Uptake of the {beta}-Lactam Precursor {alpha}-Aminoadipic Acid in Penicillium chrysogenum Is Mediated by the Acidic and the General Amino Acid Permease

External addition of the ß-lactam precursor ${alpha}$ -aminoadipicacid to the filamentous fungus Penicillium chrysogenum leadsto an increased intracellular ${alpha}$ -aminoadipic acid concentrationand an increase in penicillin production. The exact route for ${alpha}$ -aminoadipic acid uptake is not known, although the generalamino acid and acidic amino acid permeases have been implicatedin this process. Their corresponding genes, PcGAP1 and PcDIP5,of P. chrysogenum were cloned and functionally expressed ina mutant of Saccharomyces cerevisiae (M4276) in which the acidicamino acid and general amino acid permease genes (DIP5 and GAP1,respectively) are disrupted. Transport assays show that bothPcGap1 and PcDip5 mediated the uptake of ${alpha}$ -aminoadipic acid,although PcGap1 showed a higher affinity for ${alpha}$ -aminoadipic acidthan PcDip5 (K_m values, 230 and 800 µM, respectively).Leucine strongly inhibits ${alpha}$ -aminoadipic acid transport via PcGap1but not via PcDip5. This difference was exploited to estimatethe relative contribution of each transport system to the ${alpha}$ -aminoadipicacid flux in ß-lactam-producing P. chrysogenum. Thetransport measurements demonstrate that both PcGap1 and PcDip5contribute to the ${alpha}$ -aminoadipic acid flux.

INTRODUCTION

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Introduction

The production of penicillin, still the most widely used antibiotictogether with its derivatives, is mainly based on an industrialfermentation utilizing the filamentous fungus Penicillium chrysogenum.Although the biochemistry of penicillin biosynthesis has beenresearched extensively, much less is known about the transportprocesses involved. These include, for instance, the transportof penicillin or its precursors across membranes of the intracellularcompartments and its transport across the plasma membrane (43).The penicillin biosynthesis pathway starts in the cytosol withthe condensation of three amino acids, L- ${alpha}$ -aminoadipic acid ( ${alpha}$ -AAA),L-cysteine, and L-valine, to form the tripeptide L- ${alpha}$ -amino-adipyl-L-cysteinyl-D-valine(ACV) (44). ACV is converted into isopenicillin N (IPN) by IPNsynthase. In this step the characteristic ß-lactamring structure is formed by ring closure. IPN is subsequentlytransported into microbodies or peroxisomes, where the ${alpha}$ -AAAmoiety is replaced by a phenylacetic acid group involving acoenzyme A derivative of this aromatic acid. This process yieldspenicillin G, which subsequently must be transported acrossthe microbody membrane and the plasma membrane in order to accumulatein the extracellular medium (1, 7, 29, 43). ${alpha}$ -AAA is releasedin the microbody and can be recycled for either lysine or penicillinbiosynthesis. However, a portion of the ${alpha}$ -AAA is lost by theirreversible formation of 6-oxopiperidine-2-carboxylic acid(OPC), a cyclized form of ${alpha}$ -AAA. The extent of OPC formationranges from 6 to 60% relative to the formation of penicillin(on a molar basis), depending on the strain and cultivationconditions. A major fraction of the OPC seems to be releasedfrom the cell, but the mechanism of secretion is unknown (16).

The intracellular concentration of ${alpha}$ -AAA, but not that of cysteineor valine, appears limiting for the synthesis of the tripeptideACV, which also affects the overall penicillin biosynthesisrate in low-producing strains (13, 19). This has become apparentfrom experiments in which the mycelium is supplemented with ${alpha}$ -AAA, whereupon the intracellular ${alpha}$ -AAA concentration is elevatedconcomitantly with enhanced levels of ACV and penicillin production(13, 19). In addition, strains producing higher levels of penicillinhave increased intracellular ${alpha}$ -AAA levels (23). In P. chrysogenum, ${alpha}$ -AAA is a branching intermediate of the lysine and penicillinbiosynthesis pathways, which share common enzymatic steps startingfrom ${alpha}$ -ketoglutarate. The routes diverge at the point where ${alpha}$ -AAAcan be converted into ${alpha}$ -AAA-semialdehyde by ${alpha}$ -AAA reductase (5,12, 23). Disruption of the gene encoding this enzyme, LYS2,results in a higher intracellular ${alpha}$ -AAA concentration and concomitantlyhigher levels of penicillin production (10). In Aspergillusnidulans, which also produces penicillin but is not used forindustrial production, the relative amount of ${alpha}$ -AAA enteringeither the penicillin synthesis pathway or the lysine synthesispathway is tightly regulated (9). Another important aspect ofthe ${alpha}$ -AAA biosynthesis route is that in the yeast Saccharomycescerevisiae, some of the enzymes of the lysine biosynthesis pathwayare localized in the microbodies instead of the mitochondria(8). It is unclear how this pathway is organized in filamentousfungi.

The observation that externally added ${alpha}$ -AAA enhances penicillinbiosynthesis strongly suggests that there is a mechanism of ${alpha}$ -AAA uptake. Fungi have different amino acid permeases thatdiffer in specificity. Some systems are specific only for agroup of related amino acids, while the general amino acid permeasecan transport all amino acids (20, 32, 37). These systems allbelong to one family, referred to as the amino acid permeasefamily (3). Exceptions are the permease encoded by the mtr locusof Neurospora crassa and its homologue in P. chrysogenum, whichare specific for neutral aliphatic and aromatic amino acids(26, 39; H. Trip et al., unpublished data). In general, aminoacid transport occurs by proton symport and thus is driven bythe proton motive force (18, 35). Although ${alpha}$ -AAA is not one ofthe natural amino acids but an intermediate of amino acid metabolism,it shares the characteristics of glutamate and aspartate asa dicarboxylic amino acid. In S. cerevisiae, these amino acidscan enter the cell via the general amino acid permease Gap1and the acidic amino acid permease Dip5 (33). For P. chrysogenum,transport systems have mostly been described only on the basisof functional studies; these systems have not been geneticallydescribed. The general amino acid permease is a nonspecificsystem that is involved in the uptake of all amino acids (4),while the acidic amino acid permease mediates the uptake ofglutamate and aspartate. Previous studies have shown that glutamatetransport by the acidic amino acid permease can be inhibitedby an excess of ${alpha}$ -AAA, which suggests that this compound is asubstrate for this transporter (21).

Here we have analyzed the uptake of ${alpha}$ -AAA by P. chrysogenum inmore detail, and we show that there are two major uptake routes:(i) via the acidic amino acid permease and (ii) via the generalamino acid permease. The genes encoding these transporters werecloned into an S. cerevisiae mutant in which acidic amino aciduptake is defective, allowing the functional characterizationof the P. chrysogenum Gap1 and Dip5 homologues. The resultsindicate that both systems contribute to the uptake of ${alpha}$ -AAAby P. chrysogenum under conditions in which ß-lactamsare formed.

MATERIALS AND METHODS

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Materials and Methods

Strains and culture conditions.
P. chrysogenum strain Wisconsin 54-1255 (kindly provided byDSM-Anti-Infectives, Delft, The Netherlands) was grown in aminimal medium based on a penicillin production medium as describedpreviously (27). The medium contained 4% (wt/vol) glucose orlactose as the carbon source and either 0.4% (wt/vol) ammoniumacetate, 0.4% (wt/vol) urea, 10 mM L-glutamate, 10 mM L-serine,or 10 mM L-lysine as the nitrogen source. Cultures were startedon YPG medium (1% yeast extract, 2% peptone, 2% glucose), incubatedfor 16 to 20 h in a rotary shaker at 200 rpm and 25°C, andthen diluted into minimal medium and incubated for 24 or 48h.

S. cerevisiae strain M4276 (MAT ${alpha}$ ura3 ${Delta}$ gap1 ${Delta}$ dip5) (33) was growneither in minimal medium (1% [wt/vol] succinic acid, 0.6% [wt/vol]NaOH, 0.16% [wt/vol] yeast nitrogen base [Difco] without ammoniumsulfate and amino acids, and 2% [wt/vol] D-glucose) (15), inMA medium (minimal medium containing 0.5% [wt/vol] ammoniumsulfate as the sole nitrogen source), in MP medium (containing0.1% [wt/vol] L-proline as the sole nitrogen source), or inMG medium (containing 0.5 g of L-glutamate/liter as the solenitrogen source). Where indicated, these media were solidifiedwith 1.5% agar.

Escherichia coli strain DH5 ${alpha}$ was used as the plasmid host, andDNA manipulations were carried out essentially as describedelsewhere (34). E. coli XL10-Gold Ultracompetent cells (Stratagene,Amsterdam, The Netherlands) were used for amplification of thepartial cDNA library.

Expression of a partial cDNA library of P. chrysogenum in S. cerevisiae M4276.
A cDNA library of P. chrysogenum (kindly provided by DSM-Anti-Infectives,Delft, The Netherlands) was transferred from pCMVSPORT 4.0 (Stratagene)to a suitable yeast expression vector. For this purpose, theampicillin resistance marker of the yeast/E. coli shuttle vectoryEP352 (17) was replaced by a kanamycin resistance marker, andthe copper-inducible promoter of CUP1, pCUP1 (36), was introducedtogether with the terminator of CYC1 (45), yielding plasmidyEX-C. The SbfI and NotI sites between pCUP1 and tCYC1 wereused for insertion of the cDNA library. The cDNA library wasisolated from pCMVSPORT 4.0 by digestion with SbfI and NotIand was subjected to gel electrophoresis. Since the sizes ofknown fungal amino acid permease genes range from 1.4 to 2 kb,fragments ranging from 1.0 to 2.5 kb were isolated, purified,and ligated into yEX-C. To amplify the library, the ligationmixture was transformed to E. coli XL10-Gold Ultracompetentcells (Stratagene) for high transformation efficiency, and thecells were spread on Luria broth plates with kanamycin. PlasmidDNA was isolated by resuspending the colonies in water, followedby a standard plasmid isolation procedure. About 5 µgof plasmid DNA was transformed to S. cerevisiae M4276, a straindeficient in glutamate and aspartate uptake, as described previously(14). Cells were spread on MG plates containing 0.05 g of L-glutamate/literas the sole nitrogen source and 0.2 mM CuSO₄ for induction ofthe copper-inducible promoter pCUP1. At the same time, the transformationefficiency was checked by spreading transformed cells on MAplates, containing NH₄⁺ as the nitrogen source; an efficiencyof approximately 35,000 transformants per µg of DNA wasobtained. After 6 days of incubation at 30°C, eight coloniesappeared; they were transferred to liquid minimal medium containing0.05 g of L-glutamate/liter as the sole nitrogen source. Onlyone of the colonies was able to grow on glutamate, and the plasmidDNA was isolated by following a standard plasmid rescue protocol.For propagation, plasmid DNA was transformed to E. coli DH5 ${alpha}$ .The plasmid was analyzed by restriction, revealing a 1.9-kbinsert in the yEX-C vector; the DNA sequence of the insert wasdetermined.

Cloning of PcGAP1.
The following degenerate primers were designed on the basisof conserved regions of known fungal (putative) general aminoacid permease genes: primer Gap F (5'-CCCGGCGCCATCAARCARGTNTTYTGG-3')and primer Gap R1 (3'-CCGGAGATGGCCAGNAGCCARTCRAA-5'). PCR wasperformed with genomic DNA of P. chrysogenum as a template.PCR products were analyzed by gel electrophoresis, and a clear,distinct fragment of 0.4 kb was isolated, purified, and ligatedinto pGEM-T Easy (Promega, Leiden, The Netherlands). Of thefour clones analyzed by sequencing, three contained a fragmentshowing high homology (50% amino acid identity) with Gap1 ofS. cerevisiae and one contained a fragment showing highest homology(45 to 48% amino acid identity) with yeast basic amino acidpermeases. The Gap1 homologous fragment was used to make a radioactivelylabeled probe for the screening of a genomic library.

Isolation of genomic DNA of permease genes.
A genomic library of P. chrysogenum Wisconsin 1255-54 in phage ${lambda}$ ZAP II (Stratagene) was screened by plaque hybridization usinga radioactively labeled 400-bp internal fragment of PcDIP5 amplifiedby PCR or the PcGAP1 gene fragment described above. Positiveplaques were isolated, phages were released, and pBluescript,containing the genome fragments (average size, 8 kb), was rescuedfrom the phage by incubation with helper phage M13. DNA sequencingof the PcDIP5 positive clone revealed a complete, 1,677-bp openreading frame, interrupted by five introns of approximately60 bp. The PcGAP1 positive clone contained a 1,743-bp open readingframe interrupted by three introns of 63, 55, and 35 bp. Intronswere identified on the basis of consensus sequences of intronsof P. chrysogenum and, in the case of PcDIP5, by alignment ofthe cDNA and genomic DNA.

Cloning of the cDNA of PcGAP1 in the yeast expression vector yEX-C.
A forward primer with an EcoRI restriction site (5'-ATTCACATAGAATTCATGGAGGAGAAGAAGTTTGAGGC-3')and a reverse primer with a NotI restriction site (3'-ACAGCGGCCGCTTTCCAGGTAAGATGC-5')were used in a PCR to amplify the cDNA of PcGAP1 with the cDNAlibrary as a template. The 1.8-kb product obtained was digestedwith EcoRI and NotI and ligated into the EcoRI- and NotI-digestedvector yEX-C. The resulting plasmid, yEX-PcGAP1, was transformedto S. cerevisiae M4276.

${alpha}$ -AAA transport assays with the mycelium of P. chrysogenum.
P. chrysogenum was precultured overnight as described above,and germinating spores were added to penicillin production media.After 48 h of growth, the mycelium was harvested by suctionfiltration, washed, and resuspended in ice-cold 50 mM KH₂PO₄—K₂HPO₄(pH 6.0) to a density of approximately 15 mg (dry weight)/ml.This suspension was preincubated for 5 min at 25°C withaeration, and DL-[³H] ${alpha}$ -aminoadipate was added to final concentrationsof 10 µM to 2.5 mM. For inhibition studies, DL-[³H] ${alpha}$ -aminoadipatewas present at 25 µM, while the competitor L-leucine wasused at a concentration range of 10 µM to 2.5 mM. After3 min, uptake was stopped by addition of 2 ml of ice-cold 0.1M LiCl and subsequent suction filtration through a 0.45-µM-pore-sizenitrocellulose filter. The filter was washed with 2 ml of 0.1M LiCl, and radioactivity was measured in a scintillation counter.Background values were determined by measuring uptake in themycelium, which was pretreated with the protonophore carbamoylcyanide m-chlorophenylhydrazone (CCCP). Uptake measurementswith P. chrysogenum were made in four independent experiments,for which average values and standard deviations are shown (seeFig. 1A).

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FIG. 1. Uptake of ${alpha}$ -AAA and inhibition by unlabeled L-leucine. (A) The uptake of ³H- ${alpha}$ -AAA (25 µM) by the mycelium of P. chrysogenum grown under penicillin-producing conditions was assayed in the presence of increasing concentrations of unlabeled L-leucine. The dashed line represents the best-fitting curve after computer-aided regression and curve fitting of the equation given in Materials and Methods (see "Amino acid transport assays with S. cerevisiae" above) to the measured data. (B and C) Assays of uptake of [³H] ${alpha}$ -AAA by S. cerevisiae M4276 cells expressing PcDIP5 and PcGAP1, respectively. Assay conditions were as described for panel A.

Amino acid transport assays with S. cerevisiae.
S. cerevisiae strains M4276 yEX-PcDIP5, M4276 yEX-PcGAP1, andM4276 yEX-C (empty vector) were grown overnight in MP mediumat 30°C. Cultures were then diluted 10-fold in fresh MPmedium, containing 0.2 mM CuSO₄ for induction of transcriptionof PcDIP5 or PcGAP1, and were grown to an optical density at600 nm (OD₆₀₀) of 0.4 to 0.8. Cells were harvested by centrifugation,washed with minimal medium without a nitrogen source (MM), andresuspended to an OD₆₀₀ of 10 in the same medium. Before thetransport assay was started, cells were incubated for 10 minat 30°C with stirring. Subsequently, 100 µl of thecell suspension was added to 150 µl of MM with 25 µM¹⁴C-labeled L-amino acid (0.05 µCi), and incubation wascontinued at 30°C with stirring. Uptake reactions were stoppedeither immediately after addition of the substrate or after30, 60, or 120 s by the addition of 2 ml of ice-cold 0.1 M LiCland subsequent suction filtration through a 0.45-µM-pore-sizenitrocellulose filter. Radioactivity retained on the filterswas measured in a scintillation counter. For K_m determinations,uptake of glutamate and aspartate at concentrations varyingfrom 10 to 2,500 µM was measured after 30 s to ensurelinearity with time. For K_m determinations of ${alpha}$ -AAA transport,uptake was assessed after 3 min. K_i values of leucine inhibitionwere determined at ${alpha}$ -AAA concentrations of 10 to 2,500 µM,in the presence or absence of L-leucine at 1 or 2.5 mM in PcDIP5-expressingcells and at 10 µM in PcGAP1-expressing cells. All uptakemeasurements with S. cerevisiae M4276 were made in at leasttwo independent experiments, and average values are given.

The K_m values for ${alpha}$ -AAA transport via PcDip5 and PcGap1 and therespective K_i values for the competitive inhibition by leucinewere used to assess the relative contributions of the two transportersto the uptake of ${alpha}$ -AAA by P. chrysogenum in the presence of increasingconcentrations of leucine. The data were analyzed by regressionaccording to Michaelis-Menten kinetics by using the followingequation:

where vis the observed rate of ${alpha}$ -AAA uptake; v_PcDip5 and v_PcGap1 arethe rates of uptake via PcDip5 and PcGap1, respectively; K_m_-PcDip5and K_m_-PcGap1 are the Michaelis constants and V_max-PcDip5 andV_max-PcGap1 are the maximal velocities for ${alpha}$ -AAA uptake via PcDip5and PcGap1, respectively; K_i_-PcDip5 and K_i_-PcGap1 are the inhibitionconstants for competitive inhibition by leucine of ${alpha}$ -AAA uptakevia PcDip5 and PcGap1, respectively; and [ ${alpha}$ -AAA] and [Leu] arethe concentrations of ${alpha}$ -AAA and leucine, respectively.

Semiquantitative RT-PCR.
Total RNA extracts were prepared by a Trizol-based method (Invitrogen,Breda, The Netherlands). The mycelium was frozen in liquid nitrogenand ground. Approximately 5 volumes of Trizol were added, andsamples were mixed thoroughly. After the addition of 1/5 volumeof chloroform and mixing, samples were spun for 15 min at 10,000rpm in a microcentrifuge. The RNA-containing water phase wascollected and further purified by phenol extraction. RNA wasprecipitated with ethanol and dissolved in H₂O. The RNA concentrationwas determined spectroscopically at 260 nm. Reverse transcriptasePCR (RT-PCR) was performed using RT-PCR beads (Amersham-Pharmacia,Freiburg, Germany) and a Perkin-Elmer thermocycler. Primerswere used that generated internal fragments of PcDIP5 (0.35kb) or PcGAP1 (0.5 kb) or the internal standard actA (0.8 kb),which served as a control to monitor the total amount of RNAused as a template. Samples were incubated at 42°C for 30min for reverse transcription, followed by a standard PCR underthe following conditions: 5 min at 95°C, followed by 22cycles of 30 s at 95°C, 30 s at 55°C, and 40 s at 72°C.PCR products were analyzed by gel electrophoresis.

Materials.
Uniformly labeled DL-[³H] ${alpha}$ -aminoadipate, with a specific activityof 38 Ci/mmol, was custom synthesized by Amersham PharmaciaBiotech.

Nucleotide sequence accession numbers.
The 2,580- and 1,997-kb sequences containing the P. chrysogenumPcDIP5 and PcGAP1 genes have been deposited in GenBank underaccession numbers AY456273 and AY456274, respectively.

RESULTS

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Results

Uptake of ${alpha}$ -AAA by P. chrysogenum Wisconsin 54-1255.
Since the general amino acid permease of P. chrysogenum transportsmost amino acids including glutamate and aspartate, and because ${alpha}$ -AAA inhibits glutamate uptake mediated by the acidic aminoacid permease (21), both of these permeases have been implicatedin the uptake of ${alpha}$ -AAA. However, this assumption has not beendirectly tested in experiments in which the uptake of ${alpha}$ -AAA ismeasured. Nor have the individual contributions of the two permeasesand other possible systems to ${alpha}$ -AAA uptake in P. chrysogenumcells grown at penicillin-producing conditions been determined.For that purpose, transport studies were performed with DL-[³H] ${alpha}$ -aminoadipate.The amino acid was used at a concentration of 25 µM. L-Leucineis a good substrate for the general amino acid permease andis not transported by the acidic amino acid permease (4, 21,22). Therefore, L-leucine was used for competition studies todistinguish between the two transporters. ${alpha}$ -AAA was readily accumulatedby the cells. The inhibition profile of ${alpha}$ -AAA uptake by P. chrysogenumin the presence of increasing concentrations of L-leucine showedtwo distinguishable inhibition effects (Fig. 1A). At low L-leucineconcentrations, up to 100 µM, the uptake of ${alpha}$ -AAA was readilyreduced by 45 to 50%, whereas higher concentrations of L-leucineup to 2.5 mM only marginally inhibited the remaining ${alpha}$ -AAA uptake.These data suggest that a major fraction of the ${alpha}$ -AAA uptakeis mediated by the general amino acid permease, but they alsoshow that there is a residual uptake which is minimally inhibitedby higher concentrations of L-leucine.

Cloning of the acidic amino acid permease gene PcDIP5.
To define the exact identity of the transporters involved in ${alpha}$ -AAA, it is necessary to clone the genes and analyze their activitiesseparately. Since the residual ${alpha}$ -AAA uptake in the presence ofexcess L-leucine could be inhibited by unlabeled glutamate (datanot shown), we decided, in addition to the general amino acidpermease, to clone the acidic amino acid permease. In S. cerevisiae,acidic amino acids (glutamate and aspartate) can be taken upby the general amino acid permease Gap1, as well as by the acidicamino acid permease Dip5 (33). A mutant strain that lacks boththe Gap1 and Dip5 genes, M4276, has been described. This mutantis deficient in acidic amino acid transport and therefore cannotgrow with glutamate or aspartate as the sole nitrogen source(33). In contrast to the parental strain, S. cerevisiae M4276is also unable to accumulate ${alpha}$ -AAA, which indicates that thereare no other routes for uptake of this molecule in S. cerevisiae(data not shown). Strain M4276 was used for a functional complementationcloning strategy to identify transporters that mediate dicarboxylicamino acid uptake. A cDNA library of P. chrysogenum was expressedin S. cerevisiae M4276, and cells were selected on plates andliquid media containing L-glutamate as the sole nitrogen source.Cells that grow on these media must have acquired a transportsystem that is capable of glutamate uptake. This procedure yieldedone clone that could grow with glutamate as the sole nitrogensource. The cDNA of the clone contained a 1,677-bp open readingframe encoding a 559-amino-acid protein that is 47% identicalto Dip5 (Fig. 2) and 30 to 34% identical to Gap1 and other aminoacid permeases of S. cerevisiae. The gene was designated PcDIP5.

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FIG. 2. Amino acid sequence alignment of the acidic amino acid permeases of P. chrysogenum (PcDip5) and S. cerevisiae (Dip5) (33) and putative acidic amino acid permeases of A. nidulans (AnDip5) and Kluyveromyces lactis (KlDip5). The A. nidulans sequence, 57% identical to that of PcDip5 and 50% identical to that of Dip5, was derived from the A. nidulans database of the Whitehead Institute after a BLAST search (2). This sequence is incomplete at the N terminus. The K. lactis sequence was obtained after a BLAST search at the National Center for Biotechnology Information; it shares 61% amino acid identity with Dip5 and 50% identity with PcDip5. Conserved and similar amino acids are highlighted in black and grey, respectively.

Cloning of the general amino acid permease gene PcGAP1.
Despite several attempts, selection for complementation of glutamateuptake in S. cerevisiae with the partial cDNA library did notyield a general amino acid permease. Therefore, an alternativePCR approach using degenerate primers based on the alignmentof five known general amino acid permeases was employed. Withthese primers, a 424-bp PCR fragment was obtained that, upontranslation into amino acids, showed high homology with S. cerevisiaeGap1. The fragment was used to probe a genomic library fromwhich the full-length gene was isolated. The entire gene consistsof a 1,751-bp open reading frame interrupted by three intronsof 63, 55, and 35 bp and encodes a protein of 581 amino acids.After a BLAST search (2), the highest homology was found withknown general amino acid permeases of S. cerevisiae (Gap1; 50%identity), Candida albicans (Gap1; 47%), and N. crassa (Naap1;48%) (Fig. 3). The gene was therefore designated PcGAP1.

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FIG. 3. Sequence alignment of the general amino acid permeases of P. chrysogenum (PcGap1), S. cerevisiae (Gap1) (24), C. albicans (CaGap1) (6), Aspergillus fumigatus (AfGap1), and N. crassa (NcGap1; encoded by the pmg locus) (28). AfGap1 is a putative general amino acid permease, based on its homology with PcGap1 (78% amino acid identity) and Gap1 (55% identity), and was obtained from the A. fumigatus Genome Database at The Institute for Genomic Research after a BLAST search (2). NcGap1 was originally deposited with GenBank as NAAP1. Conserved and similar amino acids are highlighted in black and grey, respectively.

Overexpression of PcDIP5 and PcGAP1 in S. cerevisiae M4276 and transport characteristics.
The plasmids isolated from the cDNA library, yEX-PcDIP5 andyEX-PcGAP1, were used for functional characterization of thetransporters in S. cerevisiae M4276. As a negative control,M4276 was transformed with the empty vector yEX-C. Cells wereincubated with CuSO₄ for induction of expression and were analyzedfor the uptake of a range of amino acids (42). Cells expressingPcDIP5 readily accumulated L-glutamate and L-aspartate, while ${alpha}$ -AAA was taken up at a lower rate (Fig. 4A). L-Asparagine wasaccumulated slowly, whereas for L-glutamine and L-serine nosignificant difference was observed between the PcDip5 and controlcells (data not shown). The affinity (K_m) of PcDip5 for theuptake of L-glutamate and L-aspartate was about 35 µM,while the K_m for ${alpha}$ -AAA uptake appeared rather high, i.e., 800µM. Since the ³H-labeled ${alpha}$ -AAA represents a racemic mixtureof the D and L configurations, further competition experimentswere performed with the unlabeled stereoisomers. A 100-foldexcess of unlabeled D- ${alpha}$ -AAA did not inhibit uptake of labeledDL- ${alpha}$ -aminoadipate, whereas an excess of L- ${alpha}$ -AAA decreased uptakeby more than 90%. This shows that PcDip5 is specific for theL configuration (data not shown). Taken together, these resultsdemonstrate that the cloned permease, PcDip5, corresponds tothe acidic amino acid permease of P. chrysogenum.

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FIG. 4. Time-dependent uptake of acidic amino acids by S. cerevisiae M4276 expressing PcDIP5 (A) or PcGAP1 (B). Cells containing the empty vector were used as controls (open symbols). The inset in panel A shows the uptake of ${alpha}$ -AAA with an adjusted scale. Uptake assays were performed with cells grown to exponential phase in MP medium, and expression of PcDIP5 was induced with 0.2 mM CuSO₄ 5 h before harvesting.

For cells expressing PcGAP1, the uptake of 19 amino acids, includingthe nonprotein amino acids L-citrulline, DL- ${alpha}$ -aminoadipate, L- ${alpha}$ -aminoisobutyricacid, and L-ornithine, was measured (Fig. 5). For all aminoacids except L-proline, a significant increase of at least twofoldin uptake was observed upon expression of PcGAP1. These datasuggest either that L-proline is not a substrate for PcGap1or that in cells overexpressing PcGAP1, the background uptakevia endogenous proline permease(s) is reduced due to the expressionof PcGAP1. The acidic amino acids glutamate and aspartate wereaccumulated more slowly by PcGAP1-expressing cells than by PcDIP5-expressingcells (Fig. 4B). However, since the total amount of PcGap1 orPcDip5 protein in these cells is unknown, the exact V_max valuescannot be compared. Strikingly, ${alpha}$ -AAA was readily accumulated,with a K_m of 230 µM. This affinity is more than 3 timeshigher than that observed for PcDip5. The general amino acidpermeases of S. cerevisiae and N. crassa have been reportedalso to transport some D amino acids (20), but like PcDip5,PcGap1 was found to transport ${alpha}$ -aminoadipate only in the L configuration(data not shown). These data demonstrate that the cloned genePcGAP1 encodes the general amino acid permease of P. chrysogenum.

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FIG. 5. Uptake of amino acids by S. cerevisiae M4276 expressing PcGAP1. Cells were incubated for 3 min with the indicated radioactively labeled amino acids at a final concentration of 25 µM. Solid or open bars, levels of uptake by cells expressing PcGAP1 (yEX-PcGAP1) or cells with the empty vector (yEX-C), respectively.

Inhibition of PcDip5- or PcGap1-mediated ${alpha}$ -AAA uptake by leucine.
The biphasic inhibition by L-leucine of ${alpha}$ -AAA uptake by the P.chrysogenum mycelium (Fig. 1A) was explained by the presenceof at least two different uptake routes for ${alpha}$ -AAA: uptake viathe general amino acid permease, which is strongly inhibitedby L-leucine, and uptake via a specific amino acid permeasethat is nearly insensitive to L-leucine. To validate this hypothesis,we reinvestigated the inhibition by leucine of ${alpha}$ -AAA uptake inS. cerevisiae M4276 expressing PcDIP5 and, separately, in M4276expressing PcGAP1 (Fig. 1B and C). Indeed, PcGap1-mediated ${alpha}$ -AAAuptake was strongly inhibited by L-leucine (Fig. 1C) at exactlythe concentration range that was inhibitory in P. chrysogenumcells. In contrast, PcDip5-mediated uptake was inhibited byL-leucine only at high concentrations (Fig. 1B). The K_i forleucine inhibition of PcGap1-mediated uptake was 10 µM,and for PcDip5-mediated uptake the K_i was around 6.3 mM. Thishigh K_i is not in perfect agreement with the inhibition patternshown in Fig. 1B, which should have a flatter slope. Therefore,a nonspecific effect by leucine seems to inhibit ${alpha}$ -AAA uptakevia PcDip5.

The various K_m and K_i values were used for computer modelingof ${alpha}$ -AAA uptake by using the equation given in Materials andMethods (see "Amino acid transport assays with S. cerevisiae"above), which describes the relative contributions of the twotransporters according to Michaelis-Menten kinetics. The datawere fitted by regression to the data shown in Fig. 1A. Thebest-fitting curve (Fig. 1A) showed an imperfect fit with thedata measured at higher leucine concentrations, indicating thatthe uptake process is more complex than that described by theequation. From the regression analysis, the relative contributions(maximal velocities) of PcDip5 and PcGap1 to ${alpha}$ -AAA uptake inthe absence of leucine could be calculated as correspondingto 51 and 49%, respectively. This is in good agreement witha more phenomenological analysis in which it is considered thatnearly 95% of the ${alpha}$ -AAA uptake activity of PcGap1 is alreadyinhibited at 250 µM L-leucine, while the inhibition ofPcDip5 at this concentration is, at most, 5% (Fig. 1B and C).This would also yield an estimated 50% contribution of eachpermease (Fig. 1A). Thus, PcDip5 and PcGap1 seem to make equalcontributions to the uptake of ${alpha}$ -AAA when each is present at25 µM. Taking the difference in K_m into account, a greaterfraction of the ${alpha}$ -AAA flux will be mediated by PcDip5 with increasing ${alpha}$ -AAA concentrations. Taken together, these data strongly suggestthat the uptake of ${alpha}$ -AAA by P. chrysogenum involves two transporters,PcGap1 and PcDip5.

Expression of PcDIP5 and PcGAP1 in response to nitrogen source and carbon source.
In fungi, the activity of amino acid permeases is regulatedboth at the transcriptional and the posttranslational level(20, 37, 38, 40, 41). To analyze the expression of PcDIP5 andPcGAP1 in P. chrysogenum, an RT-PCR method was used. The myceliumwas grown in liquid culture with different nitrogen and carbonsources and in penicillin production medium (with lactose asthe carbon source and with urea and glutamate as nitrogen sources).After preculturing of P. chrysogenum Wisconsin 54-1255 on YPGmedium, germinating conidia were transferred to minimal mediacontaining NH₄⁺ (a rich nitrogen source), urea (a poor nitrogensource), glutamate (a substrate of PcDip5 and PcGap1), serine,or lysine (substrates of PcGap1) as the sole nitrogen sourceand glucose as the carbon source. After 24 h of incubation,mRNA was isolated and used as a template for semiquantitativeRT-PCR (Fig. 6A). Expression of PcDIP5 and PcGAP1 was inducedwhen the mycelium was grown with glutamate, whereas in the presenceof NH₄⁺, expression was very low. With urea, PcDIP5 was notexpressed, while PcGAP1 showed only low expression. With serine,both genes were expressed at moderate levels. In contrast tothe findings for PcDIP5, lysine was as effective as glutamateat inducing the expression of PcGAP1. However, lysine appearsnot to be a very good nitrogen source, since the cultures grewslowly as mycelial pellets. This morphological behavior is indicativeof stress.

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FIG. 6. RT-PCR expression analysis of PcDIP5 and PcGAP1 in P. chrysogenum grown under different conditions. Expression of PcDIP5 and PcGAP1 was determined after 24 h of growth on minimal medium containing glucose as the carbon source and different nitrogen sources (A) or on various media as indicated (B). Penicillin production medium (pen prod) contains urea and glutamate as nitrogen and carbon sources, respectively. The other three media are minimal media with lactose (lact) or glucose (gluc) as the sole carbon source and glutamate or urea as the sole nitrogen source. Isolated mRNA was used as a template for semiquantitative RT-PCR. The expression analysis provides relative information for one gene only; analyses for different genes should not be compared.

To test whether PcDIP5 and PcGAP1 are expressed under conditionsof penicillin production and/or are subject to carbon cataboliterepression, P. chrysogenum Wisconsin 54-1255 was grown for 48h on either YPG, penicillin production medium containing lactoseas the carbon source, or minimal medium with glutamate or ureaas the sole nitrogen source and lactose or glucose as the carbonsource (Fig. 4B). Under penicillin-producing conditions, PcDIP5and PcGAP1 were moderately expressed in comparison with theother tested growth conditions. Nevertheless, substantial ratesof ${alpha}$ -AAA uptake were observed via PcGap1 and PcDip5 under theseconditions (see Fig. 1A). The pattern of expression did notchange significantly after 72 h of growth (data not shown).Carbon catabolite repression was not observed in any of themedia tested. Expression of PcGAP1 was much lower when cellswere growing on lactose and urea than on glucose and urea (Fig.6B, last two lanes). In addition, growth on YPG with glucoseas the carbon source did not repress PcGAP1 or PcDIP5 expression.Although nitrogen catabolite repression was observed in thepresence of NH₄⁺, PcDIP5 and PcGAP1 seem not to be under thecontrol of carbon catabolite repression. Both transporters areexpressed when cells are grown with glutamate or serine as thesole nitrogen source, whereas PcGAP1 is also expressed whenurea is used as the sole nitrogen source.

DISCUSSION

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Discussion

When ${alpha}$ -AAA is fed to the penicillin-producing mycelium of P.chrysogenum, a higher intracellular ${alpha}$ -AAA concentration and ahigher penicillin synthesis rate can be observed (13, 19). Theexact mechanism of uptake of ${alpha}$ -AAA has not been studied before.Here we demonstrate that both the acidic and general amino acidpermeases (PcDip5 and PcGap1) contribute to ${alpha}$ -AAA uptake in P.chrysogenum when cells are grown under conditions that resultin penicillin production. Although the studies with the clonedgenes in S. cerevisiae indicate that PcGap1 has a higher affinityfor ${alpha}$ -AAA, it appears that each system contributes equally to ${alpha}$ -AAA uptake by P. chrysogenum when ${alpha}$ -AAA present at 25 µM.Taking the kinetic parameters into account, one can predictthat the contribution of PcDip5 will increase with the ${alpha}$ -AAAconcentration and will reach a maximum at about 70 to 77% oftotal uptake. The transport assays were performed at pH 6.0,but since PcGap1 has a preference for the uncharged form ofglutamate (21), the contribution of PcGap1 to ${alpha}$ -AAA uptake mayincrease at lower pHs. Although we cannot exclude the possibilitythat in addition to PcGap1 and PcDip5, other permeases mightbe involved in ${alpha}$ -AAA uptake, the studies with the S. cerevisiaemutant indicate that at least in yeast, Gap1 and Dip5 are themajor permeases for uptake of this molecule. In other fungialso, no other transporters have been identified that couldparticipate in the uptake of negatively charged amino acids.

Feeding of penicillin fermentations with external ${alpha}$ -AAA is nota cost-effective process. Therefore, at first sight it appearsthat the transporters identified would be of little benefitto the fermentation. However, transporters not only functionin the uptake of compounds but also prevent the loss of criticalnutrients by cells. In this regard, the permeases identifiedmay be important for the retention of intracellular ${alpha}$ -AAA. InA. nidulans, two ammonium transporters have been identified,MeaA and MepA, that are required for the retention of intracellularammonium (30). Surprisingly, MeaA, which exhibits a lower affinityfor ammonium (K_m, 3 mM), appears more important for retentionthan the high-affinity ammonium permease MepA (K_m, 44 µM).It is not known to what extent losses of intracellular ${alpha}$ -AAAin P. chrysogenum to the medium occur during industrial fermentation.However, processes such as fragmentation of the hyphae by agitationor leakage across the membrane could potentially lead to significantlosses. PcGap1 and PcDip5 might be involved in reuptake. Ourresults suggest that PcDIP5 and PcGAP1 are both moderately expressedin shaking flask cultures when penicillin-producing conditionsprevail, i.e., when lactose is used as the carbon source andurea and glutamate are nitrogen sources. However, these conditionsare not identical to those in industrial fermentation (25, 31),where glucose is fed to the cells in a fed-batch fermentation.Carbon catabolite repression, however, was not observed forPcGAP1 or PcDIP5. On the contrary, the mRNA level of PcGAP1was much higher when cells were grown in minimal medium withurea as the sole nitrogen source and glucose as the carbon sourcethan in a medium with lactose as the sole carbon source. Alsoin YPG medium with glucose, significant levels of PcGAP1 andPcDIP5 expression were observed. It should be stressed thatthe final activities of these permeases also depend on posttranslationalregulatory phenomena. For instance, for Gap1 of S. cerevisiaegrowing with glutamate as the sole nitrogen source, a high mRNAlevel is observed but the transport activity is low. This hasbeen attributed to the sorting of Gap1 to the vacuole insteadof the plasma membrane (11, 38).

In conclusion, externally added ${alpha}$ -AAA can be taken up by P. chrysogenumvia the acidic amino acid permease PcDip5 and the general aminoacid permease PcGap1. Even though transport occurs with relativelylow affinity, a significant flux of ${alpha}$ -AAA uptake can be detectedin mycelia grown under penicillin-producing conditions. Thesetransporters may contribute to the maintenance of a high ${alpha}$ -AAAconcentration within the cell to allow a high ß-lactamproduction capacity.

ACKNOWLEDGMENTS

S. cerevisiae strain M4276 was kindly provided by M. C. Kielland-Brandt(Department of Physiology, Carlsberg Laboratory, Copenhagen,Denmark). We thank Wil Konings for his interest in this work.

This work was supported by the Eurofung, European Community(grant QLK3-CT-1999-00729).

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, University of Groningen, Kerklaan 30, 9751 NN Haren, The Netherlands. Phone: 31-50-3632164. Fax:. 31-50-3632154. E-mail: a.j.m.driessen{at}biol.rug.nl.

REFERENCES

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