Characteristics of Insertional Mutants of Pseudomonas syringae with Reduced Epiphytic Fitness

Random Tn5 mutagenesis was used to identify genes ir. Pseudomonas syringae which contribute to epiphytic fitness. Mutants were selected on the basis of deficiencies in epiphytic growth or survival on plants rather than deficiencies in predetermined phenotypes exhibited in culture. A sample freezing procedure was used to measure the population sizes of 5,300 mutants of P. syringae exposed to alternating wet and dry conditions on bean leaves in growth chambers. Eighty-two mutants exhibited reduced population sizes. Of these mutants, over half exhibited a reduced ability to survive the stresses associated with dry leaves, while others grew more slowly or attained reduced stationary-phase population sizes on leaves. While some epiphytic fitness mutants were altered in phenotypes that could be measured in culture, many mutants were not altered in any in vitro phenotype examined. Only three of the epiphytic fitness mutants were auxotrophs, and none had catabolic deficiencies for any of 31 organic compounds tested. Other mutants that exhibited reductions in one or more of the following were identified: motility, osmotolerance, desiccation tolerance, growth rate in batch culture, and extracellular polysaccharide production. All of the mutants retained the abilities to produce disease symptoms on the compatible host plant, bean, to incite a hypersensitive response on the non-host plant, tobacco, and to produce a fluorescent pyoverdine siderophore.     

Biological Control of Pseudomonas syringae pv. glycinea by Epiphytic Bacteria under Field Conditions

The efficacy of a bacterial strain as a biocontrol agent in the field may be related to the ecological similarity between the biocontrol agent and the target pathogen. Therefore, a number of different Pseudomonas syringae strains were evaluated for their antagonistic activities in vitro (agar-diffusion assay) and in planta (greenhouse assay) against the target pathogen, Pseudomonas syringae pv. glycinea. Six strains of five different pathovars were found to be antagonistic in vitro as well as in planta. The epiphytic fitness of the antagonistic Pseudomonas syringae strain 22d/93 and its two antibiotic-resistant mutants were examined on soybean plants in the fields. After adaptation the parental strain and its mutants had the ability to establish and maintain large epiphytic populations (about 10⁶ cfu/g FW) over the whole growing season after a single spray inoculation. The epiphytic behaviors of the mutants and the parent were not significantly different. The introduced bacteria did not influence the total bacterial population size. When the antagonist was coinoculated with the pathogen, the development of the pathogen was significantly reduced during the whole growing season. When the antagonistic strain was inoculated 4 weeks in advance of the pathogen, this antagonistic effect could be markedly enhanced. The final population size of the pathogen reached just 10⁴ cfu/g FW and was significantly reduced to 0.12% compared to the pathogen alone. This study demonstrates that biological control of foliar pathogens through colonization of the host plants with near isogenic or ecologically similar antagonistical strains seems to be a realistic goal.     

Survival, Growth, and Localization of Epiphytic Fitness Mutants of Pseudomonas syringae on Leaves

Among 82 epiphytic fitness mutants of a Pseudomonas syringae pv. syringae strain that were characterized in a previous study, 4 mutants were particularly intolerant of the stresses associated with dry leaf surfaces. These four mutants each exhibited distinctive behaviors when inoculated onto and into plant leaves. For example, while none showed measurable growth on dry potato leaf surfaces, they grew to different population sizes in the intercellular spaces of bean leaves and on dry bean leaf surfaces, and one mutant appeared incapable of growth in both environments although it grew well on moist bean leaves. The presence of the parental strain did not influence the survival of the mutants immediately following exposure of leaves to dry, high-light incubation conditions, suggesting that the reduced survival of the mutants did not result from an inability to produce extracellular factors in planta. On moist bean leaves that were colonized by either a mutant or the wild type, the proportion of the total epiphytic population that was located in sites protected from a surface sterilant was smaller for the mutants than for the wild type, indicating that the mutants were reduced in their ability to locate, multiply in, and/or survive in such protected sites. This reduced ability was only one of possibly several factors contributing to the reduced epiphytic fitness of each mutant. Their reduced fitness was not specific to the host plant bean, since they also exhibited reduced fitness on the nonhost plant potato; the functions altered in these strains are thus of interest for their contribution to the general fitness of bacterial epiphytes.     

Comparison of the Behavior of Epiphytic Fitness Mutants of Pseudomonas syringae under Controlled and Field Conditions

The epiphytic fitness of four Tn5 mutants of Pseudomonas syringae that exhibited reduced epiphytic fitness in the laboratory was evaluated under field conditions. The mutants differed more from the parental strain under field conditions than under laboratory conditions in their survival immediately following inoculation onto bean leaves and in the size of the epiphytic populations that they established, demonstrating that their fitness was reduced more under field conditions than in the laboratory. Under both conditions, the four mutants exhibited distinctive behaviors. One mutant exhibited particularly large population decreases and short half-lives following inoculation but grew epiphytically at near-wild-type rates, while the others exhibited reduced survival only in the warmest, driest conditions tested and grew epiphytically at reduced rates or, in the case of one mutant, not at all. The presence of the parental strain, B728a, did not influence the survival or growth of three of the mutants under field conditions; however, one mutant, an auxotroph, established larger populations in the presence of B728a than in its absence, possibly because of cross-feeding by B728a in planta. Experiments with B728a demonstrated that established epiphytic populations survived exposure of leaves to dry conditions better than newly inoculated cells did and that epiphytic survival was not dependent on the cell density in the inoculum. Three of the mutants behaved similarly to two nonpathogenic strains of P. syringae, suggesting that the mutants may be altered in traits that are missing or poorly expressed in naturally occurring nonpathogenic epiphytes.     

Neanderthal Extinction by Competitive Exclusion

Background

Despite a long history of investigation, considerable debate revolves around whether Neanderthals became extinct because of climate change or competition with anatomically modern humans (AMH).

Methodology/Principal Findings

We apply a new methodology integrating archaeological and chronological data with high-resolution paleoclimatic simulations to define eco-cultural niches associated with Neanderthal and AMH adaptive systems during alternating cold and mild phases of Marine Isotope Stage 3. Our results indicate that Neanderthals and AMH exploited similar niches, and may have continued to do so in the absence of contact.

Conclusions/Significance

The southerly contraction of Neanderthal range in southwestern Europe during Greenland Interstadial 8 was not due to climate change or a change in adaptation, but rather concurrent AMH geographic expansion appears to have produced competition that led to Neanderthal extinction.     

Epiphytic populations of Pseudomonas syringae on barley.

The epiphytic populations of Pseudomonas syringae were monitored on 23 barley entries planted in the field in four replications during the summer of 1986, and on six selected entries during the summer of 1987, from the second-leaf stage until senescence. Populations were initially low (0-3 log colony-forming units (cfu) per leaf) in all but one entry; they generally increased throughout the season, and at the end they reached 3-7 log cfu/leaf. Significant differences among the average epiphytic populations were found in the 1986 trial; only one entry, however, had a significantly different average population in the 1987 trial. The slopes of population increase were also compared: significant differences were observed in 1986 but not in 1987. In addition to epiphytic population counts, the percentage of ice nucleation active bacteria was determined in the population isolated from each leaf sample, and averaged throughout the season for each entry. Significant differences were observed in 1986 and in 1987. When the entries were ranked according to their average epiphytic population and compared between the two experiments, they were found to be very similar. The same was not true for the other parameters studied in the experiment.     

Flagellar Motility Confers Epiphytic Fitness Advantages upon Pseudomonas syringae

The role of flagellar motility in determining the epiphytic fitness of an ice-nucleation-active strain of Pseudomonas syringae was examined. The loss of flagellar motility reduced the epiphytic fitness of a normally motile P. syringae strain as measured by its growth, survival, and competitive ability on bean leaf surfaces. Equal population sizes of motile parental or nonmotile mutant P. syringae strains were maintained on bean plants for at least 5 days following the inoculation of fully expanded primary leaves. However, when bean seedlings were inoculated before the primary leaves had expanded and bacterial populations on these leaves were quantified at full expansion, the population size of the nonmotile derivative strain reached only 0.9% that of either the motile parental or revertant strain. When fully expanded bean primary leaves were coinoculated with equal numbers of motile and nonmotile cells, the population size of a nonmotile derivative strain was one-third of that of the motile parental or revertant strain after 8 days. Motile and nonmotile cells were exposed in vitro and on plants to UV radiation and desiccating conditions. The motile and nonmotile strains exhibited equal resistance to both stresses in vitro. However, the population size of a nonmotile strain on leaves was less than 20% that of a motile revertant strain when sampled immediately after UV irradiation. Epiphytic populations of both motile and nonmotile P. syringae declined under desiccating conditions on plants, and after 8 days, the population size of a nonmotile strain was less than one-third that of the motile parental or revertant strain.     

Antagonistic Activities of Epiphytic Bacteria from Soybean Leaves against Pseudomonas syringae pv. glycinea in vitro and in planta

Abstract Over two growing seasons, 273 bacterial strains were isolated from soybean leaves without and with bacterial blight symptoms caused by Pseudomonas syringae pv. glycinea (Psg). The majority of the isolates from leaves with symptoms were identified as Psg (43%), followed by Erwinia herbicola (21%), and Enterobacter/Erwinia (19%). The isolates from leaves without symptoms included mainly a group of unidentified Gram-negative bacteria (22%), Psg (21%), and E. herbicola (18%). Psg colonized the soybean leaves prior to saprophytic bacteria, and remained dominant during both seasons on healthy, as well as infected, leaves. Eighty-two saprophytic isolates were tested in vitro for their antagonistic activities against Psg, using an agar-diffusion assay. For the in planta assay, Psg and each isolate were simultaneously inoculated into wounds of pin-pricked leaves of greenhouse-grown soybean plants. Twenty-nine isolates were antagonistic in vitro. Nineteen isolates were able to suppress the growth of Psg and prevented the formation of leaf spots in planta when mixtures of isolate and pathogen were inoculated at ratios >1. Only 9 of the 82 isolates inhibited Psg in vitro as well as in planta. Most antagonists detected belonged to the genera Pseudomonas and the species Erwinia herbicola. The in planta assay should be a reliable predictor of field performance for screening of biological control agents. Received: 8 April 1996; Accepted: 22 October 1996     

Aerial Dispersal of Epiphytic Bacteria over Bean Plants

Plant canopies are strong sources of bacterial aerosols during sunny days when the leaves are dry. Bacterial concentration, upward flux, and deposition onto exposed petri plates were measured over snap beans during three growing seasons. A net upward flux of bacteria occurred only during the warm part of sunny days, not at night when leaves were wet with dew or when a thermal inversion was present. Aerosol source strength was positively correlated with wind speed. Upward fluxes were higher on days after rain than on days when the soil was dry. Other unidentified sources of variability in source strength probably exist. Canopy-level deposition, apparently due to intermediate-scale transport of bacteria in fairly concentrated clouds, can occur in the early evening.     

Toxicity of Smoke to Epiphytic Ice Nucleation-Active Bacteria

Wheat straw smoke aerosols and liquid smoke condensates reduced significantly both the viability and the ice-nucleating activity of Pseudomonas syringae pv. syringae and Erwinia herbicola in vitro and on leaf surfaces in vivo. Highly significant reductions in numbers of bacterial ice nuclei on the surface of both corn and almond were observed after exposure to smoke aerosols. At −5°C, frost injury to corn seedlings colonized by ice nucleation-active bacteria was reduced after exposure to smoke aerosols. Effects on −9°C ice nuclei, although significant, were less than on ice nuclei active at −5°C. These results suggest that smoke from wildfires or smudge pots may reduce plant frost susceptibility and sources of ice nuclei important in other natural processes under some conditions.     

Novel Method for Identifying Bacterial Mutants with Reduced Epiphytic Fitness

In order to identify novel traits involved in epiphytic colonization, a technique for the rapid identification of bacterial mutants with quantitatively different population sizes in a natural habitat based on measurements of ice nucleation activity was developed. The threshold freezing temperatures of leaves harboring different numbers of cells of ice nucleation-active Pseudomonas syringae B728a differed substantially. While few leaves containing less than about 10⁶ cells per g (fresh weight) froze at assay temperatures of -2.75°C or higher, nearly all leaves froze at these temperatures when population sizes of this strain increased to about 10⁷ cells per g (fresh weight). Presumptive epiphytic fitness mutants could readily be identified as strains which initiated freezing in fewer leaves than did other strains within a given experiment. Most Tn5-induced mutants of strain B728a which conferred a low frequency of ice nucleation on inoculated bean leaves generally had a smaller population size than the parental strain at the time of the leaf freezing assay. The leaf freezing assay was capable of differentiating samples which varied by approximately three- to fivefold in mean bacterial population size.     

l-Tryptophan Production by 5-Methyltryptophan-resistant Mutants of Glutamate-producing Bacteria

1. Some of 5-methyltrypotophan (5MT)-resistant mutants derived from glutamate-producing bacteria such as Brevibacterium flavum, Corynebacterium acetoglutamicum and Micrococcus glutamicus produced a small amount of l-tryptophan, while tyrosine and phenylalanine auxotrophs of B. flavum did not.

2. 5-MT-resistant mutant derived from the auxotroph for tyrosine and phenylalanine produced 390 mg/liter of l-tryptophan at most. A mutant resistant to a higher concentration of 5MT, which was derived from a tyrosine and phenylalanine auxotrophic mutant which was resistant to a low concentration of 5MT, produced 660 mg/liter of l-tryptophan. Using this mutant, the effects of the concentrations of components of the culture medium on the l-tryptophan production were examined. The high concentration of l-tyrosine, but not l-phenylalanine, inhibited the l-tryptophan production. Using the improved culture medium, this strain produced 1.9 g/liter of l-tryptophan.     

Chemotaxis of Pseudomonas syringae subsp. savastanoi Virulence Mutants

Several mutants of Pseudomonas syringae subsp. savastanoi were tested for their ability to sense and respond to a chemotactic gradient in low concentrations of yeast extract. The mutants were deficient in one or both of the genes coding for the synthesis of the plant hormones indole-3-acetic acid (IAA) and isopentenyl adenosine. Mutations which resulted in the loss of IAA production were due to the loss of the entire plasmid containing the iaa operon or to an 18-kb deletion of the iaa region. Additional mutants tested were deficient in their ability to produce isopentenyl adenosine as a result of the loss of the ptz-bearing plasmid. In all cases, strains which had lost the ability to produce IAA exhibited enhanced motility of up to 2.5 times that of the wild type (IAA⁺) in medium containing 0.01% yeast extract. No differences in motility were observed on medium containing lower concentrations of yeast extract. The presence or absence of the cytokinin plasmid and the presence or absence of inorganic nitrogen in the medium had no effect on the relative mobility of the strains.     

Altered Epiphytic Colonization of Mannityl Opine-Producing Transgenic Tobacco Plants by a Mannityl Opine-Catabolizing Strain of Pseudomonas syringae

The plasmid pYDH208, which confers the ability to catabolize the mannityl opines mannopine and agropine, was mobilized into the nonpathogenic Pseudomonas syringae strain Cit7. The growth of the mannityl opine-catabolizing strain Cit7(pYDH208) was compared with that of the near-isogenic non-opine-catabolizing strain Cit7xylE on leaves of wild-type tobacco (Nicotiana tabacum cv. Xanthi) and transgenic mannityl opine-producing tobacco plants (N. tabacum cv. Xanthi, line 2-26). The population size of Cit7(pYDH208) was significantly greater on the lower leaves of transgenic plants than on middle or upper leaves of those plants. The population size of Cit7(pYDH208) on lower leaves of transgenic plants was also significantly greater than the population size of Cit7xylE on similar leaves of wild-type plants. High-voltage paper electrophoresis demonstrated higher levels of mannityl opines in washings from lower- and mid-level leaves than in washings from upper-level leaves. The ability of Cit7(pYDH208) to catabolize mannityl opines in the carbon-limited phyllosphere increased the carrying capacity of the lower leaves of transgenic plants for Cit7(pYDH208). In coinoculations, the increase in the ratio of population sizes of Cit7(pYDH208) to Cit7xylE on transgenic plants was apparently due to a subtle difference in the growth rates of the two strains and to the difference in final population sizes. An ability to utilize additional carbon sources on the transgenic plants also enabled Cit7(pYDH208) to achieve a higher degree of coexistence with Cit7xylE on transgenic plants than on wild-type plants. This supports the hypothesis that the level of coexistence between epiphytic bacterial populations can be altered through nutritional resource partitioning.     

竞争排斥益生菌研究进展

竞争排斥益生菌(competitive exclusion product, CE)是1973年由Nurmi和Rantala提出的用于预防和控制刚出壳鸡沙门氏菌感染的复合益生菌产品,后来渐渐扩展到用于其他肠道病原菌的防控。除了控制病原菌定殖外,CE产品也可以促进生长、提高饲料转化率和降低死亡率等。现欧美等国家也开发出20多种CE产品用于养禽和养猪业。关于竞争排斥益生菌的作用机制尚不清楚,但已经提出了一些假说,如竞争粘附位点或营养、刺激局部免疫反应和产生各种各样的抗菌物质等。由于细菌的抗菌素抗性日益严重,CE产品的应用前景将非常广阔。     

Invasion and Exclusion among Coexisting Pseudomonas syringae Strains on Leaves

The invasion and exclusion abilities of coexisting Pseudomonas syringae strains were quantified on leaves. Twenty-nine P. syringae strains were inoculated onto plants in 107 pairwise combinations. All pairs were duplicated so that each strain was inoculated both first as an antagonist strain (day 0) and second as a challenge strain (day 3). The population size of each strain in a mixture was quantified on day 6 following incubation under moist conditions. For P. syringae strains, the presence of an established population often significantly reduced the growth of subsequently arriving challenge strains on the leaf surface. Invasion and exclusion abilities, quantified by contrasting population sizes of challenge strains in the presence and in the absence of another strain, varied significantly among P. syringae strains and were partly a function of the particular strain pair. The population size of a strain when present alone on a leaf was not predictive of invasion or exclusion ability. Successful invaders were significantly less likely to exclude challenge populations than were nonsuccessful invaders. Population sizes of successful excluders were negatively correlated with population sizes of coexisting challenge strains, while population sizes of successful invaders were positively correlated with those of coexisting antagonist strains. The patterns of interaction among coexisting strains suggest mechanisms for successful invasion and exclusion among P. syringae strains on leaves.     

Interaction of Epiphytic Bacteria and Activated Carbon on Root Growth

The influence of activated carbon and aseptic conditions has been studied on the growth of the primary root of wheat seedlings in order to ascertain whether or not the growth effect of activated carbon is connected with the occurrence of epiphytic bacteria. Growth was measured as mitotic activity, rate of cell elongation and duration of cell elongation. The surface infection of the septic roots probably consisted of common airborn and waterborn bacteria. Aseptic conditions increased the rate of cell elongation by ca 70 % but had no effect on the meristem activity. Activated carbon increased mitoses in the meristem and slightly augmented the duration of cell elongation but had no effect on the rate of elongation. The effects of sepsis and carbon were independent and appeared additative. Activated carbon removed inhibitors produced by the root tip itself but not those formed by the bacteria. In these experiments neither group of inhibitors seemed to contain IAA-like substances.     

Pathways of IAA Production from Tryptophan by Plants and by Their Epiphytic Bacteria: A Comparison

Metabolites of tryptophan were investigated using 2 systems: a bacterial (Peastem homogenates containing the epiphytic bacteria) and a plant system (pea stem sections under sterile conditions). The plant system produces: indolepyruvic acid (IPyA), indoleacetaldehyde (IAAld) indoleacetic acid (IAA), indoleethanol (tryptophol, IAAol), indolecarboxylie acid (ICA), indolecarboxaldehyde (ICAld). Bacteria produce additionally: indoleactic acid (ILA), tryptamine (TNH₂) and the unknown Xb and Yb, but IAAld was not detected. A nonacidic inhibitor extract from pea stems decreases the gain of IAA, IPyA, ILA, Yb. It increases the gain of IAAld, IAAol, TNH₂, Xb, and (only in the bacterial system) ICA and ICAld. Three sites of inhibitor action are suggested, namely the steps Try → IPyA, TNH₂→ IAAld, IAAld → IAA.