@article{Dienst.200810,
  abstract = {The ssr3341 locus was previously suggested to encode an orthologue of the RNA chaperone Hfq in the cyanobacterium Synechocystis sp. strain PCC 6803. Insertional inactivation of this gene resulted in a mutant that was not naturally transformable and exhibited a non-phototactic phenotype compared with the wild-type. The loss of motility was complemented by reintroduction of the wild-type gene, correlated with the re-establishment of type IV pili on the cell surface. Microarray analyses revealed a small set of genes with drastically reduced transcript levels in the knockout mutant compared with the wild-type cells. Among the most strongly affected genes, slr1667, slr1668, slr2015, slr2016 and slr2018 stood out, as they belong to two operons that had previously been shown to be involved in motility, controlled by the cAMP receptor protein SYCRP1. This suggests a link between cAMP signalling, motility and possibly the involvement of RNA-based regulation. },
  added-at = {2008-10-28T11:38:56.000+0100},
  author = {Dienst, Dennis and Duehring, Ulf and Mollenkopf, Hans-Joachim and Vogel, Joerg and Golecki, Jochen and Hess, R. Wolfgang and Wilde, Annegret},
  biburl = {http://www.bibsonomy.org/bibtex/2360d6f6b7b103a12630fc529c0d5f681/microbio},
  interhash = {fb37688fd328815cfe4f5febeb7d43e9},
  intrahash = {360d6f6b7b103a12630fc529c0d5f681},
  issn = {1350-0872},
  journal = {Microbiology},
  keywords = {imported},
  number = {Pt 10},
  pages = {3134-3143},
  timestamp = {2008-10-28T11:38:56.000+0100},
  title = {The cyanobacterial homologue of the RNA chaperone Hfq is essential for motility of Synechocystis sp. PCC 6803},
  volume = 154,
  year = 2008
}

@article{legewie_small_2008,
  abstract = {Non-coding RNAs are crucial regulators of gene expression in prokaryotes and eukaryotes, but it remains poorly understood how they affect the dynamics of transcriptional networks. We analyzed the temporal characteristics of the cyanobacterial iron stress response by mathematical modeling and quantitative experimental analyses, and focused on the role of a recently discovered small non-coding RNA, IsrR. We found that IsrR is responsible for a pronounced delay in the accumulation of isiA mRNA encoding the late-phase stress protein, IsiA, and that it ensures a rapid decline in isiA levels once external stress triggers are removed. These kinetic properties allow the system to selectively respond to sustained (as opposed to transient) stimuli, and thus establish a temporal threshold, which prevents energetically costly IsiA accumulation under short-term stress conditions. Biological information is frequently encoded in the quantitative aspects of intracellular signals (e.g., amplitude and duration). Our simulations reveal that competitive inhibition and regulated degradation allow intracellular regulatory networks to efficiently discriminate between transient and sustained inputs.},
  added-at = {2008-08-08T13:57:07.000+0200},
  author = {Legewie, Stefan and Dienst, Dennis and Wilde, Annegret and Herzel, Hanspeter and Axmann, Ilka},
  biburl = {http://www.bibsonomy.org/bibtex/2ec9ffb6cc96212683ac242e000392152/microbio},
  doi = {biophysj.108.133819},
  interhash = {50428c90df6f23cbd833d707d57fa944},
  intrahash = {ec9ffb6cc96212683ac242e000392152},
  issn = {1542-0086},
  journal = {Biophysical Journal},
  keywords = {imported},
  month = {July},
  note = {PMID: 18599624},
  timestamp = {2008-08-08T13:57:07.000+0200},
  title = {Small RNAs Establish Delays and Temporal Thresholds in Gene Expression},
  url = {http://www.ncbi.nlm.nih.gov/pubmed/18599624},
  year = 2008
}

@article{sobotka_importance_2008,
  abstract = {Gun4 is a porphyrin binding protein that activates magnesium chelatase, a multimeric enzyme catalyzing the first committed step in chlorophyll biosynthesis. In plants, GUN4 has been implicated in plastid-to-nucleus retrograde signalling processes that coordinate both photosystem II and photosystem I nuclear gene expression with chloroplast function. In this work we present the functional analysis of Gun4 from the cyanobacterium Synechocystis sp. PCC 6803. Affinity co-purification of the FLAG-tagged Gun4 with the ChlH subunit of the magnesium chelatase confirmed the association of Gun4 with the enzyme in cyanobacteria. Inactivation of the gun4 gene abolished photoautotrophic growth of the resulting gun4 mutant strain that exhibited a decreased activity of magnesium chelatase. Consequently, the cellular content of chlorophyll-binding proteins was highly inadequate, especially that of proteins of photosystem II. Immunoblot analyses, blue native polyacrylamide gel electrophoresis and radiolabeling of the membrane protein complexes suggested that the availability of the photosystem II antenna protein CP47 is a limiting factor for the photosystem II assembly in the gun4 mutant.},
  added-at = {2008-08-08T13:57:07.000+0200},
  author = {Sobotka, Roman and Dühring, Ulf and Komenda, Josef and Peter, Enrico and Gardian, Zdenko and Tichy, Martin and Grimm, Bernhard and Wilde, Annegret},
  biburl = {http://www.bibsonomy.org/bibtex/261fcd468696964b95bbfbe6ad871ebac/microbio},
  doi = {M803787200},
  interhash = {2c0eb39e61b3920664edb902977ee1b3},
  intrahash = {61fcd468696964b95bbfbe6ad871ebac},
  issn = {0021-9258},
  journal = {The Journal of Biological Chemistry},
  keywords = {imported},
  month = {July},
  note = {PMID: 18625715},
  timestamp = {2008-08-08T13:57:07.000+0200},
  title = {Importance of the cyanobacterial Gun4 protein for chlorophyll metabolism and assembly of photosynthetic complexes},
  url = {http://www.ncbi.nlm.nih.gov/pubmed/18625715},
  year = 2008
}

@article{ISI:000237399900049,
  abstract = {Small regulatory noncoding RNAs exist in both eukaryotic and
prokaryotic organisms. Most of these RNA transcripts are transencoded
RNAs with short and only partial antisense complementarity to their
target RNAs, which regulate gene expression by modifying mRNA stability
and translation. In contrast, reports on the function of cis-encoded,
perfectly complementary antisense RNAs in eubacteria are rare.
Cyanobacteria respond to iron deficiency by expressing IsiA (iron
stress-induced protein A), which forms a giant ring structure around
photosystem I. Here, we show that this process is controlled by IsrR
(iron stress-repressed RNA), a cis-encoded antisense RNA transcribed
from the isiA noncoding strand. Artificial overexpression of IsrR under
iron stress causes a strongly diminished number of IsiA-photosystem I
supercomplexes, whereas IsrR depletion results in premature expression
of IsiA. The coupled degradation of IsrR/isiA mRNA duplexes appears to
be a reversible switch that can respond to environmental changes. IsrR
is the only RNA known so far to regulate a photosynthesis component.},
  added-at = {2008-08-08T13:46:10.000+0200},
  author = {Duehring, U. and Axmann, Im and Hess, W. R. and Wilde, A.},
  biburl = {http://www.bibsonomy.org/bibtex/2a7fcf4b35f040ba8951cd0f2fed64713/microbio},
  interhash = {d6780696764efdfdf2f16c3bf508999a},
  intrahash = {a7fcf4b35f040ba8951cd0f2fed64713},
  issn = {0027-8424},
  journal = {PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA},
  keywords = {cyanobacteria expression iron_stress light_harvesting redox_stress regulation_of_gene},
  number = 18,
  pages = {7054-7058},
  timestamp = {2008-08-08T13:46:10.000+0200},
  title = {An internal antisense RNA regulates expression of the photosynthesis gene isiA},
  volume = 103,
  year = 2006
}

@article{ISI:000245381300002,
  abstract = {Cyanobacteria are the simplest known cellular systems that regulate
their biological activities in daily cycles. For the cyanobacterium
Synechococcus elongatus, it has been shown by in vitro and in vivo
experiments that the basic circadian timing process is based on
rhythmic phosphorylation of KaiC hexamers. Despite the excellent
experimental work, a full systems level understanding of the in vitro
clock is still lacking. In this work, we provide a mathematical
approach to scan different hypothetical mechanisms for the primary
circadian oscillator, starting from experimentally established
molecular properties of the clock proteins. Although optimised for
highest performance, only one of the in silico-generated reaction
networks was able to reproduce the experimentally found high amplitude
and robustness against perturbations. In this reaction network, a
negative feedback synchronises the phosphorylation level of the
individual hexamers and has indeed been realised in S. elongatus by
KaiA sequestration as confirmed by experiments.},
  added-at = {2008-07-15T11:10:10.000+0200},
  author = {Clodong, Sebastien and Duehring, Ulf and Kronk, Luiza and Wilde, Annegret and Axmann, Ilka and Herzel, Hanspeter and Kollmann, Markus},
  biburl = {http://www.bibsonomy.org/bibtex/24416df445cea52104905722029172e49/microbio},
  interhash = {6767cb27f732e7cf313935084f19cea2},
  intrahash = {4416df445cea52104905722029172e49},
  issn = {1744-4292},
  journal = {MOLECULAR SYSTEMS BIOLOGY},
  keywords = {IFZ circadian_clock cyanobacteria networks robustness systems_biology},
  timestamp = {2008-07-15T11:10:10.000+0200},
  title = {Functioning and robustness of a bacterial circadian clock},
  volume = 3,
  year = 2007
}

@article{ISI:000245941500011,
  abstract = {The dynamics of photosystem I assembly in cyanobacteria have been
addressed using in vivo pulse-chase labeling of Synechocystis sp. PCC
6803 proteins in combination with blue native polyacrylamide gel
electrophoresis. The analyses indicate the existence of three different
monomeric photosystem I complexes and also the high stability of
photosystem I trimers. We show that in addition to a complete
photosystem I monomer, containing all 11 subunits, we detected a
PsaK-less monomer and a short-lived PsaL/PsaK-less complex. The latter
two monomers were missing in the ycf37 mutant of Synechocystis sp. PCC
6803 that accumulates also less trimers. Pulse-chase experiments
suggest that the three monomeric complexes have different functions in
the biogenesis of the trimer. Based on these findings we propose a
model where PsaK is incorporated in the latest step of photosystem I
assembly. The PsaK-less photosystem I monomer may represent an
intermediate complex that is important for the exchange of the two PsaK
variants during high light acclimation. Implications of the presented
data with respect to Ycf37 function are discussed.},
  added-at = {2008-07-15T11:10:10.000+0200},
  author = {Duehring, Ulf and Ossenbuehl, Friedrich and Wilde, Annegret},
  biburl = {http://www.bibsonomy.org/bibtex/23dcea2360c114b92e714eb362e66634e/microbio},
  interhash = {1b6bb212fe91fcabde245545a71a6509},
  intrahash = {3dcea2360c114b92e714eb362e66634e},
  issn = {0021-9258},
  journal = {JOURNAL OF BIOLOGICAL CHEMISTRY},
  keywords = {IFZ imported},
  number = 15,
  pages = {10915-10921},
  timestamp = {2008-07-15T11:10:10.000+0200},
  title = {Late assembly steps and dynamics of the cyanobacterial photosystem I},
  volume = 282,
  year = 2007
}

@article{ISI:000245467700024,
  abstract = {In response to iron deficiency, cyanobacteria synthesize the iron
stress-induced chlorophyll binding protein IsiA. This protein protects
cyanobacterial cells against iron stress. It has been proposed that the
protective role of IsiA is related to a blue light-induced
nonphotochemical fluorescence quenching (NPQ) mechanism. In
iron-replete cyanobacterial cell cultures, strong blue light is known
to induce a mechanism that dissipates excess absorbed energy in the
phycobilisome, the extramembranal antenna of cyanobacteria. In this
photoprotective mechanism, the soluble Orange Carotenoid Protein (OCP)
plays an essential role. Here, we demonstrate that in iron-starved
cells, blue light is unable to quench fluorescence in the absence of
the phycobilisomes or the OCP. By contrast, the absence of IsiA does
not affect the induction of fluorescence quenching or its recovery. We
conclude that in cyanobacteria grown under iron starvation conditions,
the blue light-induced nonphotochemical quenching involves the
phycobilisome OCP-related energy dissipation mechanism and not IsiA.
IsiA, however, does seem to protect the cells from the stress generated
by iron starvation, initially by increasing the size of the photosystem
I antenna. Subsequently, the IsiA converts the excess energy absorbed
by the phycobilisomes into heat through a mechanism different from the
dynamic and reversible light-induced NPQ processes.},
  added-at = {2008-07-15T11:10:10.000+0200},
  author = {Wilson, Adjele and Boulay, Clemence and Wilde, Annegret and Kerfeld, Cheryl A. and Kirilovsky, Diana},
  biburl = {http://www.bibsonomy.org/bibtex/26435a761a1819f0d00a48daf8ae39150/microbio},
  interhash = {9f25f40c5d875421b6bf6457b276bf29},
  intrahash = {6435a761a1819f0d00a48daf8ae39150},
  issn = {1040-4651},
  journal = {PLANT CELL},
  keywords = {IFZ imported},
  number = 2,
  pages = {656-672},
  timestamp = {2008-07-15T11:10:10.000+0200},
  title = {Light-induced energy dissipation in iron-starved cyanobacteria: Roles of OCP and IsiA proteins},
  volume = 19,
  year = 2007
}