Comparative Genomics of Two Closely Related Unicellular Thermo-Acidophilic Red Algae, Galdieria sulphuraria and Cyanidioschyzon merolae, Reveals the Molecular Basis of the Metabolic Flexibility of Galdieria  sulphuraria and Significant Differences in Carbohydrate Metabolism of Both Algae

Barbier, Guillaume G.; Oesterhelt, Christine; Larson, Matthew D.; Halgren, Robert G.; Wilkerson, Curtis G.; Garavito, R. Michael; Benning, Christoph; Weber, Andreas P.M.

doi:10.1104/pp.104.051169

Cited by 186 publications

(139 citation statements)

References 114 publications

Supporting

Mentioning

136

Contrasting

Order By: Relevance

“…Genomic analyses of carbon metabolism have suggested that Cyanidioschyzon merolae, as G. sulphuraria, harbors metabolic pathways for floridoside, trehalose, storage glucans, and matrix polysaccharides [16]. C. merolae is predicted to contain a minimal set of metabolic transporters but no aquaporin-type glycerol permease for uptake of glycerol from the environment, or plastidic dicarboxylate translocators, which are required for nitrogen assimilation and for photorespiration and which are conserved in green plants and algae [17].…”

Section: Resultsmentioning

confidence: 99%

Investigation of the Malic Acid Concentration on Extremophilic Red Microalga Galdieria Sulphuraria

Demirkaya¹,

Demirel²,

İmamoğlu³

et al. 2016

deufmd

View full text Add to dashboard Cite

Malic acid is a dicarboxylic acid which is made by living organisms and the salts of malic acid are known as malates. Malates are used in pruvate/malate cycle that merges carbohydrate, fat and protein metabolism. Based on this cycle, the prediction was that malic acid could change carbohydrates ratio in G.sulphuraria. In this study, the effects of malic acid concentrations were investigated on growth (maximum specific growth rate and doubling time) of extremophilic, red alga Galdieria sulphuraria (SAG 108.79). By increasing malic acid concentration, specific growth rate and biomass concentration were also increased, however the highest concentration of protein (153.81±0.673 mg/L) was obtained in 5 mM. The total amount of carbohydrates was increased about 8.35%. Keywords

show abstract

Section: Resultsmentioning

confidence: 99%

Investigation of the Malic Acid Concentration on Extremophilic Red Microalga Galdieria Sulphuraria

Demirkaya¹,

Demirel²,

İmamoğlu³

et al. 2016

deufmd

View full text Add to dashboard Cite

show abstract

“…However, recent investigations strongly suggest that at least Rhodophyceae (Barbier et al 2005;Coppin et al 2005) and possibly also Glaucophyta (Plancke et al 2008) synthesize their starch from a far simpler set of analogous enzymes. These consist of soluble and granule-bound starch synthases, branching enzyme, transglucosidase, D enzyme, debranching enzyme, GWD, laforin, phosphorylase, and b-amylase but in fewer isoforms (for a detailed analysis see Deschamps et al 2008).…”

Section: Discussionmentioning

confidence: 99%

Early Gene Duplication Within Chloroplastida and Its Correspondence With Relocation of Starch Metabolism to Chloroplasts

et al. 2008

View full text Add to dashboard Cite

The endosymbiosis event resulting in the plastid of photosynthetic eukaryotes was accompanied by the appearance of a novel form of storage polysaccharide in Rhodophyceae, Glaucophyta, and Chloroplastida. Previous analyses indicated that starch synthesis resulted from the merging of the cyanobacterial and the eukaryotic storage polysaccharide metabolism pathways. We performed a comparative bioinformatic analysis of six algal genome sequences to investigate this merger. Specifically, we analyzed two Chlorophyceae, Chlamydomonas reinhardtii and Volvox carterii, and four Prasinophytae, two Ostreococcus strains and two Micromonas pusilla strains. Our analyses revealed a complex metabolic pathway whose intricacies and function seem conserved throughout the green lineage. Comparison of this pathway to that recently proposed for the Rhodophyceae suggests that the complexity that we observed is unique to the green lineage and was generated when the latter diverged from the red algae. This finding corresponds well with the plastidial location of starch metabolism in Chloroplastidae. In contrast, Rhodophyceae and Glaucophyta produce and store starch in the cytoplasm and have a lower complexity pathway. Cytoplasmic starch synthesis is currently hypothesized to represent the ancestral state of storage polysaccharide metabolism in Archaeplastida. The retargeting of components of the cytoplasmic pathway to plastids likely required a complex stepwise process involving several rounds of gene duplications. We propose that this relocation of glucan synthesis to the plastid facilitated evolution of chlorophyllcontaining light-harvesting complex antennae by playing a protective role within the chloroplast. BOTH glycogen and starch are made of glucose chains (glucans) linked at the a-1,4 position and branched at a-1,6. While glycogen is a homogeneous hydrosoluble polymer with uniformly distributed branches, starch is known to be composed of two types of polysaccharides: a minor amylose fraction with very few branches (,1% a-1,6 linkages) and a major moderately branched (5% a-1,6 linkages) amylopectin fraction. Unlike glycogen, amylopectin displays an asymmetric distribution of branches, which regularly alternates poorly branched with highly branched regions. This generates clusters of chains and forms the backbone of the insoluble and semicrystalline starch granule (for a review of starch structure, see Buléon et al. 1997).Glycogen is by far the most widespread form of storage polysaccharide. It is found in archaea, bacteria, and many heterotrophic eukaryotes. Interestingly, the distribution of starch metabolism within the tree of life is restricted to Archaeplastida and some eukaryotic lineages derived from the Archaeplastida by secondary endosymbiosis (alveolates, cryptophytes). Archaeplastida themselves can be traced back to a single endosymbiotic event involving an ancestor of present-day cyanobacteria and a heterotrophic eukaryotic host (Rodríguez-Ezpelata et al. 2005). This event introduced the organelle now known as th...

show abstract

“…Therefore, the identification and characterization of genes encoding putative IP 3 or IP 6 receptors of unknown structure is of the highest priority for elucidating and comparing the regulation of the PI-PLC signalling cascade between IP 3 receptor-carrying and -lacking algae. Ostreococcus lucimarinus [9] Chlorophyceae Volvocales Chlamydomonadaceae Chlamydomonas reinhardtii [10] Volvocaceae Volvox carteri [11] Chlorococcales Coccomyxaceae Coccomyxa subellipsoidea [12] Rhodophyta Cyanidiophyceae Cyanidiales Cyanidiaceae Cyanidioschyzon merolae [13] Galdieria sulphuraria [14] Porphyridiophyceae Porphyridiales Porphyridiaceae Porphyridium purpureum [15] Rhodophyceae Bangiales Bangiaceae Pyropia yezoensis [16] Florideophyceae Gigartinales Gigartinaceae Chondrus crispus [17] Glaucophyta Glaucophyceae Glaucocystales Glaucocystaceae Cyanophora paradoxa [18] Heterokontophyta Coscinodiscophyceae Thalassiosirales Thalassiosiraceae Thalassiosira pseudonana [19] Bacillariophyceae Naviculales Phaeodactylaceae Phaeodactylum tricornutum [20] Pelagophyceae …”

mentioning

confidence: 99%

“…However, although the PI-PLC signaling cascade is present in plants [5][6][7], genes encoding PKC and the IP 3 receptor have not been found in terrestrial plant genomes, suggesting differences in second messenger systems between animals and plants. To date, the genomes of a variety of unicellular and multicellular algae have been sequenced [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23] as shown in (Table 1). In addition, large-scale EST information for the red seaweeds Porphyra umbilicalis and Porphyra purpurea has been accumulated [24][25][26].…”

mentioning

confidence: 99%

Comparative Genomic View of The Inositol-1,4,5-Trisphosphate Receptor in Plants

Mikami¹

2014

J Plant Biochem Physiol

View full text Add to dashboard Cite

Inositol-1,4,5-trisphosphate [Ins(1,4,5)P 3 , IP 3 ] is a second messenger involved in transient release of Ca 2+ from the ER that activates cytosolic Ca 2+ signalling cascades in response to extracellular and intracellular stimuli [1,2]. Phosphatidylinositol-4,5-bisphosphate is cleaved by phosphoinositide-specific phospholipase C (PI-PLC) into the second messengers diacylglycerol (DAG) and IP 3 [3,4]. These second messengers then activate protein kinase C (PKC) and the ER-localised IP 3 receptor, respectively, in animal cells [1,2]. However, although the PI-PLC signaling cascade is present in plants [5][6][7], genes encoding PKC and the IP 3 receptor have not been found in terrestrial plant genomes, suggesting differences in second messenger systems between animals and plants. To date, the genomes of a variety of unicellular and multicellular algae have been sequenced [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23] as shown in (Table 1). In addition, large-scale EST information for the red seaweeds Porphyra umbilicalis and Porphyra purpurea has been accumulated [24][25][26]. Such rich gene information enables us to identify the genes encoding IP 3 receptor gene homologues in algae to hypothesize the evolutionary route of the loss of the IP 3 gene in plant lineages.The origin of the IP 3 receptor-dependent transient Ca 2+ release system predates the divergence of animals and fungi [27,28]. Indeed, homologues of genes encoding the IP 3 receptor have been identified in protozoa such as the choanoflagellate Monosiga brevicollis [29], the myxomycete Dictyostelium discoideum [30], the ciliate Paramecium tetraurelia [31], and the parasite Trypanosoma brucei [32]. Thus, it is plausible that an ancient eukaryotic cell containing an IP 3 receptor gene was the target of endosymbiosis with an ancient cyanobacterium to produce plant cells, after which the IP 3 gene was lost from plant lineages. At present, IP 3 receptor homologues have been found in green algae, such as Chlamydomonas reinhardtii [10] and Volvox carteri [33,34], and in heterokont algae including Aureococcus anophagefferrens [21] and Ectocarpus siliculosus [22], but have not been identified in red algae or streptophytes (land plants and charophytic algae) (Figure 1). These findings have led to proposals that the IP 3 receptor gene homologue was lost on multiple occasions during plant evolution. Because an ancestor of both green and red photosynthetic algal cells appeared after the primary endosymbiosis of a cyanobacterium into an ancient non-photosynthetic eukaryotic cell [35], the IP 3 receptor homologue was probably lost from lineages of red algae and green algae except for Volvocales (Figure 1). In fact, the genomes of unicellular Aureococcus anophagefferrens and multicellular Ectocarpus siliculosus carry an IP 3 receptor gene homologue (Figure 1). Because both photosynthetic algae arose from secondary endosymbiosis of a red algal cell into an ancient non-photosynthetic eukaryotic cell [35], it appears that red algae subsequently lost the IP...

show abstract

Comparative Genomics of Two Closely Related Unicellular Thermo-Acidophilic Red Algae, Galdieria sulphuraria and Cyanidioschyzon merolae, Reveals the Molecular Basis of the Metabolic Flexibility of Galdieria sulphuraria and Significant Differences in Carbohydrate Metabolism of Both Algae

Cited by 186 publications

References 114 publications

Investigation of the Malic Acid Concentration on Extremophilic Red Microalga Galdieria Sulphuraria

Investigation of the Malic Acid Concentration on Extremophilic Red Microalga Galdieria Sulphuraria

Early Gene Duplication Within Chloroplastida and Its Correspondence With Relocation of Starch Metabolism to Chloroplasts

Comparative Genomic View of The Inositol-1,4,5-Trisphosphate Receptor in Plants

Contact Info

Product

Resources

About