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.     

Control of cell length in Bacillus subtilis.

During inhibition of deoxyribonucleic acid synthesis in Bacillus subtilis 168 Thy-minus Tryp-minus, the rate of length extension is constant. A nutritional shift-up during thymine starvation causes an acceleration in the linear rate of length extension. During a nutritional shift-up in the presence of thymine, the rate of length extension gradually increases, reaching a new steady state at about 50 min before the new steady-state rate of cell division is reached. The steady-state rates of nuclear division and length extension are reached at approximately the same time. The ratio of average cell length to numbers of nuclei per cell in exponential cultures is constant over a fourfold range of growth rates. These observations are consistent with: (i) surface growth zones which operate at a constant rate of length extension under any one growth condition, but which operate at an absolute rate proportional to the growth rate of the culture, (ii) a doubling in number of growth zones at nuclear segregation, and (iii) a requirement for deoxyribonucleic acid replication for the doubling in a number of sites.     

The timing of initiation of macronuclear DNA synthesis is set during the preceding cell cycle in Paramecium tetraurelia. Analysis of the effects of abrupt changes in nutrient level

In many eukaryotic organisms, initiation of DNA synthesis is associated with a major control point within the cell cycle and reflects the commitment of the cell to the DNA replication-division portion of the cell cycle. In Paramecium, the timing of DNA synthesis initiation is established prior to fission during the preceding cell cycle. DNA synthesis normally starts at 0.25 in the cell cycle. When dividing cells are subjected to abrupt nutrient shift-up by transfer from a chemostat culture to medium with excess food, or shift-down from a well-fed culture to exhausted medium. DNA synthesis initiation in the post-shift cell cycle occurs at 0.25 of the parental cell cycle and not at either 0.25 in the post-shift cell cycle or at 0.25 in the equilibrium cell cycle produced under the post-shift conditions. The long delay prior to initiation of DNA synthesis following nutritional shift-up is not a consequence of continued slow growth because the rate of protein synthesis increases rapidly to the normal level after shift-up. Analysis of the relation between increase in cell mass and initiation of DNA synthesis following nutritional shifts indicates that increase in cell mass, per se, is neither a necessary nor a sufficient condition for initiation of DNA synthesis, in spite of the strong association between accumulation of cell mass and initiation of DNA synthesis in cells growing under steady-state conditions.     

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.     

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.     

Dimensional rearrangement of rod-shaped bacteria following nutritional shift-up. II. Experiments with Escherichia coliBr

The dimensions of Escherichia coli$\text{B}\text{r}$ (strain H266) in transition between two states of balanced growth, were determined from electron micrographs of fixed cells by sampling the culture at various times following nutritional shift-up from a doubling time of 72 min to one of 24 min. Mean cell length rises immediately and overshoots its final steady-state value, cell diameter increases monotonically; both approach their asymptotic levels only after several hours.The results are compared with the dimensions predicted by each of two models of cell growth and morphogenesis in rod-shaped bacteria. The first attributes cell elongation to circular zones that double in number at a particular time during the cell cycle and which act at rates proportional to the growth rate; the second is similar, except that it considers surface growth rather than length extension as the active process, length being determined passively. Two possibilities are examined, that the zonal growth rate adjusts immediately to the new growth conditions, and that it does so gradually.The experimental data appear consistent with the gradual response version of the surface growth model.     

Macromolecular synthesis after a nutritional shift-up of Bacillus subtilis

Summary Effects of amino acids on macromolecular synthesis in Bacillus subtilis were studied. Two mutants, CRK4001 and NIG45, that were selected as slow growers in rich media were proved to be useful to analyse early events occurring after addition of amino acids to exponentially growing cells in a glucose-salts medium (nutritional shift-up). In a wild type strain, the rate of stable RNA (sRNA: essentially ribosomal RNA) synthesis increased 2.3 fold shortly after the shift-up to the rate characteristic of the post-shift steady state growth. In contrast, sRNA synthesis in the mutant strains responded to the shift-up in two steps. Thus, shortly after the shift the rate of sRNA synthesis increased 2.2 fold as in the wild type, but this increased level was maintained temporarily for 60 min and suddenly decreased to the post-shift steady state rate (1.4 fold increase). On the other hand, rates of DNA synthesis increased some 30 min after the shift directly to the post-shift steady state rates in all strains. Ratios of an origin to a terminus marker (purA/metB) began to increase exponentially to reach maximum values at 60 min after the shift, indicating that initiation of DNA replication occurred at frequencies characteristic of respective post-shift growth rates soon after the shift. These results revealed that the initial increase in the rate of sRNA synthesis and the frequency of initiation of DNA replication after nutritional shift are not related to each other and are independently affected by amino acids. In concert with these findings, the increase in sRNA synthesis was not affected by inhibition of DNA synthesis for the first 60 min after the shift, while it was completely prevented by puromycin and chloramphenicol. Protein synthesis for 10 min after the shift was sufficient to fully change the sRNA synthesis rate by amino acids.     

Analysis of initiation of sites of cell wall growth in Streptococcus faecium during a nutritional shift

Three-dimensional reconstruction methods were applied to electron micrographs of Streptococcus faecium to study the initiation of cell wall growth sites during a nutritional shift experiment. Upon lowering the mass doubling time from 76 to 33 min by the addition of excess glutamate, the formation of new cell wall growth sites accelerated above the old steady-state rate at about the same time (10 to 15 min) as did mass, RNA, protein, cell numbers, and autolytic capacity but considerably before DNA (30 min) and peptidoglycan (20 min) synthesis did. During the shift, the average range of cell volumes over which new wall growth sites were introduced did not change significantly. However, upon the shift there was an increase in the frequency of cells having new sites, which was due to the faster-growing cells initiating more new sites in peripheral locations before division. After a transition period, the number of new sites per milliliter of culture increased at a rate that paralleled that of the culture mass. These findings support a model in which new sites are introduced when cells grow to a relatively constant, growth rate-independent size, while the rate at which sites form and grow increases with the growth rate. In this model, chromosome synthesis does not regulate the formation of new sites of cell wall growth, but existing sites cannot be completed until rounds of chromosome synthesis are completed.     

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.     

Simulated bacterial growth

A mathematical model system for the simulation of bacterial growth is presented, based on eight observable growth parameters used as input. These parameters reflect the chain elongation rates of DNA, RNA and protein, the control of stable RNA and RNA polymerase genes, the functional activities of ribosomes and RNA polymerase, and the control of DNA replication and cell division. With observed values for these parameters, the model system simulates the exponential increase in the number of ribosomes and RNA polymerase molecules, as well as in the amounts of DNA, RNA and protein and in the cell number. The doubling time of this exponential increase and the simulated cell composition (DNA, RNA and protein per cell, or RNA and protein per genome) assume the correct values typical for the culture in which the input parameters were observed, and independent of the zero time conditions of the system which can be arbitrarily chosen. The simulation can be used to check the consistency of observed growth parameters, or to indirectly find the kinetic behavior of growth parameters which cannot be readily observed, or to analyze experiments involving a perturbation of steady-state growth. As examples of the latter, the simulation of a “step-up” experiment is presented in which the effects of a step-wise increase in the DNA replication velocity are analyzed, and the simulation of a nutritional shift-up, in which the kinetic changes in the gene activities for rRNA and rprotein genes are examined.     

The inefficiency of ribosomes functioning in Escherichia coli growing at moderate rates

It is generally agreed that ribosomes function with reduced efficiency (i.e. a smaller proportion is actually engaged in protein synthesis) in bacteria growing at low growth rates (doubling times greater than 2 h). This paper examines whether the efficiency is constant in bacteria growing at various rates corresponding to doubling times of less than 2 h. Because isotopic methods cannot be used in very rich media, turbidimetric methods have been extended to follow the kinetics of growth immediately following the shift-up of cultures of Escherichia coli ML308 growing in glucose minimal medium or succinate minimal medium into a very rich medium supporting a balanced doubling time of 17.4 min. It is concluded that the efficiency of ribosome participation in protein synthesis is higher in the very rich medium than in the two minimal media, which support doubling times of 43 and 65 min, respectively, at 37 degrees C.     

The regulation of RNA synthesis in yeast II: Amino acids shift-up experiments

Summary A study has been made of the effects of a casamino acids shift-up on a prototrophic strain of yeast growing under conditions of ammonium repression. The shift-up produced an increase in growth rate some 120 min after the addition of amino acids to the medium. This growth rate increase was slightly preceded by an increase in the rate of accumulation of DNA. In contrast, the rate of accumulation of protein increased immediately and that of RNA 15–20 min after the shift. RNA was initially accumulated at a rate greater than that required to sustain the new steady state. This was shown to be due to an increase in the rate of synthesis of the rRNA species derived from the 35S precursor. The rate of synthesis of 5S rRNA and of tRNA increased much later and to a lesser extent than that of the 35S derived species. The implications of these results for general theories of the regulation of RNA synthesis are discussed.Paper I in this series is Oliver and McLaughlin (1977)     

The relationships among RNA synthesis,RNA polymerase synthesis and guanosine tetraphosphate levels in Escherichia coli during nutritional shift-up

The relationships among the rate of RNA synthesis, RNA polymerase synthesis and activity, and guanosine tetraphosphate levels were investigated following nutritional shift-up in Escherichia coli. RNA synthesis continues at the preshift rate for 1.5 min after which an increase is observed that reaches a new steady-state rate at between 2 and 2.5 min. RNA polymerase activity measured in crude extracts increases immediately and by 10 min has increased 50%. RNA polymerase synthesis as measured by the synthesis of the β and β′ subunits lags for 2.5 min and then increases 75% by 10 min. Guanosine tetraphosphate levels decrease 50% by 3 min to levels characteristic of steady-state post-shift-up cells. The significance of these data to the regulation of RNA synthesis during shift-up is discussed.     

In vitro translation of polyadenylic acid-free rabbit globin messenger RNA

Following a nutritional shift-up, both the fraction of functioning RNA polymerase engaged in the synthesis of stable RNA, ψ_s, and the ribosomal RNA chain growth rate, c_s, increase within five minutes to near their final post-shift steady-state values. The increase in these two parameters is sufficient to account completely for the observed sudden increase in the rate of RNA accumulation. This implies that the control of stable RNA synthesis following a shift-up does not involve an activation of an inactive reserve of RNA polymerase or a burst of RNA polymerase synthesis, but rather results from a shift of RNA polymerase-transcribing messenger RNA genes to ribosomal and transfer RNA genes along with some increase in the stable RNA chain growth rate.     

Replication of R-factor R1 in Scherichia coli K-12 at different growth rates.

The R-factor R1drd-19 mediates resistance to beta-lactam antibiotics via a beta-lactamase. A strain of Escherichia coli K-12 carrying R1drd-19 was grown at different growth rates by using different carbon sources. The specific rate of production of the R1 beta-lactamase increased linearly with the growth rate and with the gene dosage. The content of R1 deoxyribonucleic acid was estimated by alkaline sucrose gradient centrifugation and by analysis of the specific rate of beta-lactamase synthesis in nutritional shift-up experiments and was found to decrease fivefold when the growth rate was increased from 0.4 to 1.8 doublings per h. The number of R1 molecules per cell decreased from six to two in the same growth range. The presence of the plasmid affected the mean cell size significantly; at a growth rate of 0.4 doublings per h the R-+ cells were on the average 50% bigger than the R-minus cells, whereas the effect was less than 10% at a growth rate of 1.8 doublings per h. Several reports in the leterature state that the initiation mass of chromosome replication is constant. In this paper it is shown that the initiation mass of R1 replication is proportional to the growth rate. Thus, the replication of the plasmid R1 and of the chromosome are independently regulated processes. It is argued that plasmid replication is under negative control.     

Kinetics of ribosome synthesis during a nutritional shift-up in Escherischia coli K-12.

Summary The rates of total protein synthesis, polyribosome formation and 70S ribosome accumulation were measured following a nutritional shift-up ofEscherichia coli K-12. Changes in ribosome content and distribution during the shift-up were measured by examining the total cellular content of free and polysome-associated ribosomes using a sensitive double isotope labeling method. The kinetics of ribosomal subunit formation and the biosynthesis of subunit protein and RNA species were also defined. The results indicated that a pre-shift population of ribosomal subunits was utilized for the immediate post shift increase in both total and ribosomal-specific protein synthesis. An assembly time for new subunits of about 3 min was observed. The formation of certain ribosomal proteins during the shift suggested that new subunit assembly was limited by the rate of synthesis of particular ribosomal proteins during this growth transition.