High‐fat diet induces cardiac remodelling and dysfunction: assessment of the role played by SIRT3 loss

Mitochondrial dysfunction plays an important role in obesity‐induced cardiac impairment. SIRT3 is a mitochondrial protein associated with increased human life span and metabolism. This study investigated the functional role of SIRT3 in obesity‐induced cardiac dysfunction. Wild‐type (WT) and SIRT3 knockout (KO) mice were fed a normal diet (ND) or high‐fat diet (HFD) for 16 weeks. Body weight, fasting glucose levels, reactive oxygen species (ROS) levels, myocardial capillary density, cardiac function and expression of hypoxia‐inducible factor (HIF)‐1α/‐2α were assessed. HFD resulted in a significant reduction in SIRT3 expression in the heart. Both HFD and SIRT3 KO mice showed increased ROS formation, impaired HIF signalling and reduced capillary density in the heart. HFD induced cardiac hypertrophy and impaired cardiac function. SIRT3 KO mice fed HFD showed greater ROS production and a further reduction in cardiac function compared to SIRT3 KO mice on ND. Thus, the adverse effects of HFD on cardiac function were not attributable to SIRT3 loss alone. However, HFD did not further reduce capillary density in SIRT3 KO hearts, implicating SIRT3 loss in HFD‐induced capillary rarefaction. Our study demonstrates the importance of SIRT3 in preserving heart function and capillary density in the setting of obesity. Thus, SIRT3 may be a potential therapeutic target for obesity‐induced heart failure.     

TRPC3 is required for the survival,pluripotency and neural differentiation of mouse embryonic stem cells(mESCs)

Transient receptor potential canonical subfamily member 3(TRPC3) is known to be important for neural development and the formation of neuronal networks. Here, we investigated the role of TRPC3 in undifferentiated mouse embryonic stem cells(mESCs) and during the differentiation of mESCs into neurons. CRISPR/Cas9-mediated knockout(KO) of TRPC3 induced apoptosis and the disruption of mitochondrial membrane potential both in undifferentiated mESCs and in those undergoing neural differentiation. In addition, TRPC3 KO impaired the pluripotency of mESCs. TRPC3 KO also dramatically repressed the neural differentiation of mESCs by inhibiting the expression of markers for neural progenitors, neurons, astrocytes and oligodendrocytes.Taken together, our new data demonstrate an important function of TRPC3 with regards to the survival, pluripotency and neural differentiation of mESCs.     

Increasing maternal age of blastocyst affects on efficient derivation and behavior of mouse embryonic stem cells

Mouse embryonic stem cells (mESCs) have the capability to undergo unlimited cell division and differentiate into derivatives of all three embryonic germ layers. These fundamental features enable mESCs to potentially be appropriate, efficient models for biological and medical research. Therefore, it is essential to produce high-performance mESCs. In the current study, we have produced mESCs from blastocysts that developed from fertilized oocytes of 2 (2-C57)-, 4 (4-C57)-, and 6 (6-C57)-month-old C57BL/6 mice. A comparison of isolated stem cells was done from the viewpoint of the efficiency of mESC derivation, self-renewal, and their differentiation capacity. All generated mESCs showed a similar expression of the molecular markers protein of pluripotency and AP activity. In the 3i medium, there was a significant decrease in undifferentiated marker genes expression in the 2-C57 cells compared with the other two groups ( P < 0.05) but developmental genes significantly increased in the 4-C57 and 6-C57 cells compared with the 2-C57 cells ( P < 0.05). The differentiation capacity into three germ layers through the embryoid body formation and percentage of cell lines with normal numbers of chromosomes reduced with increased maternal age. The highest DT and highest percentage of cells in the S phase belonged to 2-C57 cells. These data demonstrated that blastocysts which developed from fertilized oocytes of 2-, 4-, and 6-month-old C57BL/6 mice can generate pluripotent stem cells, and suggested that both the efficiency of mESC isolation and the behavior of these isolated mESCs including pluripotency, self-renewal, cell cycle, and DT changed with increasing maternal age.     

Longevity and skeletal muscle mass: the role of IGF signalling,the sirtuins,dietary restriction and protein intake

Advancing age is associated with a progressive loss of skeletal muscle (SkM) mass and function. Given the worldwide aging demographics, this is a major contributor to morbidity, escalating socio‐economic costs and ultimately mortality. Previously, it has been established that a decrease in regenerative capacity in addition to SkM loss with age coincides with suppression of insulin/insulin‐like growth factor signalling pathways. However, genetic or pharmacological modulations of these highly conserved pathways have been observed to significantly enhance life and healthspan in various species, including mammals. This therefore provides a controversial paradigm in which reduced regenerative capacity of skeletal muscle tissue with age potentially promotes longevity of the organism. This paradox will be assessed and considered in the light of the following: (i) the genetic knockout, overexpression and pharmacological models that induce lifespan extension (e.g. IRS‐1/s6K KO, mTOR inhibition) versus the important role of these signalling pathways in SkM growth and adaptation; (ii) the role of the sirtuins (SIRTs) in longevity versus their emerging role in SkM regeneration and survival under catabolic stress; (iii) the role of dietary restriction and its impact on longevity versus skeletal muscle mass regulation; (iv) the crosstalk between cellular energy metabolism (AMPK/TSC2/SIRT1) and survival (FOXO) versus growth and repair of SkM (e.g. AMPK vs. mTOR); and (v) the impact of protein feeding in combination with dietary restriction will be discussed as a potential intervention to maintain SkM mass while increasing longevity and enabling healthy aging.     

Analyses of copy number variation reveal putative susceptibility loci in MTX‐induced mouse neural tube defects

Copy number variations (CNVs) are thought to act as an important genetic mechanism underlying phenotypic heterogeneity. Impaired folate metabolism can result in neural tube defects (NTDs). However, the precise nature of the relationship between low folate status and NTDs remains unclear. Using an array‐comparative genomic hybridization (aCGH) assay, we investigated whether CNVs could be detected in the NTD embryonic neural tissues of methotrexate (MTX)‐induced folate dysmetabolism pregnant C57BL/6 mice and confirmed the findings with quantitative real‐time PCR (qPCR). The CNVs were then comprehensively investigated using bioinformatics methods to prioritize candidate genes. We measured dihydrofolate reductase (DHFR) activity and concentrations of folate and relevant metabolites in maternal serum using enzymologic method and liquid chromatography/tandem mass spectrometry (LC/MS/MS). Three high confidence CNVs on XqA1.1, XqA1.1‐qA2, and XqE3 were found in the NTD embryonic neural tissues. Twelve putative genes and three microRNAs were identified as potential susceptibility candidates in MTX‐induced NTDs and possible roles in NTD pathogenesis. DHFR activity and 5‐methyltetrahydrofolate (5‐MeTHF), 5‐formyltetrahydrofolate (5‐FoTHF), and S‐adenosylmethionine (SAM) concentrations of maternal serum decreased significantly after MTX injection. These findings suggest that CNVs caused by defects in folate metabolism lead to NTD, and further support the hypothesis that folate dysmetabolism is a direct cause for CNVs in MTX‐induced NTDs. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 74: 877–893, 2014     

Three‐dimensional culture systems for the expansion of pluripotent embryonic stem cells

Mouse embryonic stem cell (ESC) lines, and more recently human ESC lines, have become valuable tools for studying early mammalian development. Increasing interest in ESCs and their differentiated progeny in drug discovery and as potential therapeutic agents has highlighted the fact that current two‐dimensional (2D) static culturing techniques are inadequate for large‐scale production. The culture of mammalian cells in three‐dimensional (3D) agitated systems has been shown to overcome many of the restrictions of 2D and is therefore likely to be effective for ESC proliferation. Using murine ESCs as our initial model, we investigated the effectiveness of different 3D culture environments for the expansion of pluripotent ESCs. Solohill Collagen, Solohill FACT, and Cultispher‐S microcarriers were employed and used in conjunction with stirred bioreactors. Initial seeding parameters, including cell number and agitation conditions, were found to be critical in promoting attachment to microcarriers and minimizing the size of aggregates formed. While all microcarriers supported the growth of undifferentiated mESCs, Cultispher‐S out‐performed the Solohill microcarriers. When cultured for successive passages on Cultispher‐S microcarriers, mESCs maintained their pluripotency, demonstrated by self‐renewal, expression of pluripotency markers and the ability to undergo multi‐lineage differentiation. When these optimized conditions were applied to unweaned human ESCs, Cultispher‐S microcarriers supported the growth of hESCs that retained expression of pluripotency markers including SSEA4, Tra‐1–60, NANOG, and OCT‐4. Our study highlights the importance of optimization of initial seeding parameters and provides proof‐of‐concept data demonstrating the utility of microcarriers and bioreactors for the expansion of hESCs. Biotechnol. Bioeng. 2010;107:683–695. © 2010 Wiley Periodicals, Inc.     

Sirtuin3 deficiency exacerbates carbon tetrachloride−induced hepatic injury in mice

Sirtuin3 (SIRT3) plays an important role in maintaining normal mitochondrial function and alleviating oxidative stress. After carbon tetrachloride (CCl₄) administration, the expression of SIRT3 decreased in the liver of mice, which indicated that the SIRT3 might play a crucial role during chemical‐induced acute hepatic injury. To verify the hypothesis, CCl ₄ was given to induce acute hepatic injury in SIRT3 knockout (KO) mice and wild‐type (WT) mice. CCl ₄‐induced liver injury was more severe in SIRT3 KO mice compared with the WT mice. In addition, the oxidative stress induced by CCl ₄ was enhanced in the SIRT3 KO mice. Furthermore, the increased expression of dynamin‐related protein 1 was also aggravated in SIRT3 KO mice after CCl ₄ administration. In conclusion, our study demonstrated that SIRT3 deficiency exacerbated CCl ₄‐induced impairment of the liver in mice, and the mechanism might be related to enhanced oxidative stress.     

Genome-wide regulation of 5hmC, 5mC, and gene expression by Tet1 hydroxylase in mouse embryonic stem cells

DNA methylation at the 5 position of cytosine (5mC) in the mammalian genome is a key epigenetic event critical for various cellular processes. The ten-eleven translocation (Tet) family of 5mC-hydroxylases, which convert 5mC to 5-hydroxymethylcytosine (5hmC), offers a way for dynamic regulation of DNA methylation. Here we report that Tet1 binds to unmodified C or 5mC- or 5hmC-modified CpG-rich DNA through its CXXC domain. Genome-wide mapping of Tet1 and 5hmC reveals mechanisms by which Tet1 controls 5hmC and 5mC levels in mouse embryonic stem cells (mESCs). We also uncover a comprehensive gene network influenced by Tet1. Collectively, our data suggest that Tet1 controls DNA methylation both by binding to CpG-rich regions to prevent unwanted DNA methyltransferase activity, and by converting 5mC to 5hmC through hydroxylase activity. This Tet1-mediated antagonism of CpG methylation imparts differential maintenance of DNA methylation status at Tet1 targets, ultimately contributing to mESC differentiation and the onset of embryonic development.     

DNA methylation,an epigenetic mechanism connecting folate to healthy embryonic development and aging

Experimental studies demonstrated that maternal exposure to certain environmental and dietary factors during early embryonic development can influence the phenotype of offspring as well as the risk of disease development at the later life. DNA methylation, an epigenetic phenomenon, has been suggested as a mechanism by which maternal nutrients affect the phenotype of their offspring in both honeybee and agouti mouse models. Phenotypic changes through DNA methylation can be linked to folate metabolism by the knowledge that folate, a coenzyme of one-carbon metabolism, is directly involved in methyl group transfer for DNA methylation. During the fetal period, organ-specific DNA methylation patterns are established through epigenetic reprogramming. However, established DNA methylation patterns are not immutable and can be modified during our lifetime by the environment. Aberrant changes in DNA methylation with diet may lead to the development of age-associated diseases including cancer. It is also known that the aging process by itself is accompanied by alterations in DNA methylation. Diminished activity of DNA methyltransferases (Dnmts) can be a potential mechanism for the decreased genomic DNA methylation during aging, along with reduced folate intake and altered folate metabolism. Progressive hypermethylation in promoter regions of certain genes is observed throughout aging, and repression of tumor suppressors induced by this epigenetic mechanism appears to be associated with cancer development. In this review, we address the effect of folate on early development and aging through an epigenetic mechanism, DNA methylation.     

Sirtuin 3 is essential for hypertension‐induced cardiac fibrosis via mediating pericyte transition

Hypertension is the key factor for the development of cardiac fibrosis and diastolic dysfunction. Our previous study showed that knockout of sirtuin 3 (SIRT3) resulted in diastolic dysfunction in mice. In the present study, we explored the role of SIRT3 in angiotensin II (Ang‐II)–induced cardiac fibrosis and pericyte‐myofibroblast transition. NG2 tracing reporter NG2‐DsRed mouse was crossed with wild‐type (WT) mice and SIRT3KO mice. Cardiac function, cardiac fibrosis and reactive oxygen species (ROS) were measured. Mice infused with Ang‐II for 28 days showed a significant reduction of SIRT3 expression in the mouse hearts. Knockout of SIRT3 sensitized Ang‐II‐induced elevation of isovolumic relaxation time (IVRT) and reduction of ejection fraction (EF) and fractional shortening (FS). Ang‐II‐induced cardiac fibrosis, capillary rarefaction and hypertrophy were further enhanced by knockout of SIRT3. NG2 pericyte tracing reporter mice infused with Ang‐II had a significantly increased number of NG2‐DsRed pericyte in the heart. Knockout of SIRT3 further enhanced Ang‐II‐induced increase of pericytes. To examine pericyte‐myofibroblast/fibroblast transition, DsRed pericytes were co‐stained with FSP‐1 and α‐SMA. Ang‐II infusion led to a significant increase in numbers of DsRed⁺/FSP‐1⁺ and DsRed⁺/α‐SMA⁺ cells, while SIRT3KO further developed pericyte‐myofibroblast/fibroblast transition. In addition, knockout of SIRT3 promoted Ang‐II‐induced NADPH oxidase‐derived ROS formation together with increased expression of transforming growth factor beta 1 (TGF‐β1). We concluded that Ang‐II induced cardiac fibrosis partly by the mechanisms involving SIRT3‐mediated pericyte‐myofibroblast/fibroblast transition and ROS‐TGF‐β1 pathway.     

Long interspersed nucleotide element‐1 hypomethylation in folate‐deficient mouse embryonic stem cells

Folate is thought to contribute to health and development by methylation regulation. Long interspersed nucleotide element‐1 (LINE‐1), which is regulated by methylation modification, plays an important role in sculpting the structure and function of genomes. Some studies have shown that folate concentration is related to LINE‐1 methylation. However, the direct association between LINE‐1 methylation and folate deficiency remains unclear. To explore whether folate deficiency directly induced LINE‐1 hypomethylation and to analyze the relationship between folate concentration and the LINE‐1 methylation level, mouse ESCs were treated with various concentrations of folate which was measured by chemiluminescent immunoassay, and the homocysteine content was detected by ELISA. LINE‐1 methylation was examined by matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry at various time points. Concurrently, cell proliferation and differentiation were observed. The result showed that the intracellular folate decreases under folate‐deficient condition, conversely, homocysteine content increased gradually and there was a negatively correlated between them. Folate insufficiency induced LINE‐1 hypomethylation at the lowest levels in folate‐free group and moderate in folate‐deficient group, compared with that in the folate‐normal group at day 18. Moreover, LINE‐1 methylation level was positively correlated with folate content, and negatively correlated with homocysteine content. At corresponding time points, proliferation and differentiation of mouse ESCs showed no alteration in all groups. Our data indicated that folate deficiency affected the homeostasis of folate‐mediated one‐carbon metabolism, leading to reduced LINE‐1 methylation in mouse ESCs. This study provides preliminary evidence of folate deficiency affecting early embryonic development. J. Cell. Biochem. 114: 1549–1558, 2013. © 2013 Wiley Periodicals, Inc.     

Chick embryos can form teratomas from microinjected mouse embryonic stem cells

We examined whether chick embryos are a suitable experimental model for the evaluation of pluripotency of stem cells. Mouse embryonic stem cells (mESCs) expressing the reporter gene, LacZ or GFP were injected into the subgerminal cavity of blastoderms (freshly oviposited) or the marginal vein of chick embryos (2 days of incubation). Injected mESCs were efficiently incorporated into the body and extra‐embryonic tissues of chick embryos and formed small clusters. Increased donor cell numbers injected were positively associated with the efficiency of chimera production, but with lower viability. A single mESC injected into the blastoderm proliferated into 34.7 ± 3.8 cells in 3 days, implying that the chick embryo provides an optimal environment for the growth of xenogenic cells. In the embryo body, mESCs were interspersed as small clustered chimeras in various tissues. Teratomas were observed in the yolk sac and the brain with three germ layers. In the yolk sac, clusters of mESCs gradually increased in volume and exhibited varied morphology such as a water balloon‐like or dark‐red solid mass. However, mESCs in the brain developed into a large soft tissue mass of whitish color and showed a tendency to differentiate into ectodermal lineage cells, including primitive neural ectodermal and neuronal cells expressing the neurofilament protein. These results indicate that chick embryos are useful for the teratoma formation assays of mESCs and have a broad‐range potential as an experimental host model.     

LINE‐1 hypomethylation induced by reactive oxygen species is mediated via depletion of S‐adenosylmethionine

Whether long interspersed nuclear element‐1 (LINE‐1) hypomethylation induced by reactive oxygen species (ROS) was mediated through the depletion of S‐adenosylmethionine (SAM) was investigated. Bladder cancer (UM‐UC‐3 and TCCSUP) and human kidney (HK‐2) cell lines were exposed to 20 μM H₂O₂ for 72 h to induce oxidative stress. Level of LINE‐1 methylation, SAM and homocysteine (Hcy) was measured in the H₂O₂‐exposed cells. Effects of α‐tocopheryl acetate (TA), N‐acetylcysteine (NAC), methionine, SAM and folic acid on oxidative stress and LINE‐1 methylation in the H₂O₂‐treated cells were explored. Viabilities of cells treated with H₂O₂ were not significantly changed. Intracellular ROS production and protein carbonyl content were significantly increased, but LINE‐1 methylation was significantly decreased in the H₂O₂‐treated cells. LINE‐1 methylation was restored by TA, NAC, methionine, SAM and folic acid. SAM level in H₂O₂‐treated cells was significantly decreased, while total glutathione was significantly increased. SAM level in H₂O₂‐treated cells was restored by NAC, methionine, SAM and folic acid; while, total glutathione level was normalized by TA and NAC. Hcy was significantly decreased in the H₂O₂‐treated cells and subsequently restored by NAC. In conclusion, in bladder cancer and normal kidney cells exposed to H₂O₂, SAM and Hcy were decreased, but total glutathione was increased. Treatments with antioxidants (TA and NAC) and one‐carbon metabolites (SAM, methionine and folic acid) restored these changes. This pioneer finding suggests that exposure of cells to ROS activates glutathione synthesis via the transsulfuration pathway leading to deficiency of Hcy, which consequently causes SAM depletion and eventual hypomethylation of LINE‐1. Copyright © 2015 John Wiley & Sons, Ltd.