Production of two proteins encoded by the Bacteroides mobilizable transposon NBU1 correlates with time-dependent accumulation of the excised NBu1 circular form

NBU1 is a mobilizable transposon that excises from the Bacteroides chromosome to form a double-stranded circular transfer intermediate. Excision is triggered by exposure of the bacteria to tetracycline. Accordingly, we expected that the expression of NBU1 genes would be induced by tetracycline. To test this hypothesis, antibodies that recognized two NBU1-encoded proteins, PrmN1 and MobN1, were used to monitor production of these proteins. PrmN1 is essential for excision, and MobN1 is essential for transfer of the excised circular form. At first, expression of the genes encoding these two proteins appeared to be regulated by tetracycline, because the proteins were detectable on Western blots only after the cells were exposed to tetracycline. However, when the prmN1 gene and/or the mobN1 gene was cloned on a multicopy plasmid, production of the protein was constitutive. Initially, we assumed that the constitutive expression was due to loss of a repressor protein that was encoded by one of the other genes on NBU1. Deletions or insertions in the other genes (orf2 and orf3) on NBU1 and various integrated NBU1 derivatives abolished production of PrmN1 and MobN1. This is the opposite of what should have happened if one or both of these genes encoded a repressor. A second possibility was that when NBU1 excised, it replicated transiently, increasing the gene dosage of prmN1 and mobN1 and thereby producing enough PrmN1 and MobN1 for these proteins to become detectable. In fact, after the cells entered late exponential phase the copy number of NBU1 increased to 2 to 3 copies per cell. Production of PrmN1 and MobN1 showed a similar pattern. Any mutation in NBU1 that decreased or prevented excision also prevented elevated production of these two proteins. Our results show that the apparent tetracycline dependence of the production of PrmN1 and MobN1 is due to a growth phase- or time-dependent increase in the number of copies of the NBU1 circular form.     

Unexpected effect of a Bacteroides conjugative transposon, CTnDOT, on chromosomal gene expression in its bacterial host

Foreign DNA elements such as plasmids and conjugative transposons are constantly entering new bacterial hosts. A possible outcome of such events that has not been considered previously is that regulatory genes carried on some of them might affect the expression of chromosomal genes of the new host. To assess this possibility, we investigated the effect of the Bacteroides conjugative transposon CTnDOT on expression of chromosomal genes in Bacteroides thetaiotaomicron 5482 (BT4001). Most of the upregulated genes were genes of unknown function, but a number of them were associated with a region of the chromosome that contained a putative conjugative transposon, which had been tentatively designated as CTn4-bt. Upregulation of CTn4-bt genes and other chromosomal genes affected by CTnDOT was controlled by two regulatory genes on CTnDOT, rteA and rteB, which encode a two-component regulatory system. Transfer of CTn4-bt was also mediated by rteA and rteB. Three other putative CTns, CTn1-bt, CTn2-bt and CTn3-bt, were mobilized by CTnERL, a CTn closely related to CTnDOT, but genes from CTnERL other than rteA and rteB were also required. Unexpectedly, homologous recombination was required for CTn1-bt, CTn2-bt, CTn3-bt and CTn4-bt to integrate in the recipient. Our results show that regulatory genes on an incoming mobile element can have multiple effects on its new host, including the activation of previously non-transmissible elements.     

Tetracycline-dependent appearance of plasmidlike forms in Bacteroides uniformis 0061 mediated by conjugal Bacteroides tetracycline resistance elements.

Some human colonic Bacteroides strains carry conjugal tetracycline resistance (Tcr) elements, which are thought to be chromosomal. We have found that some of these Tcr elements can mediate the appearance of plasmidlike forms in Bacteroides uniformis 0061. When B. uniformis 0061, containing a conjugal Tcr element designated Tcr ERL, was grown in medium containing tetracycline (1 microgram/ml), two circular DNA forms were found in the alkaline plasmid preparations: NBU1 (10.3 +/- 0.5 kilobases) and NBU2 (11.5 +/- 0.5 kilobases). Restriction analysis of NBU1 and NBU2 showed that they were not identical, although Southern blot analysis indicated that they did contain some region(s) of homology. Results of Southern blot analysis also demonstrated that both NBU1 and NBU2 were normally integrated in the chromosome of B. uniformis or in some undetected large plasmid. Although we were unable to determine the exact structure and location of the integrated forms of NBU1 and NBU2 in B. uniformis, they appear to be in close proximity to each other. Neither NBU1 or NBU2 could be detected as a plasmidlike form in cells exposed to UV light, thymidine starvation, mitomycin C, or autoclaved chlortetracycline (50 micrograms/ml). Four conjugal Tcr elements other than the Tcr ERL element were able to mediate the appearance of NBU1 alone, and two Tcr elements did not mediate the excision of either NBU1 or NBU2. Three strains from different Bacteroides species contained some DNA sequences which had homology to NBU1 and NBU2.     

Identification of genes required for excision of CTnDOT, a Bacteroides conjugative transposon

Integrated self-transmissible elements called conjugative transposons have been found in many different bacteria, but little is known about how they excise from the chromosome to form the circular intermediate, which is then transferred by conjugation. We have now identified a gene, exc, which is required for the excision of the Bacteroides conjugative transposon, CTnDOT. The int gene of CTnDOT is a member of the lambda integrase family of recombinases, a family that also contains the integrase of the Gram-positive conjugative transposon Tn916. The exc gene was located 15 kbp from the int gene, which is located at one end of the 65 kbp element. The exc gene, together with the regulatory genes, rteA, rteB and rteC, were necessary to excise a miniature form of CTnDOT that contained only the ends of the element and the int gene. Another open reading frame (ORF) in the same operon and upstream of exc, orf3, was not essential for excision and had no significant amino acid sequence similarity to any proteins in the databases. The deduced amino acid sequence of the CTnDOT Exc protein has significant similarity to topoisomerases. A small ORF (orf2) that could encode a small, basic protein comparable with lambda and Tn916 excision proteins (Xis) was located immediately downstream of the CTnDOT int gene. Although Xis proteins are required for excision of lambda and Tn916, orf2 had no effect on excision of the element. Excision of the CTnDOT mini-element was not affected by the site in which it was integrated, another difference from Tn916. Our results demonstrate that the Bacteroides CTnDOT excision system is tightly regulated and appears to be different from that of any other known integrated transmissible element, including those of some Bacteroides mobilizable transposons that are mobilized by CTnDOT.     

Excision, transfer, and integration of NBU1, a mobilizable site-selective insertion element.

The Bacteroides species harbor a family of conjugative transposons called tetracycline resistance elements (Tcr elements) that transfer themselves from the chromosome of a donor to the chromosome of a recipient, mobilize coresident plasmids, and also mediate the excision and circularization of members of a family of 10- to 12-kbp insertion elements which share a small region of DNA homology and are called NBUs (for nonreplicating Bacteroides units). The NBUs are sometimes cotransferred with Tcr elements, and it was postulated previously that the excised circular forms of the NBUs were plasmidlike forms and were transferred like plasmids and then integrated into the recipient chromosome. We used chimeric plasmids containing one of the NBUs, NBU1, and a Bacteroides-Escherichia coli shuttle vector to show that this hypothesis is probably correct. NBU1 contained a region that allowed mobilization by both the Tcr elements and IncP plasmids, and we used these conjugal elements to allow us to estimate the frequencies of excision, mobilization, and integration of NBU1 in Bacteroides hosts to be approximately 10(-2), 10(-5) to 10(-4), and 10(-2), respectively. Although functions on the Tcr elements were required for the excision-circularization and mobilization of NBU1, no Tcr element functions were required for integration into the recipient chromosome. Analysis of the DNA sequences at the integration region of the circular form of NBU1, the primary insertion site in the Bacteroides thetaiotaomicron 5482 chromosome, and the resultant NBU1-chromosome junctions showed that NBU1 appeared to integrate into the primary insertion site by recombining within an identical 14-bp sequence present on both NBU1 and the target, thus leaving a copy of the 14-bp sequence at both junctions. The apparent integration mechanism and the target selection of NBU1 were different from those of both XBU4422, the only member of the conjugal Tcr elements for which these sequences are known, and Tn4399, a mobilizable Bacteroides transposon. The NBUs appear to be a distinct type of mobilizable insertion element.     

Activity of translation system and abundance of tmRNA during development ofStreptomyces aureofaciens producing tetracycline

Transition from exponential phase of growth to stationary phase in Streptomyces aureofaciens is characterized by a decrease in the rate of translation and induction of tetracycline (Ttc) biosynthesis. In exponential phase, no significant changes were found in the activity of ribosomes at binding of ternary complex Phe-tRNA.EF-Tu.GTP to the A-site on ribosomes. Overexpression of Ttc in stationary phase is accompanied by a decrease in the binding of the ternary complex Phe-tRNA.EF-Tu.GTP to the A-site of ribosome and a formation of an aggregate with Ttc by part of the ribosomes. Antibiotics that cause ribosome to stall or pause could increase the requirement for tmRNA in the process called trans-translation. We found differences in the level of tmRNA during the development of S. aureofaciens. Subinhibitory concentrations of Ttc, streptomycin and chloramphenicol induced an increase in the tmRNA level in cells from the exponential phase of growth. In vitro trans-translation system of S. aureofaciens was sensitive to Ttc at a concentration of > 15 micromol/L; the trans-translation system can thus be considered to contribute to resistance against Ttc produced only at sublethal concentrations. These experiments suggest that the main role of the rising tmRNA level at the beginning of the Ttc production is connected with ribosome rescue.     

Activation of the alarm response of Escherichia by antibiotics

The data on the effect of antibiotics suppressing the synthesis of protein on the activation of the SOS-system are presented. The action of tetracycline, chloramphenicol rifampicin and nalidixic acid, a well-known activator of SOS-response, has been studied. The short-term action of inhibitory concentrations and the prolonged action of subinhibitory concentrations of these preparations on the activity of genes rec A and sul A and the induction of the synthesis of phage lambda have been considered. Chloramphenicol and tetracycline, as well as nalidixic acid, have been shown to be capable of activating genes rec A, sul A and synthesis of the phage. The induction of SOS-response has been found to be more pronounced in the short-term action of inhibitory concentrations of antibiotics on bacteria than in the prolonged subinhibitory concentrations.     

Blasticidin S inhibits mammalian translation and enhances production of protein encoded by nonsense mRNA

Deciphering translation is of paramount importance for the understanding of many diseases, and antibiotics played a pivotal role in this endeavour. Blasticidin S (BlaS) targets translation by binding to the peptidyl transferase center of the large ribosomal subunit. Using biochemical, structural and cellular approaches, we show here that BlaS inhibits both translation elongation and termination in Mammalia. Bound to mammalian terminating ribosomes, BlaS distorts the 3′CCA tail of the P-site tRNA to a larger extent than previously reported for bacterial ribosomes, thus delaying both, peptide bond formation and peptidyl-tRNA hydrolysis. While BlaS does not inhibit stop codon recognition by the eukaryotic release factor 1 (eRF1), it interferes with eRF1’s accommodation into the peptidyl transferase center and subsequent peptide release. In human cells, BlaS inhibits nonsense-mediated mRNA decay and, at subinhibitory concentrations, modulates translation dynamics at premature termination codons leading to enhanced protein production.     

Antimicrobial and anti-pathogenic activity of some thioureides derivatives against Erwinia amylovora phytopathogenic strains

A series of N-(1-methyl-1 Hpyrazole-4-carbonyl)-thiourea derivatives were assessed for their in vitro antimicrobial and anti-pathogenic activity against twenty-two strains of Erwinia amylovora isolated from different regions in Romania. The compounds were solubilised in dimethylsulfoxide and screened for their in vitro antimicrobial activity. The qualitative screening of the susceptibility spectra of various strains to the compounds was performed by adapted diffusion techniques (distribution of the tested compound solution directly on the solid medium previously seeded with the bacterial inoculums). The quantitative assay of the minimal inhibitory concentration (MIC, microg/mL) was based on liquid medium two-fold microdilutions. The subinhibitory concentrations of the tested substances were investigated for their influence on biofilm development on inert substrata. The present study showed that six new thiourea compounds exhibited a low antibacterial activity (MIC values > 500 microg/ml), but the subinhibitory concentrations inhibited the biofilm development on inert substrata. Thus, these results could suggest the usefulness of the tested compounds as control agents for preventing the first stage (colonization) of the infection with the fire blight pathogen.     

Translational control of tetracycline resistance and conjugation in the Bacteroides conjugative transposon CTnDOT

The tetQ-rteA-rteB operon of the Bacteroides conjugative transposon CTnDOT is responsible for tetracycline control of the excision and transfer of CTnDOT. Previous studies revealed that tetracycline control of this operon occurred at the translational level and involved a hairpin structure located within the 130-base leader sequence that lies between the promoter of tetQ and the start codon of the gene. This hairpin structure is formed by two sequences, designated Hp1 and Hp8. Hp8 contains the ribosome binding site for tetQ. Examination of the leader region sequence revealed three sequences that might encode a leader peptide. One was only 3 amino acids long. The other two were 16 amino acids long. By introducing stop codons into the peptide coding regions, we have now shown that the 3-amino-acid peptide is the one that is essential for tetracycline control. Between Hp1 and Hp8 lies an 85-bp region that contains other possible RNA hairpin structures. Deletion analysis of this intervening DNA segment has now identified a sequence, designated Hp2, which is essential for tetracycline regulation. This sequence could form a short hairpin structure with Hp1. Mutations that made the Hp1-Hp2 structure more stable caused nearly constitutively high expression of the operon. Thus, stalling of ribosomes on the 3-amino-acid leader peptide could favor formation of the Hp1-Hp2 structure and thus preclude formation of the Hp1-Hp8 structure, releasing the ribosome binding site of tetQ. Finally, comparison of the CTnDOT tetQ leader regions with upstream regions of five tetQ genes found in other elements reveals that the sequences are virtually identical, suggesting that translational attenuation is responsible for control of tetracycline resistance in these other cases as well.     

In-vitro activity of miltefosine and voriconazole on clinical isolates of free-living amebas: Balamuthia mandrillaris, Acanthamoeba spp., and Naegleria fowleri

The anticancer agent miltefosine and the antifungal drug voriconazole were tested in vitro against Balamuthia mandrillaris, Acanthamoeba spp., and Naegleria fowleri. All three amebas are etiologic agents of chronic (Balamuthia, Acanthamoeba) or fulminant (Naegleria) encephalitides in humans and animals and, in the case of Acanthamoeba, amebic keratitis. Balamuthia exposed to <40 microm concentrations of miltefosine survived, while concentrations of >or=40 microM were generally amebacidal, with variation in sensitivity between strains. At amebastatic drug concentrations, recovery from drug effects could take as long as 2 weeks. Acanthamoeba spp. recovered from exposure to 40 microM, but not 80 microM miltefosin. Attempts to define more narrowly the minimal inhibitory (MIC) and minimal amebacidal concentrations (MAC) for Balamuthia and Acanthamoeba were difficult due to persistence of non-proliferating trophic amebas in the medium. For N. fowleri, 40 and 55 microM were the MIC and MAC, respectively, with no trophic amebas seen at the MAC. Voriconazole had little or no inhibitory effect on Balamuthia at concentrations up to 40 microg/ml, but had a strong inhibitory effect upon Acanthamoeba spp. and N. fowleri at all drug concentrations through 40 microg/ml. Following transfer to drug-free medium, Acanthamoeba polyphaga recovered within a period of 2 weeks; N. fowleri amebas recovered from exposure to 1 microg/ml, but not from higher concentrations. All testing was done on trophic amebas; drug sensitivities of cysts were not examined. Miltefosine and voriconazole are potentially useful drugs for treatment of free-living amebic infections, though sensitivities differ between genera, species, and strains.     

Structure–Activity Relationships for Six Ketolide Antibiotics

Six structurally related 3-keto-substituted macrolide antibiotics (ketolides) were compared for concentration-dependent inhibitory effects on growth rate, viable cell number, and protein synthesis rates in Staphylococcus aureus cells. Inhibitory effects on 50S ribosomal subunit formation were also examined, as this is a second target for these antibiotics. A concentration range of 0.01 to 0.1 microg/ml was tested. An IC50 for inhibition of translation and 50S synthesis was measured for each compound, to relate structural features to inhibitory activity. ABT-773 was the most effective of the six compounds tested with an IC50 = 0.035 microg/ml. HMR 3004 was almost as effective with an IC50 = 0.05 microg/ml. Two 2-fluoroketolides (HMR 3562 and HMR 3787) were equivalent in their inhibitory activity with an IC50 = 0.06 microg/ml. Telithromycin (HMR 3647) had an IC50 = 0.08 microg/ml, and HMR 3832 was least effective with an IC50 = 0.11 microg/ml. Each antibiotic had an equivalent inhibitory effect on translation and 50S subunit formation. These results indicate specific structural features of these antimicrobial agents, which contribute to defined inhibitory activities against susceptible organisms.     

Multiple gene products and sequences required for excision of the mobilizable integrated Bacteroides element NBU1

NBU1 is an integrated 10.3-kbp Bacteroides element, which can excise and transfer to Bacteroides or Escherichia coli recipients, where it integrates into the recipient genome. NBU1 relies on large, >60-kbp, conjugative transposons for factors that trigger excision and for mobilization of the circular form to recipients. Previously, we showed that a single integrase gene, intN1, was necessary and sufficient for integration of NBU1 into its target site on the Bacteroides or E. coli genome. We now show that an unexpectedly large region of NBU1 is required for excision. This region includes, in addition to intN1, four open reading frames plus a large region downstream of the fourth gene, prmN1. This downstream sequence was designated XRS, for "excision-required sequence." XRS contains the oriT of the circular form of NBU1 and about two-thirds of the adjacent mobilization gene, mobN1. This is the first time an oriT, which is involved in conjugal transfer of the circular form, has been implicated in excision. Disruption of the gene immediately downstream of intN1, orf2, completely abolished excision. The next open reading frame, orf2x, was too small to be disrupted, so we still do not know whether it plays a role in the excision reaction. Deletions were made in each of two open reading frames downstream of orf2x, orf3 and prmN1. Both of these deletions abolished excision, indicating that these genes are also essential for excision. Attempts to complement various mutations in the excision region led us to realize that a portion of the excision region carrying prmN1 and part of the XRS (XRS(HIII)) inhibited excision when provided in trans on a multicopy plasmid (8 to 10 copies per cell). However, a fragment carrying prmN1, XRS, and the entire mobilization gene, mobN1, did not have this effect. The smaller fragment may be interfering with excision by attracting proteins made by the intact NBU1 and thus removing them from the excision complex. Our results show clearly that excision is a complex process that involves several proteins and a cis-acting region (XRS) which includes the oriT. We suggest that this complex excision machinery may be necessary to allow NBU1 to coordinate nicking at the ends during excision and nicking at the oriT during conjugal transfer, to prevent premature nicking at the oriT before NBU1 has excised and circularized.