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Journal ArticleDOI

Identification of Nostoc punctiforme akinete-expressed genes using differential display.

Claudia Argueta1, Kamile Yuksek1, Ronak Patel1, Michael L. Summers1
California State University, Northridge1
01 Aug 2006-Molecular Microbiology (Blackwell Publishing Ltd)-Vol. 61, Iss: 3, pp 748-757
TL;DR: To identify genes associated with akinete development, differential display was used to amplify and compare cDNA from a wild‐type and zwf mutant strain of N. punctiforme following a switch to dark heterotrophic conditions and three novel akinete‐expressed genes were identified.
Abstract: Akinetes are spore-like resting cells formed by certain filamentous cyanobacteria that have increased resistance to environmental stress. They can be found at low frequencies in dense cultures experiencing low light or phosphate limitation, but also form at high frequencies in a zwf mutant strain of Nostoc punctiforme following dark incubation in the presence of fructose. The wild-type strain is capable of facultative heterotrophic growth under these conditions and does not form akinetes. To identify genes associated with akinete development, differential display was used to amplify and compare cDNA from a wild-type and zwf mutant strain of N. punctiforme following a switch to dark heterotrophic conditions. Screening of candidate genes by reverse transcriptase real-time quantitative PCR and subsequent testing for akinete-specific expression using GFP transcriptional reporter plasmids lead to the identification of three novel akinete-expressed genes. The genes identified from the screening encoded for proteins homologous to an aminopeptidase (aapN), a zinc protease (hap) and an ATP-binding cassette (ABC)-type transporter (aet). Expression of hap was also increased in developing hormogonia, a transient type of differentiated filament capable of gliding motility. Transcriptional start sites for akinete-expressed genes were determined using random amplification of cDNA ends (RACE), and promoter regions were compared with orthologues in other filamentous cyanobacteria to identify putative regulatory sequences.

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Citations
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Journal ArticleDOI
Compartmentalized function through cell differentiation in filamentous cyanobacteria

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Enrique Flores1, Antonia Herrero1
University of Seville1
01 Jan 2010-Nature Reviews Microbiology
TL;DR: This Review addresses cyanob bacterial intercellular communication, the supracellular structure of the cyanobacterial filament and the basic principles that govern the process of heterocyst differentiation.
Abstract: Within the wide biodiversity that is found in the bacterial world, Cyanobacteria represents a unique phylogenetic group that is responsible for a key metabolic process in the biosphere - oxygenic photosynthesis - and that includes representatives exhibiting complex morphologies. Many cyanobacteria are multicellular, growing as filaments of cells in which some cells can differentiate to carry out specialized functions. These differentiated cells include resistance and dispersal forms as well as a metabolically specialized form that is devoted to N(2) fixation, known as the heterocyst. In this Review we address cyanobacterial intercellular communication, the supracellular structure of the cyanobacterial filament and the basic principles that govern the process of heterocyst differentiation.

400 citations

Cites background from "Identification of Nostoc punctiform..."

  • ...punctiforme PCC 73102, which is impaired in heterotrophy, akinetes differentiate when the filaments are placed in the dark in the presence of fructos...

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Journal ArticleDOI
Allelopathy in freshwater cyanobacteria

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Pedro N. Leão1, M. Teresa S. D. Vasconcelos, Vitor Vasconcelos
University of Porto1
28 Oct 2009-Critical Reviews in Microbiology
TL;DR: The role of allelopathy in cyanobacteria ecology is still not well understood, and its clarification should benefit from carefully designed field studies, chemical characterization of allelochemicals and new methodological approaches at the “omics” level.
Abstract: Freshwater cyanobacteria produce several bioactive secondary metabolites with diverse chemical structure, which may achieve high concentrations in the aquatic medium when cyanobacterial blooms occur. Some of the compounds released by cyanobacteria have allelopathic properties, influencing the biological processes of other phytoplankton or aquatic plants. These kinds of interactions are more easily detectable under laboratory studies; however their ecological relevance is often debated. Recent research has discovered new allelopathic properties in some cyanobacteria species, new allelochemicals and elucidated some of the allelopathic mechanisms. Ecosystem-level approaches have shed some light on the factors that influence allelopathic interactions, as well as how cyanobacteria may be able to modulate their surrounding environment by means of allelochemical release. Nevertheless, the role of allelopathy in cyanobacteria ecology is still not well understood, and its clarification should benefit from carefully designed field studies, chemical characterization of allelochemicals and new methodological approaches at the "omics" level.

134 citations

Cites background from "Identification of Nostoc punctiform..."

  • ...…error in the outcome of the assay—for discussion on this subject please refer to Bustin (2002) and Ginzinger (2002)—and a survey of the literature reveals that only a few studies which employ this methodology with cyanobacteria have been published (Argueta et al. 2006; Woodger et al. 2003)....

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Journal ArticleDOI
Global Gene Expression Patterns of Nostoc punctiforme in Steady-State Dinitrogen-Grown Heterocyst-Containing Cultures and at Single Time Points during the Differentiation of Akinetes and Hormogonia

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Elsie L. Campbell1, Michael L. Summers2, Harry D. Christman1, Miriam E. Martin1, John C. Meeks1 
University of California, Davis1, California State University, Northridge2
15 Jul 2007-Journal of Bacteriology
TL;DR: The differentiation of heterocysts (steady state, N(2) grown), akinetes, and hormogonia appears to involve the up-regulation of genes distinct for each state, consistent with entry into a nongrowth state.
Abstract: The vegetative cells of the filamentous cyanobacterium Nostoc punctiforme can differentiate into three mutually exclusive cell types: nitrogen-fixing heterocysts, spore-like akinetes, and motile hormogomium filaments. A DNA microarray consisting of 6,893 N. punctiforme genes was used to identify the global transcription patterns at single time points in the three developmental states, compared to those in ammonium-grown time zero cultures. Analysis of ammonium-grown cultures yielded a transcriptome of 2,935 genes, which is nearly twice the size of a soluble proteome. The NH4+-grown transcriptome was enriched in genes encoding core metabolic functions. A steady-state N2-grown (heterocyst-containing) culture showed differential transcription of 495 genes, 373 of which were up-regulated. The majority of the up-regulated genes were predicted from studies of heterocyst differentiation and N2 fixation; other genes are candidates for more detailed genetic analysis. Three days into the developmental process, akinetes showed a similar number of differentially expressed genes (497 genes), which were equally up- and down-regulated. The down-regulated genes were enriched in core metabolic functions, consistent with entry into a nongrowth state. There were relatively few adaptive genes up-regulated in 3-day akinetes, and there was little overlap with putative heterocyst developmental genes. There were 1,827 differentially transcribed genes in 24-h hormogonia, which was nearly fivefold greater than the number in akinete-forming or N2-fixing cultures. The majority of the up-regulated adaptive genes were genes encoding proteins for signal transduction and transcriptional regulation, which is characteristic of a motile filament that is poised to sense and respond to the environment. The greatest fraction of the 883 down-regulated genes was involved in core metabolism, also consistent with entry into a nongrowth state. The differentiation of heterocysts (steady state, N2 grown), akinetes, and hormogonia appears to involve the up-regulation of genes distinct for each state.

118 citations

Cites background from "Identification of Nostoc punctiform..."

  • ...NpR4070 was up-regulated in steady-state N2-grown cultures at a significant but low level....

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  • ...and NpR4070) (6) was present in the akinete transcriptome or...

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  • ...Transcription of avaK (NpF5452), encoding an akinete marker protein (6, 48), was enhanced, as was transcription of patA and hetF, whose products are assigned to heterocyst differentiation....

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  • ...None of the four genes determined by differential display to be up-regulated during akinete development (NpF0062, NpF5999, NpF6000, and NpR4070) (6) was present in the akinete transcriptome or in the NH4 -grown transcriptome or proteome....

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  • ...Five genes that are differentially transcribed during akinete differentiation have recently been identified (6, 48)....

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Book ChapterDOI
Akinetes: Dormant Cells of Cyanobacteria

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Ruth N. Kaplan-Levy, Ora Hadas, Michael L. Summers1, Jacqueline Rücker2, Assaf Sukenik 
California State University, Northridge1, Brandenburg University of Technology2
01 Jan 2010
TL;DR: This review focuses on akinetes of Nostocales, emphasizing environmental triggers and cellular responses involved in differentiation, maturation, dormancy, and germination of these resting cells and special attention is given to genetic regulation of the differentiation process.
Abstract: Cyanobacteria are an ancient and morphologically diverse group of photosynthetic prokaryotes, which were the first to evolve oxygenic photosynthesis. Cyanobacteria are widely distributed in diversed environments. In the case of members of the orders Nostocales and Stigonematales, their persistence and success were attributed to their ability to form specialized cells: heterocysts, capable of fixing atmospheric nitrogen and spore-like cells, the akinetes. This review focuses on akinetes of Nostocales, emphasizing environmental triggers and cellular responses involved in differentiation, maturation, dormancy, and germination of these resting cells. Morphological and structural changes, variation in akinete composition, and metabolism are summarized. Special attention is given to the genetic regulation of the differentiation process in an attempt to close gaps in our understanding of the dormancy phenomenon in cyanobacteria and to identify open questions for future research.

100 citations

Cites background or result from "Identification of Nostoc punctiform..."

  • ...These results are consistent with the expression of avaK in A. variabilis (Zhou and Wolk 2002), with N. punctiforme differential display results for aet ( Argueta et al. 2006 ), and with microarray results from zwf akinetes for nblA and avaK (Campbell et al. 2007)....

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  • ...Argueta et al. (2006) reported the detection of three novel genes involved in akinete differentiation....

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Journal ArticleDOI
Clear differences in metabolic and morphological adaptations of akinetes of two Nostocales living in different habitats.

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Rebeca Perez1, Karl Forchhammer1, Graciela Lidia Salerno, Iris Maldener1
University of Tübingen1
01 Feb 2016-Microbiology
TL;DR: The clear differences in the metabolic and morphological adaptations of akinetes of the two species could be related to their different lifestyles and pave the way for genetic and functional studies of akinete differentiation in these species.
Abstract: Akinetes are resting spore-like cells formed by some heterocyst-forming filamentous cyanobacteria for surviving long periods of unfavourable conditions. We studied the development of akinetes in two model strains of cyanobacterial cell differentiation, the planktonic freshwater Anabaena variabilis ATCC 29413 and the terrestrial or symbiotic Nostoc punctiforme ATCC 29133, in response to low light and phosphate starvation. The best trigger of akinete differentiation of Anabaena variabilis was low light; that of N. punctiforme was phosphate starvation. Light and electron microscopy revealed that akinetes of both species differed from vegetative cells by their larger size, different cell morphology and large number of intracellular granules. Anabaena variabilis akinetes had a multilayer envelope; those of N. punctiforme had a simpler envelope. During akinete development of Anabaena variabilis, the amount of the storage compounds cyanophycin and glycogen increased transiently, whereas in N. punctiforme, cyanophycin and lipid droplets increased transiently. Photosynthesis and respiration decreased during akinete differentiation in both species, and remained at a low level in mature akinetes. The clear differences in the metabolic and morphological adaptations of akinetes of the two species could be related to their different lifestyles. The results pave the way for genetic and functional studies of akinete differentiation in these species.

40 citations

Cites background from "Identification of Nostoc punctiform..."

  • ...Here, we showed that low light was the best inducer of akinete formation in Anabaena variabilis and confirmed the earlier finding (Argueta & Summers, 2005; Argueta et al., 2006) that phosphate starvation was the best inducer in N. punctiforme....

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  • ...Here, we showed that low light was the best inducer of akinete formation in Anabaena variabilis and confirmed the earlier finding (Argueta & Summers, 2005; Argueta et al., 2006) that phosphate starvation was the best inducer in N....

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  • ...However, only a few genes involved in akinete formation have been so far identified (e.g. Argueta et al., 2006; Campbell et al., 1996; Leganés et al., 1994, 1998; Lehner et al., 2011; Zhou &Wolk, 2002; see also review by Maldener et al., 2014)....

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References
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Journal ArticleDOI
BioLingua: a programmable knowledge environment for biologists

[...]

J. P. Massar, Michael Travers, Jeff Elhai1, Jeff Shrager
Virginia Commonwealth University1
15 Jan 2005-Bioinformatics
TL;DR: The pilot instantiation of BioLingua, which has been developed in collaboration with several cyanobacteriologists, integrates knowledge about a subset of cyanobacteria with the Gene Ontology, KEGG and BioCyc knowledge bases.
Abstract: Summary: BioLingua is an interactive, web-based programming environment that enables biologists to analyze biological systems by combining knowledge and data through direct end-user programming. BioLingua embeds a mature symbolic programming language in a frame-based knowledge environment, integrating genomic and pathway knowledge about a class of similar organisms. The BioLingua language provides interfaces to numerous state-of-the-art bioinformatic tools, making these available as an integrated package through the novel use of web-based programmability and an integrated Wiki-based community code and data store. The pilot instantiation of BioLingua, which has been developed in collaboration with several cyanobacteriologists, integrates knowledge about a subset of cyanobacteria with the Gene Ontology, KEGG and BioCyc knowledge bases. We introduce the BioLingua concept, architecture and language, and give several examples of its use in complex analyses. Availability: Extensive documentation is available online at http://nostoc.stanford.edu/Docs/index.html Contact: JShrager@Stanford.edu

45 citations

"Identification of Nostoc punctiform..." refers methods in this paper

  • ...Sequences were manipulated using DNA Strider (Marck, 1988) and BioBike (Massar et al., 2005)....

    [...]

Journal ArticleDOI
Construction and use of GFP reporter vectors for analysis of cell-type-specific gene expression in Nostoc punctiforme.

[...]

Claudia Argueta1, Kamile Yuksek1, Michael L. Summers1
California State University, Northridge1
01 Nov 2004-Journal of Microbiological Methods
TL;DR: Two transcriptional reporter shuttle vectors constructed for the filamentous cyanobacterium Nostoc punctiforme using the green fluorescence protein (GFP) reporter demonstrate the utility of these GFP vectors to study cell-type-specific gene expression in differentiating filamentous Cyanobacteria.

43 citations

"Identification of Nostoc punctiform..." refers background or methods in this paper

  • ...punctiforme is similarly regulated (Argueta et al., 2004), but its function remains unknown....

    [...]

  • ...Promoter regions of specific genes were amplified by PCR from the N. punctiforme genome using primers containing added restriction enzyme sites (Table 1), and cloned into the transcriptional reporter vector pSUN202 (Argueta et al., 2004)....

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  • ...To make this an inclusive promoter analysis, avaK, the only previously described akinete-marker gene originally identified in A. variabilis (Zhou and Wolk, 2002), was included as this gene has also been demonstrated to be expressed in akinetes of N. punctiforme (Argueta et al., 2004)....

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  • ...punctiforme genome using primers containing added restriction enzyme sites (Table 1), and cloned into the transcriptional reporter vector pSUN202 (Argueta et al., 2004)....

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  • ...The orthologue of avaK in N. punctiforme is similarly regulated (Argueta et al., 2004), but its function remains unknown....

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Journal ArticleDOI
Macromolecular Composition of Spores from the Filamentous Cyanobacterium Anabaena cylindrica

[...]

Robert D. Simon1
University of Rochester1
01 Feb 1977-Journal of Bacteriology
TL;DR: Spores were isolated from the filamentous cyanobacterium Anabaena cylindrica, and their deoxyribonucleic acid, ribonuclear acid, and protein compositions were determined.
Abstract: Spores were isolated from the filamentous cyanobacterium Anabaena cylindrica, and their deoxyribonucleic acid, ribonucleic acid, and protein compositions were determined.

42 citations

"Identification of Nostoc punctiform..." refers background in this paper

  • ...A. variabilis is capable of forming nearly all cells into akinetes when aged on agar plates, and has been used to study the macromolecular components of akinetes (Simon, 1977; Cardemil and Wolk, 1981)....

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  • ...variabilis is capable of forming nearly all cells into akinetes when aged on agar plates, and has been used to study the macromolecular components of akinetes (Simon, 1977; Cardemil and Wolk, 1981)....

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Journal ArticleDOI
Heterocyst glycolipids of the cyanobacterium Cyanospira rippkae

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Annunziata Soriente1, Agata Gambacorta2, Agata Gambacorta1, Antonio Trincone2, Antonio Trincone1, Claudio Sili1, Claudio Sili2, Massimo Vincenzini1, Guido Sodano1 
University of Salerno1, ARCO2
13 May 1993-Phytochemistry
TL;DR: The absolute configuration at the two stereogenic centres in the aglycone moiety of the former compound has been established in a single step by Mosher's method on the triol derivative.

39 citations

Journal ArticleDOI
Polysaccharides from the envelopes of heterocysts and spores of the blue-green algae anabaena variabilis and cylindrospermum licheniforme1

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Liliana Cardemil1, C. Peter Wolk2
University of Chile1, Michigan State University2
01 Sep 1981-Journal of Phycology
TL;DR: The polysaccharides from the envelopes of heterocysts and spores of C. licheniforme and Anabaena variabilis appear to be structurally related; tentative structures for those not previously investigated are presented.
Abstract: The polysaccharides from the envelopes of heterocysts of Cylindrospermum licheniforme Kutz., and of heterocysts and spores of Anabaena variabilis Kutz., like those from the differentiated cells of Anabaena cylindrica Lemm., have a 1,3-linked backbone consisting of glucosyl and mannosyl residues in a molar ratio of approximately 3:1. As is the case with A. cylindrica the polysaccharides from A. variabilis and from the heterocysts of C. licheniforme have terminal xylosyl and galactosyl residues as side branches. In addition, the polysaccharide from C. licheniforme resembles that from A. cylindrica in having terminal mannosyl residues as side branches (absent from A. variabilis). The polysaccharides from A. variabilis resemble that from A. cylindrica in having glucose-containing side branches (absent from the heterocyst polysaccharide from C. licheniforme), but in contrast to the polysaccharides from the other two species they also have terminal arabinosyl residues as side branches. All of the polysaccharides mentioned appear to be structurally related; we present tentative structures for those not previously investigated. In contrast, the envelope of spores of C. licheniforme contains only a largely 4-linked galactan. The bulk of this envelope is not polysaccharide in nature, and contains aromatic groups.

38 citations

"Identification of Nostoc punctiform..." refers background in this paper

  • ...A. variabilis is capable of forming nearly all cells into akinetes when aged on agar plates, and has been used to study the macromolecular components of akinetes (Simon, 1977; Cardemil and Wolk, 1981)....

    [...]

  • ...Akinetes contain a thickened envelope composed of polysaccharides and glycolipids (Cardemil and Wolk, 1981; Soriente et al., 1993), and usually contain refractile granules of storage material for carbon in the form of glycogen, and nitrogen in the form of cyanophycin (copolymers of arginine and…...

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  • ...variabilis is capable of forming nearly all cells into akinetes when aged on agar plates, and has been used to study the macromolecular components of akinetes (Simon, 1977; Cardemil and Wolk, 1981)....

    [...]

  • ...Akinetes contain a thickened envelope composed of polysaccharides and glycolipids (Cardemil and Wolk, 1981; Soriente et al., 1993), and usually contain refractile granules of storage material for carbon in the form of glycogen, and nitrogen in the form of cyanophycin (copolymers of arginine and aspartate)....

    [...]

Related Papers (5)
Tansley Review No. 107. Heterocyst and akinete differentiation in cyanobacteria

[...]

01 Oct 1999-New Phytologist
David G. Adams, Paula S. Duggan
An overview of the genome of Nostoc punctiforme, a multicellular, symbiotic cyanobacterium.

[...]

01 Jan 2001-Photosynthesis Research
John C. Meeks, Jeff Elhai, Teresa Thiel, Malcolm Potts, Frank W. Larimer, Jane Lamerdin, Paul Predki, Ronald M. Atlas 
Global Gene Expression Patterns of Nostoc punctiforme in Steady-State Dinitrogen-Grown Heterocyst-Containing Cultures and at Single Time Points during the Differentiation of Akinetes and Hormogonia

[...]

15 Jul 2007-Journal of Bacteriology
Elsie L. Campbell, Michael L. Summers, Harry D. Christman, Miriam E. Martin, John C. Meeks 
Generic assignments, strain histories, and properties of pure cultures of cyanobacteria

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01 Mar 1979-Microbiology
Rosmarie Rippka, Josette Deruelles, John B. Waterbury, Michael Herdman, Roger Y. Stanier 
Regulation of Cellular Differentiation in Filamentous Cyanobacteria in Free-Living and Plant-Associated Symbiotic Growth States

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01 Mar 2002-Microbiology and Molecular Biology Reviews
John C. Meeks, Jeff Elhai