Inhibition of pyruvate carboxylase degradation and total protein breakdown by lysosomotropic agents in 3T3-L1 cells.

1. Exposure to [3H]biotin during the differentiation of 3T3-L1 cells to adipocytes selectively labelled pyruvate carboxylase (EC 6.4.1.1). A subsequent incubation of labelled cells permitted the measurement of the degradation rate constant of this mitochondrial enzyme. 2. In medium without serum, pyruvate carboxylase was degraded with a half-life of 64 h, considerably longer than that found for average cell protein. The long half-life is commensurate with the enzyme being catabolized when whole mitochondria are destroyed. 3. The breakdown of pyruvate carboxylase was inhibited to a greater extent than the breakdown of total cell protein by insulin, NH4Cl and inhibitors of lysosomal proteinases, suggesting that the enzyme is degraded by the autophagic lysosomal system of the cell. 4. The above evidence implies that whole mitochondria are degraded in lysosomes, a conclusion that agrees with earlier electron-microscopic evidence showing mitochondria within autophagic vacuoles. 5. A second degradative pathway must be invoked to account for the breakdown of mitochondrial proteins of short half-life.     

Degradation of erythrocyte-microinjected and scrape-loaded homologous cytosolic proteins by 3T3-L1 cells.

Homologous cytosol was introduced into 3T3-L1 cells by two different methods. Erythrocytes loaded with radiolabelled cytosolic proteins extracted from 3T3-L1 cells were fused with the aid of Sendai virus to 3T3-L1 cells, which were then seeded to confluent and non-confluent cultures. Cytosolic proteins were also introduced into cells by the technique of scrape-loading. In confluent cells, injected cytosolic proteins were recovered largely (54-93%) in a sedimentable (6 X 10(6) gav.-min) fraction from recipient cells irrespective of the method of introduction or of radiolabelling of the injected proteins [( 125I]iodination, reductive methylation with NaB3H4 and backbone labelling with L-[4,5-3H]leucine). The degradation of microinjected cytosolic proteins was in all cases inhibited by the lysosomotropic agent NH4Cl to a greater extent (32-75%) than that observed for endogenous cytosolic (less than or equal to 19%) proteins (labelled with L-[4,5-3H]leucine). In growing cells both endogenous total cell proteins and microinjected proteins were degraded at a slower rate than in confluent cell monolayers. The inhibition by NH4Cl of the degradation of both the endogenous and microinjected proteins is decreased compared with the inhibition observed in confluent monolayers. The results are discussed in terms of the cytoplasmic capacity to segregate microinjected homologous proteins before protein degradation can take place.     

Intracellular degradation of hemoglobin transferred into fibroblasts by fusion with red blood cells

Hamster fibroblast protein and rabbit hemoglobin were labelled by incubation of fibroblasts (BHK21) or reticulocytes with [³H]leucine. Alternatively, human or rabbit hemoglobin was labelled by carbamoylation of erythrocytes with K¹⁴CNO. The labelled hemoglobins were introduced into fibroblasts by virus-mediated fusion between the blood cells and fibroblasts. The hemoglobins became uniformly distributed throughout the cytoplasm. Degradation was assessed from release of acid-soluble radioactivity into the medium. Radioactivity from [¹⁴C]-carbamoylhemoglobin was released as carbamoylvaline and homocitrulline, and these compounds were not metabolized or reincorporated by the cells. Intermediate degradation products could not be detected. The degradation of hemoglobin followed first-order kinetics. The half-life of both carbamoylated and native rabbit hemoglobin in hamster fibroblasts was 28 h, and the half-life of carbamoylated human hemoglobin was about 150 h in fibroblasts from hamster (BHK21), mouse (Balb/3T3), and man (MRC 5), corresponding to that of the more stable endogenous proteins. Phenylhydrazine increased the intracellular degradation of carbamoylated human hemoglobin about 13 times, whereas the degradation of endogenous proteins was little affected. Hemoglobin was degraded in homogenates at 31% h^?1 at pH 5 and 0.3% h^?1 at pH 7.4. Phenylhydrazine increased these rates to 45% h^?1 and 9.7% h^?1, respectively. Growing hamster fibroblasts, which are brought into quiescence by serum deprivation or by high culture density, increase the degradation of endogenous protein and of hemoglobin in parallel.     

Degradation of proteins microinjected into IMR-90 human diploid fibroblasts

Erythrocyte ghosts loaded with 125I-labeled proteins were fused with confluent monolayers of IMR-90 fibroblasts using polyethylene glycol. Erythrocyte-mediated microinjection of 125I-proteins did not seriously perturb the metabolism of the recipient fibroblasts as assessed by measurements of rates of protein synthesis, rates of protein degradation, or rates of cellular growth after addition of fresh serum. A mixture of cytosolic proteins was degraded after microinjection according to expected characteristics established for catabolism of endogenous cytosolic proteins. Furthermore, withdrawal of serum, insulin, fibroblast growth factor, and dexamethasone from the culture medium increased the degradative rates of microinjected cytosolic proteins, and catabolism of long-lived proteins was preferentially enhanced with little or no effect on degradation of short-lived proteins. Six specific polypeptides were degraded after microinjection with markedly different half-lives ranging from 20 to 320 h. Degradative rates of certain purified proteins (but not others) were also increased in the absence of serum, insulin, fibroblast growth factor, and dexamethasone. The results suggest that erythrocyte- mediated microinjection is a valid approach for analysis of intracellular protein degradation. However, one potential limitation is that some microinjected proteins are structurally altered by the procedures required for labeling proteins to high specific radioactivities. Of the four purified proteins examined in this regard, only ribonuclease A consistently showed unaltered enzymatic activity and unaltered susceptibility to proteolytic attack in vitro after iodination.     

Regulation of protein synthesis and degradation in L8 myotubes. Effects of serum, insulin and insulin-like growth factors.

We have examined the regulation of protein turnover in rat skeletal myotubes from the L8 cell line. We measured protein synthesis by the rates of incorporation of radiolabelled tyrosine into protein in the presence of a flooding dose of non-radioactive tyrosine. We monitored degradation of proteins labelled with radioactive tyrosine by the release of acid-soluble radioactivity into medium containing excess nonradioactive tyrosine. Extracellular tyrosine pools and intracellular tyrosyl-tRNA equilibrate rapidly during measurements of protein synthesis, and very little reutilization of the radiolabelled tyrosine occurs during degradation measurements. Measured rates of protein synthesis and degradation are constant for several hours, and changes in myotube protein content can be accurately predicted by the measured rates of protein synthesis and degradation. Most of the myotube proteins labelled with radioactive tyrosine for 2 days are degraded, with half-lives (t1/2) of approx. 50 h. A small proportion (less than 2.5%) of the radiolabelled proteins are degraded more rapidly (t1/2 less than 10 h), and, at most, a small proportion (less than 15%) are degraded more slowly (t1/2 greater than 50 h). A variety of agents commonly added to primary muscle cell cultures or to myoblast cell lines (18% Medium 199, 1% chick-embryo extract, antibiotics and antifungal agents) had no effect on rates of protein synthesis or degradation. Horse serum, fetal bovine serum and insulin stimulate protein synthesis and inhibit the degradation of long-lived proteins without affecting the degradation of short-lived proteins. Insulin-like growth factors (IGF)-1 and -2 also stimulate protein synthesis and inhibit protein degradation. The stimulation of protein synthesis and the inhibition of protein degradation are of similar magnitude (a maximum of approx. 2-fold) and display similar sensitivities to a particular anabolic agent. Insulin stimulates protein synthesis and inhibits protein degradation only at supraphysiological doses, whereas IGF-1 and -2 are effective at physiological concentrations. These and other findings suggest that IGFs may be important regulators of skeletal muscle growth during the fetal and early neonatal periods.     

Protein degradation in skin fibroblasts from patients with Duchenne muscular dystrophy.

The rates of degradation of [3H]leucine-labelled proteins have been measured in cultures of skin fibroblasts obtained from normal controls (five subjects) and patients with Duchenne muscular dystrophy (six subjects). Cultures were incubated with [3H]leucine (10 microCi/ml) for 60 min to label "short-lived" proteins, and with [3H]leucine (5 microCi/ml) for 60 h to label "long-lived" proteins. Optimal wash procedures were devised for removal of [3H]leucine from the extracellular space and from cell pools before beginning degradation measurements. Re-utilization of [3H]leucine released from degraded labelled proteins was prevented by supplementing the medium with 4mM-leucine. Rates of degradation did not depend on the growth state of the cells or on cell age over the range used (passages eight-20). Degradation of long-lived proteins was approximately linear over a 24h period, at a rate of 1.0% per h. 30% of short-lived protein was degraded within 6h. No differences were observed between protein degradation in normal fibroblasts and in those from patients with Duchenne muscular dystrophy.     

Microcarrier culture of bowes melanoma cells in serum-free medium with Human plasma fraction IV-4+ V

Bowes melanoma cells were cultivated successfully in a serum-free medium which was constructed by the concept of maximum retention of proteins from fractionated human plasma having growth stimulatory activities. The cells could be cultivated in the serum-free medium without any adaptation period. The major serum-free component of the medium was the fraction IV-4 + V of the Cohn fractionation process of human plasma. Approximately six times increase of tissue-type plasminogen activator (t-PA) activity as compared with that in serum-free medium even though the cell growth was much slower. In addition, the growth stimulatory activities of thrombin and fibronectin were investigated during the cultivation of Bowes melanoma cells in this serum-free medium. These proteins contributed significantly to the enhanced growth of cells by reducing doubling time to 25 and 35 h as compared with 55 h in the serum-free medium without them. Especially, fibronectin supported cells to propagate near to the maximum cell density achieved in the medium with 10% FBS.     

Role of proteasomes in the degradation of short-lived proteins in human fibroblasts under various growth conditions

Degradation of proteins in the cells occurs by proteasomes, lysosomes and other cytosolic and organellar proteases. It is believed that proteasomes constitute the major proteolytic pathway under most conditions, especially when degrading abnormal and other short-lived proteins. However, no systematic analysis of their role in the overall degradation of truly short-lived cell proteins has been carried out. Here, the degradation of short-labelled proteins was examined in human fibroblasts by release of trichloroacetic acid-soluble radioactivity. The kinetics of degradation was decomposed into two, corresponding to short- and long-lived proteins, and the effect of proteasomal and lysosomal inhibitors on their degradation, under various growth conditions, was separately investigated. From the degradation kinetics of proteins labelled for various pulse times it can be estimated that about 30% of newly synthesised proteins are degraded with a half-life of approximately 1h. These rapidly degraded proteins should mostly include defective ribosomal products. Deprivation of serum and confluent conditions increased the degradation of the pool of long-lived proteins in fibroblasts without affecting, or affecting to a lesser extent, the degradation of the pool of short-lived proteins. Inhibitors of proteasomes and of lysosomes prevented more than 80% of the degradation of short-lived proteins. It is concluded that, although proteasomes are responsible of about 40-60% of the degradation of short-lived proteins in normal human fibroblasts, lysosomes have also an important participation in the degradation of these proteins. Moreover, in confluent fibroblasts under serum deprivation, lysosomal pathways become even more important than proteasomes in the degradation of short-lived proteins.     

Initial kinetics of Protein turnover in growing yeast

Proteins in yeast growing in a medium with glucose or ethanol as carbon source were pulse-labelled by a 20-min incubation with¹⁴C-leucine. The proteins in cells labelled and growing in a glucose medium were stable; when this population was transferred to the ethanol medium, the proteins were degraded at a rate of 1.1 %/h. The population labelled and growing in an ethanol medium displayed a fraction of short-lived proteins (about 4 %), decaying with a half-life of 0.5 h. The size of the short-lived protein fraction increased slightly after shifts to a glucose as well as to a starvation medium. The residual long-lived proteins underwent a turnover of 1.3 –1.4 %/h in the ethanol or the starvation medium and of 0.3 %/h in the glucose medium, respectively. Proteins labelled in the presence of canavanine or ethionine were degraded at only a slightly greater rate than the normal proteins. Participant of the UNESCO Postgraduate Course “On Modern Problems in Biology”.     

Mechanisms of protein degradation in growing and non-growing L-cell cultures.

L-cells prelabelled with [14C]leucine and [3H]thymidine were placed in either fresh growth medium (minimal essential medium with 10% serum) or stepdown medium (minimal essential medium) for 3 days. The 14C/3H ratio remained constant in the growing cultures and decreased in the stationary-phase cultures, indicating no protein turnover in growing cultures and a degradative rate of 0.6%/h in the stationary-phase cultures. Media analysis, however, indicated that 14C-labelled proteins were being degraded at approx. 1.2%/h in growing cultures and 1.7%/h in stationary-phase cultures. Additional studies indicated that a subpopulation of L-cells in the monolayer, comprising approx. 20--30% of the total, were lost in the original processing procedure. Experiments in which recoveries approached 100% by fixation of the monolayer in situ indicated that a protein-degrading subpopulation accounted for all the observed proteolysis in the growing cultures. Proteolysis in these cultures was only partially inhibited with NH4Cl, indicating that only a small part of the protein degradation was occurring in an activated lysosomal-autophagic system. NaF produced a more effective inhibition of proteolysis, but we were not able to distinguish whether this effect was on an ATP-requiring basal-turnover mechanism or a direct effect on unregulated activity of proteinases in the cell hyaloplasm. However, NH4Cl inhibited the proteolysis induced when cells were placed in stepdown medium, suggesting that the induced proteolysis was occurring via the autophagic system. We conclude that L-cells exist in at least two states with respect to protein degradation: (a) a subpopulation that is actively replicating and does not degrade cellular proteins, and (b) a second subpopulation of cells, derived from the preceding one, which degraded most of their labelled proteins, are not capable of further replication, and are not sedimented in an iso-osmotic EDTA buffer solution. In addition, proliferating L-cells, when placed in stepdown medium, begin to degrade cell protein through a mechanism involving autophagolysosomes.     

Biosynthesis of plasma proteins in serum-free medium by primary monolayer culture of rat hepatocytes

Morphologically intact rat hepatocytes separated by collagenase perfusion were cultured in L-15/fetal calf serum medium to form a monolayer. Thereafter the hepatocytes were grown in serum-free L-15 medium in which they produced and continuously released plasma proteins. The secreted plasma proteins were collected, separated and characterized by crossed immunoelectrophoresis. Most of the newly biosynthesized plasma proteins secreted into the medium during incubation for thirty hours had the same electrophoretic mobility, antigenicity and staining characteristics as their counterparts in rat serum. The addition of tritium labelled amino acid mixture to the culture medium revealed that the release of radioactively labelled plasma proteins into the culture medium was essentially linear during the thirty hour incubation period. However, saturation of the intracellular pool took place after ca. ten hours of incubation. Addition of leukocytic endogenous mediator, LEM, to cultures of rat hepatocytes caused a profound increase in the relative concentration of acute-phase proteins secreted into the culture medium.     

Mechanisms of intracellular protein catabolism. Intracellular fate of microinjected polypeptides translated in vitro.

Erythrocyte-mediated microinjection was used to introduce [35S]polypeptides translated in vitro into 3T3-L1 cells. Such [35S]polypeptides are not degraded after loading into erythrocytes and are stable for the first 2 h after microinjection into growing 3T3-L1 cells. Similarly, little or no degradation of microinjected [35S]polypeptides is observed in either growing or confluent 3T3-L1 cells over a 70 h period. Microinjection of reticulocyte lysate alone does not affect the rate of degradation of long-lived endogenous protein. Reductively [3H]methylated lysate haemoglobin is degraded after microinjection by a cytosolic mechanism. Microinjected 125I-labelled bovine serum albumin is rapidly degraded by a cytosolic mechanism at the same rate in the absence or presence of reticulocyte lysate. The data do not support the notion that the observed lack of degradation of microinjected [35S]polypeptides translated in vitro is due to the presence of proteolytic inhibitors in reticulocyte lysates which can inhibit the degradation of microinjected or cellular proteins.     

Peptide sequences that target proteins for enhanced degradation during serum withdrawal

Fibroblasts increase the catabolism of certain intracellular proteins in response to serum withdrawal, and these proteins contain specific peptide regions that may be required for their increased degradation. We show that the increased degradation of microinjected ribonuclease A during serum withdrawal can be blocked by co-injection of a pentapeptide corresponding to residues 7-11 of ribonuclease A, Lys-Phe-Glu-Arg-Gln. Furthermore, similar peptide sequences appear to play a widespread role in targeting proteins for enhanced degradation. Affinity-purified antibodies raised against the pentapeptide are able to precipitate 20-35% of radiolabeled cytosolic proteins from fibroblasts. Such proteins are preferentially degraded when cells are deprived of serum while nonimmunoprecipitable proteins are degraded at the same rate in the presence and absence of serum. Immunoreactive cytosolic proteins also exist in rat liver and kidney, and these proteins are depleted when protein degradation rates are enhanced due to starvation. Several types of evidence suggest that the peptides recognized in cellular proteins are similar to Lys-Phe-Glu-Arg-Gln but are not this exact sequence. Analyses of amino acid sequences for four proteins whose degradative rates are enhanced in response to serum withdrawal and for four proteins that are degraded in a serum-independent manner indicate two possible peptide motifs related to Lys-Phe-Glu-Arg-Gln that may target cellular proteins for enhanced degradation. These results, combined with previous studies (McElligott, M. A., Miao, P., and Dice, J. F. (1985) J. Biol. Chem. 260, 11986-11993), suggest that these peptide regions target specific proteins to a lysosomal pathway of degradation during serum withdrawal.     

Degradation and replenishment of the labile protein fraction in non-growing cells of the asporogenic mutant ofBacillus megaterium

Kinetics of degradation of labelled proteins was followed in two asporogenic mutants ofBacillus megaterium during incubation in a sporulation medium. Both the mutant producing exocellular protease (KM 1prn ⁺) and the mutant not producing the enzyme (KM 12prn) were found to contain a labile protein fraction, whose proportion decreases with prolonged time of labelling and whose half-life is about 1 h. Most proteins were relatively stable and were degraded at a rate of 1 %/h and 2 %/h in strains KM 1 and KM 12, respectively (half life 70–80 h and 35–40 h in strains KM 1 and KM 12, respectively). The intracellular proteolytic activity of the KM 12 mutant remains practically the same during incubation in the sporulation medium or slowly increases. The labile protein fraction practically disappears from the cells after a 3.5-h incubation. When such a culture is then subjected to a shift-up and transferred again to the sporulation medium, the rate of protein turnover temporarily increases. The temporary increase of the turnover rate is caused by a partial replenishment of the labile protein fraction rather than by an accelerated degradation of the relatively stable fraction. The intracellular proteolytic activity does not increase under these conditions. The wild sporogenic strain ofB. megaterium also contains the labile protein fraction. Its half protein life is 1 h or less. However, the second protein fraction is degraded much more rapidly than in the asporogenic mutants and its half life is 6–7 h.     

Intracellular protein degradation in cultured bovine lens epithelial cells

Summary 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 >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 <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. This work was supported in part by grants from U. S. Department of Agriculture contract 53-3K06-5-10, Massachusetts Lions Eye Research Fund, Inc., and the Daniel and Florence Guggenheim Foundation. D. A. E. is a recipient of a National Eye Institute postdoctoral fellowship.     

Intracellular proteolysis in rat cardiac and skeletal muscle cells in culture.

Treatment of adult rats with dexamethasone resulted in an increase in cardiac muscle weight but a decrease in skeletal muscle weight. The different response of skeletal and cardiac muscles to the glucocorticoid was also reflected by a dexamethasone-induced enhancement of myofibrillar protease activity in the gastrocnemius muscle and an inhibition of a similar proteolytic activity in the heart. Newborn rats also exhibit the same, tissue-specific response to the glucocorticoid hormone. Consequently, the difference between cardiac and skeletal muscle responsiveness to conditions of wasting was investigated in culture. Average rates of degradation of intracellular proteins were determined in cultured cells derived from rat skeletal and cardiac muscle by following the release of radioactivity from cells prelabelled with ¹⁴C-phenylalanine. The release of label into the TCA soluble medium as measured during 12 hours of incubation, conformed to a first-order reaction and both cell types were found to degrade intracellular proteins at a similar rate. After 12 hours of incubation in a complete Ham F-10 medium supplemented with serum approximately 18% of total cellular protein was degraded. Incubation in a minimal medium or serum-deprivation enhanced the average rate of proteolysis to a value of 29% degradation at 12 hours indicating that intracellular proteolysis in these cells is responding to nutritional deprivation by increased activity. However, addition of glucose (22.2 nM) or dexamethasone (10^?6M) to the incubation medium failed to affect the rate of net protein degradation. Under no experimental condition could a difference be found between the proteolytic response of skeletal muscle cells to that of cardiac muscle cells and both cell types displayed similar changes in rates of protein degradation under various nutritional and hormonal conditions in culture. Thus, protein sparing in the heart of intact animals under catabolic conditions which enhance protein loss in skeletal muscle can probably not be ascribed to intrinsic differences in the direct response of cellular proteases to the tested hormones and nutrients. Rather, an extracellular factor(s) is apparently required for induction of the differential response of these tissues in the intact animal to protein wasting conditions. Alternatively, cells in culture might have lost the property of differential degradative response which operates in vivo.     

Effect of prolactin and cyclic AMP on 125I-labelled low density lipoprotein uptake and metabolism by luteinized porcine granulosa cells in culture

The present study examines the effect of prolactin (PRL) and N6-2(1)-O-dibutyryladenosine 3'5'-cyclic monophosphate (cAMP) on low density lipoprotein (LDL) uptake and metabolism by luteinized porcine granulosa cells in culture. Granulosa cells from preovulatory follicles were plated with 1% serum and 1 microgram/mL of insulin for the first 48 h. Following plating (day 3) the cells were cultured in serum-free media with the same dose of insulin. The next day the medium was replaced with serum- and insulin-free medium, and to some cultures 1.23 IU/mL of human chorionic gonadotrophin (hCG) was added. On day 5 the medium was again replaced and graded amounts of PRL (0, 0.03, 0.3, and 3 micrograms/mL) were added. Following 48 h of incubation with PRL, 20 micrograms/mL of 125I-labelled LDL was added to cultures. Surface-bound, internalized, and degraded LDLs were quantitated at 12 h following addition of LDL. To examine the effect of cAMP on LDL metabolism, the cells were exposed for 24 h to cAMP (3mM) on day 6 of culture. PRL had a stimulatory effect on LDL degradation by luteinized granulosa cells. Pre-exposure of cells to hCG augmented the stimulatory effect of PRL. Addition of cAMP also enhanced LDL degradation by luteinized granulosa cells. Both PRL and cAMP increased surface binding of LDL in cells pre-exposed to hCG, but there was no effect on internalization. The increase in cell surface binding of LDL with PRL and cAMP was less than their effect on LDL degradation.(ABSTRACT TRUNCATED AT 250 WORDS)     

HDL3 degradation by proteases in isolated rat intestinal mucosal cells

Human 125I-labelled HDL3 is degraded by isolated rat intestinal mucosal cells. In our experimental conditions, lipoprotein degradation occurred by two different mechanisms. In one, lipoprotein was degraded within the cell, following binding and internalisation. In the other, degradation occurred in the medium, which seemed to contain protease activity released from cells during incubation. Though lipoprotein-deficient serum apparently interfered with degradation in the medium, bovine serum albumin had no such effect. The lysosomal inhibitor, chloroquine, reduced degradation by 60% without inhibiting HDL binding. Intestinal cell extracts contained at least two different proteases, with pH optima of 4.5 and 8.0, respectively. Comparing HDL and LDL degradation on a molar basis, more HDL particles were degraded by the cell-free extracts at pH 4.5. This degradation was activated by dithiothreitol and was inhibited by iodoacetic acid. From these observations we conclude that HDL3 is taken up by the rat intestinal mucosal cell through a specific binding site and subsequently degraded by a thiol-dependent protease in the lysosome.     

Serum suppresses the expression of hormonally induced functions in cultured granulosa cells

Growth and function of primary cultures of granulosa cells obtained from immature, hypophysectomized, estrogen-treated rats were compared in serum-containing and serum-free media. In serum-free medium (1:1 mixture of DMEM:F-12) supplemented with insulin, hydrocortisone, transferrin and fibronectin (4F medium), the cells remained healthy and steroidogenically responsive for at least 60 days in culture. The growth profile of the granulosa cells in 4F medium was similar to that obtained in serum-containing medium. In both media cell proliferation did not exceed more than one cell doubling. DMEM:F-12 alone did not support the cell viability. Upon FSH stimulation, the cells produced 25 fold more progestin and estrogen per cell in 4F medium than in medium supplemented with 5% serum. This effect was not directly related to serum proteins which mediate cell adhesion since cells cultured in dishes precoated with serum remained steroidogenically responsive to FSH. Cholera toxin and Bt₂-cAMP readily stimulated progestin production in the presence of serum. The inhibitory effect of serum was not reversed by adding the four factors to serum-containing medium. The factors were essential for the FSH-induced steroidogenesis in serum-free medium. After four days of incubation in 4F medium, the cells showed a transient loss of their ability to produce progestin in response to FSH. In both 4F medium as well as in serum-containing medium, the cells regained their hormonal responsiveness after 35 days in culture. Since the loss of hormonal responsiveness occurred at the same time as growth was initiated in the cultures, it is suggested that the FSH-induced steroidogenesis is negatively controlled by growth-related processes.     

A putative protein-sequestration site involving intermediate filaments for protein degradation by autophagy. Studies with microinjected purified glycolytic enzymes in 3T3-L1 cells.

Several glycolytic enzymes (lactate dehydrogenase, pyruvate kinase, glyceraldehyde-3-phosphate dehydrogenase) were radiolabelled by [125I]iodination, conjugation with 125I-labelled Bolton & Hunter reagent and reductive [3H]methylation, and their degradative rates after microinjection into 3T3-L1 cells compared with that of the extracellular protein bovine serum albumin. Although the albumin remains largely cytosolic in recipient cells, the glycolytic enzymes rapidly (less than 30 min) become insoluble, as measured by detergent and salt extractions. The microinjected glycolytic enzymes appear to form disulphide-linked aggregates, are found in a cell fraction rich in vimentin-containing intermediate filaments and histones (nuclear-intermediate-filament fraction), and are degraded slowly by a lysosomal mechanism, as judged by the effects of inhibitors (NH4Cl, leupeptin, 3-methyladenine). 125I-labelled bovine serum albumin appears to be degraded rapidly and non-lysosomally. Prolonged treatment (96 h) of cultured cells with leupeptin results in the accumulation of pulse-labelled ([35S]methionine for 24 h) endogenous cell proteins in the detergent-and salt-non-extractable residue, but NH4Cl and 3-methyladenine do not have this effect. The findings are in terms of the interpretation of experiments involving microinjection of proteins to study intracellular protein protein degradation by autophagy.