when there are no other hypertrophy-predisposing conditions present. Therefore, HCM provides a unique opportunity to study the molecular determinants of LVH in the context of a Mendelian disorder, instead of in more complex disorders such as hypertension. Over 1000 HCM-causing mutations in 19 genes have been identified thus far, most of them encoding sarcomeric proteins residing in the sarcomeric C-zone. However, for many HCM patients no disease-causing genes have been identified. Moreover, studies have shown phenotypic variation in presentation of disease in, as well as between, families in which the same HCM-causing mutation segregates. This has led many investigators to conclude that genetic modifiers of hypertrophy exist.
The aim of the study was to identify novel plausible HCM-causing or modifier genes by searching for interactors of a known HCM-causing protein, namely titin. The hypothesis was that genes encoding proteins, which interact with proteins that are encoded by known HCM-causative genes, may also be considered HCM-causing or may modify the HCM phenotype. To this end, the aim was to identify novel interactors of the 11-domain super-repeat region of titin, which resides within the sarcomeric C-zone, using yeast two-hybrid analysis. Five putative interactors of the 11-domain super-repeat region of titin were identified in this study. These interactions were subsequently verified by colocalisation in H9C2 rat cardiomyocytes, providing further evidence for possible interactions between titin and these proteins.
The putative interactor proteins of titin determined from the Y2H library screen were: filamin C (FLNC), phosphatidylethanolamine-binding protein 4 (PEBP4), heart-type fatty acid binding protein 3 (H-FABP3), myomesin 2 (MYOM2) and myomesin 1 (MYOM1).
The FLNC gene could be a candidate for cardiac diseases, especially cardiomyopathies that are associated with hypertrophy or developmental defects. The putative interaction of titin and PEBP4 is speculated to be indicative of the formation of the interstitial fibrosis and myocyte disarray seen in HCM. Heart-type fatty acid-binding protein 3 has prognostic value to predict recurrent cardiac events. Its suggested interaction with titin is speculated to play a role in inhibiting its functional abilities. Myomesin 2 is jointly responsible, with MYOM1, for the formation of a head structure on one end of the titin string that connects the Z and M bands of the sarcomere. This is speculated to be linked to a developmental error with the result being a defect in sarcomeric structure formation, which could result in pathologies such as HCM.
Therefore, these identified proteins could likely play a functional role in HCM due to their interactions with titin. This research could thus help with new insights into the further understanding of HCM patho-aetiology. / AFRIKAANSE OPSOMMING: Linker ventrikulêre hipertrofie (LVH) ontstaan wanneer die kardiomyosiete in die linkerventrikel vergroot as gevolg van 'n verhoging in massa in reaksie op hemodinamiese drukoorlading. Dit kan toegeskryf word aan 'n normale fisiologiese respons op oefening of kan die gevolg wees van 'n wanaangepaste of siektetoestand, soos chroniese hipertensie. Hipertrofiese kardiomiopatie (HKM) is die mees algemene vorm van Mendeliese oorerflike hartsiekte. 'n Bepalende eienskap daarvan is primêre LVH, wat plaasvind wanneer daar geen ander hipertrofie-predisponerende voorwaardes teenwoordig is nie. Gevolglik bied HKM 'n unieke geleentheid om die molekulêre derterminante van LVH te bestudeer, in die konteks van 'n Mendeliese oorerflike siekte, in plaas van om dit in die meer komplekse siektes soos hoë bloeddruk te bestudeer. Meer as 1000 HKM-veroorsakende mutasies is tot dusver in 19 gene geïdentifiseer. Die meeste van hulle kodeer vir sarkomeriese proteïene wat in die C-sone voorkom. Egter, vir baie HKM-pasiënte is geen siekte-veroorsakende gene al geïdentifiseer nie. Daarbenewens het studies getoon dat variasie in fenotipiese aanbieding van die siekte in, sowel as tussen, families voorkom wat dieselfde HKM-veroorsakende mutasie het. Dit het daartoe gelei dat baie navorsers tot die gevolgtrekking gekom het dat genetiese wysigers van hipertrofie wel bestaan.
Die doel van die studie was om nuwe moontlike HKM-veroorsakende of wysiger-gene te identifiseer deur te soek vir interaktors van 'n bekende HKM-veroorsakende proteïen, naamlik titin. Die hipotese was dat gene wat vir proteïene kodeer, wat in wisselwerking is met proteïene wat geïnkripteer word deur bekende HKM-veroorsakende gene, ook oorweeg kan word om HKM te veroorsaak. Dit kan ook die HKM fenotipe verander. Dus was die doel om nuwe interaktors van die 11-domein super-herhaalstreek van titin, soos gevind binne die sarkomeriese C-sone, te identifiseer deur middel van gis-twee-hibried-analise. Vyf vermeende interaktors van die 11-domein super-herhaalstreek van titin is in hierdie studie geïdentifiseer. Hierdie interaksies is later geverifieer met behulp van ko-lokalisering in H9C2-rotkardiomyosiete, wat verdere bewyse vir moontlike interaksies tussen titin en hierdie proteïene verskaf.
Die vermeende interaktor-proteïene van titin wat bepaal is vanaf die gis-twee-hibried-biblioteeksifting was as volg: filamin C (FLNC), phosphatidylethanolamine-bindingsproteïen 4 (PEBP4), hart-tipe-vetsuur bindingsproteïen 3 (H-FABP3), myomesin 2 (MYOM2) en myomesin 1 (MYOM1).
Die FLNC-geen kan 'n kandidaat vir kardiale siektes, veral kardiomiopatieë, wees wat geassosieer word met hipertrofie of ontwikkelingsafwykings. Die vermeende interaksie van titin en PEBP4 dui daarop om 'n aanduiding te wees vir die vorming van die interstisiële fibrose en miokardiale wanorde, soos gesien in HKM. Hart-tipe-vetsuur bindingsproteïen 3 het prognostiese waarde om herhalende kardiale gebeure te voorspel. Verder dui sy voorgestelde interaksie met titin moontlik daarop dat dit 'n rol kan speel in die inhibering van sy funksionele vermoëns. Myomesin 2 tesame met MYOM1 is verantwoordelik vir die vorming van 'n kopstruktuur aan die een kant van die titinstring wat dan die Z- en M-bande van die sarkomeer verbind. Daar word vermoed dat dit gekoppel is aan 'n ontwikkelingsfout, met die gevolg dat daar 'n defek is in sarkomeriese struktuurvorming, wat weer kan lei tot patologieë soos HKM. / Mrs Wendy Ackerman / Prof Paul van Helden / National Research Foundation (NRF) / Stellenbosch University
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