Correlation between RNA synthesis and ppGpp content in Escherichia coli during temperature shifts

Metabolic rearrangement enables adaptation of microbial growth rate to temperature shifts

Temperature is a key determinant of microbial behaviour and survival in the environment and within hosts. At intermediate temperatures, growth rate varies according to the Arrhenius law of thermodynamics, which describes the effect of temperature on the rate of a chemical reaction. However, the mechanistic basis for this behaviour remains unclear. Here we use single-cell microscopy to show that Escherichia coli exhibits a gradual response to temperature upshifts with a timescale of ~1.5 doublings at the higher temperature. The response was largely independent of initial or final temperature and nutrient source. Proteomic and genomic approaches demonstrated that adaptation to temperature is independent of transcriptional, translational or membrane fluidity changes. Instead, an autocatalytic enzyme network model incorporating temperature-sensitive Michaelis-Menten kinetics recapitulates all temperature-shift dynamics through metabolome rearrangement, resulting in a transient temperature memory. The model successfully predicts alterations in the temperature response across nutrient conditions, diverse E. coli strains from hosts with different body temperatures, soil-dwelling Bacillus subtilis and fission yeast. In sum, our model provides a mechanistic framework for Arrhenius-dependent growth.

Metabolomic rearrangement controls the intrinsic microbial response to temperature changes

Temperature is one of the key determinants of microbial behavior and survival, whose impact is typically studied under heat- or cold-shock conditions that elicit specific regulation to combat lethal stress. At intermediate temperatures, cellular growth rate varies according to the Arrhenius law of thermodynamics without stress responses, a behavior whose origins have not yet been elucidated. Using single-cell microscopy during temperature perturbations, we show that bacteria exhibit a highly conserved, gradual response to temperature upshifts with a time scale of ~1.5 doublings at the higher temperature, regardless of initial/final temperature or nutrient source. We find that this behavior is coupled to a temperature memory, which we rule out as being neither transcriptional, translational, nor membrane dependent. Instead, we demonstrate that an autocatalytic enzyme network incorporating temperature-sensitive Michaelis-Menten kinetics recapitulates all temperature-shift dynamics through metabolome rearrangement, which encodes a temperature memory and successfully predicts alterations in the upshift response observed under simple-sugar, low-nutrient conditions, and in fungi. This model also provides a mechanistic framework for both Arrhenius-dependent growth and the classical Monod Equation through temperature-dependent metabolite flux.

Protein-Ligand Interactions in Scarcity: The Stringent Response from Bacteria to Metazoa, and the Unanswered Questions

The stringent response, originally identified in Escherichia coli as a signal that leads to reprogramming of gene expression under starvation or nutrient deprivation, is now recognized as ubiquitous in all bacteria, and also as part of a broader survival strategy in diverse, other stress conditions. Much of our insight into this phenomenon derives from the role of hyperphosphorylated guanosine derivatives (pppGpp, ppGpp, pGpp; guanosine penta-, tetra- and tri-phosphate, respectively) that are synthesized on starvation cues and act as messengers or alarmones. These molecules, collectively referred to here as (p)ppGpp, orchestrate a complex network of biochemical steps that eventually lead to the repression of stable RNA synthesis, growth, and cell division, while promoting amino acid biosynthesis, survival, persistence, and virulence. In this analytical review, we summarize the mechanism of the major signaling pathways in the stringent response, consisting of the synthesis of the (p)ppGpp, their interaction with RNA polymerase, and diverse factors of macromolecular biosynthesis, leading to differential inhibition and activation of specific promoters. We also briefly touch upon the recently reported stringent-like response in a few eukaryotes, which is a very disparate mechanism involving MESH1 (Metazoan SpoT Homolog 1), a cytosolic NADPH phosphatase. Lastly, using ppGpp as an example, we speculate on possible pathways of simultaneous evolution of alarmones and their multiple targets.

The Effects of Temperature on Cellular Physiology

Temperature impacts biological systems across all length and timescales. Cells and the enzymes that comprise them respond to temperature fluctuations on short timescales, and temperature can affect protein folding, the molecular composition of cells, and volume expansion. Entire ecosystems exhibit temperature-dependent behaviors, and global warming threatens to disrupt thermal homeostasis in microbes that are important for human and planetary health. Intriguingly, the growth rate of most species follows the Arrhenius law of equilibrium thermodynamics, with an activation energy similar to that of individual enzymes but with maximal growth rates and over temperature ranges that are species specific. In this review, we discuss how the temperature dependence of critical cellular processes, such as the central dogma and membrane fluidity, contributes to the temperature dependence of growth. We conclude with a discussion of adaptation to temperature shifts and the effects of temperature on evolution and on the properties of microbial ecosystems.

C Group-Mediated Antibiotic Stress Mimics the Cold Shock Response

A temperature downshift results in stabilized secondary structure formation in mRNA that halts translation to which Escherichia coli responds by synthesizing a set of proteins termed as cold shock proteins (Csps). To cope with the sudden temperature drop, gene expression patterns are reprogrammed to induce Csps at the cost of other proteins. Out of the nine homologous proteins in the CspA family, CspA, CspB, CspG, and CspI have major roles in protecting the cell under a cold shock. Additionally, a subset of Csps has conferred the organism an ability to adapt to various stresses along the lines of nutrient deprivation, oxidative, heat, acid, and antibiotic stresses. Stressors like C group translational inhibitors stall the translational apparatus and produce a response similar to that observed under a temperature downshift. Conditions set by the antibiotic therefore elicit a cold shock response and induce the major Csps, thereby pointing out to a common mechanism existing between the two. In the current review, we briefly describe the induction of E. coli Csps under an antibiotic stress acquired from data published previously and help establish the role of Csps in protecting the cell against the inducing agents and as a participant in the organisms' complex stress response network.

De novo Synthesis and Assembly of rRNA into Ribosomal Subunits during Cold Acclimation in Escherichia coli

During the cold adaptation that follows a cold stress, bacterial cells undergo many physiological changes and extensive reprogramming of their gene expression pattern. Bulk gene expression is drastically reduced, while a set of cold shock genes is selectively and transiently expressed. The initial stage of cold acclimation is characterized by the establishment of a stoichiometric imbalance of the translation initiation factors (IFs)/ribosomes ratio that contributes to the preferential translation of cold shock transcripts. Whereas de novo synthesis of the IFs following cold stress has been documented, nothing was known concerning the activity of the rrn operons during the cold acclimation period. In this work, we focus on the expression of the rrn operons and the fate of rRNA after temperature downshift. We demonstrate that in Escherichia coli, rRNA synthesis does not stop during the cold acclimation phase, but continues with greater contribution of the P2 compared to the P1 promoter and all seven rrn operons are active, although their expression levels change with respect to pre-stress conditions. Eight hours after the 37°→10 °C temperature downshift, the newly transcribed rRNA represents up to 20% of total rRNA and is preferentially found in the polysomes. However, with respect to the de novo synthesis of the IFs, both rRNA transcription and maturation are slowed down drastically by cold stress, thereby accounting in part for the stoichiometric imbalance of the IFs/ribosomes. Overall, our data indicate that new ribosomes, which are possibly suitable to function at low temperature, are slowly assembled during cold acclimation.

Salmonella enterica serovar Typhimurium BipA exhibits two distinct ribosome binding modes

BipA is a highly conserved prokaryotic GTPase that functions to influence numerous cellular processes in bacteria. In Escherichia coli and Salmonella enterica serovar Typhimurium, BipA has been implicated in controlling bacterial motility, modulating attachment and effacement processes, and upregulating the expression of virulence genes and is also responsible for avoidance of host defense mechanisms. In addition, BipA is thought to be involved in bacterial stress responses, such as those associated with virulence, temperature, and symbiosis. Thus, BipA is necessary for securing bacterial survival and successful invasion of the host. Steady-state kinetic analysis and pelleting assays were used to assess the GTPase and ribosome-binding properties of S. enterica BipA. Under normal bacterial growth, BipA associates with the ribosome in the GTP-bound state. However, using sucrose density gradients, we demonstrate that the association of BipA and the ribosome is altered under stress conditions in bacteria similar to those experienced during virulence. The data show that this differential binding is brought about by the presence of ppGpp, an alarmone that signals the onset of stress-related events in bacteria.

Intracellular and extracellular components as bacterial thermometers, and early warning against thermal stress

Responses induced by cold or heat are triggered following detection of temperature changes by specific sensing molecules, complexes or structures. Low temperature responses are often induced following sensing of cold-induced falls in membrane fluidity, such changes turning-on or -off enzymic activities in membrane proteins, although ribosomes and DNA may also function in cold perception. Many thermal sensors are components of structures damaged by the heat, with sensing involving changes to ribosomes, DNA, intracellular proteins and, less commonly, membrane fluidity. Additionally, secreted proteins (extracellular sensing components, ESCs) detect temperature increases i.e. act as thermometers, with ESC activation in the medium, by the stimulus, converting such sensors to extracellular signalling molecules, the extracellular induction components (EICs), which induce thermal responses. Several ESC/EIC pairs trigger thermal responses, and have the unique property of giving early warning of the stress by diffusing to regions (and organisms) not yet exposed to elevated temperatures.

Transcriptional and post-transcriptional control of cold-shock genes

A mesophile like Escherichia coli responds to abrupt temperature downshifts (e.g. from 37 degrees C to 10 degrees C) with an adaptive response that allows cell survival and eventually resumption of growth under the new unfavorable environmental conditions. During this response, bulk transcription and translation slow or come to an almost complete stop, while a set of about 26 cold-shock genes is preferentially and transiently expressed. At least some of the proteins encoded by these genes are essential for survival in the cold, but none plays an exclusive role in cold adaptation, not even the "major cold-shock protein" CspA and none is induced de novo. The majority of these proteins binds nucleic acids and are involved in fundamental functions (DNA packaging, transcription, RNA degradation, translation, ribosome assembly, etc.). Although cold-induced activation of specific promoters has been implicated in upregulating some cold-shock genes, post-transcriptional mechanisms play a major role in cold adaptation; cold stress-induced changes of the RNA degradosome determine a drastic stabilization of the cold-shock transcripts and cold shock-induced modifications of the translational apparatus determine their preferential translation in the cold. This preferential translation at low temperature is due to cis elements present in the 5' untranslated region of at least some cold-shock mRNAs and to trans-acting factors whose levels are increased substantially by cold stress. Protein CspA and the three translation initiation factors (IF3 in particular), whose stoichiometry relative to the ribosomes is more than doubled during the acclimation period, are among the trans elements found to selectively stimulate cold-shock mRNA translation in the cold.

Bacterial cold shock responses

As a measure for molecular motion, temperature is one of the most important environmental factors for life as it directly influences structural and hence functional properties of cellular components. After a sudden increase in ambient temperature, which is termed heat shock, bacteria respond by expressing a specific set of genes whose protein products are designed to mainly cope with heat-induced alterations of protein conformation. This heat shock response comprises the expression of protein chaperones and proteases, and is under central control of an alternative sigma factor (sigma 32) which acts as a master regulator that specifically directs RNA polymerase to transcribe from the heat shock promotors. In a similar manner, bacteria express a well-defined set of proteins after a rapid decrease in temperature, which is termed cold shock. This protein set, however, is different from that expressed under heat shock conditions and predominantly comprises proteins such as helicases, nucleases, and ribosome-associated components that directly or indirectly interact with the biological information molecules DNA and RNA. Interestingly, in contrast to the heat shock response, to date no cold-specific sigma factor has been identified. Rather, it appears that the cold shock response is organized as a complex stimulon in which post-transcriptional events play an important role. In this review, we present a summary of research results that have been acquired in recent years by examinations of bacterial cold shock responses. Important processes such as cold signal perception, membrane adaptation, and the modification of the translation apparatus are discussed together with many other cold-relevant aspects of bacterial physiology and first attempts are made to dissect the cold shock stimulon into less complex regulatory subunits. Special emphasis is placed on findings concerning the nucleic acid-binding cold shock proteins which play a fundamental role not only during cold shock adaptation but also under optimal growth conditions.

Coping with the cold: the cold shock response in the Gram-positive soil bacterium Bacillus subtilis

All organisms examined to date, respond to a sudden change in environmental temperature with a specific cascade of adaptation reactions that, in some cases, have been identified and monitored at the molecular level. According to the type of temperature change, this response has been termed heat shock response (HSR) or cold shock response (CSR). During the HSR, a specialized sigma factor has been shown to play a central regulatory role in controlling expression of genes predominantly required to cope with heat-induced alteration of protein conformation. In contrast, after cold shock, nucleic acid structure and proteins interacting with the biological information molecules DNA and RNA appear to play a major cellular role. Currently, no cold-specific sigma factor has been identified. Therefore, unlike the HSR, the CSR appears to be organized as a complex stimulon rather than resembling a regulon. This review has been designed to draw a refined picture of our current understanding of the CSR in Bacillus subtilis. Important processes such as temperature sensing, membrane adaptation, modification of the translation apparatus, as well as nucleoid reorganization and some metabolic aspects, are discussed in brief. Special emphasis is placed on recent findings concerning the nucleic acid binding cold shock proteins, which play a fundamental role, not only during cold shock adaptation but also under optimal growth conditions.

Low-temperature-induced DnaA protein synthesis does not change initiation mass in Escherichia coli K-12

Expression of the dnaA gene continues in the lag phase following a temperature downshift, indicating that DnaA is a cold shock protein. Steady-state DnaA protein concentration increases at low temperatures, being twofold higher at 14 degrees C than at 37 degrees C. DnaA protein was found to be stable at both low and high temperatures. Despite the higher DnaA concentration at low temperatures, the mass per origin, which is proportional to the initiation mass, was the same at all temperatures. Cell size and cellular DNA content decreased moderately below 30 degrees C due to a decrease in the time from termination to division relative to generation time at the lower temperatures. Analysis of dnaA gene expression and initiation of chromosome replication in temperature shifts suggests that a fraction of newly synthesized DnaA protein at low temperatures is irreversibly inactive for initiation and for autorepression or that all DnaA protein synthesized at low temperatures has an irreversible low-activity conformation.

RbfA, a 30S ribosomal binding factor, is a cold-shock protein whose absence triggers the cold-shock response

The cold-shock response, characterized by a specific pattern of gene expression, is induced upon a downshift in temperature and in the presence of inhibitors of ribosomal function. Here, we demonstrate that RbfA of Escherichia coli, considered to be involved in ribosomal maturation and/or initiation of translation, is a cold-shock protein. Shifting the rbfA mutant to a lower temperature resulted in a constitutive induction of the cold-shock response accompanied by slower growth at low temperatures, while shifting the rbfA mutant that overproduces wild-type RbfA resulted in an increase in total protein synthesis accompanied by faster growth adaptation to the lower temperature. Furthermore, the cold-shock response was also constitutively induced in a cold-sensitive 16S rRNA mutant at low temperatures. Accompanying the transient induction of the cold-shock response, we also report that shifting E. coli from 37 degrees C to 15 degrees C resulted in a temporary inhibition of initiation of translation, as evidenced by the transient decrease in polysomes accompanied by the transient increase in 70S monosomes. The accumulative data indicate that the inducing signal for the cold-unadapted non-translatable ribosomes which are converted to cold-adapted translatable ribosomes by the association of cold-shock proteins such as RbfA. Therefore, the expression of the cold-shock response, and thus cellular adaptation to low temperature, is regulated at the level of translation. The data also indicate that cold-shock proteins can be translated by ribosomes under conditions that are not translatable for most mRNAs.

Hsc66, an Hsp70 homolog in Escherichia coli, is induced by cold shock but not by heat shock

Hsc66 is the second identified Hsp70 protein in Escherichia coli. Mutations in hscA, the gene encoding Hsc66, compensate for some phenotypic effects of a mutation in hns, a gene encoding the cold-inducible, nucleoid-associated protein H-NS. Expression of hscA was not induced upon heat shock but was induced approximately 11-fold 3 h after a shift from 37 to 10 degrees C. Furthermore, hscA was induced upon chloramphenicol addition, which induces the synthesis of other cold-inducible genes. Mapping of the transcription initiation site showed that hscA was cotranscribed with an upstream dnaJ-like gene, hscB; thus, hscB was also cold inducible. The hscBA promoter did not contain a Y-box element found in some cold-inducible promoters. Using two-dimensional electrophoresis, we identified Hsc66 under static 37 degrees C growth conditions and showed that Hsc66 was induced, as well as hscA, 3 h after a cold shock. Growth of an hscA mutant following cold shock was monitored relative to that of an isogenic wild-type strain. While cold shock adaptation as a function of growth rate was not significantly impaired in an hscA mutant, the expression of at least five other proteins was altered in this mutant following cold shock. On the basis of the homology to Hsp70 proteins and the induction following cold shock, we speculate that Hsc66 functions as a cold shock molecular chaperone.

The cold-shock response--a hot topic

The cold-shock response of Escherichia coli describes a specific pattern of gene expression in response to abrupt shifts to lower temperatures. This pattern includes the induction of cold-shock proteins, synthesis of proteins involved in transcription and translation, and repression of heat-shock proteins. The identified cold-shock proteins are involved in various cellular functions from supercoiling of DNA to initiation of translation. The major cold-shock protein, CspA, has high sequence similarity with three other E. coli proteins--CspB, CspC, and CspD. Using translational lacZ fusions, cspB was found to be cold-shock inducible at the level of transcription like cspA, while cspC and cspD were not. The Csp proteins, which share sequence similarity with other prokaryotic proteins and with the 'cold-shock domain' of eukaryotic Y-box proteins, may have a function in activating transcription or unwinding or masking RNA molecules. Because the cold-shock response can also be induced by the addition of certain inhibitors of translation, it has been proposed that the state of the ribosome is the physiological sensor for the induction. In addition to E. coli, cold-shock proteins have also been found in other prokaryotic and eukaryotic organisms.

Chloramphenicol induces the transcription of the major cold shock gene of Escherichia coli, cspA

A downshift in temperature or exposure of cells to certain inhibitors of translation has been shown to induce the synthesis of cold shock proteins in Escherichia coli. We characterized the induction of the major cold shock protein (CS7.4, the product of the cspA gene) of E. coli in response to a shift from 37 to 15 degrees C and in response to the addition of chloramphenicol at 15 degrees C. A pulse-labeling assay and primer extension experiments indicated that the cold shock treatment resulted in a transient increase in the level of the cspA transcript and a transient induction of CS7.4, while the addition of chloramphenicol resulted in a constitutive increase in the level of cspA transcript and constitutive production of CS7.4. The addition of rifamycin immediately following the temperature downshift or along with the addition of chloramphenicol repressed the transcription of cspA as well as the induced production of CS7.4. Furthermore, changes in the cspA mRNA level were coincident with changes in CS7.4 synthesis. These results indicate that the expression of cspA induced by cold shock and chloramphenicol is at the level of transcription but not at the level of translation. Measurement of the half-life revealed that the cspA mRNA induced by chloramphenicol was more stable than that induced by cold shock.

Characterization of twenty-six new heat shock genes of Escherichia coli

Most organisms respond to heat by substantial alteration of the pattern of gene expression. This has been particularly well studied with Escherichia coli although the response has by no means been completely characterized. Here we report the characterization of 26 new heat shock genes of E. coli, termed hsl, discovered by global transcription analysis with an overlapping lambda clone bank. We have measured the molecular weights of the corresponding heat shock proteins and mapped each of them to within a few kilobases on the E. coli genome. In vitro, 16 of them can be activated by the E sigma 32 RNA polymerase, which specifically transcribes heat shock genes. In vivo expression kinetics of seven of eight examined new proteins were found to be similar to those of the four most studied heat shock proteins, DnaK, DnaJ, GroEL (MopA), and GroES (MopB). In the course of this work, we confirmed that the catalytic subunit of the ATP-dependent Clp protease (also known as Ti protease), ClpP, is derived from a larger precursor protein. Possible assignments of some of the hsl genes to known proteins are discussed.

Transcription of the Escherichia coli rrnB P1 promoter by the heat shock RNA polymerase (E sigma 32) in vitro

The P1 promoters of the seven Escherichia coli rRNA operons contain recognition sequences for the RNA polymerase (RNAP) holoenzyme containing sigma 70 (E sigma 70), which has been shown to interact with and initiate transcription from rrn P1 promoters in vivo and in vitro. The rrn P1 promoters also contain putative recognition elements for E sigma 32, the RNAP holoenzyme responsible for the transcription of heat shock genes. Using in vitro transcription assays with purified RNAP holoenzyme, we show that E sigma 32 is able to transcribe from the rrnB P1 promoter. Antibodies specific to sigma 70 eliminate transcription of rrnB P1 by E sigma 70 but have no effect on E sigma 32-directed transcription. Physical characterization of the E sigma 32-rrnB P1 complex shows that there are differences in the interactions made by E sigma 70 and E sigma 32 with the promoter. E sigma 32 responds to both Fis-mediated and factor-independent upstream activation, two systems shown previously to stimulate rrnB P1 transcription by E sigma 70. We find that E sigma 32 is not required for two major control systems known to regulate rRNA transcription initiation at normal temperatures in vivo, stringent control and growth rate-dependent control. On the basis of the well-characterized role of E sigma 32 in transcription from heat shock promoters in vivo, we suggest that E sigma 32-directed transcription of rRNA promoters might play a role in ribosome synthesis at high temperatures.

Function of a relaxed-like state following temperature downshifts in Escherichia coli

Temperature downshifts of Escherichia coli throughout its growth range resulted in transient growth inhibition and a cold shock response consisting of transient induction of several proteins, repression of heat shock proteins, and, despite the growth lag, continued synthesis of proteins involved in transcription and translation. The paradoxical synthesis of the latter proteins, which are normally repressed when growth is arrested, was explored further. First, by means of a nutritional downshift, a natural stringent response was induced in wild-type cells immediately prior to a shift from 37 to 10 degrees C. These cells displayed decreased synthesis of transcriptional and translational proteins and decreased induction of cold shock proteins; also, adaptation for growth at 10 degrees C was delayed, even after restoration of the nutrient supplementation. Next, the contribution of guanosine 5'-triphosphate-3'-diphosphate and guanosine 5'-diphosphate-3'-diphosphate, collectively abbreviated (p)ppGpp, to the alteration in cold shock response was studied with the aid of a mutant strain in which overproduction of these nucleotides can be artificially induced. Induction of (p)ppGpp synthesis immediately prior to shifting this strain from 37 to 10 degrees C produced results differing only in a few details from those described above for nutritional downshift of the wild-type strain. Finally, shifting a relA spoT mutant, which cannot synthesize (p)ppGpp, from 24 to 10 degrees C resulted in a greater induction of the cold shock proteins, increased synthesis of transcriptional and translational proteins, decreased synthesis of a major heat shock protein, and faster adaptation to growth than for the wild-type strain. Our results indicate that the previously reported decrease in the (p)ppGpp level following temperature downshift plays a physiological role in the regulation of gene expression and adaptation for growth at low temperature.

Pleiotropic changes resulting from depletion of Era, an essential GTP-binding protein in Escherichia coli

Phenotypic analysis of a temperature-sensitive era mutant strain indicates that Escherichia coli cells depleted of Era undergo many physiological changes. At 43 degrees C, a completely non-permissive temperature, growth is arrested because of loss of the gene and depletion of the Era protein. Depletion of Era at 43 degrees C results in depressed synthesis of heat-shock proteins DnaK, GroEL/ES, D33.4 and C62.5, lack of thermal induction of ppGpp pool levels, and increased capacity for carbon source metabolism through the citric acid cycle. Thus, in addition to inhibition of cell growth and viability, loss of Era function results in pleiotropic changes including abnormal adaptation to thermal stress.

Ribosomes as sensors of heat and cold shock in Escherichia coli

Nearly all cells respond to an increase in temperature by inducing a set of proteins, called heat shock proteins (HSPs). Because a large number of other stress conditions induce the HSPs (or at least the most abundant ones), this response is often termed the universal stress response. However, a careful study of conditions that truly mimic a temperature shift suggested that these proteins are induced in response to a change in the translational capacity of the cell. To test this directly, Escherichia coli cells were treated with antibiotics that target the prokaryotic ribosome. Two-dimensional gels were used to evaluate the ability of these drugs to alter the rate of synthesis of the HSPs. One group of antibiotics induced the HSPs, whereas a second group repressed the HSPs and induced another set of proteins normally induced in response to a cold shock. Depending on the concentration used, the induction of the heat or cold shock proteins mimicked a mild or severe temperature shift. In addition, antibiotics of the cold shock-inducing group were found to block high temperature induction of the HSPs. The results implicate the ribosome as a prokaryotic sensor for the heat and cold shock response networks, a role it may serve in eukaryotes as well.

Effects of light deprivation on RNA synthesis, accumulation of guanosine 3'(2')-diphosphate 5'-diphosphate, and protein synthesis in heat-shocked Synechococcus sp. strain PCC 6301, a cyanobacterium

The rate of total RNA synthesis, the extent of guanosine 3'(2')-diphosphate 5'-diphosphate (ppGpp) accumulation, and the pattern of protein synthesis were studied in light-deprived and heat-shocked Synechococcus sp. strain PCC 6301 cells. There was an inverse correlation between the rate of total RNA synthesis and the pool of ppGpp, except immediately after a temperature shift up, when a parallel increase in the rate of RNA synthesis and accumulation of ppGpp was observed. The inverse correlation between RNA synthesis and ppGpp accumulation was more pronounced when cells were grown in the dark. Heat shock treatment (47 degrees C) had an unexpected effect on ppGpp accumulation; there was a fairly stable level of ppGpp under heat shock conditions, which coincided with a stable steady-state rate of RNA synthesis even in the dark. We found that the pattern of dark-specific proteins was altered in response to heat shock. The transient synthesis of several dark-specific proteins was abolished by an elevated temperature (47 degrees C) in the dark; moreover, the main heat shock proteins were synthesized even in the dark. This phenomenon might be of aid in the study of cyanobacterial gene expression.

Processing of precursor ribosomal RNA and the presence of a modified ribosome assembly scheme in Escherichia coli relaxed strain

An electrophoretic system capable of separating 25 S, 23 S, 17.5 S and 16 S ribosomal RNA (rRNA) species was used to study the synthesis and fate of rRNA during amino acid starvation and resupplementation of E. coli relaxed strain KL99. This E. coli relAl strain responded to an amino acid starvation by increasing the rate of synthesis of 25 S and 17.5 S precursor rRNA. When the limiting amino acid was resupplemented, a previously observed 40-fold increase in the cellular guanosine 5'-diphosphate, 3'-diphosphate content [Mol. Gen. Genet. (1983) 192, 5-9] appeared to cause a reduction in new rRNA synthesis. Following amino acid resupplementation, the precursor 25 S and 17.5 S rRNA accumulated during the amino acid starvation were conserved and processed to 23 S and 16 S rRNA species, respectively. This suggests that a modified ribosome assembly scheme involving stable precursor rRNA exists in relAl bacteria during periods of amino acid limitation and resupplementation.