Stimulation by cyclic AMP and ppGpp of chloramphenicol acetyl transferase synthesis

The lipolytic activity of LipJ, a stress-induced enzyme, is regulated by its C-terminal adenylate cyclase domain

Aim: The confirmation of lipolytic activity and role of Rv1900c in the Mycobacterium physiology Methods: rv1900c/N-terminus domain (rv1900NT) were cloned in pET28a/Escherichia coli, purified by affinity chromatography and characterized. Results: A zone of clearance on tributyrin-agar and activity with pNP-decanoate confirmed the lipolytic activity of Rv1900c. The Rv1900NT demonstrated higher enzyme specific activity, V_max and k_cat, but Rv1900c was more thermostable. The lipolytic activity of Rv1900c decreased in presence of ATP. Mycobacterium smegmatis expressed rv1900c/rv1900NT-altered colony morphology, growth, cell surface properties and survival under stress conditions. The effect was more prominent with Rv1900NT as compared with Rv1900c. Conclusion: The study confirmed the lipolytic activity of Rv1900c and suggested its regulation by the adenylate cyclase domain and role in the intracellular survival of bacteria.

A novel transcriptional response by the cat gene during slow growth of Escherichia coli

A novel response to growth rate was found with expression of the chloramphenicol acetyltransferase (cat) gene in Escherichia coli. The amount of cat mRNA relative to total RNA increased about 11-fold as growth rates decreased 5- to 6-fold, without an increase in translation. The accumulation of cat mRNA was in contrast to decreased cellular concentrations of total RNA, trxA, ompA, or 23S rRNA as the growth rate decreased and was not due to changes in gene dosage or mRNA stability. Stability of the cat mRNA does not appear to be regulated by growth rate. No significant change in either chemical or functional stability was observed within a five- to sixfold range of growth rates when chemostat-grown cells were used. However, cat mRNA stability was affected by growth medium composition. The half-life of cat mRNA decreased about threefold, with an approximate fourfold increase in generation time due to changes in growth medium. Transcriptional studies have indicated that accumulation of cat mRNA at slow growth rates is the result of a specific transcriptional response to changes in cellular generation times. We propose that increases in the cellular concentration of a specific message at slow growth rates may reflect an additional type of survival response in E. coli.

A rapid, sensitive, and inexpensive assay for chloramphenicol acetyltransferase

We present a rapid, sensitive enzymatic assay for chloramphenicol acetyltransferase (CAT) that does not require chromatography, HPLC, or autoradiography. The assay is based on the use of an inexpensive substrate, tritiated acetate, instead of [14C]chloramphenicol. The method is adapted from one originally used by de Crombrugghe et al. (1973) and by Shaw (1975), but with simplifications appropriate for routine use. In our hands, the method is as sensitive as the customary thin-layer chromatography assay and is far more efficient for the performance of many assays, both in terms of labor and expense.

Sequence and expression characteristics of a shuttle chloramphenicol-resistance marker for Saccharomyces cerevisiae and Escherichia coli

An efficiently transforming chloramphenicol-resistance (CmR) shuttle marker for Saccharomyces cerevisiae and Escherichia coli has been characterized in terms of its primary structure and expression characteristics. The complete nucleotide (nt) sequence of the CmR marker is given, with details on restriction sites, apparent expression signals for both organisms, and translation of the Cm acetyltransferase (CAT)-coding sequence. SDS-polyacrylamide gel electrophoresis and Western blotting have confirmed that the marker produced an identical CAT protein in yeast and E. coli. Each copy of the marker, whether present in multiple copies or as a single copy, gave rise to approx. 0.1% of the total soluble protein as CAT in haploid yeast cells. When compared with homologous expression of alcohol dehydrogenase (ADH-I) by the same ADC1 promoter, this represents a 27-fold reduction for CAT expression, which is typical of heterologous gene expression in yeast. When the marker was on a multicopy plasmid in yeast, up to 2.1% of the total soluble cell protein was produced as CAT, but this did not adversely affect the growth of host cells. Increase of the Cm concentration in the medium did not result in an increase in the number of plasmids nor the amount of CAT protein produced, showing that plasmid copy number and marker expression are regulated independently of the selection pressure. In E. coli, the ADC1 yeast-promoter DNA was found to contain both forwards and backwards promoter activity. The level of expression provided by these promoters was equivalent to that of an average E. coli gene.

Prokaryotic gene expression in vitro: transcription-translation coupled systems

Transcription-translation coupled systems have been developed to study prokaryotic gene expression. Several types of expression system have been described. The original system consists of a crude unfractionated Escherichia coli extract, which supports protein synthesis directed by a template DNA. Control of gene expression at the transcriptional stage has been studied using this unfractionated system. In this respect, two examples of particular interest, lactose and tryptophan operons, are described. Other systems are either partially reconstituted or highly defined, containing up to 30 purified factors necessary for transcription (RNA polymerase) and translation (aminoacyl-tRNA synthetases, initiation, elongation and release factors). Additional differences between the various systems relate to the analysis of the gene products. Whereas most methods involve analysis of the totally synthesized protein, a particular system implies the formation of only the N-terminal di- or tripeptide of the gene product. Reconstituted systems have proved useful in studies on transcriptional, e.g., discovery and role of L factor, as well as translational regulation of gene expression, e.g., autogenous control of ribosomal protein synthesis.

Genetic dissection of stringent control and nutritional shift-up response of the Escherichia coli S10 ribosomal protein operon

The S10 operon of Escherichia coli is autogenously regulated by L4, one of 11 ribosomal proteins encoded by the operon. We have previously shown that L4 regulates transcription of the operon by modulating the level of read-through at an attenuator in the S10 leader. To determine the physiological roles of both L4-mediated attenuation and the regulation of transcription initiation, we have constructed mutations eliminating their two regulatory targets, the S10 leader and the S10 promoter. Our results indicate that stringent control requires only the S10 promoter and therefore is mediated at the level of initiation. However, growth-medium-dependent control after a nutritional shift-up involves regulation of both initiation of transcription at the promoter and transcription read-through at the attenuator.

Resistance to chloramphenicol in Proteus mirabilis by expression of a chromosomal gene for chloramphenicol acetyltransferase

Proteus mirabilis PM13 is a well-characterized chloramphenicol-sensitive isolate which spontaneously gives rise to resistant colonies on solid media containing chloramphenicol (50 micrograms ml-1) at a plating efficiency of 10(-4) to 10(-5). Such chloramphenicol-resistant colonies exhibit a novel phenotype with respect to chloramphenicol resistance. When a single colony grown on chloramphenicol agar is transferred to liquid medium and grown in the absence of antibiotic for 150 generations, a population of predominantly sensitive cells arises. This mutation-reversion phenomenon has been observed in other Proteus species and Providencia strains, wherein resistance has been shown to be mediated in each case by the enzyme chloramphenicol acetyltransferase. The cat gene responsible for the phenomenon is chromosomal and can be cloned from P. mirabilis PM13 with DNA prepared from cells grown in the absence or the presence of chloramphenicol. Recombinant plasmids which confer resistance to chloramphenicol carry an 8.5-kilobase PstI fragment irrespective of the source of host DNA. The location of the cat gene within the PstI fragment was determined by Southern blotting with a cat consensus oligonucleotide corresponding to the expected amino acid sequence of the active site region of chloramphenicol acetyltransferase, and the direction of transcription was deduced from homology with the type I cat variant.

Analogs of cyclic AMP that elicit the biochemically defined conformational change in catabolite gene activator protein (CAP) but do not stimulate binding to DNA

We have measured the effects on catabolite gene activator protein (CAP) of 22 synthetic analogs of cAMP. Each analog was assayed to test three parameters: (1) binding to CAP; (2) induction of the conformational change in CAP; and (3) activation of transcription. Thus we have identified seven cAMP analogs that bind to CAP as well or better than does cAMP, cause the assayed conformational change in CAP, yet exhibit no ability to activate transcription. We designate these analogs class D. The conformational change elicited in CAP by the class D analogs was further investigated by: (1) sensitivity to the proteolytic enzymes chymotrypsin, Staphylococcus aureus V8 protease, subtilisin and trypsin; (2) formation of inter-subunit covalent crosslinks by 5,5'-dithiobis(2-nitrobenzoic acid); and (3) degree of labeling of cysteine by [3H]N-ethylmaleimide. These experiments failed to detect a conformational difference between the CAP-class D and CAP-cAMP complexes. Filter binding and nuclease protection experiments indicate that the class D analogs do not efficiently support the binding of CAP to DNA. From these results, we suggest that there exists a hitherto undetected event dependent on cAMP, and required for CAP to bind to DNA. We suggest that this event involves a change that takes place in proximity to the N6 atom of cAMP. Three possible interpretations are discussed.

Expression in Escherichia coli of streptococcal plasmid-determined erythromycin resistance directed by the cat gene promoter of pACYC 184

The streptococcal erythromycin resistance (Emr) plasmid pSM7 (6.4 kb) and the E. coli vector pACYC184 (4.0 kb) were fused at their single EcoRI sites to form the bifunctional chimeric plasmid pSM7184 (10.4 kb) in which the Emr determinant was placed under control of the chloramphenicol acetyl transferase (cat) promoter of pACYC184. In the sense orientation (orientation I) of pSM7, the cat promoter directed expression of Emr in the E. coli host strains 294 and DB11 more efficiently than did the indigenous transcription signals of pSM7, which were functional in the opposite orientation II. In Streptococcus sanguis (Challis), the level of Emr was independent of the orientation of pSM7 in pACYC184, showing that the cat promoter was not recognized in the gram-positive host. The growth of E. coli (pSM7184I) in a defined medium containing glycerol as carbon source, or containing glucose plus extraneous cyclic 3'-5' adenosine monophosphate (cAMP) led to an Emr level which was 15-30 times higher than that of cultures grown on glucose. These results showed that under control of the cat promoter, Emr is subject to cAMP-mediated catabolite repression and provided conclusive evidence that the enhancement of Emr expression in E. coli carrying pSM7184I is controlled at the transcriptional level. Besides enabling us to determine the orientation of transcription of the Emr gene in pSM7 and related vectors, this work also made available new bifunctional cloning vehicles able to replicate in both E. coli and S. sanguis.

Regulation of antibiotic resistance in bacteria: the chloramphenicol acetyltransferase system

The evaluations of antibiotic resistance has been a subject of interest to workers in several disciplines. Our current understanding of the molecular biology of plasmids, phages, and transposable elements provides a basis for appreciating the range of mechanisms likely to be involved in the horizontal spread of resistance determinants through microbial ecosystems. Rather less can be imagined with confidence about the origins of the genes or the constraints and selection pressures operating at the level of protein structure. The CAT system illustrates the extent of variation possible for an accessory gene product which is required infrequently and which is encoded by multicopy and promiscuous vectors which can cross taxonomic boundaries. Still less is known with certainty about the evolution of genetic control of the expression of antibiotic resistance. While there are sound reasons for looking in detail at prokaryotic antibiotic-producing organisms such as Streptomyces to find the progenitors of present resistance mechanisms (44, 45), it seems likely that controls of expression have been acquired during the "passage" of selectable markers through more distant bacterial genera. The CAT system is illustrative of the variety we may expect to find in control strategies used by microbial systems generally. It might indeed be a surprise to find an expression mechanism operating in the CAT system (or for any other family of resistance genes) which was not illustrative of a general strategy exploited by essential genes specifying biosynthetic or degradative functions. There may be some truth in referring to the cat structural gene as a "cartridge" for the isolation and manipulation of promoter functions. It would seem that nature has been at it for some time.

Identification of the rodA gene product of Escherichia coli

Plasmids that carry the Escherichia coli cell shape gene rodA directed the synthesis of a cytoplasmic membrane protein (Mr, 31,000 [31K protein] ) in minicells, maxicells, and an in vitro-coupled transcription-translation system. The 31K protein was identified as the rodA gene product, because it was not synthesized from the vector plasmids or from a plasmid in which the rodA gene was inactivated by insertion of Tn1000. Furthermore, a purified 1.6-kilobase KpnI-BamHI DNA fragment that contained the intact rodA gene directed the synthesis of only the 31K protein in an in vitro system. The apparent molecular weight of the protein was identical whether synthesized in vivo or in vitro, indicating that the rodA gene product is not made as a preprotein. The direction of transcription of rodA was from the KpnI site towards the BamHI site. The 31K protein was unusual in that it could only be detected when cell membranes were solubilized at low temperature (e.g., 37 degrees C) before sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Apparently the rodA gene product aggregates after being boiled in sodium dodecyl sulfate and fails to enter a polyacrylamide gel.

Chloramphenicol acetyltransferase: enzymology and molecular biology

Naturally occurring chloramphenicol resistance in bacteria is normally due to the presence of the antibiotic inactivating enzyme chloramphenicol acetyltransferase (CAT) which catalyzes the acetyl-S-CoA-dependent acetylation of chloramphenicol at the 3-hydroxyl group. The product 3-acetoxy chloramphenicol does not bind to bacterial ribosomes and is not an inhibitor of peptidyltransferase. The synthesis of CAT is constitutive in E. coli and other Gram-negative bacteria which harbor plasmids bearing the structural gene for the enzyme, whereas Gram-positive bacteria such as staphylococci and streptococci synthesize CAT only in the presence of chloramphenicol and related compounds, especially those with the same stereochemistry of the parent compound and which lack antibiotic activity and a site of acetylation (3-deoxychloramphenicol). Studies of the primary structures of CAT variants suggest a marked degree of heterogeneity but conservation of amino acid sequence at and near the putative active site. All CAT variants are tetramers composed in each case of identical polypeptide subunits consisting of approximately 220 amino acids. The catalytic mechanism does not appear to involve an acyl-enzyme intermediate although one or more cysteine residues are protected from thiol reeagents by substrates. A highly reactive histidine residue has been implicated in the catalytic mechanism.

Specific-purpose plasmid cloning vectors. I. Low copy number, temperature-sensitive, mobilization-defective pSC101-derived containment vectors

Two cloning vector plasmids, pHSG415 (7100 bp) and a lambda phage cos site-containing derivative (cosmid) thereof, pHSG422 (8760 bp), were constructed from a low copy number plasmid (pSC101) replicon to permit the propagation of cloned DNA segments at low gene dosage levels. Two features of the vectors, namely temperature sensitivity of replication and inability to be mobilized by conjugative plasmids, cause them to exhibit a high level of "biological containment". The essential characteristics of pHSG415 and pHSG422 may be summarized as follows: (1) their genome copy number is low (4--6 copies/chromosome); (2) their replication ceases at high temperature and they are rapidly lost from host cells grown at temperatures of 37 degrees C and above; (3) the relaxation nick site of pSC101, which is thought to be synonymous with its origin of transfer replication, is absent from the vectors; as a consequence, they are not mobilized to a significant extent by co-existing conjugative plasmids that are able to mobilize wild-type pSC101; (4) they contain unique insertion sites for DNA fragments generated by the following restriction endonucleases: EcoRI, XhoI, XmaI, HindIII and PstI; pHSG415 additionally contains single BamHI, BstEII and HincII sites and may also be used to clone PvuI-generated fragments; (5) the plasmids confer upon their host cells resistance to chloramphenicol, kanamycin and ampicillin, and every unique cloning site, except those of BamHI and BstEII, is located within one of these antibiotic-resistance genes.

Expression of plant tumor-specific proteins in minicells of Escherichia coli: a fusion protein of lysopine dehydrogenase with chloramphenicol acetyltransferase

Fragment EcoRI 7 from Ti-plasmid pTi Ach5, a part of the T-DNA in octopine tumors, was cloned in both orientations into pACYC184 and expressed in E. coli minicells. The cells synthesized four proteins from four different coding regions on EcoRI 7. Two of the proteins (Mr 25.000 and 26.000) were expressed with promoters from the Ti-plasmid fragment, while transcription for the two other proteins (Mr 18.000 and 74.000) started with a promoter on pACYC184. The Mr 18.000 protein represented a fusion product between chloramphenicol acetyltransferase (CAT) on pACYC184 and a part of lysopine dehydrogenase (LpDH), the enzyme synthesizing octopine and lysopine in plant tumor cells. The results suggest that E. coli minicells are a valuable system to study the proteins coded for by the T-region of Ti-plasmids.

Characterization of the beta-lactamase promoter of pBR322

The beta-lactamase promoter of pBR322, derived from Tn3, has been characterized using several techniques. The transcription initiation site is located 35 base pairs from the translation initiation codon of beta-lactamase. The mRNA produced in vitro has a 5' pppGpA terminus. RNA polymerase bound at this start site protects a region from about -50 to +20 from DNase I cleavage using the footprinting technique. RNA polymerase binds rapidly to the beta-lactamase promoter. The half-time of association is less than one-half minute. The half-time of dissociation is approximately 6 hr. A study of the binding of RNA polymerase at different temperatures showed a large change between 11 degrees and 15 degrees C. Comparison of these parameters with those reported for other promoters is discussed.

Stringent control and protein synthesis in bacteria

Most bacteria have evolved a number of regulatory mechanisms which allow them to maintain a balanced and rather constant cellular composition in response to nutritional variations. In particular, when the availability of any aminoacyl-tRNA species becomes limiting (namely through amino acid starvation or inactivation of an aminoacyl-tRNA synthetase), several biochemically distinct physiological processes are significantly modified. This coordinate adjustment of cellular activity is termed the "stringent response". Under such conditions of aminoacyl-tRNA limitation, protein synthesis still proceeds, but various quantitative as well as qualitative changes in polypeptide metabolism can be observed. In this review, after a brief recall of the main characteristics of the stringent response, several aspects concerning protein synthesis in deprived bacteria have been presented. First, the rates of residual protein formation, peptide chain growth and protein degradation, and the molecular weight distribution of proteins newly synthesized have been analyzed. Then, the data relative to the biosynthetic regulation of non-ribosomal and ribosomal proteins have been summarized and compared to the results obtained from in vitro experiments using transcription-translation coupled systems. Finally, the problem of translational fidelity during deprivation has been discussed in connection with the metabolic behavior of polysomal structures which are still maintained in cells. The stringent dependence of cellular activity on aminoacyl-tRNA supply is known to be abolished by single-site mutations which confer to bacteria a phenotype referred to as "relaxed". These mutant strains provide an useful analytical tool in the scope of understanding the stringency phenomenon. Therefore, their proteosynthetic activity under aminoacyl-tRNA deprivation has also been studied here, in comparison to that of normal wild-type strains.

Primary structure of a chloramphenicol acetyltransferase specified by R plasmids

Naturally occurring isolates of chloramphenicol-resistant bacteria commonly synthesise chloramphenicol acetyltransferase (EC 2.3.28; CAT) in amounts which are sufficient to account for the resistance phenotype and often harbour plasmids which carry the structural gene for CAT. The findings of CAT in such diverse prokaryotes as Proteus mirabilis, Agrobacterium tumefaciens, Streptomyces sp., and a soil Flavobacterium has led to speculation concerning the origin and evolution of the more commonly observed CAT variants specified by plasmids in clinically important bacteria. To provide a more solid basis for studying the evolution and spread of CAT within prokaryotes we chose to determine the complete amino acid sequence of a type I variant of CAT, the variant known to be associated with most F-like plasmids conferring chloramphenicol resistance. The sequence has been determined by combining the results obtained from manual and automated sequential degradation with those obtained by mass spectrometry of peptides generated by enzymatic digestion. The directly determined primary structure is identical with that predicted by the DNA sequence analysis of the chloramphenicol resistance transponson Tn9 known to specify a type I variant of chloramphenicol acetyltransferase.

Nucleotide sequence analysis of the chloramphenicol resistance transposon Tn9

The transposable genetic element Tn9 consists of two direct repeats of the insertion sequence IS1 flanking a region of 1,102 base pairs which determines chloramphenicol resistance. Transposition of Tn9 leads to the duplication of a 9-base pair sequence which preexists at the site of insertion. One copy of this sequence is found at each end of the inserted element. The chloramphenicol resistance determined by Tn9, and by various other R plasmids, is due to the synthesis of the enzyme chloramphenicol acetyl transferase (CAT). This enzyme catalyses the formation of acetylated derivatives of chloramphenicol which are inactive as inhibitors of protein synthesis. By using the chain termination technique of DNA sequencing, we have now determined the nucleotide sequence of the 1,102 base pair region between the directly repeated IS1 sequence in the bacterial transposon Tn9 (encoding chloramphenicol resistance). The amino acid sequence of CAT predicted from the nucleotide sequence is identical to that determined by Shaw and coworkers. An analysis of the sequence suggests that the internal 1,102 base pair region is not directly involved in transposition.

Effect of guanosine 5'-diphosphate 3'-diphosphate and related nucleoside polyphosphates on induction of tryptophanase and beta-galactosidase in permeabilized cells of Escherichia coli

Exogenous addition of guanosine and adenosine 5'-(mono, di and tri) phosphate 3'-diphosphates (pppGpp, ppGpp, pGpp, pppApp, ppApp and pApp) stimulated the synthesis of tryptophanase and beta-galactosidase in permeabilized cells of Escherichia coli. From the results obtained with ppGpp and pppApp, this effect appeared to be at a transcriptional level and depended greatly on the growth condition; the largest effect was observed in cells under shiftdown or grown on poor enrgy source. ppGpp and pppApp, unlike cyclic AMP, did not act to overcome the inhibition of enzyme induction by glucose, but in combination with cyclic AMP caused a synergistic stimulation effect. In the shiftdown cells, ppGpp and pppApp gave 30% or more stimulation effect on tryptophanase induction while cyclic AMP did not stimulate induction. There was therefore a pronounced difference between cyclic AMP and ppGpp or pppApp in stimulatory function.

Requirement of cyclic adenosine 3',5'-monophosphate for the thermosensitive effects of Rts1 in a cyclic adenosine 3',5'-monophosphate-less mutant of Escherichia coli

Previous publications showed that a covalently closed circular (CCC) Rts1 plasmid deoxyribonucleic acid (DNA) that confers kanamycin resistance upon the host bacteria inhibits host growth at 42 degrees C but not at 32 degrees C. At 42 degrees C, the CCC Rts1 DNA is not formed, and cells without plasmids emerge. To investigate the possible role of cyclic adenosine 3',5'-monophosphate (cAMP) in the action of Rts1 on host bacteria, Rts1 was placed in an Escherichia coli mutant (CA7902) that lacks adenylate cyclase or in E. coli PP47 (a mutant lacking cAMP receptor protein). Rts1 did not exert the thermosensitive effect on these cells, and CCC Rts1 DNA was formed even at 42 degrees C. Upon addition of cAMP to E. coli CA7902(Rts1), cell growth and formation of CCC Rts1 DNA were inhibited at 42 degrees C. The addition of cAMP to E. coli PP47(Rts1) did not cause inhibitory effects on either cell growth or CCC Rts1 DNA formation at 42 degrees C. The inhibitory effect of cAMP on E. coli CA7902(Rts1) is specific to this cyclic nucleotide, and other cyclic nucleotides such as cyclic guanosine 3',5'-monophosphate did not have the effect. For this inhibitory effect, cells have to be preincubated with cAMP; the presence of cAMP at the time of CCC Rts1 DNA formation is not enough for the inhibitory effect. If the cells are preincubated with cAMP, one can remove cAMP during the [(3)H]thymidine pulse and still observe its inhibitory effect on the formation of CCC Rts1 DNA. The presence of chloramphenicol during this preincubation period abolished the inhibitory effect of cAMP. These observations suggest that cAMP is necessary to induce synthesis of a protein that inhibits CCC Rts1 DNA formation and cell growth at 42 degrees C.

Regulation of two phosphatases and a cyclic phosphodiesterase of Salmonella typhimurium

The regulation of three Salmonella typhimurium phosphatases in reponse to different nutritional limitations has been studied. Two enzymes, an acid hexose phosphatase (EC 3.1.3.2) and a cyclic phosphodiesterase (EC 3.1.4.d), appear to be regulated by the cyclic adenosine 3' ,5'-monophosphate (AMP) catabolite repression system. Levels of these enzymes increased in cells grown on poor carbon sources but not in cells grown on poor nitrogen or phosphorus sources. Mutants lacking adenyl cyclase did not produce elevated levels of these enzymes in response to carbon limitation unless cyclic AMP was supplied. Mutants lacking the cyclic AMP receptor protein did not produce elevated levels of these enzymes in response to carbon limitation regardless of the presence of cyclic AMP. Since no specific induction of either enzyme could be demonstrated, these enzymes appear to be controlled solely by the cyclic AMP system. Nonspecific acid phsphatase activity (EC 3.1.3.2) increased in response to carbon, nitrogen, phosphorus, or sulfur limitation. The extent of the increase depended on growth rate, with slower growth rates favoring greater increases, and on the type of limitation. Limitation for either carbon or phosphorus resulted in maximum increases, whereas severe limitation of Mg2+ caused only a slight increase. The increase in nonspecific acid phosphatase during carbon limitation was apparently not mediated by the catabolite repression system since mutants lacking adenyl cyclase or the cyclic AMP receptor protein still produced elevated levels of this enzyme during carbon starvation. Nor did the increase during phosphorus limitation appear to be mediated by the alkaline phosphatase regulatory system. A strain of Salmonella bearing a chromosomal mutation, which caused constitutive production of alkaline phosphatase (introduced by an episome from Escherichia coli), did not have constitutive levels of nonspecific acid phosphatase.

Thiogalactoside transacetylase of the lactose operon as an enzyme for detoxification

Thigalactoside transacetylase, the lacA gene product, confers selective advantage to cells of Escherichia coli K-12 growing on beta-galactosides in the presence of non-metabolizable analogues.

In vivo transcription of R-plasmid deoxyribonucleic acid in Escherichia coli strains with altered antibiotic resistance levels and/or conjugal proficiency

The amounts of plasmid deoxyribonucleic acid (DNA) and the levels of the in vivo transcription of the Escherichia coli plasmids R538-1 (repressed for conjugal transfer) and R538-1drd (derepressed for transfer) were determined by DNA-DNA hybridization and DNA-ribonucleic acid hybridization, respectively. The results demonstrate that the level of plasmid transcription is increased by two-fold in the strain carrying the derepressed plasmid, compared to an isogenic strain carrying the repressed plasmid, whereas the amount of plasmid DNA is approximately the same, suggesting that the transfer genes are under transcriptional control. Levels of plasmid DNA, plasmid DNA transcription, and chloramphenicol acetyltransferase activity were also compared in a mutant strain that carried the R538-1drd plasmid and was resistant to high levels of antibiotics. This strain produces about 13 copies of plasmid DNA per chromosome compared to five copies for the parent strain. The level of transcription of plasmid DNA was found to be twofold higher in the high-level resistant strain, whereas the level of chloramphenition, acetyltransferase activity was increased by 10-fold. In addition the levels of plasmid DNA transcription and chloramphenicol acetyltransferase activity in the high-level resistant strain were found to be further increased by the presence of high levels of chloramphenicol in the growth medium. The amount of plasmid DNA remained constant under these conditions, indicating that high levels of chloramphenicol can stimulate the expression of plasmid genes at the level of transcription in this strain.

Variation in expression of sex factor genes in the Proteus-Providencia group relative to Escherichia coli

Several instances of anomalous expression of genes introduced from Escherichia coli K-12 into Proteus mirabilis have been described. It is shown here that control of sex pilus synthesis directed by the F-like R factor R1 and its depressed derivatives R1-16 (O-C) and R1-19 (i-minus) is also anomalous in P. mirabilis. Piliation in cells bearing the depressed plasmids is expressed at a lower level than in E. coli K-12, and repression is absent in R1-carrying cells. Preliminary results show a similar effect in Providencia. In Proteus morganii, a similarly reduced level of piliation in R1-16-+ or R1-19-+ cultures is observed, but an intermediate level of repression occurs in R1-+ cultures. Less extensive data suggest that expression of the sex factor genes of an R factor of the N incompatibility group differs far less between E. coli and P. mirabilis hosts. Possible bases for these effects are discussed.

Effects of guanosine tetraphosphate, guanosine pentaphosphate, and beta-gamma methylenyl-guanosine pentaphosphate on gene expression of Escherichia coli in vitro

The effects of guanosine tetraphosphate (ppGpp) and guanosine pentaphosphate (pppGpp), both produced by E. coli, were measured on the activities of several genes in a cell-free system. Gene activity is measured as gene-directed synthesis of biochemically competent protein or transfer RNA. Both ppGpp and pppGpp stimulated the activities of the ara, lac, and trp operons and inhibited the arg operon. Production of transfer-RNA(Tyr) was unaffected by moderate levels of either ppGpp or pppGpp and only slightly inhibited at higher levels of ppGpp. Since the cell-free reaction mixtures hydrolyze pppGpp to ppGpp, we performed similar studies with a hydrolysis-resistant analog of pppGpp, the beta-gamma methylenyl derivative (pcppGpp). In general, pcppGpp shows the same inhibitory potency as pppGpp for the arg operon, but lacks the stimulatory effects on the ara, lac, and trp operons. This result suggests that the stimulation of these gene activities is specific for ppGpp.Under similar conditions, pppGpp and ppGpp show a slight inhibitory effect on the messenger-directed synthesis of beta-galactosidase and no effect on the messenger-directed synthesis of MS2 viral-coat protein. These observations, together with the fact that in the same system these nucleotides affect coupled transcription and translation, lead us to surmise that the activities of pppGpp and ppGpp are exerted at the level of RNA polymerase activity.