Regulation of ribonucleic acid synthesis in Escherichia coli B-r: an analysis of a shift-up. II. Fraction of RNA polymerase engaged in the synthesis of stable RNA at different steady-state growth rates

The relative rates of stable RNA synthesis (rate of stable synthesis/rate of total RNA synthesis) were determined for Escherichia coli$\text{B}\text{r}$ growing in succinate (μ = 0.69 doublings/h), glucose (μ = 1.36 doublings/h) and glucose/amino acids (μ = 2.10 doublings/h) media. The relative rates were 0.29, 0.50 and 0.66 at these growth rates. From the relative rates, the fraction of RNA polymerase engaged in the synthesis of stable RNA, ψ_s, was calculated to be 0.22, 0.36 and 0.48, respectively, by taking into account the difference between the RNA chain growth rate of stable and that of unstable RNA. The relationship between these ψ_s values and μ and our previously determined chain growth rate of stable RNA has two implications for the control of RNA synthesis during a nutritional shift-up: (1) the increase in the net rate of RNA synthesis after a shift-up results from a transfer of RNA polymerase molecules from unstable to stable RNA genes, and a concomitant increase in the stable RNA chain growth rate, but does not require an activation of RNA polymerase; (2) the synthesis of functioning RNA polymerase enzymes is subject to a growth rate-dependent control.     

Synthesis and function of ribonucleic acid polymerase and ribosomes in Escherichia coli B/r after a nutritional shift-up.

The syntheses of stable ribosomal ribonucleic acid (RNA) and transfer RNA in bacteria depend on the concentration and activity of RNA polymerase and on the fraction of active RNA polymerase synthesizing stable RNA. These parameters were measured in Escherichia coli B/r after a nutritional shift-up from succinate-minimal to glucose-amino acids medium and were found to change in complex patterns during a 1- to 2-h period after the shift-up before reaching a final steady-state level characteristic for the postshift growth medium. The combined effect of these changes was an immediate, one-step increase in the exponential rate of stable RNA synthesis and thus of ribosome synthesis. This suggests that the distribution of transcribing RNA polymerase over ribosomal and nonribosomal genes and the polymerase activity are continuously adjusted during postshift growth to some growth-limiting reaction whose rate increases exponentially. It is proposed that this reaction is the production of amino-acylated transfer RNA and that is exponentially increasing rate results in part from a gradually increasing concentration of aminoacyl transfer RNA synthetases after a shift-up. This idea was tested and is supported by a computer simulation of a nutritional shift-up.     

Differential rate of ribosomal protein synthesis in Escherichia coli B-r

The differential rate of ribosomal protein synthesis, α_r (ribosomal protein synthesis rate/total protein synthesis rate), was measured for Escherichia coli strain B/r growing at different steady-state rates ranging from 0.67 to 2.3 doublings/hour. For growth rates above 1.2 doublings/hour, α_r was found to be proportional to the growth rate μ (doublings/h), such that α_r = 0.09 μ, and the ribosome efficiency (amino acids polymerized/second per ribosome), calculated from α_r, was found to be 14 to 18 amino acids/second per ribosome. With decreasing growth rates below 1.2 doublings/hour, α_r was found to be increasingly greater than 0.09 μ and the ribosome efficiency gradually decreased such that at μ = 0.67, α_r = 0.085, and the ribosome efficiency was reduced by 30% and was equal to 10 to 13 ammo acids/second per ribosome. These results imply that the protein to DNA ratio is constant for μ > 1.2 and equal to 4 × 10⁸ to 5 × 10⁸ amino acids/genome. For μ < 1.2, this ratio gradually decreases such that at μ = 0.67, protein to DNA = 3 × 10⁸ to 4 × 10⁸ amino acids/genome. These relationships were verified by direct measurements of the amounts of DNA, RNA and protein at different steady-state growth rates. In addition, protein accumulation was measured following a nutritional shift-up from succinate to glucose minimal medium. The results indicate that the ribosome efficiency increases by approximately 40% within the first few minutes following the shift-up.     

Regulation of ribonucleic acid synthesis in Escherichia coli B-r: an analysis of a shift-up. 1. Ribosomal RNA chain growth rates

The chain growth rate for ribosomal RNA was determined for Escherichia coli$\text{B}\text{r}$ growing in succinate (μ = 0.69 doublings/h), glucose (μ = 1.36) and glucose/ amino acids (μ = 2.10) medium. With increasing bacterial growth rate the chain growth rate increases from 4400 to 6300 nucleotides/min. These values are almost twofold higher than the chain growth rate reported for messenger RNA; this implies that, following a nutritional shift-up, the transfer of a relatively small number of RNA polymerase molecules from unstable to stable RNA genes along with the increase in the stable RNA chain growth rate is sufficient to account for the abrupt increase in the net rate of RNA synthesis. Furthermore, our calculations indicate that the linear density of polymerase molecules on the ribosomal DNA template increases with the bacterial growth rate, such that in rapidly growing bacteria all ribosomal RNA genes (48 copies at μ = 3) are nearly saturated with RNA polymerase.     

Different control circuits for growth rate-dependent regulation of 6-phosphogluconate dehydrogenase and protein components of the translational machinery in Escherichia coli.

Previous studies showed that the level of 6-phosphogluconate (6PG) dehydrogenase increases about fourfold with increasing growth rate when the growth rate is varied by varying the carbon source. When the growth rate was reduced by anaerobic growth or by using mutations to divert metabolism to less efficient pathways, the level of 6PG dehydrogenase was the same as in a wild-type strain growing aerobically on other carbon sources that yielded the same growth rate. Thus, expression of gnd, which encodes 6PG dehydrogenase, is regulated by the cellular growth rate and not by specific nutrients in the medium. Growth rate-dependent regulation was independent of temperature. After a nutritional shift-up, 6PG dehydrogenase and total protein did not attain the postshift rate of accumulation for 30 min, whereas RNA accumulation increased immediately. The kinetics of accumulation of 6PG dehydrogenase and RNA were coincident after a nutritional shift-down. Partial amino acid starvation of a strain that controls RNA synthesis stringently (rel+) had no effect on the differential rate of accumulation of the enzyme. The level of 6PG dehydrogenase in cells harboring a gnd+ multicopy plasmid was in approximate proportion to gene dosage and somewhat higher at faster growth rates. Growth rate control of chromosomal gnd was normal in strains carrying multiple copies of the promoter-proximal and promoter-distal portions of gnd. These results show that gnd is not part of the same regulatory network as components of the translational apparatus since gnd shows a delayed response to a nutritional shift-up, is not autoregulated, and is not subject to stringent control. Models to account for growth rate-dependent regulation of gnd are discussed.     

Metabolic regulation of beta-galactosidase synthesis in Escherichia coli. A test for constitutive ribosome synthesis.

The rate of differential synthesis of beta-galactosidase (alphalac) was measured in maximally induced cultures of Escherichia coli B/r with 0.01 M-inducer and 0.01 M-cyclic AMP. The value of alphalac decreases with growth rate (60% between 0.67 and 2.1 doublings/h) and after a nutritional shift-up. This decrease is presumed to reflect a decrease in the intracellular concentration of free active RNA polymerase after a shift-up, which implies that the increase in ribosome synthesis after a shift-up is due to an active induction of the ribosomal components.     

Synthesis of deoxyribonucleic acid, ribonucleic acid, and protein during sporulation of Clostridium perfringens.

The kinetics of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein synthesis as well as protein breakdown during sporulation by Clostridium perfringens were determined. Maximum levels of DNA and net RNA synthesis occurred 3 and 2 h, respectively, after inoculation of sporulation medium. The rate of RNA synthesis decreased as sporulation progressed. Deoxyadenosine increased uptake of [14C]uracil and [14C]thymine but depressed the level of sporulation and the formation of heat-resistant spores when added at concentrations above 100 mug/ml. Unlike Bacillus species, net protein synthesis, which was sensitive to chloramphenicol inhibition, continued during sporulation. The rate of protein breakdown during vegetative growth was 1%/h. During sporulation this rate increased to 4.7%/h. When added to sporulation medium at 0 time chloramphenicol reduced protein breakdown to 1%/h. If added at 3 h the rate decreased to 2.1%/h. The role of proteases in this process is discussed.     

Early increases in the frequency of DNA initiations and of phospholipid synthesis discontinuities after nutritional shift-up in Escherichia coli

Cultures of Escherichia coli (strains ML30 and K12 AB1157), synchronized by repeated phosphate starvation, were submitted to nutritional shifts-up at various cell ages. The progression of the replication forks was assessed by DNA-DNA hybridization of pulse-labelled chromosomal DNA with plasmid DNA probes containing specific chromosomal sequences. The rate of phospholipid synthesis and its cyclic discontinuities were measured by continuous and pulse labelling with palmitate. The DNA-DNA hybridization experiments showed that a shift-up induces a burst of initiation from the oriC region. These hybridization results, taken together with older data from the literature, suggest that most DNA initiations belonging to this burst are not followed by complete replication. Following a shift-up, the rate of phospholipid synthesis is maintained for 13-20 min, depending on cell age at shift-up, then doubles. The new steady-state rate of phospholipid synthesis is reached through a series of three doublings, while the cell mass doubles approximately twice. This discrepancy brings the rate of phospholipid synthesis per mass unit to its steady-state postshift value.     

REGULATION OF GROWTH PROCESSES DURING THE CELL CYCLE OF THE CHLOROCOCCAL ALGA SCENEDESMUS QUADRICAUDA UNDER A DNA REPLICATION BLOCK

The kinetics of two growth parameters (total RNA and total protein accumulation) was followed in synchronized cultures of the chlorococcal alga Scenedesmus quadricauda ( Turp.) Bréb. under conditions of inhibited DNA replication in the presence of 5-fluorodeoxyuridine (25 mg.L^-1). In the control culture, growth processes occurred in several steps with a decreasing rate of accumulation of RNA and protein amount approximately at each doubled value of the preceding step. Oscillations in the rate of growth processes in the control culture were temporally related to the initiation of individual reproductive steps. At each doubling, the cell became committed to triggering a sequence of reproductive processes, starting with DNA replication and ending with protoplast fission. Three commitment points were attained in the control culture and, consequently, three replication rounds of DNA followed by three nuclear divisions and three protoplast fissions occurred during one cell cycle. If 5-fluorodeoxyuridine (FdUrd) was added at the beginning of the cell cycle, no reproductive processes occurred, and the cells remained uninuclear with one genome and did not divide. RNA accumulation did not seem to be affected by the presence of FdUrd for at least one cell cycle, and three or four doublings in the amount of RNA occurred during this period. Protein accumulation was even more independent of reproductive processes in the cell and continued for a period of about two or three cell cycles, attaining six doublings at the end of this period. Therefore, oscillations in the rate of protein or RNA accumulation remained even if reproductive processes were inhibited .     

Polypeptide-chain-elongation rate in Escherichia coli B/r as a function of growth rate.

By evaluating the kinetics of radioactive labelling of nascent and finished polypeptides, the peptide-chain elongation rate for Escherichia coli B/r at three different growth rates (mu) was determined to be 17 amino acids/s for the fast-growing cells (mu equals 1.3 and 2.0 doublings/h) and 12 amino acids/s for slow-growing cells (mu equals 0.67 doublings/h). The results agree with the growth-rate-dependence of the rate of peptide-chain elongation found for the translation of newly induced beta-galactosidase messenger in this strain and under these conditions of growth [Dalbow & Young (1975) Biochem. J. 150, 13-20]. Together with the previously observed ribosome efficiency at these growth rates [Dennis & Bremer (1974) J. Mol. Biol. 84, 407-422] the results indicate that the fraction of ribosomes engaged in protein synthesis is about 0.8 at all three growth rates.     

Kinetic comparison of seven strains of 2,4-dichlorophenoxyacetic acid-degrading bacteria.

Seven strains of 2,4-dichlorophenoxyacetic acid-degrading bacteria, including Pseudomonas, Alcaligenes, and Bordetella spp., were compared on the basis of growth kinetics. Estimates of maximum growth rate (mu max, k1) and half-saturation growth constant (Ks, k3) were obtained by fitting substrate depletion curves to a four-parameter version of the integrated Monod equation. Estimates of Ks ranged from 2.2 micrograms/ml (10 microM) to 33.8 micrograms/ml (154 microM), and estimates of mu max ranged from 0.20 h-1 (Td = 3.5 h) to 0.32 h-1 (Td = 2.2 h). Estimates of mu max, but not Ks, were affected by changes in initial inoculum density. Maximum growth rates (mu max) were also estimated from turbidity measurements. They ranged from 0.10 h-1 (Td = 6.9 h) to 1.0 h-1 (Td = 0.7 h). There was no correlation between estimates of mu max derived from substrate depletion curves and those derived from turbidity measurements (P = 0.20).     

Kinetic comparison of seven strains of 2,4-dichlorophenoxyacetic acid-degrading bacteria.

Seven strains of 2,4-dichlorophenoxyacetic acid-degrading bacteria, including Pseudomonas, Alcaligenes, and Bordetella spp., were compared on the basis of growth kinetics. Estimates of maximum growth rate (mu max, k1) and half-saturation growth constant (Ks, k3) were obtained by fitting substrate depletion curves to a four-parameter version of the integrated Monod equation. Estimates of Ks ranged from 2.2 micrograms/ml (10 microM) to 33.8 micrograms/ml (154 microM), and estimates of mu max ranged from 0.20 h-1 (Td = 3.5 h) to 0.32 h-1 (Td = 2.2 h). Estimates of mu max, but not Ks, were affected by changes in initial inoculum density. Maximum growth rates (mu max) were also estimated from turbidity measurements. They ranged from 0.10 h-1 (Td = 6.9 h) to 1.0 h-1 (Td = 0.7 h). There was no correlation between estimates of mu max derived from substrate depletion curves and those derived from turbidity measurements (P = 0.20).     

Regulation of macromolecular synthesis during nutritional shift-up in the fungusMucor

The dimorphic fungusMucor racemosus was grown anaerobically in the yeast form and shifted from a defined minimal medium (=0.17 doublings/h) to an enriched complex medium (=0.43 doublings/h). The measured rates of increase of several growth-related parameters displayed an immediate and complete adjustment to the higher growth rate without an intervening lag. Pulse-labeling experiments indicated that the rates of protein and RNA synthesis increased immediately and in parallel in response to the shift. The rate of polypeptide chain elongation immediately increased by approximately 60% to support the new higher rate of protein accumulation, but later declined to near pre-shift values. The accelerated rate of protein accretion was apparently sustained by a gradual increase in the total number of ribosomes per weight of cellular material and by a more rapid increase in the percentage of ribosomes recruited into polysomes at a given time. Thus, this simple eukaryote displays a much more rapid and varied mechanism of response to nutritional shift-up conditions than is classically observed in bacteria.     

Macromolecular Synthesis in Saccharomyces cerevisiae in Different Growth Media

Synthesis of ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and protein was determined in Saccharomyces cerevisiae during amino acid and pyrimidine starvation and during shift-up and shift-down conditions. During amino acid starvation, cell mass, cell number, and RNA continued to increase for varying periods. During amino acid and pyrimidine starvation, cell mass and RNA showed little increase, whereas total DNA increased 11 to 17%. After a shift from broth medium to a minimal defined medium, increase in RNA and protein remained at the preshift rate before assuming a lower rate. DNA increase remained at an intermediate rate during shift-down, and then dropped to a low rate. During shift-up from minimal to broth medium, increase in cell number, protein, and DNA showed varying lag periods before increasing to the new rate characteristic of broth medium; each of these quantities exhibited a step sometime in the first 2 hr after transfer to rich medium, suggesting a partial synchronous division. Immediately after shift-up, RNA synthesis assumed a high rate, and then dropped to a rate characteristic of growth in the rich medium after about 1 hr.     

Growth and cell division of Mycobacterium avium

The rates of cell division and of protein, DNA and RNA synthesis upon transition of Mycobacterium avium to and from rich medium were examined. The changes in cell morphology (elongation) were also examined by optical and electron microscopy. Upon transfer from poor to rich medium, the rate of synthesis of RNA increased rapidly, followed by an increase in protein synthesis within 3 h and by an increase in DNA synthesis within 7 h; cell division began after a lag of about 10 h. Upon transfer from rich to poor medium, the preshift rates for protein and DNA synthesis changed to postshift rates after 3 h and 7 h, respectively; RNA synthesis stopped immediately, there was a transient fall in total RNA, and synthesis was resumed at a new rate only after 24 h. After the period of adjustment to new medium, the bacteria entered the postshift growth in which cell size, the increase in cell mass (absorbance at 650 nm) and viable counts, and the rates of synthesis of protein, DNA and RNA were constant. Ultrastructural examination of elongated cells during the adjustment period showed that they had septa at different stages of formation, but no evidence of fragmentation was found. It was concluded that cell division in M. avium was by binary fission, and that the notion of a life-cycle was not supported by present findings.     

Kinetic analysis of nucleotide incorporation by mammalian DNA polymerase delta

The kinetics of nucleotide incorporation into 24/36-mer primer/template DNA by purified fetal calf thymus DNA polymerase (pol) delta was examined using steady-state and pre-steady-state kinetics. The role of the pol delta accessory protein, proliferating cell nuclear antigen (PCNA), on DNA replication by pol delta was also examined by kinetic analysis. The steady-state parameter k(cat) was similar for pol delta in the presence and absence of PCNA (0.36 and 0.30 min(-1), respectively); however, the K(m) for dNTP was 20-fold higher in the absence of PCNA (0.067 versus 1.2 microm), decreasing the efficiency of nucleotide insertion. Pre-steady-state bursts of nucleotide incorporation were observed for pol delta in the presence and absence of PCNA (rates of polymerization (k(pol)) of 1260 and 400 min(-1), respectively). The reduction in polymerization rate in the absence of PCNA was also accompanied by a 2-fold decrease in burst amplitude. The steady-state exonuclease rate of pol delta was 0.56 min(-1) (no burst, 10(3)-fold lower than the rate of polymerization). The small phosphorothioate effect of 2 for correct nucleotide incorporation into DNA by pol delta.PCNA indicated that the rate-limiting step in the polymerization cycle occurs prior to phosphodiester bond formation. A K(d)(dNTP) value of 0.93 microm for poldelta.dNTP binding was determined by pre-steady-state kinetics. A 5-fold increase in K(d)(DNA) for the pol delta.DNA complex was measured in the absence of PCNA. We conclude that the major replicative mammalian polymerase, pol delta, exhibits kinetic behavior generally similar to that observed for several prokaryotic model polymerases, particularly a rate-limiting step following product formation in the steady state (dissociation of oligonucleotides) and a rate-limiting step (probably conformational change) preceding phosphodiester bond formation. PCNA appears to affect pol delta replication in this model mainly by decreasing the dissociation of the polymerase from the DNA.     

The dioxygen cycle. Spectral, kinetic, and thermodynamic characteristics of ferryl and peroxy intermediates observed by reversal of the cytochrome oxidase reaction.

The catalytic mechanism of O2 reduction by cytochrome oxidase was studied in isolated mitochondria and mitoplasts by partial reversal of the reaction. At a high redox potential (Eh) of cytochrome c, high pH, and a high electrochemical proton gradient (delta mu H+) across the inner mitochondrial membrane, the initial ferriccupric state (O) of the oxidized enzyme's bimetallic oxygen reaction center is converted to ferryl (F) and peroxy (P) intermediates, the optical spectroscopic properties of which are reported in detail. This is associated with reversed electron transfer from the bimetallic center to ferricytochrome c. The kinetics of reduction of ferricytochrome c by the reversed electron transfer process are compared with the kinetics of formation of F and P. The results are consistent with transfer of one electron from the ferric-cupric bimetallic center (O) to cytochrome c, yielding the F intermediate, followed by transfer of one electron from the latter to cytochrome c, yielding the P state. In the absence of an effective redox buffer, poising cytochrome c highly oxidized, these primary events are immediately followed by reoxidation of cytochrome c, which is ascribed to forward electron transfer to enzyme molecules still in the O state. This forward reaction also results in accumulation of the P intermediate. Kinetic stimulations of the data predict equilibrium constants for the reversed electron transfer steps, and Em,7 values of approximately 1.1 and 1.2 V may be calculated for the F/O and P/F redox couples, respectively, at delta mu H+ and delta psi equal to zero. Taken together with previously measured Em,7 values, these data indicate that it is the two-electron reduction of bound dioxygen to bound peroxide that is responsible for the irreversibility of the catalytic dioxygen cycle of cell respiration.