Stress Sensors and Signal Transducers in Cyanobacteria

Los, Dmitry A.; Zorina, Anna; Sinetova, Maria A.; Kryazhov, S.; Mironov, Kirill S.; Зинченко, В.В.

doi:10.3390/s100302386

Cited by 116 publications

(92 citation statements)

References 126 publications

(158 reference statements)

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“…Moreover, transcripts of the alternative sigma factors sigB (sll0306), sigD (sll2012), and sigH (sll0856) were highly induced in D4, irrespective of Ci supply. These transcripts responded to general stress (Los et al, 2010), high-light and redox stress (Imamura et al, 2003), oxidative stress (Li et al, 2004), or heat stress (Huckauf et al, 2000;Tuominen et al, 2003;Singh et al, 2006). Additionally, the expression of slr1738, coding for a peroxide responsive regulator (PerR)/ferric uptake regulation protein (FUR)-type transcriptional regulator of oxidative stress (Li et al, 2004; Garcin et al, Table I.…”

Section: Resultsmentioning

confidence: 99%

Integrated analysis of engineered carbon limitation in a quadruple CO2/HCO3--uptake mutant of Synechocystis sp. PCC 6803

et al. 2015

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ORCID IDs: 0000-0002-7224-9134 (I.O.); 0000-0002-2517-4440 (M.F.); 0000-0001-9675-4883 (J.K.).Cyanobacteria have efficient carbon concentration mechanisms and suppress photorespiration in response to inorganic carbon (Ci) limitation. We studied intracellular Ci limitation in the slow-growing CO 2 /HCO 3 2 -uptake mutant DndhD3 (for NADH dehydrogenase subunit D3)/ndhD4 (for NADH dehydrogenase subunit D4)/cmpA (for bicarbonate transport system substratebinding protein A)/sbtA (for sodium-dependent bicarbonate transporter A): D4 mutant of Synechocystis sp. PCC 6803. When cultivated under high-CO 2 conditions, Δ4 phenocopies wild-type metabolic and transcriptomic acclimation responses after the shift from high to low CO 2 supply. The Δ4 phenocopy reveals multiple compensation mechanisms and differs from the preacclimation of the transcriptional Ci regulator mutant ΔndhR (for ndhF3 operon transcriptional regulator). Contrary to the carboxysomeless ΔccmM (for carbon dioxide concentrating mechanism protein M) mutant, the metabolic photorespiratory burst triggered by shifting to low CO 2 is not enhanced in Δ4. However, levels of the photorespiratory intermediates 2-phosphoglycolate and glycine are increased under high CO 2 . The number of carboxysomes is increased in Δ4 under high-CO 2 conditions and appears to be the major contributing factor for the avoidance of photorespiration under intracellular Ci limitation. The Δ4 phenocopy is associated with the deregulation of Ci control, an overreduced cellular state, and limited photooxidative stress. Our data suggest multiple layers of Ci regulation, including inversely regulated modules of antisense RNAs and cognate target messenger RNAs and specific trans-acting small RNAs, such as the posttranscriptional PHOTOSYNTHESIS REGULATORY RNA1 (PsrR1), which shows increased expression in Δ4 and is involved in repressing many photosynthesis genes at the posttranscriptional level. In conclusion, our insights extend the knowledge on the range of compensatory responses of Synechocystis sp. PCC 6803 to intracellular Ci limitation and may become a valuable reference for improving biofuel production in cyanobacteria, in which Ci is channeled off from central metabolism and may thus become a limiting factor.Cyanobacteria evolved more than 2.5 billion years ago and shaped the atmosphere by decreasing the CO 2 concentration while increasing the proportion of molecular oxygen. In marine environments, cyanobacteria are still important CO 2 sinks and contribute significantly to the global carbon cycle (Stuart, 2011) via net fixation of inorganic carbon (Ci). Cyanobacteria are the evolutionary ancestors of all eukaryotic plastids (Mereschkowski, 1905;Deusch et al., 2008;Ochoa de Alda et al., 2014) and serve as prokaryotic models in which to study photosynthesis and plant Ci fixation.Rubisco catalyzes the central reaction of photosynthetic Ci fixation, in which ribulose-1,5-bisphosphate reacts with CO 2 to produce two molecules of 3-phosphoglycerate (3PGA). High levels of atmospheric CO 2 in Ea...

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Section: Resultsmentioning

confidence: 99%

Integrated analysis of engineered carbon limitation in a quadruple CO2/HCO3--uptake mutant of Synechocystis sp. PCC 6803

et al. 2015

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“…Their genome has evolved in such a way that they can sense and respond to different environmental stimuli (Los et al, 2010). Due to their photoautotrophic nature, they have also developed an ability to fine-tune their photosynthetic machinery in response to ambient light quality.…”

Section: Discussionmentioning

confidence: 99%

“…The present study demonstrates that ROS levels are correlated with morphological changes during CCA in F. diplosiphon; however, how this signal is translated into morphological changes by regulating cytoskeletal proteins or components of the cytoskeleton to give final morphological changes is still unknown. Notably, cyanobacterial genomes possess several sensor kinases to sense oxidative stress (Los et al, 2010) and it will be interesting to determine whether morphological changes in F. diplosiphon during CCA involve a sensor kinase of oxidative stress that directly affects the integrity of the cytoskeletal proteins to give the spherical morphology under RL.…”

Section: Ros Ros Gl Rlmentioning

confidence: 99%

Reactive oxygen species are involved in the morphology-determining mechanism of Fremyella diplosiphon cells during complementary chromatic adaptation

Singh

Montgomery

2012

Microbiology

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Fremyella diplosiphon modifies the pigment composition of its major light-harvesting complexes, i.e. phycobilisomes, and cell and filament morphology according to ambient light quality in a process termed complementary chromatic adaptation (CCA). The cells are red in colour and rectangular shaped, and filaments are longer under green light (GL), in contrast with blue-green, spherical cells and shorter filaments under red light (RL). In this study, we report that wild-type (WT) UTEX 481 and WT-pigmented, shortened filament strain SF33 of F. diplosiphon accumulate reactive oxygen species (ROS) under both GL and RL, with the level of oxidative stress being higher under RL as compared with GL. During CCA, higher levels of ROS under RL are correlated with the RL-specific spherical cell shape and filament fragmentation -cells exhibiting elevated levels of ROS under RL have reduced cell length, yet the width of cells is not affected. Addition of ascorbic acid to RL-grown cultures resulted in lower ROS levels and a concomitant shift to GL-associated cellular morphology, i.e. an increased cell length. This observation identifies an RL-dependent oxidative-stress-mediated regulation of morphogenesis in a bacterial system. Spherical cell morphology may result from ROS-dependent changes in the cell membrane integrity or cell wall loosening and associated cell expansion.

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“…The two-component signal transduction systems, consisting of histidine kinases and the corresponding response regulators, was previously considered as the predominant phosphorylation based signal transduction mechanism in cyanobacteria [62]. However, recently, comprehensive functional analyses have revealed that Ser/Thr/Tyr kinases and phosphatases play vital roles in regulating many critical processes in cyanobacteria, such as stress adaptation, cell differentiation, cell motility, carbon and nitrogen metabolism and photosynthesis [63].…”

Section: Phosphoproteomementioning

confidence: 99%