Enhanced expression of mitochondrial genes in senescent endothelial cells and fibroblasts

Low-intensity and moderate exercise training improves autonomic nervous system activity imbalanced by postnatal early overfeeding in rats

Background

Postnatal early overfeeding and physical inactivity are serious risk factors for obesity. Physical activity enhances energy expenditure and consumes fat stocks, thereby decreasing body weight (bw). This study aimed to examine whether low-intensity and moderate exercise training in different post-weaning stages of life is capable of modulating the autonomic nervous system (ANS) activity and inhibiting perinatal overfeeding-induced obesity in rats.

Methods

The obesity-promoting regimen was begun two days after birth when the litter size was adjusted to 3 pups (small litter, SL) or to 9 pups (normal litter, NL). The rats were organized into exercised groups as follows: from weaning until 90-day-old, from weaning until 50-day-old, or from 60- until 90-days-old. All experimental procedures were performed just one day after the exercise training protocol.

Results

The SL-no-exercised (SL-N-EXE) group exhibited excess weight and increased fat accumulation. We also observed fasting hyperglycemia and glucose intolerance in these rats. In addition, the SL-N-EXE group exhibited an increase in the vagus nerve firing rate, whereas the firing of the greater splanchnic nerve was not altered. Independent of the timing of exercise and the age of the rats, exercise training was able to significantly blocks obesity onset in the SL rats; even SL animals whose exercise training was stopped at the end of puberty, exhibited resistance to obesity progression. Fasting glycemia was maintained normal in all SL rats that underwent the exercise training, independent of the period. These results demonstrate that moderate exercise, regardless of the time of onset, is capable on improve the vagus nerves imbalanced tonus and blocks the onset of early overfeeding-induced obesity.

Conclusions

Low-intensity and moderate exercise training can promote the maintenance of glucose homeostasis, reduces the large fat pad stores associated to improvement of the ANS activity in adult rats that were obesity-programmed by early overfeeding.

Establishment of ultra long-lived cell lines by transfection of TERT into normal human fibroblast TIG-1 and their characterization

To establish useful human normal cell lines, TERT (telomerase reverse transcriptase) cDNA was transfected into normal female lung fibroblast, TIG-1. After long-term-sub-cultivation of 74 individual clones selected for resistance to G418, we obtained 55 cultures with normal range of life span [75 PDL (population doubling level)], 16 cultures with extended life span (75-140 PDL). In addition, 3 immortal cell strains and unexpectedly, one ultra long-lived cell line (ULT-1) with life span of 166 PDL were established. IMT-1, one of the immortal cell strains was confirmed to maintain long telomere length, high telomerase activity and an extremely low level of p16INK4A. They also showed moderate p53 and p21CIP1 expression, keeping vigorous growth rate even at 450 PDL. High level of fibronectin and collagen 1α expression confirmed IMT-1 as normal fibroblasts, although one X chromosome had been lost. ULT-1, however, kept a near normal karyotypes and had shortening of telomere length, high expression of p16INK4A, moderate levels of senescence associated-β-galactosidase positive cells and decreased growth rate only after 150 PDs (population doublings), and finally reached senescence at 166 PDL with morphology of normal senescent fibroblasts. As resources of standard normal human cell, abundant vials of early and middle passages of ULT-1 have been stocked. The use of the cell line is discussed, focusing on isograft of artificial skin and screening of anti-aging or safe chemical agents.

Vascular cell senescence: contribution to atherosclerosis

Cardiologists and most physicians believe that aging is an independent risk factor for human atherosclerosis, whereas atherosclerosis is thought to be a characteristic feature of aging in humans by many gerontologists. Because atherosclerosis is among the age-associated changes that almost always escape the influence of natural selection in humans, it might be reasonable to regard atherosclerosis as a feature of aging. Accordingly, when we investigate the pathogenesis of human atherosclerosis, it may be more important to answer the question of how we age than what specifically promotes atherosclerosis. Recently, genetic analyses using various animal models have identified molecules that are crucial for aging. These include components of the DNA-repair system, the tumor suppressor pathway, the telomere maintenance system, the insulin/Akt pathway, and other metabolic pathways. Interestingly, most of the molecules that influence the phenotypic changes of aging also regulate cellular senescence, suggesting a causative link between cellular senescence and aging. For example, DNA-repair defects can cause phenotypic changes that resemble premature aging, and senescent cells that show DNA damage accumulate in the elderly. Excessive calorie intake can cause diabetes and hyperinsulinemia, whereas dysregulation of the insulin pathway has been shown to induce cellular senescence in vitro. Calorie restriction or a reduction of insulin signals extends the lifespan of various species and decreases biomarkers of cellular senescence in vivo. There is emerging evidence that cellular senescence contributes to the pathogenesis of human atherosclerosis. Senescent vascular cells accumulate in human atheroma tissues and exhibit various features of dysfunction. In this review, we examine the hypothesis that cellular senescence might contribute to atherosclerosis, which is a characteristic of aging in humans.

SNEV overexpression extends the life span of human endothelial cells

In a recent screening for genes down regulated in replicatively senescent human umbilical vein endothelial cells (HUVECs), we have isolated the novel protein SNEV. Since then SNEV has proven as a multifaceted protein playing a role in pre-mRNA splicing, DNA repair, and the ubiquitin/proteosome system. Here, we report that SNEV mRNA decreases in various cell types during replicative senescence, and that it is increased in various immortalized cell lines, as well as in breast tumors, where SNEV transcript levels also correlate with the survival of breast cancer patients. Since these mRNA profiles suggested a role of SNEV in the regulation of cell proliferation, the effect of its overexpression was tested. Thereby, a significant extension of the cellular life span was observed, which was not caused by altered telomerase activity or telomere dynamics but rather by enhanced stress resistance. When SNEV overexpressing cells were treated with bleomycin or bleomycin combined with BSO, inducing DNA damage as well as reactive oxygen species, a significantly lower fraction of apoptotic cells was found in comparison to vector control cells. These data suggest that high levels of SNEV might extend the cellular life span by increasing the resistance to stress or by improving the DNA repair capacity of the cells.

Cloning and characterization of cellular senescence-associated genes in human fibroblasts by suppression subtractive hybridization

Cellular senescence marks the end of the proliferative life span of normal cells in tissue culture and occurs after cells have undergone a certain number of population doublings (PDLs). It is accompanied by alterations in the pattern of gene expression. A specific human embryonic lung diploid fibroblast cell line, 2BS, has been studied as a model of senescence in our laboratory. Here, we report a set of cellular senescence-associated genes identified from suppression subtractive cDNA libraries from senescent and young 2BS cells. They include three novel genes and six previously identified genes of unknown function. The genes whose functions are known belong to various functional pathways that have been reported to change with the onset of senescence. These include three pre-mRNA splicing factors with reduced expression in senescent cells, indicating that the regulation of mRNA splicing is altered during cell senescence. In addition, the expression of the gene TOM1 (target of Myb 1), which has not previously been associated with cellular senescence, is shown to increase in senescent cells, and we demonstrate that the expression of antisense TOM1 gene in 2BS cells can delay the progress of senescence.

Gene expression profiling of human satellite cells during muscular aging using cDNA arrays

It is well established that biological aging is associated with functional deficits at the cellular, tissue, organ and system levels, but the molecular mechanisms that control lifespan and age-related phenotypes are still not well understood. In order to investigate the molecular mechanisms underlying myoblast aging, we have used quantitative hybridization of a cDNA array of 2016 clones from a human skeletal muscle 3'-end cDNA library to monitor gene expression patterns of myoblasts of individuals with different ages (5 days old, 52 years old and 79 years old) and at different stages of proliferation (early, presenescent and senescent). We have shown that expression profiles in satellite cells vary with donor age, with an up-regulation of genes involved in muscle structure, muscle differentiation and in metabolism in the newborn, and a down-regulation of genes involved in protein renewal in adults. We have also observed that myoblasts isolated from subjects of different ages have typical expression profiles at the beginning of their proliferative lifespan. However, this phenomenon progressively disappears as the cells approach senescence. In addition, even though some of the modifications are similar to those observed in other cell types, we have observed that many changes in gene expression are characteristic of the myoblasts, confirming the hypothesis that the program of replicative senescence is specific for each cell type. Finally, we have identified four potential new markers of presenescence for human myoblasts, which could be useful in developing therapeutic strategies.

Molecular mechanisms of replicative senescence in endothelial cells

As human somatic cells age, they stop replicating and enter an irreversible state of growth arrest known as replicative senescence. Senescent cells are viable, metabolically active, and display altered gene and protein expression compared to proliferating cells. Endothelial cells, both in vitro and in vivo, are known to undergo senescence. As endothelial cells are a critical component of the vasculature, senescence of these cells can have a significant impact of vascular integrity, function, and overall homeostasis. This review will summarize recent work to understand the molecular mechanisms of endothelial cell senescence and the resulting alterations in gene/protein expression in these cells. Endothelial cell senescence will then be discussed in the context of disease development with a focus on atherosclerosis, an important age-associated disease of the vasculature.

Overexpression of VDUP1 mRNA sensitizes HeLa cells to paraquat

5-Bromodeoxyuridine (BrdU) induces or suppresses senescence-associated genes in any types of mammalian cells. From a cDNA library upregulated by BrdU in HeLa cells, we identified the gene encoding VDUP1 as a senescence-associated gene in normal human fibroblasts. To address a role of VDUP1 in senescence, we established HeLa cell clones, V7 and V27, which express its mRNA in a doxycycline-dependent manner. Although their growth in liquid culture was moderately retarded, colony formation on semi-solid medium was strongly inhibited by overexpression of the mRNA. We also examined susceptibility of these clones to various reagents. Consequently, colony formation in liquid culture was strongly inhibited by paraquat in these clones. Their superoxide dismutase activity was normal.

Enhanced apoptosis in prolonged cultures of senescent porcine pulmonary artery endothelial cells

Senescent or aged endothelial cells in culture remain metabolically active after cessation of division, and are generally believed to eventually die. However, mechanisms underlying the terminal aging of cultured cells, i.e. from senescence to death, are poorly understood. Here, we report that culturing of replicative senescent endothelial cells for a prolonged period of time without passaging leads to enhanced programmed cell death or apoptosis. Senescent (passage 45) and young (passage 3) porcine pulmonary artery endothelial cells (PAEC) were cultured for 0-42 days post confluence. The cells attached to culture dishes and floating in medium were collected at 0, 7, 14, 21, 28, 35 and 42 days post confluence and were assessed for markers of apoptosis. Morphology studies showed that ratios between senescent and young cells attached to dishes declined to 45% after 42 days postconfluence. Apoptotic cells in prolonged cultures of senescent PAEC increased from 5 to 35% as determined by protein mass, DNA breakage, and caspase-3 activation. Steady state levels of Bcl-2, an anti-apoptotic protein, in senescent prolonged cultures decreased to less than 20% for all time points compared with young cells. Relative levels of Bad, a pro-apoptotic protein, in senescent cells were elevated from 60 to 130% during prolonged culturing. These results indicate that terminal cellular aging enhances apoptosis and the levels of Bcl-2/Bad may be associated with the apoptotic process in porcine lung endothelial cells.

Induction of senescence-associated genes by 5-bromodeoxyuridine in HeLa cells

5-Bromodeoxyuridine (BrdU) universally induces a senescence-like phenomenon in mammalian cells. To assess this phenomenon at the level of gene expression, we constructed a PCR-based subtractive cDNA library enriched for mRNA species that immediately increase by administration of BrdU to HeLa cells. Candidate cDNA clones were isolated by differential colony hybridization, and then positive clones were identified by Northern blot analysis. Sequencing analysis revealed that the identified cDNA species were classified into three groups: widely used senescence-markers, known species whose relevance to senescence is yet to be reported, and known or novel ESTs. As expected, the majority of them showed an increase in expression in senescent human diploid fibroblasts. These results suggest that similar mechanisms operate in the regulation of BrdU-induced genes and senescence-associated genes.

Effects of p21Waf1/Cip1/Sdi1 on cellular gene expression: implications for carcinogenesis, senescence, and age-related diseases

Induction of cyclin-dependent kinase inhibitor p21(Waf1/Cip1/Sdi1) triggers cell growth arrest associated with senescence and damage response. Overexpression of p21 from an inducible promoter in a human cell line induces growth arrest and phenotypic features of senescence. cDNA array hybridization showed that p21 expression selectively inhibits a set of genes involved in mitosis, DNA replication, segregation, and repair. The kinetics of inhibition of these genes on p21 induction parallels the onset of growth arrest, and their reexpression on release from p21 precedes the reentry of cells into cell cycle, indicating that inhibition of cell-cycle progression genes is a mechanism of p21-induced growth arrest. p21 also up-regulates multiple genes that have been associated with senescence or implicated in age-related diseases, including atherosclerosis, Alzheimer's disease, amyloidosis, and arthritis. Most of the tested p21-induced genes were not activated in cells that had been growth arrested by serum starvation, but some genes were induced in both forms of growth arrest. Several p21-induced genes encode secreted proteins with paracrine effects on cell growth and apoptosis. In agreement with the overexpression of such proteins, conditioned media from p21-induced cells were found to have antiapoptotic and mitogenic activity. These results suggest that the effects of p21 induction on gene expression in senescent cells may contribute to the pathogenesis of cancer and age-related diseases.

Subtractive hybridization of mRNA from early passage and senescent endothelial cells

Regulation of cellular processes that eventually lead to a state of growth arrest is an important manifestation of in vitro cellular senescence caused and accompanied by variations of the gene expression pattern. Whereas these changes at the mRNA level have been studied mainly in fibroblast cultures, we concentrated on endothelial cells that represent an accepted model for vascular systems and may be involved in the pathogenesis of diseases related to aging. To isolate differentially expressed genes, we created a subtractive cDNA library using mRNA from senescent (35 passages) and young (five passages) human umbilical vein endothelial cells (HUVECs). Candidate clones were isolated from the cDNA library, differential expression was confirmed by Northern blot analyses and sequences were compared with a genbank data base. Because many mRNAs were below the detection limit of Northern blot analysis, we were forced to establish a more sensitive PCR based method (ATAC-PCR) to quantify and confirm altered levels of gene expression. Several mRNAs were found to be upregulated in senescent HUVECs including two components of the extracellular matrix (ECM): plasminogen activator inhibitor and fibronectin. Elevated expression of both has already been described in senescent cells. The mRNAs of TGF-beta-inducible gene H3 (beta-IG-H3; ECM protein), insulin-like growth factor binding protein (IGFBP-3), p53-inducible gene (PIG3) a protein involved in vesicular transport (SEC13R) and ribosomal protein L28 have likewise been shown to be preferentially expressed in senescent cells. Because studies support the involvement of ECM components, TGF-beta and p53 in tumor suppressing mechanisms, our data supports the hypothesis that cellular senescence and upregulation of ECM proteins may be associated with tumor preventive functions.