Hydrocarbons Are Essential for Optimal Cell Size, Division, and Growth of Cyanobacteria

Lea‐Smith, David J.; Ortiz-Suarez, Maite L.; Lenn, Tchern; Nürnberg, Dennis J.; Baers, Laura L.; Davey, Matthew P.; Parolini, Lucia; Huber, Roland G.; Cotton, Charles A. R.; Mastroianni, Giulia; Bombelli, Paolo; Ungerer, Petra; Stevens, Tim J.; Smith, Alison G.; Bond, Peter J.; Mullineaux, Conrad W.; Howe, Christopher J.

doi:10.1104/pp.16.01205

Cited by 59 publications

(75 citation statements)

References 71 publications

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“…The physiological roles of cyanobacterial hydrocarbons, which are involved in introducing flexibility into membranes and are required for optimal cell division, size, and growth, have been previously reported (7). Though strains harboring the Ols pathway have been proposed to account for a small proportion (approximately 10%) of the cyanobacterial population (4, 5), hydrocarbon production in such strains is recog-…”

Section: Discussionmentioning

confidence: 99%

“…The subcellular location of hydrocarbons is within the lipid bilayers of thylakoid and cytoplasmic membranes, and the biological function of hydrocarbons is thought to be associated with the membrane flexibility required for optimal cell division, size, and growth (7). Free fatty acids in cyanobacteria are thought to be released from complex membrane lipids (8).…”

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confidence: 99%

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Terminal Olefin Profiles and Phylogenetic Analyses of Olefin Synthases of Diverse Cyanobacterial Species

Zhu

Scalvenzi

Sassoon

et al. 2018

Appl Environ Microbiol

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Cyanobacteria can synthesize alkanes and alkenes, which are considered to be infrastructure-compatible biofuels. In terms of physiological function, cyanobacterial hydrocarbons are thought to be essential for membrane flexibility for cell division, size, and growth. The genetic basis for the biosynthesis of terminal olefins (1-alkenes) is a modular type I polyketide synthase (PKS) termed olefin synthase (Ols). The modular architectures of Ols and structural characteristics of alkenes have been investigated only in a few species of the small percentage (approximately 10%) of cyanobacteria that harbor putative Ols pathways. In this study, investigations of the domains, modular architectures, and phylogenies of Ols in 28 cyanobacterial strains suggested distinctive pathway evolution. Structural feature analyses revealed 1-alkenes with three carbon chain lengths (C, C, and C). In addition, the total cellular fatty acid profile revealed the diversity of the carbon chain lengths, while the fatty acid feeding assay indicated substrate carbon chain length specificity of cyanobacterial Ols enzymes. Finally, analyses suggested that the N terminus of the modular Ols enzyme exhibited characteristics typical of a fatty acyl-adenylate ligase (FAAL), suggesting a mechanism of fatty acid activation via the formation of acyl-adenylates. Our results shed new light on the diversity of cyanobacterial terminal olefins and a mechanism for substrate activation in the biosynthesis of these olefins. Cyanobacterial terminal olefins are hydrocarbons with promising applications as advanced biofuels. Despite the basic understanding of the genetic basis of olefin biosynthesis, the structural diversity and phylogeny of the key modular olefin synthase (Ols) have been poorly explored. An overview of the chemical structural traits of terminal olefins in cyanobacteria is provided in this study. In addition, we demonstrated by fatty acid feeding assays that cyanobacterial Ols enzymes might exhibit substrate carbon chain length specificity. Furthermore, by performing bioinformatic analyses, we observed that the substrate activation domain of Ols exhibited features typical of a fatty acyl-adenylate ligase (FAAL), which activates fatty acids by converting them to fatty acyl-adenylates. Our results provide further insight into the chemical structures of terminal olefins and further elucidate the mechanism of substrate activation for terminal olefin biosynthesis in cyanobacteria.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Terminal Olefin Profiles and Phylogenetic Analyses of Olefin Synthases of Diverse Cyanobacterial Species

Zhu

Scalvenzi

Sassoon

et al. 2018

Appl Environ Microbiol

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“…[10,[14][15][16][17][18][19][20] It is a unicellular coccoid organism, with diameter around 1.6 μm, although this is altered in some mutant strains. [21] Some cyanobacteria, such as Synechococcus elongatus PCC7942, [22,23] which is also commonly used, have more elongated cells. Others, such as Nostoc, [24,25] routinely form filaments.…”

Section: Biological Materialsmentioning

confidence: 99%

The Development of Biophotovoltaic Systems for Power Generation and Biological Analysis

et al. 2019

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Biophotovoltaic systems (BPVs) resemble microbial fuel cells, but utilise oxygenic photosynthetic microorganisms associated with an anode to generate an extracellular electrical current, which is stimulated by illumination. Study and exploitation of BPVs have come a long way over the last few decades, having benefited from several generations of electrode development and improvements in wiring schemes. Power densities of up to 0.5 W m À 2 and the powering of small electrical devices such as a digital clock have been reported. Improvements in standardisation have meant that this biophotoelectrochemical phenomenon can be further exploited to address biological questions relating to the organisms. Here, we aim to provide both biologists and electrochemists with a review of the progress of BPV development with a focus on biological materials, electrode design and interfacial wiring considerations, and propose steps for driving the field forward.[a] L.

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“…In addition, isolating membranes via two-phase aqueous polymer partitioning results in considerable losses of cellular material and undersampling of the proteome. Furthermore, both the PM and TM may be heterogeneous (Srivastava et al, 2006;Agarwal et al, 2010;Pisareva et al, 2011) and previous work has suggested that only a hydrocarbon-rich fraction of the TM, and not the whole membrane, is purified via two-phase partitioning (Lea-Smith et al, 2016b). For example, a highly curved 'convergence membrane' substructure in the TM was recently observed, which was in close contact with the PM, and may play a role in biogenesis of thylakoid proteins (Rast et al, 2019).…”

mentioning

confidence: 98%

“…For example, these methods have been shown to give 'purified' PM fractions that actually contain detectable amounts of TM (e.g. Zhang et al, 2015;Lea-Smith et al, 2016b). In addition, isolating membranes via two-phase aqueous polymer partitioning results in considerable losses of cellular material and undersampling of the proteome.…”

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confidence: 99%

Proteome Mapping of a Cyanobacterium Reveals Distinct Compartment Organization and Cell-Dispersed Metabolism

et al. 2019

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Cyanobacteria are complex prokaryotes, incorporating a Gram-negative cell wall and internal thylakoid membranes (TMs). However, localization of proteins within cyanobacterial cells is poorly understood. Using subcellular fractionation and quantitative proteomics, we produced an extensive subcellular proteome map of an entire cyanobacterial cell, identifying ;67% of proteins in Synechocystis sp. PCC 6803, ;1000 more than previous studies. Assigned to six specific subcellular regions were 1,712 proteins. Proteins involved in energy conversion localized to TMs. The majority of transporters, with the exception of a TM-localized copper importer, resided in the plasma membrane (PM). Most metabolic enzymes were soluble, although numerous pathways terminated in the TM (notably those involved in peptidoglycan monomer, NADP 1 , heme, lipid, and carotenoid biosynthesis) or PM (specifically, those catalyzing lipopolysaccharide, molybdopterin, FAD, and phylloquinol biosynthesis). We also identified the proteins involved in the TM and PM electron transport chains. The majority of ribosomal proteins and enzymes synthesizing the storage compound polyhydroxybuyrate formed distinct clusters within the data, suggesting similar subcellular distributions to one another, as expected for proteins operating within multicomponent structures. Moreover, heterogeneity within membrane regions was observed, indicating further cellular complexity. Cyanobacterial TM protein localization was conserved in Arabidopsis (Arabidopsis thaliana) chloroplasts, suggesting similar proteome organization in more developed photosynthetic organisms. Successful application of this technique in Synechocystis suggests it could be applied to mapping the proteomes of other cyanobacteria and single-celled organisms. The organization of the cyanobacterial cell revealed here substantially aids our understanding of these environmentally and biotechnologically important organisms.

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Hydrocarbons Are Essential for Optimal Cell Size, Division, and Growth of Cyanobacteria

Cited by 59 publications

References 71 publications

Terminal Olefin Profiles and Phylogenetic Analyses of Olefin Synthases of Diverse Cyanobacterial Species

Terminal Olefin Profiles and Phylogenetic Analyses of Olefin Synthases of Diverse Cyanobacterial Species

The Development of Biophotovoltaic Systems for Power Generation and Biological Analysis

Proteome Mapping of a Cyanobacterium Reveals Distinct Compartment Organization and Cell-Dispersed Metabolism

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