Ribosome and the Secret of Longevity (A Hypothesis)

Proteins in cells are constantly undergoing damage. Nevertheless, the concentration of damaged proteins in young organisms is maintained at a low level owing to the continual protein turnover: breakdown of damaged proteins and synthesis of new ones. During aging, the concentration of damaged proteins increases because of decelerating protein turnover, the cause of which is unknown; however, it may be related to the decrease in ribosome concentration.     

Global analysis of cellular protein flux quantifies the selectivity of basal autophagy

In eukaryotic cells, the macroautophagy pathway has been implicated in the degradation of long-lived proteins and damaged organelles. Although it has been demonstrated that macroautophagy can selectively degrade specific targets, its contribution to the basal turnover of cellular proteins had previously not been quantified on proteome-wide scales. In a recent study, we utilized dynamic proteomics to provide a global comparison of protein half-lives between wild-type and autophagy-deficient cells. Our results indicated that in quiescent fibroblasts, macroautophagy contributes to the basal turnover of a substantial fraction of the proteome. However, the contribution of macroautophagy to constitutive protein turnover is variable within the proteome. The methodology outlined in the study provides a global strategy for quantifying the selectivity of basal macroautophagy.     

Physiological significance of selective degradation of p62 by autophagy

Autophagy is a highly conserved bulk protein degradation pathway responsible for the turnover of long-lived proteins, disposal of damaged organelles, and clearance of aggregate-prone proteins. Thus, inactivation of autophagy results in cytoplasmic protein inclusions, which are composed of misfolded proteins and excess accumulation of deformed organelles, leading to liver injury, diabetes, myopathy, and neurodegeneration. Although autophagy has been considered non-selective, growing lines of evidence indicate the selectivity of autophagy in sorting vacuolar enzymes and in the removal of aggregate-prone proteins, unwanted organelles and microbes. Such selectivity by autophagy enables diverse cellular regulations, similar to the ubiquitin-proteasome pathway. In this review, we introduce the selective turnover of the ubiquitin- and LC3-binding protein ‘p62’ through autophagy and discuss its physiological significance.     

Regulation of protein turnover by heat shock proteins

Protein turnover reflects the balance between synthesis and degradation of proteins, and it is a crucial process for the maintenance of the cellular protein pool. The folding of proteins, refolding of misfolded proteins, and also degradation of misfolded and damaged proteins are involved in the protein quality control (PQC) system. Correct protein folding and degradation are controlled by many different factors, one of the most important of which is the heat shock protein family. Heat shock proteins (HSPs) are in the class of molecular chaperones, which may prevent the inappropriate interaction of proteins and induce correct folding. On the other hand, these proteins play significant roles in the degradation pathways, including endoplasmic reticulum-associated degradation (ERAD), the ubiquitin–proteasome system, and autophagy. This review focuses on the emerging role of HSPs in the regulation of protein turnover; the effects of HSPs on the degradation machineries ERAD, autophagy, and proteasome; as well as the role of posttranslational modifications in the PQC system.     

The eukaryotic translation elongation Factor 1Bgamma has a non-guanine nucleotide exchange factor role in protein metabolism

The turnover of damaged proteins is critical to cell survival during stressful conditions such as heat shock or oxidative stress. The accumulation of misfolded proteins in the endoplasmic reticulum (ER) is toxic to cells. Therefore these proteins must be efficiently exported from the ER and degraded by the proteasome or the vacuole. Previously it was shown that the loss of eukaryotic elongation factor 1Bγ (eEF1Bγ) from the yeast Saccharomyces cerevisiae results in resistance to oxidative stress. Strains lacking eEF1Bγ show severe defects in protein turnover during conditions of oxidative stress. Furthermore, these strains accumulate a greater amount of oxidized proteins, which correlates with changes in heat shock chaperones. These strains show severe defects in vacuole morphology and defects related to the maturation of carboxypeptidase Y that is not dependent on the catalytic subunit of the eEF1B complex as a guanine nucleotide exchange factor. Finally, eEF1Bγ co-immunoprecipitates with an essential component of ER-Golgi transport vesicles. Taken together, these results support a broader protein metabolism role for eEF1Bγ.     

Dynamics of photosystem II: a proteomic approach to thylakoid protein complexes

Oxygenic photosynthesis produces various radicals and activeoxygen species with harmful effects on photosystem II (PSII).Such photodamage occurs at all light intensities. Damaged PSIIcentres, however, do not usually accumulate in the thylakoidmembrane due to a rapid and efficient repair mechanism. Theexcellent design of PSII gives protection to most of the proteincomponents and the damage is most often targeted only to thereaction centre D1 protein. Repair of PSII via turnover of thedamaged protein subunits is a complex process involving (i)highly regulated reversible phosphorylation of several PSIIcore subunits, (ii) monomerization and migration of the PSIIcore from the grana to the stroma lamellae, (iii) partial disassemblyof the PSII core monomer, (iv) highly specific proteolysis ofthe damaged proteins, and finally (v) a multi-step replacementof the damaged proteins with de novo synthesized copies followedby (vi) the reassembly, dimerization, and photoactivation ofthe PSII complexes. These processes will shortly be reviewedpaying particular attention to the damage, turnover, and assemblyof the PSII complex in grana and stroma thylakoids during thephotoinhibition–repair cycle of PSII. Moreover, a two-dimensionalBlue-native gel map of thylakoid membrane protein complexes,and their modification in the grana and stroma lamellae duringa high-light treatment, is presented. Key words: Arabidopsis thylakoid membrane proteome, assembly of photosystem II, D1 protein, light stress, photosystem II photoinhibition, repair of photosystem II     

The chloroplast protease subunit ClpP4 is a substrate of the E3 ligase AtCHIP and plays an important role in chloroplast function

Animal CHIP proteins are chaperone-dependent E3 ubiquitin ligases that physically interact with Hsp70, Hsp90 and proteasome, promoting degradation of a selective group of non-native or damaged proteins in animal cells. The plant CHIP-like protein, AtCHIP, also plays important roles in protein turnover metabolism. AtCHIP interacts with a proteolytic subunit, ClpP4, of the chloroplast Clp protease in vivo, and ubiquitylates ClpP4 in vitro. The steady-state level of ClpP4 is reduced in AtCHIP-overexpressing plants under high-intensity light conditions, suggesting that AtCHIP targets ClpP4 for degradation and thereby regulates the Clp proteolytic activity in chloroplasts under certain stress conditions. Overexpression of ClpP4 in Arabidopsis leads to chlorotic phenotypes in transgenic plants, and chloroplast structures in the chlorotic tissues of ClpP4-overexpressing plants are abnormal and largely devoid of thylakoid membranes, suggesting that ClpP4 plays a critical role in chloroplast structure and function. As AtCHIP is a cytosolic protein that has been shown to play an important role in regulating an essential chloroplast protease, this research provides new insights into the regulatory networks controlling protein turnover catabolism in chloroplasts.     

Proteasome-mediated degradation of cotranslationally damaged proteins involves translation elongation factor 1A

Rad23 and Rpn10 play synergistic roles in the recognition of ubiquitinated proteins by the proteasome, and loss of both proteins causes growth and proteolytic defects. However, the physiological targets of Rad23 and Rpn10 have not been well defined. We report that rad23Delta rpn10Delta is unable to grow in the presence of translation inhibitors, and this sensitivity was suppressed by translation elongation factor 1A (eEF1A). This discovery suggested that Rad23 and Rpn10 perform a role in translation quality control. Certain inhibitors increase translation errors during protein synthesis and cause the release of truncated polypeptide chains. This effect can also be mimicked by ATP depletion. We determined that eEF1A interacted with ubiquitinated proteins and the proteasome following ATP depletion. eEF1A interacted with the proteasome subunit Rpt1, and the turnover of nascent damaged proteins was deficient in rpt1. An eEF1A mutant (eEF1A(D156N)) that conferred hyperresistance to translation inhibitors was much more effective at eliminating damaged proteins and was detected in proteasomes in untreated cells. We propose that eEF1A is well suited to detect and promote degradation of damaged proteins because of its central role in translation elongation. Our findings provide a mechanistic foundation for defining how cellular proteins are degraded cotranslationally.     

Kinetic implications of structural modification in protein turnover

It is thought that an important function of protein turnover is to purge the cell of damaged, displaced or unwanted polypeptide molecules. A model combining kinetic equations for synthesis, degradation and alteration is employed to evaluate this proposed role for protein turnover. It is demonstrated that the degradative system need not be aimed exclusively at altered protein molecules for turnover to be capable of controlling the size both of the total population and of the altered subpopulation. These conclusions are relevant to the part played by turnover in metabolic homeostasis, adaptation and catastrophe, and for the notion of control of protein turnover through specific "tagging" of molecules destined for breakdown.     

Stimulatory effect of vitamin C on autophagy in glial cells

Intracellular accumulation of damaged or abnormal proteins is a common event associated with numerous neurodegenerative diseases and other age-related pathologies. Increasing the activity of the intracellular proteolytic systems normally responsible for the removal of these abnormal proteins might be beneficial in lessening the severity or development of those pathologies. In this study we have used human astrocyte glial cells to investigate the effect of vitamin C (ascorbate) on the intracellular turnover of proteins. Supplementation of the culture medium with physiological concentrations of vitamin C did not affect protein synthesis, but did increase the rate of protein degradation by lysosomes. Vitamin C accelerated the degradation of intra- and extracellular proteins targeted to the lysosomal lumen by autophagic and heterophagic pathways. At the doses analyzed, vitamin C lowered and stabilized the acidic intralysosomal pH at values that result in maximum activation of the lysosomal hydrolases.     

Adenovirus degradation of cellular proteins

Eukaryotic cells orchestrate constant synthesis and degradation of intracellular components, including soluble proteins and organelles. The two major intracellular degradation pathways are the ubiquitin/proteasome system and autophagy. Whereas ubiquitin/proteasome system is involved in rapid degradation of proteins, autophagy selectively removes protein aggregates and damaged organelles. Failure of these highly adjusted proteolytic systems to maintain basal turnover leads to altered cellular homeostasis. During evolution, certain viruses have developed mechanisms to exploit their functions to facilitate their own replication, prevent viral clearance and promote the outcome of infection. In this article, we summarize the current opinion on adenoviruses (Ad) and molecular host cell targets, extending on recent evidences for protein degradation pathways in infected cells. We describe recently identified connections between Ad-mediated proteolysis and viral replication with main emphasis on the function of certain Ad proteins.     

Turnover of oxidatively modified proteins: the usage of in vitro and metabolic labeling

Cellular reactions to oxidative stress always include a response in the protein turnover. Therefore, cellular handling of proteins is important to observe. In this method review, radioactive labeling of proteins in vitro and in intact cells is described. The use of techniques based on the radioactive quantification of amino acids is much more selective and reliable than other nonradioactive methods for studying the protein turnover of both long- and short-lived proteins. Variations of such measurements allow one to measure protein synthesis, protein degradation, formation of insoluble proteins, and, perhaps, the turnover of individual proteins.     

Pyrrolidine dithiocarbamate and zinc inhibit proteasome-dependent proteolysis

Proteasomes play important roles in a variety of cellular processes such as cell cycle progression, signal transduction and immune responses. Proteasome activity is important in maintaining rapid turnover of short-lived proteins, as well as preventing accumulation of misfolded or damaged proteins. Alteration in ubiquitin-proteasome function may be detrimental to its crucial role in maintaining cellular homeostasis. Here, we have found that treatment of pyrrolidine dithiocarbamate (PDTC), a zinc ionophore, resulted in the accumulation of several proteasome substrates including p53 and p21 in HeLa cells. The PDTC effect was due to an extended half-life of these proteins through the mobilization of zinc. PDTC and/or zinc also increased fluorescence intensity of Ub(G76V)-GFP fusion protein that is degraded rapidly by the ubiquitin-proteasome system. Treatment of cells with zinc induced formation of ubiquitinated inclusions in the centrosome, a histological marker of proteasome inhibition. Western blotting showed zinc-induced increase in laddering bands of polyubiquitin-conjugated proteins. In vitro study, zinc inhibited the ubiquitin-independent proteasomal degradations of p21 and alpha-synuclein. These results suggest that zinc may modulate cell functions through its action on the turnover of proteins that are susceptible to proteasome-dependent proteolysis.     

Photoinhibition of photosystem I at chilling temperature and subsequent recovery in Arabidopsis thaliana

Chilling-induced photoinhibition and subsequent recovery was studied in Arabidopsis thaliana exposed to 4 degrees C and 150 micromol photons m(-2) s(-1). PSII showed progressive damage with a 14% decrease in quantum yield after 8 h exposure. In contrast, the damage to PSI leveled off after 8 h with a decrease in in vitro NADP+ photoreduction activity of around 32%. In vivo P700 measurements demonstrated that antenna efficiency was decreased by the photoinhibitory treatment. Measurements of P700 and immunoblotting demonstrated that the damaged PSI was not degraded during the 8 h light-chilling treatment, but after 12 h recovery at 20 degrees C, no damaged PSI remained in the thylakoids. Thus, degradation of damaged PSI is a step in the recovery and not a direct result of photodamage. Unlike photodamaged PSII, the PSI core complex is not repaired but completely degraded. In contrast, light harvesting complex I proteins have a slow turnover. PSII recovered completely within 8 h after transfer to 20 degrees C whereas PSI activity recovered very slowly, and the amount of PSI on a leaf area basis remained low even after 1 week at 20 degrees C. The results show that damage, protein turnover and recovery are well separated processes in Arabidopsis.     

A cut above the rest: the regulatory function of plant proteases

Proteolytic enzymes are intricately involved in many aspects of plant physiology and development. On the one hand, they are necessary for protein turnover. Degradation of damaged, misfolded and potentially harmful proteins provides free amino acids required for the synthesis of new proteins. Furthermore, the selective breakdown of regulatory proteins by the ubiquitin/proteasome pathway controls key aspects of plant growth, development, and defense. Proteases are, on the other hand, also responsible for the post-translational modification of proteins by limited proteolysis at highly specific sites. Limited proteolysis results in the maturation of enzymes, is necessary for protein assembly and subcellular targeting, and controls the activity of enzymes, regulatory proteins and peptides. Proteases are thus involved in all aspects of the plant life cycle ranging from the mobilization of storage proteins during seed germination to the initiation of cell death and senescence programs. This article reviews recent findings for the major catalytic classes, i.e. the serine, cysteine, aspartic, and metalloproteases, emphasizing the regulatory function of representative enzymes.     

A Physical Interaction of UvrD with Nucleotide Excision Repair Protein UvrB

The dual-incision nature of the reaction of UV-irradiated DNA catalyzed by the UvrABC complex potentially leads to excision of a damaged fragment. However, neither fragment release under nondenaturing conditions nor the UvrBC proteins are turned over. The addition of the UvrD protein to the incised DNA-UvrBC complex results in excision of the incised damaged strand and in the turnover of the UvrC protein. In an effort to better understand the involvement of UvrD in the excision step, immunoprecipitation was used to detect interacting proteins with UvrD in the DNA repair. In this communication, it is shown that UvrA and UvrB are precipitated with UvrD in solution but the UvrAB complex is not. In the incision complex, UvrB could be precipitated and the preincubation of UvrD with UvrB revealed an inhibitory effect on the turnover of the incision complex. These data imply that UvrB in the incision complex seems to recruit UvrD to the 3 incised site of the incised strand by protein-protein interaction and to allow initiation of unwinding by UvrD from the resulting nick in a 3 to 5 direction.     

Kinetic analysis of glycation as a tool for assessing the half-life of proteins

Glycation of proteins, a common postribosomal modification, proceeds via Amadori rearrangement to yield a stable ketoamine linkage of glucose with the protein. Kinetic analysis of the reaction shows that the amount of glycation at steady state is proportional to the glucose concentration, to protein half-life and to the rate of glycation. Thus, when the rate of glycation is determined in vitro and the extent of glycation of a given protein isolated from euglycemic subjects is measured, the half-life may be calculated. As the in vivo situation may not be simulated accurately in vitro, the calculated values may be considered as approximation. When the calculated values were compared with values reported in the literature fairly good agreement was found except for hemoglobin. Studies on stability of glycated albumin show that ketoamine decreases by about 20% when incubated under physiological conditions for 20 days. The method described by us is especially valuable when turnover of proteins in normal and pathophysiological states are compared. The half-life of plasma low-density lipoprotein is longer in patients with hypothyroidism or a high plasma low-density lipoprotein level than in normal subjects. Extending our studies to tissue proteins we did not find a significant increase in half-life of tendon collagen with age. Basement membrane collagen turnover is faster in diabetic patients in bad metabolic control. Thus, the procedure using fructosylamine as endogenous label of protein offers a method of great potential to study the turnover of human body proteins.     

Towards the control of intracellular protein turnover: mitochondrial Lon protease inhibitors versus proteasome inhibitors

Cellular protein homeostasis results from the combination of protein biogenesis processes and protein quality control mechanisms, which contribute to the functional state of cells under normal and stress conditions. Proteolysis constitutes the final step by which short-lived, misfolded and damaged intracellular proteins are eliminated. Protein turnover and oxidatively modified protein degradation are mainly achieved by the proteasome in the cytosol and nucleus of eukaryotic cells while several ATP-dependent proteases including the matrix protease Lon take part in the mitochondrial protein degradation. Moreover, Lon protease seems to play a major role in the elimination of oxidatively modified proteins in the mitochondrial matrix. Specific inhibitors are commonly used to assess cellular functions of proteolytic systems as well as to identify their protein substrates. Here, we present and discuss known proteasome and Lon protease inhibitors. To date, very few inhibitors of Lon have been described and no specific inhibitors of this protease are available. The current knowledge on both catalytic mechanisms and inhibitors of these two proteases is first described and attempts to define specific non-peptidic inhibitors of the human Lon protease are presented.