Influences of nitrogen deficiency on the transcript levels of ammonium transporter, nitrate transporter and glutamine synthetase genes in Isochrysis galbana (Isochrysidales, Haptophyta)

Kang, Lee-Kuo; Hwang, Sheng-Ping L.; Gong, Gwo‐Ching; Lin, Hsing‐Juh; Chen, Pei-Chung; Chang, Jeng Kuei

doi:10.2216/06-44.1

Cited by 36 publications

(44 citation statements)

References 45 publications

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“…In this case, an increase of mRNA level of both transporter genes was observed in N-depleted, to nitrate conditioned cells of I. galbana, but when ammonium and nitrate was provided, the expression of both transporter genes decreased. Moreover, the expression of a glutamine synthase gene in I. galbana was upregulated in nitrogen depleted cells, whereas no differential regulation was shown in the presence of ammonium (Kang et al, 2007).…”

Section: Nitrogen Starvationmentioning

confidence: 86%

“…Surprisingly, no clear N-starvation response was discernable on the gene expression level, because none of the genes putatively involved in N acquisition, transportation and storage were upregulated under N-starvation. In contrast to P. parvum, the non-toxic and presumably non-mixotroph haptophyte I. galbana, reacts to N-starvation by up-regulation of nitrate and ammonium transporters (Kang et al, 2007(Kang et al, , 2009. In this case, an increase of mRNA level of both transporter genes was observed in N-depleted, to nitrate conditioned cells of I. galbana, but when ammonium and nitrate was provided, the expression of both transporter genes decreased.…”

Section: Nitrogen Starvationmentioning

confidence: 92%

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Transcriptomic response of the toxic prymnesiophyte Prymnesium parvum (N. Carter) to phosphorus and nitrogen starvation

et al. 2012

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Section: Nitrogen Starvationmentioning

confidence: 86%

Section: Nitrogen Starvationmentioning

confidence: 92%

Transcriptomic response of the toxic prymnesiophyte Prymnesium parvum (N. Carter) to phosphorus and nitrogen starvation

et al. 2012

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“…Genes that encode for enzymes catalyzing the reduction of NO 3 -to NH 4 + and the biosynthesis of nitrogen-carrying amino acids were strongly expressed under nitrogen limitation [32,33]. Along with the pentose phosphate pathway, these genes were among the most up-regulated genes in -N cells of N. oleoabundans.…”

Section: Nitrogen Limitation Affects the Nitrogen-assimilatory Pathwamentioning

confidence: 98%

Microalgae Isolation and Selection for Prospective Biodiesel Production

Duong¹,

Li²,

Nowak³

et al. 2016

Advances in Biofuel Production

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Background: The lack of sequenced genomes for oleaginous microalgae limits our understanding of the mechanisms these organisms utilize to become enriched in triglycerides. Here we report the de novo transcriptome assembly and quantitative gene expression analysis of the oleaginous microalga Neochloris oleoabundans, with a focus on the complex interaction of pathways associated with the production of the triacylglycerol (TAG) biofuel precursor. Results: After growth under nitrogen replete and nitrogen limiting conditions, we quantified the cellular content of major biomolecules including total lipids, triacylglycerides, starch, protein, and chlorophyll. Transcribed genes were sequenced, the transcriptome was assembled de novo, and the expression of major functional categories, relevant pathways, and important genes was quantified through the mapping of reads to the transcriptome. Over 87 million, 77 base pair high quality reads were produced on the Illumina HiSeq sequencing platform. Metabolite measurements supported by genes and pathway expression results indicated that under the nitrogen-limiting condition, carbon is partitioned toward triglyceride production, which increased fivefold over the nitrogen-replete control. In addition to the observed overexpression of the fatty acid synthesis pathway, TAG production during nitrogen limitation was bolstered by repression of the β-oxidation pathway, up-regulation of genes encoding for the pyruvate dehydrogenase complex which funnels acetyl-CoA to lipid biosynthesis, activation of the pentose phosphate pathway to supply reducing equivalents to inorganic nitrogen assimilation and fatty acid biosynthesis, and the up-regulation of lipases-presumably to reconstruct cell membranes in order to supply additional fatty acids for TAG biosynthesis. Conclusions: Our quantitative transcriptome study reveals a broad overview of how nitrogen stress results in excess TAG production in N. oleoabundans, and provides a variety of genetic engineering targets and strategies for focused efforts to improve the production rate and cellular content of biofuel precursors in oleaginous microalgae.

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“…Recently, a group of nitrate transporter genes (Nrt2) was proposed as a potential marker for evaluating nitrogen deficiencies in eukaryotic phytoplankton (23,26,27). Nrt2 genes encode high-affinity nitrate transporters, which are considered the primary transporter system responsible for nitrate uptake (23,26,27,43).…”

mentioning

confidence: 99%

“…In addition, genes homologous to Nrt2 were widely identified in bacteria, fungi, algae, and higher plants (for recent reviews, see references 12, 18, and 42). In most marine eukaryotic algae studied, Nrt2 transcript levels are repressed in the presence of ammonium, moderately expressed under a nitrate-sufficient condition, and highly expressed under a nitrogen-deprived condition (26,43). Also, the maximum and minimum transcript levels can be achieved by artificial removal and addition of nitrogenous nutrients, which is helpful in interpreting the physiological state of the original cell population (27).…”

mentioning

confidence: 99%

Diversity of Phytoplankton Nitrate Transporter Sequences from Isolated Single Cells and Mixed Samples from the East China Sea and mRNA Quantification

Kang

Wang

Chang

2011

Appl Environ Microbiol

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The transcript abundances of nitrate transporter genes (Nrt2) were proposed as potential markers for nitrogen deficiency in marine diatoms. To correctly quantify diatom Nrt2 mRNA in the East China Sea (ECS), we utilized both mixed-species sequencing and single-cell PCR to expand the sequence database for this region. Using the single-cell method of PCR, 9 new diatom Nrt2 sequences belonging to 5 genera, the Nrt2 sequences of which have never been reported before, were obtained. On the other hand, 291 sequences homologous to Nrt2 were retrieved from mixed-species sequencing using degenerate primers, and these sequences were clustered into 12 major groups according to a phylogenetic analysis. Based on sequence alignments, 11 pairs of group-specific PCR primers were designed to detect Nrt2 mRNA levels in the ECS, and 3 of these primer pairs showed high specificity to target species. In ECS phytoplankton samples, environmental RNA was amplified via antisense RNA amplification followed by cDNA production. Subsequently, Nrt2 transcript levels were readily detected using quantitative PCR. Our results indicated that investigating sequence diversity followed by careful primer design and evaluation is a good strategy to quantify the expression of genes of ecologically important phytoplankton.

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Influences of nitrogen deficiency on the transcript levels of ammonium transporter, nitrate transporter and glutamine synthetase genes in Isochrysis galbana (Isochrysidales, Haptophyta)

Cited by 36 publications

References 45 publications

Transcriptomic response of the toxic prymnesiophyte Prymnesium parvum (N. Carter) to phosphorus and nitrogen starvation

Transcriptomic response of the toxic prymnesiophyte Prymnesium parvum (N. Carter) to phosphorus and nitrogen starvation

Microalgae Isolation and Selection for Prospective Biodiesel Production

Diversity of Phytoplankton Nitrate Transporter Sequences from Isolated Single Cells and Mixed Samples from the East China Sea and mRNA Quantification

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