<i>In Vivo</i> Nitrogenase Regulation by Ammonium and Methylamine and the Effect of MSX on Ammonium Transport in <i>Anabaena flos-aquae</i>

Turpin, David H.; Edie, Scott A.; Canvin, David T.

doi:10.1104/pp.74.3.701

Cited by 54 publications

(36 citation statements)

References 11 publications

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“…This contrasts with the report of a direct inhibition of NH4+ transport system by MSX in Anabaenaflos-aquae (12). It has recently been pointed out (3) that methylammonium is metabolized to methylglutamine in cyanobacteria.…”

contrasting

confidence: 52%

Transport and Assimilation of Nitrogen by Stichococcus bacillaris Grown in the Presence of Methionine Sulfoximine

Ahmad¹,

Hellebust²

1985

Plant Physiol.

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Stichococcus bacillaris Naeg., a green soil alga, can grow in the presence of methionine sulfoximine (MSX) Recently, using MSX2 as a specific inhibitor of GS, we have demonstrated the ability of Chlorella autotrophica to maintain a normal rate ofNH44 assimilation via the NADPH-GDH pathway (1,2). This contrasts with the report of a direct inhibition of NH4+ transport system by MSX in Anabaenaflos-aquae (12). It has recently been pointed out (3) that methylammonium is metabolized to methylglutamine in cyanobacteria. Therefore, the observed inhibition of methylammonium uptake appears to be attributable to MSX inhibition of methylammonium assimilation via GS. The metabolism of methylammonium in cyanobacteria and bacteria (7) raises serious questions about its usefulness as an analog for NH4+ transport in prokaryotes. Eukaryotic microalgae do not appear to be able to metabolize methylammonium (13,14). We have recently studied the transport of nitrogenous compounds by the green alga Stichococcus bacillaris. As this alga contains NADPH-GDH with sufficiently high affinity for ammonium (6), it provides a useful system to investigate the effect of MSX on the transport of inorganic nitrogen without the undesirable effects of a buildup of an internal NH4+ pool. MATERIAIS AND METHODSOrganism and Culture Conditions. Stichococcus bacillaris (UTEX No. 314) was grown axenically as described (5). The culture nitrogen source was either 2 mM NaNO3 or 2 mM NH4CI. Preparation of MSX-containing media was as described (1, 2).Enzyme Activities. Preparation of cell-free extracts and determination of synthetase activities of GS and amination reactions of NAD(P)H-GDH were as described (1, 2).

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confidence: 52%

Transport and Assimilation of Nitrogen by Stichococcus bacillaris Grown in the Presence of Methionine Sulfoximine

Ahmad¹,

Hellebust²

1985

Plant Physiol.

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“…This increase in N content in the grain with inoculation without N was markedly higher than in the treatments that received additional N, probably due to higher N uptake after anthesis (Table 4). Such increment was above 66%, representing about 8.4 kg ha -1 of N. This effect was not observed in the treatments receiving N fertilizer, which could be attributed to the inhibitory effect of N compounds on the nitrogenase activity of the bacterium (Turpin et al, 1984). In this regard, Zimmer et al (1988) com-mented that the growth of the bacterium with nitrite or nitrate suppresses the biosynthesis of nitrogenase, since the cells synthetize nitrite reductase and nitrate reductase instead of using their limited energy in the nitrogenase reaction.…”

Section: Fig 2 Effect Of Wheat (T Aestivum L Cv Br 23) Inoculatmentioning

confidence: 84%

Nitrogen translocation in wheat inoculated with Azospirillum and fertilized with nitrogen

Rodrigues

Didonet

Gouveia

et al. 2000

Pesq. agropec. bras.

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-The productivity and the translocation of assimilates and nitrogen (N) were compared after inoculation of wheat (Triticum aestivum L., cv. BR-23) seeds with two strains of Azospirillum brasilense (strains 245 and JA 04) under field conditions. The inoculation of wheat seeds was done with a peat inoculant at sowing time. Plant material for evaluations were collected at anthesis and maturity. No differences in grain yield and in the translocation of assimilates resulting from inoculation were detected. Differences were observed in relation to N rates (0, 15, and 60 kg ha -1 ). N content in the grain increased significantly in the bacteria-inoculated treatments in which N was not added. This increase in N content in the grain with inoculation was probably due to higher N uptake after anthesis without any significant contribution on the grain yield. Such increment was of 8.4 kg ha -1 of N representing 66% more N than in no inoculated treatment. Regardless of the inoculation and the rate of N applied, it was observed that about 70% of the N accumulated at anthesis was translocated from vegetative parts to the grain.Index terms: Triticum aestivum, nitrogen fertilization, nitrogen metabolism, assimilation, nitrogen fixing bacteria. TRANSLOCAÇÃO DE NITROGÊNIO EM TRIGO INFECTADO POR AZOSPIRILLUME ADUBADO COM NITROGÊNIO RESUMO -Com o objetivo de verificar o efeito da inoculação na produtividade, na translocação de assimilados e de N, durante o desenvolvimento da planta de trigo (Triticum aestivum L. cv. BR-23), foi realizado este estudo em condições de campo, com duas estirpes de Azospirillum brasilense (245 e JA 04). A inoculação foi efetuada no momento da semeadura, com inoculante turfoso. As coletas dos materiais para as avaliações foram efetuadas na antese e na maturação. Não foi detectado efeito da inoculação na produção de grãos e na translocação de assimilados. Diferenças foram observadas em relação às doses de N (0, 15 e 60 kg ha -1 ). O teor de N no grão aumentou significativamente nos tratamentos com bactérias, sem adição de N. Esse aumento foi provavelmente decorrente da maior absorção de N após a antese, sem reflexo significativo no rendimento de grãos. Tal aumento no N absorvido após a antese foi superior em 66% ao tratamento sem inoculação, representando um incremento de cerca de 8,4 kg ha -1 . Independentemente da inoculação e da dose de N estudadas, observou-se que aproximadamente 70% do N acumulado na antese foi translocado das partes vegetativas para o grão.Termos para indexação: Triticum aestivum, adubação nitrogenada, metabolismo do nitrogênio, assimilação, bactéria fixadora de nitrogênio.

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“…The initial rapid phase may relate to the transport mechanism itself, while the second slower phase may relate to the metabolic transformation of MA to g-methylglutamine by glutamine synthetase (GS). In studies with cyanobacteria (Boussiba et al 1984;Turpin et al 1984;Kerby et al 1986), the second phase can be eliminated with the GS inhibitor methionine sulfoximine (MSX). In other studies that have demonstrated the biphasic nature of MA uptake in the dinoflagellate Gonyaulux (Balch 1986) and the diatom Phaeodactylum (Wright and Syrett 1983), the second phase was not related to the metabolism of MA.…”

Section: Discussionmentioning

confidence: 99%

“…Hackette et al 1970), free-living and symbiotic bacteria (Kleiner and Fitzke 198 1;Wiegel and Kleiner 1982), cyanobacteria (Turpin et al 1984), microalgae (Wheeler 1980), macroalgae (Wheeler 1979;MacFarlane and Smith 1982), lichens with algal endosymbionts (Tapper 1983), and angiosperms (Smith 1982). With few exceptions, [14C]MA has proved useful in understanding NH,+ transport, and generally the "affinity" of the transport system has been shown to be greater (i.e.…”

mentioning

confidence: 99%

Methylamine uptake by zooxanthellae‐invertebrate symbioses: Insights into host ammonium environment and nutrition

D’Elia

Cook²

1988

Limnology & Oceanography

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Cnidarians with endosymbiotic algae (=zooxanthellae) take up dissolved inorganic nutrients from seawater, but neither the physiological mechanisms nor the effect ofhost nutrition on transport kinetics is known. We used the NH,+ analogue [14C]methylamine ([14C]MA) to examine these aspects of NH,+ uptake by a sea anemone (Aiptasia pallida) and a coral (Madracis decactis).Both intact symbioses and isolated zooxanthellae took up [14C]MA. In anemones, uptake rates per algal cell increased with time after feeding. Uptake rates for isolates from hosts unfed for 7-10 d were linear for at least 200 min, slightly light-dependent, and conformed to Michaelis-Menten kinetics (K, = 68 PM; I', = 3.8 mol lo-l8 cell-' s-l). Isolates from well-fed hosts took up [14C]MA much less rapidly at all concentrations tested and did not exhibit saturable uptake kinetics. NH,+ competitively inhibited [14C]MA uptake by isolated algae (inhibition constant = 4.0 PM) and reduced [14C]MA uptake by intact symbiotic anemones. We hypothesize that [14C]MA (and by analogy NH,+) uptake occurs by a "depletion-diffusion" mechanism in intact symbiotic anemones with zooxanthellae maintaining very low intracellular [14C]MA and NH,+ concentrations in host tissue and that [14C]MA uptake kinetics will be useful in evaluating the nutritional status of corals and similar symbiotic associations under field conditions.

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In Vivo Nitrogenase Regulation by Ammonium and Methylamine and the Effect of MSX on Ammonium Transport in Anabaena flos-aquae

Cited by 54 publications

References 11 publications

Transport and Assimilation of Nitrogen by Stichococcus bacillaris Grown in the Presence of Methionine Sulfoximine

Transport and Assimilation of Nitrogen by Stichococcus bacillaris Grown in the Presence of Methionine Sulfoximine

Nitrogen translocation in wheat inoculated with Azospirillum and fertilized with nitrogen

Methylamine uptake by zooxanthellae‐invertebrate symbioses: Insights into host ammonium environment and nutrition

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