Metabolism of messenger RNA from the gal operon of Escherichia coli

Post-transcriptional control of gene expression: bacterial mRNA degradation

Many biological processes cannot be fully understood without detailed knowledge of RNA metabolism. The continuous breakdown and resynthesis of prokaryotic mRNA permit rapid production of new kinds of proteins. In this way, mRNA levels can regulate protein synthesis and cellular growth. Analysing mRNA degradation in prokaryotes has been particularly difficult because most mRNA undergo rapid exponential decay. Prokaryotic mRNAs differ in their susceptibility to degradation by endonucleases and exonucleases, possibly because of variation in their sequencing and structure. In spite of numerous studies, details of mRNA degradation are still largely unknown. This review highlights those aspects of mRNA metabolism which seem most influential in the regulation of gene expression.

Messenger RNA Decay

This chapter discusses several topics relating to the mechanisms of mRNA decay. These topics include the following: important physical properties of mRNA molecules that can alter their stability; methods for determining mRNA half-lives; the genetics and biochemistry of proteins and enzymes involved in mRNA decay; posttranscriptional modification of mRNAs; the cellular location of the mRNA decay apparatus; regulation of mRNA decay; the relationships among mRNA decay, tRNA maturation, and ribosomal RNA processing; and biochemical models for mRNA decay. Escherichia coli has multiple pathways for ensuring the effective decay of mRNAs and mRNA decay is closely linked to the cell's overall RNA metabolism. Finally, the chapter highlights important unanswered questions regarding both the mechanism and importance of mRNA decay.

Effect of different conformations of galactose messenger RNA on gene expression and messenger half-life in vitro

From a DNA-directed cell-free system, functional gal mRNA is obtained which directs the cell-free synthesis of the three galactose enzymes of Escherichia coli. A substantial fraction of this gal mRNA has the properties of a polycistronic messenger. Exposure to elevated temperatures in the presence or absence of magnesium ion results in pronounced changes of the capacity of this mRNA to give rise to the synthesis of the three enzymes. Depending on the conditions of the pre-treatment, the absolute amounts as well as the ratio of the three gene products synthesized can be changed. The different forms of gal messenger so obtained also exhibit different susceptibilities towards functional inactivation during the enzyme synthesis reaction. As the changes in template activity are reversible, it is concluded that the different treatments cause reversible transitions between different conformations of the gal mRNA.

Control of mRNA processing and decay in prokaryotes

Post-transcriptional mechanisms operate in regulation of gene expression in bacteria, the amount of a given gene product being also dependent on the inactivation rate of its own message. Moreover, segmental differences in mRNA stability of polycistronic transcripts may be responsible for differential expression of genes clustered in operons. Given the absence of 5' to 3' exoribonucleolytic activities in prokaryotes, both endoribonucleases and 3' to 5' exoribonucleases are involved in chemical decay of mRNA. As the 3' to 5' exoribonucleolytic activities are readily blocked by stem-loop structures which are usual at the 3' ends of bacterial messages, the rate of decay is primarily determined by the rate of the first endonucleolytic cleavage within the transcripts, after which the resulting mRNA intermediates are degraded by the 3' to 5' exoribonucleases. Consequently, the stability of a given transcript is determined by the accessibility of suitable target sites to endonucleolytic activities. A considerable number of bacterial messages decay with a net 5' to 3' directionality. Two different alternative models have been proposed to explain such a finding, the first invoking the presence of functional coupling between degradation and the movement of the ribosomes along the transcripts, the second one implying the existence of a 5' to 3' processive '5' binding nuclease'. The different systems by which these two current models of mRNA decay have been tested will be presented with particular emphasis on polycistronic transcripts.

Lambda nutR mutations convert HK022 Nun protein from a transcription termination factor to a suppressor of termination

The Nun protein of the lambdoid phage HK022 blocks lambda growth by terminating transcription at (or near) the lambda nut sites. An HK022 lysogen carrying a fusion of the lambda pR promoter and nutR site to a gal operon that lacks its own promoter is, therefore, Gal-. To characterize the target of Nun action, spontaneous Gal+ revertants of this strain were isolated and characterized. Two cis-acting mutations are located in the fusion and represent transversions of conserved nucleotides within the boxA sequence (CGCTCTTA) of nutR. One mutation, (CTCTCTTA), is identical with boxA5. The second, boxA16 (CGCTATTA), has not been reported previously. In the absence of Nun, both boxA mutants reduce gal expression. Analysis of in vivo fusion RNA indicates that the mutations increase termination at or near tR1, a rho-dependent lambda terminator located upstream from the fusion point. In contrast to the nutR+ fusion, Nun stimulates gal expression in the boxA mutants by suppressing transcription termination in the tR1 region. Nun antitermination, however, does not extend to distal terminators. The lambda N-function also suppresses termination at or near tR1 in the mutant fusions. N fails to suppress terminators distal to tR1 in the boxA5 fusion, but displays persistent antitermination activity in the boxA16 fusion. A similar reversal of Nun activity occurs when wild-type fusions are introduced into nusA1, nusB5 or nusE71 hosts. We therefore suggest that Nun and N can interact with RNA polymerase in the absence of wild-type boxA, nusA, nusB or nusE, but that the complex formed with mutant components differs functionally from wild-type.

Purification and characterization of ribonuclease M and mRNA degradation in Escherichia coli

A previously unreported endoribonuclease has been identified in Escherichia coli, which has a preference for hydrolysis of pyrimidine-adenosine (Pyd-Ado) bonds in RNA. It was purified about 7000-fold to give a single band after SDS/polyacrylamide gel electrophoresis; the eluted protein gave the same RNase specificity. The sizes of the native and denatured enzymes agreed suggesting that the enzyme exists as a monomer of approximately 26 kDa. It is called RNase M. The only other reported broadly specific endoribonuclease in E. coli is RNase I, a periplasmic enzyme. Based on differences in charge, heat stability and substrate specificity, it was clear that RNase M is not RNase I. The specificity of RNase M was remarkably similar to that of pancreatic RNase A even though the two enzymes differ in charge characteristics and size. Earlier studies had shown that mRNA from the lactose operon of E. coli is hydrolyzed in vivo primarily between Pyd-Ado bonds [Cannistraro et al. (1986) J. Mol. Biol. 192, 257-274] We propose that this major RNase activity accounts for these cleavages observed in vivo and that it is the endonuclease for mRNA degradation in E. coli.

Terminal sequences do not contain the rate-limiting decay determinants of E. coli cat mRNA

The mechanism of E. coli chloramphenicol acetyltransferase (cat) mRNA decay was investigated. Alteration of the 5' untranslated terminus does not appear to have an effect on the turnover rate of the mRNA. Similarly, changes at the 3' terminus of the message, including the addition of a stable stem and loop structure, do not affect the half-life of the message. The data suggest that 5' and 3' terminal untranslated sequences do not contain the rate-limiting determinants for cat message decay. Decay rates for various segments of the cat mRNA were measured and indicate that all regions of the message have similar stabilities. The current model of cat mRNA degradation involves a rate-limiting endonucleolytic decay event that occurs internal to the message followed by degradation of the cleavage products.

Mechanisms of mRNA decay in bacteria: a perspective

Messenger RNA decay plays an important role in prokaryotic gene expression. The disparate stabilities of bacterial messages in vivo are a consequence of their differential susceptibility to degradation by cellular endoribonucleases and 3' -exoribonucleases, which in turn results from differences in mRNA sequence and structure. RNase II and polynucleotide phosphorylase, the major bacterial exonucleases involved in mRNA turnover, rapidly degrade single-stranded RNA from the 3' end, but are impeded by 3' stem-loop structures. At present, the identify and substrate specificity of the endonucleases that control mRNA decay rates are relatively poorly defined. Ribosomes and antisense RNA also can influence the stability of transcripts with which they associate. Differences in mRNA stability can contribute to differential expression of genes within polycistronic operons and to modulation of gene expression in response to changes in bacterial growth conditions.

Stabilization of translationally active mRNA by prokaryotic REP sequences

The REP sequence is a highly conserved inverted repeat that is present in about 25% of all E. coli transcription units. We show that the REP sequence can stabilize upstream RNA, independently of any other sequences, by protection from 3'-5' exonuclease attack. The REP sequence is frequently responsible for the differential stability of different segments of mRNA within an operon. We demonstrate that REP-stabilized mRNA can be translated in vivo and that cloning the REP sequence downstream of a gene can increase protein synthesis. This provides direct evidence that alterations in mRNA stability can play a role in determining bacterial gene expression. The implications of these findings for the mechanisms of mRNA degradation and for the role of RNA stability in the regulation of gene expression are discussed.

Induced mRNA stability in Bacillus subtilis

We have investigated the induced stability of mRNA encoded by the ermC gene in Bacillus subtilis. Induction of ermC gene expression by erythromycin is known to occur at the translational level. We show that this induction is accompanied by an increase in ermC mRNA half-life from about 2 min to about 40 min. Induced stabilization of ermC mRNA occurs independently of induced translation. The regulatory sequences required for stability are promoter-proximal and can confer induced stability on large mRNAs having diverse 3' ends. Translation of the ermC leader peptide and ribosome-stalling in the leader peptide sequence are necessary for induced stabilization.

Nucleotide sequence of the transcription unit containing the aroL and aroM genes from Escherichia coli K-12

The nucleotide sequence of 2,021 base pairs (bp) of DNA containing the Escherichia coli aroLM operon was determined, and the coding regions of both aroL and aroM were identified. The 501-bp intercistronic region between aroL and aroM contains an open reading frame which might encode a 63-residue protein. Northern blots with RNA from strains carrying multicopy aroL+ plasmids detected one longer (2,000-base) and two shorter (950- and 1,100-base) transcripts which contained aroL. It was concluded that the longest transcript, which was not abundant, spanned the entire operon and that the shorter transcripts resulted from either termination or posttranscriptional processing in the intercistronic region. The DNA upstream of aroL contains a number of imperfect palindromes which are closely homologous to known sites of regulation by the TyrR protein in other operons.

The relationship between translational initiation and messenger RNA inactivation in down-shifted Escherichia coli

The parameters of protein synthesis and functional inactivation of global messenger RNA (mRNA) were examined in a Tic+ strain of Escherichia coli during the 30-min period following a shift-down from glucose-minimal to succinate-minimal medium. The rate of mRNA inactivation and the relative translational initiation frequency were both most severely depressed immediately after the shift-down and increased slowly thereafter. If glucose was restored to the medium at any time after shift-down, mRNA inactivation immediately resumed its normal (preshift) rate and the protein-forming capacity was increased. These changes in mRNA inactivation rate do not reflect an altered mRNA composition in the down-shifted cells. The relative rate of mRNA inactivation was linearly proportional to the relative translational initiation frequency over a 10-fold range of initiation frequencies. Low initiation frequencies represent increased "dwell" of the ribosomes at the initiation site before the commencement of polypeptide chain initiation. We propose that initiating ribosomes protect mRNA from an inactivating endonucleolytic cleavage at or near the ribosome binding site.

The 5' ends of Escherichia coli lac mRNA

We identified the predominant 5' ends of an mRNA in Escherichia coli to the exact nucleotides. There are four such ends of lac mRNA in fully induced cells. About 70% of the molecules have the reported major in vitro end, A-A-U-U-G (at +1), which is located 38 nucleotides before the A-U-G translation start. Another 15% start with A-U-U-G at +2, and about 8% start with A-U-U-A-G at -52. A fourth class of molecules begin with either A-G, C-A-G, A-C-A-G, or a weak A-C-A-C-A-G (at +24), observed only once. The origins of this latter set (less than or equal to 10% of the total) are not known, but they could represent "ragged" ends of the mRNA when it is degraded to the beginning of the ribosome-protected region of the message. The A-U-U-A-G molecules are probably initiated from an upstream promoter whose position would coincide with the cAMP-CRP DNA binding site for the major promoter.

Differential expression of photosynthesis genes in R. capsulata results from segmental differences in stability within the polycistronic rxcA transcript

We report that the light-harvesting and reaction center genes in the rxcA locus of R. capsulata are contained within a single operon and that their differential expression results predominantly from marked segmental differences in stability within the polycistronic rxcA transcript. The 3' portion of this transcript is rapidly degraded to give rise to either of two slowly decaying mRNA remnants, both of which encode only the light-harvesting polypeptides. The greater stability of these remnants accounts for nearly all of the difference between the concentrations of the light-harvesting and reaction center proteins. The unstable 3' portion of the transcript is delimited by two alternative stem-and-loop structures, which apparently act as barriers to 3' exoribonucleases and thereby protect the upstream RNA segment. When a DNA fragment containing the rxcA locus was fused to a plasmid promoter and transcribed in E. coli, the long precursor transcript was processed to two short messages of greater stability, as in R. capsulata.

Organization and processing of the mitochondrial oxi3/oli2 multigenic transcript in yeast

In the present article, we confirm our previous proposal (Faye and Simon 1983a, b) that the oxi3 and oli2 genes belong to the same transcription unit. Furthermore, we have shown that a primary polycistronic transcript covers oxi3, aap1, oli2 and extends beyond URF2. Transcriptional analysis of this region revealed several cleavage points. The examination of the DNA sequence at and surrounding these cleavage points disclosed that some of them take place at or near specific sequences found also in other known multigenic transcripts. Two of the major cleavages involve the stem-loop structure of GC rich clusters. We discuss the possibility that some of these cleavage sites serve as post-transcriptional processing signals and may be necessary for the maturation of the precursor RNA.

Repetitive extragenic palindromic sequences: a major component of the bacterial genome

We describe a remarkably conserved nucleotide sequence, the many copies of which may occupy up to 1% of the genomes of E. coli and S. typhimurium. This sequence, the REP (repetitive extragenic palindromic) sequence, is about 35 nucleotides long, includes an inverted repeat, and can occur singly or in multiple adjacent copies. A possible role for the REP sequences in regulation of gene expression has been thoroughly investigated. While the REP sequences do not appear to modulate differential gene expression within an operon, they can affect the expression of both upstream and downstream genes to a small extent, probably by affecting the rate of mRNA degradation. Possible roles for the REP sequence in mRNA degradation, chromosome structure, and recombination are discussed.

Characterization of the mRNA coding for ribonucleoside diphosphate reductase in Escherichia coli

Total Escherichia coli RNA was separated by electrophoresis on methyl mercury agarose gels, transferred to diazobenzyloxymethyl-paper, and hybridized to various DNA probes containing different segments of the nrd genes to determine the organization of these genes. A 3.2-kilobase polycistronic mRNA transcript which hybridizes to both the nrdA and nrdB genes indicated that the nrdA and nrdB genes are organized in an operon. The polycistronic transcript contained the nrdA gene at the 5' end and the nrdB gene at the 3' end. The size of the polycistronic mRNA was sufficient to code for the 80,000-molecular-weight B1 protein and the 40,000-molecular-weight B2 protein. The results also indicated that the nrdA and nrdB genes are the only genes in E. coli that code for ribonucleoside diphosphate reductase. Two smaller RNA species that hybridized to nrd DNA were observed and probably overlap with the 3.2-kilobase nrd mRNA.

Amplification of ribonuclease II (rnb) activity in Escherichia coli K-12

A 7.1 kb HindIII-XhoI fragment of E. coli DNA which contains the structural gene for ribonuclease II (rnb) has been cloned in the recombinant plasmid pDK24. At least two constitutively expressed genes are encoded on the fragment as shown by maxicell analysis. On denaturing polyacrylamide gels RNase II appears as a single 72,000 dalton species. The approximate site of transcription initiation of the rnb gene has been mapped. Although derivatives of E. coli harboring pDK24 contained 10-fold more RNase II activity that wild type strains without the plasmid, the degradation rate of mRNA was similar in all strains tested. Strains deficient in both RNase II and polynucleotide phosphorylase appear inviable.

lac Transcription in Escherichia coli cells treated with chloramphenicol

When protein synthesis was blocked by chloramphenicol in vivo, transcription initiation of lac mRNA was severely inhibited. In a promoter mutant (L8-UV5) or in wild-type cells supplemented with adenosine 3',5'-phosphate (greater than or equal to 5 mM), nearly normal initiation could be achieved, and when the mRNA chains formed were extracted, they coded for the 5'-terminal alpha-peptide of the lacZ gene in vitro. However, even under such conditions, only a fraction of RNA polymerases proceeded to the end of the Z gene in the presence of chloramphenicol; as a consequence, a wide range of sizes of mRNA was produced, and very few transcripts were formed all the way to the natural termination site of the operon. In other words, premature transcription termination occurred in chloramphenicol-treated cells, as current models predict, but terminations occurred to variable extents at several intragenic sites and apparently at least one intergenic site. Termination at intragenic sites occurred far less in cells bearing a mutation in the transcription termination factor rho.

Lactose operon transcription from wild-type and L8-UV5 lac promoters in Escherichia coli treated with chloramphenicol

In cells treated with chloramphenicol and the inducer isopropyl-beta-D-thiogalacto-pyranoside, messenger ribonucleic acid transcription from the wild-type lac promoter was not detected. Transcription occurred from the mutant UV5-L8 promoter. The transcripts were of variable length; some included the whole Z gene. No major site of transcription arrest within the Z gene was apparent.

Evidence for endonucleolytic cleavage at the 5'-proximal segment of the trp messenger RNA in Escherichia coli

The 5'-proximal trp leader RNA segment (about 5S) decays at 2 to 3 times slower rates than the distal trp mRNA sequence. This has been demonstrated by employing the deletion mutants which lack a large portion of the structural genes but retain the promoter-proximal region of the trp operon. Relative stability of the leader RNA is not merely due to the presence of an untranslatable region in the segment; the internal untranslatable segment of trp mRNA downstream from the nonsense alteration site of a double mutant trpAD28.trpE9758 decays as fast as the normal trp mRNA sequence. These results suggest that the trp mRNA is endonucleolytically cleaved to yield the small 5'-proximal leader RNA segment before the distal mRNA decays and that the leader RNA sequence is not subject to usual mode of mRNA decay in the 5' to 3' direction.

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.

A gal region mutant that requires cAMP for growth on galactose in an adenyl cyclase negative (cya delta) background

Strains of Escherichia coli K12 that contain a deletion of the adenyl cyclase gen (cya delta), required for the synthesis of cyclic adenosine-3';5' monophosphate (cAMP), grow on galactose-containing minimal medium. A mutant was isolated that grows on this medium only if cAMP is added. The mutation (designated galP20) is linked to the gal operon region as determined by both generalized transduction with bacteriophage P1 and specialized transduction with bacteriophage lambda. Studies with galP20 cya delta strains as well as gal delta (deletions of the gal operon) cya delta strains indicate that synthesis of the physiologically important transport mechanism for galactose (galactose permease) requires either cAMP or a function mission from both the galdelta strains and the galP20 strain.

Genetic inversion in the formation of an Hfr strain from a temperature-sensitive F' gal strain

An Hfr strain (PB15) that carries a duplicated copy of the galactose operon genes flanking the integrated sex factor is unusually stable since it does not show excision of the repeated deoxyribonucleic acid segment. The right-hand galactose operon is in the normal orientation. Deletion mutations that eliminate the right-hand galactose genes, the sex factor, and some of the left-hand operon have been isolated. Mutants believed to have their left-hand galactose operon inverted were able to be induced for galactose epimerase synthesis by D-fucose but did not show escape synthesis on induction of bacteriophage lambda. Ribonucleic acid specific for the galactose operon was isolated after induction of lysogenic strains presumed to carry the galactose operon in the normal and inverted orientation. Hybridization to the isolated left and right strands of lambdapgal showed that the noninformational strand of the left-hand galactose operon of the deletion mutant of PB15 was transcribed on escape induction. These results show that inversion has occurred.

Arrangement and regulation of the nitrogen fixation genes in Klebsiella pneumoniae studied by depression kinetics

Events underlying depression of the nitrogen fixation (nif) genes in Klebsiella pneumoniae M5A1 were analyzed in vivo by comparing the effects of selective inhibitors of transcription and translation on subsequent nitrogenase activity (rate of acetylene reduction). When batch cultures were induced for depression, an 87-min lag separated ammonium ion/oxygen removal and the appearance of activity.

Functional half-lives of bacteriophage m13 gene 5 and gene 8 messages

The half-lives of the M13 gene 5 and gene 8 messages were determined by measuring the decay in the rate of synthesis of the gene 5 and gene 8 proteins after inhibition of new RNA chain initiations with rifampin. The gene 5 and gene 8 messages decay with half-lives of approximately 2.5 and 5 min, respectively. We found no evidence of a functional M13 message with a half-life as long as that reported for hybridizable mRNA.

Early gene expression in bacteriophage T7. I. In vivo synthesis, inactivation, and translational utilization of early mRNA's

In vivo decay rates for the individual T7 early mRNA species were determined. The physical half-lives, measured at 37 C, range from 1.1 min for gene 0.7 RNA to 4.5 min for gene 0.3 RNA. Physical half-lives, as observed after rifampin inhibition of RNA synthesis and polyacylamide electrophoresis of RNAs, are approximately 30% longer than functional half-lives, as observed by 14C-labeled amino acid uptake into individual T7 early proteins. The different RNA species are synthesized at grossly different rates, 0.3 RNA at four times the rate of 1.0 RNA, 0.7 RNA at twice the rate, and 1.1 and 1.3 RNAs at about the same or a slightly lower rate than 1.0 RNA. Rho-factor-mediated termination of transcription behind genes 0.3, 0.7, and perhaps behind 1.0 is inferred from these data. The in vivo translational utilization of the individual T7 early-message species was found to vary by not more than a factor of 2.

Analysis of enzyme induction in bacteria

The theoretical relations between the induced initiation and accumulation of lac mRNA and its translation are derived, taking the kinetics of repressor-operator dissociation and enzyme maturation into account. These relations are used to evaluate observed data on lac induction and to estimate a number of parameters that characterize the transcription and translation of the beta-galactosidase gene in the bacterium Escherichia coli B/r growing at three different rates (0.7-2.1 doublings/h).