Telomere shortening triggers a p53-dependent cell cycle arrest via accumulation of G-rich single stranded DNA fragments.

It has been repeatedly suspected that telomere shortening might be one possible trigger of the p53-dependent cell cycle arrest, although the mechanism of this arrest remained unclear. Telomeres in human cells under mild oxidative stress accumulate single-strand damage faster than interstitial repetitive sequences. In MRC-5 fibroblasts and U87 glioblastoma cells, which both express wild-type p53, oxidative stress-mediated production of single-strand damage in telomeres is concomitant to the accumulation of p53 and p21 and to cell cycle arrest. This response can be modeled by treatment of cells with short single stranded telomeric G-rich DNA fragments. The arrest is transient in U87 cells. Recovery from it is accompanied by up-regulation of telomerase activity and elongation of telomeres. Overexpression of mutated p53 is sufficient to reverse the phenotype of inhibition as well as the delayed activation of telomerase. These data suggest that the production of G-rich single stranded fragments during the course of telomere shortening is sufficient to trigger a p53 dependent cell cycle arrest.

Protein oxidation and proteolysis in RAW264.7 macrophages: effects of PMA activation.

Macrophages are stimulable cells able to increase the production of reactive oxygen and nitrogen species dramatically for a short period of time. Free radicals and other oxidants are able to oxidize the intracellular protein pool. These oxidized proteins are selectively recognized and degraded by the intracellular proteasomal system. We used the mouse macrophage-like cell line RAW264.7 to test whether macrophagial cells are able to increase their protein turnover after oxidative stress and whether this is accompanied by an increased protein oxidation. Macrophagial cells are particularly susceptible to bolus additions of hydrogen peroxide and peroxynitrite. In further experiments we activated RAW264.7 cells with PMA to test whether the production of endogenous oxidants has analogous effects. A clear dependence of the protein turnover and protein oxidation on the oxidative burst could be measured. In further experiments the role of the proteasomal system in the selective removal of oxidized proteins could be revealed exploring the proteasome specific inhibitor lactacystin. Therefore, although oxidants are able to attack the intracellular protein pool in macrophages, these cells are able to remove oxidized proteins selectively and protect the intracellular protein pool from oxidation.

Proteasome-dependent degradation of oxidized proteins in MRC-5 fibroblasts.

Fibroblasts were exposed to various concentrations of hydrogen peroxide and the removal of oxidized proteins was followed by determining protein-bound carbonyls. Fibroblasts are able to increase the turnover of metabolically radiolabeled proteins after treatment with hydrogen peroxide. It was demonstrated for the first time, that the increased protein turnover was accompanied by a removal of protein-bound carbonyl groups. The proteasome-specific inhibitor lactacystin was able to inhibit the elimination of protein-bound carbonyl groups. Therefore, the key role of the proteasome in the degradation of oxidized proteins in fibroblasts could be demonstrated.

Accumulation of single-strand breaks is the major cause of telomere shortening in human fibroblasts.

Telomere shortening triggers replicative senescence in human fibroblasts. The inability of DNA polymerases to replicate a linear DNA molecule completely (the end replication problem) is one cause of telomere shortening. Other possible causes are the formation of single-stranded overhangs at the end of telomeres and the preferential vulnerability of telomeres to oxidative stress. To elucidate the relative importance of these possibilities, amount and distribution of telomeric single-strand breaks, length of the G-rich overhang, and telomere shortening rate in human MRC-5 fibroblasts were measured. Treatment of nonproliferating cells with hydrogen peroxide increases the sensitivity to S1 nuclease in telomeres preferentially and accelerates their shortening by a corresponding amount as soon as the cells proliferate. A reduction of the activity of intracellular peroxides using the spin trap alpha-phenyl-t-butyl-nitrone reduces the telomere shortening rate and increases the replicative life span. The length of the telomeric single-stranded overhang is independent of DNA damaging stresses, but single-strand breaks accumulate randomly all along the telomere after alkylation. The telomere shortening rate and the rate of replicative aging can be either accelerated or decelerated by a modification of the amount of oxidative stress. Quantitatively, stress-mediated telomere damage contributes most to telomere shortening under standard conditions.

Degradation of hypochlorite-damaged glucose-6-phosphate dehydrogenase by the 20S proteasome.

Glucose-6-phosphate dehydrogenase (G6PD) was treated with various concentrations of hypochlorite, which is produced by myeloperoxidase and is one of the most important oxidants during inflammatory processes. Inhibition of enzymatic activity, protein fragmentation, and proteolytic susceptibility toward the isolated 20S proteasome of G6PD were investigated. With rising hypochlorite concentrations, an increased proteasomal degradation of G6PD was measured. This occurred at higher hypochlorite concentrations than G6PD inactivation and at lower levels than G6PD fragmentation. The proteolytic activities of the 20S proteasome itself was determined by degradation of oxidized model proteins and cleavage of the synthetic proteasome substrate suc-LLVY-MCA. Proteasome activities remained intact at hypochlorite concentrations in which G6PD is maximally susceptible to proteasomal degradation. Only higher hypochlorite concentrations could decrease the proteolytic activities of the proteasome, which was accompanied by disintegration and fragmentation of the proteasome and proteasome subunits. Therefore, we conclude that the 20S proteasome can degrade proteins moderately damaged by hypochlorite and could contribute to an increased protein turnover in cells exposed to inflammatory stress.

Accelerated telomere shortening in fibroblasts after extended periods of confluency.

Telomere length in MRC-5 fibroblasts remains constant if the cells are proliferation-inhibited for up to 3 months by confluency. However, the apparent frequency of single-stranded sites in telomeres, measured as sensitivity to degradation by S1 nuclease, increases about fourfold during this extended inhibition of proliferation. After release of the cells, the frequency of telomeric single-stranded sites decreases to control values, and the telomere shortening rate increases about threefold as compared to controls proliferating without inhibition. This acceleration is transitory, the telomere shortening rate decreases to control values after about two population doublings after release. Finally, temporarily arrested fibroblast populations senesce at a lower cumulative population doubling level, but at about the same telomere length, as continuously proliferating controls. The data suggest that metabolic time-dependent single-strand degradation is a major cause of telomere shortening. They support the idea that telomere shortening plays an important role in triggering cellular senescence.

BJ fibroblasts display high antioxidant capacity and slow telomere shortening independent of hTERT transfection.

Human foreskin BJ fibroblasts are well protected against oxidative stress as shown by their low intracellular peroxide content, low levels of protein carbonyls, and low steady-state lipofuscin content as compared to other primary human fibroblasts. This correlates with a long replicative life span of the parental cells of about 90 population doublings and a telomere-shortening rate of only 15-20 bp/PD. This value might define the upper limit of a telomere-shortening rate that can still be explained by the end replication problem alone. In BJ clones immortalized by transfection with hTERT, the catalytic subunit of telomerase, the same telomere-shortening rate as in parental cells is observed over a long time despite strong telomerase activity. Hyperoxia, which induces oxidative stress and accelerates telomere shortening in a variety of human fibroblast strains, does not do so in BJ cells. It is possible that the high antioxidative capacity of BJ cells, by minimizing the accumulation of genomic damage, is instrumental in the successful immortalization of these cells by telomerase.

Protein oxidation and degradation during proliferative senescence of human MRC-5 fibroblasts.

One of the highlights of age-related changes of cellular metabolism is the accumulation of oxidized proteins. The aging process on a cellular level can be treated either as the ongoing proliferation until a certain number of cell divisions is reached (the Hayflick limit) or as the aging of nondividing cells, that is, the age-related changes in cells without proliferation. The present investigation was undertaken to reveal the changes in protein turnover, proteasome activity, and protein oxidation status during proliferative senescence. We were able to demonstrate that the activity of the cytosolic proteasomal system declines dramatically during the proliferative senescence of human MRC-5 fibroblasts. Regardless of the loss in activity, it could be demonstrated that there are no changes in the transcription and translation of proteasomal subunits. This decline in proteasome activity was accompanied by an increased concentration of oxidized proteins. Cells at higher proliferation stages were no longer able to respond with increased degradation of endogenous [(35)S]-Met-radiolabeled proteins after hydrogen peroxide- or quinone-induced oxidative stress. It could be demonstrated that oxidized proteins in senescent human MRC-5 fibroblasts are not as quickly removed as they are in young cells. Therefore, our study demonstrates that the accumulation of oxidized proteins and decline in protein turnover and activity of the proteasomal system are not only a process of postmitotic aging but also occur during proliferative senescence and result in an increased half-life of oxidized proteins.

Increased levels of 4-hydroxynonenal modified proteins in plasma of children with autoimmune diseases.

Analysis of serum samples of healthy children (n = 11) and children with Systemic Lupus Erythematosus (SLE), (n = 21) was performed by SDS-PAGE and immunoblot with an antibody directed against proteins modified by lipid peroxidation (LPO) product 4-hydroxynonenal (HNE). A single major stained protein band was detected. By comparison of the molecular weights in nonreducing and reducing SDS-PAGE was found that the main protein modified by HNE is immunoglobulin G. Significantly higher concentrations of the aldehyde modified protein were found in children with high disease activity of SLE measured by SLE disease activity index (SLEDAI). Lipid peroxidation measured by malondialdehyde and 4-hydroxynonenal concentrations show an enhanced level of both compounds also in patients with the active autoimmune disease. Therefore, it can be assumed that free radical mediated processes play a pathophysiological role in the active phase of SLE and HNE-modified serum proteins are a further parameter for the detection of in vivo LPO.

Dose- and wavelength-dependent oxidation of crystallins by UV light--selective recognition and degradation by the 20S proteasome.

The lens of the human eye is a suitable model for age-related alterations at the molecular level. Age-related cataract formation is closely related to the accumulation of oxidatively altered proteins. In this study the influence of UV-A, UV-B, and UV-C irradiation on the proteolytic susceptibility of alpha-, betaL-, and betaH-crystallins by the isolated 20S proteasome was investigated. The proteins were irradiated with 280, 300, and 350 nm monochromatic light. Changes of the physical properties of the crystallins were characterized by absorbance measurements at 280 nm, fluorescence spectra, and SDS-PAGE-electrophoresis. The proteolytic susceptibility of crystallins was maximal after irradiation at 280 nm and three- to fivefold lower at 300 nm. Irradiation at 350 nm was not able to initiate proteolysis, probably due to protein-aggregate formation of higher molecular weight, as shown by SDS-PAGE. The damage of crystallins by UV-C light might be a signal for its proteolytic degradation by the 20S proteasome, whereas UV-B and UV-A do not increase the proteolytic susceptibility to the same extent but promote the formation of crosslinked proteins. Therefore, irradiation with UV, which is not followed by an increase in the proteolytic susceptibility, is accompanied by the formation of crosslinked proteins. It was concluded, that also long UV-B and UV-A may be involved in age-related alterations of the human lens and cataract formation.

Oxidized proteins as a marker of oxidative stress during coronary heart surgery.

The measurement of the degree of oxidative stress in patients often causes problems because of the lack of useful parameters. Therefore, we used an ELISA technique to evaluate serum protein carbonyls as a parameter of oxidative stress in patients during coronary heart surgery. Protein carbonyls were detected in serum samples of 14 patients undergoing coronary surgery and cardiopulmonary artery bypass grafting. A clear 2- to 3-fold increase in protein carbonyls in serum samples taken from human venous coronary sinus could be detected in the reperfusion period of the heart. We compared these data with markers of oxidative stress previously used, such as the glutathione status and the lipid peroxidation product malondialdehyde (MDA). Strong correlations of the protein carbonyl formation with MDA (r2 = 0.86) and oxidized glutathione (r2 = 0.81) were found in the early reperfusion stage. Increased levels of oxidized glutathione and MDA were detected only in the early reperfusion period. In contrast, the serum protein carbonyl content remained elevated for several hours, indicating a considerably slower serum clearance of oxidized proteins compared with that of lipid peroxidation products and the normalization of the glutathione status. We therefore concluded that the measurement of serum carbonyls by this ELISA technique is suitable to detect oxidative stress in serum samples of patients. The relative stability of the parameter makes the protein carbonyl detection even more valuable for clinical purposes.

beta-Endorphin-containing memory-cells and mu-opioid receptors undergo transport to peripheral inflamed tissue.

Immunocyte-derived beta-endorphin can activate peripheral opioid receptors on sensory neurons to inhibit pain within inflamed tissue. This study examined mu-opioid receptors (MOR) on sensory nerves and beta-endorphin (END) in activated/memory CD4(+) cells (the predominant population homing to inflamed tissue). We found an upregulation of MOR in dorsal root ganglia, an increased axonal transport of MOR in the sciatic nerve and an accumulation of MOR in peripheral nerve terminals in Freund's adjuvant-induced hindpaw inflammation. A large number of CD4(+) cells containing beta-endorphin, but very few naive cells (CD45RC(+)), were observed in inflamed tissue, suggesting that this opioid is mainly present in activated/memory cells (CD4(+)/CD45RC(-)). Taken together, our results indicate an enhanced transport of both MOR and of the endogenous ligand beta-endorphin to injured tissue. This unique simultaneous upregulation of both receptors and ligands may serve to prevent excessive and/or chronic inflammatory pain.

Lipofuscin accumulation in proliferating fibroblasts in vitro: an indicator of oxidative stress.

The amount of the ageing pigment, lipofuscin, found in replicating cells depends both on its rate of formation as well as its rate of dissolution by cell division. We present a model which allows the calculation of the lipofuscin accumulation rate from measurements of its amount and of the cell cycle duration. In two human fibroblast strains, the accumulation rate correlates well with differences in oxidative stress/antioxidative defence as measured by intracellular peroxide generation, protein carbonyl content, telomere shortening rate and replicative life span. The lipofuscin content increases with replicative age in both cultures. The rather steep increase in presenescent fibroblasts is not solely due to a slowing down of the cell turnover, but is partially caused by an increased rate of lipofuscin formation/ accumulation. This might indicate an increased level of oxidative stress in presenescent fibroblasts, or a decreased efficiency of proteolytic systems, or both. The results are in accordance with data demonstrating an adverse effect of lipofuscin accumulation on cellular protein turnover and suggest an active role for lipofuscin accumulation in cellular senescence.

Evidence for a novel ATP-dependent protease from the rat liver mitochondrial intermembrane space: purification and characterisation.

An ATP-dependent protease in the intermembrane space of rat liver mitochondria, MISP I (mitochondrial intermembrane space protease), was partially purified and characterised. The protease complex has a molecular mass of 200 kDa and appears to be an oligomeric enzyme complex. The proteolytic activity of the enzyme can be stimulated up to 3-fold by Mg2+ATP. The Km for ATP is 200 microM. Nucleoside triphosphates, but not ADP, AMP, or nonhydrolysable ATP analogues, can substitute for ATP. The protease exhibits multicatalytic properties with chymotrypsin-like, peptidyl-glutamyl-hydrolysing, and trypsin-like activities. Of the latter the trypsin-like activity is not enhanced by ATP. In addition to the hydrolysis of fluorogenic peptide substrates the protease is able to degrade radiolabeled model proteins. The ATP-dependent mitochondrial protease was characterised as a cysteine protease sensitive to hemine. The cross reactivity of an anti-human-S4 antibody raised against an ATPase subunit of the PA700 complex with a component of MISP I indicated a structural relationship. Furthermore, ATP-agarose-binding assays revealed the connection of the peptide hydrolysing activity with an ATP binding domain. The data presented here and a comparison with known ATP-dependent mitochondrial proteases demonstrated that MISP I represents a novel ATP-dependent protease in the mitochondrial intermembrane space of rat liver.

Age-related changes in protein oxidation and proteolysis in mammalian cells.

Reactive oxygen species generated as by-products of oxidative metabolism, or from environmental sources, frequently damage cellular macromolecules. Proteins are recognized as major targets of oxidative modification, and the accumulation of oxidized proteins is a characteristic feature of aging cells. An increase in the amount of oxidized proteins has been reported in many experimental aging models, as measured by the level of intracellular protein carbonyls or dityrosine, or by the accumulation of protein-containing pigments such as lipofuscin and ceroid bodies. In younger individuals, moderately oxidized soluble cell proteins appear to be selectively recognized and rapidly degraded by the proteasome. An age-related accumulation of oxidized proteins could, therefore, be a result of declining activity of the proteasome. Previous research to investigate the notion of an age-related decline in the content and/or activity of the proteasome has generated contradictory results. The latest evidence, including our own recent findings, indicates that proteasome activity does, indeed, decline during aging as the enzyme complex is progressively inhibited by oxidized and cross-linked protein aggregates. We propose that cellular aging involves both an increase in (mitochondrial) oxidant production and a progressive decline in proteasome activity. Eventually so much proteasome is inactivated that oxidized proteins begin to accumulate rapidly and contribute to cellular dysfunction and senescence.

Hydrogen peroxide-mediated protein oxidation in young and old human MRC-5 fibroblasts.

It is suggested that the aging process is dependent on the action of free radicals. One of the highlights of age-related changes of cellular metabolism is the accumulation of oxidized proteins. The present investigation was undertaken to reveal the proliferation-related changes in the protein oxidation and proteasome activity during and after an acute oxidative stress. It could be demonstrated that the activity of the cytosolic proteasomal system declines during proliferative senescence of human MRC-5 fibroblasts and is not able to remove oxidized proteins in old cells efficiently. Whereas in young cells removal of oxidized proteins was accompanied by an increase in the overall protein turnover, this increase in protein turnover could not be seen in old MRC-5 fibroblasts. Therefore, our studies demonstrate that old fibroblasts are much more vulnerable to the accumulation of oxidized proteins after oxidative stress and are not able to remove these oxidized proteins as efficiently as young fibroblasts.

Identification of a novel ATP-dependent proteolytic activity in mitochondrial intermembrane space.

The formation of primary amines via proteolysis was monitored in isolated rat liver, kidney cortex and heart mitochondria in the presence and in the absence of ATP. The highest proteolytic activity was detected in kidney cortex mitochondria with about 120 nmoles primary amines/hour x mg protein. The formation rates of liver mitochondria amounted to about 100 nmoles primary amines/hour x mg protein and in heart mitochondria about 60 nmoles primary amines/hour x mg protein. In all mitochondria investigated an ATP-dependent proteolysis of 20-40 nmoles primary amines/hour x mg protein was detected. The effects of various protease inhibitors were tested in rat liver mitochondria and thiol-specific reagents showed a 35-70% inhibition. The ATP stimulable portion of proteolysis was blocked by hemin, a known inhibitor of ATP-dependent proteases. The localization of the proteolytic activity was tested by fractionation of the compartments of rat liver mitochondria using the flourogenic peptide suc-Leu-Leu-Val-Tyr-MCA as substrate. About 90% of the ATP-dependent peptide cleavage activity were found in the mitochondrial intermembrane space. The characteristics of the enzyme were compared to those of other known mitochondrial ATP-dependent proteases and it was concluded that it represents a novel proteolytic system of the intermembrane space.

4-Hydroxynonenal-modified amyloid-beta peptide inhibits the proteasome: possible importance in Alzheimer's disease.

The amyloid beta-peptide (Abeta) is a 4-kDa species derived from the amyloid precursor protein, which accumulates in the brains of patients with Alzheimer's disease. Although we lack full understanding of the etiology and pathogenesis of selective neuron death, considerable data do imply roles for both the toxic Abeta and increased oxidative stress. Another significant observation is the accumulation of abnormal, ubiquitin-conjugated proteins in affected neurons, suggesting dysfunction of the proteasome proteolytic system in these cells. Recent reports have indicated that Abeta can bind and inhibit the proteasome, the major cytoslic protease for degrading damaged and ubiquitin-conjugated proteins. Earlier results from our laboratory showed that moderately oxidized proteins are preferentially recognized and degraded by the proteasome; however, severely oxidized proteins cannot be easily degraded and, instead, inhibit the proteasome. We hypothesized that oxidatively modified Abeta might have a stronger (or weaker) inhibitory effect on the proteasome than does native Abeta. We therefore also investigated the proteasome inhibitory action of Abeta1-40 (a peptide comprising the first 40 residues of Abeta) modified by the intracellular oxidant hydrogen peroxide, and by the lipid peroxidation product 4-hydroxynonenal (HNE). H2O2 modification of Abeta1-40 generates a progressively poorer inhibitor of the purified human 20S proteasome. In contrast, HNE modification of Abeta1-40 generates a progressively more selective and efficient inhibitor of the degradation of fluorogenic peptides and oxidized protein substrates by human 20S proteasome. This interaction may contribute to certain pathological manifestations of Alzheimer's disease.

Ferritin oxidation in vitro: implication of iron release and degradation by the 20S proteasome.

Ferritin, the major iron storage protein in mammalian cells, was treated with various concentrations of different oxidants: xanthine/xanthine oxidase, Sin-1 (3-morpholinosydnonimine, purchased from Alexis, Grunberg, Germany), DEA-NO (Diethylamine NONOate, purchased from Calblochem-Novabiochem, Schwalbach, Germany), and hydrogen peroxide. The proteolytic susceptibility towards the isolated 20S proteasome of untreated ferritin and oxidized ferritin was measured in parallel with the iron liberated by these oxidants. With increasing hydrogen peroxide, Sin-1, and xanthine oxidase concentrations, the measured proteasomal degradation of ferritin also increased. At higher oxidant concentrations, however, the proteolytic susceptibility began to decrease. The oxidation of ferritin by DEA-NO was accompanied by a lesser increase of proteolytic susceptibility in comparison with the effects of the other oxidants. Addition of DEA-NO to Sin-1 suppressed the increase in proteolytic susceptibility of ferritin, whereas adding xanthine/xanthine oxidase had no additional effect. Iron was liberated readily from ferritin as a result of the oxidation process, although the increase in proteolytic susceptibility was not always correlated to the iron release. In fact, the degradation of oxidatively damaged ferritin was not accompanied by a further increase of free iron. Therefore, we conclude that the proteasome is a secondary antioxidative defense system that degrades only nonfunctional ferritin.