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 of RNA polymerase in Escherichia coli B-r growing at different rates

Polyacrylamide gel electrophoresis of unfractionated sodium dodecyl sulfate lysates of Escherichia coli$\text{B}\text{r}$ has been used to investigate the synthesis of β and β′ subunits of RNA polymerase as a function of bacterial growth rate. In succinate (μ = 0.67 doublings/h), glucose (μ = 1.36 doublings/h) and glucose/amino acids (μ = 2.10 doublings/h) supplemented media, the fraction of [¹⁴C]leucine-labeled β and β′ protein/total protein was found to be 1.05, 1.31 and 1.56%, respectively. Comparison of these values with recent estimates from this laboratory of the differential rate of synthesis of functioning RNA polymerase suggests an excess of total over functioning RNA polymerase. The significance of these data in reference to the regulation of RNA polymerase synthesis is discussed.     

Regulation of RNA synthesis in Neurospora crassa : An analysis of a shift-up

A shift-up transition of growth from acetate to glucose is analyzed in Neurospora crassa. The rates of DNA and of protein accumulations remain at the preshift values for about 2 h, afterwards they increase to the rate characteristic of the new medium. The rate of RNA accumulation increases markedly 30 min after glucose addition initially at a rate greater than that of the new exponential growth which is achieved later on. An increase of the level of ribosomal proteins accompanies the increase of the rRNA content of the shifting cells, and 2–2.5 h after the shift the ribosomal level has reached the value characteristic of the new steady state of growth. The rate of rRNA methylation, which is strictly proportional to rRNA synthesis, remains almost unchanged in the 30 min following the shift; thereafter it increases to values greater than the final rate. It is interesting that the rate of rRNA synthesis is enhanced above the value typical of the new steady state as long as the ribosome level in the cells is below that characteristic of the new steady state, as if a compensatory mechanism were active.     

Establishment of exponential growth after a nutritional shift-up in Escherichia coli B/r: accumulation of deoxyribonucleic acid, ribonucleic acid, and protein.

The accumulation of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein was followed in cultures of Escherichia coli B/r during exponential growth in different media and for 2 h after a nutritional shift-up from succinate minimal medium (growth rate [mu1] = 0.67 doublings per h) to glucose plus amino acids medium (mu2 = 3.14 doublings per h). During postshift growth of the culture, the amounts of RNA (R), DNA (D), and protein (P) increased such that the ratios of the increments (delta R/delta P; delta D/delta P) were constants (k1, k2). This implies that the rates of accumulation of nuclei1:k2:1. These constants change from their preshift value to their final postshift value (i.e., k1 and k2) within a few minutes after the shift. k1 is a function of the activity of ribosomes, whereas k2 is related to the initiation of rounds of DNA replication. These parameters and the observed change in the doubling time of RNA (= mu2/mu1) were used to derive kinetic equations that describe the accumulation of DNA, RNA, protein, and cell mass during the 2- to 3-h transition period after a shift-up. The calculated kinetics agree closely with the observed kinetics.     

Transient regulation of protein synthesis in Escherichia coli upon shift-up of growth temperature.

Synthesis of total cellular proteins of Escherichia coli was studied upon transfer of a log-phase culture from 30 (or 37) to 42 degrees C. Cells were pulse-labeled with [3H]leucine, and the labeled proteins were analyzed by gel electrophoresis in the presence of sodium dodecyl sulfate. The rates of synthesis of at least five protein chains were found to increase markedly (5- to 10-fold) within 5 min after temperature shift-up and gradually decrease to the new steady-state levels, in contrast to the majority of proteins which gradually increase to the steady-state levels (about 1.5-fold the rate at 30 degrees C). Temperature shift-down did not cause any appreciable changes in the pattern of protein synthesis as detected by the present method. Among the proteins greatly affected by the temperature shift-up were those with apparent molecular weights fo 87,000 (87K), 76K, 73K, 64K, and 61K. Two of them (64K and 61K) were found to be precipitated with specific antiserum against proteins that had previously been shown to have an adenosine triphosphatase activity. The bearings of these findings on bacterial adaptation to variation in growth temperature are discussed.     

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.     

Role of aminoacyl-transfer ribonucleic acid in the regulation of ribonucleic acid synthesis in Escherichia coli

Morris, D. W. (University of California, San Diego), and J. A. DeMoss. Role of aminoacyl-transfer ribonucleic acid in the regulation of ribonucleic acid synthesis in Escherichia coli. J. Bacteriol. 90:1624-1631. 1965.-A leucine auxotroph of Escherichia coli was examined for its rate of ribonucleic acid (RNA) synthesis and the level of charged leucine-, arginine-, and valine-specific transfer RNA (tRNA) during the exponential growth period and when growth was limited by leucine starvation. During the logarithmic growth period, the leucine-specific tRNA was 70% charged, arginine-specific tRNA was 30% charged, and the valine-specific tRNA was 80% charged. When leucine became limiting, RNA synthesis was inhibited and the levels of charged arginine- and valine-specific tRNA remained constant, whereas the level of charged leucine-specific tRNA dropped to 40%. Examination of the leucyl-tRNA during the leucine starvation period showed that this 40% level is maintained by protein turnover. Addition of chloramphenicol or puromycin to a leucine-starved culture derepressed RNA synthesis. In the presence of chloramphenicol, the leucine-specific tRNA was fully charged; however, in the presence of puromycin the amount of charged leucine-specific tRNA remained at the starved level. Therefore, during leucine starvation the level of uncharged leucine-specific tRNA is not invariably correlated with the rate of RNA synthesis. We propose that it is the availability of charged tRNA and not the amount of uncharged tRNA which is the important factor in the amino acid control of RNA synthesis.