Organization and Function of Chlorophyll in Membranes of Cyanobacteria during Iron Starvation

Guikema, James A.; Sherman, Louis A.

doi:10.1104/pp.73.2.250

Cited by 156 publications

(135 citation statements)

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“…However, Chl-a to C (biomass) ratio may change with time during the incubation because Chl-a quota is affected by Fe nutrition. Chl-a quota is lower under Fe-limited than that under Fe-replete conditions (Guikema and Sherman, 1983,Greene et al, 1992, Kudo et al, 2000, McKay et al, 1997, van Leeuwe and Stefels, 1998.…”

Section: Discussionmentioning

confidence: 96%

Phytoplankton community response to Fe and temperature gradients in the NE (SERIES) and NW (SEEDS) subarctic Pacific Ocean

Kudo

Noiri

Nishioka

et al. 2006

Deep Sea Research Part II: Topical Studies in Oceanography

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Ship-board iron enrichment bottle experiments were carried out with samples collected at the mesoscale iron fertilization experimental site (SERIES) in the subarctic NE Pacific in the summer of 2002. Samples were collected on Day 14 of the experiment outside the patch that was in a typical HNLC (high nitrate and low chlorophyll) condition. The iron concentration in the incubation bottles ranged from 0.1 to 2.0 nM by adding FeCl 3 solution. The increase in Chl-a in the micro (>10 µm) and nano-sized (2-10 µm) fraction was observed as a function of the added iron. Chl-a in the pico-sized fraction (0.7-2 µm) showed no increase with time. Nitrate and silicate were exhausted in the Fe-amended bottles, while those in the control bottle remained at the end of incubation. The relative consumption ratio of silicate to nitrate for the control bottles was significantly higher than that for the Fe-amended bottles. As a hyperbolic relation was found between iron concentration and the rate of increase in Chl-a (specific growth rate) for the micro and nano-sized fraction, the Monod equation was fit to obtain a maximum growth rate (µ max ) and a half-saturation constant for iron (K Fe ).

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Section: Discussionmentioning

confidence: 96%

Phytoplankton community response to Fe and temperature gradients in the NE (SERIES) and NW (SEEDS) subarctic Pacific Ocean

Kudo

Noiri

Nishioka

et al. 2006

Deep Sea Research Part II: Topical Studies in Oceanography

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“…Cells of A. nidulans R2 were obtained and grown in shaking culture as previously described (8). Optimal growth was obtained using BG-I I growth medium.…”

Section: Methodsmentioning

confidence: 99%

“…The thylakoid membranes of cyanobacteria show changes in response to iron deprivation (8,(17)(18)(19) 686 nm. These changes in the biophysical parameters spurred an examination of the Chi-protein arrangement of iron-deficient thylakoids.…”

Section: Introductionmentioning

confidence: 99%

“…When iron was restored to a deficient culture, a metabolic sequence was initiated within the first 12 h after the addition of iron which led to phenotypically normal cells. Pulse labeling with I35Sjsulfate during this period demonstrated that iron addition initiates a coordinated pattern of synthesis that leads to the assembly of normal membranes.The thylakoid membranes of cyanobacteria show changes in response to iron deprivation (8,(17)(18)(19) 686 nm. These changes in the biophysical parameters spurred an examination of the Chi-protein arrangement of iron-deficient thylakoids.…”

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confidence: 99%

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Influence of Iron Deprivation on the Membrane Composition of Anacystis nidulans

Guikema¹,

Sherman²

1984

Plant Physiol.

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Cultures of the cyanobacterium Anacystis nidulans were grown under iron-deficient conditions and then restored by the addition of iron. Membrane proteins from iron-deficient and iron-restored cells were analyzed by lithium dodecyl sulfate-polyacrylamide gradient gel electrophoresis.The incorporation of l3SIsulfate into membrane proteins and lactoperoxidase-catalyzed "5I iodination were used to monitor the rates of polypeptide biosynthesis and surface exposure of membrane proteins, respectively. These polypeptide profiles revealed major differences in the membrane composition of iron-deficient and normal cells. Iron deficiency caused a decrease in the amount of certain important membrane proteins, reflecting a decreased rate of biosynthesis of these peptides. Several photosystem II peptides also showed an increase in surface exposure after iron stress. In addition, iron deficiency led to the synthesis of proteins at 34 and 52 kilodaltons which were not present in normal cells. When iron was restored to a deficient culture, a metabolic sequence was initiated within the first 12 h after the addition of iron which led to phenotypically normal cells. Pulse labeling with I35Sjsulfate during this period demonstrated that iron addition initiates a coordinated pattern of synthesis that leads to the assembly of normal membranes.The thylakoid membranes of cyanobacteria show changes in response to iron deprivation (8,(17)(18)(19) 686 nm. These changes in the biophysical parameters spurred an examination of the Chi-protein arrangement of iron-deficient thylakoids. We observed a loss of the large mol wt Chl-protein complexes normally associated with these membranes (5, 7). Furthermore, we suggested that, by monitoring membrane synthesis following the readdition of iron, we would be able to detect peptides responsible for the altered membrane structure.We have analyzed polypeptide patterns by gel electrophoresis to document the alterations in thylakoid protein composition caused by iron deficiency in A. nidulans. Certain peptides are accumulated in the membrane fraction upon iron stress, while others are lost. Membranes from iron-stressed cells show a different topology, as monitored by the lactoperoxidase-catalyzed iodination of surface-exposed tyrosines. In vivo incorporation of[35S]sulfate into protein was used as a monitor of peptide synthesis during both iron stress and the recovery from iron deficiency. Maximum changes in photosynthetic parameters occurred during the first 7 to 13 h following the addition of iron to a deficient culture. These changes lead to the addition of membrane proteins which are important for normal photosynthetic membrane structure. MATERIALS AND METHODSCells of A. nidulans R2 were obtained and grown in shaking culture as previously described (8). Optimal growth was obtained using BG-I I growth medium. Iron-deficient media was prepared by replacing ferric ammonium citrate with equal molar amounts of ammonium citrate in this medium. Glassware was rinsed thoroughly with glass-distilled H20 p...

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“…At the same time, the up-regulation of "homologous recombination" might result in an increase of DNA mismatch repair and recombination [39]. Detailed analysis of genes with the same change trends (up-or downregulated) in both PMM and PMT under iron depletion condition suggested the mechanism that cyanobacteria employ to iron deficiency could be: firstly transporters were activated to obtain more iron from the environment [25], and photosynthesis and chlorophyll metabolism was inhibited due to the limited supply of iron [40][41][42], and then oxidative stress was enhanced and may cause RNA degradation, protein translation inhibition and other cellular metabolic changes. All these further resulted in inhibition of DNA replication and cell cycle block, and eventually growth cease.…”

Section: Construction Of Cyanobacteria Metal Response Networkmentioning

confidence: 99%

Cross‐species Transcriptional Network Analysis Reveals Conservation and Variation in Response to Metal Stress in Cyanobacteria

Wang

Chen

et al. 2016

Stress and Environmental Regulation of Gene Expression and Adaptation in Bacteria

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Background: As one of the most dominant bacterial groups on Earth, cyanobacteria play a pivotal role in the global carbon cycling and the Earth atmosphere composition. Understanding their molecular responses to environmental perturbations has important scientific and environmental values. Since important biological processes or networks are often evolutionarily conserved, the cross-species transcriptional network analysis offers a useful strategy to decipher conserved and species-specific transcriptional mechanisms that cells utilize to deal with various biotic and abiotic disturbances, and it will eventually lead to a better understanding of associated adaptation and regulatory networks.

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Organization and Function of Chlorophyll in Membranes of Cyanobacteria during Iron Starvation

Cited by 156 publications

References 19 publications

Phytoplankton community response to Fe and temperature gradients in the NE (SERIES) and NW (SEEDS) subarctic Pacific Ocean

Phytoplankton community response to Fe and temperature gradients in the NE (SERIES) and NW (SEEDS) subarctic Pacific Ocean

Influence of Iron Deprivation on the Membrane Composition of Anacystis nidulans

Cross‐species Transcriptional Network Analysis Reveals Conservation and Variation in Response to Metal Stress in Cyanobacteria

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