Properties of antithrombin-thrombin complex formed in the presence and in the absence of heparin.

Protein degradation by diploid human-embryo lung fibroblasts (MRC5 cells) in monolayer culture was studied. 1. Varying the labelling period of proteins was found to alter the half-lives of labelled abnormal canavanine-containing proteins to an extent very similar to that obtained with normal proteins. 2. By manipulating the times of labelling it was possible to generate a species of abnormal protein with a greater half-life than that of a species of normal protein. A comparison of the lysosomal involvement in their degradation as determined both by inhibition by methylamine, a lysosomotropic agent, and by the degree of increase in protein degradation in step-down conditions, indicated that the degree of lysosomal involvement was not entirely dependent upon the half-life of the protein, but that abnormal proteins are preferentially degraded non-lysosomally. 3. The microtubule inhibitors colchicine and vinblastine were found to stimulate statistically basal protein degradation of normal long-labelled protein, whereas they had less effect upon the basal degradation of the other species of proteins studied and very little effect upon step-down degradation of all proteins studied. The stimulation in protein degradation found did not seem to involve the acid proteinases of lysosomes.     

Collagen degradation in I-cells is normal

There is evidence that lysosomal proteases mediate the intracellular degradation of structurally abnormal collagen. I-Cell disease (Mucolipidosis II) is characterized by marked deficiency of many lysosomal hydrolases, including the collagenolytic enzyme cathepsin B. The experiments reported here tested the hypothesis that degradation of abnormal collagen would be severely impaired in I-cells. Skin fibroblasts from 3 patients with I-cell disease were incubated with and without cis-hydroxyproline, a proline analog that causes structural abnormalities in collagen, and [14C]proline. The amount of [14C]hydroxyproline in a low molecular weight fraction relative to total [14C]hydroxyproline was used as a measure of intracellular collagen degradation. Levels of degradation were significantly higher in I-cells exposed to cis-hydroxyproline than in cells incubated without the analog. Similar data were obtained for normal human fetal lung fibroblasts incubated under the same conditions. Degradation of [125I]-epidermal growth factor was used to assess the functionality of the lysosomal pathway for protein degradation, and it was much lower in I-cells than in normal cells. It can be concluded that a completely functional complement of lysosomal enzymes is not necessary for structurally abnormal collagen to be degraded intracellularly; the data suggest that a nonlysosomal pathway exists.     

Quality control of protein folding in extracellular space

The pathologies of many serious human diseases are thought to develop from the effects of intra- or extracellular aggregates of non-native proteins. Inside cells, chaperone and protease systems regulate protein folding; however, little is known about any corresponding mechanisms that operate extracellularly. The identification of these mechanisms is important for the development of new disease therapies. This review briefly discusses the consequences of protein misfolding, the intracellular mechanisms that control folding and the potential corresponding extracellular control processes. Finally, a new speculative model is described, which proposes that newly discovered extracellular chaperones bind to exposed regions of hydrophobicity on non-native, extracellular proteins to target them for receptor-mediated endocytosis and intracellular, lysosomal degradation.     

细胞自噬及真菌中自噬研究概述

细胞自噬是真核生物中广泛存在的、主要依赖于溶酶体或液泡的保守的降解途径,通过降解细胞内过多或异常的蛋白、细胞器等以维持正常的细胞功能。近10年来自噬研究方面的飞速进展显示出自噬与癌症、神经退行性疾病、衰老及心脏病等人类疾病相关。与此同时,自噬在丝状真菌的生长、形态和发育等方面发挥着重要作用,特别是在丝状真菌的细胞分化过程中,自噬起到了关键性作用,如致病性生长、程序性细胞死亡及孢子形成。本文主要论述了什么是自噬,自噬的检测方法及以真菌为对象的自噬研究进展。     

Temperature and induction effects on the degradation rate of an abnormal beta-galactosidase in Escherichia coli.

Intracellular protein degradation was investigated using an unstable fragment of Escherichia coli beta-galactosidase, the CSH11 mutant, as a model protein. This abnormal protein was expressed from a single copy gene in the chromosome and is converted to a detectable degradable intermediate. The in vivo degradation rates of both beta-galactosidase fragments were measured using pulse-chase radioactive labeling techniques, and their intracellular concentrations were determined using alpha-complementation assays. In the physiological range of 30 to 37 degrees C, the apparent degradation rate constant for the CSH11 fragment follows Arrhenius behavior; while the intermediate's apparent degradation rate constant is nearly unchanged. However, above 37 degrees C the degradation rates of both fragments increase significantly. Analysis of the labeled intermediate's rate of change above 40 degrees C reveals that the CSH11 fragment is being degraded by a second pathway which does not produce the intermediate. When the induction level of the abnormal beta-galactosidase was varied the degradation rates of both fragments behaved similarly, but they unexpectedly decreased with increasing IPTG concentration. The two parallel degradation pathways for CSH11 apparently operated at only the lower IPTG levels. The measured degradation rates did not correlate directly with the intracellular concentration of abnormal proteins.     

Endocytosis of liposomes containing lysosomal proteins increases intracellular protein degradation in growing L-132 cells

We have used a new approach to test the possible participation of lysosomes in the degradation of long-lived proteins. Rat liver lysosomal proteins were introduced, via multilamellar liposomes, into L-132 cells. Viability and protein synthesis were not impaired by this treatment. The liposomal content was released into the lysosomes of the cultured cells, as revealed by ferritin uptake and electron microscopy. Degradation rates of long-lived proteins increased with the uptake of lysosomal proteases. However, the increased protein degradation of chloroquine and leupeptin, in contrast to the inhibition by these reagents of the increased protein degradation of cells 'starved' of serum (step-down conditions). This approach opens a new way of investigating the degradation of intracellular proteins in cultured cells.     

Nanotools for megaproblems: probing protein misfolding diseases using nanomedicine modus operandi

Misfolding and self-assembly of proteins in nanoaggregates of different sizes and morphologies (nanoensembles, primary nanofilaments, nanorings, filaments, protofibrils, fibrils, etc.) is a common theme unifying a number of human pathologies termed protein misfolding diseases. Recent studies highlight increasing recognition of the public health importance of protein misfolding diseases, including various neurodegenerative disorders and amyloidoses. It is understood now that the first essential elements in the vast majority of neurodegenerative processes are misfolded and aggregated proteins. Altogether, the accumulation of abnormal protein nanoensembles exerts toxicity by disrupting intracellular transport, overwhelming protein degradation pathways, and/or disturbing vital cell functions. In addition, the formation of inclusion bodies is known to represent a major problem in the production of recombinant therapeutic proteins. Formulation of these therapeutic proteins into delivery systems and their in vivo delivery are often complicated by protein association. Thus, protein folding abnormalities and subsequent events underlie a multitude of human pathologies and difficulties with protein therapeutic applications. The field of medicine therefore can be greatly advanced by establishing a fundamental understanding of key factors leading to misfolding and self-assembly responsible for various protein folding pathologies. This article overviews protein misfolding diseases and outlines some novel and advanced nanotechnologies, including nanoimaging techniques, nanotoolboxes and nanocontainers, complemented by appropriate ensemble techniques, all focused on the ultimate goal to establish etiology and to diagnose, prevent, and cure these devastating disorders.     

Lysosomes and protein degradation

Evidence from studies on mouse peritoneal macrophages using the inhibitor pepstatin confirms lysosomal involvement in basal protein degradation, and extends its relevance to degradation of long half-life and analogue containing proteins. Studies on the ability of MRC-5 (a limited life-span fibroblast line) cells to selectively degrade analogue-containing proteins are described. These indicate that this capacity is retained even in very old cells; indeed such cells show an increased proportion of rapidly-degradable proteins. Analogue containing proteins bind preferentially to lysosomal membranes, and like liver cytosol proteins of short half-life, are selectively endocytosed and degraded by certain cells in culture. Thus membrane binding allowing selective entry to the lysosomal system may be important in controlling rate of degradation of both intracellular and extracellular protein. A method potentially allowing for determination of the rate of autophagy in cells, is described. This should enable further assessment of the quantitative involvement of lysosomes in protein degradation.     

Protein kinase C-dependent inhibition of the lysosomal degradation of endocytosed proteins in rat hepatocytes

We studied the role of protein kinase C (PKC) in the lysosomal processing of endocytosed proteins in isolated rat hepatocytes. We used [14C]sucrose-labeled horseradish peroxidase ([14C]S-HRP) to simultaneously evaluate endocytosis and lysosomal proteolysis. The PKC activator phorbol 12-myristate 13-acetate (PMA) inhibited the lysosomal degradation of [14C]S-HRP (1 microM PMA: 40% inhibition, P<.05), without affecting either the endocytic uptake or the delivery to lysosomes. However, PMA was not able to affect the lysosomal processing of the beta-galactosidase substrate dextran galactosyl umbelliferone. The PKC inhibitors, chelerytrine (Che), staurosporine (St) and G? 6976, prevented PMA inhibitory effect on lysosomal proteolysis. Nevertheless, purified PKC failed to alter proteolysis in [14C]S-HRP-loaded isolated lysosomes, suggesting that intracellular intermediates are required. PMA induced phosphorylation and hepatocyte membrane-to-lysosome redistribution of the myristoylated alanine-rich C kinase substrate (MARCKS) protein, raising the possibility that MARCKS mediates the PKC-induced inhibition of lysosomal proteolysis.     

Red blood cells contain a pathway for the degradation of oxidant-damaged hemoglobin that does not require ATP or ubiquitin

It is generally accepted that ATP is required for intracellular protein breakdown. Reticulocytes contain a soluble ATP-dependent pathway for the degradation of highly abnormal proteins and for the elimination of certain proteins during cell maturation. Reticulocytes and erythrocytes also selectively degrade proteins damaged by oxidation. When these cells were exposed to oxidants, such as phenylhydrazine or nitrite, they showed a large increase in protein breakdown. This oxidant-induced proteolysis was not inhibited in cells depleted of ATP. However, ATP depletion did prevent the degradation of pre-existent cell proteins. In reticulocyte extracts, phenylhydrazine-treated hemoglobin is also degraded rapidly by an ATP-independent process, unlike endogenous proteins and many exogenous polypeptides. This lack of an ATP requirement means that the degradation of oxidant-damaged proteins does not require ligation to ubiquitin (even though phenylhydrazine treatment does make hemoglobin a very good substrate for ubiquitin conjugation). In many respects, the pathway for breakdown of oxidant-treated hemoglobin differs from the ATP-dependent process. The latter has a much higher activation energy than the degradation of oxidized proteins. The ATP-dependent process is inhibited by hemin, 3,4-dichloroisocoumarin, diisopropylfluorophosphate and N-ethylmaleimide. The ATP-independent pathway is less sensitive to N-ethylmaleimide, hemin, and 3,4-dichloroisocoumarin and is not affected by diisopropylfluorophosphate. In addition, only the ATP-dependent proteolytic process is inactivated by dilution or incubation at 37 degrees C in the absence of nucleotides. Reticulocytes thus contain multiple soluble systems for degrading proteins and can rapidly hydrolyze certain types of abnormal proteins by either an ATP-independent or ATP-dependent process. Erythrocytes lack the ATP-dependent process present in reticulocytes; however, erythrocytes retain the capacity to degrade oxidant-damaged hemoglobin. These two processes probably are active in the elimination of different types of abnormal proteins.     

Taurocholate-induced inhibition of hepatic lysosomal degradation of horseradish peroxidase.

Endocytosed proteins in hepatocytes are transported to lysosomes for degradation. Metabolites accumulating in these organelles are released into bile by exocytosis, a process that seems to be regulated by the bile salt taurocholate (TC). In this study we examined if TC is also involved in the control of the lysosomal degradation of endocytosed proteins. We used [(14)C]sucrose-labeled horseradish peroxidase ([(14)C]S-HRP), a probe suitable to evaluate lysosomal proteolysis. TC-infused rats as well as isolated rat hepatocytes exposed to TC showed a significant inhibition in the lysosomal degradation of [(14)C]S-HRP (approximately 30%), with no change in either the uptake or the amount of protein reaching lysosomes. Under these conditions, the in vitro assay of lysosomal cathepsins B, L, H, and D revealed no change in their activities, suggesting that a reversible inhibition (lysosomal alkalinization?) was taking place in hepatocytes. Nevertheless, lysosomal pH measured using fluorescein isothiocyanate-dextran was shown not to be altered by TC. In addition, TC was unable to inhibit proteolysis in [(14)C]S-HRP loaded lysosomes or interfere in cathepsin assays. The results suggest that TC inhibits the lysosomal degradation of endocytosed proteins in hepatocytes and that the mechanism does not involve an effect of the bile salt per se or a rise in lysosomal pH.     

Hyperthermia stimulates energy-proteasome-dependent protein degradation in cultured myotubes

Previous studies suggest that elevated temperature stimulates protein degradation in skeletal muscle, but the intracellular mechanisms are not fully understood. We tested the role of different proteolytic pathways in temperature-dependent degradation of long- and short-lived proteins in cultured L6 myotubes. When cells were cultured at different temperatures from 37 to 43 degrees C, the degradation of both classes of proteins increased, with a maximal effect noted at 41 degrees C. The effect of high temperature was more pronounced on long-lived than on short-lived protein degradation. By using blockers of individual proteolytic pathways, we found evidence that the increased degradation of both long-lived and short-lived proteins at high temperature was independent of lysosomal and calcium-mediated mechanisms but reflected energy-proteasome-dependent degradation. mRNA levels for enzymes and other components of different proteolytic pathways were not influenced by high temperature. The results suggest that hyperthermia stimulates the degradation of muscle proteins and that this effect of temperature is regulated by similar mechanisms for short- and long-lived proteins. Elevated temperature may contribute to the catabolic response in skeletal muscle typically seen in sepsis and severe infection.     

Insertion of Lysosomal Targeting Sequences to the Amyloid Precursor Protein Reduces Secretion of βA4

Abstract: The processing of the amyloid precursor protein (APP) was investigated in cells stably expressing different APP hybrid proteins. The cytoplasmic domain of APP was either deleted or replaced by the corresponding domain of the membrane protein TGN38, lamp-1, or LIMPII. The cytosolic domain of TGN38 in the APP molecule did not alter the secretion of βA4 when compared with the wild-type APP; however, APP associated with the cell surface and the nonamyloidogenic processing of APP were reduced. With the APP molecules carrying the lysosomal targeting signals of lamp-1 or LIMPII, a decrease in the secretion of βA4 was observed. Cell surface association and nonamyloidogenic processing were also impaired. This suggests increased degradation of APP and thus efficient targeting to the lysosomal system. Cells expressing the Swedish APP variant generated intracellular βA4 that accumulated after treatment with chloroquine. This effect was more dramatic with APP mutants carrying lysosomal targeting signals than with full-length APP. Our data suggest the existence of an intracellular site of βA4 generation from where βA4 is degraded rather than secreted.     

Emerging functions of the VCP/p97 AAA-ATPase in the ubiquitin system

The ATP-driven chaperone valosin-containing protein (VCP)/p97 governs critical steps in ubiquitin-dependent protein quality control and intracellular signalling pathways. It cooperates with diverse partner proteins to help process ubiquitin-labelled proteins for recycling or degradation by the proteasome in many cellular contexts. Recent studies have uncovered unexpected cellular functions for p97 in autophagy, endosomal sorting and regulating protein degradation at the outer mitochondrial membrane, and elucidated a role for p97 in key chromatin-associated processes. These findings extend the functional relevance of p97 to lysosomal degradation and reveal a surprising dual role in protecting cells from protein stress and ensuring genome stability during proliferation.     

When the chains do not break: the role of USP10 in physiology and pathology

Deubiquitination is now understood to be as important as its partner ubiquitination for the maintenance of protein half-life, activity, and localization under both normal and pathological conditions. The enzymes that remove ubiquitin from target proteins are called deubiquitinases (DUBs) and they regulate a plethora of cellular processes. DUBs are essential enzymes that maintain intracellular protein homeostasis by recycling ubiquitin. Ubiquitination is a post-translational modification where ubiquitin molecules are added to proteins thus influencing activation, localization, and complex formation. Ubiquitin also acts as a tag for protein degradation, especially by proteasomal or lysosomal degradation systems. With ~100 members, DUBs are a large enzyme family; the ubiquitin-specific peptidases (USPs) being the largest group. USP10, an important member of this family, has enormous significance in diverse cellular processes and many human diseases. In this review, we discuss recent studies that define the roles of USP10 in maintaining cellular function, its involvement in human pathologies, and the molecular mechanisms underlying its association with cancer and neurodegenerative diseases. We also discuss efforts to modulate USPs as therapy in these diseases.Subject terms: Cell biology, Cell signalling     

Altered vitamin E status in Niemann-Pick type C disease

Vitamin E (α-tocopherol) is the major lipid-soluble antioxidant in many species. Niemann-Pick type C (NPC) disease is a lysosomal storage disorder caused by mutations in the NPC1 or NPC2 gene, which regulates lipid transport through the endocytic pathway. NPC disease is characterized by massive intracellular accumulation of unesterified cholesterol and other lipids in lysosomal vesicles. We examined the roles that NPC1/2 proteins play in the intracellular trafficking of tocopherol. Reduction of NPC1 or NPC2 expression or function in cultured cells caused a marked lysosomal accumulation of vitamin E in cultured cells. In vivo, tocopherol significantly accumulated in murine Npc1-null and Npc2-null livers, Npc2-null cerebella, and Npc1-null cerebral cortices. Plasma tocopherol levels were within the normal range in Npc1-null and Npc2-null mice, and in plasma samples from human NPC patients. The binding affinity of tocopherol to the purified sterol-binding domain of NPC1 and to purified NPC2 was significantly weaker than that of cholesterol (measurements kindly performed by R. Infante, University of Texas Southwestern Medical Center, Dallas, TX). Taken together, our observations indicate that functionality of NPC1/2 proteins is necessary for proper bioavailability of vitamin E and that the NPC pathology might involve tissue-specific perturbations of vitamin E status.     

Investigation of the mechanism of protein turnover in HeLa S-3 cells by incubation at elevated temperatures

An apparent paradox relating to the degradation of endogenous proteins in HeLa S-3 cells occurs at 45 degrees C, at which their proteolysis is considerably enhanced in vitro but completely inhibited in vivo. No significant differences in rates of degradation of short-lived (nascent) and long-lived ('existing') proteins synthesised at 37 degrees C were found when chased at temperatures up to 43 degrees C, but at 45 degrees C degradation of both categories was reduced to zero in vivo. Synthesis of protein was suppressed at temperatures above 41 degrees C, being reduced by up to 60% at 43 degrees C. Proteolysis in vitro proceeded 1.6-1.7 times faster at 45 degrees C than at 37 degrees C and neutral pH. Evidence is presented for the involvement of the basal system; the findings both in vivo and in vitro do not seem to implicate the lysosomal system, no firm indication being obtained of its 'induction' at elevated temperatures. The results are discussed in terms of the arrest of intracellular circulation at elevated temperatures, thereby reducing the delivery rate of proteins as substrates of the intracellular basal proteolytic enzyme system to negligible levels (i.e., to the frequency of encounters due solely to the diffusion of protein molecules with the cytoplasm).     

Relationship between thermal tolerance and protein degradation in temperature-sensitive mouse cells.

The induction of thermotolerance was studied in a temperature sensitive mouse cell line, ts85, and results were compared with those for the wild-type FM3A cells. At the nonpermissive temperature of 39 degrees C, ts85 cells are defective in the degradation of short-lived abnormal proteins, apparently because of loss of activity of a ubiquitin-activating enzyme. The failure of the ts85 cells to develop thermotolerance to 41-43 degrees C after incubation at the nonpermissive temperature of 39 degrees C correlated with the failure of the cells to degrade short-lived abnormal proteins at 39 degrees C. However, the failure of the ts85 cells to develop thermotolerance to 43 degrees C during incubation at 33 degrees C after either arsenite treatment or heating at 45.5 degrees C for 6 or 10 min did not correlate with protein degradation rates. Although the rate of degrading abnormal protein was reduced after heating at 45.5 degrees C for 10 min, the rates were normal after arsenite treatment or heating at 45.5 degrees C for 6 min. In addition, when protein synthesis was inhibited with cycloheximide both during incubation at 33 degrees C or 39 degrees C and during heating at 41-43 degrees C, resistance to heating was observed, but protein degradation rates at 39 degrees C or 43 degrees C were not altered by the cycloheximide treatment. Therefore, there is apparently no consistent relationship between rates of degrading abnormal proteins and the ability of cells to develop thermotolerance and resistance to heating in the presence of cycloheximide.     

Autophagy and mitochondria in Pompe disease: nothing is so new as what has long been forgotten

Macroautophagy (often referred to as autophagy) is an evolutionarily conserved intracellular system by which macromolecules and organelles are delivered to lysosomes for degradation and recycling. Autophagy is robustly induced in response to starvation in order to generate nutrients and energy through the lysosomal degradation of cytoplasmic components. Constitutive, basal autophagy serves as a quality control mechanism for the elimination of aggregated proteins and worn-out or damaged organelles, such as mitochondria. Research during the last decade has made it clear that malfunctioning or failure of this system is associated with a wide range of human pathologies and age-related diseases. Our recent data provide strong evidence for the role of autophagy in the pathogenesis of Pompe disease, a lysosomal glycogen storage disease caused by deficiency of acid alpha-glucosidase (GAA). Large pools of autophagic debris in skeletal muscle cells can be seen in both our GAA knockout model and patients with Pompe disease. In this review, we will focus on these recent data, and comment on the not so recent observations pointing to the involvement of autophagy in skeletal muscle damage in Pompe disease.