Background: The primary objective of this review was to explore the contribution of oxidative stress to the pathogenesis of genetically-triggered thoracic aortic aneurysm (TAA). Genetically-triggered TAAs manifest substantial variability in onset, progression, and risk of aortic dissection, posing a significant clinical management challenge. There is a need for non-invasive biomarkers that predict the natural course of TAA and therapeutics that prevent aneurysm progression. Methods: An online systematic search was conducted within PubMed, MEDLINE, Scopus and ScienceDirect databases using keywords including: oxidative stress, ROS, nitrosative stress, genetically triggered thoracic aortic aneurysm, aortic dilatation, aortic dissection, Marfan syndrome, Bicuspid Aortic Valve, familial TAAD, Loeys Dietz syndrome, and Ehlers Danlos syndrome. Results: There is extensive evidence of oxidative stress and ROS imbalance in genetically triggered TAA. Sources of ROS imbalance are variable but include dysregulation of redox mediators leading to either insufficient ROS removal or increased ROS production. Therapeutic exploitation of redox mediators is being explored in other cardiovascular conditions, with potential application to TAA warranting further investigation. Conclusion: Oxidative stress occurs in genetically triggered TAA, but the precise contribution of ROS to pathogenesis remains incompletely understood. Further research is required to define causative pathological relationships in order to develop therapeutic options.
Genetically triggered thoracic aortic aneurysms (TAAs) account for 30% of all TAAs and can result in early morbidity and mortality in affected individuals. Epigenetic factors are now recognised to influence the phenotype of many genetically triggered conditions and have become an area of interest because of the potential for therapeutic manipulation. Major epigenetic modulators include DNA methylation, histone modification and non-coding RNA. This review examines epigenetic modulators that have been significantly associated with genetically triggered TAAs and their potential utility for translation to clinical practice.
Multiple genes are associated with thoracic aortic aneurysm (TAA) formation, including FBN1, TGFBR1&2, COL3A1 & 5A2, and MYH11. Given the population incidence of mutations in these genes we hypothesise that it is likely that ‘double hit’ mutations occur, which may result in an altered clinical phenotype when compared with the single gene mutation.
Genomic DNA analysis of 19 genes implicated in TAA was performed on 12 patients with inherited TAA disease. Of the patients analysed, one patient (P1) was identified as having a mutation in both MYH11 (c.2517G.C (pW839C)) and FBN1 (splice donor site c.4210+1G>A). Another patient (P2) was identified as having both COL5A2 (c.3794A>G (pD1265G)) and FBN1 (c.5861T>G (p.F1954C)). All mutations were predicted by PolyPhen to be deleterious.
P1 has Marfan Syndrome (MFS), caused by the FBN1 mutation, and has severe aortic dilatation while his mother (M1), who also has MFS but does not have the MHY11 mutation, developed mild aortic dilatation, suggesting that the MHY11 mutation in P1 has resulted in a more aggressive phenotype.
P2, siblings S1 and S2 and father (F2) all have relatively less severe MFS with progressive moderate dilatation of the aorta. Thus, the phenotype of pedigree 2 is similar for all affected members, but only P2 has a double hit mutation, suggesting that the presence of the COL5A2 mutation in P2 has not altered the clinical phenotype.
This is the first instance where double hit mutations have been described in inherited thoracic aortic aneurysm but the effect of multiple mutations on phenotype appears to be variable. Mutation analysis for individuals with inherited thoracic aortic aneurysm should consider the possibility of multiple gene culprits.
mutants with either wild type TRPML3 or a non-functional ER-retained mutant, TRPML3-KK, we examined how differentially targeted TRPML1 proteins affect TRPML3 localization. We show that while the wild type TRPML1 decreased the PM targeting of TRPML3, the PM-targeted TRPML1 mutants did not enhance PM localization of TRPML3. Interestingly, not only the wild type TRPML1 brought TRPML3-KK to lysosomes, but also TRPML3 brought the ER-retained TRPML1-KK to these acidic organelles. Moreover, coexpression of TRPML-KK not only reduced TRPML3-mediated Ca 2þ response to a TRPML agonist, but also nearly abolished PM localization of TRPML3. We conclude that while the lysosome targeting sequence(s) is important for sorting TRPML channels out of ER-Golgi network, the ion-conducting function may be critical for PM trafficking of these endolysosomal channels.
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