Genome of the halotolerant green alga Picochlorum sp. reveals strategies for thriving under fluctuating environmental conditions

Summary An expected outcome of climate change is intensification of the global water cycle, which magnifies surface water fluxes, and consequently alters salinity patterns. It is therefore important to understand the adaptations and limits of microalgae to survive changing salinities. To this end, w...

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Published inEnvironmental microbiology Vol. 17; no. 2; pp. 412 - 426
Main Authors Foflonker, Fatima, Price, Dana C., Qiu, Huan, Palenik, Brian, Wang, Shuyi, Bhattacharya, Debashish
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.02.2015
Wiley Subscription Services, Inc
Subjects
acetates
acetoin
Algae
Aquatic plants
Bacteria - genetics
Base Sequence
Brackish water
Chlorophyta
Chlorophyta - enzymology
Chlorophyta - genetics
Chlorophyta - metabolism
Climate Change
complement
DNA, Plant - genetics
Environment
Environmental conditions
environmental factors
Fermentation
Gene Transfer, Horizontal
Genome, Plant
Genomes
Genomics
glucose
growth promotion
horizontal gene transfer
Hydrologic cycle
Microalgae
multigene family
Ostreococcus tauri
Salinity
salt stress
Salt tolerance
Salt-Tolerance - genetics
Salt-Tolerance - physiology
Salts
Sequence Analysis, DNA
stress response
Surface water
transporters
Urea
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Summary:Summary An expected outcome of climate change is intensification of the global water cycle, which magnifies surface water fluxes, and consequently alters salinity patterns. It is therefore important to understand the adaptations and limits of microalgae to survive changing salinities. To this end, we sequenced the 13.5 Mbp genome of the halotolerant green alga Picochlorum SENEW3 (SE3) that was isolated from a brackish water pond subject to large seasonal salinity fluctuations. Picochlorum SE3 encodes 7367 genes, making it one of the smallest and most gene dense eukaryotic genomes known. Comparison with the pico‐prasinophyte Ostreococcus tauri, a species with a limited range of salt tolerance, reveals the enrichment of transporters putatively involved in the salt stress response in Picochlorum SE3. Analysis of cultures and the protein complement highlight the metabolic flexibility of Picochlorum SE3 that encodes genes involved in urea metabolism, acetate assimilation and fermentation, acetoin production and glucose uptake, many of which form functional gene clusters. Twenty‐four cases of horizontal gene transfer from bacterial sources were found in Picochlorum SE3 with these genes involved in stress adaptation including osmolyte production and growth promotion. Our results identify Picochlorum SE3 as a model for understanding microalgal adaptation to stressful, fluctuating environments.
Bibliography:istex:C91A36397940916E34C5C4AB8DA4A66FBBFA7350
ark:/67375/WNG-7N2LKRVL-X
Fig. S1. Mixotrophic growth of Picochlorum SE3. Growth of Picochlorum SE3 cultures in the absence of high salt stress (0.4 M NaCl) with the addition of different amounts of glucose. The inoculation density was 1 × 10 E + 5 cells ml−1. The error bars represent standard error from triplicate cultures.Table S1. List of predicted proteins in Picochlorum SE3 showing their putative annotations and results of a blastp search against a comprehensive in-house database.Table S2. Ostreococcus tauri nitrate assimilation gene clusters and the corresponding Picochlorum SE3 genes and their contig locations. Genes located on the same contig are shown in boldface.
Department of Energy - No. DE-EE0003373/001
National Science Foundation Fuels IGERT program at Rutgers University - No. 0903675
ArticleID:EMI12541
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
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ISSN:1462-2912
1462-2920
1462-2920
DOI:10.1111/1462-2920.12541