Translational control of immunoglobulin synthesis: II. Cell-free interaction of myeloma immunoglobulin with mRNA

Repression of heavy chain synthesis by myeloma protein has been demonstrated (Stevens & Williamson, 1973) and shown to result from an interaction of the myeloma protein molecule with the H-chain² mRNA.Oocytes from Xenopus laevis, when injected with polyribosomes from myeloma cells and increasing amounts of H₂L₂ protein, were shown to produce decreasing amounts of H-chain protein in the presence of increasing amounts of H₂L₂. This repression of H-chain synthesis was shown to result from the interaction of H₂L₂ with the added mRNA and not with mRNA-associated proteins. Under proper conditions of temperature and salt concentration, a population of mRNA molecules specifically and reversibly binds to H₂L₂ protein. This RNA was shown to contain sequences coding for H-chain protein when assayed by injection into oocytes.     

L-asparaginase synthesis by Escherichia coli B

We have studied the influence of strain of organism, temperature, and medium on the production of the antileukemic intracellular enzyme L-asparaginase by E. coli B grown in shaken flasks. Five strains of E. coli B exhibited wide differences in their capacities to synthesize the EC-2 form of L-asparaginase active against leukemia. For the most productive strain, when grown in a casein hydrolysate medium, maximal production of L-asparaginase occurred at 25°C. At this temperature, the organism required glycerol, glucose, or other mono-saccharides to synthesize L-asparaginase. Synthesis was stimulated when glycerol was used in place of glucose, but not in its presence. The effect of glycerol on L-asparaginase synthesis was most evident when the cells were grown at 37°C, rather than at 25°C. With 0.25% glucose, cells had a specific activity of 409 I.U./g; with glycerol cells had a specific activity of 553 I.U./g. At 25°C, both cell and L-asparaginase synthesis were increased by the use of 0.25% glycerol resulting in only a slight increase in specific activity of the cells. The addition of zinc, copper, manganese, iron, L-asparagine, L-glutamine, or L-aspartic acid had no effect on L-asparaginase synthesis in the casein hydrolysate medium. L-aspartic acid (10^?2 M) enhanced L-asparaginase synthesis in a synthetic medium that lacked these metals or L-asparagine, L-glutamine, or L-aspartic acid; cells grown under these conditions had a specific activity of 90 I.U./g. In the casein hydrolysate medium, cell morphology was correlated with temperature of incubation.     

Hydrophobic interaction of P25, containing Asn-linked oligosaccharide chains, with the H-L complex of silk fibroin produced by Bombyx mori.

Fibroin light (L-) chain and P25 are low molecular weight protein components of silk fibroin which are secreted from the posterior silk gland cells of the silkworm, Bombyx mori. The primary structure of L-chain was determined previously by cDNA cloning and peptide analysis, but that of P25 has only been deduced from its genomic sequence. Our previous studies with specific antibodies against L-chain and P25 have shown that L-chain and H-chain are linked by disulfide bond(s) but P25 is not covalently linked to H-chain. Here, we present evidence that P25 associates with the H-L complex primarily by hydrophobic interactions and that P25 is a glycoprotein containing Asn-linked oligosaccharide chains. From the analysis of three fibroin-secretion-deficient 'naked pupa' mutant breeds [Nd(2), Nd-s and Nd-sD], it is suggested that P25 interacts with H-chain in the absence of H-L linkage but its content of oligosaccharide is reduced when the H-L linkage is not formed. From these results, models are presented implying that the H-L complex and P25 are associated to form a higher-order complex of specific conformation during the processes of intracellular transport and secretion, and that the Asn-linked glycosylation of P25 is partially altered under such conditions.     

Temperature sensitivity of protein synthesis initiation in reticulocyte cell-free systems. A ribosomal factor which protects protein synthesis inactivation at elevated temperatures.

Inactivation of protein synthesis in the reticulocyte lysate system, which occurs when the system is incubated at 42 °C, was prevented by a high concentration KCl extract of the ribosomes. The KCl extract also supported protein synthesis at 42 °C by KCl-washed ribosomes. Three factor fractions (IF.15, IF.2, and IF.25) were separated from the extract and characterized in partial reactions of initiation. The factor IF.2 could prevent the inactivation of the factor IF.15-promoted protein synthesis by the washed ribosomes at 42 °C. IF.2 also overcame the decrease in IF.15-promoted 40S subunit-Met-tRNA_f complex at 42 °C. The protective activity of IF.2 was inactivated by N-ethylmaleimide. The activities of IF.15 and IF.2 were little affected by heating the factors at 42 °C. However, prewarming of KCl-washed ribosomes at 42 °C caused decreased protein synthesis in subsequent incubation at 34 °C with unwarmed factors. These results suggest that some components other than the initiation factors may be inactivated at 42 °C, which is prevented by IF.2 in the course of protein synthesis.     

Nucleotide pools of Novikoff rat hepatoma cells growing in suspension culture. II. Independent snucleotide pools for nucleic acid synthesis

Novikoff rat hepatoma cells (subline NlSl-67) in suspension culture incorporate ³H-5-uridine into the acid-soluble nucleotide pool more rapidly than into RNA, resulting in the accumulation of labeled UTP in the cells. When labeled uridine is removed from the medium after 20 minutes or 4.75 hours of labeling, the rate of incorporation of label from the nucleotide pool into RNA decreases to less than 10% of the original rate within five to ten minutes, in spite of the presence of a large pool of labeled UTP in the cells, and incorporation ceases completely if an excess of unlabeled uridine is present during the chase. Upon addition of ¹⁴C-uridine to ³H-uridine pulse-labeled, chased cells, the ¹⁴C begins to be incorporated into RNA without delay and at a rate predetermined by the concentration of ¹⁴C-uridine in the medium and without affecting the fate of the free ³H-nucleotides labeled during the pulse-period. The results are interpreted to indicate that uridine is incorporated into at least two different pools, only one of which serves as primary source of nucleotides for RNA synthesis. During active synthesis of RNA, the latter pool of free nucleotides is very small and rapidly exhausted when uridine is removed from the medium. However, UTP accumulates in this pool when cells are labeled at 4–6°, since at this temperature RNA synthesis is blocked while uridine is still phosphorylated by the cells, and the UTP is rapidly incorporated into RNA during a subsequent ten-minute chase at 37°. From these types of experiments it is estimated that only 20–25% of the total uridine nucleotides formed in the cells from uridine in the medium is directly available for RNA synthesis and that the remainder becomes available only at a slow rate. Evidence is presented which suggests that one uridine nucleotide pool is located in the cytoplasm and another in the nucleus and that mainly the nuclear pool supplies nucleotides for RNA synthesis. The size of the latter pool is under strict regulatory control, since preincubation of the cells with 0.5 mM unlabeled uridine has little or no effect on the subsequent incorporation of ³H-uridine, although it results in an increase of the overall cellular uridine nucleotide content to at least 5 mM. Other results indicate that adenosine is also incorporated into two independent nucleotide pools, whereas the cells normally appear to possess a single thymidine nucleotide pool.     

Temperature sensitivity of protein synthesis initiation. Inactivation of a ribosomal factor by an inhibitor formed at elevated temperatures.

When a reticulocyte lysate, supplemented with hemin, was warmed at 42 °C, its protein-synthesizing activity was greatly decreased. This was accompanied by the reduced formation of the 40 S·Met-tRNA_f initiation complex. This complex preformed at 34 °C, however, was stable and combined with added globin mRNA and the 60 S ribosomal subunit to form the 80 S complex at the elevated temperature. When the ribosome-free supernatant fraction of lysates was warmed at 42 °C with hemin and then added to the fresh lysate system, it inhibited protein synthesis by decreasing the formation of the 40 S complex. This decrease in protein synthesis by warmed lysates or warmed supernatant could be overcome by high concentrations of GTP and cyclic AMP. This effect of GTP and cyclic AMP was antagonized by ATP. The results indicate that the inactivation of protein synthesis by the lysate warmed at 42 °C is due to the formation of an inhibitor in the supernatant. The ribosomal KCl extract prepared from the lysate that had been warmed at 34 °C and then incubated at this temperature for protein synthesis supported protein synthesis by the KCl-washed ribosome at both 34 and 42 °C. On the contrary, the extract from lysates that had been warmed at 42 °C and then incubated at 34 °C could not support protein synthesis at 42 °C, although it was almost equally as promotive as the control extract in supporting protein synthesis at 34 °C. The results indicate that the factor which can protect protein synthesis against inactivation at 42 °C is itself inactivated in lysates warmed at 42 °C. However, the activity of this extract to support formation of the ternary complex with Met-tRNA_f and GTP was not reduced. Native 40 S ribosomal subunits isolated from lysates that had been warmed at 42 °C and then incubated for protein synthesis indicated that the quantity of subunits of density 1.40 g/cm³ in a CsCl density gradient were decreased while those of density 1.49 g/cm³ were increased. The factor-promoted binding of Met-tRNA_f to the 40 S subunit of lower density from the warmed and unwarmed lysates was equal, suggesting that the ribosomal subunit was not inactivated. These results were discussed in terms of the action of the inhibitor formed in the supernatant at 42 °C, which may inactivate a ribosomal factor essential for protein synthesis initiation.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

Effect of temperature on ion content, ion fluxes and energy metabolism in Chara corallina

Abstract Effects of temperature on the ionic relations and energy metabolism of Chara corallina were investigated. Measurements were made of the ionic content, tracer ion fluxes, and photosynthetic and dark CO₂ fixation in isolated cells, and of O₂ exchange in photosynthesis and respiration in isolated shoot apices. The total intracellular concentration of K⁺, Na⁺ and Cl^? was the same in cells held for 5 days in non-growing medium at 15°C (the growth temperature) as in those held at 25°C or 5°C. The tracer influx in the light of all ions tested (Rb⁺, Na⁺, CH₃NH₃⁺, Cl^? and H₂PO₄^?) was lower at 5°C than at 15°C in experiments in which cells were subjected to 5°C for less than 24 h in toto. The influx at 25°C was greater than that at 15°C for H₂PO^?₄, there was no difference between the two temperatures for Na⁺, while the influx at 25°C was less than that at 15°C for Cl^?, Rb⁺ and CH₃NH₃⁺ For Cl^? and H₂PO^?₄ similar results were found in later experiments with cells grown at 20—23°C. Photosynthetic CO₂ fixation and O₂ evolution, and respiratory O₂ uptake, are greater at 25°C, and lower at 5°C, than they are at the growth temperature of 15°C. In longer-term pretreatments at the different temperatures, tracer Cl^? influx at 15°C and particularly at 25°C were lower than in short-term experiments, while the influx at 5°C was higher. It was concluded from these experiments, and from previous data on H⁺ free energy differences across the plasmalemma, that (1) the maintenance of internal ion concentrations involves a close balancing of influx and efflux of K⁺, Na⁺ and Cl^? at all experimental temperatures; (2) the regulation of the tracer fluxes of the ions is kinetic rather than thermodynamic and (3) that the tracer fluxes at low temperatures are not restricted by the rate at which respiration or photosynthesis can supply energy to them.     

Phosphocreatine in Ehrlich ascites tumor cells detected by noninvasive 31P NMR spectroscopy

³¹P NMR spectra of intact Ehrlich ascites tumor cells of high phosphorylation potential reveal a well-defined resonance peak assignable to phosphocreatine, corresponding to 2.3 μmoles/ml cell H₂O in adenosine-treated cells containing 5.2 μmoles ATP/ml. The NMR spectrum of Ehrlich cells incubated with iodoacetate and glucose indicates depletion of phosphocreatine and ATP to undetectable levels and substantial accumulation of fructose-1,6-bisphosphate. From the difference between the chemical shifts of internal P_i and phosphocreatine resonances, the intracellular pH was estimated to be 7.1 ± 0.1 in protein-synthesizing cells suspended in a medium of pH 7.4 at 10°C. Ehrlich cells are unable to transfer the labeled amidine group from L-(guanidino-¹⁴C)-arginine to the large intracellular glycine pool to form labeled guanidinoacetate, the demethylated precursor of creatine. These results imply that the synthesis of phosphocreatine in ATP-rich Ehrlich cells is limited primarily by the extracellular free creatine supply, the extent of which depends upon the degree of cachectic perturbation of energy and nitrogen metabolism of the tumor-bearing host.     

Evidence for a nuclease in Saccharomyces cerevisiae that affects the cell-free translation of natural messenger RNA.

A postpolysomal extract of $\text{Saccharomyces}\text{cerevisiae}$, treated with micrococcal nuclease to remove endogenous mRNAs, translates exogenous natural and synthetic mRNA templates actively and accurately at 20°C. When the temperature of incubation is 30°C or higher, protein synthesis with yeast poly(A)⁺ mRNA is markedly reduced, but synthesis of polyphenyl-alanine with poly (U) is only slightly affected. The protein synthesizing activity of the extract is decreased 50% in 30 minutes at 37°C, while the ability of yeast mRNA to template for protein synthesis is decreased 50% in 5 to 7 minutes when it is incubated with the postpolysomal fraction at 37°C. The release of radioactivity from isotopically-labeled yeast mRNA, into the acid-soluble form, is also much greater at 37°C than at 20°C. Thus, at the elevated temperatures, the loss of mRNA templating activity and RNA hydrolysis occur more rapidly than the loss of activity of the translational apparatus. The evidence suggests that the failure of the extract to catalyze translation at 30°C or higher, as compared to 20°C, is due to a temperature-stimulated nuclease that degrades mRNA.     

Identification of a mechanism by which lens epithelial cells limit accumulation of overexpressed ferritin H-chain

The primary cultures of canine lens epithelial cells were transiently transfected with cDNAs for dog ferritin H- or L-chains in order to study differential expression of these chains. By using chain-specific antibodies, we determined that at 48 h after transfection overexpression of L-chain was much higher (9-fold over control) than that of H-chain (1.7-fold). We discovered that differentially transfected cells secrete overexpressed chains as homopolymeric ferritin into the media. Forty-eight hours after transfection accumulation of H-ferritin in the media was much higher (3-fold) than that of L-ferritin. This resulted in lowering of the concentration of H-chain in the cytosol. Co-transfection of cells with both H- and L-chain cDNAs increased the intracellular levels of H-chain and eliminated secretion of H-ferritin to the media. We concluded that lens epithelial cells differentially regulate concentration of both ferritin chains in the cytosol. The overexpressed L-chain accumulated in the cytosol as predominantly homopolymeric L-ferritin. This is in contrast to H-chain, which is removed to the media unless there is an L-chain available to form heteropolymeric ferritin. These data indicate that the inability of cells to more strictly control cytosolic levels of L-chain may augment its accumulation in lenses of humans with hereditary hyperferritinemia cataract syndrome, which is caused by overexpression of L-chain due to mutation in the regulatory element in the untranslated region of the mRNA of the chain.     

The effect of elevated temperature on protein synthesis in cell-free extracts of cultured Chinese hamster ovary cells

The effect of elevated temperature on the activity of various components involved in protein synthesis was investigated in extracts from cultured Chinese hamster ovary cells. The translation of exogenous mRNA was markedly inhibited by preincubation of the extract for 15 to 20 minutes at 42°C. However, the following intermediary reactions were not affected, or only slightly inhibited, at 42°C: 1) the incorporation of Met-tRNA_f into eIF-2·Met-tRNA_f·GTP ternary complex; 2) the interaction of the ternary complex with 40S ribosomal subunits to form the 40S preinitiation intermediate; 3) the binding of mRNA and 60S subunits to form the 80S initiation complex; and 4) the reactions catalyzed by elongation factors EF-1 and EF-2. The activity of Met-tRNA synthetase was markedly inhibited, affecting the formation of initiator Met-tRNA_f required for the initiation of protein synthesis and the translation of natural mRNA. Other aminoacyl-tRNA synthetases were not significantly affected by the elevated temperature.     

Histone protein and DNA synthesis in HeLa cells after thermal shock

Exposure of suspension-cultured HeLa cells to a 45° thermal shock resulted in cell inactivation and inhibition of both protein and DNA synthesis. DNA synthesis was inhibited in a biphasic manner with a more sensitive (D₀ = 7 min) and a less sensitive (D₀ = 20 min) phase. The less sensitive process was demonstrated to be DNA chain elongation. Transport of thymidine into intracellular pools was significantly less sensitive to thermal shock (D₀ in excess of 200 min). When HeLa cells were heated at 45° for 15 min there was an 80% inhibition of incorporation of precursors into both DNA and protein with little effect on precursor transport into cellular pools. While the rate of synthesis of whole cell and histone protein (H2a, H2b, H3, and H4) and DNA chain elongation recovered by 6 h after cell heating, total precursor incorporation into DNA was only 0.4 of control levels. The long-term depression of the DNA synthetic rate could not be explained by a cell cycle redistribution, a depression in the total fraction of S phase cells synthesizing DNA, or by a depression in the rate of DNA chain elongation. We conclude that thermal shock results in a long-term depression in the fraction of cell replicons involved in DNA replication.     

Measurement of protein synthesis in rat lungs perfused in situ

Compartmentalization of amino acid was investigated to define conditions required for accurate measurements of rates of protein synthesis in rat lungs perfused in situ. Lungs were perfused with Krebs–Henseleit bicarbonate buffer containing 4.5% (w/v) bovine serum albumin, 5.6mm-glucose, normal plasma concentrations of 19 amino acids, and 8.6–690μm-[U-¹⁴C]phenylalanine. The perfusate was equilibrated with the same humidified gas mixture used to ventilate the lungs [O₂/CO₂ (19:1) or O₂/N₂/CO₂ (4:15:1)]. [U-¹⁴C]Phenylalanine was shown to be a suitable precursor for studies of protein synthesis in perfused lungs: it entered the tissue rapidly (t_½, 81s) and was not converted to other compounds. As perfusate phenylalanine was decreased below 5 times the normal plasma concentration, the specific radioactivity of the pool of phenylalanine serving as precursor for protein synthesis, and thus [¹⁴C]phenylalanine incorporation into protein, declined. In contrast, incorporation of [¹⁴C]histidine into lung protein was unaffected. At low perfusate phenylalanine concentrations, rates of protein synthesis that were based on the specific radioactivity of phenylalanyl-tRNA were between rates calculated from the specific radioactivity of phenylalanine in the extracellular or intracellular pools. Rates based on the specific radioactivities of these three pools of phenylalanine were the same when extracellular phenylalanine was increased. These observations suggested that: (1) phenylalanine was compartmentalized in lung tissue; (2) neither the extracellular nor the total intracellular pool of phenylalanine served as the sole source of precursor for protein; (3) at low extracellular phenylalanine concentrations, rates of protein synthesis were in error if calculated from the specific radioactivity of the free amino acid; (4) at high extracellular phenylalanine concentrations, the effects of compartmentalization were negligible and protein synthesis could be calculated accurately from the specific radioactivity of the free or tRNA-bound phenylalanine pool.     

Calcium Transport by Frankia sp. Strain EAN1pec

When incubated at 25°C, N₂-grown cells of Frankia strain EAN1pec actively accumulated calcium, while NH₄Cl-grown cells did not accumulate calcium. When incubated at 0°C, both N₂-grown and NH₄Cl-grown cells did not actively accumulate calcium. Inhibitors of respiration inhibited calcium accumulation by N₂-grown cells at 25°C. Isolated vesicles also accumulated calcium in an energy- and temperature-dependent manner. Two lines of evidence show that Frankia strain EAN1pec has an active calcium extrusion mechanism. First, NH₄Cl-grown cells incubated under deenergizing conditions accumulated calcium. Second, calcium efflux from calcium-loaded cells required an energy source and was blocked by inhibitors. The results of this study indicate that Frankia strain EAN1pec has two systems for calcium transport: a calcium extrusion system and a developmentally regulated calcium uptake system. Received: 1 December 1997 / Accepted: 9 January 1998     

Intracellular amino acids and protein synthesis in Hela cells

1. When the intracellular amino acid pool is prelabelled and subsequently chased in non-radioactive medium, the radioactivity of the amino acid pool is not found to have been incorporated into protein.
2. Leucine transport into Hela cells is reduced in the presence of 10 mM valine in the medium. This results in a lower specific radioactivity of leucine in the intracellular amino acid pool. However, neither the overall rate of protein synthesis nor the incorporation of radioactive leucine into protein is affected.

From these experiments it is concluded that incoming amino acids entering the intracellular amino acid pool are not used for de novo synthesis of protein.     

Implication of storage conditions on luminescence response from Photobacterium phosphoreum in free and immobilized form

Bioluminescent bacteria in the form of a cell suspension for on-site hazard analysis are not suitable as in vivo luminescence in free cells fluctuates and may lead to erroneous results. Furthermore, the culture broth cannot be stored for long durations to continue sensing analytes as the luminescence ceases over time. Factors that affect luminescence response include growth dynamism, and ambient environmental conditions. The present study investigated the effect of storage conditions such as temperature (25 ± 2°C, room temperature; 4°C; and −20°C) and ambient aqueous environment (M1: sucrose, 1.02 M; M2, bioluminescent media [tryptone, 10 g L⁻¹; NaCl, 28.5 g L⁻¹; MgCl₂.7H₂O, 4.5 g L⁻¹; CaCl₂, 0.5 g L⁻¹; KCl 0.5 g L⁻¹; yeast extract, 1 g L⁻¹; H₂O, 1 L]; M3, bioluminescent media and 95% glycerol, 1:1 ratio) on the luminescence emission from the calcium alginate-immobilized Photobacterium phosphoreum (S_b) against the cells in free suspension for an extended period. The results indicated that both the parameters that were undertaken markedly affected the luminescence. In the study, S_b showed an enhanced luminescence emission than the control up to 18.5-fold and for a prolonged period which can be efficiently utilized for rapid biosensing of hazardous materials.     

The initiation and elongation steps in protein synthesis: Relative rates in chinese hamster ovary cells during and after hyperthermic and hypothermic shocks

The relative rates of the initiation and elongation phases of protein synthesis have been determined in heat- and cold-shocked CHO cells from measurements of the incorporation of ³⁵S-methionine into N-terminal and internal positions of growing peptides by a modified Edman degradation. When the cells are shifted from 37°C to temperatures between 10°C and 34°C, the rate of initiation is at first reduced more extensively than that of elongation. After 20 to 30 minutes at the lower temperature, however, the cells undergo a metabolic adjustment which includes increasing the rate of initiation until it corresponds to the rate of elongation at that temperature. Calculated apparent energies of activation for initiation and elongation are in reasonable agreement with those determined in other mammalian cells. When the cooled cells are returned to 37°C, the rates of initiation and elongation recover immediately but do not exceed the control values. Exposure to elevated temperature (43°C) causes an immediate cessation of initiation and thus a delayed inhibition of elongation; upon return to 37°C, the rate of initiation is transiently elevated above the control rate, and the rate of elongation returns to the control rate after a 2- to 3-minute delay. Hence, a factor which leads to supranormal rates of initiation may accumulate at high but not at low temperatures.     

Properties of ts Cl mouse L cells which exhibit temperature-sensitive DNA synthesis.

ts Cl mouse L cells are temperature-sensitive (ts) in DNA synthesis. The protein involved undergoes inactivation at 38.5 °C, with an apparent half-life of 3–4 h. A variety of experimental approaches yield data indicating that the ts Cl gene product acts directly during the DNA-synthesis period, probably late during the duplication of chromosomal DNA. The specificity of the ts lesion is reflected in the fact that replication of mitochondrial DNA is unaffected for many hours after nuclear DNA synthesis is almost totally inhibited. Temperature inactivation is not due to degradation or to loss of template capacity of preformed DNA. ts Cl cells are able to enter a DNA-synthesis phase at the higher temperature, as indicated by radioautographic experiments and by studies in which cells, blocked at the permissive temperature (34 °C) in a pre-DNA synthesis phase by isoleucine deprivation, are subsequently incubated at 38.5 °C. Cells arrested early in DNA synthesis by hydroxyurea treatment at 34 °C continue such synthesis for a short interval after up-shift to 38.5 °C. However, they are then unable to complete the S phase in progress nor can they proceed into cell division. The kinetics of DNA synthesis in cells incubated at 38.5 °C and back-shifted to 34 °C are compatible with the model that the ts Cl locus encodes an S phase function.