NusA Is Required for Ribosomal Antitermination and for Modulation of the Transcription Elongation Rate of both Antiterminated RNA and mRNA*

(Received for publication, October 11, 1996, and in revised form, February 14, 1997)

Ulla Vogel Dagger § and Kaj Frank Jensen par

From the Dagger  Department of Biological Chemistry and  Center of Enzyme Research, Institute of Molecular Biology, University of Copenhagen, Sølvgade 83H, DK-1307 Copenhagen K, Denmark

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Ribosomal RNA (rRNA) is elongated twice as fast as mRNA in vivo due to the presence of antitermination sequences in the 5' part of the rRNA transcripts. A number of Nus factors bind to RNA polymerase at the antitermination sites and help confer resistance to Rho-dependent termination of transcription. In this paper, the effects of the nusAcs10 allele on the elongation rate of both mRNA and antiterminated RNA were investigated. The results indicate that NusA is required to achieve a high elongation rate of RNA chains carrying the ribosomal antitermination boxA and that antitermination is defective when the rate of transcription elongation is decreased by the nusAcs10 allele. Furthermore, the nusAcs10 allele had no significant effects on the elongation rate of normal lacZ mRNA during steady state growth, but it abolished the inhibition of lacZ mRNA elongation by guanosine 3',5'-bis(diphosphate) (ppGpp). These results suggest that NusA is the component of the transcription elongation complex required for inhibition of mRNA elongation by ppGpp.


INTRODUCTION

Messenger RNA chains are elongated at a rate of 40-50 nucleotides (nt)1/s during steady state growth, and the elongation rate is reduced to 20 nt/s in the presence of high intracellular concentrations of ppGpp (1, 2), which accumulate during the stringent response (3). Ribosomal RNA, on the other hand, is elongated at a rate of 80-90 nt/s, and the rRNA chain elongation rate appears to be unaffected by the stringent response (1, 4). The high rate of rRNA chain elongation depends on the presence of the antitermination sequences in the rRNA transcripts, and the incorporation of such an antitermination sequence, i.e. the boxA sequence, into lacZ resulted in an increase in the RNA chain elongation rate during steady state growth from 40-50 nt/s to 70-80 nt/s and made lacZ mRNA chain elongation insensitive to inhibition by ppGpp (4).

The ribosomal antitermination boxes were identified on the basis of their homology to the nut sites of bacteriophage lambda  (5, 6). The antiterminated transcription complex of phage lambda  consists of RNA polymerase in association with the lambda -encoded N-protein and the host factors NusA, NusB, NusE (S10), and NusG (7), but the antiterminated transcription complex for ribosomal RNA is less well defined. It has been shown that the complex contains NusB and NusG and that it probably contains NusA as well (8, 9, 10). Furthermore, factors other than the known Nus factors are needed for proper ribosomal antitermination in vitro (9).

In addition to being a part of the antitermination complex, NusA becomes associated with the core polymerase shortly after release of the sigma  factor (11, 12), but the complex constantly dissociates and reforms during transcription elongation (13). NusA has also been reported to induce pauses during in vitro transcription, to reduce the rate of elongation, and to stimulate termination at intrinsic terminators (7, 13-15).

We have investigated the effect of NusA on transcription elongation in vivo by measuring the RNA elongation rate in a strain containing the nusAcs10 allele. Our results suggest NusA is required both for ribosomal antitermination and for maintaining the high elongation rate of antiterminated RNA, since the nusAcs10 mutant showed a considerable level of premature termination of boxA-lacZ mRNA chains and was unable to sustain a high elongation rate of RNA chains carrying the boxA sequence.


EXPERIMENTAL PROCEDURES

Strains and Plasmids

The strains and plasmids used are listed in Table I.

Table I. Strains and plasmids


Name Description Source

Bacterial strains
  MAS78 thi Delta (pro-lac)recA1 M. Sørensen
  NF1830 MC1000 recA1/F'lacI9q1lacZ::Tn5 proAB+ N. Fiil
  SØ3829 thi araD139 Delta (lacU169) relA Ref. 18
  SØ6075 thi araD139 Delta (lacU169) relA nusAcs10 Ref. 14
  SØ6100 thi araD139 delta (lacU169) relA wxz::Tn10 This work
  SØ6681 thi araD139 Delta (lacU169) relA nusAcs10 wxz::Tn10 This work
  SØ6718 thi Delta pro-lac recA1 nusAcs10 wxz::Tn10/F'lacIq1lacZ::Tn5 proAB+ This work
  SØ6719 thi Delta pro-lac recA1 wxz::Tn10/F'lacIq1lacZ::Tn5 proAB+ This work
  YN2458 gal1 gal2 lac rpsL supo nusAts11 wxz::Tn10 Ref. 18
Plasmids
  pMAS53 recA+ repts clmr M. Sørensen
  pUV12 PA1/04/03 lacZ apr Ref. 19
  pUV16 PA1/04/03 boxA-lacZ apr Ref. 4

The MC4100 derivatives, SØ6100 and SØ6681, were constructed to have the nucAcs10 allele (16) linked with the tetracycline resistance marker, wxz::Tn10 (17). The first strain was constructed by P1 transduction using the nusAts11 wxz::Tn10 strain YN2458 (17) as the donor and the nusA+ strain SØ3829 (18) as the recipient. Resistance to tetracycline (5 µg/ml) was selected at 32 °C. After testing for growth on LB broth at 43 °C, a temperature-resistant colony (SØ6100) was chosen. Strain SØ6681 was constructed by transduction of the nusAcs10 strain, SØ6075 (14), with a P1 phage lysate grown on SØ6100 (wxz::Tn10), selecting for resistance to tetracycline on LB broth at 39 °C and isolating a colony unable to grow at 25 °C.

The isogenic pair of strains, SØ6718 and SØ6719, was constructed to have the nusAcs10 mutation in the genetic background, MAS90, previously used for measurements of transcription elongation rates (1, 2, 4, 19). To facilitate this construction, the recombination-deficient strain, MAS78, was transformed with plasmid pMAS53, which encodes resistance to chloramphenicol, harbors a functional recA gene, and has a temperature-sensitive replication function (a generous gift from M. Sørensen, to be described elsewhere). The transformant, MAS78-pMAS53, was subsequently transduced with a P1 phage lysate grown on SØ6681 selecting for resistance to tetracycline (5 µg/ml) at 39 °C. The transductants were tested for the inability to grow at 25 °C (the nusAcs10 phenotype), sensitivity to nitrofurantoin (the recA phenotype), and sensitivity to chloramphenicol (the loss of plasmid pMAS53). One cold-sensitive colony (a nusAcs10 wxz::Tn10 mutant) and one colony able to grow at 25 °C (a nusA+ wxz::Tn10 strain) were chosen and subsequently mated with NF1830 for transfer of the F'lacIq1lacZ::Tn5 proAB+ episome by selecting for resistance to kanamycin on glucose minimal medium at 39 °C. These latter F' derivatives were named SØ6718 and SØ6719.

Media and Growth

The bacteria were grown in shaking flasks in A + B medium (20) supplemented with 0.2% glucose, 1 µg/ml thiamine, and 100 µg/ml ampicillin at the indicated temperature. Isoleucine starvation was induced by the addition of 0.4 mg/ml valine. Transcription from the PA1/04/03 promoter was induced by the addition of 1 mM IPTG (final concentration). Transformations with plasmids were performed by standard techniques. LB broth medium and solid media were prepared as described by Miller (21).

RNA Techniques

RNA sampling and purification was performed as described previously (2); dot blots and hybridization were performed as described by Vogel and Jensen (1), except that GeneScreen Plus hybridization transfer membranes from DuPont NEN were used for some experiments instead of GeneScreen membranes. The riboprobe plasmids employed and the procedure for in vitro transcription in the presence of [alpha -32P]UTP (DuPont NEN) have also been described (1, 2). The radioactivity on the dot blots was quantified on an Instant Imager (Canberra-Packard).

Determination of Transcription Elongation Rates

The transcription times of the lacZ gene on pUV12 and of the boxA-lacZ construct on pUV16 were determined as the time lag between induction of transcription initiation at the PA1/04/03 promoter by the addition of IPTG and detection of specific hybridization to a probe complementary to the 3' end of the lacZ transcripts. Transcription elongation rates were calculated by dividing the length of the transcript (3107 nt for pUV12 and 3104 nt for pUV16) with the measured transcription time (2, 4). While the transcription times measured in these experiments were very reproducible, the absolute amount of radioactivity in the dots varied severalfold between identical experiments due to variations in the specific radioactivity of the probe, the number of times it was used, and the type of hybridization membrane employed, i.e. GeneScreen or GeneScreen Plus membranes. Therefore, the slopes of the induction curves are generally meaningless, and they can only be compared for experiments where hybridization was performed in parallel on the same membrane. In most cases, the transcription time was determined in two independent experiments, which were separated in time by days or weeks and included separate inoculation of cultures as well as growth of cells, sampling, preparation of RNA, and dot hybridization. However, to simplify the presentation, the two curves are shown in a normalized way where the radioactivity in the dots from one experiment was multiplied by a constant factor to superimpose the one induction curve on the other. The employed normalization factors ranged from 1 to 25 for the different panels in Fig. 2 and 3. 


Fig. 2. Induction of lacZ mRNA synthesis in nusAcs10 and nusA+ strains harboring pUV12. Strain SØ6718 (nusAcs10; panels B and D) and the corresponding nusA+ stain SØ6718 (panels A and C) both harboring pUV12 were grown in a glucose minimal medium containing 0.1 mg/ml ampicillin. At time 0, IPTG (1 mM) was added to the cultures. A436 was very close to 0.5 at the time of induction. Transcription was either induced during steady state growth (A and B) or 6 min after the onset of isoleucine starvation, which was provoked by the addition of 0.4 mg/ml valine (C and D). RNA was extracted at the indicated times after induction and used for dot blot hybridization with the 3' lac probe (see Fig. 1). The amount of hybridization was quantified in an Instant Imager (Canberra-Packard), and cpm was plotted versus sampling time. All of the experiments were performed at least two times, and different symbols designate independent experiments. However, to simplify the presentation the two curves in each panel were superimposed on each other using the normalization procedure described under "Experimental Procedures." Thus, the slopes of the induction curves in the different panels are not comparable.
[View Larger Version of this Image (23K GIF file)]

Determination of the Parameter rs/rt

Determination of the instantaneous rates of stable RNA initiations relative to total RNA (rs/rt) was performed as described by Baracchini et al. (22). Aliquots of the cultures (0.5 ml) were labeled with [3H]uridine (10 µCi, 43 Ci/mmol) for 60 s. Total RNA synthesis was determined as the amount of radioactivity in trichloroacetic acid-insoluble material, while ribosomal RNA synthesis was quantified by filter hybridization with plasmid pKK3535 DNA (23) or pBR322 for determination of background. 32P-Labeled Escherichia coli RNA was used as an internal control of hybridization efficiency.

RNA Accumulation

The differential rate of accumulation of RNA was measured photometrically as trichloroacetic acid-precipitable, NaOH-labile material absorbing UV light at 260 nm as described by Vogel et al. (24).

Determination of Nucleotide Pools

This was performed using a medium containing 0.3 mM [32P]phosphate (~200 Ci/mol) as described by Vogel et al. (24). The amount of radioactivity incorporated into the nucleotides was quantified on an Instant Imager (Canberra-Packard).


RESULTS

To test the effect of NusA on the rate of transcription elongation in vivo, we used the conditionally lethal nusAcs10 mutation, since the nusA gene can only be deleted in Rho-deficient strains (25). Strains harboring the nusAcs10 mutation are cold-sensitive and unable to grow at temperatures below 30 °C (16). The mutation was also shown to cause a defect in N-mediated transcriptional antitermination in bacteriophage lambda  (16), and it has been proposed to impose a defect in ribosomal antitermination, because it causes an increase in the rate of synthesis of tRNAs encoded outside the ribosomal operons, relative to those encoded inside these operons (10). The nusAcs10 mutant, SØ6718, and the isogenic nusA+ strain, SØ6719, were grown in a glucose minimal medium at 34 °C, which is a semipermissive temperature for the nusAcs10 mutant. The generation times were 60 min for the wild type and 72 min for the nusAcs10 mutant.

Transcription elongation rates were measured using the plasmids pUV12 and pUV16 (Fig. 1), which both contain lacZ inserted behind the strong IPTG-inducible PA1/04/03 promoter. Plasmid pUV12 contains a normal lacZ gene, while pUV16 contains the minimal ribosomal antitermination boxA sequence and flanking regions, i.e. the sequence 5'-CACTGCTCTTTAACAATTTA-3', inserted between the promoter and the structural lacZ gene. This minimal boxA sequence has previously been shown to be both necessary and sufficient for proper antitermination in vitro and in vivo (6, 9). Transcription rates were determined following induction of transcription initiation at the PA1/04/03 promoter by the addition of IPTG and hybridization to a probe complementary to the 3' end of the lacZ transcripts (see "Experimental Procedures").


Fig. 1. Schematic presentation of the employed plasmids. Genes are represented by open bars. P/O, promoter/operator site of PA1/04/03; T, transcription terminator sequence; ', truncated gene; thick lines, probe complementary to the transcripts at the indicated positions relative to the 5' end.
[View Larger Version of this Image (14K GIF file)]

Elongation of lacZ mRNA Chains in the nusAcs10 Mutant

The transcription time of the unmodified lacZ gene on pUV12 was 90 s during steady state growth of the wild type strain at 34 °C (Fig. 2A), corresponding to an elongation rate of 35 nt/s. During the stringent response, provoked by inducing starvation for isoleucine, the transcription time increased to 160 s (Fig. 2C), in agreement with previous results (1, 2). For the nusAcs10 mutant the transcription time was 95 s (33 nt/s) during steady state growth (Fig. 2B), indicating that nusAcs10 does not disturb mRNA chain elongation during steady state growth. However, no inhibition of transcription elongation was observed during the stringent response, since the transcription time was 90 s under these growth conditions (Fig. 2D). These results suggested that the nusAcs10 allele abolished inhibition of transcription elongation by ppGpp, since the nusAcs10 mutant accumulated even more ppGpp than the wild type strain during the stringent response (Table II).

Table II. Nucleotide pools in the nusAcs10 mutant compared with the nusA+ cells (pmol/A436/ml)


Nucleotide nusA+
nusAcs10
Steady state Stringent response Steady state Stringent response

GTP 460 330 640 300
ATP 950 970 995 1100
CTP 160 320 190 350
UTP 180 240 210 270
ppGpp 24 310 47 710

Elongation of Antiterminated boxA-lacZ mRNA

For the nusA+ strain, the transcription time of the antiterminated boxA-lacZ construct carried on pUV16 was 55 s both during steady state growth at 34 °C and during amino acid starvation (Fig. 3, A and C). This indicates that insertion of the antitermination boxA is sufficient both to elevate the elongation rate and render chain elongation insensitive to ppGpp, as previously observed (4). In the nusAcs10 mutant, however, the transcription time of the boxA-lacZ gene was 80 s during steady state growth (Fig. 3B), corresponding to an elongation rate of 38 nt/s, and it increased to about 95 s during the stringent response (Fig. 3D). The elongation rate observed during steady state growth (38 nt/s) is similar to the elongation rate (33 nt/s) found for the normal lacZ mRNA and much lower than the elongation rate of the boxA-lacZ RNA observed in wild type cells (57 nt/s). These results suggest that the nusAcs10 mutant is unable to achieve a high rate of transcription elongation despite the presence of the boxA antitermination sequence.


Fig. 3. Induction of boxA-lacZ RNA synthesis in nusAcs10 and nusA+ strains harboring pUV16. Strain SØ6718 (nusAcs10; panels B and D) and the corresponding nusA+ stain SØ6719 (panels A and C) both harboring pUV16 were grown in a glucose minimal medium containing 0.1 mg/ml ampicillin. At time 0, IPTG was added to 1 mM. Transcription was either induced during steady state growth (A and B) or 6 min after the onset of isoleucine starvation induced by the addition of 0.4 mg/ml valine (C and D). The experimental procedures were the same as those described in the legend to Fig. 2. The slopes of the induction curves in the different panels are not comparable. The experiments were performed at least twice, except for the curve shown in panel C. However, the transcription elongation rates of the nusA+ stain transformed with pUV16 has previously been analyzed carefully at 37 °C (4).
[View Larger Version of this Image (23K GIF file)]

Transcriptional Polarity

To determine the extent of premature transcription termination within boxA-lacZ during the stringent response, we quantified both the accumulation of 5' ends, which we interpret as the rate of initiation at the PA1/04/03 promoter, and the accumulation of 3' ends of the resulting RNA chain (Fig. 4). The slopes of these induction curves, which were made in parallel on the same membrane to ensure uniform hybridization, were identical during steady state growth and during amino acid starvation, both for the wild type and for the nusAcs10 mutant (Fig. 4, A and B). This indicates that transcription initiation at the PA1/04/03 promoter is insensitive to ppGpp, as seen previously (4, 15). For the wild type strain, the slopes of the curves representing the accumulation of 3' ends of the boxA-lacZ transcripts were also identical during steady state growth and amino acid starvation (Fig. 4C), but for the nusAcs10 mutant, the rate of accumulation of 3' ends of the boxA-lacZ transcript was reduced 4-fold after the onset of amino acid starvation (Fig. 4D). Therefore, we conclude that the minimal ribosomal boxA sequence is unable to suppress premature transcription termination in a strain harboring the nusAcs10 mutation.


Fig. 4. Levels of premature transcription termination in the boxA-lacZ gene in nusAcs10 and nusA+ cells. The 5' lacZ probe shown in Fig. 1 was used to quantify the accumulation of the 5' end of boxA-lacZ RNA in the nusAcs10 strain SØ6718 (panel B) and the nusA+ strain SØ6719 (panel A) carrying pUV16. Transcription was either induced during steady state growth (filled circles) or 6 min after the addition of 0.4 mg/ml valine (open circles). For comparison of the slopes, the induction curves using the late lacZ probe (Fig. 1) during steady state growth (filled circles) and during the stringent response (open circles) were plotted in the same panel (nusA+ in panel C and nusAcs10 in panel D). The induction curves for panels A and B and for panels B and D were derived from hybridizations that were made in parallel with the early probe and the late probe, respectively.
[View Larger Version of this Image (20K GIF file)]

The transcription elongation rates measured for the two transcripts under different growth conditions are summarized in Table III.

Table III. Summary of transcription elongation rates in the isogenic pair of strains, SØ6719 (nusA+) and SØ6718 (nusAcs10), grown at 34 'C


Gene Growth condition Transcription elongation rates
nusA+ nusAcs10

nt/s
lacZ Exponential 35 33
lacZ Starved 19 38
boxA-lacZ Exponential 57 38
boxA-lacZ Starved 57 33

Control of RNA Synthesis during the Stringent Response

The inhibition of transcription elongation, normally observed during the stringent response, has been proposed by Jensen and Pedersen (26) to play a major role in the passive regulation of rRNA synthesis by sequestering RNA polymerase in the elongation phase and thus lowering the concentration of free RNA polymerase. Since the nusAcs10 mutant did not change the transcription elongation rate of mRNA, it could be used to test if the decreased mRNA elongation rate is important for the regulation of stable RNA synthesis during the stringent response. The rate of total RNA synthesis, measured as the incorporation of [3H]uridine into acid-insoluble material during 60-s pulses (Fig. 5A) or as the UV absorption of alkaline RNA hydrolysates (not shown), decreased strongly both in the nusA+ strain and the nusAcs10 mutant after the onset of amino acid starvation. Furthermore, the parameter rs/rt, which represents the fraction of de novo RNA synthesis devoted to stable RNA, decreased from 0.45 to 0.30 during the stringent response both for the wild type strain and for the nusAcs10 mutant (Fig. 5B). This indicates that relative rates of initiation of mRNA and rRNA synthesis is normally regulated during the stringent response in the nusAcs10 mutant despite the constant RNA chain elongation rate.


Fig. 5. Regulation of RNA synthesis in the nusAcs10 mutant during the stringent response. Panel A shows the incorporation of radioactivity in total RNA during a 60-s pulse with [3H]uridine. Filled circles represent the nusA+ strain SØ6719; open circles represent the nusAcs10 mutant SØ6718. Panel B shows the rs/rt ratio determined by hybridization to rrn DNA immobilized on nitrocellulose filters as described by Baracchini et al. (22).
[View Larger Version of this Image (15K GIF file)]


DISCUSSION

Our results show that antiterminated boxA-lacZ RNA is elongated at a slower rate in the nusAcs10 mutant than in the wild type strain, and that the nusAcs10 allele abolishes the inhibition of normal lacZ mRNA chain elongation by ppGpp without affecting the elongation rate during steady state growth. The nusAcs10 allele contains two different mutations, which, in combination, confer cold sensitivity to the host (27). When the two mutations are separated, the lambda -plating type is linked to the mutation at nucleotide 634 in the nusA gene. It is therefore possible that the two different effects of nusAcs10, i.e. the decreased elongation rate of antiterminated RNA and the resistance to ppGpp inhibition, are caused by different mutations.

The nusAcs10 allele prevented boxA-mediated suppression of polarity in the boxA-lacZ transcript, suggesting that the mutant is unable to antiterminate rRNA normally, in agreement with the observations of Sharrock et al. (10). Ribosomal antitermination is equivalent to the suppression of Rho-dependent transcription termination in the rrn operons (28, 29) and Rho-dependent termination has been proposed to depend on the kinetic coupling between the RNA polymerase and Rho (30). Thus, it is possible that the antiterminated RNA polymerase may simply escape Rho-dependent termination by running away from Rho as suggested by several groups (7, 28, 30). Our results are in agreement with this interpretation.

The observation that the nusAcs10 mutation caused resistance to inhibition of normal lacZ mRNA elongation by ppGpp indicates that NusA is part of the elongation complex for normal mRNA in vivo. This is in agreement with several previous observations from both in vitro and in vivo experiments (12-14). However, it also indicates that NusA is important for inhibition of mRNA chain elongation by ppGpp, although Kingston et al. (15) observed that ppGpp inhibited elongation of the early transcript of phage T7 in vitro without adding the NusA protein to the transcription mixtures.

We found that the ratio between rRNA and total RNA initiations (rs/rt) decreased from 0.45 to 0.30 following induction of amino acid starvation, both in the nusAcs10 mutant and in the isogenic nusA+ strain. This indicates that the ratio between rRNA and mRNA synthesis is normally regulated in the nusAcs10 mutant during amino acid starvation and, thus, that the inhibition of transcription elongation and pausing by ppGpp does not play the major role in the regulation of rRNA synthesis during the stringent response as proposed by Jensen and Pedersen (Ref. 26; but see Ref. 31). The nusAcs10 mutant, however, incorporated about 60% more [3H]uracil in RNA during the pulse labeling under conditions of steady state growth (Fig. 5A). This may be the result of an increased labeling of the UTP pool resulting from the increased GTP pool in the nusAcs10 mutant, because uracil phosphoribosyltransferase is allosterically activated by GTP (32, 33). Alternatively, it may be that the nusAcs10 mutant has an increased capacity for total RNA synthesis despite the normal partitioning of RNA polymerase between mRNA and stable RNA initiations (rs/rt). The elevated pool of ppGpp may be taken as an indication of an increased mRNA pool in the nusAcs10 mutant, which has previously been observed following induction of a stable version of the lacZ mRNA (34).

In summary, our results strongly indicate that NusA is part of the ribosomal antitermination complex, where it helps RNA polymerase to increase the elongation rate thereby preventing Rho-dependent premature termination, and they suggest a close relationship between a high elongation rate and the degree of antitermination. The results also indicate that NusA is part of the transcription elongation complex for mRNA synthesis and mediates the sensitivity of the elongating RNA polymerase to ppGpp.


FOOTNOTES

*   The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§   Present address: Structural Cell Biology Unit, Institute of Medical Anatomy, The Panum Institute, University of Copenhagen, DK-2200 Copenhagen N, Denmark.
par    To whom correspondence should be addressed. Tel.: 45 3532 2020; Fax: 45 3532 2040; E-mail: kfj{at}mermaid.molbio.ku.dk.
1   The abbreviations used are: nt, nucleotide(s); IPTG, isopropyl-1-thio-§-D-galactopyranoside; ppGpp, guanosine 3',5'-bis(diphosphate); boxA, minimal sequence sufficient for ribosomal antitermination.

ACKNOWLEDGEMENTS

We thank Michael Sørensen, Department of Molecular Cell Biology, Institute of Molecular Biology, University of Copenhagen, for letting us use pMAS53 prior to publication. We thank Carsten Petersen and Karsten Tedin for helpful discussions and for critical reading of the manuscript.


REFERENCES

  1. Vogel, U., and Jensen, K. F. (1994) J. Biol. Chem. 269, 16236-16241 [Abstract/Free Full Text]
  2. Vogel, U., Sørensen, M., Pedersen, S., Jensen, K. F., and Kilstrup, M. (1992) Mol. Microbiol. 6, 2191-2200 [Medline] [Order article via Infotrieve]
  3. Cashel, M., and Rudd, K. E. (1987) in Escherichia coli and Salmonella typhimurium: Cellular and Molecular Biology (Neidhardt, F. C., Ingraham, J. C., Brooks-Low, K., Magasanik, B., Schaecter, M., and Umbarger, H. E., eds), pp. 1410-1438, American Society for Microbiology, Washington, D. C.
  4. Vogel, U., and Jensen, K. F. (1995) J. Biol. Chem. 270, 18335-18340 [Abstract/Free Full Text]
  5. Aksoy, A., Squires, C. L., and Squires, C. (1984) J. Bacteriol. 159, 260-264 [Medline] [Order article via Infotrieve]
  6. Berg, K. L., Squires, C., and Squires, C. L. (1989) J. Mol. Biol. 209, 345-358 [Medline] [Order article via Infotrieve]
  7. Das, A. (1992) J. Bacteriol. 174, 6711-6716 [Medline] [Order article via Infotrieve]
  8. Li, J., Horwitz, R., McCracken, S., and Greenblatt, J. (1992) J. Biol. Chem. 267, 6012-6019 [Abstract/Free Full Text]
  9. Squires, C. L., Greenblatt, J., Li, J., Condon, C., and Squires, C. L. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 970-974 [Abstract]
  10. Sharrock, R. A., Gourse, R. L., and Nomura, M. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 5275-5279 [Abstract]
  11. Greenblatt, J., and Li, J. (1981) Cell 24, 421-428 [Medline] [Order article via Infotrieve]
  12. Horwitz, R. J., Li, J., and Greenblatt, J. (1989) Cell 51, 631-641
  13. Schmidt, M. C., and Chamberlin, M. J. (1984) Biochemistry 23, 197-203 [Medline] [Order article via Infotrieve]
  14. Andersen, J. T., Jensen, K. F., and Poulsen, P. (1991) Mol. Microbiol. 5, 327-333 [Medline] [Order article via Infotrieve]
  15. Kingston, R. E., Nierman, W. C., and Chamberlin, M. J. (1981) J. Biol. Chem. 256, 2787-2797 [Abstract/Free Full Text]
  16. Schauer, A. T., Carver, D. L., Bigelow, B., Baron, L. S., and Friedman, D. I. (1987) J. Mol. Biol. 194, 679-690 [Medline] [Order article via Infotrieve]
  17. Nakamura, Y., Mizusawa, S., Court, D. L., and Tsugawa, A. (1986) J. Mol. Biol. 189, 103-111 [Medline] [Order article via Infotrieve]
  18. Jensen, K. F. (1988) Eur. J. Biochem. 175, 587-593 [Abstract]
  19. Vogel, U., and Jensen, K. F. (1994) J. Bacteriol. 176, 2807-2813 [Abstract]
  20. Clark, D. J., and Maaløe, O. (1967) J. Mol. Biol. 23, 99-112
  21. Miller, J. H. (1972) Experiments in Molecular Genetics, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
  22. Baracchini, E., Glass, R., and Bremer, H. (1988) Mol. Gen. Genet. 213, 379-387 [Medline] [Order article via Infotrieve]
  23. Brosius, J., Dull, T. J., Sleeter, D. D., and Noller, H. F. (1981) J. Mol. Biol. 148, 107-127 [Medline] [Order article via Infotrieve]
  24. Vogel, U., Pedersen, S., and Jensen, K. F. (1991) J. Bacteriol. 173, 1168-1174 [Medline] [Order article via Infotrieve]
  25. Zheng, C., and Friedman, D. I. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 7543-7547 [Abstract]
  26. Jensen, K. F., and Pedersen, S. (1990) Microbiol. Rev. 54, 89-100
  27. Craven, M. G., and Friedman, D. I. (1991) J. Bacteriol. 173, 1485-1491 [Medline] [Order article via Infotrieve]
  28. Condon, C., Squires, C., and Squires, C. L. (1995) Microbiol. Rev. 59, 623-645 [Abstract]
  29. Greenblatt, J., Nodwell, J. R., and Mason, S. W. (1993) Nature 364, 401-406 [CrossRef][Medline] [Order article via Infotrieve]
  30. Jin, D. J., Burgess, R. R., Richardson, J. P., and Gross, C. A. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 1453-1457 [Abstract]
  31. Bremer, H., and Ehrenberg, M. (1995) Biochim. Biophys. Acta 1262, 15-36 [Medline] [Order article via Infotrieve]
  32. Fast, R., and Sköld, O. (1977) J. Biol. Chem. 252, 7620-7624 [Abstract]
  33. Jensen, K. F., and Mygind, B. (1996) Eur. J. Biochem. 240, 637-645 [Abstract]
  34. Sørensen, M. A., Jensen, K. F., and Pedersen, S. (1994) J. Mol. Biol. 236, 441-454 [CrossRef][Medline] [Order article via Infotrieve]

©1997 by The American Society for Biochemistry and Molecular Biology, Inc.