Altered degradation of intracellular proteins in aging human fibroblasts

Modulating Chaperone-Mediated Autophagy and Its Clinical Applications in Cancer

Autophagy is a central mechanism for maintaining cellular homeostasis in health and disease as it provides the critical energy through the breakdown and recycling of cellular components and molecules within lysosomes. One of the three types of autophagy is chaperone-mediated autophagy (CMA), a degradation pathway selective for soluble cytosolic proteins that contain a targeting motif related to KFERQ in their amino acid sequence. This motif marks them as CMA substrate and is, in the initial step of CMA, recognised by the heat shock protein 70 (Hsc70). The protein complex is then targeted to the lysosomal membrane where the interaction with the splice variant A of the lysosomal-associated membrane protein-2 (LAMP-2A) results in its unfolding and translocation into the lysosome for degradation. Altered levels of CMA have been reported in a wide range of pathologies including many cancer types that upregulate CMA as part of the pro-tumorigenic phenotype, while in aging a decline is observed and associated with a decrease of LAMP-2 expression. The potential of altering CMA to modify a physiological or pathological process has been firmly established through genetic manipulation in animals and chemical interference with this pathway. However, its use for therapeutic purposes has remained limited. Compounds used to target and modify CMA have been applied successfully to gain a better understanding of its cellular mechanisms, but they are mostly not specific, also influence other autophagic pathways and are associated with high levels of toxicity. Here, we will focus on the molecular mechanisms involved in CMA regulation as well as on potential ways to intersect them, describe modulators successfully used, their mechanism of action and therapeutic potential. Furthermore, we will discuss the potential benefits and drawbacks of CMA modulation in diseases such as cancer.

Maintenance of Chronological Aging Features in Culture of Normal Human Dermal Fibroblasts from Old Donors

Chronological aging is defined as a time-dependent decline of tissue homeostasis which severely impacts skin. Understanding the mechanisms of skin aging is an active research area limited by the lack of relevant in vitro models. Being a component of aging, replicative or stress-induced senescence is repeatedly used to mimic skin aging in vitro, thus presenting only a partial view of the complexity of aging. Herein, we aimed to clarify whether primary normal human dermal fibroblasts retained age-related characteristics when cultured in 2D monolayer, and could be used as a relevant model for aging research. We compared three groups of fibroblasts isolated from different aged donors. We observed strongly decreased population doubling capacities, a reduced clonogenic ability, an impairment in extracellular matrix production together with modifications of respiratory metabolism with an increase in age. These disruptions were particularly marked when comparing fibroblasts isolated from old individuals (over 70 years old) to those isolated from young individuals (18–37 years old), while cells from middle-aged donors exhibited an intermediate profile. These alterations of cell features can be related to the signs of dermis aging, thus showing that cultured primary cells indeed retain some characteristics of the original tissue from which they were extracted.

Influence of Normal Aging on Brain Autophagy: A Complex Scenario

Misfolded proteins are pathological findings in some chronic neurodegenerative disorders including Alzheimer's, Parkinson's, and Huntington's diseases. Aging is a major risk factor for these disorders, suggesting that the mechanisms responsible for clearing misfolded proteins from the brain, the ubiquitin-proteasome system and the autophagy-lysosomal pathway, may decline with age. Although autophagic mechanisms have been found to decrease with age in many experimental models, whether they do so in the brain is unclear. This review examines the literature with regard to age-associated changes in macroautophagy and chaperone-mediated autophagy (CMA) in the central nervous system (CNS). Beclin 1, LC3-II, and the LC3-II/LC3-I ratio have frequently been used to examine changes in macroautophagic activity, while lamp2a and HSPA8 (also known as hsc70) have been used to measure CMA activity. Three gene expression analyses found evidence for an age-related downregulation of macroautophagy in human brain, but no published studies were found of age-related changes in CMA in human brain, although cerebrospinal fluid concentrations of HSPA8 were reported to decrease with age. Most studies of age-related changes in brain autophagy in experimental animals have found age-related declines in macroautophagy, and macroautophagy is necessary for normal lifespan in Caenorhabditis elegans, Drosophila, and mice. However, the few studies of age-related changes in brain CMA in experimental animals have produced conflicting results. Investigations of the influence of aging on macroautophagy in experimental animals in systems other than the CNS have generally found an age-related decrease in Beclin 1, but conflicting results for LC3-II and the LC3-II/LC3-I ratio, while CMA decreases with age in most models. CONCLUSION: while indirect evidence suggests that brain autophagy may decrease with normal aging, this issue has not been investigated sufficiently, particularly in human brain. Measuring autophagic activity in the brain can be challenging because of differences in basal autophagic activity between experimental models, and the inability to include lysosomal inhibitors when measuring the LC3-II/LC3-I ratio in postmortem specimens. If autophagy does decrease in the brain with aging, then pharmacological interventions and/or lifestyle alterations to slow this decline could reduce the risk of developing age-related neurodegenerative disorders.

Integrating cellular senescence with the concept of damage accumulation in aging: Relevance for clearance of senescent cells

Understanding the aging process and ways to manipulate it is of major importance for biology and medicine. Among the many aging theories advanced over the years, the concept most consistent with experimental evidence posits the buildup of numerous forms of molecular damage as a foundation of the aging process. Here, we discuss that this concept integrates well with recent findings on cellular senescence, offering a novel view on the role of senescence in aging and age‐related disease. Cellular senescence has a well‐established role in cellular aging, but its impact on the rate of organismal aging is less defined. One of the most prominent features of cellular senescence is its association with macromolecular damage. The relationship between cell senescence and damage concerns both damage as a molecular signal of senescence induction and accelerated accumulation of damage in senescent cells. We describe the origin, regulatory mechanisms, and relevance of various damage forms in senescent cells. This view on senescent cells as carriers and inducers of damage puts new light on senescence, considering it as a significant contributor to the rise in organismal damage. Applying these ideas, we critically examine current evidence for a role of cellular senescence in aging and age‐related diseases. We also discuss the differential impact of longevity interventions on senescence burden and other types of age‐related damage. Finally, we propose a model on the role of aging‐related damage accumulation and the rate of aging observed upon senescent cell clearance.

Chaperone mediated autophagy in aging: Starve to prosper

The major lysosomal proteolytic pathways essential for maintaining proper cellular homeostasis are macroautophagy, chaperone-mediated autophagy (CMA) and microautophagy. What differentiates CMA from the other types of autophagy is the fact that it does not involve vesicle formation; the unique feature of this pathway is the selective targeting of substrate proteins containing a CMA-targeting motif and the direct translocation into the lysosomal lumen, through the aid of chaperones/co-chaperones localized both at the cytosol and the lysosomes. CMA operates at basal conditions in most mammalian cell models analyzed so far, but it is mostly activated in response to stressors, such as trophic deprivation or oxidative stress. The activity of CMA has been shown to decline with age and such decline, correlating with accumulation of damaged/oxidized/aggregated proteins, may contribute to tissue dysfunction and, possibly, neurodegeneration. Herein, we review the recent knowledge regarding the molecular components, regulation and physiology of the CMA pathway, the contribution of impaired CMA activity to poor cellular homeostasis and inefficient response to stress during aging, and discuss the therapeutic opportunities offered by the restoration of CMA-dependent proteolysis in age-associated degenerative diseases.

Autophagy and aging: keeping that old broom working

Autophagy, a highly conserved mechanism of quality control inside cells, is essential for the maintenance of cellular homeostasis and for the orchestration of an efficient cellular response to stress. The decrease in autophagic activity observed in almost all cells and tissues as organisms age was proposed to contribute to different aspects of the aging phenotype and to the aggravation of detrimental age-related diseases. The recent advances in our understanding of the molecular mechanisms underlying autophagy and the identification of the subset of genes involved in this process has enabled the use of genetic manipulations to start testing this hypothesis. Here, I review the recent genetic evidence in support of tight connections between autophagy, health span and aging.

Age-related changes in barrier function in mouse brain I. Accelerated age-related increase of brain transfer of serum albumin in accelerated senescence prone SAM-P/8 mice with deficits in learning and memory

The time course of brain accumulation of radiolabelled human serum albumin ((125)I-HSA) injected intravenously and the transfer of (125)I-HSA from blood to brain were evaluated in DDD mice using a double isotope technique. The brain accumulation of (125)I-HSA at 3 and 9 h but not at 24 h postinjection and the brain transfer rates were significantly higher in 22-month-old DDD mice than in 4-month-old ones. The brain transfer rates of (125)I-HSA were measured also in senescence accelerated prone mice (SAM-P/8) with age-related deficits in learning and memory, and in senescence accelerated resistant mice (SAM-R/I) without these deficits. The brain transfer rates were significantly higher in 13-month-old SAM-P/8 and 22-month-old SAM-R/1 than in 3-month-old mice of the same strains, respectively. The mean brain transfer rates in five regions observed in 22-month-old DDD mice, 22-month-old SAM-R/1 and 13-month-old SAM-P/8 increased by 31%, 41% and 51% compared with corresponding values in 3- or 4-month-old mice of the same strains. DDD mice and SAM-R/1 mice with normal characteristics of aging showed similar age-related significant changes in brain transfer rates. Age-related increase in the brain transfer rate was manifested at the youngest age in SAM-P/8 among the three strains examined. These findings show that the transfer of human serum albumin into the mouse brain increases with aging and suggest that the barrier function in the mouse brain against macromolecules changes with aging.

Age-related decline in chaperone-mediated autophagy

Intracellular protein degradation rates decrease with age in many tissues and organs. In cultured cells, chaperone-mediated autophagy, which is responsible for the selective degradation of cytosolic proteins in lysosomes, decreases with age. In this work we use lysosomes isolated from rat liver to analyze age-related changes in the levels and activities of the main components of chaperone-mediated autophagy. Lysosomes from "old" (22-month-old) rats show lower rates of chaperone-mediated autophagy, and both substrate binding to the lysosomal membrane and transport into lysosomes decline with age. A progressive age-related decrease in the levels of the lysosome-associated membrane protein type 2a that acts as a receptor for chaperone-mediated autophagy was responsible for decreased substrate binding in lysosomes from old rats as well as from late passage human fibroblasts. The cytosolic levels and activity of the 73-kDa heat-shock cognate protein required for substrate targeting to lysosomes were unchanged with age. The levels of lysosome-associated hsc73 were increased only in the oldest rats. This increase may be an attempt to compensate for reduced activity of the pathway with age.

Oxidative DNA damage and senescence of human diploid fibroblast cells

Human diploid fibroblast cells cease growth in culture after a finite number of population doublings. To address the cause of growth cessation in senescent IMR-90 human fibroblast cells, we determined the level of oxidative DNA damage by using 8-oxoguanine excised from DNA and 8-oxo-2'-deoxyguanosine in DNA as markers. Senescent cells excise from DNA four times more 8-oxoguanine per day than do early-passage young cells. The steady-state level of 8-oxo-2'-deoxyguanosine in DNA is approximately 35% higher in senescent cells than in young cells. Measurement of protein carbonyls shows that senescent cells did not appear to have elevated protein oxidation. To reduce the level of oxidative damage, we cultured cells under a more physiological O2 concentration (3%) and compared the replicative life span to the cells cultured at the O2 concentration of air (20%). We found that cells grown under 3% O2 achieved 50% more population doublings during their lifetime. Such an extension of life span resulted from the delayed onset of senescence and elevation of growth rate and saturation density of cells at all passages. The spin-trapping agent alpha-phenyl-t-butyl nitrone (PBN), which can act as an antioxidant, also effectively delayed senescence and rejuvenated near senescent cells. The effect is dose-dependent and is most pronounced for cells at the stage just before entry into senescence. Our data support the hypothesis that oxidative DNA damage contributes to replicative cessation in human diploid fibroblast cells.

Involvement of protein kinase C and arachidonate signaling pathways in the alteration of proliferative response of senescent IMR-90 human fibroblasts

The proliferative response of IMR-90 fibroblasts at low and high population doubling level (PDL) to protein kinase C activation has been investigated to clarify whether the reduced mitogenic responsiveness of senescent cells can be ascribed to an alteration in protein kinase C signal transduction pathway. The results show that the signaling pathway leading to DNA synthesis through protein kinase C activation, appears to be modified in senescent IMR-90 human fibroblasts. High PDL fibroblasts exhibit a different sensitivity to phorbol 12-myristate 13-acetate (PMA) and dioctanoylglycerol (diC8); high glucose reduced responsiveness to PMA only in these cells. In addition, high PDL fibroblasts are characterized by an increase in diacylglycerol (DAG) cellular mass that could contribute to the different regulatory properties of the signaling pathway. On the other hand, the ability of the cyclooxygenase inhibitor indomethacin to strikingly improve the proliferative response of high PDL cells to PMA indicates that an altered overall metabolism of arachidonate may represent a crucial step in the reduced mitogenic response involving protein kinase C activation.

Senescence-like growth arrest induced by hydrogen peroxide in human diploid fibroblast F65 cells

Human diploid fibroblast cells lose replicative potential after a certain number of population doublings. We use this experimental system to investigate the role of oxidative damage in cellular aging. Treating cells with H2O2 at < 300 microM did not affect the viability of the majority of cells when judged by morphology, trypan blue exclusion, and protein synthesis. However, the treatment caused a dose-dependent inhibition of DNA synthesis. After a 2-hr treatment with 200 microM H2O2, the cells failed to respond to a stimulus of serum, platelet-derived growth factor, basic fibroblast growth factor, or epidermal growth factor by synthesizing DNA, and the loss of response could not be recovered by 4 days. Subcultivation showed that, as in senescent cells, division of the treated cells was inhibited. The life-time cumulative growth curve showed that the loss of replication due to H2O2 treatment was cumulative and irreversible. The H2O2 treatment decreased the number of the population doublings in the rest of the life span by 35.3 +/- 10.3%. Enzymatic assays indicated that, like the cells in their senescent state, the treated cells were less able to activate ornithine decarboxylase and thymidine kinase. Furthermore, subcultivation after the H2O2 treatment showed that the cells developed the morphology of senescent cells. In conclusion, sublethal treatment of H2O2 "stunned" F65 cells and caused the cells to enter a state resembling senescence.

Ubiquitin pools, ubiquitin mRNA levels, and ubiquitin-mediated proteolysis in aging human fibroblasts

Senescent cells have less free ubiquitin and more ubiquitin-protein conjugates than do young cells. The ubiquitin-protein conjugates are heterogeneous in size but contain prominent bands at 106, 55, and 22 kDa. The age-related increase in ubiquitin-protein conjugates applies primarily to the 55-kDa band, while the 106-kDa and 22-kDa conjugates change little with age. Ubiquitin mRNA levels do not change with age, and the ability of cells to degrade two proteins that are good substrates for ubiquitin-mediated proteolysis is unaltered by aging. These results indicate that an increase in ubiquitin-protein conjugates does not necessarily reflect alterations in ubiquitin-mediated proteolysis. Furthermore, an overactive pathway of ubiquitin-mediated proteolysis does not appear to contribute to the proliferative arrest in senescent cells.

Metallothionein expression and stress responses in aging human diploid fibroblasts

Metallothioneins (MTs) are low molecular weight proteins with a high cysteine content that are inducible by heavy metals and by other conditions of environmental stress. This laboratory was investigated in human diploid fibroblasts the induction of MTs by cadmium and by dexamethasone, and the induction of heat shock proteins, as models for age-related changes in gene expression that reflect the ability of old cells to respond to environmental stress. Old cells were more sensitive to the toxic effects of CdCl2 in the concentration range 100-175 microM. Analysis of 35S-cysteine-labelled cell extracts by polyacrylamide gel electrophoresis and fluorography showed that in the absence of any inducer, old cells have a 3.7-fold increase over young cells in the basal level of MT. The rate and extent of induction of MT by CdCl2 was reduced in old cells: Exposure of old cells to 100 microM CdCl2 for 18 h resulted in MT levels about 33% of the amount in young cells. Northern blot analysis showed that the changes in MT protein levels occurred in parallel with changes in mRNA levels, which implicates transcriptional control as the origin of these aging changes. These young/old differences in MT synthesis were maintained in density-arrested cultures, indicating that the aging changes were not due to differences in the cell cycle status of these cell populations. The rate and extent of induction of a 68-kDa heat shock protein were also reduced in old cells, which showed an increase in basal, uninduced level of this protein similar to MT. In contrast, old cells retained the ability to synthesize MTs in response to dexamethasone at a rate similar to that in young cells.

Effects of aging in vitro on intracellular proteolysis in cultured rabbit lens epithelial cells in the presence and absence of serum

Alterations in proteolytic capabilities have been associated with abnormalities in the aged eye lens, but in vivo tests of this hypothesis have been difficult to pursue. To simulate aging, we cultured cells from an 8-yr-old rabbit to early (population-doubling level 20 to 30) and late (population-doubling level greater than 125) passage. Long-lived (t1/2 greater than 10 h) and short-lived (t1/2 less than 10 h) intracellular proteins were labeled with [3H]leucine, and the ability of the cells to mount a proteolytic response to the stress of serum withdrawal was determined. For early passage cells, the average t1/2 of long-lived proteins in the presence and absence of serum was 62 and 39 h, respectively. For late-passage cells, the average t1/2 of long-lived proteins in the presence and absence of serum was 58 and 43 h, respectively. The net increase in intracellular proteolysis in the absence of serum was 59 and 35% for early and late-passage cells, respectively. Thus, in vitro-aged rabbit lens epithelial cells amount only 60% the proteolytic response to serum removal shown in "younger" cells. The enhanced ability of early passage cells to respond to serum removal seems to involve lower homeostatic levels of proteolysis in the presence of serum and greater enhancement of proteolysis in the absence of serum. Less than 2% of the protein is in the pool of short-lived proteins. Rates of proteolysis of short-lived proteins in the presence and absence of serum were indistinguishable. With respect to basal proteolytic rates in the presence of serum and ability to mount a proteolytic response upon serum withdrawal, these rabbit lens epithelial cells are similar to bovine lens epithelial cells and fibroblasts.

Isoforms of chicken triosephosphate isomerase are due to specific oxidation of cysteine126

The electrophoretic isoforms of mammalian triosephosphate isomerase (TPI; EC 5.3.1.1) are due to deamidation at two Asn-Gly sites (Asn15 and Asn71). Deamidation of these two asparagines in the subunit-subunit interface of the isologous dimer appears to destabilize the dimer and initiate degradation of the protein. Chicken TPI contains a lysine substitution for Asn71, thus precluding this deamidation site. Nevertheless, the chicken enzyme exhibits three electrophoretic isoforms. This multiplicity is not the result of deamidation of the remaining Asn15 site, but due to a specific site which is highly susceptible to oxidation. The three isoforms of chicken TPI can be reduced to a single form in the presence of high concentrations of reducing agents (e.g., greater than 15 mM dithiothreitol or greater than 50 mM 2-mercaptoethanol) and are also generated when oxidizing agents, such as oxidized glutathione, are present. The oxidized isoforms exhibit lowered catalytic activity and are more susceptible to denaturation and proteolytic degradation than the native enzyme. Structural analysis of the isoforms by chemical cleavage at the cysteine peptide bonds with 2-nitro-5-thiocyanobenzoic acid and subsequently at the methionines with CNBr followed by peptide sequencing reveals that Cys126 is the site of the modification. Since the oxidized isoforms of chicken TPI accumulate in vivo during aging analogous to the deamidated isoforms from mammals, it appears that TPI is the first example of a protein which has evolved two specific types of weak links which may initiate turnover of the protein.

Protein Turnover During Aging of Cultured Human Fibroblasts

Les cellules qui vieillissentin vitroou bien celles qui sont prélevées de donneurs d'àge avancé ou de sujets manifestant certaines des particularités qui s'apparentent à un vieillissement accéléré (progérie ou le syndrome de Werner), peuvent être qualifiées de 'vieilles'. Celles-ci on des taux de croissance ralentis en milieu de culture si on les compare aux cellules nouvelles ou à mi-passage prélevées de jeunes donneurs normaux. Durant la croissance exponentielle, les taux de constantes pour la synthèse protéique dans les jeunes cellules ne sont pas significativement différents de ceux retrouvés dans les vieilles cellules (0.023 ± 0.002h1vs. 0.021 ± 0.002h1respectivement) et pourtant les taux de croissance (i.e. accrétion protéique) sont de seulement 0.013±0.003h1dans les vieilles cellules comparés à 0.022±0.002h1dans les jeunes cellules. Done, le taux ralenti d'accumulation protéique durant la croissance des vieilles cellules comparé aux jeunes cellules est associé à une dégradation protéique accélérée (0.01±0.002h1vs 0.001 ±0.002h1;P<0.05) plutôt qu'à des taux ralentis de synthèse protéique. Lorsque les cellules deviennent quiescentes suivant une période d'inhibition de croissance due à la densité, les taux de synthèse protéique diminuent dans les jeunes et les vieilles cellules pour aboutir à des niveaux comparables (0.013±0.002h1) où les taux de croissance (0.003±0.0003h1) et de dégradation (0.01±0.003h1) ne sont significativement pas differents dans les deux groupes. Done, ce n'est qu'en période de croissance exponentielle qu'une différence dans le turn-over protéique entre jeunes et vieilles cellules est observée, alors que la dégradation est accélérée dans les vieilles cellules. La relation causale entre la dégradation protéique accélérée et les taux de croissance ralentis dans les vieilles cellules demeure inconnue.

Differential degradation of intracellular proteins in human skin fibroblasts of mitotic and mitomycin-C (MMC)-induced postmitotic differentiation states in vitro

Rates of degradation of short- and long-lived proteins were analysed in homogeneous fibroblast cultures of mitotic or mitomycin C (MMC)-induced postmitotic states. When the highly mitotic MFII type cells--the major cell type of so called "early passage" or "young" fibroblasts--differentiate into MFIII type cells, the last mitotic fibroblast type, and further into MMC-induced postmitotic fibroblasts, the degradation of short-lived proteins increases by a factor of 1.4, resulting in significantly reduced half-lives of these proteins in the postmitotic fibroblasts. From the highly mitotic MFII to the final postmitotic PMFVI-type cells via the intermediates MFIII, PMFIV and PMFV, the half lives (t1/2) of short-lived proteins decrease by a total of 122 min in average, from 362 to 240 min. Degradation of long-lived proteins did not change significantly from cell type MFII to PMFVI. As analysed by two-dimensional (2D)-gel electrophoresis the half-lives of the mitotic and postmitotic cell-type-specific proteins except one, protein PIVa (33 kDa; Pi 5.0), range between 33.2 h and 62.9 h. Protein PIVa, the first protein specific for postmitotic cells, is initially expressed 18 h after the induction of the postmitotic state by mitomycin C (MMC) and has a half-life of approximately 66 min. This may indicate that protein PIVa could function as one possible regulatory factor controlling the postmitotic differentiation state.

Altered intracellular protein degradation in aging: a possible cause of proliferative arrest

Many proteins that control cell-cycle progression are short-lived. Therefore, alterations in protein degradation are as likely as changes in transcription and/or translation in causing the proliferation arrest of senescent cells. Several different pathways of intracellular protein degradation have been identified, and both cytosolic and lysosomal pathways operate in most cells. We have used red cell-mediated microinjection to study degradation of radiolabelled proteins introduced into IMR-90 human diploid fibroblasts at early and late population doubling levels. Lysosomal pathways of protein degradation are reduced in senescent cells, and this defect may account for many characteristics of aging, including the accumulation of posttranslationally altered proteins. These abnormal proteins may then stimulate cytosolic, ubiquitin-dependent proteolytic pathways that are also responsible for the degradation of crucial regulatory proteins. Unknown short-lived proteins are also required for some step in lysosomal proteolysis, and this connection between the two degradative systems may cause the age-related changes in protein degradation to be progressive. Several experimental approaches are available to test whether altered protein degradation significantly contributes to proliferative arrest of senescent cells.

Decreased accuracy of protein synthesis in extracts from aging human diploid fibroblasts

The accuracy of protein synthesis has been measured in extracts from human diploid fibroblasts of different ages. Extracts were supplied with purified mRNA for the coat protein of the cowpea variant of tobacco mosaic virus (CcTMV), which lacks codons for cysteine and methionine. The presence of 35S-cysteine in CcTMV coat protein synthesized during translation reactions therefore represents translational error. Translation reactions were performed with extracts from young fibroblasts (less than 50% of life span completed) and old fibroblasts (more than 90% of life span completed), and the translation products were purified by immunoprecipitation and analyzed by polyacrylamide gel electrophoresis. The error frequency increased from 4.2 x 10(-5) cysteines/amino acid in young cell extracts to 2.9 x 10(-4) cysteines/amino acid in old cell extracts. Cysteine incorporation was not due to nonspecific binding, and could be increased approximately sixfold by the addition of the misreading antibiotic, paromomycin. It is concluded that translational accuracy is not stable during aging in vitro, and it is proposed that this decrease in the fidelity of information transfer could be responsible for the variety of changes observed in aging cultured human cells.

Intracellular protein degradation in cultured bovine lens epithelial cells

Although several proteases have been identified in homogenates of cultured epithelial cells of the eye lens and in lens tissues, there is little information regarding intracellular protein degradation in intact lens cells in vitro. Cultured lens cells may be useful in the study of intracellular protein degradation in the lens, a tissue with a wide range of protein half-lives. This is of interest because alterations in protein turnover in the lens have been implicated in cataract formation. This study examines intracellular protein degradation in cultured bovine lens epithelial cells (BLEC). Cell cultures were incubated with radiolabeled leucine to label intracellular proteins. Protein degradation was measured by monitoring the release of trichloroacetic-acid-soluble radioactivity into the culture medium. The average half-life of long-lived proteins (half-life greater than 50 h) was typically about 57 h in serum-supplemented medium. Average rates of degradation of long-lived proteins increased by up to 73% when fetal bovine serum was withdrawn from the culture medium. Serum had no effect on the degradation of short-lived proteins (half-life less than 10 h). Degradation of long-lived proteins in the presence and absence of serum was further studied in cultured BLEC from population doubling level (PDL) 2 to 43. Average half-life of proteins in serum-supplemented medium was 52 to 58 h and did not vary significantly as a function of PDL. Degradation rates in serum-free medium increased approximately twofold up to PDL 7, but returned by PDL 25 to original levels, which were maintained through PDL 43.

Protease activities in cultured beef lens epithelial cells peak and then decline upon progressive passage

Beef lens cells in culture are readily obtained and provide many opportunities to study phenomena related to cell differentiation and maturation, environmental stress, disease, and perhaps mechanisms of transformation. Although altered rates of proteolysis are known to accompany these phenomena, the proteolytic activities available in cultured beef lens epithelial cells have not been documented. In this work are documented the specific activities, based on protein and DNA content, of neutral exo- and endopeptidase, cathepsins B- and D-like enzymes and acid phosphatase in lens epithelial cortical and core tissue and in cultured epithelial cells at passages 1-43. Maximal activity of each protease occurs almost routinely at passage 5 or 9, reaching values of approx. 1400-, 0.77-, 4520-nmol min-1 per mg protein for neutral exopeptidase (passage 5), neutral endopeptidase (passage 5) and cathepsin B (passage 5) respectively, and 7.1 micrograms trichloroacetic acid soluble peptide min-1 per mg protein for cathepsin D (passage 15). On a microgram-1 DNA basis, the maximal specific activities for the same enzymes were 48 (passage 5), 0.03 (passage 5), 283 (passage 9), and 0.5 (passage 9) respectively. In subsequent passages, the specific activities declined to values which were similar to or lower than the specific activities observed for these proteases in lens epithelial tissue.

Accumulation of a high molecular weight glycoprotein during in vitro ageing and contact inhibition of growth

A 240 000 molecular weight protein was found to accumulate in sorted autofluorescent (AF) cells, and during growth inhibition and in vitro ageing of cultures of human skin fibroblasts. Vitamin E, a lipophilic free radical scavenger which suppressed completely the formation of cellular autofluorescence, did not affect the accumulation of this protein. So, this accumulation is not related to cellular autofluorescence and lipid peroxidation, the major cause of this autofluorescence. This protein was also found in cells from a patient with the Spielmeyer-Vogt syndrome with a high percentage of maximal lifespan (MLS), while it was completely absent from all cells of a patient with Werner's syndrome. On two-dimensional gel electrophoresis the protein showed a heterogeneous acidic isoelectric point (IEP) of around 5.3. Neuraminidase treatment caused the IEP of this protein to shift towards a less acidic pH value (5.85). Upon differential centrifugation of a cell homogenate the protein was found to be located in the microsomal pellet and the cytosol. Chromatography on gelatin-sepharose revealed that the protein was not fibronectin. It is concluded that in human skin fibroblasts a high molecular weight glycoprotein accumulates as a result of impaired proliferation and that this accumulation is not related to cellular lipid peroxidation.

Degradation of peptides and proteins of different sizes by homogenates of human MRC5 lung fibroblasts. Aged cells have a decreased ability to degrade shortened proteins

The degradation of haemoglobin and haemoglobin-derived peptide fragments by homogenates of MRC5 fibroblasts has been investigated. Results show that the smaller fragments were degraded more rapidly than larger substrates at both pH 5.5 and pH 7.5. Only the smallest of the soluble cyanogen bromide peptides (Mr 3500) was degraded at pH 7.5. Degradation at pH 5.5 proceeded more rapidly than that at pH 7.5 for all substrates tested but was more marked with the larger substrates. Homogenates prepared from aged cells degraded puromycin peptides and, to a lesser extent, cyanogen bromide peptides at a slower rate, at pH 7.5, than those prepared from younger cells. We suggest that cytosolic degradation is less selective and at least one cytosolic proteolytic activity decreases as cells age.

Cellular theories of aging as related to the liver

The age-associated decline in function of several organs, including the liver, may be caused by mechanisms operating on the cellular level. Fibroblasts and several other cell types derived from normal individuals have limited lifespans in culture, and several abnormalities described for senescent cultured fibroblasts also apply to hepatocytes and other cell types obtained from aged organisms. Cellular theories of aging can be divided into two broad and overlapping categories: (a) those that view cell death as an actively programmed developmental process, and (b) those that consider cellular aging to result from a passive accumulation of errors in macromolecules. These theories are not necessarily mutually exclusive, and many of the phenotypic changes in senescent hepatocytes, fibroblasts and other cells are compatible with several different theories. The challenge for the future is to distinguish primary causes from secondary consequences of cellular aging so that rational attempts to intervene in the aging process are possible.