Effects of the type of dietary fat at two levels of vitamin E in Wistar male rats during development and aging. IV. Biochemical and morphometric parameters of the heart

Aging Induces Hepatic Oxidative Stress and Nuclear Proteomic Remodeling in Liver from Wistar Rats

Aging is a continuous, universal, and irreversible process that determines progressive loss of adaptability. The liver is a critical organ that supports digestion, metabolism, immunity, detoxification, vitamin storage, and hormone signaling. Nevertheless, the relationship between aging and the development of liver diseases remains elusive. In fact, although prolonged fasting in adult rodents and humans delays the onset of the disease and increases longevity, whether prolonged fasting could exert adverse effects in old organisms remains incompletely understood. In this work, we aimed to characterize the oxidative stress and nuclear proteome in the liver of 3-month- and 24-month-old male Wistar rats upon 36 h of fasting and its adaptation in response to 30 min of refeeding. To this end, we analyzed the hepatic lipid peroxidation levels (TBARS) and the expression levels of genes associated with fat metabolism and oxidative stress during aging. In addition, to gain a better insight into the molecular and cellular processes that characterize the liver of old rats, the hepatic nuclear proteome was also evaluated by isobaric tag quantitation (iTRAQ) mass spectrometry-based proteomics. In old rats, aging combined with prolonged fasting had great impact on lipid peroxidation in the liver that was associated with a marked downregulation of antioxidant genes (Sod2, Fmo3, and Cyp2C11) compared to young rats. Besides, our proteomic study revealed that RNA splicing is the hepatic nuclear biological process markedly affected by aging and this modification persists upon refeeding. Our results suggest that aged-induced changes in the nuclear proteome could affect processes associated with the adaptative response to refeeding after prolonged fasting, such as those involved in the defense against oxidative stress.

Cell Senescence, Multiple Organelle Dysfunction and Atherosclerosis

Atherosclerosis is an age-related disorder associated with long-term exposure to cardiovascular risk factors. The asymptomatic progression of atherosclerotic plaques leads to major cardiovascular diseases (CVD), including acute myocardial infarctions or cerebral ischemic strokes in some cases. Senescence, a biological process associated with progressive structural and functional deterioration of cells, tissues and organs, is intricately linked to age-related diseases. Cell senescence involves coordinated modifications in cellular compartments and has been demonstrated to contribute to different stages of atheroma development. Senescence-based therapeutic strategies are currently being pursued to treat and prevent CVD in humans in the near-future. In addition, distinct experimental settings allowed researchers to unravel potential approaches to regulate anti-apoptotic pathways, facilitate excessive senescent cell clearance and eventually reverse atherogenesis to improve cardiovascular function. However, a deeper knowledge is required to fully understand cellular senescence, to clarify senescence and atherogenesis intertwining, allowing researchers to establish more effective treatments and to reduce the cardiovascular disorders' burden. Here, we present an objective review of the key senescence-related alterations of the major intracellular organelles and analyze the role of relevant cell types for senescence and atherogenesis. In this context, we provide an updated analysis of therapeutic approaches, including clinically relevant experiments using senolytic drugs to counteract atherosclerosis.

Implications of time-series gene expression profiles of replicative senescence

Although senescence has long been implicated in aging-associated pathologies, it is not clearly understood how senescent cells are linked to these diseases. To address this knowledge gap, we profiled cellular senescence phenotypes and mRNA expression patterns during replicative senescence in human diploid fibroblasts. We identified a sequential order of gain-of-senescence phenotypes: low levels of reactive oxygen species, cell mass/size increases with delayed cell growth, high levels of reactive oxygen species with increases in senescence-associated β-galactosidase activity (SA-β-gal), and high levels of SA-β-gal activity. Gene expression profiling revealed four distinct modules in which genes were prominently expressed at certain stages of senescence, allowing us to divide the process into four stages: early, middle, advanced, and very advanced. Interestingly, the gene expression modules governing each stage supported the development of the associated senescence phenotypes. Senescence-associated secretory phenotype-related genes also displayed a stage-specific expression pattern with three unique features during senescence: differential expression of interleukin isoforms, differential expression of interleukins and their receptors, and differential expression of matrix metalloproteinases and their inhibitory proteins. We validated these phenomena at the protein level using human diploid fibroblasts and aging Sprague-Dawley rat skin tissues. Finally, disease-association analysis of the modular genes also revealed stage-specific patterns. Taken together, our results reflect a detailed process of cellular senescence and provide diverse genome-wide information of cellular backgrounds for senescence.

Fluorescence-based detection and quantification of features of cellular senescence

Cellular senescence is a spontaneous organismal defense mechanism against tumor progression which is raised upon the activation of oncoproteins or other cellular environmental stresses that must be circumvented for tumorigenesis to occur. It involves growth-arrest state of normal cells after a number of active divisions. There are multiple experimental routes that can drive cells into a state of senescence. Normal somatic cells and cancer cells enter a state of senescence upon overexpression of oncogenic Ras or Raf protein or by imposing certain kinds of stress such as cellular tumor suppressor function. Both flow cytometry and confocal imaging analysis techniques are very useful in quantitative analysis of cellular senescence phenomenon. They allow quantitative estimates of multiple different phenotypes expressed in multiple cell populations simultaneously. Here we review the various types of fluorescence methodologies including confocal imaging and flow cytometry that are frequently utilized to study a variety of senescence. First, we discuss key cell biological changes occurring during senescence and review the current understanding on the mechanisms of these changes with the goal of improving existing protocols and further developing new ones. Next, we list specific senescence phenotypes associated with each cellular trait along with the principles of their assay methods and the significance of the assay outcomes. We conclude by selecting appropriate references that demonstrate a typical example of each method.

A comparative analysis of the cell biology of senescence and aging

Various intracellular organelles, such as lysosomes, mitochondria, nuclei, and cytoskeletons, change during replicative senescence, but the utility of these changes as general markers of senescence and their significance with respect to functional alterations have not been comprehensively reviewed. Furthermore, the relevance of these alterations to cellular and functional changes in aging animals is poorly understood. In this paper, we review the studies that report these senescence-associated changes in various aging cells and their underlying mechanisms. Changes associated with lysosomes and mitochondria are found not only in cells undergoing replicative or induced senescence but also in postmitotic cells isolated from aged organisms. In contrast, other changes occur mainly in cells undergoing in vitro senescence. Comparison of age-related changes and their underlying mechanisms in in vitro senescent cells and aged postmitotic cells would reveal the relevance of replicative senescence to the physiological processes occurring in postmitotic cells as individuals age.

Quantifying dense bodies and lipofuscin during aging: a morphologist's perspective

Secondary lysosomes, residual or dense bodies containing lipofuscin or age pigment accumulate in post-mitotic and inter-mitotic cells during aging. The consensus is that the accumulation of this auto-fluorescent material is an index of cellular senescence. Biochemical and morphological studies have independently demonstrated marked age-related increases in the cell and tissue contents of lipofuscin. Most morphological studies on aging have been qualitative, have included only two or three age groups and have not yielded data that are easily correlated with biochemical analyses. One of the best documented age-related changes in hepatocytes and cardiac myocytes is the accumulation of dense bodies and lipofuscin inclusions. Independent stereologic studies reported two- to eightfold age-related increases in the dense body volume fraction of rat hepatocytes. Furthermore, we reported a fourfold increase in the dense body volume fraction of cardiac myocytes in rats between 6 and 30 months of age. These and other studies confirm the use of quantitative morphology to estimate the increases in dense body and lipofuscin inclusions as indices of age. Whether or not the accumulated lipofuscin compromises cell functions in senescent animals has not been adequately addressed. On the one hand, there is little evidence that several-fold increases in this subcellular compartment impair the functional capacities of either hepatocytes or cardiac myocytes. On the other hand, the age-related accumulation of immunoprecipitable, but catalytically inactive, lysosomal enzymes in both liver and heart muscle may be a reflection of increased lipofuscin deposits in the dense bodies.

Dietary factors in lipofuscinogenesis and ceroidogenesis

The presence of ceroid pigments in human and animal tissues is associated with numerous pathological conditions in which the main pathogenic factor is the primary or secondary deficiency of vitamin E or imbalances between anti- and pro-oxidants. That oxidative stress, particularly through its consequent lipid peroxidation, plays a capital role in the genesis of ceroid pigments, is supported by numerous in vitro and in vivo studies. Discussed in this presentation are two examples of oxidative stress on ceroidogenesis, namely the in vivo rat model of dietary hepatic necrosis, and the in vitro formation of ceroid pigments by the aerobic incubation of unsaturated fat and blood cells. Although it is widely believed that the progressive accumulation of lipofuscin is also a marker of oxidative stress, and that this pigment can be modulated by the dietary anti- and pro-oxidant factors, the evidence for these related notions is highly questionable. Some years ago, this controversial problem was reexplored in our laboratories by a series of studies in Wistar male rats, and the results indicated that neither the type of dietary fat, nor the pharmacological amounts of vitamin E significantly influenced the amounts of lipofuscin in cerebral neurons, cerebellar Purkinje cells, hepatocytes or cardiac myocytes. It was also found that the indices of lipid peroxidation determined in this study (production of malonaldehyde, and detection of conjugated dienes) did not correlate with the progressive accumulation of lipofuscin with age. All these results strongly suggest that the presence and cellular accumulation of lipofuscin can hardly be considered a marker of oxidative stress.

The reductive hotspot hypothesis: an update

The mitochondrial free radical theory of aging is seriously challenged by the finding that mutant mtDNA never becomes abundant in vivo, a result disputed only in experiments using novel PCR variants whose quantitative accuracy is widely doubted. However, evidence continues to mount that mitochondria are the crucial site of free radical damage in vivo, most notably that mice lacking the nonmitochondrial isoforms of superoxide dismutase are healthy. It is thus important to determine whether a low level of mutant mtDNA could have serious systemic effects. This possibility exists because of the observed mosaic distribution of mutant mtDNA: some cells (or muscle fiber segments) lack any aerobic respiration. Such cells are presumed to satisfy their ATP needs by glycolysis. In vitro, however, NADH recycling by transmembrane pyruvate/lactate exchange does not suffice: cells only survive if they can up-regulate the plasma membrane oxidoreductase (PMOR). The PMOR's physiological electron acceptor is unknown. It was proposed recently (de Grey, A. D. N. J. (1998) J. Anti-Aging Med. 1(1), 53-66) that a prominent in vivo acceptor from these mitochondrially mutant cells may be oxygen, forming extracellular superoxide. The mosaic ("hotspot") distribution of this superoxide would limit its dismutation by extracellular superoxide dismutase; it may thus reduce transition metals leading to oxidation of circulating material, such as LDL. This would raise systemic oxidative stress, greatly amplifying the damage done by the originating mitochondrially mutant cells. This model, now known as the "reductive hotspot hypothesis," has recently gained much indirect experimental support; several direct tests of it are also feasible.

Dietary antioxidants inhibit development of fatty streak lesions in the LDL receptor-deficient mouse

Oxidized low density lipoprotein (LDL) promotes atherogenesis. Although pharmacological antioxidants such as probucol inhibit both LDL oxidation and atherosclerosis in hyperlipidemic animals, the effects of natural antioxidants such as vitamin E are inconclusive. To further determine the effects of supplemental dietary antioxidants in vivo, we evaluated whether combined dietary antioxidants (0.1% vitamin E, 0.5% beta-carotene, and 0.05% vitamin C) inhibit LDL oxidation and fatty streak lesion development in homozygous LDL receptor-null (LDLR-/-) mice fed a high-fat, high-cholesterol diet. An additional group of mice were fed black tea, which has been shown to inhibit LDL oxidation in vitro. After receiving a high-fat, high-cholesterol diet for 8 weeks, the combined antioxidant-supplemented (antioxidant) group (n=18), tea group (n=19), and control group (n=17) had equivalent plasma cholesterol levels. LDL oxidation, as measured by the lag phase of conjugated diene formation, was markedly inhibited in the antioxidant group compared with the tea or control groups [mean lag phases=143+/-7 (antioxidant), 100+/-5 (tea), and 84+/-4 (control) minutes; P<0.0001 antioxidant versus tea or control]. The cross-sectional surface area of fatty streak lesions in the aortic sinus was reduced by 60% in the antioxidant group compared with both the tea and control groups (P<0.0001 antioxidant versus tea or control). There was no difference in lesion area between tea and control groups. Although both LDL oxidation and atherosclerosis were significantly inhibited in the antioxidant group, no correlation between lag phase values and lesion size was observed among individual animals. Furthermore, black tea did not inhibit fatty streak development in LDLR-/- mice. These data suggest that combined natural dietary antioxidants inhibit both LDL oxidation and atherogenesis in animals with elevated LDL but that inhibition of LDL oxidation alone may not prevent the development of atherosclerosis.

Lipofuscin: mechanisms of formation and increase with age

Lipofuscin (age pigment) is a brown-yellow, electron-dense, autofluorescent material that accumulates progressively over time in lysosomes of postmitotic cells, such as neurons and cardiac myocytes. The exact mechanisms behind this accumulation are still unclear. This review outlines the present knowledge of age pigment formation, and considers possible mechanisms responsible for the increase of lipofuscin with age. Numerous studies indicate that the formation of lipofuscin is due to the oxidative alteration of macromolecules by oxygen-derived free radicals generated in reactions catalyzed by redox-active iron of low molecular weight. Two principal explanations for the increase of lipofuscin with age have been suggested. The first one is based on the notion that lipofuscin is not totally eliminated (either by degradation or exocytosis) even at young age, and, thus, accumulates in postmitotic cells as a function of time. Since oxidative reactions are obligatory for life, they would act as age-independent enhancers of lipofuscin accumulation, as well as of many other manifestations of senescence. The second explanation is that the increase of lipofuscin is an effect of aging, caused by an age-related enhancement of autophagocytosis, a decline in intralysosomal degradation, and/or a decrease in exocytosis.

An alternative explanation for anomalies in "soluble lipofuscin" fluorescence data from insects, crustaceans, and other aquatic species

Published attempts to extract lipofuscin from crustaceans and fish to assess age for fisheries research purposes have used essentially the same extraction methodology applied to insects, but have neither shown a conclusive age-dependence of spectrally similar fluorescence nor proved its association with lipofuscin. The reported lipofuscin solvent extraction method for fleshflies, Sarcophaga bullata, was manipulated by varying wash volume. This revealed that almost all age-dependent blue fluorescent material persisting in lipid fractions was actually pteridine-like. This finding was consistent with some previous independent results for Musca domestica. Examination of reported lipofuscin extraction protocols for other insects suggested that this problem was probably widespread. The pteridines are known to occur in unusually high amounts in insects, accumulating with age specifically in some members of this group by storage excretion, probably as a terrestrial water conservation strategy. In addition, there is growing evidence in the gerontological literature for other groups that solvent extracted blue fluorescence is not a true measure of lipofuscin content in tissues. These findings provide considerable insight into anomalies in putative lipofuscin fluorescence data between the insects and various aquatic species and suggest that there may be little basis for expectations of age-dependent fluorescence from aquatic species when the same gross extraction and crude purification methods are used.

Lipofuscin and lipofuscin-like substances

Lipofuscin is defined as being a yellowish brown, lipid-rich, heterogeneous, cytoplasmic granular pigment emitting an intense yellow autofluorescence when excited with ultraviolet light, which accumulates in various tissues of animals during their aging. It is believed that the pigments are derived from the reaction of some of reactive secondary products including malonaldehyde, formed during membranous lipid peroxidation, with amino groups of phospholipids and proteins, etc., and that these formations are accompanied by alteration of the membrane structure and inactivation of the enzymes. The fluorescence measurement of the pigments is widely used as a parameter of lipid peroxidation in vivo as well as in vitro. However, their origin, chemical structure, biological significance or fate has not as yet been fully elucidated. This article introduces and discusses the recent studies on these problems.

Vitamin E deficiency and the susceptibility to lipid peroxidation of mouse cardiac and skeletal muscles

Effects of a short-term vitamin E deficiency on some lipid peroxidative properties were investigated in mouse cardiac and skeletal muscles. The concentration of vitamin E decreased 35.8% in 5 weeks and 61.2% in 12 weeks in skeletal muscle. The corresponding decrease in cardiac muscle was 65.7% in 12 weeks. Simultaneously the susceptibility of muscle homogenates to in vitro lipid peroxidation increased with 48.6% (5 weeks) and 44.5% (12 weeks) in skeletal muscle and with 101.8% (12 weeks) in cardiac muscle. Highly significant negative correlations were observed between the concentration of vitamin E and in vitro lipid peroxidation in cardiac and skeletal muscles. Also the sensitivity to Fe2+-induced peroxidation was increased in skeletal muscle after the deficiency of 5 weeks. The total contents of peroxidizable lipids (Fe2+-induction) were significantly (approx. 20%) decreased after 12 weeks in cardiac and skeletal muscles. The concentration of lipofuscin was unaffected in both muscles of vitamin E-deficient mice. Vitamin E deficiency (5 weeks) decreased the activity of selenium-dependent glutathione peroxidase in skeletal muscle but did not affect the activities of catalase and beta-glucuronidase and the concentrations of protein, reduced glutathione and total sulfhydryl groups. These results show that a short-term vitamin E deficiency affects the peroxidative properties of cardiac and skeletal muscles and may thus expose the muscles to peroxidation injuries.