Human mitochondrial DNA (mtDNA) shows extensive within population sequence variability. Many studies suggest that mtDNA variants may be associated with ageing or diseases, although mechanistic evidence at the molecular level is lacking. Mitochondrial replacement has the potential to prevent transmission of disease-causing oocyte mtDNA. However, extension of this technology requires a comprehensive understanding of the physiological relevance of mtDNA sequence variability and its match with the nuclear-encoded mitochondrial genes. Studies in conplastic animals allow comparison of individuals with the same nuclear genome but different mtDNA variants, and have provided both supporting and refuting evidence that mtDNA variation influences organismal physiology. However, most of these studies did not confirm the conplastic status, focused on younger animals, and did not investigate the full range of physiological and phenotypic variability likely to be influenced by mitochondria. Here we systematically characterized conplastic mice throughout their lifespan using transcriptomic, proteomic,metabolomic, biochemical, physiological and phenotyping studies. We show that mtDNA haplotype profoundly influences mitochondrial proteostasis and reactive oxygen species generation,insulin signalling, obesity, and ageing parameters including telomere shortening and mitochondrial dysfunction, resulting in profound differences in health longevity between conplastic strains.
< 0.001. Two-tailed Student's t-test (last normoxia time versus hypoxia times in KO + pNCLX; d, e): & P < 0.05, && P < 0.01. In f, h, statistical comparisons are shown only for normoxia versus 0-10 groups. AU, arbitrary units; NS, not significant.
The introduction of the PKP2 R735X mutation into mice resulted in an exercise-dependent ARVC phenotype. The R735X mutation appears to function as a dominant-negative variant. This novel system for AAV-mediated introduction of a mutation into wild-type mice has broad potential for study of the implication of diverse mutations in complex cardiomyopathies.
Vascular stiffness is a major cause of cardiovascular disease during normal aging and in Hutchinson–Gilford progeria syndrome (HGPS), a rare genetic disorder caused by ubiquitous progerin expression. This mutant form of lamin A causes premature aging associated with cardiovascular alterations that lead to death at an average age of 14.6 years. We investigated the mechanisms underlying vessel stiffness in LmnaG609G/G609G mice with ubiquitous progerin expression, and tested the effect of treatment with nitrites. We also bred LmnaLCS/LCSTie2Cre+/tgand LmnaLCS/LCSSM22αCre+/tg mice, which express progerin specifically in endothelial cells (ECs) and in vascular smooth muscle cells (VSMCs), respectively, to determine the specific contribution of each cell type to vascular pathology. We found vessel stiffness and inward remodeling in arteries of LmnaG609G/G609G and LmnaLCS/LCSSM22αCre+/tg, but not in those from LmnaLCS/LCSTie2Cre+/tgmice. Structural alterations in aortas of progeroid mice were associated with decreased smooth muscle tissue content, increased collagen deposition, and decreased transverse waving of elastin layers in the media. Functional studies identified collagen (unlike elastin and the cytoskeleton) as an underlying cause of aortic stiffness in progeroid mice. Consistent with this, we found increased deposition of collagens III, IV, V, and XII in the media of progeroid aortas. Vessel stiffness and inward remodeling in progeroid mice were prevented by adding sodium nitrite in drinking water. In conclusion, LmnaG609G/G609G arteries exhibit stiffness and inward remodeling, mainly due to progerin‐induced damage to VSMCs, which causes increased deposition of medial collagen and a secondary alteration in elastin structure. Treatment with nitrites prevents vascular stiffness in progeria.
NMR metabolomic analysis is a potentially useful technique for diagnosis of sepsis. The concentrations of metabolites involved in energy metabolism and in the inflammatory response change in this model of sepsis.
Highlights d Wild-type mtDNA heteroplasmy is sensed in oocyte maturation and embryo development d Random versus selective mtDNA segregation is driven by the nuclear genetic context d Haplotype-derived OXPHOS differences and ROS signaling define the preferred mtDNA d Efficiency of iPSC generation strongly depends on the mtDNA haplotype
Colloidal suspensions of iron oxide and metal iron nanoparticles prepared by laser pyrolysis
have been obtained by coating the particles with dextran in an aqueous media giving rise
to biocompatible ferrofluids. The structural characteristics of the powders and the
size of the particles and the aggregates in the colloidal suspensions have been
analysed and correlated with the magnetic properties of both solids and fluids.
For the first time, to our knowledge, a stable ferrofluid based on metal particles
(<10 nm)
has been obtained with aggregate sizes of nm. In comparison to iron oxide based products, this material exhibits higher saturation magnetization
(45 emu g−1) and
susceptibilities (4000 emu/g T). In addition, the nuclear magnetic resonance response of the ferrofluids has been
measured in order to gain information about the influence of the crystallochemical and
magnetic properties on their relaxation behaviour. The main parameter affected
by the presence of the magnetic nanoparticles is the transversal relaxation time
T2 and the corresponding
relaxivity R2 value that
is of the order of 400 (mmol/l)−1 s−1. It
has been shown that R2
value increases not only by using iron metal instead of iron oxide but also by increasing the
crystal size of the particles. From this study an evaluation of the possibilities of
these materials as contrast agents for magnetic resonance imaging has been made.
Heart failure (HF) is a major health and economic burden in developed countries. It has been proposed that the pathogenesis of HF may involve the action of mitochondria. We evaluate three different mouse models of HF: tachycardiomyopathy, HF with preserved left ventricular (LV) ejection fraction (LVEF), and LV myocardial ischemia and hypertrophy. Regardless of whether LVEF is preserved, our results indicate that the three models share common features: an increase in mitochondrial reactive oxygen species followed by ultrastructural alterations in the mitochondrial cristae and loss of mitochondrial integrity that lead to cardiomyocyte death. We show that the ablation of the mitochondrial protease OMA1 averts cardiomyocyte death in all three murine HF models, and thus loss of OMA1 plays a direct role in cardiomyocyte protection. This finding identifies OMA1 as a potential target for preventing the progression of myocardial damage in HF associated with a variety of etiologies.
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