Bertrand Friguet

Oxidized protein degradation and repair in ageing and oxidative stress

Cellular ageing is characterized by the accumulation of oxidatively modified proteins which may be due to increased protein damage and/or decreased elimination of oxidized protein. Since the proteasome is in charge of protein turnover and removal of oxidized protein, its fate during ageing and upon oxidative stress has received special attention, and evidence has been provided for an age‐related impairment of proteasome function. However, proteins when oxidized at the level of sulfur‐containing amino acids can also be repaired. Therefore, the fate of the methionine sulfoxide reductase system during ageing has also been addressed as well as its role in protection against oxidative stress.

Age-related alterations of proteasome structure and function in aging epidermis.

Recent studies on the effect of aging in epidermal cells have evidenced a decrease of proteasome activity and content, suggesting that proteasome is down-regulated in aged cells. The 20S proteasome is the major proteolytic system that has been implicated in removal of abnormal and oxidatively damaged proteins. Therefore, a decreased proteasome content may explain, at least in part, the well-documented age-related accumulation of oxidized proteins. To gain further insight in other mechanisms that may be implicated in a decreased activity of the proteasome with age, 20S proteasome has been purified from the epidermis from donors of different ages: young, middle-aged and old. The patterns of proteasome subunits have been analyzed by 2D gel electrophoresis to determine whether its structure is also affected with age. The 2D gel pattern of proteasome subunits was found to be modified for four subunits, indicating that the observed decline in proteasome activity with age may also be related to alterations of its subunits. These subunit alterations are likely to be involved in the age-related decrease of proteasome activity since the specific peptidase activities of the purified proteasome were found to be decreased with age.

Protein Degradation by the Proteasome and Its Implications in Aging

Abstract: Free radical damage to cellular components is believed to contribute to the aging process. Studies on proteins have shown both an age‐related decline in several enzyme activities and an age‐related accumulation of oxidized forms of protein. Oxidized forms of protein are generally degraded more rapidly than their native counterparts. Indeed, the normal functions of the cell involve the regular elimination of these altered molecules. The proteasome, a multienzymatic proteolytic complex, is the major enzymatic system in charge of cellular “cleansing” and plays a key role in the degradation of damaged proteins. Consequently, proteasome function is very important in controlling the level of altered proteins in eukaryotic cells. Because the steady‐state level of oxidized protein reflects the balance between the rate of protein oxidation and the rate of protein degradation, age‐related accumulation of altered protein can be due to an increase of free radical‐mediated damage, a loss of protease activity, or the combination of both mechanisms. One of the hypotheses put forward to explain the accumulation of altered proteins is the decrease of proteasome activity with age. In this paper, the importance of oxidative damage to proteins and that of their elimination by the proteasome are first described. Then, evidence for a decline of proteasome activity upon aging and upon oxidative stress is provided by studies from our and other laboratories.

Fibroblast cultures from healthy centenarians have an active proteasome

Healthy centenarians represent the best example of successful ageing. Various studies have shown that centenarians have escaped the major age-associated diseases, they have several well-conserved immune parameters and at least one gene allele has been identified and linked with their increased longevity. During ageing there is an accumulation of oxidised proteins, a phenomenon that has been related to an impaired function of the 20S proteasome in aged cells. We have, therefore, analysed the expression and the proteolytic activity of the proteasome in centenarian cells. Four fibroblast cultures derived from healthy centenarians were studied and compared with cultures derived from adult donors of different ages. Analysis of several proteasome subunits RNA expression levels, determination of one peptidase activity and identification of oxidised proteins in these samples revealed that centenarian cultures have a functional proteasome. In addition, it was found that the centenarian cultures exhibit characteristics similar to the younger rather than the older control donors derived cultures in all three assays. These data indicate that centenarian cells may be different from elderly donors cells, thus opening up new dimensions for the identification and characterisation of factors that are linked with longevity.

Mitochondrial protein oxidation and degradation in response to oxidative stress and aging.

Mitochondria are a major source of intracellular reactive oxygen species (ROS), the production of which increases with age. These organelles are also targets of oxidative damage. The deleterious effects of ROS may be responsible for impairment of mitochondrial function observed during various pathophysiological states associated with oxidative stress and aging. An important factor for protein maintenance in the presence of oxidative stress is enzymatic reversal of oxidative modifications and/or protein degradation. Failure of these protein maintenance systems is likely a critical component of the aging process. Mitochondrial matrix proteins are sensitive to oxidative inactivation and oxidized proteins are known to accumulate during aging. The ATP-stimulated mitochondrial Lon protease is a highly conserved protease found in prokaryotes and the mitochondrial compartment of eukaryotes and is believed to play an important role in the degradation of oxidized mitochondrial matrix proteins. Age-dependent declines in the activity and regulation of this proteolytic system may underlie accumulation of oxidatively modified and dysfunctional protein and loss in mitochondrial viability.

Subcellular localization of methionine sulphoxide reductase A (MsrA): evidence for mitochondrial and cytosolic isoforms in rat liver cells

Proteins are sensitive to reactive oxygen species, and the accumulation of oxidized proteins has been implicated in the aging process and in other age-related pathologies. In proteins, methionine residues are especially sensitive to oxidation, leading to S - and R -methionine sulphoxide diastereoisomers, the reversion of which is achieved by the peptide methionine sulphoxide reductases MsrA and MsrB respectively. The MsrA enzyme, in addition to its role in repair, forms part of the reactive oxygen species scavenging systems that are important in cellular antioxidant defence. MsrA is present in most living organisms, and the mammalian enzyme has been detected in all tissues investigated. In the present study, we investigated the subcellular distribution of MsrA in rat liver cells. Since it seemed likely that MsrA may be localized in areas where reactive oxygen species are produced, rat liver mitochondrial matrix and cytosolic extracts were prepared. The presence of MsrA was assayed in these subcellular compartments by monitoring peptide methionine sulphoxide reductase enzymic activity, by Western blotting and by in situ immunolocalization by electron microscopy using a specific antibody. Moreover, MsrA was identified by MS in a partially purified cytosolic fraction and in a mitochondrial matrix crude extract. Rat MsrA isoforms are encoded by a single gene, and it is suggested that the precursor of the mitochondrial form contains an N-terminal cleavable signal sequence that localizes the MsrA to this organelle. Finally, two-dimensional gel electrophoresis followed by Western-blot analysis of partially purified MsrA from the cytosol and mitochondria, and comparison with the two-dimensional patterns of oxidized recombinant MsrA, revealed oxidative modifications of cysteine residues.

Enzymatic reactions involved in the repair of oxidized proteins

Proteins are the targets of reactive oxygen species, and cell aging is characterized by a build-up of oxidized proteins. Oxidized proteins tend to accumulate with age, due to either an increase in the rate of protein oxidation, a decrease in the rate of oxidized protein repair and degradation, or a combination of both mechanisms. Oxidized protein degradation is mainly carried out by the proteasomal system, which is the main intracellular proteolytic pathway involved in protein turnover and the elimination of damaged proteins. However, part of the oxidative damage to cysteine and methionine residues, two amino acids which are highly susceptible to oxidation, can be repaired by various enzymatic systems that catalyze the reduction of cysteine disulfide bridge, cysteine-sulfenic and -sulfinic acids as well as methionine sulfoxide. The aim of this review is to describe these enzymatic oxidized protein repair systems and their potential involvement in the decline of protein maintenance associated with aging, focusing in particular on the methionine sulfoxide reductases system.

Maintenance of proteins and aging: the role of oxidized protein repair.

According to the free radical theory of aging proposed by Denham Harman (Journal of Gerontology 1956, 11, pp. 298–300), the continuous oxidative damage to cellular components over an organisms life span is a causal factor of the aging process. The age-related build-up of oxidized protein is therefore resulting from increased protein oxidative damage and/or decreased elimination of oxidized proteins. In this mini-review, we will address the fate, during aging, of the protein maintenance systems that are involved in the degradation of irreversibly oxidized proteins and in the repair of reversible protein oxidative damage with a special focus on the methionine sulfoxide reductases system. Since these protein degradation and repair systems have been found to be impaired with age, it is proposed that not only failure of redox homeostasis but, as importantly, failure of protein maintenance are critical factors in the aging process.

Age-related increase of protein glycation in peripheral blood lymphocytes is restricted to preferential target proteins

Advanced glycation end products (AGE) have been analyzed in aging human peripheral blood lymphocytes since protein glycation and glycoxidation are believed to contribute to the intracellular age-related accumulation of damaged proteins, a process that has been associated with the cellular functional deficits that occur with age. The appearance of AGE in cell lysates was monitored with an enzyme-linked immunosorbent assay using an anti-AGE antibody raised against glycated RNAse. When lymphocyte cytosolic extracts from old donors (86-91 years old) were compared with those from young donors (20-25 years old), a small but significant 40% increase of protein glycation was observed. In both age groups, further analysis of the pattern of glycated proteins by two-dimensional gel electrophoresis followed by western blotting with the same anti-AGE antibody, showed that the protein silver stain and the immunoblot patterns were not superimposable indicating that glycoxidative modifications are targeting only a restricted set of proteins. Among these preferential protein targets, seven of them exhibited a significant age-related increased immunoreactivity with the anti-AGE antibody suggesting that the corresponding modified proteins might serve as biomarkers of aging lymphocytes.

The ubiquitin-proteasome system at the crossroads of stress-response and ageing pathways : A handle for skin care?

The regulation of gene expression at the transcriptional level has been considered for long as the main mechanism of cellular adaptive responses. Since the turn of the century, however, it is becoming clear that higher organisms developed a complex, sensitive and maybe equally important network of regulatory pathways, relying largely on protein interactions, post-translational modifications and proteolysis. Here we review the involvement of the ubiquitin-proteasome pathway of protein degradation at different levels of cellular life in relation with ageing, and with a special focus on skin. It comes out that the ubiquitin system plays a major role in signal transduction associated with stress and ageing, in skin in particular through the control of retinoid and NF-kappaB pathways. The understanding of specific proteolytic targeting by E3 ubiquitin-ligases paves the way for a new generation of active molecules that may control particular steps of normal and pathological ageing.