Brain Slice Protein Degradation and Development

Protein degradation rates were measured in brain slices prepared from rats of various ages. This was done by adding the protein synthesis rate, determined by incorporation of a labeled precursor, and the net protein degradation rate, determined by measuring the changes with time of total free amino acids. These rates are about 30% higher than those previously calculated from data on protein synthesis rates and protein accumulation rates in vico. The protein degradation rates in brain slices diminish with age; i.e., 2-day cerebellum > 2-day cerebral hemisphere > 12-day cerebral hemisphere > young adult cerebral hemisphere. Protein degradation rates in slices from young brain are initially slightly higher than protein synthesis rates, resulting in a small net degradation with time. Unlike slices from adult brain, the protein degradation rates in slices from young brain decline only modestly with time for as much as 100 min of incubation. The characteristics of protein degradation in brain slices from young animals are roughly similar to some of the data calculated for protein degradation in vivi. suggesting that this system may prove useful for studying factors which control or affect brain protein degradation.     

DEVELOPMENTAL EFFECTS ON PROTEIN SYNTHESIS RATES IN REGIONS OF THE CNS IN VIVO AND IN VITRO

Abstract— Protein synthesis rates have been determined quantitatively in several regions of the nervous system of rats of various ages. The developmental changes in these regions are generally similar with a high rate maintained from several days before birth to about 4 days of age (1.9–2.1% h⁻¹). A decline in the rate ensues thereupon which continues till approx 30 days of age, whence the curve flattens though continuing slowly downward with increasing age. In the young three regions, cerebellum, pineal and pituitary, exhibit exceptionally higher rates (40–50%) than the cerebral hemispheres, pons-medulla, mid brain or cord, which all display curves of similar magnitude and shape. While the rate in the cerebellum eventually declines with age to within 10% of the rate in cerebral hemisphere, rates in the pineal and pituitary though decreasing remain far above (100%) rates in cerebral hemisphere even in adults.
The rate in vitro for slices of cerebellum follows a pattern similar to that shown previously for cerebral hemispheres: in the very young rates are 70–80% of the in vivo value but decline much more rapidly with age and in adult represent only 10–15% of the rate in vivo.
A markedly different pattern is seen in whole (unsliced) pituitaries wherein in vitro rates parallel in vivo rates with increasing age at approx 70–80% of the in vivo rate. Pineals appear to follow a similar pattern.     

Long-term modulation of type L pyruvate kinase activity in young and mature rats

The regulation of type L pyruvate kinase concentrations in liver of young (35–45 days old) and adult (60–85 days old) rats starved and re-fed a 71% sucrose diet was investigated. Re-feeding is accompanied by an increase in the enzyme level in liver determined kinetically and immunologically. A constant ratio of kinetic activity to immunological activity was observed under all conditions examined, indicating that activity changes are the result of a regulation of synthesis or degradation and not an interconversion between kinetically active and inactive forms of the enzyme. Synthesis of pyruvate kinase was directly examined by using hepatocytes isolated from starved and re-fed rats. A stimulation of pyruvate kinase synthesis is observed on re-feeding. This increase in synthesis of pyruvate kinase is retained by the isolated hepatocyte for up to 7h in the absence of hormonal stimuli. Administration of glucagon (1μm) to the isolated hepatocytes had no influence on synthesis of pyruvate kinase and no evidence for a glucagon-directed degradation of the enzyme was found. Re-feeding the rat was followed by a transient increase in the synthesis of pyruvate kinase. The peak rate of synthesis was observed before a detectable increase in the enzyme concentration. After a rapid synthesis period, a new steady-state level of the enzyme was achieved and synthesis rates declined. The time course and magnitude for the response to the sucrose diet was dependent on the age of the rat. In young rats, an increase in pyruvate kinase synthesis is observed within 6h and peak synthesis occurs at 11h after re-feeding sucrose. The peak synthesis rate for pyruvate kinase for young rats represents approx. 1% of total protein synthesis. With adult rats, increased pyruvate kinase synthesis is not observed for 11h, with peak synthesis occurring at 24h after re-feeding. In the older rats, peak pyruvate kinase synthesis constitutes greater than 4% of total protein synthesis. Continued re-feeding of the adult rat beyond 24h is accompanied by a decline of pyruvate kinase synthesis to approx. 1.5% of total protein synthesis. The concentration of the enzyme, however, does not decline during this period, suggesting that control of pyruvate kinase degradation as well as synthesis occurs.     

Protein Synthesis Rates in Rats with Portacaval Shunts

Abstract: Protein synthesis rates were measured (33 days postoperatively) in rats with portacaval shunts and in unoperated controls. In brain, no change in the rate of protein synthesis was evident in shunted rats. These data thus do not support the hypothesis that an inhibition of brain protein synthesis is a factor in the etiology of hepatic encephalopathy. The synthesis rate in forebrain at 82 days of age was 0.52%/h. Though brain wet weight was the same in both groups, rats with shunts grew relatively slowly, and their testicles probably decreased in weight. However, no inhibition of muscle, liver, or testicular protein synthesis could be detected. The mechanism of slower or negative growth in these tissues might thus involve an increase in the degradation rate, although a transient inhibition of synthesis at an earlier period is also possible.     

The change in the rate of muscle protein metabolism of rats from weaning to 90 days of age

1. Protein synthesis, net deposition and breakdown was studied in the gastrocnemius muscles of growing rats between weaning and 90 days of age. 2. Fractional protein synthetic rates declined from 30.02% at 25 days to 7.41% at 90 days. 3. The rate of protein degradation follows a similar pattern to that of protein synthesis. A linear relationship was found. 4. The break in the growth curve between 30 and 31 days was also observed in protein metabolism.     

Regulation of myofibrillar protein turnover during maturation in normal and undernourished rat pups

The study tested the hypothesis that a higher rate of myofibrillar than sarcoplasmic protein synthesis is responsible for the rapid postdifferentiation accumulation of myofibrils and that an inadequate nutrient intake will compromise primarily myofibrillar protein synthesis. Myofibrillar (total and individual) and sarcoplasmic protein synthesis, accretion, and degradation rates were measured in vivo in well-nourished (C) rat pups at 6, 15, and 28 days of age and compared at 6 and 15 days of age with pups undernourished (UN) from birth. In 6-day-old C pups, a higher myofibrillar than sarcoplasmic protein synthesis rate accounted for the greater deposition of myofibrillar than sarcoplasmic proteins. The fractional synthesis rates of both protein compartments decreased with age, but to a greater degree for myofibrillar proteins (-54 vs. -42%). These decreases in synthesis rates were partially offset by reductions in degradation rates, and from 15 days, myofibrillar and sarcoplasmic proteins were deposited in constant proportion to one another. Undernutrition reduced both myofibrillar and sarcoplasmic protein synthesis rates, and the effect was greater at 6 (-25%) than 15 days (-15%). Decreases in their respective degradation rates minimized the effect of undernutrition on sarcoplasmic protein accretion from 4 to 8 days and on myofibrillar proteins from 13 to 17 days. Although these adaptations in protein turnover reduced overall growth of muscle mass, they mitigated the effects of undernutrition on the normal maturational changes in myofibrillar protein concentration.     

A METHOD FOR MEASURING BRAIN PROTEIN SYNTHESIS RATES IN YOUNG AND ADULT RATS

The injection of large quantities of radioactive amino acid precursor is proposed as a technique for determining rates of cerebral protein synthesis in vivo. In this way the specific radioactivity of the amino acid precursor in the brain is maintained at a relatively constant level for at least 2 h. Injections of 10–15 μ mol of valine per g body weight result in nearly constant rates of incorporation of radioactivity and do not appear to inhibit cerebral protein synthesis in adult or young (2–6 day old) rat brain. Similar rates were obtained in young rat brain with lysine and histidine. Rates of protein synthesis in cerebral hemisphere were for 2-day-olds 2·1 per cent replacement of protein bound amino acid per h and for adult 0·62 per cent per h. Advantages and disadvantages of the procedure are discussed.     

Growth and muscle protein turnover in the chick

The growth rates of young chicks were varied from 0 to 10% per day by manipulation of the adequacy of the amino acid and energy supply. The rates of protein synthesis in the white breast (pectoralis thoracica) muscle and the dark leg (gastrocnemius and peronaeus longus) muscles were estimated by feeding l-[U-¹⁴C]tyrosine in amino acid/agar-gel diets (`dietary infusion'). This treatment rapidly and consistently produced an isotopic equilibrium in the expired CO₂ and in the free tyrosine of plasma and the muscles. Wholebody protein synthesis in 2-week-old chicks was estimated from the tyrosine flux and was 6.4g/day per 100g body wt. In 1-week-old chicks the rate of protein synthesis was more rapid in the breast muscles than in the leg muscles, but decreased until the rates were similar in 2-week-old birds. Synthesis was also more rapid in fast-growing Rock Cornish broilers than in medium-slow-growing New Hampshire×Single Comb White Leghorn chicks. No or barely significant decrease in the high rates of protein synthesis, in the protein/RNA ratio and in the activity of RNA for protein synthesis occurred in non- or slow-growing chicks fed on diets deficient in lysine, total nitrogen or energy. Thus the machinery of protein synthesis in the young chick seems to be relatively insensitive to dietary manipulation. In the leg muscles, there was a small but significant correlation between the fractional rate of growth and protein synthesis. A decrease in the fractional rate of degradation, however, appeared to account for much of the accumulation of muscle protein in rapidly growing birds. In addition, the rapid accumulation of breast-muscle protein in rapidly growing chicks appeared to be achieved almost entirely by a marked decrease in the fractional rate of degradation.     

Protein Turnover in Brain of the Rat Fetus

Protein synthesis in vivo was studied in whole brain of rat fetuses using continuous intravenous infusion of L-[U-14C]tyrosine into unrestrained pregnant rats at 19 and 21 days gestation. Protein degradation (KD) was calculated by subtracting fractional growth rate of brain protein (KG) from the fractional synthesis rate (KS). KS was high at both gestational ages (0.42 +/- 0.03 days-1 at day 19, 0.47 +/- 0.029 days-1 at 21 days), comparable to values previously reported for newborn rat cerebral hemispheres, and threefold higher than is seen in adult animals. KD was similar at both 19 and 21 days gestation (0.19-0.24) and lower than that reported in neonatal rat brain using similar techniques. Protein accretion during the most rapid phase of brain growth (fetus) is accomplished by similar rates of protein synthesis, but decreased rates of degradation when compared with a slower growth phase (newborn). KD in the brain of the rapidly growing fetus is slightly higher than in adult cerebral hemispheres.     

The effect of protein depletion and repletion on muscle-protein turnover in the chick.

Rates of growth and protein turnover in the breast muscle of young chicks were measured in order to assess the roles of protein synthesis and degradation in the regulation of muscle mass. Rates of protein synthesis were measured in vivo by injecting a massive dose of L-[1-14C]valine, and rates of protein degradation were estimated as the difference between the synthesis rate and the growth rate of muscle protein. In chicks fed on a control diet for up to 7 weeks of age, the fractional rate of synthesis decreased from 1 to 2 weeks of age and then changed insignificantly from 2 to 7 weeks of age, whereas DNA activity was constant for 1 to 7 weeks. When 4-week-old chicks were fed on a protein-free diet for 17 days, the total amount of breast-muscle protein synthesized and degraded per day and the amount of protein synthesized per unit of DNA decreased. Protein was lost owing to a greater decrease in the rate of protein synthesis, as a result of the loss of RNA and a lowered RNA activity. When depleted chicks were re-fed the control diet, rapid growth was achieved by a doubling of the fractional synthesis rate by 2 days. Initially, this was a result of increased RNA activity; by 5 days, the RNA/DNA ratio also increased. There was no evidence of a decrease in the fractional degradation rate during re-feeding. These results indicate that dietary-protein depletion and repletion cause changes in breast-muscle protein mass primarily through changes in the rate of protein synthesis.     

Rates of protein turnover in vivo and in vitro in ventricular muscle of hearts from fed and starved rats.

Starvation of 300 g rats for 3 days decreased ventricular-muscle total protein content and total RNA content by 15 and 22% respectively. Loss of body weight was about 15%. In glucose-perfused working rat hearts in vitro, 3 days of starvation inhibited rates of protein synthesis in ventricles by about 40-50% compared with fed controls. Although the RNA/protein ratio was decreased by about 10%, the major effect of starvation was to decrease the efficiency of protein synthesis (rate of protein synthesis relative to RNA). Insulin stimulated protein synthesis in ventricles of perfused hearts from fed rats by increasing the efficiency of protein synthesis. In vivo, protein-synthesis rates and efficiencies in ventricles from 3-day-starved rats were decreased by about 40% compared with fed controls. Protein-synthesis rates and efficiencies in ventricles from fed rats in vivo were similar to values in vitro when insulin was present in perfusates. In vivo, starvation increased the rate of protein degradation, but decreased it in the glucose-perfused heart in vitro. This contradiction can be rationalized when the effects of insulin are considered. Rates of protein degradation are similar in hearts of fed animals in vivo and in glucose/insulin-perfused hearts. Degradation rates are similar in hearts of starved animals in vivo and in hearts perfused with glucose alone. We conclude that the rates of protein turnover in the anterogradely perfused rat heart in vitro closely approximate to the rates in vivo in absolute terms, and that the effects of starvation in vivo are mirrored in vitro.     

Responses of protein synthesis and degradation in growth control of WI-38 cells

The overall rates of protein synthesis and degradation in perfusion-grown WI-38 cells were followed in the three days after a stepdown in the serum concentration of the culture medium, from 10% to 0.3%. Within three hours after the stepdown, the rate of protein synthesis had decreased and the rate of protein degradation had increased, the combined result being the cessation of protein accumulation. The degradation rate returned over the next three days to its original value, but a zero rate of accumulation was retained because the synthesis rate continued to decline. The rate of DNA synthesis remained constant for six hours after the stepdown. It then declined steadily until reaching a minimum about eight hours later. The results show that extracellular control of protein accumulation depends on adjustments in both protein synthesis and protein degradation, and that the adjustments take place rapidly. This behavior suggests that the cell cycle is arrested after a stepdown because post-mitotic cells are unable to accumulate additional protein. However, an alternative interpretation of the data is that at least part of the changed accumulation is the result, rather than the cause, of the cycle arrest, and that the arrest is caused by other, more specific, reactions than those of general protein metabolism.     

Effect of diabetes on the rates of synthesis and degradation of ribosomes in rat muscle and liver in vivo

An important component of the decrease in protein synthesis in muscle of diabetic animals is a fall in the ribosome content. Therefore, we have investigated the turnover of ribosomes in skeletal muscle, heart, and liver of rats during the onset of diabetes. Synthesis rates were measured by incorporation of label into the protein moieties of the ribosomes, and a dual isotope technique was used to relate ribosome synthesis to that of total tissue protein. Degradation rates were calculated as the difference between the rates of synthesis and accumulation. The loss of ribosomes from gastrocnemius muscle and heart took place mainly between the 2nd and 4th days of insulin deficiency and was brought about largely by a very pronounced increase in the degradation rate, though synthesis also fell by a substantial amount. Rates of total tissue protein synthesis decreased markedly, but the degradation rates were only slightly elevated, if at all. Thus, the effect of diabetes on muscle ribosome breakdown was quite distinct from that on degradation of total tissue protein. In liver the response of protein synthesis to diabetes was much less pronounced than in muscle, and ribosome synthesis was not affected.     

Interactive effects of insulin and corticosterone on myofibrillar protein turnover in rats as determined by N tau-methylhistidine excretion.

The effects of graded doses of insulin and corticosterone on myofibrillar protein turnover were investigated in growing diabetic rats in order to assess their counteractive roles in the control of protein accretion. N tau-Methylhistidine excretion and carcass protein accretion were measured over 6 days in streptozotocin-diabetic rats receiving either a constant catabolic dose of corticosterone accompanied by graded doses of insulin or a constant dose of insulin accompanied by graded doses of corticosterone. The high corticosterone dose decreased the rate of protein accretion by both increasing the rate of degradation and decreasing the rate of synthesis. Increasing insulin dosage counteracted these effects, but could not restore positive accretion rates. Direct measurement of protein-synthesis rates gave results comparable with those obtained from use of N tau-methylhistidine excretion. At constant insulin dosage, increased corticosterone to 45 mg/kg body wt. per day caused a dose-related linear decrease in protein accretion rates from +4.5 to -3.2% per day. Growth ceased at 28 mg of corticosterone/kg body wt. per day, largely owing to a fall in synthesis rates (-3.5%/day) rather than the increase in degradation rates (+1.0%/day). However, at steroid doses greater than 30 mg/kg body wt. per day the degradation rate increased markedly and accounted for most of the additional fall in accretion. These results show that insulin antagonizes the action of glucocorticoids on both the synthesis and degradative pathways of myofibrillar protein turnover. The changes in fractional degradation rates appear relatively more attenuated by insulin than are those of synthesis.     

Time course of the effect of catabolic doses of corticosterone on protein turnover in rat skeletal muscle and liver.

The time course of the response of protein synthesis in muscle and liver to catabolic doses of corticosterone (10 mg/day per 100 g body wt.) was studied in vivo in growing rats over a 12-day period. The rate of protein synthesis in muscle and liver and the rate of actomyosin synthesis in muscle were measured by the phenylalanine-flooding technique, and 3-methylhistidine (N tau-methylhistidine) synthesis was measured by injection of labelled histidine. 3-Methylhistidine concentrations in tissue free pools and urinary excretion were also measured to compare directly with the rate of muscle protein degradation determined as the difference between synthesis and growth each day during the treatment. The overall rate of protein synthesis in muscle fell gradually over the first 4 days, reaching a rate after 5 days that was 36% of the initial rate, and this lower rate was then maintained for the following week. This decrease in the overall rate was accompanied with changes in the relative rate of synthesis in muscle proteins, since during the first 4 days there was a disproportionate decrease in the rate of actomyosin synthesis, and specifically 3-methylhistidine synthesis. In the latter case the synthesis rate was decreased to only 4% of its initial rate after 4 days. These changes in protein synthesis in muscle were accompanied by a transient increase in the rate of protein degradation, which was more than doubled on days 2 and 3 of treatment but which returned to the original rate on day 5, and a similar pattern of response was indicated by urinary 3-methylhistidine excretion, which also exhibited a transient increase. Thus in this case 3-methylhistidine excretion and measured rates of protein degradation in muscle do correlate. The transient effects of the glucocorticoids on degradation compared with the sustained effect on synthesis suggest that these two responses are achieved by different mechanisms. The hepatic size and protein mass were increased by the treatment, and protein synthesis was well maintained until after 12 days, when the rate was suppressed. Although the fractional synthesis rate was transiently increased for 24 h, it is argued that the enlarged liver most likely reflects a decrease in protein degradation resulting from the increased amino acid supply to the liver. This would result from the cessation of muscle growth while dietary supply was maintained.     

Osmotic regulation of aldose reductase protein synthesis in renal medullary cells

Renal medullary cells are normally exposed to high extracellular NaCl as part of the urinary concentrating mechanism. They react to this stress by accumulating sorbitol and other organic osmolytes. PAP-HT25, a line of epithelial cells derived from rabbit renal inner medulla, expresses this response. In hypertonic medium, these cells accumulate large amounts of sorbitol. There is a large increase in the amount of aldose reductase, which catalyzes production of sorbitol from glucose. The purpose of the present study was to investigate whether the aldose reductase protein increases because of faster synthesis or slower degradation. We measured the rate of synthesis and degradation of aldose reductase protein by pulse-chase with [35S]methionine, followed by immunoprecipitation with specific antiserum and autoradiography. The protein synthesis rate was 6 times greater in cells grown in hypertonic (500 mosmol/kg) medium, than in those grown in normal (300 mosmol/kg) medium. When control cells were switched to hypertonic medium, the synthesis rate increased 15-fold by 24 h, then decreased to 11-fold after 48 h. In contrast, synthesis rate continued to increase past 24 h when accumulation of sorbitol was prevented by inhibiting aldose reductase activity with Tolrestat. Thus, there is a feedback mechanism by which cellular sorbitol accumulation inhibits aldose reductase protein synthesis. Degradation of aldose reductase protein was slow (only about 25% in 3 days) and was not affected by osmolality. Thus, the osmoregulatory increase in aldose reductase protein is due to an increase in its synthesis rate and not to any change in its degradation.     

Developmental regulation of rat lung Cu,Zn-superoxide dismutase.

In the present investigation we found that lung Cu,Zn-superoxide dismutase (SOD) activity (units/mg of DNA) increases steadily in the rat from birth to adulthood. The specific activity (units/micrograms of enzyme) of Cu,Zn-SOD was unchanged from birth to adulthood, excluding enzyme activation as a mechanism responsible for the increase in enzyme activity. Lung synthesis of Cu,Zn-SOD peaked at 1 day before birth and decreased thereafter to adult values. Calculations, based on rates of Cu,Zn-SOD synthesis and the tissue content of the enzyme, indicated that lung Cu,Zn-SOD activity increased during development owing to the rate of enzyme synthesis exceeding its rate of degradation by 5-10%. These calculations were supported by measurements of enzyme degradation in the neonatal (half-life, t1/2, = 12 h) and adult lung (t1/2 = greater than 100 h); the difference in half-life did not reflect the rates of overall protein degradation in the lung, since these rates were not different in lungs from neonatal and adult rats. We did not detect differences in the Mr or pI of Cu,Zn-SOD during development, but the susceptibility of the enzyme to inactivation by heat or copper chelation decreased with increasing age of the rats. We conclude that the progressive increase in activity of Cu,Zn-SOD is due to a rate of synthesis that exceeds degradation of the enzyme. The data also suggest that increased stabilization of enzyme conformation accounts for the greater half-life of the enzyme in lungs of adult compared with neonatal rats.     

The rate of protein degradation in developing brain. Methodological considerations.

Recently we reported that the rate of protein breakdown decreases during development. Breakdown rates were calculated from the rates of protein synthesis and the changes in brain protein content with age. A different study, measuring breakdown by monitoring the loss of label from brain protein after an H14CO3- pulse, came to the opposite conclusion: that the rate of breakdown is low in immature brain and increases during development. We have now investigated some of the factors (the distribution of label in protein and the potential for recycling) that might introduce errors into these measurements. The specific radioactivities of both protein-bound and free amino acids were determined in the brains of young rats several days after an intraperitoneal pulse of H14CO3-. For a number of amino acids the specific radioactivity of the free amino acid is high compared with that of the protein-bound amino acid, and therefore recycling could result in an underestimate of the degradation rate. Because glutamic acid had a relatively low specific-radioactivity ratio, [1-14C]glutamic acid was used in a pulse-labelling experiment to measure degradation. The rate so obtained, 0.6% . h-1, is twice the rate found with H14CO3- labelling (based on total protein-bound radioactivity). Insofar as recycling is a possible complication, 0.6% . h-1 may be a minimum value. Although somewhat higher degradation rates are found after labelling with an intracranial pulse, which was considered as a possible route to limit recycling, there are difficulties in interpreting these data.     

The effect of insulin and intermittent mechanical stretching on rates of protein synthesis and degradation in isolated rabbit muscle.

Tyrosine balance and protein synthesis were studied during the same incubation in isolated rabbit forelimb muscles. From these measurements, protein degradation was calculated. Isolated muscles were usually in a state of negative amino acid balance, principally as a result of the 75% decrease in protein synthesis. Muscles from rabbits starved for 18 h had lower rates of both protein synthesis and degradation compared with muscles from normally fed rabbits. Intermittent mechanical stretching and the addition of insulin at 100 microunits/ml increased rates of both protein synthesis and degradation. Increases in the rate of protein synthesis were proportionately greater in the muscles from starved animals. In muscles from both fed and starved donors, increases in protein-synthesis rates owing to intermittent stretching and insulin were proportionately greater than the increases in degradation rates. For example, insulin increased the rate of protein synthesis in the muscles from starved donors by 111% and the rate of degradation by 31%. Insulin also increased the rate of protein synthesis when added at a higher concentration (100 munits/ml); at this concentration, however, the rate of protein degradation was not increased. The suppressive effect of insulin on high rates of protein degradation in other skeletal-muscle preparations may reflect a non-physiological action of the hormone.     

Protein turnover and proliferation. Turnover kinetics associated with the elevation of 3T3-cell acid-proteinase activity and cessation of net protein gain.

1. At least 95% of the total protein of A31-3T3 cell cultures undergoes turnover. 2. First-order exponential kinetics were used to provide a crude approximation of averaged protein synthesis, Ks, degradation, Kd, and net accumulation, Ka, as cells ceased growth at near-confluent density in unchanged Dulbecco's medium containing 10% serum. The values of the relationship Ka = Ks - Kd were : 5%/h = 6%/h - 1%/h in growing cells, and 0%/h = 3%/h - 3%/h in steady-state resting cells. 3. As determined by comparison of the progress of protein synthesis and net protein accumulation, the time course of increase in protein degradation coincided with the onset of an increase in lysosomal proteinase activity and decrease in thymidine incorporation after approx. 2 days of exponential growth. 4. After acute serum deprivation, rapid increases in protein degradation of less than 1%/h could be superimposed on the prevailing degradation rate in either growing or resting cells. The results indicate that two proteolytic mechanisms can be distinguished on the basis of the kinetics of their alterations. A slow mechanism changes in relation to proliferative status and lysosomal enzyme elevation. A prompt mechanism, previously described by others, changes before changes in cell-cycle distribution or lysosomal proteinase activity. 5. When the serum concentration of growing cultures was decreased to 1% or 0.25%, then cessation of growth was accompanied by a lower steady-state protein turnover rate of 2.0%/h or 1.5%/h respectively. When growth ceased under conditions of overcrowded cultures, or severe nutrient insufficiency, protein turnover did not attain a final steady state, but declined continually into the death of the culture.