An inducible expression system in the alga Nannochloropsis gaditana controlled by the nitrate reductase promoter
The marine microalgal species Nannochloropsis gaditana has emerged as a model organism for research into algal-derived biofuels due to its ability to produce large amounts of lipids. In addition, this species has biotechnological potential owing to its ease of transformation and availability of a sequenced and annotated genome. The ability to control expression of transgenes in an inducible manner is an important requirement for many genetic engineering approaches and as such, inducible promoters are an important component of the molecular toolkit for a host organism. We designed an expression vector containing a ~ 1.3 kb region upstream of the endogenous nitrate reductase gene of N. gaditana and demonstrated this is capable of promoting the expression of a heterologous enhanced green fluorescent protein (eGFP) reporter. In the presence of ammonium, expression of the eGFP reporter was undetectable; however, in the presence of nitrate, eGFP expression is induced. In addition, we demonstrated how altering the nitrogen source of the growth media can be used to precisely control expression. We have shown that the nitrate reductase promoter can be used as a powerful molecular tool for heterologous protein expression in N. gaditana, further contributing to the development of this species as a candidate strain for biotechnology.
KeywordsNannochloropsis Synthetic biology Biofuels Heterologous expression Inducible promoter Nitrate reductase
Recent advances have seen the emergence of Nannochloropsis spp. as a platform for biotechnological application of marine microalgae. Reverse genetic approaches using random mutagenesis combined with high-throughput phenotypic screening have isolated Nannochloropsis strains with improved light-use efficiency and increased lipid accumulation (Doan and Obbard 2012; Beacham et al. 2015; Perin et al. 2015). Further, Nannochloropsis spp. are haploids and transformation of the nuclear genome with integration constructs has been established and shown to occur by high-efficiency homologous recombination in Nannochloropsis oceanica, allowing the generation of knockout mutants (Kilian et al. 2011; Radakovits et al. 2012). Wang et al. (2016) reported the first use of a CRISPR/Cas9-based approach in a Nannochloropsis species, generating mutant strains of N. oceanica with precise five-base deletions in the nitrate reductase gene, demonstrating the potential for sophisticated gene editing techniques.
Within the genus, Nannochloropsis gaditana is a particularly promising organism for biofuel production systems due to its ability to accumulate high levels of lipids such as triacylglycerols (TAGs), which can exceed 60% of total biomass on a dry weight basis under nitrogen starvation (Rodolfi et al. 2009). A detailed understanding of key metabolic pathways in N. gaditana has been assisted by the draft assembly of the nuclear (~ 27.5 Mbp; 10,646 protein-coding genes) and organellar genomes (Radakovits et al. 2012; Jinkerson et al. 2013; Corteggiani Carpinelli et al. 2014). Codon utilization analysis of N. gaditana has shown no unused codons, an advantageous property for host systems for heterologous protein expression (Jinkerson et al. 2013). Clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 has also been successfully implemented in N. gaditana to knock out 18 transcription factors involved in negative lipid regulation under nitrogen starvation (Ajjawi et al. 2017). Attenuation of one of the identified genes yielded strains with a twofold increase in lipid content and little effect on growth, which has previously been a problem of alteration to lipid metabolism (Ajjawi et al. 2017). These advances have resulted in the emergence of N. gaditana as a candidate platform species to enable further biotechnological development.
Endogenous promoters have been shown to be more effective for generating stable transformants and driving expression of heterologous genes (Walker et al. 2005). A limited number of endogenous promoters have been used to successfully drive expression of heterologous genes in N. gaditana, although this number is likely to increase (Radakovits et al. 2012; Ajjawi et al. 2017). The availability of a wide selection of endogenous promoters with well-characterized and novel expression traits is a key requirement for the development of a species from both a fundamental research and a biotechnological perspective (Doron et al. 2016). In particular, there is a requirement for inducible promoters that can be switched on and off, without negative effects on growth, to enable temporally controlled expression of toxic molecules such as Cas9 or for use in silencing systems such as RNAi (Jiang et al. 2014; Doron et al. 2016). Various inducible expression systems have been developed in algae; however, many rely on induction methods that may have limitations in a photoautotrophic species. For example, the hsp70A promoter has been used in green algae to regulate heat-induced expression; however, the use of heat as a method of induction may deem this promoter unsuitable as a molecular switch for N. gaditana due to the possibility of detrimental effects on growth caused by changing temperatures (Schroda et al. 2000; Jakobiak et al. 2004). Light-based induction systems have also been explored in algae, initially by use of the CABII-I promoter in Chlamydomonas, but pose similar concerns regarding the effects of the method of induction on growth (Blankenship and Kindle 1992; Park et al. 2013; Baek et al. 2016).
We therefore considered expression systems controlled by nutrients or chemicals that can be regulated in the growth media. Algae (including Nannochloropsis spp.) are able to utilise nitrate and subsequently convert it into ammonium through use of the enzyme nitrate reductase (Fernández et al. 1989; Berges 1997). Micromolar concentrations of nitrate elicit a rapid induction of expression of the nitrate reductase gene (Raven et al. 1992; Forde 2000; Galván and Fernández 2001; Llamas et al. 2002; Fernández and Galván 2008). The energy cost of direct ammonium assimilation is lower than that of nitrate (Bloom et al. 1992). Consequently, the presence of ammonium provides a negative feedback effect on nitrate assimilation and supresses the nitrate reductase gene (Ohresser et al. 1997; Loppes et al. 1999; Llamas et al. 2002; Fernández and Galván 2008). Hence, expression of the nitrate reductase gene is induced in the presence of nitrate ions and repressed in the presence of ammonium ions in a range of algae, including Cylindrotheca fusiformis, Chlamydomonas reinhardtii, Chlorella ellipsoidea, Dunaliella salina, Volvox carteri and Phaeodactylum triornutum (Wang et al. 2004; Poulsen and Kröger 2005; Li et al. 2007; Schmollinger et al. 2010; Niu et al. 2012; von der Heyde et al. 2015). In addition, the promoter of the nitrate reductase gene has been used to regulate inducible expression of a reporter gene in several species of algae including C. reinhardtii (Schmollinger et al. 2010), C. ellipsoidea (Wang et al. 2004), D. salina (Li et al. 2008; Li et al. 2007) and P. triornutum (Niu et al. 2012).
Using an enhanced green fluorescent protein (eGFP) as a fluorescent reporter and for immunoblot analysis, we investigated the ability of the endogenous N. gaditana nitrate reductase promoter to robustly drive inducible expression of heterologous protein in transgeneic cell lines. In addition, the temporal regulation characteristics of the nitrate reductase promoter over a range of nitrogen conditions were explored at the protein level to help define the biotechnological potential of this inducible promoter.
Strains and culture conditions
Nannochloropsis gaditana CCMP526 was obtained from the National Center for Marine Algae and Microbiota (Bigelow Laboratory for Ocean Sciences, Maine, USA) and grown in F2N, a modified version of F/2 media for Nannochloropsis (Kilian et al. 2011), containing 5 mM ammonium (NH4Cl) as a nitrogen source. Media were prepared with 30 g L−1 Tropic Marin artificial sea salts (Tropical Marine Centre, Rickmansworth, UK). Where mentioned, nitrogen sources were replaced with sodium nitrate (NaNO3; 5 mM), urea (CH4N2O; 5 mM), or in some cases, no nitrogen was present. F2N agar plates were prepared with 1.5% (w/v) bacteriological agar. Liquid cultures were maintained at a photon flux density of 70 μmol photons m−2 s−1 at 30 °C in 25 cm2 vented corning flasks (Thermo Scientific, UK) with gentle shaking. Agar plates were maintained under continuous light at the same irradiance and temperature. All chemicals were reagent-grade and were obtained from Sigma-Aldrich (UK) or Melford Laboratories Ltd. (UK) unless otherwise mentioned.
For the PNR nitrogen source regulation experiments, liquid starter cultures were grown to the exponential phase, harvested, washed in nitrogen-deplete medium (×3), and subsequently inoculated at an A540 nm of 0.02.
A 540 nm to cells per millilitre calibration curve
A series of dilutions of N. gaditana wild-type cells was prepared. The absorbance at 540 nm (A540 nm) was measured for all dilutions using a Jenway 7315 spectrophotometer (Keison Products, UK). Cell concentrations in cells per millilitre were determined for all dilutions using a Beckman Multisizer 3 Coulter Counter (Beckman Coulter Life Sciences, USA).
All primers used in this study are listed in Online Resource 1. PCRs for amplification of vector elements were performed using the manufacturers cycling parameters and Q5 polymerase (New England Biolabs, USA). Wild-type N. gaditana genomic DNA was purified with the Wizard genomic DNA purification kit (Promega, USA) and used as a template to amplify genomic sequences.
Vectors were generated by in vivo homologous recombination in yeast (Oldenburg et al. 1997). To obtain the native promoter sequence of the nitrate reductase gene, a region of ~ 1.3 kb upstream of the gene (Naga_100699g1) was amplified using primers PNR fw XX ext. and PNR rv eGFP ext. A region of ~ 1.1 kb upstream of the native lipocalin protein coding gene (Naga_100131g14) was amplified using primers PLCP fw XX ext. and PLCP rv eGFP ext. The eGFP sequence was amplified from pGAP-α-GFP (unpublished) using the eGFP primer pair. The native ATP synthase α subunit terminator was generated using primers TATPα fw eGFP ext. and TATPα rv CC ext. The ubiquitin extension protein promoter (UEP) promoter (Radakovits et al. 2012) was amplified using primers PUEP fw CC ext. and PUEP rv hph ext. The hygromycin B selection marker was amplified from pZC1 using the hph primer pair. The NOS terminator was amplified from the pGWB402 vector (Addgene) using primers TNOS fw hph ext. and TNOS rv YY ext. The amplicons generated have 30 bp extensions at the 5′ and 3′ ends that direct recombination with adjacent amplicons upon co-transformation into yeast. Amplicons were co-transformed along with the acceptor vector pRS426 (Fungal Genetics Stock Centre, School of Biological Sciences, Missouri, USA) following linearization by PCR with primer pair YY fw PmeI ext. and XX rv PmeI ext., for assembly via the endogenous recombination system of yeast (Oldenburg et al. 1997). Yeast transformations were carried out using the lithium acetate/PEG method (Schiestl and Gietz 1989) and grown in 20 mL of SC-uracil for selection. The assembled plasmid was transferred from yeast to Escherichia coli and, following restriction digest screening, the cassette was released from the backbone by digestion with PmeI before transformation into N. gaditana. Plasmid DNA was purified with mini-prep kits from Zymo Research (USA). FastDigest restriction enzymes were purchased from Thermo Scientific (UK).
Transformation of N. gaditana
Nannochloropsis gaditana was transformed largely in accordance with the methods described previously (Kilian et al. 2011; Radakovits et al. 2012). Two hundred-millilitre cultures were grown in F2N media to the exponential phase (~ 2 × 106 cells mL−1). Then, 5 × 108 cells were harvested per reaction and washed (×3) in 375 mM sorbitol before resuspension in 100 μL of 375 mM sorbitol with addition of 2–5 μg of linearized plasmid DNA. Centrifugation was performed at 3000×g for 10 min (4 °C). Electroporation was carried out at 12 kV cm−1 in pre-chilled 2-mm cuvettes using a BIO-RAD MicroPulser electroporator. Cells were then immediately recovered in 10 mL of F2N medium and incubated overnight in 70 μmol photons m−2 s−1 fluorescent white light at 30 °C. The following day cells were plated at 5 × 107 cells plate−1 F2N agar plates (1.5%) containing 300 μg mL−1 hygromycin B; artificial sea salts and NH4Cl were lowered to 15 g L−1 and 2 mM, respectively. Selection plates were incubated under 70 μmol photons m−2 s−1 fluorescent white light at 30 °C until transformants appeared (~ 4 weeks) and were ready for further processing (~ 5–6 weeks). Recovered transformants were sub-cultured once in 3 mL F2N medium containing 150 μg mL−1 Hygromycin B and subsequently maintained in F2N medium containing no antibiotic.
Microplate reader assays and calculation of fluorescence levels
The fluorescence of live cells was analysed using a FLUOstar OPTIMA microplate reader (BMG Labtech Ltd) in black-bottomed 96-well plates (Thermo Scientific) in triplicate. One hundred microlitre samples were used for the expression level analysis; for all other experiments, 200 μL samples were used. eGFP fluorescence was measured using filter settings appropriate to the maximal emission and excitation wavelengths for eGFP, 488 and 509 nm, respectively. F2N medium was used as a blank for all samples; average blank measurements (3n) were subtracted from all fluorescence measurements. Fluorescence measurements for each replicate were then normalised to its absorbance at a wavelength of 540 nm (A540 nm). Finally, average normalised wild-type fluorescence values (3n) were subtracted from all normalised fluorescence values to determine eGFP fluorescence or divided into normalised fluorescence values to determine fold changes.
For quantification of fluorescence as nanogram eGFP per 107 cells, normalised wild-type fluorescence-subtracted fluorescence measurements were converted to eGFP concentrations in nanograms per microlitre using an eGFP calibration curve. For the eGFP calibration curve (Online Resource 2), 100 μL eGFP standards were prepared in dH2O at the following concentrations (ng μL−1): 0, 0.01, 0.05, 0.1, 0.25, 0.5, 1, 2.5, 5 and 10. The A540 nm to cell mL−1 calibration curve was used to calculate the cell concentration in cells per microlitre at an A540 nm of 1, eGFP concentrations in nanograms per microlitre for each replicate were then divided by this value to determine the nanogram of eGFP per unit cell.
Immunoblotting and quantification of eGFP
Forty-millilitre cultures of N. gaditana were used to prepare whole cell protein extracts. Cells were harvested by centrifugation at 3000×g for 10 min at room temperature. For homogenization, approximately 100 mg of 0.1 mm zirconia beads (Biospec Products, USA) were added to the pelleted cells in addition to an equal volume (~ 150 μL) of SDS lysis buffer (200 mM NaCl, 25 mM EDTA, 0.5% (w/v) SDS, 200 mM Tris-Cl, pH 8.5). Cells were then lysed in a TissueLyser II tissue lyser (QIAGEN, Germany) for 2 × 30 s cycles at a frequency of 30 oscillations per second. Samples were heated to 95 °C in a heat block for 10 min, cooled briefly on ice, and then pelleted by centrifugation at 17,000×g for 10 min at 4 °C. The total protein content of the lysate was quantified using a Pierce bicinchoninic acid (BCA) protein assay (Thermo Scientific) with a bovine serum albumin (BSA) standard. Recombinant green fluorescence protein (rGFP; Sigma-Aldrich) was used to prepare protein standards for quantification of immunoblots. Ten micrograms of each protein sample was added to LDS loading buffer (Invitrogen) containing 50 mM DTT before heating to 70 °C for 10 min. Electrophoresis was carried out on 4–12% (w/v) gradient Bis-tris NuPAGE gels in MES buffer (Invitrogen) in a Novex XCell SureLock Mini Cell (Invitrogen) for 35 min at 200 V. An rGFP standard was loaded at 20, 40, 80,160 and 320 ng per well.
Blotting was performed as described previously (Berepiki et al. 2016). Membranes were incubated first with an anti-GFP antibody (N-terminal antibody produced in rabbit; Sigma-Aldrich) diluted to 1:1000 in blocking solution and then with goat anti-rabbit IgG (Agrisera) diluted to 1:1000 in blocking solution. Blots were then incubated with SuperSignal West Dura reagents (Thermo Scientific) and imaged using a C-DiGit Imaging system (LI-COR Biosciences, USA). For quantification of immunoblots, images were analysed using ImageJ software (National Institute of Health, Maryland, USA).
Construction of the nitrate reductase expression vector and generation of transgenic cell lines
eGFP expression level analysis of transgenic cell lines
The integration sites of chimeric DNA following electroporation-based transformation are largely randomly distributed within the genome and positional effects can affect transgene expression levels (Thompson and Gasson 2001; Zhang et al. 2014; Chen and Zhang 2016). Accordingly, the eGFP expression levels of all 20 of the pNR transformants were analysed to determine the average and the range of expression from the nitrate reductase promoter. NgNR1–20 and N. gaditana wild-type cultures were grown to the exponential phase in media containing either 5 mM sodium nitrate or 5 mM ammonium chloride as the sole nitrogen source to induce or repress expression, respectively.
eGFP fluorescence was analysed as described previously (Rasala et al. 2013). Fluorescence from eGFP was measured in a series of recombinant eGFP standards, the N. gaditana wild type and NgNR1–20 enabling estimation of eGFP content volumetrically and per cell. Qualitative eGFP fluorescence measurements were made quantitative using calibration curves as in Richards et al. (2003). A calibration curve for the eGFP standard (fluorescence vs ng μL−1) was generated in order to convert the fluorescence measurements of the samples from relative fluorescence to nanogram eGFP per microlitre (Online Resource 2). Additionally, a calibration curve of A540 nm to cell concentration in cells per millilitre (Online Resource 2) was used to calculate the cell concentration and subsequently an estimate of the concentration of eGFP 107 cells−1.
To confirm that the changes in eGFP fluorescence in the NgNR strains were due to regulation of the nitrate reductase promoter and not to other physiological responses due to the alteration of the nitrogen source from ammonium to nitrate, a control experiment was performed. An expression vector was constructed (pLCP) that was identical to pNR except that the nitrate reductase promoter was switched for an endogenous constitutive promoter (PLCP; Naga_100131g14) coding for a lipocalin protein. Transcriptomic data obtained in N. gaditana showed that native transcript levels of the lipocalin protein were unchanged under nitrogen deprivation: 464.18 reads per kilobase of transcript per million mapped reads (RPKM) on day 3 of growth in sodium nitrate and 436.61 RPKM on day 3 under nitrogen depletion (Corteggiani Carpinelli et al. 2014). Three transformants generated with the pLCP vector (NgLCP1–3) were grown to the exponential phase in 5 mM sodium nitrate and 5 mM ammonium chloride and analysed for eGFP fluorescence as described for the NgNR cultures (Online Resource 5). The wild-type subtracted normalised fluorescence measurements in NgLCP1–3 were variable between replicates as was observed for the NgNR strains. However, there was no significant difference between eGFP fluorescence in each replicate when the nitrogen source was altered (p = 0.44, Student’s t test). Hence, the control analysis with the NgLCP strains showed no significant effect on eGFP fluorescence levels when the nitrogen source was switched from ammonium to nitrate, confirming that the changes observed in the NgNR strains were due to regulation of the nitrate reductase promoter.
To confirm that eGFP was expressed, NgNR3 was further examined by immunoblot analysis (Online Resource 6). Protein samples were extracted from wild-type cells and NgNR3 grown to the exponential phase in media containing either 5 mM ammonium or 5 mM nitrate as the sole nitrogen source. eGFP was detected as a single band at 27 kDa in the nitrate-grown NgNR3 culture but was undetectable in both the N. gaditana wild-type and NgNR3 grown in ammonium. Quantification of the protein band in the nitrate-grown NgNR3 culture using the recombinant eGFP standards calibration curve determined a concentration of 115 ng of eGFP per 10 μg of total protein (approx. 1.15% of total protein).
Regulation of P NR in different nitrogen conditions
When NgNR3 was grown on urea, eGFP fluorescence was observed before the addition of nitrate on day 5, indicating that the presence of ammonium is required for full suppression of PNR in these conditions. The level of eGFP expression after the addition of nitrate to the urea-grown cells was similar to the ammonium-grown cells (equivalent to ~ 14.1% of the expression achieved in the presence of nitrate alone; Fig. 4b). As in the ammonium-grown cultures, there was no statistically significant difference between growth of the wild type and NgNR3 over the 12 days (p = 0.37, Student’s t test; Fig. 4e).
eGFP fluorescence in the nitrogen-depleted cells peaked on day 4, before the addition of nitrate on day 5, and was equivalent to 81.1% of the expression achieved in the presence of nitrate alone (Fig. 4c). This is the highest fluorescence level observed in this series of experiments, further indicating that the presence of ammonium is required for full suppression of expression from PNR under these conditions. The absence of any nitrogen source until the addition of nitrate on day 5 resulted in low levels of growth up until this point. However, in these conditions, growth of NgNR3 was not statistically significantly different from the wild type (p = 0.37, Student’s t test; Fig. 4f). Furthermore, a comparison of the growth after the addition of nitrate on day 5 to that in the ammonium (nitrogen source in standard F2N medium; Kilian et al. 2011) grown cultures showed no significant difference for both the wild type and NgNR3 (p = 0.31 and 0.26, respectively, Student’s t test; Fig. 4d, f).
Long-term stability of NgNR3
Systems for inducible expression are of great importance, allowing for the temporal expression of toxic proteins and potentially for the control of heterologous protein expression in large-scale commercial growth operations. The potential of the promoter of the endogenous nitrate reductase gene of N. gaditana to meet these demands was explored in this study.
The eGFP fluorescence-based analysis of expression levels over 20 strains transformed with the pNR constructed (NgNR1–20) allowed calculation of an average eGFP expression level of 443.5 ± 330.1 SD ng eGFP per 107 cells in the presence of nitrate and suppression of expression to undetectable levels in ammonium (Fig. 3a). Assuming a cellular protein content of approximately 3 pg protein cell−1 (Fábregas et al. 2002), the average level of eGFP expression in the presence of nitrate in picogram per cell (4.435 × 10−2; Fig. 3a) is equivalent to approximately 1.48 ± 1.10% SD of total protein. This is comparable to expression systems established in the model organism C. reinhardtii in which heterologous protein production in the chloroplast typically ranges from 1 to 5% of total protein (Manuell et al. 2007; Rasala et al. 2011; Almaraz-Delgado et al. 2014). Using the nitrate reductase promoter to drive expression of eGFP, an average fold change in fluorescence of 4.2 was achieved (Fig. 3b). Many factors influence the ability to detect fluorescent proteins in a cellular context, such as background auto-fluorescence, the strength of the promoter used to drive expression, and rates of mis-folding and successful maturation of the fluorescent protein. In a previous study, expression of a widely used Chlamydomonas codon-optimized GFP (CrGFP) in C. reinhardtii under the control of a robust promoter (hsp70/rbcs2) yielded a comparable fold change in fluorescence of 2.8 (Rasala et al. 2013). Although the pattern of suppression and induction was conserved across the 20 NgNR strains, there was a large degree of variability in expression levels in the PNR-induced conditions (nitrate-grown). This variability is likely to be the result of random integration of the expression cassette and positional effects within the genome on expression, which is commonly observed in microbes transformed with random integration-based transformation procedures such as electroporation (Thompson and Gasson 2001; Zhang et al. 2014; Chen and Zhang 2016). The fluorescence-based approach of quantifying expression using calibration curves presented here (Fig. 3) provides a quantitative method for rapidly analysing multiple strains with relative ease, enabling cell lines with the desired level of expression to be identified.
The series of experiments exploring nitrogen regulation (Fig. 4) shed light on the ability of the nitrate reductase promoter to regulate expression under a variety of nitrogen conditions. Transcript levels of the NR gene of the eukaryotic alga Dunaliella tertiolecta have been shown to be supressed in the presence of ammonium and induced in the presence of nitrate; however, in the presence of both ammonium and nitrate the transcript was fully supressed (Song and Ward 2004). This observation at the transcript level in D. tertiolecta was not observed at the protein level in NgNR3 as eGFP expression was seen in the combined presence of ammonium and nitrate (Fig. 4a). Therefore, removal of residual ammonium before induction of PNR, which could be costly and impractical on a large scale, may not be necessary for exploitation of this system in a biotechnological context. However, expression was lower than when nitrate was the sole source of nitrogen. When grown on urea, expression of eGFP was observed before the addition of nitrate, suggesting the strong effects of ammonium on expression may be required if total suppression is required (Fig. 4b) (Forde 2000; Galván and Fernández 2001; Llamas et al. 2002; Fernández and Galván 2008). The strong expression of eGFP in the nitrogen-deplete cultures before addition of nitrate suggests that PNR is also induced by nitrogen deprivation in N. gaditana. Transcript levels of genes involved in nitrogen uptake, scavenging mechanisms and assimilation, including nitrate reductase, have been reported to increase under nitrogen deprivation in other algae as a scavenging mechanism (Alipanah et al. 2015). However, expression of NR is not induced by nitrogen deprivation in D. tertiolecta, which highlights the diversity in the regulation of the NR gene in eukaryotic algae. Expression from PNR under nitrogen-depletion could offer another means of induction for industrial application whereby the nitrogen concentration of the growth media could be set such that cells grow to a desired density before depletion of nitrogen and concurrent onset of expression from PNR.
Several key studies in Nannochloropsis spp. in recent years have identified the genus as one of the best candidate biofuel feedstock strains for advanced genome editing techniques (Kilian et al. 2011; Radakovits et al. 2012; Jinkerson et al. 2013; Ajjawi et al. 2017). This was illustrated most clearly by the work of Ajjawi et al. (2017), in which the lipid content of N. gaditana was doubled through the combined use of a range of the available technologies; namely, RNA seq, the use of annotated genomic sequences, CRISPR technology and RNAi. These advances highlight Nannochloropsis spp. as worthy species for continued biotechnological development and further expansion of the available genetic tools. Interestingly, genes involved in nitrogen assimilation in this high-lipid mutant (including a nitrate transporter) were downregulated. This is distinct from the wild-type N. gaditana response to nitrogen deprivation, in which an increased accumulation of lipid is concurrent with an upregulation of genes involved in nitrogen assimilation (Ajjawi et al. 2017).
As has been shown in other algae, the endogenous promoter of the nitrate reductase gene was able to efficiently regulate expression of heterologous protein in N. gaditana (Wang et al. 2004; Poulsen and Kröger 2005; Li et al. 2007; Schmollinger et al. 2010; Niu et al. 2012; von der Heyde et al. 2015). Strong expression and suppression was possible in the sole presence of nitrate and ammonium, respectively. Furthermore, the ability to fully supress expression from the NR promoter through continuous growth on ammonium chloride and then induce protein production through addition of sodium nitrate, without the removal of ammonium, is a useful feature that will enable future applications requiring precise temporal induction of protein expression at a specific point in the growth phase while also maintaining growth rates. Induction and suppression of PNR-driven eGFP expression was greatly affected by the nitrogen source of the growth media, presenting a variety of ways to control expression; accordingly, nitrogen sources should be user-defined on the basis of the intended use of the promoter. The establishment and validation of the in situ eGFP reporter system and ability to temporally control transgene expression with the endogenous nitrate reductase promoter are valuable additions to the advancement of sophisticated genetic engineering technologies that will enable further development of the oleaginous alga N. gaditana as a model organism for biotechnology.
The authors would like to thank The Natural Environment Research Council and the SPITFIRE DTP for funding this research.
Compliance with ethical standards
Conflict of interest
The authors declare that they have no competing interests.
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