Synthesis and decay of messenger ribonucleic acid from the lactose operon of Escherichia coli during amino-acid starvation

Model-based inference of gene expression dynamics from sequence information

A dynamic model of prokaryotic gene expression is developed that makes considerable use of gene sequence information. The main contribution arises from the fact that the combined gene expression model allows us to access the impact of altering a nucleotide sequence on the dynamics of gene expression rates mechanistically. The high level of detail of the mathematical model is considered as an important step towards bringing together the tremendous amount of biological in-depth knowledge that has been accumulated at the molecular level, using a systems level analysis (in the sense of a bottom-up, inductive approach). This enables to the model to provide highly detailed insights into the various steps of the protein expression process and it allows us to access possible targets for model-based design. Taken as a whole, the mathematical gene expression model presented in this study provides a comprehensive framework for a thorough analysis of sequence-related effects on the stages of mRNA synthesis, mRNA degradation and ribosomal translation, as well as their nonlinear interconnectedness. Therefore, it may be useful in the rational design of recombinant bacterial protein synthesis systems, the modulation of enzyme activities in pathway design, in vitro protein biosynthesis, and RNA-based vaccination.

Stationary phase, amino acid limitation and recovery from stationary phase modulate the stability and translation of chloramphenicol acetyltransferase mRNA and total mRNA in Escherichia coli

The functional stability of the chloramphenicol acetyltransferase (cat) mRNA, as well as the functional stability of the total mRNA pool, change during the course of Escherichia coli culture growth. mRNA half-lives are long during lag phase, decrease during the exponential phase and increase again during the stationary phase of the bacterial growth cycle. The half-lives of cat mRNA and total mRNA also increase three- to fourfold during amino acid starvation when compared to exponential culture growth. Even though the stability of the cat message changes about fourfold during culture growth, the amount of cat mRNA per cell mass does not vary significantly between the culture growth phases, indicating that there are compensating changes in cat gene transcription. Translation of cat mRNA also changes during culture growth. In exponential phase, the rate of cat translation is about 14-fold higher than when the culture is in stationary phase. This is in contrast to the fourfold increase in stability of cat mRNA in the stationary-phase culture compared to the exponentially growing culture and indicates that active translation is not correlated with increased mRNA stability. When a stationary-phase culture was diluted into fresh medium, there was a five- to sevenfold increase in CAT synthesis and a threefold increase in total protein synthesis in the presence or absence of rifampicin. These results suggest that while mRNA becomes generally more stable and less translated in the stationary-phase culture, the mRNA is available for immediate translation when nutrients are provided to the culture even when transcription is inhibited.

Synthesis and degradation of the mRNA of the Tn21 mer operon

The mercury resistance locus encoded by Tn21 on the monocopy IncFII plasmid R100 (merTn21) consists of a metal-responsive activator/repressor, merR, which controls initiation of a polycistronic message that includes genes for the uptake (merTPC) and reduction (merA) of Hg2+ and merD, which may also play a minor regulatory role. Comparison of the relative abundance of the 5' and 3' ends of the merTPCAD transcript revealed a strong transcriptional gradient in the operon, consistent with previous observations of lower relative abundance of the more promoter-distal gene products. In vivo mRNA degradation rates varied only slightly for the different genes: however, the rates of mRNA synthesis varied considerably from the beginning to the end of the operon. Specifically, mRNA corresponding to the promoter-proximal genes, merTPC, achieved a maximum in vivo synthesis rate between 60 and 120 seconds after induction; this rate was maintained for approximately ten minutes. In contrast, the synthesis rates of mRNA corresponding to the promoter-distal genes merA and merD, were initially fivefold lower than the rates of the promoter-proximal genes for the first five minutes after induction, and then rose gradually to approximately 50% of the merTPC synthesis rates. These data suggested that early after induction only 20% of the transcripts initiating at merT proceed beyond merC. At later times after induction approximately 50% of the transcripts proceed beyond merC. Nuclease end mapping did not reveal any discrete termination events in the merPCA region, thus, premature termination may occur at many sites.

Effects of translation on degradation of mRNA segments transcribed from the polycistronic puf operon of Rhodobacter capsulatus

Previous work has shown that expression of genes within the polycistronic puf operon of Rhodobacter capsulatus is regulated in part by differential degradation of segments of puf transcripts. To understand the role of ribosome coverage in the differential stability of puf mRNA segments, we have studied the effects of mutations that alter translation of specific puf transcript segments on puf mRNA decay. Our results show that stopping translation either within the light-harvesting I (LHI) genes or near the 5' end of the reaction center (RC)-coding region decreased the stability of puf transcript segments downstream from a hairpin loop structure located between the LHI and RC genes but failed to affect the upstream sequences so long as the loop was present. Mutations that allowed translation to proceed through the hairpin structure reduced its ability to protect upstream sequences from accelerated decay. Introduction of translation stops more than 107 bp into the RC-coding region, but still 5' to an mRNA segment containing decay-promoting endonuclease cleavage sites, had no effect on puf mRNA stability. The divergent and location-dependent consequences of translation stops imply that different mechanisms are responsible for the degradation of different puf mRNA segments and indicate that coverage of puf mRNA sequences by ribosomes is insufficient and may in some cases be unnecessary to protect these sequences from degradation.

Synthesis and degradation of lac mRNA in E. coli depleted of 30S ribosomal subunits

Escherichia coli was depleted of active ribosomes by a thermal shock at 47 degrees C which quantitatively destroyed the 30S ribosomal subunits. During recovery, RNA is synthesized while protein synthesis resumes only after about 90 minutes. It is shown that lac mRNA is synthesized in the complete absence of ribosomal activity and hence RNA synthesis is not coupled to protein synthesis. Transcription time and average transcript length were slightly less than in untreated cells. lac mRNA was degraded much more slowly in bacteria depleted of ribosomes. In E. coli W both functional half life (T 1/2 = 28 min vs. 2.25 in untreated cells) and chemical stability. The analysis of rna and pnp mutants showed that polynucleotide phosphorylase is involved in lac mRNA degradation in heat treated cells but that RNase I is not. The functional T 1/2 was increased in pnp mutants and was 95 min during the recovery period. The rate of chemical decay is so slow that the half-life cannot be accurately determined.

Altered mRNA metabolism in ribonuclease III-deficient strains of Escherichia coli

The metabolism of mRNA from the lactose (lac) operon of Escherichia coli has been studied in ribonuclease (RNase) III-deficient strains (rnc-105). The induction lag for beta-galactosidase from the first gene was twice as long, and enzyme synthesis was reduced 10-fold in one such mutant compared with its isogenic rnc+ sister; in the original mutant strain AB301-105, synthesis of beta-galactosidase was not even detectable, although transduction analysis revealed the presence of a normal lac operon. This defect does not reflect a loss of all lac operon activity galactoside acetyltransferase from the last gene was synthesized even in strain AB301-105 but at a rate several times lower than normal. Hybridization analyses suggested that both the frequency of transcription initiation and the time to transcribe the entire operon are normal in rnc-105 strains. The long induction lag was caused by a longer translation time. This defect led to translational polarity with reduced amounts of distal mRNA to give a population of smaller-sized lac mRNA molecules. All these pleiotropic effects seem to result from RNase III deficiency, since it was possible to select revertants to rnc+ that grew and expressed the lac operon at normal rates. However, the rnc-105 isogenic strains (but not AB301-105) also changed very easily to give a more normal rate of beta-galactosidase synthesis without regaining RNase III activity or a faster growth rate. The basis for this reversion is not known; it may represent a "phenotypic suppression" rather than result from a stable genetic change. Such suppressor effects could account for earlier reports of a noninvolvement of RNase III in mRNA metabolism in deliberately selected lac+ rnc-105 strains. The ribosomes from rnc-105 strains were as competent as ribosomes from rnc+ strains to form translation initiation complexes in vitro. However, per mass, beta-galactosidase mRNA from AB301-105 was at least three times less competent to form initiation complexes than was A19 beta-galactosidase mRNA. RNase III may be important in the normal cell to prepare lac mRNA for translation initiation. A defect at this step could account for all the observed changes in lac expression. A potential target within a secondary structure at the start of the lac mRNA is considered. Expression of many operons may be affected by RNase III activity; gal and trp operon expressions were also abnormal in RNase III- strains.

Translation and mRNA decay

Degradation of messenger RNA from the lactose operon (lac mRNA) was measured during the inhibition of protein synthesis by chloramphenicol (CM) or of translation-initiation by kasugamycin (KAS). With increasing CM concentration mRNA decay becomes slower, but there is no direct proportionality between rates of chemical decay and polypeptide synthesis. During exponential growth lac mRNA is cleaved endonucleolytically (Blundell and Kennell, 1974). At a CM concentration which completely inhibits all polypeptide synthesis this cleavage is blocked. In contrast, if only the initiation of translation is blocked by addition of KAS, the cleavage rate as well as the rate of chemical decay are increased significantly without delay. These faster rates do not result from immediate degradation of the lengthening stretch of ribosome-free proximal message, since the full-length size is present and the same discrete message sizes are generated during inhibition. These results suggest that neither ribosomes nor translation play an active role in the degradative process. Rather, targets can be protected by the proximity of a ribosome, and without nearly ribosomes the probability of cleavage becomes very high. During normal growth there is a certain probability that any message is in such a vulnerable state, and the fraction of vulnerable molecules determines the inactivation rate of that species.

Gene affecting longevity of messenger RNA: a mutant of Escherichia coli with altered mRNA stability

We have screened 897 temperature sensitive growth mutants of E. coli for mutant strains showing longer mRNA half-life. The fate of pulse-labelled RNA was examined at 42 degrees C after cessation of RNA synthesis and with prior exposure to nonpermissive temperature (42 degrees C). Eight stains showed altered turnover of RNA (presumably mRNA), and further analysis on mutant strain JE15144 indicated that the stability of pulse-labeled RNA as well as of tryptophan (trp) mRNA increased four to seven fold over its parental strain at 42 degrees C. At 4 min or 10 min after addition of rifampicin, some 70 to 80% of polyribosome in the growing cells could still be conserved in JE15144 cultured at the nonpermissive temperature while little, if any, polyribosomes remained in its parental strain (PA3092) under the same condition. Two generation times were required for complete stoppage of growth of this mutant strain after shifting to 42 degrees C, and protein synthesis continued at a significant, but slightly reduced, rate at 42 degrees C. However, functional decay of mRNA in the mutant strain, with respect to the capacity for producing peptides, appeared to be similar to the parent strain, with half-lives of 3.5 min in PA3092 and 4.7 min in JE15144.

Kinectics of beta-galactosidase synthesis in Escherichia coli at 5 C

The defect in protein synthesis that is observed in Escherichia coli after transfer to low temperature was studied. For the enzyme beta-galactosidase, the elongation reactions of transcription and translation can take place slowly but normally at 5 C. The time necessary to complete the coupled synthesis of the beta-galactosidase messenger ribonucleic acid and polypeptide chain was found to be about 80 min at 5 C. From this result and from the known length of the beta-galactosidase monomer, it is possible to calculate that at 5 C one amino acid is added to the growing polypeptide chain every 4 s. The initiation of transcription of the beta-galactosidase messenger is inhibited after transfer to 5 C. This fact alone, however, cannot account for all of the phenomena observed at 5 C, because a given amount of messenger yields less enzyme at 5 C than it does at 37 C. Furthermore, in cells induced for short periods at 37 C, the capacity to synthesize beta-galactosidase after transfer to 5 C was found to accumulate linearily with the square of the time of induction. Two alternative models could account for these data. If all ribosomes that initiate translation at 37 C yield complete beta-galactosidase polypeptide chains at 5 C, then an inhibition of translation initiation after transfer to 5 C must be invoked to explain the results. If, on the other hand, a substantial portion of the ribosomes that initiate translation at 37 C do not yield complete beta-galactosidase polypeptides at 5 C, then intracistronic polarity could account for the data, and there is no need to invoke an inhibition of translation initiation at 5 C.

Early changes in the messenger ribonucleic acid concentration of amino acid-starved cells of Escherichia coli are not dependent on the state of the rel gene

Measurements of the concentration of mRNA in rel(+) and rel(-) strains of Escherichia coli shortly after the imposition of amino acid deprivation indicate that there is a temporary fall in the amount of this fraction relative to the total cellular RNA.

Effect of preirradiation ribonucleic acid synthesis inhibition on resistance to ultraviolet light with resistant and sensitive strains of Escherichia coli B-r

The ultraviolet resistance of a streptolydigin-susceptible strain of Escherichia coli B/r hcr(-) increased during preirradiation treatment with streptolydigin (an inhibitor of deoxyribonucleic acid-dependent ribonucleic acid polymerase) for 20 min and then remained constant. During preirradiation treatment with chloramphenicol (an inhibitor of protein synthesis), resistance to ultraviolet light increased for 1 to 2 h, and reached a maximal level significantly above that attained in streptolydigin-containing medium. These results suggest that there are two mechanisms that function in Hcr(-) cells during chloramphenicol treatment which contribute to the concomitant ultraviolet resistance enhancement. One is ribonucleic acid dependent and is inhibited by streptolydigin. This ribonucleic acid-dependent mechanism appears to be absent in wild-type and RecA E. coli B/r strains.

Residual polarity and transcription-translation coupling during recovery from chloramphenicol or fusidic acid

Fusidic acid or chloramphenicol was used to inhibit peptide synthesis to 1% of normal in Escherichia coli B, strain AS19. After 10 min of inhibition, peptide synthesis could be quickly restored to 80% of the normal rate after washing the bacteria on a filter. However, even in the presence of adenosine 3'-5'-cyclic-monophosphoric acid to block catabolite repression, beta-galactosidase, the first enzyme of the lactose operon (lac), could only be induced to 10% of normal, and the last enzyme of the operon, galactoside acetyltransferase, even less. The first and last enzymes of the operon for tryptophan synthesis could be derepressed to about 30% of normal. The lac ribonucleic acid (RNA) induced during recovery showed a smaller than normal size distribution on sucrose gradients. The operator-proximal or -distal parts of this RNA were specifically labeled. Hybridization to phi80dlac deoxyribonucleic acid (DNA) suggested that although the distal parts of the lac RNA were barely detectable, initiation was occurring at normal rates in recovery. Either normal levels of distal messenger RNA (mRNA) are made but then rapidly degraded or the mRNA is not completed. The small amount that is made decayed abnormally slowly, probably as a result of slower transcription. Total mRNA decay was multiphasic with all components decaying slower than normal. We propose that there is a residual level of inhibition of peptide synthesis during recovery. The probability that a ribosome is blocked at any codon can be estimated from the data. The longer the message, the less likely its complete translation. We propose that the RNA polymerase can transcribe translatable mRNA for only a finite distance beyond the lead ribosome. Because ribosomes can load at the start of each message in a polycistronic mRNA, the probability that a distal message will be synthesized and translated is a function of the number of more proximal messages and the distances between their ribosome-loading sites.

The control of ribonucleic acid synthesis in bacteria. Fluctuations in messenger ribonucleic acid synthesis in cultures recovering from amino acid starvation

Changes in the cell content and rate of synthesis of mRNA were studied in auxotrophs of Escherichia coli recovering from a period of amino acid deprivation. Parallel studies were carried out on bacterial strains inhibited with trimethoprim, when glycine and methionine were added to relieve an amino acid deficiency. In the latter case, protein synthesis was still severely inhibited through a lack of N-formylmethionyl-tRNA(fMet) for chain initiation, so that fewer ribosomes were attached to mRNA chains. (1) In RC(str) strains recovering from amino acid starvation, there was a transient oversynthesis of mRNA, but the amounts returned to normal after about a 15-min period of recovery. RC(rel) strains did not show this effect; any extra mRNA accumulated during the previous starvation period was rapidly lost, but no oversynthesis occurred during the resumption of growth. (2) In trimethoprim-inhibited cultures supplemented with glycine and methionine, mRNA was produced at the same rate, relative to stable RNA species, as during normal growth. The evidence implied that decreased rates of ribosome attachment had no effect on the functional or chemical lifetime of the mRNA fraction. This suggests that mRNA stability does not depend on the frequency of translation by ribosomes. (3) Changes in the mRNA contents of trimethoprim-inhibited RC(str) and RC(rel) cultures were noted soon after supplementation with glycine and methionine. These closely followed those observed in cultures recovering from simple amino acid withdrawal.

Localization of polyribosomes containing alkaline phosphatase nascent polypeptides on membranes of Escherichia coli

A procedure has been developed for extracting membranes from bacterial cells under conditions that keep a large fraction of bacterial polyribosomes intact. Freeze-thawing spheroplasts in the presence of deoxyribonuclease, followed by differential centrifugation, permits a separation of free and membrane-associated polyribosomes. The latter fraction contains as much as 40% of cell ribosomal ribonucleic acid (RNA) and 55% of cell messenger RNA (mRNA). Nascent polypeptides were divided almost equally between the two fractions, but 70 to 80% of alkaline phosphatase nascent chains, detected both chemically and immunologically, were derived from polyribosomes associated with the bacterial membrane. Analysis of the fractions for mRNA specific for the lac and trp operons by RNA-deoxyribonucleic acid hydridization showed somewhat larger amounts on membrane than on free polyribosomes, but enrichment for nascent alkaline phosphatase (a secreted protein) on membranes was consistently greater, suggesting that polyribosomes making secreted proteins are more tightly bound to membranes. Electron micrographs of the membrane preparations show relatively intact membranes with clusters of polyribosomes on their inner surfaces.