Chloramphenicol resistance in Pseudomonas aeruginosa

Irvin, Jean E.

January 1983

The characteristics and expression of laboratory derived chloramphenicol (CM) resistance in P. aeruginosa were examined. Resistant strains exhibiting single cell resistance of 1.5 to 2 mg/mL were readily isolated following one passage in CM at 150 to 1000 (mu)g/mL. Isogenic strains, selected on CM at 150 and 500 (mu)g/mL were chosen for detailed study. Resistance was not a consequence of drug detoxification or altered sensitivity of the target site. The resistant strains exhibited unusual phenotypic properties including pronounced variations in growth rate, CM susceptibility and cell morphology as a function of the composition of the growth medium. Growth in CM also resulted in significant alterations in amino acid transport and respiratory capacity, the extent of which varied with the strain, the growth medium and the concentration of CM. These drug and medium-dependent alterations were determined to reside in an increased and highly specific requirement for Ca('2+), Mg('2+), Mn('2+) or Sr('2+). Manipulation of the divalent cation concentration of a variety of growth media resulted in dramatic alterations in growth rate, resistance and amino acid transport. Ca('2+) was significantly more effective than the latter three ions. The expression of native and plasmid-mediated CM resistance was also modified by the external concentration of divalent cations. In view of the nature and specificity of the cation requirement, it was concluded that (1) divalent cation-mediated alterations of outer membrane permeability are fundamental to the expression of native and acquired CM resistance in P. aeruginosa; (2) laboratory-derived CM resistance involves envelope changes, such that interaction with divalent cations promotes more effective exclusion of CM. The latter conclusion is supported by other divalent cation-dependent alterations in envelope function in the resistant strains.

Pseudomonas aeruginosa.

Chloramphenicol.

Drug resistance in microorganisms.

Effects of chloramphenicol on Pseudomonas aeruginosa

Léger, Jean-François

January 1991

The characteristics of the effects of chloramphenicol on Pseudomonas aeruginosa were examined. Resistant strains were easily isolated following a single passage in chloramphenicol at 150 $ mu$g/ml to 500 $ mu$g/ml. Drug detoxification or altered sensitivity of the target site could not be the mechanism of resistance. This resistance to chloramphenicol was correlated with the addition of an outer membrane protein with a molecular weight of 49 kDa and the loss of two outer membrane proteins, one with the molecular weight of 19 kDa and the other of about 10 kDa. The highly specific requirement of the resistant strains for Ca$ sp{2+}$, Mg$ sp{2+}$, Mn$ sp{2+}$ or Sr$ sp{2+}$ described by Irvin and Ingram (1982) was confirmed by the observation that the outer membrane of the resistant cells contained twice as much Mg$ sp{2+}$ cation as the sensitive cells. Many other experiments designed to observe the effects of chloramphenicol on the outer membrane of P. aeruginosa failed. It was concluded that the observations made in this study strongly suggested a "re-structuring" of the outer membrane of P. aeruginosa, rendering the resistant cells more impermeable to chloramphenicol.

Pseudomonas aeruginosa.

Chloramphenicol.

Drug resistance in microorganisms.

Regulatory Mechanisms Underlying Biological Control Activity of Pseudomonas chlororaphis PA23.

Selin, Carrie Lynn

January 2012

Biological control is an intriguing alternative to the use of chemical pesticides as it represents a safer, more environmentally friendly approach to managing plant pathogens. Pseudomonas chlororaphis strain PA23 was isolated from soybean root tips and it was found to be an excellent antagonist of sclerotinia stem rot. Our studies have shown that pyrrolnitrin (PRN) is the key metabolite required for S. sclerotiorum inhibition, while phenazine (PHZ) is important for biofilm establishment. For this reason, research efforts were directed towards elucidating the mechanisms governing PA23-mediated antibiotic production. To determine how these compounds were regulated, QS-deficient strains and an rpoS mutant were generated. The QS-deficient strains no longer inhibited the fungal pathogen S. sclerotiorum in vitro and exhibited reduced PRN, PHZ and protease production. Analysis of transcriptional fusions revealed that RpoS has a positive and negative effect on phzI and phzR, respectively. In a reciprocal manner, RpoS is positively regulated by QS. Characterization of a phzRrpoS double mutant showed reduced antifungal activity as well as PRN and PHZ production, similar to the QS-deficient strains. Furthermore, phzR but not rpoS was able to complement the phzRrpoS double mutant for the aforementioned traits, indicating that the Phz QS system is a central regulator of PA23-mediated antagonism. GacS/GacA, PsrA, RpoS and the PhzI/PhzR QS are members of a complex regulatory hierarchy that influence secondary metabolite production in PA23. An additional system, termed Rsm, was identified, adding yet another layer of complexity to the regulatory network. The Rsm system in PA23 appears to be comprised of a single small non-coding regulatory RNA termed RsmZ, and two RNA binding proteins RsmA and RsmE. We discovered that the expression of rsmZ, rsmA and rsmE all require GacA. In addition, both PsrA and QS were shown to positively regulate rsmZ transcription. For rsmE, GacA may indirectly regulate expression through PsrA, RpoS and QS, as all three regulators control rsmE transcription. Furthermore, we believe that the positive effects of PsrA and QS on rsmE transcription are likely mediated through RpoS as only RpoS show direct activation of rsmE in an E. coli background.

Biocontrol

Regulation

Pseudomonas chlororaphis

antibiotic production

Induction and production of specific extracellular lipases from selected microorganisms

Ngom, Marie Odile.

January 2000

Induction of extracellular lipases from Pseudomonas fragi CRDA 037 and Geotrichum candidum was used to increase lipase production in a shorter period of time. Induction was performed using edibles oils such as olive oil, canola oil, fish oil and butter fat. Fermentation trials of the microorganisms in the selected media were done in order to optimize the production of lipases. Optimal lipase activity was obtained in the presence of butter fat (1%, v/v) for P. fragi which was cultivated at 15°C during 48 h, and fish oil (0.75%, v/v) for G. candidum incubated at 27°C for 56 h. The induced lipase extracts of P. fragi and G. candidum obtained after these fermentation trials were purified by 3.7 and 5.9-fold respectively using ultrafiltration, while the non-induced fractions were purified by 2.3 and 5.1-fold, respectively. Activities were evaluated using p-nitrophenyl esters such as p-nitrophenyl laurate and p-nitrophenyl palmitate. (Abstract shortened by UMI.)

Lipase -- Separation.

Pseudomonas fragi.

Geotrichum candidum.

Characterizing Stress-Induced Outer Membrane Vesicle Production in Pseudomonas aeruginosa

MacDonald, Ian Alexander

January 2013

<p>As an opportunistic Gram-negative pathogen, Pseudomonas aeruginosa must be able to adapt to changes and survive stressors in its environment during the course of infection. To aid survival in the hostile host environment, P. aeruginosa has evolved a myriad of virulence factors including the production of an exopolysaccharide capsule, as well as secretion of degradative proteases and lipases that also function as defense mechanisms. Outer membrane vesicles (OMVs) acts as a secretion system to disseminate virulence factors and function as a general bacterial stress response to remove accumulated periplasmic waste. Despite the growing insights of the field into the potential functions of OMVs, the mechanism for formation remains to be fully elucidated. The three proposed mechanisms for OMV formation in P. aeruginosa are mediated by the Pseudomonas quinolone signal PQS, the AlgU envelope stress response pathway, and the periplasmic chaperone MucD. This report investigates how P. aeruginosa responds to sublethal physiological stressors with regards to OMV production levels and whether the proposed mechanisms for OMV formation are required for stress-induced OMV formation. We concluded that exposure to cell wall directed stressors increased OMV production and activity of the sigma factor that controls MucD expression, AlgU. AlgU was shown to be sufficient to induced OMV production upon overexpression; however, stress-induced OMV production was not dependent on activation of AlgU as vesiculation could be induced in strains lacking AlgU. Furthermore, MucD levels were not inversely proportional to OMV production under acute stress, and the ability to produce PQS was not required for OMV production. Finally, an investigation of the response of P. aeruginosa to oxidative stress revealed that hydrogen peroxide-induced OMV production requires the presence of B-band but not A-band lipopolysaccharide. We also demonstrated that the ability for P. aeruginosa to sense oxidative stress via OxyR, was important for hydrogen peroxide-induced OMV production, by a yet to be determined method. Together these results demonstrate that current proposed mechanisms for OMV formation do not universally apply under all stress conditions, and that additional mechanisms for OMV formation are still to be identified and fully elucidated during acute stress in P. aeruginosa.</p> / Dissertation

Microbiology

Biochemistry

OMV

OxyR

Pseudomonas aeruginosa

stress

Regulatory Mechanisms Underlying Biological Control Activity of Pseudomonas chlororaphis PA23.

Selin, Carrie Lynn

January 2012

Biological control is an intriguing alternative to the use of chemical pesticides as it represents a safer, more environmentally friendly approach to managing plant pathogens. Pseudomonas chlororaphis strain PA23 was isolated from soybean root tips and it was found to be an excellent antagonist of sclerotinia stem rot. Our studies have shown that pyrrolnitrin (PRN) is the key metabolite required for S. sclerotiorum inhibition, while phenazine (PHZ) is important for biofilm establishment. For this reason, research efforts were directed towards elucidating the mechanisms governing PA23-mediated antibiotic production. To determine how these compounds were regulated, QS-deficient strains and an rpoS mutant were generated. The QS-deficient strains no longer inhibited the fungal pathogen S. sclerotiorum in vitro and exhibited reduced PRN, PHZ and protease production. Analysis of transcriptional fusions revealed that RpoS has a positive and negative effect on phzI and phzR, respectively. In a reciprocal manner, RpoS is positively regulated by QS. Characterization of a phzRrpoS double mutant showed reduced antifungal activity as well as PRN and PHZ production, similar to the QS-deficient strains. Furthermore, phzR but not rpoS was able to complement the phzRrpoS double mutant for the aforementioned traits, indicating that the Phz QS system is a central regulator of PA23-mediated antagonism. GacS/GacA, PsrA, RpoS and the PhzI/PhzR QS are members of a complex regulatory hierarchy that influence secondary metabolite production in PA23. An additional system, termed Rsm, was identified, adding yet another layer of complexity to the regulatory network. The Rsm system in PA23 appears to be comprised of a single small non-coding regulatory RNA termed RsmZ, and two RNA binding proteins RsmA and RsmE. We discovered that the expression of rsmZ, rsmA and rsmE all require GacA. In addition, both PsrA and QS were shown to positively regulate rsmZ transcription. For rsmE, GacA may indirectly regulate expression through PsrA, RpoS and QS, as all three regulators control rsmE transcription. Furthermore, we believe that the positive effects of PsrA and QS on rsmE transcription are likely mediated through RpoS as only RpoS show direct activation of rsmE in an E. coli background.

Biocontrol

Regulation

Pseudomonas chlororaphis

antibiotic production

Molecular mechanisms involved in secondary metabolite production and biocontrol of Pseudomonas chlororaphis PA23

Poritsanos, Nicole Joanna

01 March 2006

ABSTRACT Sclerotinia sclerotiorum is a ubiquitous ascomycetous fungal pathogen that causes disease in over 400 crop species, specifically in soybean and canola plants, where stem rot is the most common disease symptom. Pseudomonas chlororaphis PA23 was previously isolated from the rhizosphere of soybean and has demonstrated excellent antifungal activity against S. sclerotiorum in vitro, greenhouse and field experiments. To elucidate the molecular mechanisms involved in PA23 biocontrol, random mutagenesis experiments were initiated. Several mutants were isolated that could be divided into three general classes. Biocontrol activity of various Pseudomonas spp. is highly regulated by a GacS/GacA two-component global regulatory system. Class I PA23 mutants harboured Tn5 insertions in the gacS-coding region, resulting in pleiotropic defects including deficiency in secondary metabolite production and biocontrol activity. Complementation with the wild type gacS allele in trans restored wild type phenotypes. These findings suggest that the ability of P. chlororaphis PA23 to suppress S. sclerotiorum causing stem rot in canola is dependent on a functional GacS/GacA global regulatory system. This is the first study assessing disease symptoms on canola (Brassica napus L.) plants inoculated with a gacS minus strain of P. chlororaphis. Phenazine compounds are considered to be a key secondary metabolite contributing to the antagonistic and antifungal activity of P. chlororaphis. In P. chlororaphis PA23, mutations in phenazine biosynthetic genes exhibited equal or more antifungal activity in vitro, compared to the wild type. To assess the effect of the deficiency in phenazine production, a Class II mutant , harbouring a Tn5 insertion in phzE was tested for a number of biocontrol traits including secondary metabolite production, motility, and suppression of Sclerotinia pathogenic traits. Since no other traits were markedly affected beyond phenazine production, it was concluded that phenazine is not the major product contributing to S. sclerotiorum biocontrol. A single Class III mutant was isolated harbouring a Tn5 insertion in a gene encoding a transcriptional regulator of the LysR family. This mutant exhibited no antifungal activity on plate assays and was unable to protect against S. sclerotiorum in green house assays. A number of secondary metabolites were no longer produced by this mutant, suggesting that this LysR-type transcriptional regulator is either directly or indirectly involved in controlling several genes in P. chlororaphis PA23.

Pseudomonas chlororaphis PA23

biofilm GacS LysR

Studies on the stability and activity of polymyxin B solutions

Saohin, Wipawee

January 1997

The correlation between the chemical stability and the microbiological activity of polymyxin B in phosphate buffer pH 6.0 and in proprietary eye drops was evaluated. High Performance Liquid Chromatography (HPLC) was used to quantify the amount of the main components in samples stored at 43,50,55 and 60°C for a period of 500 h. The data indicated that there are significant differences in chemical stability among the different proprietary eye drops. The accurate decomposition rate constants and shelf-lives (~o) at 4°C of two of the six formulated eye drops and the standard polymyxin B solution stored in glass containers at pH 6.0 were established. It was concluded that microbiological assay by agar diffusion was unsuitable for determining the activity of control polymyxin B in phosphate buffer and polymyxin B in eye drops. Killing time determinations for polymyxin B against cell suspensions of P. aeruginosa NCTC 6750 were consequently used. Thioglycollate broth containingp- aminobenzoic acid (PABA) 0.16 %w/v and magnesium sulphate 1 %w/v was used as an inactivating recovery medium. The effect of preservatives and of second antibacterials contained in the eye drops were tested individually and combined with polymyxin B. Thiomersal 0.001 %w/v, trimethoprim 0.02 %w/v and thiomersal 0.001 %w/v plus trimethoprim 0.02 %w/v did not have an effect on the activity of polymyxin B 2000 U/ml. Neomycin was an exception and at the concentrations in the range 0.0192 to 0.16 %w/v exhibited an antagonistic effect. Chemical interaction between polymyxin B and neomycin could not be detected and it was considered that the inhibitory effect of neomycin may be the result of competition between polymyxin B and neomycin for the same binding sites on the cell surface. Gentamicin is active against P. aeruginosa NCTC 6750 and at concentrations of 0.075 and 0.036 %w/v it exhibited an additive effect with polymyxin B 2000 U/ml against the test organism. The results obtained with the samples stored at 55°C for a period of 500 h demonstrated the critical effect of pH. At a pH of 6.0 microbiological activity and chemical stability appeared optimal. The chemical stability data of five eye drop samples correlated with microbiological activity data. Exceptions were polymyxin B in one eye drop sample and control polymyxin B. These extensively decomposed samples showed good antibacterial activity which appeared to result from the activity of decomposition products. Chemical stability data for standard polymyxin B solution at pH 6.0 also correlated to microbiological activity data over the temperature range of 92 - 115°C. The polymyxin B retained detectable microbiological activity when the amount of PB1 was greater than 20%. It is suggested that the decomposition products which occurred at these higher temperatures did not possess antibacterial activity.

615.1

Nitrogen fixation, hydrogen oxidation, and nickel utilization by Pseudomonas saccharophila

Barraquio, Wilfredo L.

January 1989

Pseudomonas saccharophila could fix N$ sb2$ under micro-aerobic conditions, heterotrophically and chemolithotrophically. Uptake hydrogenase activity under heterotrophic conditions had no effect on the O$ sb2$ sensitivity of nitrogenase. H$ sb2$ induced whereas sucrose and O$ sb2$ repressed hydrogenase synthesis. Sucrose and O$ sb2$ did not inhibit hydrogenase activity. Hydrogenase and urease were located in the membrane and soluble fractions, respectively. Nickel stimulated growth, hydrogenase expression, and nitrogenase activity under N-limited chemolithotrophic conditions. Hydrogenase synthesis specifically required nickel and its repression by O$ sb2$ was alleviated by increasing the nickel concentration. Incorporated $ sp{63}$Ni$ sp{2+}$ was about 3 times higher in the soluble than in the membrane fraction. The short-term uptake of nickel was energy-independent and had an apparent $K sb{m}$ of 31.7 uM and $V sb{max}$ of 3.8 nmol Ni$ sp{2+}$ (mg protein)$ sp{-1}$min$ sp{-1}$. / A counting method for heterotrophic and chemolithotrophic N$ sb2$-fixing H$ sb2$-oxidizing bacteria was developed. The white bean rhizosphere soil showed relatively high numbers of these bacteria.

Pseudomonas saccharophila.

Nitrogen -- Fixation.

Bacteria -- Physiology.

Nickel.

Analyses of Host Specificity, Immune Interactions and New Virulence Candidates of Pseudomonas syringae

Sanina, Natali

26 February 2009

We studied the host specificity, interactions with plant immune systems, and virulence factors of the phytopathogenic Type III secretion system-carrying bacterium Pseudomonas syringae. In studying host specificity, we ran growth and pod assays using seventeen pathovars of P. syringae on kidney bean hosts. We tracked bacterial growth numbers over six days and compared pathovar growth patterns. To study immune interactions with host plants, we performed effector-triggered immunity induction and suppression assays with individual effectors in Arabidopsis thaliana to determine whether effector evolutionary age was related to resultant plant immune responses. No correlations were observed. To generate candidate virulence effectors, we sequenced mRNA from seven P. syringae pathovars grown in inducing media and pulled out hits to virulence-related genes.

host specificity

Pseudomonas syringae

immune interactions

0369