Genetic fusions that help define a transcription termination region in Escherichia coli

The trpA gene product was analyzed from a class of strains of Escherichia coli K12 in which the lac operon has been fused by deletion to the trp operon. These are strains that have retained the ability to synthesize tryptophan. Two of these strains are shown to make a wild-type trpA product; these strains retain intact all structural genes of the ttrp operon. It is proposed that the lac operon in these strains is fused to a region of the trp operon between trpA, the last gene in the operon, and the region where trp messenger RNA synthesis terminates. The region where trp messenger RNA synthesis terminates thus is distinct from the trp structural genes.     

Differential inhibitory effects of antibiotics on the biosynthesis of envelope proteins of Escherichia coli

Inhibitory effects of six antibiotics (kasugamycin, tetracycline, chloramphenicol, sparsomycin, puromycin and rifampicin) on the biosynthesis of envelope proteins of Escherichia coli were examined and compared with those on the biosynthesis of cytoplasmic proteins. Kasugamycin, puromycin and rifampicin were much more inhibitory to the over-all biosynthesis of cytoplasmic proteins than to that of envelope proteins. On the contrary, tetracycline and sparsomycin showed much stronger inhibitory effects on the biosynthesis of envelope proteins than on that of cytoplasmic proteins. Chloramphenicol showed little difference in its inhibitory effect on the biosynthesis of envelope proteins and cytoplasmic proteins.The envelope proteins were labeled with [³H]arginine in the presence of the antibiotics and separated by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The inhibitory effects of the antibiotics on the biosynthesis of individual envelope proteins were then examined. Inhibition patterns were found to be widely different from one envelope protein to the other. For example, the biosynthesis of one major envelope protein of molecular weight 38,000 was more resistant to kasugamycin, chloramphenicol and sparsomycin than that of the other envelope proteins. On the other hand, the biosynthesis of another major envelope protein (lipoprotein) of about 7500 molecular weight was much more resistant to puromycin and rifampicin than that of the other envelope proteins. In the case of tetracycline, little differential inhibitory effect on the biosynthesis of individual envelope proteins was observed.Stability of messenger RNAs for individual envelope proteins was also determined from the inhibitory effect of rifampicin on their biosynthesis. It was found that the average of half lives of mRNAs for major envelope proteins examined (5.5 minutes) is twice as long as the average of those of mRNAs for cytoplasmic proteins (2 minutes), except for the lipoprotein of about 7500 molecular weight which has extremely stable mRNA with a half life of 11.5 minutes. From these results the envelope proteins of E. coli appear to be biosynthesized in a somewhat different manner from that of the cytoplasmic proteins. Furthermore, at least some envelope proteins may have their own specific biosynthetic systems.     

Polarity suppressors increase expression of the wild-type tryptophan operon of Escherichia coli

Three new polarity suppressors, selected to relieve the polar effect of nonsense mutations in the tryptophan (trp) and lactose (lac) operons of Escherichia coli, increase expression distal to nonsense mutations in both operons to a greater extent than suA. These suppressors relieve the polarity created by amber, ochre and frameshift mutations with equal efficiency.Two of the three polarity suppressors elevate enzyme synthesis in the wildtype trp operon two- and fivefold, respectively. The increase in enzyme levels is in each case correlated with increased levels and rates of synthesis of structural gene trp messenger RNA. Since expression of all genes is elevated, these findings suggest the existence of a site early in the wild-type trp operon that affects the extent of operon expression. We located the site affected by these two polarity suppressors between the operator and the first structural gene, trpE. Although the third polarity suppressor also relieves mutational polarity efficiently, it has no detectable effect on expression of the wild-type trp operon.     

Messenger Ribonucleic Acid Synthesis and Degradation in Escherichia coli During Inhibition of Translation

Various aspects of the coupling between the movement of ribosomes along messenger ribonucleic acids (mRNA) and the synthesis and degradation of mRNA have been investigated. Decreasing the rate of movement of ribosomes along an mRNA does not affect the rate of movement of some, and possibly most, of the RNA polymerases transcribing the gene coding for that mRNA. Inhibiting translation with antibiotics such as chloramphenicol, tetracycline, or fusidic acid protects extant mRNA from degradation, presumably by immobilizing ribosomes, whereas puromycin exposes mRNA to more rapid degradation than normal. The promoter distal (3') portion of mRNA, synthesized after ribosomes have been immobilized by chloramphenicol on the promoter proximal (5') portion of the mRNA, is subsequently degraded.     

Differential inhibition of coliphage MS2 protein synthesis by ribosome-directed antibiotics

Of thirteen ribosome-directed antibiotics surveyed for their inhibitory effect on viral protein synthesis in Escherichia coli infected with coliphage MS2, three antibiotics, kasugamycin, tetracycline and chloramphenicol, were found to exert differential inhibition, with synthesis of maturation protein being more sensitive than coat protein synthesis. Differential effects of kasugamycin and tetracycline were also observed in vitro. Such differential inhibition might reflect the presence of cistron-speciflc ribosomes or the induction of functional ribosomal heterogeneity by these antibiotic ligands.     

Different half-lives of messenger RNA corresponding to different segments of the tryptophan operon of Escherichia coli

In genetically derepressed strains (trpR⁻) of Escherichia coli which are growing exponentially, messenger RNA regions corresponding to different segments of the trp operon are labeled with different kinetics, suggesting that operator-proximal and distal regions of trp-mRNA have different half-lives. This conclusion was confirmed by direct measurement of trp-mRNA decay; the half-lives for different mRNA regions at 30 °C were found to be 60 seconds for trpE-mRNA, 75 seconds for trpDC-mRNA, and 95 to 115 seconds for trpBA-mRNA. Deletions of genetic segments within the operator-proximal region of the operon reduce the half-life of trp BA-mRNA. Large deletions which place the BA region near the operator reduce the half-life of trpBA-mRNA to values similar to that of trpE-mRNA in the parental strain. Therefore location in the message rather than primary structure appears to determine the half-life of each mRNA region. Several of the internal deletions have a polar effect on the synthesis of the trpB and trpA polypeptides. However, the reduction in trpBA-mRNA half-life does not appear to be due to polarity because trpBA-mRNA half-life is reduced to the same value in three deletion mutants in which there is a sevenfold difference in polarity. These results are compatible with a model of trp-mRNA degradation in which the initial degradative event occurs near the 5′ end of the mRNA molecule and is followed by over-all degradation in the 3′ direction, with random or non-random delays causing an increase in half-life of about 10% per 1000 nucleotides mRNA. Our findings are not compatible with a model of normal degradation in which the entire mRNA molecule is the target for the initial degradative event.     

Impact of P-Site tRNA and Antibiotics on Ribosome Mediated Protein Folding: Studies Using the Escherichia coli Ribosome

Background

The ribosome, which acts as a platform for mRNA encoded polypeptide synthesis, is also capable of assisting in folding of polypeptide chains. The peptidyl transferase center (PTC) that catalyzes peptide bond formation resides in the domain V of the 23S rRNA of the bacterial ribosome. Proper positioning of the 3′ –CCA ends of the A- and P-site tRNAs via specific interactions with the nucleotides of the PTC are crucial for peptidyl transferase activity. This RNA domain is also the center for ribosomal chaperoning activity. The unfolded polypeptide chains interact with the specific nucleotides of the PTC and are released in a folding competent form. In vitro transcribed RNA corresponding to this domain (bDV RNA) also displays chaperoning activity.

Results

The present study explores the effects of tRNAs, antibiotics that are A- and P-site PTC substrate analogs (puromycin and blasticidin) and macrolide antibiotics (erythromycin and josamycin) on the chaperoning ability of the E. coli ribosome and bDV RNA. Our studies using mRNA programmed ribosomes show that a tRNA positioned at the P-site effectively inhibits the ribosome''s chaperoning function. We also show that the antibiotic blasticidin (that mimics the interaction between 3′–CCA end of P/P-site tRNA with the PTC) is more effective in inhibiting ribosome and bDV RNA chaperoning ability than either puromycin or the macrolide antibiotics. Mutational studies of the bDV RNA could identify the nucleotides U2585 and G2252 (both of which interact with P-site tRNA) to be important for its chaperoning ability.

Conclusion

Both protein synthesis and their proper folding are crucial for maintenance of a functional cellular proteome. The PTC of the ribosome is attributed with both these abilities. The silencing of the chaperoning ability of the ribosome in the presence of P-site bound tRNA might be a way to segregate these two important functions.     

Differential stability of trp messenger RNA synthesized originating at the trp promoter and pL promoter of lambda trp phage.

The trp operon translocated into the early region of phage λ can be transcribed under the control of two promoters, the authentic trp promoter (p_Ttrp mRNA) and the p_L promoter of the N gene (p_Ltrp mRNA) (Imamoto &; Tani, 1972; Segawa &; Imamoto, 1974). The p_Ltrp mRNA has a 5′-terminal λ N message. The functional and chemical stability of trp segments in these mRNA species have been assayed. To determine trp mRNA from λtrp, appropriate φ80trp DNAs were used as a DNA complement in DNA-RNA hybridization assays.When formation of mRNA is inhibited, the capacity to serve as template for enzyme synthesis decays at a comparable rate for p_L and p_Ttrp mRNA, and p_Ltrp mRNA seems to be translated as efficiently as is the normal p_Ttrp mRNA. In contrast to this similar functional stability, p_Ltrp mRNA shows a more than tenfold greater chemical stability than p_Ttrp mRNA. (p_Ttrp mRNA is degraded at the same rate as trp mRNA in uninfected bacteria. Bulk host mRNA also decays at its normal rate in cells infected with λtrp.)On the basis of those and more extensive experiments including the sedimentation analysis of those stabilized trp mRNA molecules, it is inferred that (1) the rate-limiting step to initiate bulk mRNA degradation is determined by a sequence located at or near the 5′ end of the messenger RNA; and (2) functional inactivation of each messenger is regulated independently of bulk chemical degradation of the message.Stabilization of the trp mRNA produced from the p_L promoter increases with time after phage infection. Thus, the stabilization requires a modification of the decay trigger, possibly by a phage-specific protein such as a nuclease or the N and/or tof gene that might bind to the mRNA.     

Antimicrobial resistant coliform bacteria in the Gomti river water and determination of their tolerance level

The distribution of resistance to ampicillin, chloramphenicol, sulfonamides, tetracycline, and streptomycin among coliform in the Gomti river water samples was investigated. The coliform populations were isolated on Mac Conky and eosin methylene blue (EMB) agar plates supplemented with antibiotics. The incidence of resistance among the coliform population varied considerably in different drug and water sampling sites. Coliform bacteria showed lower drug resistant viable count in sampling site-III (receiving treated wastewater) as compared to more polluted site-I and site-II. Viable count of coliform population obtained on both medium was recorded higher against erythromycin from sampling site-III. Lower viable count of coliforms was recorded against tetracycline in site-II and III. Similar resistance pattern was obtained in the frequency of E. coli and Enterobacter species from all the three sampling sites. Percentage of antibiotic resistant E. coli was observed higher than Enterobacter spp among the total coliforms against all antibiotics tested without Erythromycin and penicillin in site-I and II respectively. Isolates of E. coli and Enterobacter spp. showed their tolerance level (MIC) in the range of 2-100 against the antibiotics tested. Maximum number of isolates of both genus exhibited their MICs at lower concentration range 2-5µg/ml against ciprofloxacin, tetracyclin and amoxycillin.

Abbreviations

EMB - Eosin methylene blue, IMViC tests - Indole, Methyl Red, Voges Proskauer and Citrate Utilization Tests, MIC - Minimum inhibitory concentration.     

Novel Method for Rapid Assessment of Antibiotic Resistance in Escherichia coli Isolates from Environmental Waters by Use of a Modified Chromogenic Agar

We validated a novel method for screening Escherichia coli resistance to antibiotics in environmental samples using modified Difco MI agar (Becton Dickinson) impregnated with selected antibiotics (tetracycline, ampicillin, cephalexin, and sulfamethoxazole), termed MI-R. This method combines an existing rapid assessment technique for E. coli enumeration with clinical reference data for breakpoint analysis of antibiotic resistance and was developed to address issues encountered when clinical methods are used with environmental samples. Initial trials conducted using strains of E. coli with resistance to the selected antibiotics showed that this method was reproducible and accurate with respect to antibiotic resistance. Trials using wastewater effluent demonstrated the precision of the method, and the levels of resistance found in effluent were directly comparable to the levels of antibiotic resistance determined using the more traditional CLSI (formerly NCCLS) disk susceptibility test. All wastewater isolates growing on MI-R plates were confirmed to be resistant using the CLSI disk susceptibility test. Bacterial resistance to ampicillin (38% ± 4% overall), sulfamethoxazole, tetracycline (21% ± 3% overall), and ciprofloxacin (6% ± 1%) were found in wastewater effluent. A successful trial was also conducted with water collected from the Brisbane River, Australia. The levels of antibiotic resistance in E. coli ranged from 0 to 47% for ampicillin, from 0 to 24% for tetracycline, from 0 to 63% for sulfamethoxazole, and from 0 to 1% for ciprofloxacin, with the highest incidence of resistance associated with wastewater treatment plant discharges. This method has great potential for rapid and representative assessment of antibiotic resistance in E. coli and could allow increased sample analysis, resulting in greater confidence in spatial analysis in environmental studies.     

Direct identification of the amino acid changes in two mutant lac repressors.

Deletions extending into the trp operon at one terminus and the lacI control region at the other terminus have been examined. One of these, B116, ends within the trp leader sequence and eliminates the trp attenuator site, placing the synthesis of lac repressor under trp control. We have isolated and characterized the B116 repressor. The protein sequence of the aminoterminus of B116 shows that an additional 16 residues are added to the amino-terminal end of wild-type repressor. Moreover, a valine residue appears in place of methionine at position 17 (the original amino-terminal residue of the wild-type repressor). A comparison of the messenger RNA sequence of the trp leader region and of the I leader region demonstrates that the translation of the B116 repressor is initiated at an AUG codon within the trp leader sequence. The GUG initiation codon at the start point for translation of wild-type repressor is now read as valine, since it appears at an internal position (residue 17 of the altered repressor). The B116 repressor accumulates at levels as high as 1% of the soluble cell protein in trpR^? strains. The efficiency of the trp leader initiation codon in translation suggests that in wild-type strains this AUG is also active in directing protein synthesis, which would result in a polypeptide consisting of 14 amino acids. We have examined the physical properties of the B116 repressor, which shows a marked tendency to form higher aggregates. Other characteristics of B116 are also described.     

Inhibitory action of erythromycin on bacteriophage SPO1 multiplication in sporulating cells of Bacillus subtilis 168

Summary Erythromycin (2–4 g/ml) was found to inhibit specifically multiplication of SPO1 in sporulating cells of an erythromycin-resistant, conditional asporogenous mutant of Bacillus subtilis 168 thy ^- trp ^-, Ery1040. In contrast, streptomycin (150–200 g/ml) which inhibits protein synthesis to a similar extent as erythromycin did not inhibit SPO1 multiplication severely, suggesting that the inhibition of SPO1 multiplication by erythromycin is not caused by an overall inhibition of protein synthesis. Neither phage DNA synthesis nor phage messenger RNA synthesis was affected appreciably under these conditions. However, the synthesis of three phage proteins that are synthesized 15 min after infection was preferentially inhibited by erythromycin. In addition, the inhibition of SPO1 multiplication has been correlated with the stimulation of host stable RNA synthesis exhibited by erythromycin. Possible mechanisms for the inhibition of SPO1 multiplication in Ery1040 cells are discussed.     

Nucleotide sequences from messenger RNA transcribed from the operator-proximal portion of the tryptophan operon of Escherichia coli

³²P-labeled messenger RNA transcribed in vivo from the operator-proximal portion of the tryptophan operon of Escherichia coli was purified by DNA/RNA hybridization. The mRNA preparations obtained were subjected to polyaerylaamide gel electrophoresis, and a number of discrete labeled bands were detected. Characterization of the labeled bands and of purified, unbanded mRNA preparations, by partial sequence analysis of the oligonucleotides obtained following T₁ and pancreatic RNase digestion, revealed that the bands represented discrete segments of the trp mRNA molecule. This observation suggests that endonucleolytic cleavage occurs in vivo at specific sites in the mRNA molecule.