Abolition of Swarming of Proteus by p-Nitrophenyl Glycerin: Application to Blood Agar Media

Comparative plate counts were made of Staphylococcus aureus and Streptococcus pyogenes growing on blood agar supplemented with individual chemicals to abolish the swarming of Proteus. B-phenylethanol, sodium azide, and p-nitrophenyl glycerin (PNPG) were used as anti-swarm agents. Each anti-swarm agent effectively abolished swarming for 24 h, but azide failed to control swarming for longer periods of incubation. In addition, azide displayed growth inhibition towards the staphylococci and streptococci resulting in no hemolysis and reduced viable cell numbers with the streptococci. Phenylethanol showed reduced viable cell numbers with the streptococci and unreliable hemolytic reactions. At 0.1 to 0.3 mM, PNPG proved to be a superior anti-swarm agent in that it showed no growth inhibition and allowed normal hemolysis, but abolished swarming for extended periods of time. When laboratory strains of Streptococcus pneumoniae, Klebsiella pneumoniae, Pseudomonas aeruginosa. Listeria monocytogenes, and Vibrio cholerae were screened on a blood agar medium containing 0.1 mm PNPG, they displayed similar growth and hemolytic characteristics to the identical medium without PNPG.     

Urease activity related to the growth and differentiation of swarmer cells of Proteus mirabilis

Urease activity was measured using whole cells of both long (swarming) and short (nonswarming) populations of Proteus mirabilis from casein hydrolysate agar (CHA) and broth (CHB) cultures, and from brain heart infusion broth (BHIB) cultures. Urease is a constitutive enzyme for both long and short cells, but its activity was tremendously increased when urea was incorporated into the media. Urease production was also affected by culture age and media used. Before exponential phase, urease activity was very low, and it increased to its highest point after about 4 h in BHIB and 8 h in both CHA and CHB cultures at 37 degrees C. Long cells had higher urease activity than did short cells when grown on CHA, and was also expressed by two different strains cultured in BHIB. Strain PM23, in BHIB, was able to form long cells (swarming cells) to a maximum proportion after about 4 h, but strain IM47 could not differentiate in any of the liquid media. The former had more urease when swarming differentiation was initiated. PM23 grew relatively faster than IM47 when the former began to differentiate, but this fast growth could not be observed when nutrient broth or minimal medium was used. These observations suggest that long or swarming cells are "faster growing" rather than "nongrowing bacteria".     

Inhibitory Effects of Secondary Metabolites from the Red Alga Delisea pulchra on Swarming Motility of Proteus mirabilis

Abnormal, uncoordinated swarming motility of the opportunistic human pathogen Proteus mirabilis was seen when a crude extract of the Australian red alga Delisea pulchra was added to the medium. This occurred at concentrations at which growth rate, swimming motility, cell elongation, polynucleation, and hyperflagellation were not affected. One halogenated furanone from D. pulchra inhibited swarming motility at concentrations that did not affect growth rate and swimming motility. Other structurally similar D. pulchra furanones had no effect on swarming, suggesting considerable specificity in the effects of furanones on swarming motility by P. mirabilis.     

Mode of Synergism between Colistin and Sulfisomezole in Inhibiting the Growth of Proteus Organism

When either colistin at 1,000 μg/ml or sulfisomezole at 125 μg/ml was used separately, growth of a strain of Proteus mirabilis was not inhibited. However, when 1 μg/ml of colistin and 25 μg/ml of sulfisomezole were used together in agar media, growth was inhibited. The synergistic action of colistin and sulfisomezole was also demonstrated in broth culture, when a smaller inoculum such as 10⁶ cells/ml was used. The lethal and lytic effect of this synergism parallels the characteristic effect of colistin towards colistin-sensitive gram-negative organisms. When the mode of this synergistic action was analyzed by adding each compound in sequence to a growing culture of Proteus, it was found that growth of organism for about 4 generations in the presence of sulfisomezole was a prerequisite for revealing the lethal and lytic effects of colistin. In cultures where these two compounds were present at the beginning of incubation, the synergistic effect was abolished by the addition of p-aminobenzoic acid (PABA) at an early stage of incubation, but not at a late stage. Methionine, serine, and betaine, when used together, had the same effect as PABA. An insufficiency of the three compounds induced by sulfisomezole, was considered to afford the receptor site of colistin to Proteus.     

嗜肺巴斯德杆菌选择性培养基研制及应用

目的　研制一种对嗜肺巴斯德杆菌表现出强选择作用的选择性培养基,用于该菌的常规检测。方法　药敏试验及抗生素最小抑菌浓度测定。结果　研制了嗜肺巴氏杆菌选择性培养基(PPSM培养基)及嗜肺巴斯德杆菌增菌液(PP肉汤)。嗜肺巴斯德杆菌在PPSM培养基上,37℃48h培养,形成1mm左右,凸起、湿润、灰黑色并有金属光泽的特殊菌落;对表皮葡萄球菌和大肠埃氏菌的抑制率为100%,对变形杆菌的抑制率为76%,并能抑制其迁徙生长;通过PP肉汤增菌培养,PPSM培养基使SPF小鼠粪便中嗜肺巴斯德杆菌检出率从0增至67.2%;用小鼠咽拭子接种该培养基,其初代培养物几乎为纯培养物。结论　该培养基对嗜肺巴氏杆菌具有较强的选择作用,使用该培养基对嗜肺巴氏杆菌进行检测可以简化检测程序、防止漏检、在不处死动物的情况下对嗜肺巴斯德杆菌进行常规监测。     

Inhibition of Swarming of Proteus by Sodium Tetradecyl Sulfate, beta-Phenethyl Alcohol, and p-Nitrophenylglycerine

The effects of sodium tetradecyl sulfate (STS), β-phenethyl alcohol (PEA), and p-nitrophenylglycerol (PNPG) on motility, swarming, flagellation, and growth of Proteus were examined. Growth-inhibitory concentrations (GIC) and swarming-inhibitory concentrations (SIC) were determined. A characterization of the swarming-inhibitory efficacy of these compounds was based on their GIC/SIC ratio and their concentration inhibition curves. Using the homologous series of sodium alkyl sulfates as a standard reference, we showed that PNPG was more effective than STS, which was the most effective of the homologous series. PEA was less effective than sodium decyl sulfate but more effective than sodium octyl sulfate. Motility tests in liquid medium and electron microscope investigations indicated that the modes of action of the three compounds, all of which effectively inhibit the swarming of Proteus, are different. Whereas STS and PEA inhibit swarming by inhibition of motility, PNPG seems to act on the swarming mechanism sensu strictori, without impairment of motility. STS immobilizes by inhibition of flagellum formation or by some lytic action on the flagella already synthesized. PEA acts by impairing flagellar function, but leaves the flagella morphologically intact.     

Evidence against the involvement of chemotaxis in swarming of Proteus mirabilis.

Nonswarming and nonchemotactic mutants of Proteus mirabilis were isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine or ultraviolet light. These mutants were used in experiments to determine if chemotaxis is involved in the swarming of P. mirabilis. Nonchemotactic mutants failed to form chemotactic bands in a semisolid casein hydrolysate medium, yet they swarmed on the same medium containing 1.5% agar. Nonswarming mutants were attracted towards individual amino acids and components of tryptose. In cross-feeding experiments, no evidence was obtained to indicate the production of a diffusable chemical repellent. In studies with the wild-type P. mirabilis, no clear-cut negative chemotaxis was seen even though three different assays were used and numerous chemicals were tested. Additional evidence against the involvement of chemotaxis in swarming comes from finding that dialysis does not interfere with swarming; swarm cells will swarm immediately when transferred to fresh media, and swarm cells will swarm on an agar-water medium supplemented with a surfactant. These data indicate that chemotaxis is not involved in the swarming of P. mirabilis.     

Inhibition of Swarming of Proteus by Sodium Tetradecyl Sulfate, β-Phenethyl Alcohol,and p-Nitrophenylglycerine

The effects of sodium tetradecyl sulfate (STS), β-phenethyl alcohol (PEA), and p-nitrophenylglycerol (PNPG) on motility, swarming, flagellation, and growth of Proteus were examined. Growth-inhibitory concentrations (GIC) and swarming-inhibitory concentrations (SIC) were determined. A characterization of the swarming-inhibitory efficacy of these compounds was based on their GIC/SIC ratio and their concentration inhibition curves. Using the homologous series of sodium alkyl sulfates as a standard reference, we showed that PNPG was more effective than STS, which was the most effective of the homologous series. PEA was less effective than sodium decyl sulfate but more effective than sodium octyl sulfate. Motility tests in liquid medium and electron microscope investigations indicated that the modes of action of the three compounds, all of which effectively inhibit the swarming of Proteus, are different. Whereas STS and PEA inhibit swarming by inhibition of motility, PNPG seems to act on the swarming mechanism sensu strictori, without impairment of motility. STS immobilizes by inhibition of flagellum formation or by some lytic action on the flagella already synthesized. PEA acts by impairing flagellar function, but leaves the flagella morphologically intact.     

Effects of some tricyclic psychopharmacons and structurally related compounds on motility of Proteus vulgaris.

A simple test for the evaluation of drugs interfering with bacterial motility was established with Proteus vulgaris. With this model, promethazine, 7-hydroxy-chlorpromazine, imipramine, 7,8-dioxochlorpromazine and acridine orange were shown to exert significant motility and swarming inhibitory action on Proteus vulgaris strains at subinhibitory concentrations. Quinidine enhanced the antimotility effect of promethazine. The antimotility effect of promethazine was synergized by proton pump inhibitors omeprazole and abscissic acid, but antagonized by extracellular potassium and sodium ions.     

Proteus virulence: involvement of the pore forming alpha-hemolysin (a short review)

The genus Proteus belongs to the tribe of Proteae in the family of Enterobacteriaceae, and consists of five species: P. mirabilis, P. vulgaris, P. morganii, P. penneri and P. myxofaciens. They are distinguished from the rest of Enterobacteriaceae by their ability to deaminate phenylalanine and tryptophane. They hydrolyze urea and gelatin and fail to ferment lactose, mannose, dulcitol and malonate; and do not form lysine and arginine decarboxylase or beta-galactosidase [1]. Colonies produce distinct "burned chocolate" odor and frequently show the characteristics of swarming motility on solid media. P. mirabilis, P. vulgaris and P. morganii are widely recognized human pathogens. They have been isolated from urinary tract infections, wounds, ear, and nosocomial bacteremic infections, often in immuncompromised patients [2-6]. P. myxofaciens has no clinical interest to this time. P. penneri as species nova was nominated by the recommendation of Hickman and co-workers [7]. Formerly it was recognized as P. vulgaris biogroup 1 or indole negative P. vulgaris [8, 9]. Although it has been less commonly isolated from clinical samples than the other three human pathogenic Proteus species, it has nevertheless been connected with infections of the urinary tract, wounds and has been isolated from the feces of both healthy and diarrheic individuals [10-12]. Potential virulence factors responsible for virulence of Proteae are: IgA protease, urease, type3 fimbriae associated with MR/K haemagglutinins of at least two antigenic types, endotoxin, swarming motility and HlyA and/or HpmA type hemolysins [for review see ref. 13]. In the followings we give a survey of accumulated concepts about the position and characteristics of HlyA type alpha-hemolysins both in general and with emphasis on virulence functions in the tribe of Proteae.     

Initiation of Swarming Motility by Proteus mirabilis Occurs in Response to Specific Cues Present in Urine and Requires Excess l-Glutamine

Proteus mirabilis, a leading cause of catheter-associated urinary tract infection (CaUTI), differentiates into swarm cells that migrate across catheter surfaces and medium solidified with 1.5% agar. While many genes and nutrient requirements involved in the swarming process have been identified, few studies have addressed the signals that promote initiation of swarming following initial contact with a surface. In this study, we show that P. mirabilis CaUTI isolates initiate swarming in response to specific nutrients and environmental cues. Thirty-three compounds, including amino acids, polyamines, fatty acids, and tricarboxylic acid (TCA) cycle intermediates, were tested for the ability to promote swarming when added to normally nonpermissive media. l-Arginine, l-glutamine, dl-histidine, malate, and dl-ornithine promoted swarming on several types of media without enhancing swimming motility or growth rate. Testing of isogenic mutants revealed that swarming in response to the cues required putrescine biosynthesis and pathways involved in amino acid metabolism. Furthermore, excess glutamine was found to be a strict requirement for swarming on normal swarm agar in addition to being a swarming cue under normally nonpermissive conditions. We thus conclude that initiation of swarming occurs in response to specific cues and that manipulating concentrations of key nutrient cues can signal whether or not a particular environment is permissive for swarming.     

L-asparaginase activity of Mycobacterium phlei under various growth conditions.

Seven Mycobacterium strains were grown statically on salts-glycerol-asparagine (Sauton) or on salts-glucose-glutamate (Sym) media. At desired time of incubation, the bacteria were washed with water, disintegrated with powdered corundum and in resulting cell-free extracts L-asparaginase activity was determined by the Conway method. The majority of experiments were performed on M. phlei which exhibited considerable rise in L-asparaginase activity with increasing age of the culture. This change did not occur on Sym medium because of Zn2+, which proved to abolish the effect of the enzyme induction in vivo but did not inhibit the activity in vitro. Addition of rifampicin to Sauton culture media resulted in a low enzyme level. Exogenous asparagine and glycerol were not indispensable for the enzyme synthesis and could be replaced by glutamate and glucose, respectively.     

Extension of a chromosome linkage group of Proteus mirabilis.

Mating procedures for detection of mobilization of the Proteus mirabilis chromosome were re-investigated. The chromosome was mobilized by plasmid D, the previously used hybrid between plasmids P-lac and R1drd19. About a 40-fold increase in recombinant recovery correlated with the absence of swarming during mating and a lower temperature of incubation. The modification introduced was that conjugation was allowed to proceed on a non-selective supplemented minimal medium at 30 degrees C before washing and plating on selective media. Final incubation was also at 30 degrees C. This technique enabled eight additional chromosomal markers to be mapped. Polarized transfer of the chromosome was shown by gradient of transmission experiments using a previously described marker as reference, by linkage analysis with reference to proximal and distal markers and (less successfully) by interrupted mating on solid medium. Markers of plasmid D transferred at high frequency to all recombinants. The plasmid was stable in recombinants and could transfer itself and chromosomal markers of the new hosts in further matings. Resulting recombination of markers occurred at usual frequencies. The marker order, his-1, ser-2, ura-2, pyrB1, trp-3, cysA1, ade-2, ilv-2, cysG1, gly-1, cysC1, argA2, metF2, nalA1, thr-1, leuB2, did not resemble the order of these markers in Escherichia coli.     

Effects of some tricyclic psychopharmacons and structurally related compounds on motility ofProteus vulgaris

A simple test for the evaluation of drugs interfering with bacterial motility was established withProteus vulgaris. With this model, promethazine, 7-hydroxy-chlorpromazine, imipramine, 7,8-dioxochlorpromazine and acridine orange were shown to exert significant motility and swarming inhibitory action onProteus vulgaris strains at subinhibitory concentrations. Quinidine enhanced the antimotility effect of promethazine. The antimotility effect of promethazine was synergized by proton pump inhibitors omeprazole and abscissic acid, but antagonized by extracellular potassium and sodium ions.     

Swarming characteristics of Proteus mirabilis under anaerobic and aerobic conditions

Nutrients have a pronounced effect on the growth and swarming behaviour of Proteus mirabilis 7002. Iron, zinc, amino acids, and dioxygen are important for rapid growth and normal swarming. Anaerobically grown cultures of P. mirabilis 7002 were unable to swarm on anaerobically maintained rich nutrient agar. Upon exposure to aerobic conditions, P. mirabilis 7002 resumed swarming behaviour. Scanning electron microscopy was used to demonstrate the presence of community organization and mature rafts during normal swarming. These results support the importance of dioxygen and redox status in cell differentiation.     

Effects of Related Anionic Detergents on Flagellation, Motility, Swarming, and Growth of Proteus

The effects of a series of sodium alkyl sulfates (C(4) to C(16)) on flagellation, motility, swarming, and growth of Proteus were examined. The concentrations of the various sodium alkyl sulfates completely inhibiting the swarming phenomenon (on solid medium) and motility (in liquid medium) were in the same order of magnitude. The inhibiting effect of the detergents examined increased from sodium hexyl sulfate (inhibitory concentration, 20 to 30 mmoles per liter) to sodium tetradecyl sulfate (inhibitory concentration, 0.1 to 0.5 mmoles per liter). Flagella were produced neither in liquid nor on solid medium at these concentrations as could be observed by electron microscopy. At concentrations where motility was not impaired, intact flagellation could be observed. At a concentration of 0.1 mmole per liter, sodium tetradecyl sulfate completely inhibited the motility of Proteus in the liquid medium employed without impairing growth.     

Regulatory characteristics of amino acid transport in newborn rat renal cortex cells.

The uptaken of alpha-aminoisobutyric acid by slices of kidney cortex from newborn rats is enhanced by a preliminary incubation of the tissue in buffer at 37 degrees C. This effect is abolished by anaerobiosis, the presence of dinitrophenol or the removal of Na+ during the preliminary incubation. Cycloheximide (50 muM) and purimycin (1 mM) as well as alpha-aminoisobutyric acid, glycine and proline (5 mM) in the preincubation buffer also abolish the effect, while actinomycin D (0.8 muM) partially the phenomenon indicates that the enhanced uptake is due to an increased entry rate into the cells without a change in effux. There is no alteration in the apparent transport Km but an increase in the V for entry. The effect is dependent on tissue age being observed between birth and 22 days, after which there is a decrease in response to preliminary incubation with no effect seen in adult tissues.     

Immunofluorescent evidence of Proteus mirabilis swarm cell formation on sterilized rat feces.

Swarming Proteus spp. were detected with the use of proteometry (a most-probable-number technique) in the fecal material of selected animal species and in raw sewage from a local sewage treatment plant. Proteus spp. were not detected in any of several soil and freshwater samples examined. Since rat feces harbored high numbers of Proteus mirabilis compared with other habitats examined, we chose to examine it for the possibility of supporting swarming. Immunofluorescent studies with a strain-specific conjugate revealed the morphogenesis of short forms into elongated swarm cells upon the surface of sterilized rat feces that had been inoculated with short forms of P. mirabilis. the same phenomenon was not observed consistently when nonsterile rat feces were inoculated and examined with immunofluorescence.     

Pseudomonas syringae coordinates production of a motility-enabling surfactant with flagellar assembly

Using a sensitive assay, we observed low levels of an unknown surfactant produced by Pseudomonas syringae pv. syringae B728a that was not detected by traditional methods yet enabled swarming motility in a strain that exhibited deficient production of syringafactin, the main characterized surfactant produced by P. syringae. Random mutagenesis of the syringafactin-deficient strain revealed an acyltransferase with homology to rhlA from Pseudomonas aeruginosa that was required for production of this unidentified surfactant, subsequently characterized by mass spectrometry as 3-(3-hydroxyalkanoyloxy) alkanoic acid (HAA). Analysis of other mutants with altered surfactant production revealed that HAA is coordinately regulated with the late-stage flagellar gene encoding flagellin; mutations in genes involved in early flagellar assembly abolish or reduce HAA production, while mutations in flagellin or flagellin glycosylation genes increase its production. When colonizing a hydrated porous surface, the bacterium increases production of both flagellin and HAA. P. syringae was defective in porous-paper colonization without functional flagella and was slightly inhibited in this movement when it lacked surfactant production. Loss of HAA production in a syringafactin-deficient strain had no effect on swimming but abolished swarming motility. In contrast, a strain that lacked HAA but retained syringafactin production exhibited broad swarming tendrils, while a syringafactin-producing strain that overproduced HAA exhibited slender swarming tendrils. On the basis of further analysis of mutants altered in HAA production, we discuss its regulation in Pseudomonas syringae.