Repressor and Antirepressor in the Regulation of Staphylococcal Penicillinase Synthesis

5-methyltryptophan (5MT) induces penicillinase synthesis in Staphylococcus aureus. The analog is incorporated into protein by both wild-type and tryptophan-starved cells. Since normal penicillinase repressor appears to contain tryptophan even though penicillinase itself does not, it is concluded that 5MT induces penicillinase synthesis by becoming incorporated into the penicillinase repressor and thereby inactivating the repressor. Thus biochemical data support the existence of a penicillinase repressor and indicate that penicillinase synthesis is regulated by negative control and not by positive control.-In the absence of exogenous tryptophan, staphylococcal penicillinase induction can be inhibited by 7-azatryptophan (7azaT). Because 7azaT is incorporated into protein by tryptophan-starved cells, it is concluded that 7azaT blocks penicillinase induction by inactivating a penicillinase regulatory protein into which the analog has been incorporated. Incorporation of 7azaT does not appear to inactivate the operator binding site or the effector binding site on the penicillinase repressor. Therefore, it appears that 7azaT blocks penicillinase induction by inactivating the penicillinase antirepressor, a protein required for inactivation of the penicillinase repressor and, hence, required for penicillinase induction.     

Nature of the plasmid-linked penicillinase regulatory region in Staphylococcus aureus

Summary Four noninducible staphylococcal penicillinase plasmids reported to produce a very low basal level of penicillinase were investigated. Incorporation of 5-methyltryptophan, which is known to inactivate the operator binding site of wild-type penicillinase repressor and thereby elicit penicillinase synthesis, did not induce penicillinase synthesis in any of these micro mutants. Therefore, these plasmids are not simply peni ^S mutants. Heterodiploid strains composed of a plasmid fully constitutive for penicillinase synthesis and one of the various micro penicillinase plasmids were constructed. Three of these heterodiploids produce a normal basal level of penicillinase and are inducible by 5-methyltryptophan but not by the standard gratuitous penicillinase inducer. Therefore, each of these three noninducible micro plasmids produces a peni ^S repressor, but in addition, each must bear a mutation in the penZ region. The fourth heterodiploid produces a fully constitutive level of penicillinase. The noninducible micro plasmid present in this heterodiploid must contain a penI ^– mutation and a mutation in the penZ region. Consequently, each of these four noninducible micro plasmids contains at least two mutants genes. Hence, the phenotype of noninducibility plus low basal penicillinase is not due to a point mutation in a second penicillinase regulatory region as has been proposed. Instead, these results strongly suggest that there is only one penicillinase regulatory gene located on the penicillinase plasmid and that this gene (penI) specifies the penicillinase repressor.Journal Paper No. J-8700 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa; Project No. 2029     

Regulation of Staphylococcal Penicillinase Synthesis

5-Methyl tryptophan was found to be an efficient inducer of penicillinase synthesis in Staphylococcus aureus. Addition of actinomycin D or tryptophan to the culture medium shuts off the 5-methyl tryptophan-induced synthesis of penicillinase with an apparent half-life of approximately 1 to 2 min, respectively. Hence, in the induction of penicillinase synthesis, 5-methyl tryptophan seems to function as a structural analogue of penicillin rather than by becoming incorporated in proteins and thereby creating faulty penicillinase repressor or antirepressor. This conclusion is supported by similarities in the structures of the two compounds as revealed by solid atomic models. The fact that S. aureus exposed to (14)C-penicillin in the absence of protein synthesis failed to synthesize penicillinase at an increased level when cell growth was resumed strongly suggests that a protein involved in the regulation of penicillinase synthesis must be synthesized in the presence of the penicillinase inducer. In turn, this observation suggests that the penicillinase inducer promotes penicillinase synthesis by directing the penicillinase regulatory protein (i.e., the penicillinase antirepressor) to acquire a different conformation when it is synthesized in the presence of the penicillinase inducer. A working model for the regulation of penicillinase synthesis based on these and other data has been constructed and is presented.     

Phenotypic Suppression of Methicillin Resistance in Staphylococcus aureus by Mutant Noninducible Penicillinase Plasmids

Methicillin (intrinsic) resistance of Staphylococcus aureus was suppressed almost completely by regulatory gene (penI₁) mutations of penicillinase plasmids that made penicillinase production strictly noninducible. Methicillin resistance was restored by secondary regulatory gene mutations that altered the noninducible phenotype or by complementation with a compatible plasmid that did not bear the noninducible mutation. No evidence was obtained for genetic linkage between a penicillinase plasmid and the gene for methicillin resistance. We suggest, therefore, that the mutant noninducible repressor acted in trans by binding to a site on the methicillin resistance determinant. This hypothesis would imply an appreciable degree of homology between penicillinase plasmids and methicillin resistance genes.     

Nucleotide sequence of the penicillinase repressor gene penI of Bacillus licheniformis and regulation of penP and penI by the repressor.

Bacillus licheniformis penicillinase genes, penP and penI, are coded on a 4.2-kilobase EcoRI fragment of pTTE21 (T. Imanaka, T. Tanaka, H. Tsunekawa, and S. Aiba, J. Bacteriol. 147:776-186, 1981). The EcoRI fragment was subcloned in a low-copy-number plasmid pTB522 in Bacillus subtilis. B. subtilis carrying the recombinant plasmid pPTB60 (Tcr penP+ penI+) was chemically mutagenized. Of about 150,000 colonies, two penI(Ts) mutant plasmids, pPTB60D13 and pPTB60E24, were screened by the plate assay at 30 and 48 degrees C for penicillinase. By constructing recombinant plasmids between wild-type and mutant plasmids, the mutation points were shown to be located in a 1.7-kilobase EcoRI-PstI fragment. The EcoRI-PstI fragments of the wild-type plasmid and two mutant plasmids were sequenced. A large open reading frame, composed of 384 bases and 128 amino acid residues (molecular weight, 14,983), was found. Since the mutation points were located at different positions in the protein coding region (Ala to Val for pPTB60D13 and Pro to Leu for pPTB60E24), the coding region was concluded to be the penI gene. A Shine-Dalgarno sequence was found 7 bases upstream from the translation start site (ATG). A probable promoter sequence which is very similar to the consensus sequence was also found upstream of the penP promoter, but in the opposite direction. A consensus twofold symmetric sequence (AAAGTATTA CATATGTAAGNTTT) which might have been used as a repressor binding region was found downstream and in the midst of the penP promoter and also downstream of the penI promoter. The regulation of penP and penI by the repressor is discussed.     

Analogs of the dnaB gene of Escherichia coli K-12 associated with conjugative R plasmids.

The dnaB266(Am) mutation in Escherichia coli K-12 is an amber mutation such that strains carrying this mutation are not viable in a sup+ strain. With five different R plasmids, it has been possible to construct viable R+ derivatives of this amber mutant and show that the plasmids themselves do not carry amber suppressors. This is interpreted as evidence for the presence of dnaB analog genes associated with these plasmids. Plasmid-positive strains carrying these genes often showed some degree of cryosensitivity of DNA synthesis and colony-forming ability. These observations indicate that the presence of dnaB analog genes in association with R plasmids must be relevant to the plasmid state or to some aspect of conjugative ability.     

Stability of Penicillinase Plasmids in Staphylococcus aureus

The isolation of mutants of Staphylococcus aureus that are affected in the stability of penicillinase plasmids is described. One mutation is plasmid borne and results in nonreplication of the plasmid at 42 C. A second type of mutation is host-borne and gives rise to instability of both mcr(I) and mcr(II) penicillinase plasmids but not a tetracycline-resistant plasmid.     

The effect of membrane-bound beta-lactamase on linoleic acid sensitivity in Staphylococcus aureus

The presence of a plasmid conferring resistance to penicillin (PC plasmid, e.g. pI258blaI-) in Staphylococcus aureus NCTC 8325 increases the sensitivity of such a bacterium to the growth inhibitory effects of linoleic acid, whereas a plasmid conferring resistance to tetracycline does not affect linoleic acid sensitivity. The increased linoleic acid sensitivity of bacteria containing a PC plasmid may be related to the penicillinase protein itself since (i) strains having inducible penicillinase show increased sensitivity only after induction, (ii) strains in which penicillinase is directed from chromosomal or plasmid-borne genes show similar increased linoleic acid sensitivity and (iii) notwithstanding the above, the linoleic acid inhibitory effect is enhanced in a strain in which penicillinase activity is greatly reduced by a point mutation in the structural gene for penicillinase. The enhanced linoleic acid sensitivity seems to require the membrane-bound penicillinase since added extracellular penicillinase does not confer this sensitivity, and there appears to be a specific interaction between the membrane-bound penicillinase activity and linoleic acid.     

Regulation of a Ligand-Mediated Association-Dissociation System of Anthranilate Synthesis in Clostridium butyricum

The anthranilate synthetase of Clostridium butyricum is composed of two nonidentical subunits of unequal size. An enzyme complex consisting of both subunits is required for glutamine utilization in the formation of anthranilic acid. Formation of anthranilate will proceed in the presence of partially pure subunit I provided ammonia is available in place of glutamine. Partially pure subunit II neither catalyzes the formation of anthranilate nor possesses anthranilate-5-phosphoribosylpyrophosphate phosphoribosyltransferase activity. The enzyme complex is stabilized by high subunit concentrations and by the presence of glutamine. High KCl concentrations promote dissociation of the enzyme into its component subunits. The synthesis of subunits I and II is coordinately controlled with the synthesis of the enzymes mediating reactions 4 and 5 of the tryptophan pathway. When using gel filtration procedures, the molecular weights of the large (I) and small (II) subunits were estimated to be 127,000 and 15,000, respectively. Partially pure anthranilate synthetase subunits were obtained from two spontaneous mutants resistant to growth inhibition by 5-methyltryptophan. One mutant, strain mtr-8, possessed an anthranilate synthetase that was resistant to feedback inhibition by tryptophan and by three tryptophan analogues: 5-methyl-tryptophan, 4- and 5-fluorotryptophan. Reconstruction experiments carried out by using partially purified enzyme subunits obtained from wild-type, mutant mtr-8 and mutant mtr-4 cells indicate that resistance of the enzyme from mutant mtr-8 to feedback inhibition by tryptophan or its analogues was the result of an alteration in the large (I) subunit. Mutant mtr-8 incorporates [(14)C]tryptophan into cell protein at a rate comparable with wild-type cells. Mutant mtr-4 failed to incorporate significant amounts of [(14)C]tryptophan into cell protein. We conclude that strain mtr-4 is resistant to growth inhibition by 5-methyltryptophan because it fails to transport the analogue into the cell. Although mutant mtr-8 was isolated as a spontaneous mutant having two different properties (altered regulatory properties and an anthranilate synthetase with altered sensitivity to feedback inhibition), we have no direct evidence that this was the result of a single mutational event.     

Inhibition of yeast tRNATrp aminoacylation by 4-methyltryptophan

The effect of the tryptophan analogue 4-methyltryptophan in Saccharomyces cerevisiae has been investigated. 4-Methyltryptophan inhibits the aminoacylation of tryptophan specific transfer ribonucleic acid (tRNA^Trp). The mode of inhibition is competitive and the analogue is not charged onto tRNA^Trp. Thus 4-methyltryptophan application depletes the cells from charged tRNA^Trp. As a consequence cell growth and protein synthesis are strongly reduced. 4-Methyltryptophan is degraded efficiently in culture media inoculated with the wild type strain; the effects of 4-methyltryptophan were therefore found to be transient.     

Mutant Tryptophan Aporepressors with Altered Specificities of Corepressor Recognition

The Escherichia coli trpR gene encodes tryptophan aporepressor, which binds the corepressor ligand, L-tryptophan, to form an active repressor complex. The side chain of residue valine 58 of Trp aporepressor sits at the bottom of the corepressor (L-tryptophan) binding pocket. Mutant trpR genes encoding changes of Val(58) to the other 19 naturally occurring amino acids were made. Each of the mutant proteins requires a higher intracellular concentration of tryptophan for activation of DNA binding than wild-type aporepressor. Whereas wild-type aporepressor is activated better by 5-methyltryptophan (5-MT) than by tryptophan, Ile(58) and other mutant aporepressors prefer tryptophan to 5-MT as corepressor, and Ala(58) and Gly(58) prefer 5-MT much more strongly than wild-type aporepressor in vivo. These mutant aporepressors are the first examples of DNA-binding proteins with altered specificities of cofactor recognition.     

Involvement of plasmid deoxyribonucleic acid in indoleacetic acid synthesis in Pseudomonas savastanoi.

Olive (or oleander) knot is a plant disease incited by Pseudomonas savastanoi. Disease symptoms consist of tumorous outgrowths induced in the plant by bacterial production of indole-3-acetic acid (IAA). Synthesis of IAA occurs by the following reactions: L-tryptophan leads to indoleacetamide leads to indoleacetic acid, catalyzed by tryptophan 2-monooxygenase and indoleacetamide hydrolase, respectively. Whereas the enzymology of IAA synthesis is well characterized, nothing is known about the genetics of the system. We devised a positive selection for the presence of tryptophan 2-monooxygenase based on its capacity to use as a substrate the toxic tryptophan analogue 5-methyltryptophan. Efficient curing of the bacterium of tryptophan 2-monoxygenase, indoleacetamide hydrolase, and IAA production was obtained by acridine orange treatment. Further, loss of capacity to produce IAA by curing was correlated with loss of a plasmid of 34 X 10(6) molecular weight. This plasmid, here called pIAA1, when reintroduced into Iaa- mutants by transformation, restored tryptophan 2-monooxygenase and indoleacetamide hydrolase activities and production of IAA.     

Mutations of temperature sensitivity in R plasmid pSC101.

Temperature-sensitive (Ts) mutant plasmids isolated from tetracycline resistance R plasmid pSC101 were investigated for their segregation kinetics and deoxyribonucleic acid (DNA) replication. The results fit well with the hypothesis that multiple copies of a plasmid are distributed to daughter cells in a random fashion and are thus diluted out when a new round of plasmid DNA replication is blocked. When cells harboring type I mutant plasmids were grown at 43 degrees C in the absence of tetracycline, antibiotic-sensitive cells were segregated after a certain lag time. This lag most likely corresponds to a dilution of plasmids existing prior to the temperature shift. The synthesis of plasmid DNA in cells harboring type I mutant plasmids was almost completely blocked at 43 degrees C. It seems that these plasmids have mutations in the gene(s) necessary for plasmid DNA replication. Cells haboring a type II mutant plasmid exhibited neither segregation due to antibiotic sensitivity nor inhibition of plasmid DNA replication throughout cultivation at high temperature. It is likely that the type II mutant plasmid has a temperature-sensitive mutation in the tetracycline resistance gene. Antibiotic-sensitive cells haboring type III mutant plasmids appeared at high frequency after a certain lag time, and the plasmid DNA synthesis was partially suppressed at the nonpermissive temperature. They exhibited also a pleiotrophic phenotype, such as an increase of drug resistance level at 30 degrees C and a decrease in the number of plasmid genomes in a cell.     

Physiological study of ergot: induction of alkaloid synthesis by tryptophan at the enzymatic level.

The enhancement of ergot alkaloid production by tryptophan and its analogues in both normal and high-phosphate cultures is more directly related to increased dimethylallyltryptophan (DMAT) synthetase activity rather than to a lack of regulation of the tryptophan biosynthetic enzymes. Thiotryptophan [beta-(1-benzo-thien-3-yl)-alanine] is rather ineffective in the end product regulation of tryptophan biosynthesis, whereas tryptophan and 5-methyltryptophan are potent effectors. The presence of increased levels of DMAT synthetase in ergot cultures supplemented with tryptophan or thiotryptophan, and to a lesser extent with 5-methyltryptophan, suggests that the induction effect involves de novo synthesis of the enzyme. Thiotryptophan and tryptophan but not 5-methyltryptophan can overcome the block of alkaloid synthesis by inorganic phosphate. The results with thiotryptophan indicate that the phosphate effect cannot be explained merely on the basis of a block of tryptophan synthesis.     

Action of tryptophan analogues in Saccharomyces cerevisiae

In an analysis of the effects of various tryptophan and indole analogues in Saccharomyces cerevisiae we determined the mechanisms by which they cause growth inhibition: 4-Methyltryptophan causes a reduction in protein synthesis and a derepression of the tryptophan enzymes despite of the presence of high internal levels of tryptophan. This inhibition can only be observed in a mutant with increased permeability to the analogue. These results are consistent with but do not prove an interference of this analogue with the charging of tryptophan onto tRNA. 5-Methyltryptophan causes false feedback inhibition of anthranilate synthase, the first enzyme of the tryptophan pathway. This inhibits the further synthesis of tryptophan and results in results in tryptophan limitation, growth inhibition and derepression of the enzymes. Derepression eventually allows wild type cells to partially overcome the inhibitory effect of the analogue. 5-Fluoroindole is converted endogenously to 5-fluorotryptophan by tryptophan synthase. Both endogenous and externally supplied 5-fluorotryptophan are incorporated into protein. This leads to intoxication of the cells due to the accumulation of faulty proteins. 5-Fluorotryptophan also causes feedback inhibition of anthranilate synthase and reduces the synthesis of tryptophan which would otherwise compete with the analogues in the charging reaction. Indole acrylic acid inhibits the conversion of indole to tryptophan by tryptophan synthase. This results in a depletion of the tryptophan pool which, in turn, causes growth inhibition and derepression of the tryptophan enzymes.Abbreviations cpm counts per minute - OD optical density at 546 nm - TCA trichloro acetic acid - tRNA transfer ribonucleic acid; trp1 to trp5 refer to the structural genes for the corresponding tryptophan biosynthetic enzymes - trpl^– res. trp1^± refer to mutant strains synthesizing completely resp. partially defective enzymes     

Free tryptophan pool and tryptophan biosynthetic enzymes in Saccharomyces cerevisiae

The free tryptophan pool and the levels of two enzymes of tryptophan biosynthesis (anthranilate synthase and indoleglycerolphosphate synthase) have been determined in a wild type strain of Saccharomyces cerevisiae and in mutants with altered regulatory properties.The tryptophan pool of wild type cells growing in minimal medium is 0.07 mole per g dry weight. Addition of anthranilate, indole or tryptophan to the medium produces a fifteen- to forty-fold increase in tryptophan pool, but causes no repression of the biosynthetic enzymes. Inclusion of 5-methyltryptophan in the growth medium causes a reduction in growth rate and a derepression of the biosynthetic enzymes, and this is shown here not to be correlated with a decrease in the free tryptophan pool.Mutants with an altered anthranilate synthase showing decreased sensitivity to inhibition by l-tryptophan or by the analogue dl-5-methyltryptophan have a tryptophan pool far higher than the wild type strain, but no repression of indoleglycerolphosphate synthase was observed. Mutants with an anthranilate synthase more sensitive to tryptophan inhibition show a slightly reduced tryptophan pool, but no derepression of indoleglycerolphosphate synthase was found.A mutant with constitutively derepressed levels of the biosynthetic enzymes shows a considerably increased tryptophan pool. Addition of 5-methyltryptophan to the growth medium of non-derepressible mutants causes a decrease in growth rate accompanied by a decrease in the tryptophan pool.Abbreviations CDRP 1-(o-carboxyphenylamino)-1-deoxyribulosephosphate - paba paraaminobenzoic acid - PRA N-(5-phosphoribosyl)-anthranilate - tRNA transfer ribonucleic acid; trp1 to trp5 refer to the structural genes for corresponding tryptophan biosynthetic enzymes