Balancing of mitochondrial and glycolytic ATP production and of the ATP-consuming processes of Ehrlich mouse ascites tumour cells in a high phosphate medium

A balance of energy budgeting of Ehrlich mouse ascites tumour cells including mitochondrial and glycolytic ATP production and about 80% of ATP consumption in a high phosphate medium is presented. In the share of glycolysis was about one-third of the total ATP production, more than twice that found in a low phosphate medium. The extent of a single energy reaction was assessed from the decrease of coupled oxygen consumption and lactate formation following the specific inhibition of this process. The inhibitory effects on coupled respiration and glycolysis were identical for the energy consuming processes measured: protein turnover, Na+/K(+)-ATPase, Ca2(+)-transport and RNA synthesis.     

Importance of glycolysis for the energetics of anoxia-tolerant and anoxia-intolerant teleost hepatocytes

The importance of glycolysis, as an ATP-producing and substrate-providing pathway, was studied in anoxia-tolerant (goldfish) and anoxia-intolerant (trout) hepatocytes. Inhibition of glycolysis with iodoacetic acid (IAA) left aerobic ATP production largely unaffected in hepatocytes from both species but caused a significant decrease of ATP contents in the goldfish cells. Ouabain-sensitive oxygen consumption (osVo2), an estimate of mitochondrial ATP production coupled to ATP consumption by the Na(+) pump, was significantly reduced in IAA-treated goldfish hepatocytes, whereas it was unaltered in trout hepatocytes. Partial reduction of mitochondrial respiration, achieved by titration with cyanide (CN), strongly stimulated glycolytic flux but did not affect ATP contents of hepatocytes from both species. Under these conditions, osVo2 became undetectable. Rb(+)-uptake rates, providing a direct estimate of Na(+)-pump activity, were in good agreement with estimates derived from osVo2 in IAA-treated cells, showing a decrease in goldfish and no change in trout. However, they indicated persistent Na(+)-pump activity despite the lack of osVo2 in CN-treated cells. Overall, these data indicate that in goldfish hepatocytes Na(+)-pump activity is more dependent on glycolytic ATP production as compared to trout hepatocytes. Protein synthesis of goldfish hepatocytes was inhibited in IAA- and CN-treated cells, possibly reflecting the hierarchical organization of energy metabolism. In trout hepatocytes, protein synthesis could be sustained at control levels, given that energetic substrate provision was not limited.     

ConA induced changes in energy metabolism of rat thymocytes

The influence of ConA on the energy metabolism of quiescent rat thymocytes was investigated by measuring the effects of inhibitors of protein synthesis, proteolysis, RNA/DNA synthesis, Na⁺K⁺-ATPase, Ca²⁺-ATPase and mitochondrial ATP synthesis on respiration. Only about 50% of the coupled oxygen consumption of quiescent thymocytes could be assigned to specific processes using two different media. Under these conditions the oxygen is mainly used to drive mitochondrial proton leak and to provide ATP for protein synthesis and cation transport, whereas oxygen consumption to provide ATP for RNA/DNA synthesis and ATP-dependent proteolysis was not measurable. The mitogen ConA produced a persistent increase in oxygen consumption by about 30% within seconds. After stimulation more than 80% of respiration could be assigned to specific processes. The major oxygen consuming processes of ConA-stimulated thymocytes are mitochondrial proton leak, protein synthesis and Na⁺K⁺-ATPase with about 20% each of total oxygen consumption, while Ca²⁺-ATPase and RNA/DNA synthesis contribute about 10% each. Quiescent thymocytes resemble resting hepatocytes in that most of the oxygen consumption remains unexplained. In contrast, the pattern of energy metabolism in stimulated thymocytes is similar to that described for Ehrlich Ascites tumour cells and splenocytes, which may also be in an activated state. Most of the oxygen consumption is accounted for, so the unexplained process(es) in unstimulated cells shut(s) off on stimulation.     

ConA induced changes in energy metabolism of rat thymocytes

The influence of ConA on the energy metabolism of quiescent rat thymocytes was investigated by measuring the effects of inhibitors of protein synthesis, proteolysis, RNA/DNA synthesis, Na⁺K⁺-ATPase, Ca²⁺-ATPase and mitochondrial ATP synthesis on respiration. Only about 50% of the coupled oxygen consumption of quiescent thymocytes could be assigned to specific processes using two different media. Under these conditions the oxygen is mainly used to drive mitochondrial proton leak and to provide ATP for protein synthesis and cation transport, whereas oxygen consumption to provide ATP for RNA/DNA synthesis and ATP-dependent proteolysis was not measurable. The mitogen ConA produced a persistent increase in oxygen consumption by about 30% within seconds. After stimulation more than 80% of respiration could be assigned to specific processes. The major oxygen consuming processes of ConA-stimulated thymocytes are mitochondrial proton leak, protein synthesis and Na⁺K⁺-ATPase with about 20% each of total oxygen consumption, while Ca²⁺-ATPase and RNA/DNA synthesis contribute about 10% each. Quiescent thymocytes resemble resting hepatocytes in that most of the oxygen consumption remains unexplained. In constrast, the pattern of energy metabolism in stimulated thymocytes is similar to that described for Ehrlich Ascites tumour cells and splenocytes, which may also be in an activated state. Most of the oxygen consumption is accounted for, so the unexplained process(es) in unstimulated cells shut(s) off on stimulation.     

The epithelial Na(+) channel (ENaC) is related to the hypertonicity-induced Na(+) conductance in rat hepatocytes

The epithelial Na(+) channel (ENaC) is composed of the subunits alpha, beta, and gamma [Canessa et al., Nature 367 (1994) 463-467] and typically exhibits a high affinity to amiloride [Canessa et al., Nature 361 (1993) 467-470]. When expressed in Xenopus oocytes, conflicting results were reported concerning the osmo-sensitivity of the channel [Ji et al., Am. J. Physiol. 275 (1998) C1182-C1190; Hawayda and Subramanyam, J. Gen. Physiol. 112 (1998) 97-111; Rossier, J. Gen. Physiol. 112 (1998) 95-96]. Rat hepatocytes were the first system in which amiloride-sensitive sodium currents in response to hypertonic stress were reported [Wehner et al., J. Gen. Physiol. 105 (1995) 507-535; Wehner et al., Physiologist 40 (1997) A-4]. Moreover, all three ENaC subunits are expressed in these cells [B?hmer et al., Cell. Physiol. Biochem. 10 (2000) 187-194]. Here, we injected specific antisense oligonucleotides directed against alpha-rENaC into single rat hepatocytes in confluent primary culture and found an inhibition of hypertonicity-induced Na(+) currents by 70%. This is the first direct evidence for a role of the ENaC in cell volume regulation.     

Altered responses of regenerating hepatocytes to norepinephrine and transforming growth factor type beta

Norepinephrine (NE), acting through the alpha 1-adrenergic receptor, modules the response of rat hepatocytes in primary culture to transforming growth factor type beta 1 (TGF beta) by increasing the amount of TGF beta required for a given degree of inhibition of epidermal growth factor (EGF)-induced DNA synthesis (Houck et al., J. Cell. Physiol. 135:551-555, 1988). This effect was also found in hepatocytes isolated from regenerating livers but was greatly magnified in cells isolated between 12 and 18 hr after two-thirds partial hepatectomy (PHX). During this period of enhanced sensitivity, NE was equally potent in terms of dose but more efficacious in the regenerating hepatocytes. As it did in control hepatocytes (Cruise et al., Science 227:749-751, 1985), the alpha 1-adrenergic receptor mediated the activity of NE in regenerating hepatocytes. Vasopressin (VP) and angiotensin-II (AG) also antagonized the effect of TGF beta and showed increased activity in regenerating hepatocytes but at only 50% or less of the maximal effect reached by NE. Regenerating hepatocytes isolated 24-72 hr after PHX exhibited decreased sensitivity to inhibition by TGF beta, with a nadir in 48-hr-regenerating cells. These findings suggest that NE may be involved in triggering the early phase of DNA synthesis during liver regeneration, with the subsequent acquisition of innate resistance to TGF beta responsible for continued proliferation at a time when TGF beta mRNA is known to be increasing in the liver (Braun et al., Proc. Natl. Acad. Sci. USA 85:1539-1543, 1988). EGF induced increased DNA and protein synthesis in cultures of control hepatocytes; TGF beta inhibited the EGF-induced DNA synthesis but had no effect on protein synthesis. This may be relevant to the latter stages of liver regeneration, when high levels of TGF beta mRNA are detected in liver and cellular hypertrophy predominates over hyperplasia.     

Control of hepatocyte DNA synthesis by intracellular pH and its role in the action of tumor promoters

The mechanisms of tumor promotion in liver by various xenobiotics of diverse structure are not well understood. However, these tumor promoters share the ability to exert growth-stimulatory effects on hepatocytes. Our laboratory has been utilizing normal rat hepatocytes under defined conditions of primary cultures, to investigate growth-stimulatory actions of liver tumor promoters. We have shown that most, if not all, of the liver tumor promoters tested stimulate hepatocyte DNA synthesis when added in combination with epidermal growth factor (EGF), insulin, and glucocorticoids. In the present study, we sought evidence for the role of the Na(+)/H(+) antiporter and cytoplasmic alkalinization in the direct growth-stimulatory actions of tumor promoters on hepatocytes. Hepatocytes cultured under conditions (bicarbonate-buffered medium) where intracellular pH (pH(i)) was independent of extracellular pH (pH(e)), EGF- and insulin-stimulated rates of DNA synthesis were unaffected by modest changes in pH(e). However, under conditions (HEPES-buffered medium) where pH(i) varied in a linear fashion with pH(e), rates of EGF- and insulin-stimulated DNA synthesis were highly dependent on pH(e). Similarly, 12-O-tetradecanoylphorbol-13-acetate (TPA) and alpha-hexachlorocyclohexane (HCH)-stimulated DNA synthesis were pH(e)-dependent but were stimulatory over different pH(e) ranges, suggesting that these promoters may act by distinct mechanisms. Chemicals that are capable of inducing rapid cytoplasmic alkalinization, ammonium chloride (1 and 15 mM) and monensin (0.5 microM), were found to stimulate hepatocyte DNA synthesis. The role of the Na(+)/H(+) antiport in controlling pH(i) of hepatocytes was demonstrated by artificially acidifying 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein acetoxymethyl (BCECF)-loaded isolated hepatocytes with 20 mM sodium acetate and the use of specific inhibitors. Amiloride and its analogues inhibited pH(i) recovery from the acid load in a dose dependent manner and the relative potency of these inhibitors paralleled their K(i) values for the Na(+)/H(+) antiport. At concentrations that stimulate hepatocyte DNA synthesis, some liver tumor promoters phenobarbital (PB) and HCH, were found to cause a rapid rise pH(i) in isolated hepatocytes which was sensitive to amiloride and its analogues. Taken together, our data suggest that activation of Na(+)/H(+) antiport activity may be one mechanism whereby some liver tumor promoters stimulate hepatocytes DNA synthesis. This study has implications for the mechanisms of tumor promotion in liver carcinogenesis.     

Transcriptome analyses reveal molecular mechanisms underlying phenotypic differences among transcriptional subtypes of glioblastoma

Using molecular signatures, previous studies have defined glioblastoma (GBM) subtypes with different phenotypes, such as the proneural (PN), neural (NL), mesenchymal (MES) and classical (CL) subtypes. However, the gene programmes underlying the phenotypes of these subtypes were less known. We applied weighted gene co-expression network analysis to establish gene modules corresponding to various subtypes. RNA-seq and immunohistochemical data were used to validate the expression of identified genes. We identified seven molecular subtype-specific modules and several candidate signature genes for different subtypes. Next, we revealed, for the first time, that radioresistant/chemoresistant gene signatures exist only in the PN subtype, as described by Verhaak et al, but do not exist in the PN subtype described by Phillips et al PN subtype. Moreover, we revealed that the tumour cells in the MES subtype GBMs are under ER stress and that angiogenesis and the immune inflammatory response are both significantly elevated in this subtype. The molecular basis of these biological processes was also uncovered. Genes associated with alternative RNA splicing are up-regulated in the CL subtype GBMs, and genes pertaining to energy synthesis are elevated in the NL subtype GBMs. In addition, we identified several survival-associated genes that positively correlated with glioma grades. The identified intrinsic characteristics of different GBM subtypes can offer a potential clue to the pathogenesis and possible therapeutic targets for various subtypes.     

Respiratory energy demand for protein turnover and ion transport in wheat leaves upon water deficit

The effect of water stress on the respiratory energy demand for the main biosynthetic and transport processes was estimated in the leaves of spring wheat ( Triticum aestivum L. cv. San Pastore) acclimated and non-acclimated to drought. ATP-consuming processes were assessed from the effects of selective inhibitors of RNA synthesis, protein synthesis and proteolysis, Ca²⁺-ATPase and P-type ATPases on respiration. The proportions of energy consumed by these processes were compared with the theoretical ATP production calculated from the rate of oxygen consumption measured manometrically. Respiratory energy production increased significantly in both acclimated leaves and in leaves stressed by drought. In the fully grown wheat leaves, Ca²⁺-dependent reactions and protein turnover consumed about 37% and 34% of the total respiratory energy, respectively. The costs of ion transport constituted another 15% of the total ATP production. Both acclimation and drought stress in non-acclimated leaves resulted in a decrease of leaf sensitivity towards inhibitors of RNA and protein syntheses as well as a decrease in Ca²⁺-mediated processes; but also in an increase of leaf sensitivity towards inhibitors of proteolysis and ouabain-sensitive ATPase in non-acclimated plants. This indicates a shift in ATP input into the energy-requiring processes towards greater expenses for ion transport upon water deficit. However, in acclimated leaves under drought stress, distribution of respiratory energy became almost the same as in control plants.     

Energy metabolism and ATP turnover time during the cell cycle of Ehrlich ascites tumour cells

The energy production in different parts of the cell cycle due to aerobic and aerobic glycolytic metabolism and ATP turnover time was estimated by measuring the oxygen consumption, lactate-pyruvate and ATP content of Ehrlich ascites tumour cells growing in vivo. Cell fractions of high purity from the various parts of the cell cycle were obtained by means of elutriator centrifuging. The total energy production for one cell cycle was estimated to be 19 × 10^?12 mol ATP, 60% of which was due to the aerobic metabolism. Whereas the total ATP production is unchanged during G1 a fairly exponential increase is found during the S and G2 + M phases. The total cellular ATP content increases from 12 fmol ATP at early G1 to 28 fmol ATP at G2 + M; this increase, however, is discontinuous and is most pronounced during G1 and during late S phase S phase/G2 + M. The ATP turnover time, as defined as the ratio between ATP content and ATP production, was found to increase significantly from 75 sec in early G1 to 120 sec in late G1 but was constantly 100 sec during the early, middle and late S phase as well as G2 + M. These variations indicate maximum energy-requiring processes during early G1 period of the cell cycle and are discussed in relation to K⁺Na⁺ flux and macromolecule synthesis.     

Effects of ethanol on protein metabolism in hepatocyte primary cultures from adult rat

The effect of ethanol on protein synthesis and degradation in cultured hepatocytes from adult rat has been studied. The presence of 100 mM ethanol in the culture medium significantly decreased protein synthesis without affecting protein degradation rate. The depressing effect of ethanol on protein synthesis did not appear directly correlated with the changes in ATP level. However, an inhibition of sodium-dependent and energy-requiring systems of the plasma membrane following exposure to ethanol was observed.     

Multiple requirements for glycogen synthesis by hepatocytes isolated from fasted rats

Glycogen synthesis from various combinations of substrates by hepatocytes isolated from rats fasted 24 h was studied. As reported by Katz et al. (Katz, J., Golden, S., and Wals, P. A. (1976) Proc. Natl. Acad. Sci. U. S. A. 73, 3433-3437), appreciable rates of glycogen synthesis occurred only in the presence of gluconeogenic precursors and one of several amino acids, which includes L-glutamine. L-Leucine had negligible effects on glycogen synthesis from 20 mM dihydroxyacetone and/or 15 mM glucose when L-glutamine was not added to the medium. In the presence of 10 mM L-glutamine, L-leucine greatly increased glycogen synthesis from these substrates. alpha-Ketoisocaproate was ineffective, as was oleate. NH4Cl depressed glycogen synthesis from 10 mM glucose plus 20 mM dihydroxyacetone in the absence of added L-glutamine and enhanced that in its presence, but these effects were weak compared to those of L-leucine. The amino acid analogues L-norvaline and L-norleucine exerted effects that were similar to those exerted by L-leucine. Under all conditions studied, cycloheximide and puromycin inhibited net glycogen synthesis. Cycloheximide did not stimulate gluconeogenesis from dihydroxyacetone, or phosphorylase in hepatocytes from starved rats, or glycogenolysis in hepatocytes from fed rats. Puromycin, however, stimulated glycogenolysis in hepatocytes from fed rats. Glycogen synthesis from 20 mM dihydroxyacetone proceeds with a pronounced initial lag phase that can be shortened by incubation of cells with glutamine plus leucine before addition of dihydroxyacetone. Concurrent measurements of glycogen synthesis, glycogen synthase, and gluconeogenesis under different conditions reveal that in addition to protein synthesis, activation of glycogen synthase, which must occur to allow glycogen synthesis in hepatocytes, requires a second component which can be satisfied by addition of dihydroxyacetone or fructose to the cells.     

Characterization of the effects of human placental HGF on rat hepatocytes.

Hepatocyte growth factor (HGF) also known as hepatopoietin A (HPTA) (Michalopoulos, FASEB J., 4:176-187, 1990) is a heparin-binding growth factor whose characterization and tissue distribution have been reported elsewhere. This growth factor was recently cloned and its amino acid sequence determined under the name of hepatocyte growth factor (HGF) (Miyazawa et al., Biochem. Biophys. Res. Commun., 163:967-973, 1989; Zarnegar et al., Biochem. Biophys. Res. Commun., 163:1370-1376, 1989; Nakamura et al., Nature, 342:440-443, 1989). Human placenta is one of the tissues that contains significant amounts of HGF. We isolated HGF from human placenta and characterized its biologic effect on rat hepatocytes. Human placenta HGF was isolated in high purity as a single chain molecule. Single chain HGF stimulated DNA synthesis in primary rat hepatocyte cultures in serum-free medium. The maximal effect was seen at 5-10 ng/ml. The maximal response occurred at 25-48 hours after plating of the hepatocytes. Protein synthesis was also stimulated by HGF in primary rat hepatocyte cultures. There were peak responses at 19-24 and 37-42 hours after plating of the hepatocytes. TGF beta 1 inhibited more than 95% of HGF-induced DNA synthesis but only 25% of HGF-induced protein synthesis. HGF interacted in an additive manner with EGF, a well-known hepatocyte mitogen. There was not an additive interaction between HGF and aFGF. Regenerating liver hepatocytes obtained from rats which underwent two-thirds partial hepatectomies (PHX) also responded to HGF in a dose-dependent manner as the hepatocytes from normal liver.     

Ferric-salicylaldehyde isonicotinoyl hydrazone, a synthetic iron chelate, alleviates defective iron utilization by reticulocytes of the Belgrade rat

The Belgrade rat has a hypochromic, microcytic anemia inherited as an autosomal recessive mutation. Although transferrin binds normally to reticulocytes and internalizes normally, iron accumulation into cells and heme is much slower than normal. We have investigated the role of the transferrin cycle in this mutant by bypassing transferrin iron delivery with the iron chelate ferric salicylaldehyde isonicotinoyl hydrazone (Fe-SIH). Fe-SIH increases iron uptake into heme by Belgrade reticulocytes, restoring it almost to normal levels. This increase indicates that Fe-SIH delivers iron to a step in iron utilization that is after the Belgrade defect. Depleting reticulocytes of transferrin did not alter these observations. Failure to achieve above normal rates of iron incorporation could indicate damage due to chronic intracellular iron deficiency. Also, iron delivery by Fe-SIH restored globin synthesis to near-normal levels in Belgrade reticulocytes. The rates of glycine incorporation into porphyrin and heme in Belgrade reticulocytes incubated with Fe2-transferrin or Fe-SIH paralleled the rates of iron incorporation into heme. These data are consistent with the concept that iron availability limits protoporphyrin formation in rat reticulocytes. The protoporphyrin used for heme synthesis is provided by de novo synthesis and not by a pool of pre-existing protoporphyrin. The Belgrade defect occurs in the movement of iron from transferrin to a step prior to the ferrous state and insertion into heme. This defect diminishes the synthesis of heme and, consequently, that of protoporphyrin and globin.     

Effect of temperature on protein and immunoglobulin synthesis and secretion in two mouse myeloma cell lines

Protein synthesis in differentiated MOPC-21 and MPC-11 mouse myeloma cells was studied to determine the basis for the differences in the temperature and actinomycin D sensitivity of translation between non-differentiated mouse L-cells and differentiated rabbit reticulocytes. The temperature dependence of total protein synthesis was similar to that of L-cells and reticulocytes, being biphasic in Arrhenius plots with apparent activation energies of approximately 25 and 42 kcal/mol, above and below 25 degress C. The dependence of the secretion process was different since it was not biphasic, having a single activation energy of about 22 kcal/mol. Myeloma polysomes were like L-cell polysomes in their response to lower temperature and reached a minimum level of 50% at 15 degress C. This response was also found for the specific polysomes synthesizing the IgG H- and L-chains. In the presence of actinomycin D, myeloma polysomes declined exponentially with a half-life of approximately 6 hours. These two L-cell-like responses were not found in reticulocytes. Translation of both the IgG mRNAs and the non-IgG mRNAs was reduced by lower temperatures and actinomycin D, even though the L-chain mRNA was slightly more resistant, suggesting that this mRNA is slightly more efficient. The results of these experiments suggest that the translational differences between L-cells and reticulocytes are not mRNA dependent, but are cell type differences.     

Microscopic kinetics and energetics distinguish GABA(A) receptor agonists from antagonists

Although agonists and competitive antagonists presumably occupy overlapping binding sites on ligand-gated channels, these interactions cannot be identical because agonists cause channel opening whereas antagonists do not. One explanation is that only agonist binding performs enough work on the receptor to cause the conformational changes that lead to gating. This idea is supported by agonist binding rates at GABA(A) and nicotinic acetylcholine receptors that are slower than expected for a diffusion-limited process, suggesting that agonist binding involves an energy-requiring event. This hypothesis predicts that competitive antagonist binding should require less activation energy than agonist binding. To test this idea, we developed a novel deconvolution-based method to compare binding and unbinding kinetics of GABA(A) receptor agonists and antagonists in outside-out patches from rat hippocampal neurons. Agonist and antagonist unbinding rates were steeply correlated with affinity. Unlike the agonists, three of the four antagonists tested had binding rates that were fast, independent of affinity, and could be accounted for by diffusion- and dehydration-limited processes. In contrast, agonist binding involved additional energy-requiring steps, consistent with the idea that channel gating is initiated by agonist-triggered movements within the ligand binding site. Antagonist binding does not appear to produce such movements, and may in fact prevent them.     

Effects of amino acids, ammonia and leupeptin on protein synthesis and degradation in isolated rat hepatocytes.

Protein synthesis in isolated rat hepatocytes, as measured by the incorporation of [14C]-valine at constant specific radioactivity, proceeded at a rate of 0.3-0.5%/h in an unsupplemented medium, i.e. only about one-tenth the rate of protein degradation (4%/h). Leupeptin, which inhibits lysosomal protein degradation (previously found to be 75% of the total degradation in hepatocytes), had no effect on protein synthesis, showing that endogenous protein degradation supplied amino acids in excess of the substrate requirements for protein synthesis. The inhibition of protein synthesis by NH4Cl (another inhibitor of lysosomal protein degradation) as well as the stimulation by a physiological amino acid mixture must therefore represent indirect effects, either on general energy metabolism, or on unknown regulatory processes.     

Analysis of effect of age on synthesis of specific proteins by hepatocytes

The effect of age on the synthesis of specific proteins by hepatocytes was studied in Fischer F344 rats using two-dimensional polyacrylamide gel electrophoresis. Almost all proteins synthesized by hepatocytes from young rats were synthesized by hepatocytes isolated from old rats. Of over 500 proteins visually compared by two-dimensional polyacrylamide gel electrophoresis, only 11 proteins were observed to disappear and/or appear consistently with increasing age. The rates of synthesis of 36 randomly chosen proteins were quantified. Interestingly, the synthesis of 35 of the 36 proteins decreased between 5 and 30 months of age. The decrease in protein synthesis varied (15% to 70%) from one protein to another; i.e., a heterogeneity was observed in the age-related decrease in the synthesis of proteins. The age-related decrease in protein synthesis was statistically significant for 53% of the proteins studied. The total decrease in the rate of synthesis of all 36 proteins studied was 40% between 5 and 30 months of age, which is essentially the same as the decrease in total protein synthesis by suspension of hepatocytes isolated from 5- and 30-month-old rats. The results of this study demonstrate that the mechanism underlaying aging is different from development, which is characterized by a major change in the species of proteins synthesized by a cell.