Reciprocal antibiotic collateral sensitivity in Burkholderia multivorans

Antibiotic collateral sensitivity (CS) occurs when a bacterium that acquires resistance to a treatment drug exhibits decreased resistance to a different drug. Here we identify reciprocal CS networks and candidate genes in Burkholderia multivorans. Burkholderia multivorans was evolved to become resistant to each of six antibiotics. The antibiogram of the evolved strain was compared with the immediate parental strain to determine CS and cross-resistance. The evolution process was continued for each resistant strain. CS interactions were observed in 170 of 279 evolved strains. CS patterns grouped into two clusters based on the treatment drug being a β-lactam antibiotic or not. Reciprocal pairs of CS antibiotics arose in ≥25% of all evolved strains. A total of 68 evolved strains were subjected to whole-genome sequencing and the resulting mutation patterns were correlated with antibiograms. Analysis revealed there was no single gene responsible for CS and that CS seen in B. multivorans is likely due to a combination of specific and non-specific mutations. The frequency of reciprocal CS, and the degree to which resistance changed, suggests a long-term treatment strategy; when resistance to one drug occurs, switch to use of the other member of the reciprocal pair. This switching could theoretically be continued indefinitely, allowing life-long treatment of chronic infections with just two antibiotics.

Burkholderia multivorans Exhibits Antibiotic Collateral Sensitivity

Burkholderia multivorans is a member of the Burkholderia cepacia complex whose members are inherently resistant to many antibiotics and can cause chronic lung infections in patients with cystic fibrosis. A possible treatment for chronic infections arises from the existence of collateral sensitivity (CS)-acquired resistance to a treatment antibiotic results in a decreased resistance to a nontreatment antibiotic. Determining CS patterns for bacteria involved in chronic infections may lead to sustainable treatment regimens that reduce development of multidrug-resistant bacterial strains. CS has been found to occur in Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus. Here, we report that B. multivorans exhibits antibiotic CS, as well as cross-resistance (CR), describe CS and CR networks for six antibiotics (ceftazidime, chloramphenicol, levofloxacin, meropenem, minocycline, and trimethoprim-sulfamethoxazole), and identify candidate genes involved in CS. Characterization of CS and CR patterns allows antibiotics to be separated into two clusters based on the treatment drug to which the evolved strain developed primary resistance, suggesting an antibiotic therapy strategy of switching between members of these two clusters.

The Relationship Between Agar Thickness and Antimicrobial Susceptibility Testing

Antimicrobial susceptibility testing can be done using solid or liquid-based medium. Solid-based assays are easy and inexpensive; they are limited by not being as quantitative as liquid-based assays. Agar depth can influence the accuracy of plate-based assays and it is assumed the basis of this effect is antimicrobial agent diffusion. We tested this assumption by using ETEST^® to quantitate the relationship between agar depth and minimum inhibitory concentration and zone of inhibition.

Examining changes in bacterial abundance in complex communities using next-generation sequencing is enhanced with quantitative PCR

Changes in the composition of microbial communities are often examined using high-throughput sequencing (HTS). Here we analyzed bar-coded Illumina sequencing data from a previous work describing the microbial community found in the sputum of a cystic fibrosis patient by itself or in combination with qPCR to measure the absolute abundance of Pseudomonas aeruginosa and Burkholderia multivorans. Through this comparison we were able to determine the computational analysis accuracy of sequencing data to measure the relative abundance of specific taxa. While no correlation was found between relative abundance and absolute abundance of P. aeruginosa or B. multivorans, we did find conclusions derived from HTS data alone differed from those derived from a combination of HTS and qPCR. Our results highlight the importance of using qPCR with HTS when characterizing organisms in microbial communities having a dominant taxon.

The use of open-ended problem-based learning scenarios in an interdisciplinary biotechnology class: evaluation of a problem-based learning course across three years

Use of open-ended Problem-Based Learning (PBL) in biology classrooms has been limited by the difficulty in designing problem scenarios such that the content learned in a course can be predicted and controlled, the lack of familiarity of this method of instruction by faculty, and the difficulty in assessment. Here we present the results of a study in which we developed a team-based interdisciplinary course that combined the fields of biology and civil engineering across three years. We used PBL scenarios as the only learning tool, wrote the problem scenarios, and developed the means to assess these courses and the results of that assessment. Our data indicates that PBL changed students' perception of their learning in content knowledge and promoted a change in students' learning styles. Although no statistically significant improvement in problem-solving skills and critical thinking skills was observed, students reported substantial changes in their problem-based learning strategies and critical thinking skills.

Strategy for extracting DNA from clay soil and detecting a specific target sequence via selective enrichment and real-time (quantitative) PCR amplification

We present a simple strategy for isolating and accurately enumerating target DNA from high-clay-content soils: desorption with buffers, an optional magnetic capture hybridization step, and quantitation via real-time PCR. With the developed technique, microg quantities of DNA were extracted from mg samples of pure kaolinite and a field clay soil.

Viable but nonculturable bacteria are present in mouse and human urine specimens

The presence of viable but nonculturable bacteria in human clean-catch and mouse bladder-isolated urine specimens was investigated. Viable but nonculturable bacteria are alive but do not give rise to visible growth under nonselective growth conditions. Urine specimens obtained from human female volunteers with or without an active urinary tract infection were found to contain, on average, significantly more viable than culturable forms of bacteria. Additional support for the presence of viable but nonculturable cells in urine specimens considered sterile was obtained from examination of urine specimens obtained directly from the bladder of healthy mice. Because the viability assay used to study the viable but nonculturable condition is by necessity growth independent, and hence indirect, the accuracy of this assay that scores cells with intact cell membranes as being viable was studied. Greater than 95% of Escherichia coli cells exposed to lethal doses of UV irradiation were found to lose their membrane integrity within a day, a time frame similar to that used to examine urine specimens. These data suggest that viable but nonculturable cells can occur within regions of the urinary tract previously considered sterile.

Concentrations of copper thought to be toxic to Escherichia coli can induce the viable but nonculturable condition

We have determined that concentrations of copper considered to be toxic can induce a fraction of a population of Escherichia coli to enter the viable but nonculturable (VBNC) condition. Copper-induced VBNC cells could be resuscitated for up to 2 weeks after entering the VBNC state.

The viable but nonculturable state of Ralstonia solanacearum may be involved in long-term survival and plant infection

The role of the dormant-like viable but nonculturable (VBNC) condition in the etiology of bacterial infection was examined using a plant system. The plant-pathogenic bacterium Ralstonia solanacearum was first shown to enter into the VBNC state both in response to cupric sulfate when in a saline solution and when placed in autoclaved soil. To determine if the VBNC condition is related to pathogenesis, the physiological status of bacteria recovered from different regions of inoculated tomato plants was determined at different stages of infection. The fraction of in planta bacteria that were VBNC increased during infection and became greater than 99% by the late stage of disease. The possibility that soil-dwelling VBNC bacteria may resuscitate and infect plants was also examined. When tomato seeds were germinated in sterile soil that contained VBNC but no detectable culturable forms of R. solanacearum cells, resuscitation was observed to occur in soil adjacent to plant roots; these resuscitated bacteria were able to infect plants. This is the first report of R. solanacearum entering the VBNC state and of resuscitation of any VBNC plant-pathogenic bacteria and provides evidence that the VBNC state may be involved in explaining the persistent nature of some infections.

Viable but nonculturable uropathogenic bacteria are present in the mouse urinary tract following urinary tract infection and antibiotic therapy

Involvement of the viable but nonculturable (VBNC) condition in recurrent urinary tract infections (UTIs) was investigated. VBNC bacteria are those which are alive but do not give rise to visible growth under nonselective growth conditions. Urine, bladder, and kidney samples collected over a 2-month period from BALB/c mice inoculated with the uropathogenic Escherichia coli strain J96 were examined to determine the level of culturable and viable bacteria. Urine from uninoculated mice was found to contain more viable than culturable bacteria. Inoculated mice had a transient increase in the level of culturable forms of the uropathogen in their urine, followed by a decrease to background levels; they also had multiple log higher levels of viable cells than culturable cells. The culturable pathogenic bacteria in mice that were inoculated and received antibiotic treatment dropped to undetectable levels within 1 week. At 2 out of 12 subsequent time points spanning an additional 65 days, culturable forms of the inoculated pathogenic bacteria were recovered. Polymerase chain reaction (PCR) analysis confirmed that DNA from the inoculated bacteria was present in a sample that yielded no culturable bacteria. These data indicate that the inoculated uropathogenic E. coli was not eliminated by antibiotic therapy, and suggest that these bacteria may escape detection by current standard culturability assays because they are VBNC.

Induction of the viable but non-culturable condition in Xanthomonas campestris pv. campestris in liquid microcosms and sterile soil

Xanthomonas campestris pathovar campestris was examined for the ability to enter the viable but non-culturable (VBNC) state. When nutrients were removed from a bacterial culture, the culturability dropped to undetectable levels within 6 weeks while the concentration of viable cells remained above 10(5) cells ml(-1). Addition of cupric sulfate facilitated this process. When bacteria were placed in autoclaved soil, culturability dropped by at least four logs within 5 days of the experiment while the concentration of viable cells remained at least two logs higher. These results indicate that the plant pathogen X. campestris can enter the VBNC condition in sterile soil and in liquid cultures and that cupric sulfate decreases the time for entry into the VBNC condition.

The viable-but-nonculturable condition is induced by copper in Agrobacterium tumefaciens and Rhizobium leguminosarum

Many bacteria respond to changes in environmental conditions by entering the viable-but-nonculturable state. We have determined that copper can induce nutrient-starved Agrobacterium tumefaciens and Rhizobium leguminosarum cells to become viable but nonculturable. This is the first report of a chemical inducer of this condition.

Association of single-stranded transferred DNA from Agrobacterium tumefaciens with tobacco cells

During the inception of crown gall tumorigenesis, the transferred DNA (T-DNA) is processed from the Ti (tumor inducing) plasmid of Agrobacterium tumefaciens and is transferred to plant cells. T-DNA processing and transfer require the induction of vir (virulence) genes by phenolic compounds secreted by wounded plant cells. After vir gene induction, both single-stranded (T-strands) and double-stranded forms of processed T-DNA accumulate in the bacteria. Although current models favor the transfer of T-strands to plants, there has yet been no experimental evidence to show this. In this paper, we show that T-strands disappear from acetosyringone-induced A. tumefaciens within 30 min of bacterial cocultivation with tobacco protoplasts. PCR analysis of T-DNA associated with protoplasts indicates that single-stranded, but not double-stranded, T-DNA can be detected in the plant cells within 30 min of bacterial cocultivation. Control experiments show that this T-DNA does not originate from lysed contaminating bacterial cells. T-DNA transfer depends on a functional bacterial virB operon. Protoplast infections using an A. tumefaciens virE mutant result in a low level of accumulation of T-strands in the plant cells.

Topoisomerase mutations affect the relative abundance of many Escherichia coli proteins

The relative abundance of 88 proteins was measured in extracts from three strains of Escherichia coli K-12 that are isogenic except for the topA and gyrB genes. Mutations in these genes slightly raise or lower, respectively, steady-state DNA supercoiling levels but have little effect on growth rate. Altered protein abundances were observed in the mutant strains relative to wild type. Many proteins exhibited minimum abundance at wild-type supercoiling levels, and other proteins exhibited maximal abundance at relaxed levels. A smaller number showed maximal abundance at elevated levels of supercoiling. These data suggest that small, non-lethal changes in DNA supercoiling can have widespread effects on patterns of gene expression.

VirD2 gene product from the nopaline plasmid pTiC58 has at least two activities required for virulence

Virulence genes virD1 and virD2 are required for T-DNA processing in Agrobacterium tumefaciens. The regions within virD2 contributing to T-DNA processing and virulence were investigated. Some insertional mutations in virD2 prevented T-DNA border endonucleolytic cleavage and produced an avirulent phenotype. However, a non-polar insertion immediately after bp 684 of the 1344 bp open reading frame of virD2 did not inhibit endonucleolytic cleavage but still caused a loss of virulence. This suggested that in addition to T-DNA border cleaving activity, the VirD2 protein has another virulence function which resides in the C-terminal half of the protein. Comparative nucleotide sequence analyses of virD2 showed that the first 684 bp were 81% homologous to virD2 of an octopine Ti plasmid whereas the remaining 660 bp were only 44% homologous. A plasmid containing the virD region from octopine Ti plasmid could restore both virulence and processing to a nopaline virD2 mutant. No complementation resulted when a nopaline virD2 clone containing a region similar to eukaryotic nuclear envelope transport sequences was deleted from the 3' end. These results suggest that virD1 and only the first half of virD2 are required to encode for the T-DNA processing endonuclease, and that the 3'-half of virD2 encodes a function separate from endonuclease activity that is required for virulence.

Virulence genes promote conjugative transfer of the Ti plasmid between Agrobacterium strains

Certain virulence region operons of the Agrobacterium tumefaciens Ti plasmid promoted conjugative Ti plasmid transfer. Mutations in the vir region of pTiC58 inhibited conjugative plasmid transfer between A. tumefaciens strains. Mutations in virA, virG, 5' virB, and virE had the greatest effect on plasmid transfer, and mutations in virC had no effect. Transfer inhibition in vir mutants occurred in the presence or absence of acetosyringone.

Molecular characterization of the vir regulon of Agrobacterium tumefaciens: complete nucleotide sequence and gene organization of the 28.63-kbp regulon cloned as a single unit

The entire vir regulon of Agrobacterium tumefaciens was subcloned and the complete 28.6-kbp nucleotide sequence was determined. The regulon was cloned as a single unit into two replicons, one of which replicates at a high copy number in this bacterium, and a second which has broad-host-range features to replicate in other Gram-negative bacteria. These vir region plasmids are able to confer in trans the processing and transfer activities on a second plasmid containing the T-DNA. In the high copy number vir region plasmid pUCD2614, a moderate increase in basal vir gene expression was observed as judged by virE::cat fusion expression assays relative to the wild-type control plasmid. Furthermore, higher efficiencies of tobacco leaf disk transformation were observed than with the widely used vir helper plasmid pAL4404. The nucleotide sequence studies showed that the vir region consists of 28,631 bp comprising 24 open reading frames which encode proteins involved in tumorigenicity. Two open reading frames not previously characterized, virH and ORF5, were uncovered within the virD/virE intervening spacer region. Together these studies more completely characterize the structure and function of the vir regulon.

High levels of double-stranded transferred DNA (T-DNA) processing from an intact nopaline Ti plasmid

To obtain bacterial-mediated oncogenic transformation of plants, the transferred DNA (T-DNA) of the tumor-inducing (Ti) plasmid of Agrobacterium tumefaciens is transferred to its plant host cells during infection. The initial phases of transformation involve the processing of the T-DNA in the bacterial cell after induction of the vir genes located on the Ti plasmid. The kinetics and conditions of this processing were examined and upon induction with acetosyringone up to 40% of the left and right borders of the T-DNA were cleaved. This cleavage was dependent upon virA, virG, and VirD and was rec-independent. Processed T-DNA was observed within 30 min after induction and was delayed by an increased concentration of phosphate in the induction medium. When DNA was isolated in the absence of protease treatment, the DNA fragment corresponding to the left side of the cut at both the left and right border region exhibited gel retardation, suggesting one or more "pilot" proteins may be involved in T-DNA transfer. Although the relative abundance of a processed product does not necessarily imply relative importance, the preponderance of double-stranded cleavage products suggests that double-stranded T-DNA should be considered as a possible intermediate in T-DNA transfer.

Functional organization of the plasmid pT181 replication origin

Replication of the staphylococcal plasmid pT181 is initiated at the origin (ori) with the introduction of a site-specific nick by the plasmid-encoded initiator protein RepC. Deletion analysis showed that a sequence of about 70 base-pairs is required for full ori function, including the ability to compete with a co-resident wild-type origin for the trans-acting RepC protein. A shorter sequence of 43 base-pairs is sufficient for origin function in the absence of competition. Single and double point mutations within these 43 base-pairs were used to determine the sequence requirement for replication within the minimal origin. Deletion mutants and point mutants were tested in replication and competition assays in vivo and in vitro, and in a RepC-mediated nicking assay.

Rifampin and rpoB mutations can alter DNA supercoiling in Escherichia coli

Two cases are described which indicate that RNA polymerase could alter DNA supercoiling. One occurred in a topA mutant in which abnormally high levels of plasmid supercoiling were lowered by rifampin, an inhibitor of the beta subunit of RNA polymerase. The second case involves suppression of a temperature-sensitive gyrB mutation by a rifampin-resistant allele of rpoB, the gene encoding the beta subunit of RNA polymerase. Measurements of chromosomal DNA supercoiling show that the rpoB mutation reduced DNA relaxation.

DNA supercoiling in gyrase mutants

Nucleoids isolated from Escherichia coli strains carrying temperature-sensitive gyrA or gyrB mutations were examined by sedimentation in ethidium bromide-containing sucrose density gradients. A shift to restrictive temperature resulted in nucleoid DNA relaxation in all of the mutant strains. Three of these mutants exhibited reversible nucleoid relaxation: when cultures incubated at restrictive temperature were cooled to 0 degree C over a 4- to 5-min period, supercoiling returned to levels observed with cells grown at permissive temperature. Incubation of these three mutants at restrictive temperature also caused nucleoid sedimentation rates to increase by about 50%.

Bacterial chromosome segregation: evidence for DNA gyrase involvement in decatenation

Nucleoids isolated from a temperature-sensitive gyrB mutant of E. coli, incubated at restrictive temperatures, exhibit increased sedimentation rates and an abnormal doublet or dumbbell-shaped morphology. Shifting cells from restrictive to permissive temperature prior to nucleoid isolation leads to decreases in the percentage of doublet nucleoids and in nucleoid sedimentation rates. When nucleoids isolated from mutant cells exposed to restrictive temperature are incubated with purified gyrase, the percentage of doublet nucleoids decreases as the total number of nucleoids increases. These results, together with the demonstrated ability of gyrase to decatenate small circular DNA molecules in vitro, suggest that gyrase participates in bacterial chromosome segregation through its decatenating activity.