xylP Promoter-Based Expression System and Its Use for Antisense Downregulation of the Penicillium chrysogenum Nitrogen Regulator NRE

doi:10.1128/AEM.66.11.4810-4816.2000

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Applied and Environmental Microbiology, November 2000, p. 4810-4816, Vol. 66, No. 11
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

xylP Promoter-Based Expression System and Its Use for Antisense Downregulation of the Penicillium chrysogenum Nitrogen Regulator NRE

Ivo Zadra,¹ Beate Abt,¹ Walther Parson,² and Hubertus Haas¹^,^*

Department of Microbiology¹ and Institute of Legal Medicine,² Medical School of the University of Innsbruck, A-6020 Innsbruck, Austria

Received 5 June 2000/Accepted 17 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A highly inducible fungal promoter derived from the Penicillium chrysogenum endoxylanase (xylP) gene is described. Northernanalysis and the use of a $beta$ -glucuronidase (uidA) reporter genestrategy showed that xylP expression is transcriptionally regulated.Xylan and xylose are efficient inducers, whereas glucose stronglyrepresses the promoter activity. Comparison of the same expressionconstruct as a single copy at the niaD locus in P. chrysogenumand at the argB locus in Aspergillus nidulans demonstrated thatthe xylP promoter is regulated similarly in these two speciesbut that the level of expression is about 80 times higher in theAspergillus species. The xylP promoter was found to be 65-foldmore efficient than the isopenicillin-N-synthetase (pcbC) promoterin Penicillium and 23-fold more efficient than the nitrate reductase(niaD) promoter in Aspergillus under induced conditions. Furthermore,the xylP promoter was used for controllable antisense RNA synthesisof the nre-encoded putative major nitrogen regulator of P. chrysogenum.This approach led to inducible downregulation of the steady-statemRNA level of nre and consequently to transcriptional repressionof the genes responsible for nitrate assimilation. In addition,transcription of nreB, which encodes a negative-acting nitrogenregulatory GATA factor of Penicillium, was found to be subjectto regulation by NRE. Our data are the first direct evidence thatnre indeed encodes an activator in the nitrogen regulatory circuitin Penicillium and indicate that cross regulation of the controllingfactorsoccurs.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Utilization of filamentous fungi in industrial processes for production of pharmaceuticals is well established. A varietyof fungal metabolites are commercially exploited for their antibioticproperties; e.g., the $beta$ -lactam antibiotics penicillin and cephalosporinare produced by Penicillium chrysogenum and Acremonium chrysogenum,respectively (3, 16). Furthermore, well-established large-scalefermentation technology and the capacity to secrete substantialamounts of proteins into the medium increased the industrial applicationof these organisms as hosts for homologous and heterologous proteinproduction and secretion (14). For synthesis of proteins inlarge quantities efficient gene expression systems are required.Over the years a number of such expression systems have been developed,especially for Aspergillus and Trichoderma species, focusing onheterologous protein production. A second obvious applicationfor gene expression systems is the improvement of strains of commerciallyemployed producers of pharmaceuticals, such as P. chrysogenum.In this respect, promoters with various characteristics are neededfor increasing the transcript levels of the penicillin biosyntheticgenes or for directed metabolic engineering in order to improvespecific cellular properties (39, 40). In contrast to Aspergillus,only a few homologous promoter systems have been analyzed in P.chrysogenum so far. Some examples are the largely constitutivepromoters of the genes encoding phosphoglycerate kinase (pgkA)and NADP-dependent glutamate dehydrogenase (gdhA) (10, 24).Furthermore, the promoter of the isopenicillin-N-synthetase (pcbC)has been used for driving expression of the Tn5phleomycin resistancegene as a selection marker (11, 21, 29). The only highlyregulatable homologous expression system described for P. chrysogenumutilizes the promoter of the acid phosphatase-encoding gene (phoA),but full induction requires phosphate starvation, which mightinduce production of proteases and therefore is not feasible forall purposes (15). Use of the Aspergillus nidulans glyceraldehyde-3-phosphatedehydrogenase gene (gpdA) promoter is an example of functioningof a constitutive heterologous promoter in Penicillium (29).Although several promoters have proven to be useful for expressionof genes, there still is clearly a need for new, strongly induciblepromoters in P. chrysogenum, especially promoters that can beinduced independently of the promoters alreadyavailable.

We have cloned and characterized a gene encoding a group F 1,4- $beta$ -endoxylanase (XYLP) which is expressed at a high level duringgrowth on xylan, yielding up to 25% of the total proteins secretedinto the culture medium, and is repressed by glucose (17, 18).Recently, we have employed the xylP promoter region successfullyfor overexpression of the nitrogen regulatory GATA factor NREBin Penicillium, but a detailed analysis of this promoter, whichwould permit general application, has not been performed so far(21).

In this paper we describe an extended promoter sequence analysis of xylP and a detailed characterization analysis of the regulationof xylP expression in Penicillium in which a $beta$ -glucuronidase (GUS)reporter strategy was used. Furthermore, the usefulness of thissystem was demonstrated by employing it for inducible synthesisof antisense RNA of nre, which encodes the putative major nitrogenregulator of P. chrysogenum (19). Additionally, we show thefunctionality of the xylP-based expression system in A. nidulans,indicating the suitability of this system for various other fungalsystems.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, media, and transformation. Vectors and plasmids were propagated in Escherichia coli DH5 $alpha$ (Life Technologies). All fungal strains used in this study werederived from A. nidulans WG355 (biA1 bgaO argB2) or from P. chrysogenumniaD mutant M20 (11, 51). Generally, P. chrysogenum was grownat 25°C in Vogel's minimal medium supplemented with differentcarbon and nitrogen sources (21). P. chrysogenum protoplastswere transformed as described by Cantoral et al. (5), and transformantswere selected on minimal medium containing NaNO₃ and glucose asthe nitrogen and carbon sources, respectively. For A. nidulansthe minimal medium described by Pontecorvo et al. (41) was usedand incubation was performed at 37°C. Media were supplementedas required. Transformation of A. nidulans was carried out asdescribed by Tilburn et al. (50). Screening of positive cloneswas performed by PCR and Southern blot analysis (46).

Recombinant DNA and RNA techniques. For cloning procedures standard recombinant DNA techniques were used (46).

Fungal chromosomal DNA was isolated as described by Bainbridge et al. (1), with some modifications. The fungi were grownin 3 ml of complete medium as described by Kafer (27); Aspergilluscultures were grown for 24 h at 37°C, and Penicillium cultureswere grown for 48 h at 25°C. Mycelia were collected by centrifugation,washed with 100 mM EDTA, and resuspended in 3 ml of lysis solutioncontaining 2 mg of NOVOzym 234 (Sigma) per ml, 50 mM potassiumphosphate buffer (pH 5.8), 700 mM KCl, and 100 mM EDTA. Afterincubation for 3 h at 30°C in a rotary shaker at 150 rpm, theresulting protoplasts were transferred into 1.5-ml Eppendorf tubes,pelleted by centrifugation for 10 min at 7,000 × g, and resuspendedin 0.4 ml of extraction buffer containing 100 mM NaCl, 0.5% sodiumdodecyl sulfate (SDS), 50 mM Tris-HCl (pH 7.5), and 100 mM EDTA.After incubation for 10 min at 65°C, the samples were extractedwith phenol-chloroform-isoamyl alcohol (25:24:1) and then incubatedwith 20 µg of RNase (Boehringer Mannheim) for 10 min at 65°C,followed by incubation for 30 min at 20°C. The DNA was precipitatedwith 0.5 volume of isopropanol, pelleted by centrifugation, anddissolved in TEbuffer.

Total RNA was isolated from nitrogen-frozen and ground mycelia by using TRIzol reagent (Life Technologies) according to thesupplier's instructions. Generally, 15 µg of total RNA was electrophoresedon 1.2% agarose-1.1 M formaldehyde gels and blotted onto HybondN membranes (Amersham). Hybridization probes labeled with digoxigenin(Boehringer Mannheim) were generated by PCR amplification by usingoligonucleotides described previously (21).

uidA reporter constructs and vector for nre antisense expression. A vector containing the uidA reporter gene preceded by the xylP promoter and followed by the A. nidulans trpC terminator sequencewas obtained as follows. The 1.7-kb upstream region of the xylanasepromoter was amplified by PCR from a subcloned SalI fragment (18)by using synthetic oligonucleotides to create an NcoI site inthe xylP start codon (5'-CCATGCCATGGTTGGTTCTTCGAGTCGA) and togenerate a BglII site at bp $-$ 1680, destroying the SalI site atbp $-$ 1676 (5'-TTTGAAGATCTCGACGGAAGCGCGCAG). The PCR-amplified andBglII-NcoI-cleaved fragment was ligated into the 5.4-kb BglII-NcoIfragment of plasmid pNOM102 (44). In order to allow targetedintegration in P. chrysogenum, the 4.2-kb BglII-PstI fragmentof the resulting plasmid was inserted into the 6.1-kb BamHI-PstIfragment of vector pUN-pcbC, which contains a truncated niaD gene(11, 33). The resulting vector was called pXyluidA-P (Fig.1).

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FIG. 1. Schematic representation of the vectors used for analysis of xylP promoter activity (pXyluidA-P, pXyluidA-A) and for expression of nre antisense RNA (pXylern). Construction of these vectors is described in Materials and Methods. The xylP promoter region is indicated by xylP-P, and the trpC termination region is indicated by trpC-T.

To analyze the xylP-uidA fusion in A. nidulans as a single-copy insertion at the argB locus, the truncated Penicillium niaDgene was replaced by a mutated argB allele. To do this, a 3.7-kbNruI-KpnI fragment from plasmid pTran3-1A (43) was cloned intoEcoRV-KpnI-cleaved pBluescript KS (Stratagene). The resultingvector was digested with PstI and BamHI, ligated with the 4.2-kbBglII-PstI fragment carrying the xylP-uidA fusion described above,and termed pXyluidA-A (Fig. 1).

To express nre antisense RNA under control of the xylP promoter, the pXylern vector was constructed as follows (Fig. 1). The1.7-kb PCR fragment of the xylP promoter region described abovewas inserted into plasmid pGEM-T (Promega), resulting in plasmidpXyl-Gem. A 0.8-kb SphI-KspI fragment (bp 468 to 1280) encodingNRE amino acids 138 to 407 was PCR amplified from an nre template(19), and the SphI site at bp 468 was inserted with the PCRprimer. After SphI-KspI cleavage, this fragment was subclonedinto the SphI and KspI sites of pXyl-Gem. To allow targeted integrationin P. chrysogenum, the 2.5-kb SphI-SpeI fragment carrying thexylP-nre-antisense fusion was inserted into the 7-kb BamHI-SpeIpXyluidA-P fragment; the SphI and BamHI sites were previouslyfilled in with Klenowpolymerases.

The PCR fragments were verified by sequencing (46).

GUS activity assay and N-terminal amino acid sequence determination. GUS activity was measured by using 4-methylumbelliferyl- $beta$ -D-glucuronide as the substrate as described by Jefferson (26).The amount of 4-methylumbelliferone produced was determined witha fluorometer (TKO 100; Hoefer Scientific Instruments) calibratedwith a standard 4-methylumbelliferonesolution.

For in-gel GUS detection 100 µg of soluble protein from a mycelial crude extract was subjected to native polyacrylamide gelelectrophoresis (PAGE) in 10% Tris-glycine gels (NOVEX) by usingan XCELL II MiniCell (NOVEX) operated at 120 V and 4°C for 2 hunder nondenaturing conditions (32). After completion of electrophoresis,the gel was immediately rinsed for 10 min in 50 mM sodium phosphatebuffer (pH 7.5) and then transferred into an assay solution containing50 µg of the cyclohexylammonium salt of 5-bromo-4-chloro-3-indolyl- $beta$ -D-glucuronicacid (Sigma) per ml in 50 mM sodium phosphate buffer (pH 7.5).The assay was performed at 37°C until the blue color of the GUSzone appeared. The reaction was stopped by rinsing the gel inwater. The stained band was excised from the gel, reelectrophoresedunder denaturing conditions, and stained with Coomassie blue (32).After Western blotting onto an Immobilon membrane (Pharmacia),the protein was N terminally sequenced as described by Lindneret al. (34).

Nucleotide sequence accession number. The complete sequence of the xylP promoter has been deposited in the GenBank database under accession no. M98458.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Sequence analysis of the P. chrysogenum xylP promoter. Initially, only 510 bp of the 5' noncoding region of xylP was analyzed (18). In order to characterize the complete 1,676-bppromoter fragment employed for overexpression of nreB (21),the region between an SalI site and the xylP translation startcodon was sequenced in its entirety and was analyzed to determinethe presence of putative transcription factor binding sites. ThexylP promoter region displays characteristic features of fungalpromoters, including a putative 5'-TATAA box (2), a putativeHAP complex-binding 5'-CCAAT box (4), three 5'-GGCTAAA consensusbinding sites for the transcriptional activator XLNR necessaryfor expression of the xylanolytic system of Aspergillus niger(52), five 5'-SYGGRG sites that possibly mediate carbon cataboliterepression by a CREA-homologue (9), two 5'-GCCARG consensustarget sequences for the wide-domain pH-regulatory PACC transcriptionfactor (49), and six 5'-HGATAR motifs (Fig. 2A). The last sequencesare possible targets for GATA factors which have been shown tobe involved in regulatory circuits as different as nitrogen metabolism,iron metabolism, sexual development, blue light signal transduction,and circadian rhythmicity (47). Several GATA factor-encodinggenes have already been identified in P. chrysogenum (19, 21,22).

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FIG. 2. Analysis of the xylP promoter region. (A) Schematic representation of putative binding site positions (in base pairs) for fungal transcription factors. (B) Duplicated region containing a putative binding site for an XLNR homologue.

Remarkably, a 91-bp sequence starting at position $-$ 288 seems to be duplicated at position $-$ 725 with a level of identity of80% (Fig. 2B). The presence of a perfectly conserved XLNR consensussequence in this region reveals a possible means of evolutionto enhance regulation of promoters by duplication of transcriptionfactor bindingsites.

Induction characteristics of the xylP promoter in P. chrysogenum and A. nidulans. In order to avoid interference of different xylanase activities in enzymatic assays, xylP expression was studied by usingthe GUS-encoding uidA gene of E. coli as a reporter. GUS was chosenbecause P. chrysogenum has a very low endogenous background levelof this enzyme activity. The uidA coding region, trailed by theA. nidulans trpC transcription termination region, was fused withthe xylP promoter exactly at the start codon (Fig. 1). The presenceof a truncated niaD gene on plasmid pXyluidA-P allowed targetedintegration of a single copy of this reporter construct at thenitrate reductase-encoding niaD locus of the P. chrysogenum niaDmutant M20 (11).

To evaluate the functionality of the Penicillium xylP promoter in A. nidulans, exactly the same reporter construct was targetedas a single copy to the argB locus of A. nidulans argB2 mutantWG355 by using plasmid pXyluidA-A, which carries a defective argBcopy (42) instead of the truncated niaD copy in pXyluidA-P (Fig.1). P. chrysogenum and A. nidulans were transformed with the reporterconstructs as described in Materials and Methods, and transformantscarrying a single copy of the vector at the appropriate site wereidentified by Southern blot analysis. The resulting P. chrysogenumstrain (strain QXU-P1) and A. nidulans WXU-A1 were chosen forfurtheranalysis.

It has already been shown that xylP is not expressed during growth on glucose but is highly induced by xylan as a sole carbonsource (18). To investigate induction of the xylP promoter inP. chrysogenum in more detail, QXU-P1 was grown in shake flaskson various carbon sources and GUS activity was measured afterdifferent time periods (Fig. 3A). After 24 h of growth on xylanexpression of uidA was about five times higher than expressionon xylose, whereas after 48 and 72 h of growth the levels of expressiondiffered by only 25%. The significantly lower inducibility ofthe xylP promoter by xylose than by xylan at 24 h (Fig. 3A) wasalso observed in a Northern analysis of uidA expression (Fig.4). Interestingly, the endogenous xylP gene showed even lowerinduction by xylose at this time point. On glucose no GUS activitywas detected (Fig. 3A). On glucose-xylose and glucose-xylan thelevels of uidA expression increased most significantly after 72h of growth, when the glucose had been consumed. Remarkably, inglucose-xylan cultures GUS activity at 72 h was threefold greaterthan GUS activity on xylan or xylose alone.

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FIG. 3. Effects of carbon sources on reporter gene expression. P. chrysogenum QXU-P1 and A. nidulans WXU-A1 were grown in 500 ml of minimal medium containing 4% glucose as the sole carbon source. Subsequently, mycelia were harvested by filtration and washed with a 0.9% NaCl solution. A 3-g mycelial pad was transferred into 200 ml of minimal medium containing one of the carbon sources studied. The effect of glucose, xylose, and xylan on uidA expression was determined at various times for QXU-P1 (A) and WXU-A1 (B). Symbols: $black-lozenge$ , 4% glucose;

, 4% xylose; $black-triangle$ , 0.5% xylan; ×, 4% glucose and 4% xylose;

, 4% glucose and 0.5% xylan. In addition, the effects of various carbohydrates on GUS expression were measured 48 h after mycelia were transferred into media (C). The nitrogen source was 30 mM ammonium. GUS activities are given in picomoles of 4-methylumbelliferone per minute per microgram of total soluble cellular protein, and the values represent the means based on three independent experiments; the standard deviations did not exceed 10%.

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FIG. 4. Northern analysis of xylP and uidA expression in P. chrysogenum QXU-P1. Portions (15 µg) of total RNA, isolated 24 h after transfer of mycelia into 4% glucose (lane 1), 4% xylose (lane 2), or 0.5% xylan (lane 3), were subjected to Northern analysis. The blot was probed with digoxigenin-labeled fragments of uidA, xylP, and, as a control for loading and RNA quality, actP (GenBank accession no. U61733), the $gamma$ -actin-encoding gene of P. chrysogenum.

The expression profile of the xylP-driven uidA gene in A. nidulans is similar to that in P. chrysogenum: strong inductionby xylose or xylan and repression by glucose. One major differenceis the level of expression. In A. nidulans the xylP promoter isabout 80 times more efficient than it is in P. chrysogenum underthe same conditions (Fig. 3).

To test additional carbon sources for their xylP-inducing capacity, QXU-P1 and WXU-A1 were grown on different carbohydratesfor 48 h (Fig. 3C). With both Penicillium and Aspergillus strainsstrongest expression of uidA was found during growth on a combinationof different carbon sources (sucrose, xylose, and xylan). Thehighest levels of induction other than the levels obtained withxylose and xylan were observed in cultures containing sucroseand maltose, in which the level of GUS activity reached about0.1% of the xylan induction level in P. chrysogenum and up to2% of the xylan induction level in A. nidulans.

In order to analyze uidA expression in A. nidulans at the protein level, 100-µg portions of soluble protein from mycelialextracts were subjected to SDS-PAGE. In Coomassie blue-stainedgels containing crude protein extracts, a 67-kDa protein appearedin a sucrose-xylose-xylan-induced culture of strain WXU-A1; thisprotein was not present in induced mycelia of control strain WG355and repressed strain WXU-A1 (Fig. 5). To prove that this proteinwas E. coli GUS, the same extracts were subjected to native PAGEand GUS was detected by an in-gel activity assay as describedin Materials and Methods. Subsequently, the stained band was excisedfrom the native gel and reelectrophoresed by performing SDS-PAGE(Fig. 5, lane 4). The migration pattern, as well as N-terminalsequence determination after Western blotting, which yielded thesequence Val-Arg-Pro-Val-Glu, confirmed the identity as E. coliGUS. The amount of GUS was estimated to be 0.2 µg, suggestingthat complete induction of this expression system results in productionof approximately 0.2% of the total soluble cellular protein.

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FIG. 5. PAGE analysis of GUS expression. A. nidulans WXU-A1 (lane 3), containing the xylP promoter-controlled uidA expression cassette, and control strain WG355 (lane 1) were grown in minimal medium containing 1% sucrose, 0.5% xylose, and 0.5% xylan as the carbon sources for 48 h. Additionally, WXU-A1 was grown with glucose as the carbon source for 48 h (lane 2). Portions (100 µg) of soluble cellular proteins from mycelial extracts were subjected to in-gel GUS activity staining subsequent to native PAGE (A). The same crude extracts plus the excised zymogram stained GUS band of WXU-A1 (lane 4) were also subjected to SDS-PAGE and stained with Coomassie blue (B). Lane M contained a molecular mass marker.

Comparison of xylP promoter efficiency with the efficiencies of other promoters of P. chrysogenum and A. nidulans. To relate the efficiency of the xylP promoter to the efficiencies of other promoters used in P. chrysogenum, the pcbC promoter-controlleduidA gene was inserted at the niaD locus in P. chrysogenum M20by using the pUN-pcbC vector described by Feng et al. (11).The pcbC gene encodes the isopenicillin-N-synthetase, which isnecessary for the second step in penicillin biosynthesis. GUSactivity in transformant QPU-P6 was measured after 48 h of growthon xylan and ammonium as the carbon and nitrogen sources, respectively.Comparison of the uidA expression levels demonstrated that thexylan-induced xylP promoter is about 65 times more efficient thanthe pcbC promoter under theseconditions.

To compare the efficiency of the xylP promoter with that of an A. nidulans promoter, construct pTRAN3-1A (43) was targetedto the argB locus in A. nidulans WG355, yielding strain WNU-A3.pTRAN3-1A carries the uidA reporter gene under control of theA. nidulans niaD promoter and normally drives expression of nitratereductase in a strictly nitrate-induced and nitrogen metabolite-repressedmanner (8, 43). Expression analysis indicated that the PenicilliumxylP promoter yields about 23 times more GUS activity than theniaD promoter under fully induced conditions (with nitrate asthe sole nitrogensource).

Use of the xylP promoter for nre antisense RNA expression. As an application of an expression system in P. chrysogenum, the xylP promoter was used for controllable nre antisense RNAsynthesis. The nre gene encodes an AREA-NIT2 homologue and thereforethe putative major nitrogen regulatory factor of P. chrysogenum(8, 19, 37). Its function was indicated by heterologouscomplementation of a Neurospora crassa nit-2 mutant, but directproof of this function in P. chrysogenum is still not available(19). Several attempts to disrupt nre in Penicillium by targetedintegration failed (Haas, unpublished data), probably due to avery low degree of homologous recombination in this fungus (6).In an alternative approach the vector pXylern was constructed(Fig. 1). In this plasmid the central part of nre encoding aminoacids 138 to 408 was cloned in antisense orientation downstreamof the xylP promoter. Using the same strategy that was used forthe other vectors described in this study, we integrated thisconstruct as a single copy at the niaD locus of P. chrysogenumM20.

The GATA factors AREA and NIT2 are necessary for utilization of nitrogen sources other than glutamine or ammonia in A. nidulansand N. crassa, respectively. Consequently, downregulation of NREshould result in reduced growth on such compounds (8, 37).Unexpectedly, five transformants tested to determine their growthrates on the secondary nitrogen sources nitrate, proline, andhypoxanthine exhibited no differences compared to Penicilliumcontrol strain QXU-P1 in liquid media or on solid media. Furthermore,nre antisense RNA expression did not lead to a difference in resistanceto chlorate (8, 37), which is toxic to nitrate reductase-carryingstrains (data not shown). One of the nre antisense RNA-expressingtransformants, QXERN1, was further analyzed for expression ofniaD and niiA (Fig. 6). These two genes encode the nitrate assimilatoryenzymes nitrate reductase and nitrite reductase, respectively,and are known to be subject to nitrogen metabolite repressionin this fungus (20). Northern analysis revealed that inductionof nre antisense RNA synthesis by growth on sucrose-xylose-xylanfor 48 h led to a dramatic decrease in the nre steady-state mRNAlevel and subsequently to transcriptional repression of niaD andniiA in QXERN1 (Fig. 6). In addition, transcription of nreB wasfound to be downregulated by nre antisense expression, nreB encodesa second GATA factor that has been suggested to be negativelyinvolved in the nitrogen regulatory circuit of Penicillium (21).The specificity of the antisense RNA-mediated repression of nitrogen-regulatedgenes is indicated by two lines of evidence: (i) the level ofexpression of niaD, niiA, and nreB in QERN1 during growth on glucose,which represses nre antisense synthesis, did not differ from thelevel of expression in control strain QXU-P1; and (ii) the actin-encodingactP gene was found to be constitutively expressed under all growthconditions.

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FIG. 6. Northern analysis of nre antisense RNA expression effects. P. chrysogenum QXERN, containing the nre antisense RNA expression cassette, and control strain QXU-P1 were grown for 48 h in minimal medium containing 30 mM nitrate as the sole nitrogen source and 4% glucose (lanes 1 and 3) or 1% sucrose, 0.5% xylose, and 0.5% xylan (lanes 2 and 4) as carbon sources. Subsequently, 15 µg of isolated total RNA was subjected to Northern analysis. The blot was probed with digoxigenin-labeled fragments of nre, niaD, niiA, and actP. as-nre, nre antisense RNA.

Two further experiments proved that expression of the nitrate assimilation gene cluster is not complete, which explains thegrowth that occurs on nitrate and probably the other secondarynitrogen sources; overexposure of the niaD blot shown in Fig.6 revealed the presence of a low level of the niaD transcript,and Northern analysis performed 24 h after nre antisense inductionrevealed only about 50% reduced niaD expression, indicating thatthe nre antisense effect increases with time (data notshown).

The data described above are the first direct proof that NRE functions as an activator in nitrogen metabolism by P. chrysogenum.NRE-dependent expression of nreB indicates that cross regulationof the GATA factors is involved in this regulatorycircuit.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Xylanases play an important role in the natural degradation of hemicellulosic material, as well as in biotechnological processeslike paper pulp bleaching or bioconversion of biomass into fuelsand chemicals (31). The P. chrysogenum xylP gene was one ofthe first group F xylanase-encoding genes cloned in filamentousfungi. Homologues have been identified in various filamentousfungi, including Aspergillus kawachii, Aspergillus ryzae, A. nidulans,Penicillium simplicissimum, Thermoascus aurantiacus, Fusariumoxysporum, Magnaporthe grisea, Trichoderma reesei, and Clavicepspurpurea (12, 18, 25, 28, 35, 45, 48, 53, 54).

In this study we demonstrated the suitability of the strongly regulatable xylP promoter for use as an expression system inP. chrysogenum and A. nidulans. The expression system was foundto be regulated similarly in the two fungi: strong inducibilityby xylose or xylan and tight repression by glucose. The presenceof five SYGGRG motifs in the promoter indicates that xylP expressionis subject to CREA-CRE1-mediated carbon catabolite repression,as demonstrated for xylanases from A. nidulans and T. reesei (9,38, 56). High-level induction by xylose, which is a more definedand cheaper compound than xylan, does not apply to all xylanasesbut has been demonstrated for EXLA and XYN1 from Aspergillus awamoriand T. reesei, respectively (13, 56). The presence of XLNRconsensus binding sites in the promoter suggests that there isan induction process similar to that described for A. niger (52).Furthermore, the CCAAT box indicates that HAP complex-mediatedregulation occurs, as described for other xylanases (4, 56).In A. nidulans two xylanases show an opposite pattern of expressionwith respect to ambient pH which is PACC mediated (36). Despitetwo PACC consensus sites in the regulatory region, it is unlikelythat xylP is pH regulated because uidA expression was found tobe similar during growth on ammonia (leading to an acidic ambientpH) or nitrate (leading to an alkaline ambient pH) as the nitrogensource and xylose as the carbon source (data notshown).

The efficiency of the xylP promoter was compared with the efficiencies of the pcbC promoter in P. chrysogenum and the niaDpromoter in A. nidulans by using the same reporter gene and thesame chromosomal integration locus. The xylP promoter yieldedabout 65-fold more GUS activity than the Penicillium pcbC promoter,which normally controls expression of the isopenicillin-N-synthetase.Kolar et al. (30) have demonstrated that the Penicillium pcbCpromoter is rather weak compared to the A. nidulans gpdA promoterduring growth in minimal medium, but this study was performedwith A. nidulans. In A. nidulans the xylP promoter is about 23times stronger than the niaD promoter under induced conditions.Although making a direct comparison of promoter strengths is difficultsince the resulting mRNAs possess different 5' and 3' untranslatedregions, which might result in different mRNA stabilities or differenttranslational efficiencies, it is obvious that the xylP promoteris highly inducible and veryefficient.

During the last decade various antisense technologies have become important as instruments for the development of agriculturalproducts, as therapeutic tools in human medicine, and for investigationof gene function (23). In fungi the antisense RNA approach israther rarely exploited, probably due to the relatively efficientgene disruption techniques available. Nevertheless, there aretwo obvious applications. (i) Using antisense technology, expressionof a given gene usually cannot be completely turned off but canonly be reduced. However, this obvious disadvantage might be anadvantage for certain applications; if the gene studied is essential,an antisense approach still allows functional characterizationof the gene product, especially if the antisense expression iscontrollable (55). (ii) If the organism studied has weak homologousrecombination, which seems to be the case in P. chrysogenum (6),antisense technology is a faster and more efficient approach toinvestigate a gene'sfunction.

The efficiency of the antisense approach depends on the strength of antisense expression. As an interesting application requiringhigh-level expression, the xylP promoter was therefore employedfor controllable nre antisense RNA synthesis. The nre gene encodesa homologue of the Aspergillus GATA factor AREA and hence theputative positive-acting nitrogen regulator of Penicillium, butfinal data to prove this have not been obtained since no nre mutantis available (8, 19). nre antisense expression led to aninducible decrease in nre mRNA and consequently to repressionof nitrate assimilatory gene cluster transcription. Remarkably,no decrease in the growth rate was seen with this strain whenit was grown on nitrate or other secondary nitrogen sources undernre antisense-inducing conditions. A likely explanation for thisis that this antisense approach does not lead to a complete blockof gene expression $---$ as seen for niaD and most antisense applications $---$ andthat the remaining expression is still sufficient to maintainabout the same growth rate. The data also indicate that in P.chrysogenum the level of transcription of the nitrate catabolicgenes is not the limiting factor for growth under the conditionstested. In this respect it is noteworthy that expression of theessential protein phosphatase 2A can be significantly decreasedby an RNA antisense strategy in N. crassa; nevertheless, hyphalgrowth and conidiation can still be maintained (55).

In addition, transcription of nreB, which encodes a second nitrogen regulatory GATA factor of Penicillium, was found to bedownregulated by nre antisense expression. Recently, we have shownthat NREB acts negatively in the nitrogen regulatory circuit andthat its expression is subject to nitrogen regulation (21).NRE-dependent nreB expression indicates that cross regulationof the two GATA factors is involved in nitrogen regulation inPenicillium. This resembles the situation in Saccharomyces cerevisiae.In this yeast expression of the four GATA factors controllingnitrogen catabolic gene expression is interdependent; two factorsact negatively, and two factors act in a positive manner (7).

The obvious advantage of an antisense RNA strategy is the possibility of being able to study a gene's function under conditionsthat are not possible when a classical gene disruption approachis used; e.g., by analogy to Aspergillus and Neurospora (8,37), a nre loss-of-function mutant cannot grow on nitrate asa sole nitrogen source, and therefore, the response of targetgenes cannot be investigated under these growth conditions. Theantisense strategy provided the first direct proof that NRE isan activator in the nitrogen regulatory circuit of Penicillium.

In conclusion, this study shows that the xylP-based expression system is a valuable tool in P. chrysogenum and probably ina variety of other filamentous fungi since its functionality couldalso be demonstrated in A. nidulans. Furthermore, RNA antisenseexpression proved to be a powerful tool for conducting gene regulationstudies in Penicillium.

	ACKNOWLEDGMENTS

This project was funded by the Austrian Science Foundation (grant FWF-P11164-MOB to H.H.).

We are grateful to Peter Punt and Bo Feng for providing plasmids pTRAN3-1A, pNOM102, and pUN-pcbC. We thank Herbert Lindnerfor N-terminal amino acid sequencedeterminations.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology (Medical School), University of Innsbruck, Fritz-Pregl-Str.3, A-6020 Innsbruck, Austria. Phone: 43-512-507-3608. Fax: 43-512-507-2866.E-mail: hubertus.haas{at}uibk.ac.at.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Bainbridge, B. W., C. L. Spreadbury, F. G. Scalise, and J. Cohen. 1990. Improved methods for the preparation of high molecular weight DNA from large and small scale cultures of filamentous fungi. FEMS Microbiol. Lett. 66:113-118[CrossRef].
2.	Ballance, D. J. 1986. Sequences important for gene expression in filamentous fungi. Yeast 2:229-236[CrossRef][Medline].
3.	Brakhage, A. A. 1998. Molecular regulation of beta-lactam biosynthesis in filamentous fungi. Microbiol. Mol. Biol. Rev. 62:547-585[Abstract/Free Full Text].
4.	Brakhage, A. A., A. Andrianopoulos, M. Kato, S. Steidl, M. A. Davis, N. Tsukagoshi, and M. J. Hynes. 1999. HAP-Like CCAAT-binding complexes in filamentous fungi: implications for biotechnology. Fungal Genet. Biol. 27:243-252[CrossRef][Medline].
5.	Cantoral, I. M., B. Diez, J. L. Barredo, E. Alvarez, and J. F. Martin. 1987. High frequency transformation of Penicillium chrysogenum. J. Biotechnol. 5:494-497[CrossRef].
6.	Casqueiro, J., S. Gutierrez, O. Banuelos, M. J. Hijarrubia, and J. F. Martin. 1999. Gene targeting in Penicillium chrysogenum: disruption of the lys2 gene leads to penicillin overproduction. J. Bacteriol. 181:1181-1188[Abstract/Free Full Text].
7.	Coffman, J. A., R. Rai, D. M. Loprete, T. Cunningham, V. Svetlov, and T. G. Cooper. 1997. Cross regulation of four GATA factors that control nitrogen catabolic gene expression in Saccharomyces cerevisiae. J. Bacteriol. 179:3416-3429[Abstract/Free Full Text].
8.	Crawford, N. M., and H. N. Arst, Jr. 1993. The molecular genetics of nitrate assimilation in fungi and plants. Annu. Rev. Genet. 27:115-146[CrossRef][Medline].
9.	Cubero, B., and C. Scazzocchio. 1994. Two different, adjacent and divergent zinc finger binding sites are necessary for CREA-mediated carbon catabolite repression in the proline gene cluster of Aspergillus nidulans. EMBO J. 13:407-415[Medline].
10.	Diez, B., E. Mellado, M. Rodriguez, E. Bernasconi, and J. L. Barredo. 1999. The NADP-dependent glutamate dehydrogenase gene from Penicillium chrysogenum and the construction of expression vectors for filamentous fungi. Appl. Microbiol. Biotechnol. 52:196-207[CrossRef][Medline].
11.	Feng, B., E. Friedlin, and G. Marzluf. 1994. A reporter gene analysis of penicillin biosynthesis gene expression in Penicillium chrysogenum and its regulation by nitrogen and glucose catabolite repression. Appl. Environ. Microbiol. 60:4432-4439[Abstract/Free Full Text].
12.	Giesbert, S., H. B. Lepping, K. B. Tenberge, and P. Tudzynski. 1998. The xylanolytic system of Claviceps purpurea: cytological evidence for secretion of xylanases in infected rye tissue and molecular characterization of two xylanase genes. Phytopathology 88:1020-1030[Medline].
13.	Gouka, R. J., J. G. Hessing, P. J. Punt, H. Stam, W. Musters, and C. A. Van den Hondel. 1996. An expression system based on the promoter region of the Aspergillus awamori 1,4-beta-endoxylanase A gene. Appl. Microbiol. Biotechnol. 46:28-35[CrossRef][Medline].
14.	Gouka, R. J., P. J. Punt, and C. A. Van den Hondel. 1997. Efficient production of secreted proteins by Aspergillus: progress, limitations and prospects. Appl. Microbiol. Biotechnol. 47:1-11[CrossRef][Medline].
15.	Graessle, S., H. Haas, E. Friedlin, H. Kurnsteiner, G. Stöffler, and B. Redl. 1997. Regulated system for heterologous gene expression in Penicillium chrysogenum. Appl. Environ. Microbiol. 63:753-756[Abstract].
16.	Gutierrez, S., F. Fierro, J. Casqueiro, and J. F. Martin. 1999. Gene organization and plasticity of the beta-lactam genes in different filamentous fungi. Antonie Leeuwenhoek 75:81-94.
17.	Haas, H., E. Herfurth, G. Stöffler, and B. Redl. 1992. Purification, characterization and partial amino acid sequences of a xylanase produced by Peniillium chrysogenum. Biochim. Biophys. Acta 1117:279-286[Medline].
18.	Haas, H., E. Friedlin, G. Stöffler, and B. Redl. 1993. Cloning and structural organization of a xylanase-encoding gene from Penicillium chrysogenum. Gene 126:237-242[CrossRef][Medline].
19.	Haas, H., B. Bauer, B. Redl, G. Stöffler, and G. A. Marzluf. 1995. Molecular cloning and analysis of nre, the major nitrogen regulatory gene of Penicillium chrysogenum. Curr. Genet. 27:150-158[CrossRef][Medline].
20.	Haas, H., F. Marx, S. Graessle, and G. Stöffler. 1996. Sequence analysis and expression of the Penicillium chrysogenum nitrate reductase encoding gene (niaD). Biochim. Biophys. Acta 1309:81-84[Medline].
21.	Haas, H., K. Angermayr, I. Zadra, and G. Stöffler. 1997. Overexpression of nreB, a new GATA factor-encoding gene of Penicillium chrysogenum, leads to repression of the nitrate assimilatory gene cluster. J. Biol. Chem. 272:22576-22582[Abstract/Free Full Text].
22.	Haas, H., K. Angermayr, and G. Stöffler. 1997. Molecular analysis of a Penicillium chrysogenum GATA factor encoding gene (sreP) exhibiting significant homology to the Ustilago maydis urbs1 gene. Gene 184:33-37[CrossRef][Medline].
23.	Hawkins, J. W., and W. Nellen. 1994. Diversification of antisense research and development: review of the Ringberg meeting. April 1994. Mechanisms of antisense-mediated gene silencing. Antisense Res. Dev. 4:127-129[Medline].
24.	Hoskins, I. C., and C. F. Roberts. 1994. Expression of the 3-phosphoglycerate kinase gene (pgkA) of Penicillium chrysogenum. Mol. Gen. Genet. 243:270-276[CrossRef][Medline].
25.	Ito, K., T. Ikemasu, and T. Ishikawa. 1992. Cloning and sequencing of the xynA gene encoding xylanase A of Aspergillus kawachii. Biosci. Biotechnol. Biochem. 56:906-912[Medline].
26.	Jefferson, R. A. 1987. Assaying chimeric genes in plants: the GUS gene fusion system. Plant Mol. Biol. Rep. 5:387-405[CrossRef].
27.	Kafer, E. 1977. Meiotic and mitotic recombination in Aspergillus and its chromosomal aberrations. Adv. Genet. 19:33-131[Medline].
28.	Kitamoto, N., S. Yoshino, M. Ito, T. Kimura, K. Ohmiya, and N. Tsukagoshi. 1999. Repression of the expression of genes encoding xylanolytic enzymes in Aspergillus oryzae by introduction of multiple copies of the xynF1 promoter. Appl. Microbiol. Biotechnol. 50:558-563.
29.	Kolar, M., P. J. Punt, C. A. van den Hondel, and H. Schwab. 1988. Transformation of Penicillium chrysogenum using dominant selection markers and expression of an Escherichia coli lacZ fusion gene. Gene 62:127-134[CrossRef][Medline].
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