Báo cáo khoa học: A new molecular tool for transgenic diatoms Control of mRNA and protein biosynthesis by an inducible promoter–terminator cassette docx

Genetic transformation meth-ods are at present available for the diatom species Keywords Cylindrotheca fusiformis; diatom transformation; green fluorescent protein GFP; inducible gene ex

Control of mRNA and protein biosynthesis by an inducible

promoter–terminator cassette

Nicole Poulsen1,2and Nils Kro¨ger1,2,3

1 Biochemie I, Universita¨t Regensburg, Germany

2 School of Chemistry & Biochemistry, 3 School of Materials Science & Engineering, Georgia Institute of Technology, Atlanta, GA, USA

Diatoms (Bacillariophyceae) are a group of unicellular

algae that are of enormous ecological importance,

being responsible for about 40% of the primary

bio-logical production in the oceans [1,2] In addition to

their role in global carbon cycling, diatoms have

recently attracted interdisciplinary interest because of

their extraordinary ability to produce intricately

shaped, nanostructured silica as their cell wall material

[3–5]

In contrast to the wide interest in diatom biology, genetic manipulation of diatoms is still in its infancy With the recent completion of the Thalassiosira pseu-donana genome project [6] and establishment of an expressed sequence tag (EST) databank for Phaeod-actylum tricornutum [7], there is now an urgent demand for genetic tools to analyze the function of diatom genes in vivo Genetic transformation meth-ods are at present available for the diatom species

Keywords

Cylindrotheca fusiformis; diatom

transformation; green fluorescent protein

(GFP); inducible gene expression; nitrate

reductase

Correspondence

N Kro¨ger, School of Chemistry &

Biochemistry, Georgia Institute of

Technology, 770 State St, Atlanta,

GA 30332-0400, USA

Fax: +1 404 894 7452

Tel: +1 404 894 4228

E-mail: nils.kroger@chemistry.gatech.edu

Website: http://www.chemistry.gatech.edu/

faculty/kroger/

Notes

Nucleotide sequence data for cffcpA-1A and

CfNR are available in the GenBank database

under accession numbers DQ060240 and

DQ060241

(Received 25 March 2005, revised 7 May

2005, accepted 11 May 2005)

doi:10.1111/j.1742-4658.2005.04760.x

Research in diatom biology has entered the postgenomic era since the recent completion of the Thalassiosira pseudonana genome project How-ever, the molecular tools available for genetic manipulation of diatoms are still sparse, impeding the functional analysis of diatom genes in vivo Here

we describe the first method for inducible gene expression in transgenic diatoms This method uses a DNA cassette containing both promoter (Pnr) and terminator (Tnr) elements derived from the nitrate reductase gene of the diatom Cylindrotheca fusiformis By using green fluorescent protein (gfp) cDNA as a reporter gene, it is demonstrated that gene expression under the control of the Pnr⁄ Tnr cassette is switched off when cells are grown in the presence of ammonium ions and becomes switched on within

4 h when cells are transferred to medium containing nitrate Incubating cells in nitrogen-free medium switches on transcription of the gfp gene, yet gfp mRNA does not become translated into protein This block on trans-lation is released by the addition of nitrate, resulting in rapid onset of GFP production with a drastically reduced delay time of only 1 h Altogether we have demonstrated that the Pnr⁄ Tnr cassette enables inducible gene expres-sion and control of both the level and timing of mRNA and protein expression in transgenic diatoms

Abbreviations

BLE (ble), bleomycin binding protein (gene); fcp, fucoxanthin chlorophyll a ⁄ c binding protein gene; egfp (egfp), enhanced green fluorescent protein (gene); NR, nitrate reductase; Pd, promoter of frua3 gene; Pfcp (Tfcp), promoter (terminator) of fucoxanthin chlorophyll a ⁄ c binding protein gene; Pnr (Tnr), promoter (terminator) of C fusiformis nitrate reductase gene; SOEing, splicing by overlap extension.

P tricornutum [8], Cylindrotheca fusiformis [9],

Cyclo-tella cryptica and Navicula saprophila [10] So far, in

all but one case, only constitutive expression of

intro-duced genes has been achieved The one exception

involved expression of a green fluorescent protein

(GFP) fusion protein in P tricornutum, under control

of the promoter fcpA, derived from a gene encoding

a fucoxanthin chlorophyll a⁄ c binding protein [8] In

this instance, expression of the GFP fusion protein

was repressed after a 7 day incubation in the dark

and induced by 24 h exposure of the cells to light

[11] This method is not generally applicable for

stud-ies on diatom cell biology as diatom growth is totally

inhibited in the dark For example, analyzing the

effect of introduced proteins or RNA-mediated gene

interference only at certain developmental stages (e.g

cell division) requires regulated expression of

intro-duced genes within a much shorter time scale

There-fore, to study diatom biology using molecular genetic

techniques, promoters need to be identified that

enable rapid and tightly controlled expression of

genes in transgenic diatoms

Previous physiological studies in diatoms have

shown that the activity of nitrate reductase (NR), the

rate-limiting enzyme in nitrogen assimilation, is

regula-ted by the nitrogen source present in the medium NR

activity is suppressed by ammonium and induced when

ammonium is replaced by nitrate [12,13] In the green

algae Chlamydomonas reinhardtii [14,15], Chlorella

vulgaris [16] and Dunaliella tertiolecta [17],

ammo-nium-dependent suppression of NR activity is due to

down-regulation of NR gene expression as well as

post-transcriptional regulation These studies have

prompted us to speculate that the promoter of the

diatom NR gene may be a suitable molecular genetic

tool for regulating transgenic protein expression in

diatoms However, the unexpected discovery by

gen-ome sequence analysis of a complete urea cycle in the

diatom T pseudonana appeared to imply that a more

complex regulatory network may control nitrogen

metabolism in diatoms, possibly also involving the NR

step [6] Therefore, a thorough analysis was required

of the applicability of diatom NR promoters to drive

inducible gene expression in transgenic diatoms

Only recently the first two sequences of diatom NR

genes have become available from T pseudonana [6]

and P tricornutum [18], yet in neither organism has

NRgene expression been analyzed as a function of the

nitrogen source in the medium In this study we have

isolated the NR gene (CfNR) from a genomic DNA

library of the diatom C fusiformis and analyzed CfNR

levels in response to different nitrogen sources Using

GFP as reporter protein, we have demonstrated that

the 5¢-UTR and 3¢-UTR of CfNR allow control of both the timing and level of expression of introduced genes in transgenic C fusiformis

Results

Increasing the efficiency of C fusiformis transformation

Previously, DNA fragment Pd, from the 5¢-UTR of the frua3 gene, was the only established promoter in

C fusiformis to drive expression of the selection mar-ker protein bleomycin-binding protein (BLE), as well

as other introduced proteins [9] However, only mod-erate numbers of transformants and relatively low lev-els of heterologous protein expression were obtained [9] In contrast, promoter fcpA from a gene encoding

a fucoxanthin chlorophyll a⁄ c binding protein (fcp) has been successfully used to obtain high expression levels of foreign proteins in transgenic P tricornutum [19] This promoter is constitutively active in light but not functional in C fusiformis (N Kro¨ger, unpub-lished observation) Therefore, the promoter of a

C fusiformis fcp gene has been isolated and tested for its applicability in C fusiformis transformations Prim-ers were designed based on a C fusiformis fcp cDNA sequence (cffcpA-3) available from the NCBI database (see Experimental procedures) and used to amplify

a 441-bp fragment from C fusiformis genomic DNA This DNA fragment was used as a probe for screening

a C fusiformis genomic DNA library From a phage reacting positive in this screen, the sequence of a com-plete fcp gene including 5¢-UTR and 3¢-UTR was determined This gene contained no introns and sur-prisingly was not identical with the cffcpA-3 cDNA sequence, but perfectly matched the cffcpA-1A cDNA sequence (GenBank accession number AY125580) The two sequences share 93% sequence identity at the nucleotide level

To generate an fcp promoter-based expression vector for C fusiformis termed pCfcp, 1624 bp of the 5¢-UTR (termed Pfcp) and 504 bp of the 3¢-UTR (termed Tfcp) from the cffcpA-1A genomic DNA were cloned into pBluescript flanking a short region containing three unique restriction sites (EcoRV, XbaI, NotI), allowing easy insertion of genes The ble gene, which confers resistance to the antibiotic zeocin, was ligated with pCfcp, generating pCfcp-ble This plasmid was used for

C fusiformistransformation by microparticle bombard-ment, yielding typically 36 ± 4 zeocin-resistant trans-formants per 107cells (using 1 lg plasmid), whereas an average of only 11 ± 1 zeocin-resistant transformants per 107cells were obtained using 1 lg plasmid pPd-ble

(the transformant numbers represent averages from

three transformation experiments) Thus, C fusiformis

transformation using the new plasmid pCfcp-ble was

3–4 times more efficient than the previous method

Cloning of the NR gene from C fusiformis and

mRNA expression studies

Degenerate primers corresponding to the highly

conserved NR motifs W-W-Y-K-P-E⁄ D-Y ⁄ F and

W-N-L-M-G-M were used in RT-PCR yielding a

375-bp product which exhibited 69% and 77% sequence

identity with the corresponding NR sequence regions

from T pseudonana and P tricornutum, respectively

Screening of the C fusiformis genomic DNA library,

using the 375-bp PCR product as a probe, led to the

identification of a phage clone that contained the

entire C fusiformis NR gene (CfNR) on a single 5.4-kb

BamHI DNA fragment RACE PCR was used to

determine the 5¢ end of the CfNR cDNA, allowing

unequivocal identification of the gene’s start codon

On the basis of these data, the CfNR gene is made up

of 2619 bp of intron-less sequence encoding a 873-amino acid polypeptide which exhibits 69% and 72% sequence identity with the predicted polypeptide sequences of the NR genes from T pseudonana and

P tricornutum, respectively (Fig 1)

To investigate the effect of the nitrogen source on expression of the CfNR gene, C fusiformis cells were preconditioned for 2 weeks in medium containing ammonium chloride as the sole nitrogen source (ammo-nium medium) After being washed with nitrogen-free medium, the cells were transferred to medium contain-ing ammonium (NH4+), nitrate (NO3), a 1 : 1 mixture

of ammonium and nitrate (NH4+⁄ NO3 ) or kept in nitrogen-free medium (–N) After an incubation period

of 24 h, NR expression was monitored by RT-PCR analysis (Fig 2) The CfNR gene was expressed both in the presence of nitrate and under conditions of nitrogen starvation, but not in ammonium-containing medium Ammonium proved to be an inhibitor of CfNR exsion, as shown by the lack of CfNR mRNA in the pres-ence of equal molar amounts of nitrate and ammonium (Fig 2) These results demonstrate that the CfNR gene

Fig 1 Alignment of NR polypeptide sequences from diatoms The sequence alignment was performed using CLUSTALW [40] C.f., Cylindroth-eca fusiformis NR (this study); P.t., Phaeodactylum tricornutum NR (GenBank accession number AY579336); T.p., Thalassiosira pseudonana

NR [6] Amino acids identical with the CfNR polypeptide sequence are indicated by asterisks The CfNR polypeptide exhibits the typical NR domain structure containing the molybdopterin domain (aa 54–295), dimerization domain (aa 321–447), heme domain (aa 519–592), FAD domain (aa 623–728) and NADH domain (residues 744–858) [27] A unique 17-amino-acid insertion in the molybdopterin-binding domain iden-tified in the two other diatom NR genes [18] is also conserved in CfNR (aa 211–227).

expression can be easily switched on and off by varying

the nitrogen source in the medium To evaluate the

applicability of the CfNR gene’s regulatory elements to

drive inducible expression of foreign proteins in

trans-genic diatoms, a GFP-based reporter gene system was

established

Construction of a vector for inducible gene

expression

A chimeric gene was constructed consisting of the egfp

coding sequence [20] flanked by 775 bp of the 5¢-UTR

(termed Pnr) immediately upstream of the start ATG

of the CfNR gene and 571 bp of the 3¢-UTR (termed

Tnr) immediately after the stop codon The chimeric

gene was cloned into pCfcp-ble yielding plasmid

pNICgfp (Fig 3A) The plasmid DNA (3 lg) was

introduced into C fusiformis by microparticle

bom-bardment, and transformants were selected on

zeocin-containing plates From the over 100 zeocin-resistant

clones obtained, 33 clones were analyzed for GFP

expression by fluorescence microscopy, of which 22

clones were positive The fluorescence intensities of

eight of these clones were quantified by fluorimetry,

using excitation at 485 nm and monitoring emission at

510 nm Owing to the chlorophyll content, C

fusifor-mis wild-type cells exhibited noticeable fluorescence in

these measurements, yet fluorescence intensities of

dif-ferent GFP-expressing transformants were 7- to

50-fold higher than in wild-type cells (Fig 3B) Variation

in GFP fluorescence intensities between different

transformant clones has previously been observed in

P tricornutumexpressing GFP or GFP fusion proteins

under the control of the constitutive fcp promoter [8,19] As the introduced genes become randomly integrated into the diatom’s genome [8], the variation

in GFP expression levels may result from differences

in copy numbers or location of the introduced genes within the genome Clone 31 exhibited the highest intensity of GFP fluorescence and therefore was cho-sen for further analysis In growth medium containing ammonium as the sole nitrogen source, the

fluores-A

B

C

Fig 3 Structure of transformation plasmid pNICgfp and analysis of GFP expressing C fusiformis transformants (A) Restriction map of the part of plasmid pNICgfp containing the egfp gene flanked by the Pnr ⁄ Tnr cassette and ble gene flanked by cffcpA-1A promoter (Pfcp) and terminator (Tfcp) sequences (K, KpnI; H, HindIII;

E, EcoRI; N, NotI; E105, Eco105I; E5, EcoRV; S, SacI) (B) Fluores-cence intensity (excitation 485 nm, emission 510 nm) of C fusifor-mis wild-type and transformant clones (C#) expressing GFP Cell concentration was 1· 10 7 ÆmL)1 for each clone (C) GFP fluores-cence intensity (excitation 485 nm, emission 510 nm) of transform-ant C31 in different growth media, containing nitrate (1.5 m M

KNO3), ammonium (1.5 m M NH4Cl) or mixtures of nitrate and ammonium as nitrogen source (nitrate concentration was 1.5 m M , ammonium concentrations were: Q10, 0.15 m M ; Q25, 0.06 m M ; Q50, 0.03 m M ; Q100, 0.0015 m M ).

Fig 2 Influence of nitrogen source on the expression of CfNR

mRNA C fusiformis wild-type cells were grown in ammonium

medium and then transferred to different medium containing nitrate

(NO 3–), ammonium (NH 4+), a 1 : 1 mixture of nitrate and

ammo-nium (NO 3–⁄ NH 4+) or lacking any nitrogen (– N) After a 24-h

incu-bation period, RNA was isolated from each sample and RT-PCR

was performed to analyze CfNR mRNA expression (NR) As a

posit-ive control RT-PCR analyses for the constitutposit-ively expressed

cffcpA-1A mRNA (fcp) were performed using the same RNA

prepa-rations.

cence intensity was slightly above wild-type levels (not

shown), yet dramatically increased when ammonium

was replaced by nitrate (Fig 3C) These results show

that the Pnr⁄ Tnr cassette in plasmid pNICgfp retains

the inducible property of the regulatory sequences that

drive expression of the CfNR gene

As ammonium acted as an inhibitor of CfNR

expres-sion (Fig 2), we investigated the possibility of

control-ling the level of GFP expression by growing Clone

31 in medium containing mixtures of ammonium and

nitrate At relative molar concentrations of nitrate vs

ammonium of 50 (Q50) and 100 (Q100), GFP

fluores-cence levels were virtually indistinguishable from

fluor-escence levels of cells incubated in medium containing

only nitrate (Fig 3C) However, at molar ratios of

nitrate to ammonium of 10 (Q10) and 25 (Q25), the

lev-els of GFP fluorescence were 44% and 83%,

respect-ively, of the fluorescence levels of nitrate-grown cells

Thus, by adjusting appropriate relative concentrations

of ammonium and nitrate, it is possible to

down-regu-late, rather than completely shut off, the expression of

genes that are under control of the Pnr⁄ Tnr cassette

Decoupling of transcription and translation

of gfp mRNA

To further evaluate the properties of the Pnr⁄ Tnr

expression cassette, Clone 31 cells preconditioned in

ammonium medium were subjected to nitrogen

starva-tion, and gene expression was monitored by RT-PCR

In agreement with the result obtained with wild-type

cells (Fig 2, lane –N), expression of both CfNR and

gfp genes was found to be switched on in the

trans-formant (Fig 4B) Surprisingly, when fluorimetry (not

shown) and fluorescence microscopy were used, no

GFP fluorescence was detected in Clone 31 cells

(Fig 4A), indicating the absence of functional GFP

Western blot analysis confirmed that GFP was indeed

absent from nitrogen-starved Clone 31 cells (Fig 4B),

ruling out the possibility that GFP was present in a

nonfluorescent form After the addition of nitrate,

GFP fluorescence developed in Clone 31 cells

(Fig 4A), demonstrating that inhibition of GFP

pro-duction in nitrogen-starved cells was reversible

Alto-gether these results indicate that gfp mRNA did not

become translated until nitrate was present, implying

that, in nitrogen-starved cells, protein production from

genes flanked by the NR promoter (Pnr) and

termina-tor (Tnr) is controlled at the post-transcriptional level

On the basis of these results, we assumed that

decoupling of mRNA and protein expression in

nitro-gen-starved cells may provide a useful tool to obtain

control over the timing of gene expression, as the built

up pool of transgenic mRNA may very rapidly become translated into protein after the addition of nitrate To investigate this, we analyzed by fluorimetry the kinetics

of GFP production in Clone 31 cells in nitrate medium after preconditioning in ammonium medium and nitro-gen-free medium, respectively After transfer of ammo-nium-preconditioned cells to nitrate medium, a lag phase of 5 h was observed before GFP expression became noticeable Beyond this time, fluorescence lev-els increased with a doubling time of 1.5 h (Fig 5A) RT-PCR analysis demonstrated that gfp mRNA expression started 4 h after the transfer of the cells to nitrate medium, thus preceding the onset of GFP fluorescence by about 2 h Cells preconditioned in nitrogen-free medium exhibited a comparable rate of increase of GFP fluorescence (2 h doubling time) after

A

B

Fig 4 Influence of nitrogen source on mRNA expression and the formation of GFP protein (A) Fluorescence images of C fusiformis Clone 31 cells in nitrogen-free medium (–N) and in nitrate medium (NO 3–) Each micrograph represents an overlay of a transmission light microscopy image and two different fluorescence images The green color shows GFP fluorescence and the red color depicts chloroplast autofluorescence (bar, 10 lm) (B) Comparison of gfp mRNA expression and GFP protein expression in nitrate medium (NO3– ), ammonium medium (NH4+ ) and nitrogen-free medium (–N) The bottom row shows a GFP-specific western blot from total extracts of Clone 31 cells after 24 h of incubation in the indicated media The rows above show the results from RT-PCR analysis for gfp mRNA (gfp) expression in Clone 31 cells from the same three cultures As controls, expression of CfNR mRNA (NR) and the con-stitutive cffcpA-1 A mRNA (fcp) were monitored by RT-PCR using the same RNA preparations.

transfer to nitrate medium However, the lag phase

for the onset of GFP fluorescence was drastically

reduced to only 1 h, which probably corresponds to

the time required for the extremely slow process of

GFP chromophore formation [21] Therefore, addition

of nitrate to cells preconditioned on nitrogen-free

medium appears to enable virtually instantaneous

induction of protein expression from genes that are

controlled by the Pnr⁄ Tnr cassette

Discussion

In this study, we have isolated from a C fusiformis

genomic library an fcp gene (cffcpA-1A) and a nitrate

reductase gene (CfNR) From these genes 5¢-UTRs

(pro-moters) and 3¢-UTRs (terminators) were used to

construct a transformation vector for inducible gene

expression in C fusiformis Flanking the zeocin resist-ance gene ble by promoter (Pfcp) and terminator (Tfcp) regions from cffcpA-1A improved the transformation efficiency for C fusiformis about fourfold over previ-ously used transformation vectors Presumably, the increased transformation rate is due to the exceptional strength of the fcp promoters [22] Therefore, more BLE protein may be produced in C fusiformis transformants

by using a Pfcp-based vector compared with the previ-ously used Pd-containing vectors, which allows more transformants to grow using extremely high zeocin con-centrations (1 mgÆmL)1) required for suppression of

C fusiformis wild-type growth In future the promoter Pfcp may be a useful tool for generating higher levels

of expression of other transgenic proteins

With the CfNR gene sequence in hand, we were able

to demonstrate by RT-PCR that CfNR expression can

be simply regulated at the transcriptional level by vary-ing the nitrogen source in the medium (Fig 4) Regu-lation of the NR gene transcript in C fusiformis is similar to the green alga C reinhardtii, as, in both organisms, NR mRNA production is switched off in the presence of ammonium and induced by nitrate or nitrogen starvation [23–25] This regulatory pattern is preserved in the Pnr⁄ Tnr cassette driving gfp expres-sion in C fusiformis cells that have been transformed using the pNICgfp plasmid Remarkably, induction of Pnr⁄ Tnr-driven gfp expression has different outcomes depending on whether nitrate or nitrogen starvation is used as the inducer Biosynthesis of GFP is inhibited

in nitrogen-free medium, and protein is only produced

in the presence of nitrate (Fig 4B) As the gfp mRNA coding region is a highly unlikely target for post-tran-scriptional regulation in a diatom, we assume that this effect is mediated by regions in the CfNR-derived 5¢-UTR or 3¢-5¢-UTR of the gfp mRNA Nutrient-depend-ent, post-transcriptional regulation of eukaryotic gene expression mediated by the UTRs of mRNA molecules

is well characterized for iron metabolism in mammals [26], and recently evidence has been presented that the stability of NR mRNA in the green alga Chlorella vul-garis is mediated via the 5¢-UTR [27] Therefore, we speculate that the UTRs in the CfNR mRNA may contain target sites for nitrate-dependent regulators of translation or mRNA stability Interestingly, in C fusi-formis, mRNA expression of AMT (encoding ammo-nium transporter proteins) and NAT (encoding nitrate transporter proteins) genes becomes strongly up-regu-lated when cells are transferred from ammonium medium to –N medium [28,29], suggesting that the expression of different proteins involved in nitrogen metabolism may be controlled by the same mechanism However, it is at present unknown if nitrogen-starved

A

B

Fig 5 Kinetics of gfp mRNA and GFP protein expression in C

fusi-formis (A) Development of fluorescence intensity in Clone 31 (C31)

and wild-type (wt) cells Cells were preconditioned in ammonium

medium and then transferred either directly to nitrate medium

(NO3– ) or incubated for 24 h in nitrogen-free medium before nitrate

was added (–N ⁄ NO 3–) The x-axis indicates the time after addition

of nitrate (B) RT-PCR analysis of gfp mRNA expression in Clone 31

cells Cells were preconditioned in ammonium medium and then

directly transferred to nitrate medium Hours indicate the time after

addition of nitrate At each time point RT-PCRs were performed

using primers specific for gfp mRNA (gfp) and the constitutively

expressed cffcpA-1A mRNA (fcp), respectively.

cells synthesize AMT and NAT protein or if

transla-tion of AMT and NAT mRNAs is inhibited, as we

have demonstrated for gfp mRNA

Exploiting the ability of the Pnr⁄ Tnr cassette to

decouple the transcription of a chosen gene from its

translation into protein represents a valuable

experi-mental tool The subsequent addition of nitrate enables

rapid protein production from introduced genes

Furthermore, the addition of both nitrate and

appro-priate concentrations of ammonium allows, within

lim-its, the control of the amount of induced protein The

observed lag phase of 1 h for Pnr⁄ Tnr-controlled

pro-tein expression most likely represents an underestimate

of the speed of induction, because de novo formation

of fluorescent GFP from the unfolded polypeptide is a

very slow process, exhibiting a half time of 84.3 min

[21] The following observation is consistent with this

assumption In a Saccharomyces cerevisiae

transform-ant carrying the gfp gene under control of the GAL1

promoter, GFP fluorescence starts 2.5 h after galactose

addition [30], yet GAL1-controlled expression of other

S cerevisiae proteins already occurs < 10 min after

induction with galactose [31] Therefore, we expect that

the experimental methods developed in the present

work should allow analysis of the role of diatom

pro-teins in short-lived cellular processes such as

cyto-kinesis and valve and girdle band formation which are

completed in less than 1 h In future, analysis of cell

division or valve formation in C fusiformis

transform-ants carrying a gene of interest under control of the

Pnr⁄ Tnr cassette may be performed as outlined in the

following A transformant grown in ammonium

med-ium will be starved of silicic acid to arrest the cells at

the G1⁄ S boundary [32] After subsequent incubation

in nitrogen-free medium to induce mRNA expression,

silicic acid will be added to initiate cell division and

sil-ica formation Concomitantly with or at appropriate

times after silicic acid replenishment, nitrate will be

added to induce instantaneous expression of the

pro-tein of interest, allowing observation of the propro-tein’s

influence on the progression of the cell cycle and the

silica biogenesis As the regulation of NR expression

appears to be very similar throughout the diatom

realm [12,13], the Pnr⁄ Tnr cassette of C fusiformis

rep-resents a paradigm for establishing inducible gene

expression systems also in other diatom species

Experimental procedures

Culture conditions

C fusiformis was grown as described previously [33] under

constant light and in artificial seawater medium containing

1.5 mm KNO3 as sole nitrogen source (nitrate medium) Where indicated, nitrate was not included in the medium (nitrogen-free medium) or replaced by 1.5 mm NH4Cl (ammonium medium) or a mixture of 0.75 mm NH4Cl + 0.75 mm KNO3(ammonium + nitrate medium)

Cloning of the cffcpA-1A gene

To generate a selection marker for use in C fusiformis, we first cloned the fcp gene and used its promoter and termina-tor sequences to drive expression of the zeocin resistance gene ble To this end, C fusiformis genomic DNA was extracted [33] and gene-specific oligonucleotides (sense: fcp1 5¢-AGAGCGAACTTGGTGCCCAG-3¢; antisense: fcp2 5¢-GCACGTCCGTTGTTCAATTC-3¢) were designed based

on a C fusiformis fcp precursor cDNA sequence available from the NCBI database (cffcpA-3; GenBank accession number AY125583) Thirty cycles of PCR produced a

441-bp DNA fragment, which was cloned into the pGEMT vector (Promega, Madison, WI, USA) and sequenced The sequence obtained matched perfectly the database sequence

To screen the C fusiformis genomic DNA library (in kEMBL3) [33] the 441-bp fcp DNA fragment was used as a probe after labeling with digoxygenin (Roche, Mannheim, Germany) according to the manufacturer’s instructions Phage DNA of one positive clone was analyzed by diges-tion with different restricdiges-tion enzymes and subsequent Southern blotting using the same probe as above Two BamHI-digested DNA fragments (1.9 kb and 1.46 kb) that hybridized to the probe were cloned into the BamHI site of pUC18 and sequenced, resulting in pUC18⁄ fcp1.9kb (cover-ing 278 bp of fcp cod(cover-ing sequence preceded by 5¢-UTR) and pUC18⁄ fcp1.46kb (covering 357 bp of the fcp coding sequence followed by 3¢-UTR)

Construction of vector pCfcp for constitutive gene expression

The 1.9-kb insert of the pUC18⁄ fcp1.9kb plasmid was sub-cloned into the KpnI–PstI sites of pBluescriptII SK+, gen-erating pBluescript⁄ fcp1.9kb To introduce a cloning site between the 5¢-UTR and 3¢-UTR of the fcp gene, a short 165-bp fragment of the fcp 5¢-UTR was amplified by PCR from pUC18⁄ fcp1.9kb using the sense primer 5¢-GAT CTTTGCTACGTACGAACG-3¢ and the antisense primer 5¢-GCTCTAGAGATATCTAGTCTTTGTGATAAAGAAA ATTATG-3¢ The resulting 165-bp PCR product contained

an Eco105I restriction site (underlined) and an EcoRV (bold) and XbaI (italic) restriction site, which were both introduced by the antisense primer The PCR product, which covered part of the 5¢-UTR starting 12 bp upstream

of the start ATG, was then cloned into the Eco105I–XbaI sites of pBluescript⁄ fcp1.9kb, generating pBluescript⁄ fcp1.6kb, which covers bp )12 to )1613 upstream of the fcp gene’s start ATG The fcp terminator was

ampli-fied by PCR from pUC18⁄ 1.46kb using the sense

pri-mer 5¢-GAATGCGGCCGCATTGCTTGTTGAGAAATA

GG-3¢, which introduced a NotI restriction site

(under-lined) and the antisense primer 5¢-CGGAGCTCTGG

AAGCATGAAGTACTGCCA-3¢, which introduced a SacI

restriction site (underlined) The 524-bp PCR product was

digested with NotI and SacI and cloned into the NotI⁄ SacI

sites of pBluescript⁄ fcp1.6kb, generating the C fusiformis

expression vector pCfcp Genes to be inserted into the

pCfcp vector require the sequence 5¢-ATCAAAACAACC

AAA-3¢ immediately upstream of the start codon because

vector pCfcp lacks bp)1 to )12 of the promoter

Construction of zeocin resistance plasmid

pCfcp-ble

The ble gene [34] (GenBank accession number X52869) was

amplified from pZEOSV (Invitrogen, Carlsbad, CA, USA)

by PCR using sense primer 5¢-ATCAAAACAACCAAAA

TGGCCAAGTTGACCAGTGC-3¢ and antisense primer

5¢-GAATGCGGCCGCTCAGTCCTGCTCCTCGGCCAC-3¢,

which introduced a NotI restriction site (underlined) The

resulting 386-bp PCR product was digested with NotI and

cloned into the EcoRV⁄ NotI site of pCfcp to generate

pCfcp-ble

Cloning of the CfNR gene

Extraction of poly(A)-rich RNA from C fusiformis and

synthesis of cDNA coupled to oligo(dT)25magnetic beads

(Dynal Biotech, Hamburg, Germany) was as described [9]

Degenerate oligonucleotides NR1 (5¢-TGGTGGTAYAAR

CCNGANT-3¢) and NR2 (5¢-CATNCCCATNARRTTC

CA-3¢) were designed based on the alignment of the

deduced amino-acid sequences of nine NR genes from algae

and higher plants The cDNA was used as template for 35

cycles of PCR amplification (15 s 94
C, 15 s 52
C, 30 s

72
C) resulting in a 380-bp DNA product which was

cloned into pGEMT vector (Promega) and sequenced This

380-bp DNA fragment of the CfNR gene was labeled with

digoxigenin and used to screen a C fusiformis genomic

DNA library as described above From a positive phage

identified in this screen, a 5.4-kb BamHI DNA fragment

was identified by Southern blot analysis, which hybridized

with the CfNR-specific probe This DNA fragment was

cloned into the BamHI site of pUC18, generating plasmid

Pnr⁄ BamHI5.4kb Sequencing of the 5.4-kb insert revealed

that it covered the complete CfNR gene including the

5¢-UTR and 3¢-UTR To determine the 5¢ sequence of the

CfNR mRNA, the cDNA was C-tailed as described in [35]

and used in a 5¢-RACE PCR using antisense primer

5¢-CAGCTAAACCCAATAGTCTG-3¢ and sense primer

5¢-GGCCACGCGTCGACTAGTACGGGIIGGGIIGGGI

IG-3¢ Thirteen cycles of PCR amplification (12 s 94
C,

15 s 55
C, 1.5 min 72
C) followed by 33 cycles (12 s

94
C, 15 s 55
C, 1.5 min 72
C) with an increment of 5 s

at 72
C per cycle were performed A  550-bp DNA frag-ment was gel purified and re-amplified in a second PCR using the same antisense primer and the nested sense pri-mer 5¢-GGCCACGCGTCGACTAGTAC-3¢ The resulting product was cloned into pGEMT vector and sequenced

Construction of the inducible expression plasmid pNICgfp

A 456-bp HindIII–EcoRI DNA fragment from plasmid Pnr⁄ BamHI5.4kb covering part of the 5¢-UTR of the CfNR gene was cloned into the HindIII–EcoRI sites of pBlue-scriptII SK+, generating pNRp To create the Pnr–gfp hybrid DNA fragment, the Gene SOEing technique (splicing

by overlap extension) [36] was used The first PCR for Gene SOEing was performed using Pnr⁄ BamHI5.4kb as the tem-plate with the sense primer SOE-1 (5¢-CCTCTTCTAGC GAGTCTGG-3¢) and antisense primer SOE-2 (5¢-CTC GTTGCTCACCATTGTTCAGCGTTGATTTTT-3¢) The second PCR was performed on an egfp-containing plasmid (a gift from Dr K Apt, Martek Biosciences, Columbia,

MD, USA) with sense primer SOE-3 (5¢-AAAAATCA ACGCTGAACAATGGTGAGCAAAGGGCGAG-3¢) and antisense primer SOE-4 (5¢-GAATGCGGCCGCTTACT TGTAACAGCTCGTCCATG-3¢), which introduced a NotI site (underlined) The third PCR was carried out with both the first two PCR products and primers SOE-1 and SOE-4 The resulting PCR product was digested with EcoRI and NotI and cloned into the EcoRI–NotI sites of pNRp This resulted in a chimeric gene with Pnr (775 bp) fused to egfp (pPnr-gfp) To introduce Tnr from the 3¢-UTR,

a PCR was performed using Pnr⁄ BamHI5.4kb as the template with sense primer 5¢-GAATGCGGCCGCGA ATGTGTGCAAATTGAAGAAC-3¢ and antisense primer 5¢-TTCGAGCTCCGGGGAAACGGTGCCAACTT-3¢, which introduced a NotI site (underlined) and a SacI site (bold) The resulting 592-bp DNA fragment was digested with NotI and SacI and cloned into the NotI–SacI sites of pPnr-gfp yielding pPnr-gfp-Tnr The final step of cloning involved the digestion of pPnr-gfp-Tnr with SacI (blunted) and KpnI and cloning into the BamHI (blunted)–KpnI sites of the zeocin resistance plasmid pCfcp-ble (see above) yielding pNICgfp All PCR products were checked for the correct sequence by DNA sequencing

Diatom transformation

C fusiformis was transformed by microparticle bombard-ment using the Biolistic PDS-1000⁄ He Particle Delivery system (Bio-Rad, Hercules, CA, USA) as described [9] For selection of transformants, bombarded cells were plated on artificial seawater medium containing 1.5% agar and

1 mgÆmL)1zeocin After 8 days of incubation of the plates under C fusiformis standard growth conditions (see above),

individual clones were picked from the plates and

inocula-ted into liquid artificial seawater medium containing

1 mgÆmL)1zeocin

RT-PCR

Total RNA was isolated from 5· 107

cells using 1 mL TRI reagent (Sigma, St Louis, MO, USA) according to

the manufacturer’s instructions Contaminating DNA was

removed from the RNA preparation by DNase treatment,

followed by an additional RNA purification step using

TRI reagent RNA concentration was determined

photo-metrically at 260 nm and estimated by agarose gel

electro-phoresis For first strand cDNA synthesis, 5 lg total

RNA, 25 pmol oligonucleotide 5¢-GCCGCCGAATTCC

CAG(T)18-3¢, 500 lm dNTPs and 100 U Superscript III

reverse transcriptase (Invitrogen) were incubated in a

20 lL reaction mix (1· RT buffer; Invitrogen) at 50
C

for 1 h After heat inactivation at 70
C for 15 min, 1 lL

of the reverse transcription reaction mix was used in a

50 lL PCR using 30 cycles for amplification For the

cffcpA-1A PCR, the first strand cDNA was diluted 1 : 50

before amplification, and for gfp and CfNR PCR the first

strand cDNA was used undiluted

Studies on CfNR gene expression

To investigate the effect of the type of nitrogen source

on the production of CfNR mRNA, cells were grown in

ammonium medium under constant illumination and

agi-tation After reaching a density of  1.5 · 106 cellsÆmL)1,

cells were harvested by centrifugation (2800 g, 5 min) and

washed three times with nitrogen-free medium The

washed cells were then resuspended in nitrogen-free

med-ium or medmed-ium containing either nitrate, ammonmed-ium, or

a 1 : 1 mixture of nitrate and ammonium After 24 h of

incubation, the cells were harvested for RNA isolation,

and RT-PCR was performed To study the kinetics of

CfNR expression, cells were grown in ammonium

med-ium as described above, and then transferred to fresh

medium containing nitrate Equal aliquots of cells were

harvested every other hour for RT-PCR analysis and

hourly for fluorescence measurements The same type of

kinetic analysis was performed in a second experiment, in

which cells were incubated for 24 h in nitrogen-free

med-ium before the addition of nitrate To exert control on

the amount of expressed GFP protein, cells were grown

to a cell density of  1.5 · 106

cellsÆmL)1 in ammonium medium, washed three times with nitrogen-free medium

and resuspended in nitrogen-free medium to a final cell

density of 0.5· 106 cellsÆmL)1 After a 24 h incubation

period, protein expression was induced by the addition of

various concentrations of NH4Cl (final concentrations:

0.15 mm, 0.06 mm, 0.03 mm, 0.015 mm) immediately

fol-lowed by the addition, to each sample, of KNO3 to a

final concentration of 1.5 mm The cells were grown for

a further 24 h before fluorescence measurements were taken

Fluorescence measurements of GFP

A Shimadzu RF-5301PC spectrofluorophotometer was used for fluorescence measurements of diatom cells at ambient temperature The excitation wavelength was 485 nm, the emission maximum was at 510 nm, and the slit width at both wavelengths was 5 nm Cell suspensions were either directly loaded into the quartz cuvette (kinetic measure-ments) or concentrated 10-fold before measurements (from cells grown in ammonium⁄ nitrate medium)

Western blot analysis Separation of proteins by SDS⁄ PAGE [37], Coomassie staining of SDS gels [38], and western blot analysis [39] were performed according to standard protocols For western blot analysis, 1.25· 106

cells were harvested from the respective medium, the cells were rapidly lysed by incuba-tion for 5 min in SDS sample buffer at 95
C, and equal aliquots of the extracts were subjected to SDS⁄ PAGE For detection of GFP, a specific antibody (developed in rabbit; Clontech, Mountain View, CA, USA) was used and an anti-rabbit IgG–alkaline phosphatase conjugate (Sigma) as the secondary antibody

Microscopy analysis Confocal imaging was performed using an inverted Zeiss LSM 510 laser scanning microscope and a 63· oil immer-sion objective (Carl Zeiss AG, Jena, Germany) For imaging the expression of GFP and the chloroplast autofluores-cence, excitation lines of an argon ion laser of 488 nm were used with a 505⁄ 550-nm bandpass filter for GFP and exci-tation lines of an HeNe laser of 543 nm with a 585 long pass filter for chloroplast autofluorescence in the multitrack facility of the microscope

Acknowledgements

We are grateful to the following people from the Uni-versita¨t Regensburg: Michael Leiss for experimental assistance in the initial phase of the project, Peter Heg-emann for help with spectrofluorimetry, Guido Gross-mann for assistance with confocal microscopy, and Gerhard Lehmann for technical assistance We are indebted to Ju¨rgen Stolz for critically reading the manuscript We thank Kirk Apt (Martek Biosciences, Columbia, MD, USA) for providing an egfp-containing plasmid This work was supported by the DFG (SFB-521-A2) and the Fonds der Chemischen Industrie

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