Physiological and Genetic Characterization of a Diazotrophic Pseudomonad

Chan, Yiu-Kwok; Wheatcroft, Roger; Watson, Robert J.

doi:10.1099/00221287-132-8-2277

Cited by 2 publications

(10 citation statements)

References 39 publications

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“…These include simple sugars, polysaccharides, organic acids, polyols, amino acids, hydrocarbons and aromatic compounds. They are expected, and in some cases shown, to support nitrogenase activity [38,39,46,48,63,92,116] as well as saprophytic competitiveness. Interestingly, the well-studied aromatic degradation pathways of pseudomonads also exist in N2-fixing azotobacters [117,118] which are phylogenetically closely related to the authentic Pseudomonas species [14].…”

Section: Limiting Factorsmentioning

confidence: 89%

“…Because of the heterogeneity of the non-fluorescent P. stutzeri species [23], the stability of its nomenclature may still be doubted by the taxonomic purist. Pseudomonas species strain 4B (Table 2) was originally identified as similar to P. delafieldii based on biochemical tests [39]. Its taxonomic status, however, remains elusive based on DNA-rRNA hybridisation data (J.…”

Section: Putative Nz-fixing Pseudomonadsmentioning

confidence: 99%

“…They may also be synergistically active in degrading recalcitrant substances. An example of the pseudomonads with such capabilities is Pseudomonas species 4B which was isolated by enrichment with benzoate [39,63]. It was found to have high N 2 fixation activity in co-culture with a cellulolytic bacterium, Cellulomonas sp.…”

Section: General Ecologymentioning

confidence: 99%

“…According to Palleroni [7], pseudomonads lack N2-fixing ability. The ability of the pseudomonads to fix atmospheric N 2 has not been appreciated [7,66,67] usually because of the following problems [39]: (a) mistaken or uncertain identification of the diazotroph; (b) lack of rigorous tests for diazotrophy in pseudomonads; and (c) multigeneric nature of the genus Pseudomonas as discussed above. Early attempts to find an N2-fixing pseudomonad were unsuccessful, due to the failure to recognise the 02 sensitivity or microaerobic character of its N2-fixing system.…”

Section: Diazotrophymentioning

confidence: 99%

“…Hence, Southern hybridisation [91], in which the Mo-nitrogenase structural genes nifHDK (usually obtained from the well-studied diazotroph Klebsiella pneumoniae M5AI, eqv. K. oxytoca) are used to probe an organism's genomic DNA, has been employed as a test for diazotrophy [39,90,[92][93][94][95][96][97]. Strictly, such probing is a test complementary to activity assay for indicating the genetic similarity between nitrogenases from different species.…”

Section: Determinative Testsmentioning

confidence: 99%

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N₂-fixing pseudomonads and related soil bacteria

Chan

Barraquio

Knowles

1994

FEMS Microbiology Reviews

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Pseudomonas-like organisms form a highly heterogeneous and ubiquitous group of bacteria. Recent identification of an authentic P~eudomonas genus should help to decrease difficulties which arose from taxonomic uncertainties. Further difficulties in recognising N2-fixing Pseudomonas species lie in the confirmation of diazotrophy. Optimised conditions are often needed for the detection of nitrogenase activity since it is controlled by specific environmental factors and physiological requirements. However, genetically constructed N2-fixing strains from authentic Pseudomonas species have demonstrated that at least some members of the genus possess mechanisms to accommodate and express nil (N z fixation) genes from a well-studied diazotroph, Klebsiella pneumoniae. Renowned for their catabolic versatility, pseudomonads can use a wide range of carbon and energy substrates. Hence, potential N2-fixing pseudomonads are conceivably less limited by carbon and energy sources available in the environment compared to other N2-fixing organisms. Pseudomonas species dominate in the rhizosphere of some plants from which isolates have been shown to be diazotrophic. Several strains are also chemolithotrophs, capable of using H 2 as energy and electron source and CO2 as carbon source. Besides assays for N2-fixing activity, DNA hybridisation to the well conserved molybdo-nitrogenase structural gene probe is an indicator of diazotrophy. However, absence of hybridisation to this probe, despite N 2 fixation activity, has been reported. Although the genetics of N 2 fixation in pseudomonads have hardly been studied, some nif genes have been shown to be plasmid-borne. Pseudomonas species are also predominant soil denitrifiers, reducing nitrate and nitrite to gaseous forms of nitrogen during anaerobic respiration. Hence, they play an important role in the global biological nitrogen cycle. Several diazotrophic species including a few pseudomonads can also denitrify. The potential contribution by Ne-fixing pseudomonads to the sinks and sources of soil nitrogen is considered small in the short term but essentially remains unclear in the absence of experimental data. Reliable rapid methods for their specific enumeration are indispensable for assessing their population dynamics and ascertaining their ecological significance. NUM347(a mbds.nrc.ca. distributed within any one genus, diazotrophic strains commonly exist in the genera of both archaeobacteria (eqv. archaebacteria [1]) and eubacteria. Free-living diazotrophs excluding photosynthetic bacteria and cyanobacteria are mostly heterotrophs with aerobic, microaerobic or anaerobic respiration when fixing N 2. Because of the high energy demand for N 2 fixation, free-liv-SSDI 01 68-6445(93)E0092-X

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Section: Limiting Factorsmentioning

confidence: 89%

Section: Putative Nz-fixing Pseudomonadsmentioning

confidence: 99%

Section: General Ecologymentioning

confidence: 99%

Section: Diazotrophymentioning

confidence: 99%

Section: Determinative Testsmentioning

confidence: 99%

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N₂-fixing pseudomonads and related soil bacteria

Chan

Barraquio

Knowles

1994

FEMS Microbiology Reviews

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Distribution of Insertion Sequence ISRm1 in Rhizobium meliloti and Other Gram-negative Bacteria

Wheatcroft¹,

Watson²

1988

Microbiology

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An internal 0.9 kb segment of Rhizobium meliloti insertion sequence ISRm1 was used as a probe to determine the distribution of ISRm1 in strains of R. meliloti and other Gram-negative bacteria. The insertion sequence was detected in 80% (12/15) of R. meliloti strains from different parts of the world. Its copy number ranged from one to at least eleven. The ISRm1 copies detected showed variation in their internal restriction sites and their degree of homology to the probe. ISRm1 was found in a variety of genomic restriction fragments, and was detected in plasmids, including the nod and exo megaplasmids of R. meliloti. Other rhizobia found to contain ISRm1 were a strain of R. leguminosarum biovar phaseoli and two Rhizobium isolates capable of nodulating both Medicago sativa and Phaseolus vulgaris. It was also found in a diazotrophic soil bacterium isolated from the roots of wetland rice.

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Physiological and Genetic Characterization of a Diazotrophic Pseudomonad

Cited by 2 publications

References 39 publications

N₂-fixing pseudomonads and related soil bacteria

N₂-fixing pseudomonads and related soil bacteria

Distribution of Insertion Sequence ISRm1 in Rhizobium meliloti and Other Gram-negative Bacteria

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Physiological and Genetic Characterization of a Diazotrophic Pseudomonad

Cited by 2 publications

References 39 publications

N2-fixing pseudomonads and related soil bacteria

N2-fixing pseudomonads and related soil bacteria

Distribution of Insertion Sequence ISRm1 in Rhizobium meliloti and Other Gram-negative Bacteria

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N₂-fixing pseudomonads and related soil bacteria

N₂-fixing pseudomonads and related soil bacteria