Purine Biosynthesis, Riboflavin Production, and Trophic-Phase Span Are Controlled by a Myb-Related Transcription Factor in the Fungus Ashbya gossypii

Ashbya gossypii is a natural riboflavin overproducer used inthe industrial production of the vitamin. We have isolated aninsertional mutant exhibiting higher levels of riboflavin productionthan the wild type. DNA analysis of the targeted locus in themutant strain revealed that a syntenic homolog of the Saccharomycescerevisiae BAS1 gene, a member of the Myb family of transcriptionfactors, was inactivated. Directed gene disruption of AgBAS1confirmed the phenotype observed for the insertional mutant,and the ${Delta}$ bas1 mutant also showed auxotrophy for adenine and severalgrowth defects, such as a delay in the germination of the sporesand an abnormally prolonged trophic phase. Additionally, wedemonstrate that the DNA-binding domain of AgBas1p is able tobind to the Bas1-binding motifs in the AgADE4 promoter; we alsoshow a clear nuclear localization of a green fluorescent protein-Bas1fusion protein. Real-time quantitative PCR analyses comparingthe wild type and the ${Delta}$ bas1 mutant revealed that AgBAS1 was responsiblefor the adenine-mediated regulation of the purine and glycinepathways, since the transcription of the ADE4 and SHM2 geneswas virtually abolished in the ${Delta}$ bas1 mutant. Furthermore, thetranscription of ADE4 and SHM2 in the ${Delta}$ bas1 mutant did not diminishduring the transition from the trophic to the productive phasedid not diminish, in contrast to what occurred in the wild-typestrain. A C-terminal deletion in the AgBAS1 gene, comprisinga hypothetical regulatory domain, caused constitutive activationof the purine and glycine pathways, enhanced riboflavin overproduction,and prolonged the trophic phase. Taking these results together,we propose that in A. gossypii, AgBAS1 is an important transcriptionfactor that is involved in the regulation of different physiologicalprocesses, such as purine and glycine biosynthesis, riboflavinoverproduction, and growth.

INTRODUCTION

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Introduction

Ashbya gossypii is a filamentous hemiascomycete of considerableimportance in biotechnology due to its natural ability to overproduceriboflavin (vitamin B₂) (5), an essential factor for humansand animals that is frequently used as a food additive (38).A. gossypii overproduces riboflavin as a detoxifying and protectivemechanism during the late growth phase, when the maximum mycelialmass has been reached (37). Thus, in terms of riboflavin production,two stages can be differentiated during A. gossypii culture:a trophic phase when riboflavin production is minimal and thegrowth rate increases, and a productive phase when the growthrate decreases and riboflavin is overproduced (37). Many physiologicaland morphological changes occur during the shift from the trophicto the productive phase (27, 37), but the mechanisms triggeringthe transition are not fully understood. The productive phaseis associated with a characteristic intense yellow color ofthe mycelia, due to the accumulation of the vitamin in the vacuolarcompartment (9). During the past few years, different studieshave been carried out with a view to improving the excretionof the vitamin (8) and also to increasing the metabolic fluxfor riboflavin biosynthesis (16, 17, 25, 35).

Riboflavin is synthesized from GTP and ribulose 5-phosphatein a six-step pathway governed by the RIB genes (RIB1 to RIB5and RIB7) (3). For A. gossypii, it has been shown that riboflavinproduction is correlated with the activity of the Rib3 protein(34). However, enhanced riboflavin overproduction has been reportedonly when GTP precursors are added to the medium or when thepurine or glycine pathways are engineered to provide high concentrationsof GTP precursors (16, 21, 25, 35, 38). This indicates thatGTP availability is a limiting factor for riboflavin productionin A. gossypii.

GTP is formed in the cell through the de novo purine pathway(Fig. 1), which starts with the conversion of 5'-phosphoribosyl-1-pyrophosphate(PRPP) to IMP, after which IMP can be transformed into AMP orGMP (30). Alternatively, purine salvage pathways (Fig. 1) allowthe interconversion and recycling of purines with the consumptionof PRPP (30). The purine salvage pathways contribute to a correctbalance between adenyl and guanyl nucleotides. In fact, maintenanceof this balance is essential for cell viability; hence, thebiosynthesis of purines relies on several regulatory mechanismsat the transcriptional and metabolic levels (4, 10, 11, 13,14, 22, 40).

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FIG. 1. Schematic representation of the purine biosynthetic pathway. Black arrows designate the de novo pathway, and gray arrows indicate the salvage pathways. Gly, glycine; GMP, guanosine 5'-monophosphate; Ade, adenine, Gua, guanine; Xan, xanthine. The gene names are italicized and correspond to the following enzymatic activities: PRS, PRPP synthetase; ADE4, PRPP amidotransferase; SHM1 and SHM2, serine hydroxymethyltransferase; IMD1, IMP dehydrogenase; AMD1, AMP deaminase; APT1, adenine phosphoribosyltransferase; XPT1, xanthine phosphoribosyltransferase; ADK1, adenylate kinase; RIB, riboflavin genes.

In Saccharomyces cerevisiae, it has been shown that a complexformed between the transcription factors Bas1 and Bas2 (Pho2)is required for the transcriptional activation of the de novopurine pathway under adenine deprivation (4). In addition, Bas1and Bas2 also activate the biosynthesis of histidine, glutamine,glycine, and 10-formyl tetrahydrofolate (2, 7), which are purine-relatedpathways (see Fig. 5 in reference 31).

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FIG. 5. Comparison of the steady-state transcription levels of purine and riboflavin genes in wild-type and ${Delta}$ bas1 strains. (A) Differences in the transcription levels of the genes included in the assays between wild-type and ${Delta}$ bas1 strains grown in MA2 rich medium. (B) Relative transcription levels of the indicated genes measured in the wild-type (gray bars) and ${Delta}$ bas1 (white bars) strains grown in MA2 rich medium with (+ade) or without (–ade) an excess of adenine (0.1 g/liter). Transcription levels are normalized to the level of AgACT1 mRNA. The ratio of relative transcription of the target gene in panel A was calculated as 2^–Ct, where ${Delta}$ ${Delta}$ Ct = ${Delta}$ Ctbas1 – ${Delta}$ Ct_{wild type}. The ratio of the relative transcription of the target gene in panel B was calculated as 2^–Ct, where ${Delta}$ ${Delta}$ Ct = ${Delta}$ Ct_MA2 ₊ _ade – ${Delta}$ Ct_MA2 _– _ad_e. An average of three separate cDNA dilutions from each target gene were obtained, and the relative transcription levels were expressed as log₂ ± SD. vs, versus; WT, wild type.

Current studies have reported that two intermediates of thepurine pathway, namely, 5'-phosphoribosyl-4-succinocarboxamide-5-aminoimidazole(SAICAR) and 5'-phosphoribosyl-4-carboxamide-5-aminoimidazole(AICAR), are intracellular signals that promote the interactionbetween Bas1 and Bas2 and, hence, transcriptional activation(30, 31). Unlike SAICAR, AICAR is also synthesized through thehistidine pathway, again confirming the cross talk between purineand histidine biosynthesis (4, 30).

Bas1 is a Myb-related transcription factor comprising an amino-terminalDNA-binding domain that binds to the sequence TGACTC (15, 39),an internal trans-activation domain, and a C-terminal domaincalled the Bas1 interaction and regulatory domain (BIRD) forinteraction with Bas2 and regulation of the trans-activationdomain (28). A recent report has suggested that Bas1 is permanentlybound to DNA, with the trans-activation domain being inactivewhen adenine is present in the medium. Under conditions of adeninelimitation, a regulatory signal, probably dependent on SAICARand AICAR, increases the Bas1-Bas2 interaction; Bas2 is recruitedto the promoters, and the trans-activation domains of Bas1 andBas2 are unmasked for transcriptional activation (31, 36).

Here, we describe the identification and characterization ofthe transcription factor Bas1 in the filamentous fungus A. gossypii.AgBas1p participates in the regulated transcription of genesinvolved in the biosynthesis of purines and glycine. In addition,different bas1 mutants showed a significant increase in theproduction of riboflavin and other growth-related phenotypes.The involvement of AgBAS1 in different processes of the A. gossypiiphysiology and its implications for the biotechnological productionof riboflavin are discussed.

MATERIALS AND METHODS

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Materials and Methods

A. gossypii strains, media, and growth conditions.
The A. gossypii ATCC 10895 strain was used and considered awild-type strain. A. gossypii strains were cultured in richmedium (MA2) (9) or synthetic minimal medium (SMM) (35) at 28°C.Amino acids adenine and guanine were purchased from Sigma (Steinheim,Germany) and were used at a final concentration of 0.1 g/liter.A concentration of 250 µg/ml for Geneticin (G418) (Sigma,Steinheim, Germany) or 200 µg/ml for hygromycin B (PhytotechnologyLaboratories, Shawnee Mission, Kans.) was used when stated.Sporulation conditions and spore isolations were carried outas previously described (33). Liquid cultures were inoculatedwith 1 x 10⁶ spores per liter of medium and were performed ona rotary shaker at 120 rpm. The determination of riboflavinproduction was performed by high-performance liquid chromatographyas described previously (35).

Insertional mutagenesis and targeted locus identification.
A detailed description of the method has been previously reportedelsewhere (33). Briefly, an in vitro transposition reactionusing A. gossypii genomic DNA digested with PstI and a minitransposonR comprising the 5' and 3' inverted terminal repeats from theHimar1 transposon flanking the dominant G418 resistance markerand the bacterial replicon ColE1 was performed. After the transpositionreaction, the genomic DNA carrying an integrated minitransposonR was self-ligated and used to transform the Escherichia coliDH10B strain.

To generate insertional mutants, the plasmid library was linearizedby enzymatic digestion with PstI and used to transform the wild-typeA. gossypii strain. The G418^r A. gossypii colonies were sporulatedand plated onto selective medium (MA2 plus G418) again. After4 days, colonies exhibiting a bright yellow color were selectedfor further analyses. Genomic DNA from the insertional mutantswas isolated, digested with XhoI, self-ligated, and transformedinto E. coli DH10B. The transformants carrying the minitransposonR flanked by genomic DNA were selected on LB-kanamycin (50 µg/ml)plates. The identification of the targeted loci was achievedby sequence analysis using primers derived from the left andright ends of the minitransposon R, respectively. Determinationof the full-length sequences was performed using primer-walkingstrategies.

Construction of the ${Delta}$ bas1 strain.
To construct the ${Delta}$ bas1 strain, a disruption cassette was engineered.An internal BamHI-SphI fragment of the AgBAS1 open reading frame(ORF) was replaced with the G418^r marker obtained as a BamHI-SphIfragment (33). The disruption module was obtained as a XhoI-BglIIfragment with a 356-bp 5'-flanking region and a 520-bp 3'-flankingregion homologous to the AgBAS1 locus. This fragment was usedto transform spores of the wild-type strain of A. gossypii.Primary G418^r heterokaryotic transformants were sporulated and,after clonal selection, G418^r ${Delta}$ bas1 homokaryotic colonies wereisolated. The disruption of AgBAS1 was confirmed by analyticalPCR and Southern blotting.

RNA extraction, reverse transcription-PCR, and real-time PCR.
A. gossypii mycelium (200 to 300 mg), previously frozen, wasmechanically homogenized in liquid nitrogen using TRIzol reagent(Invitrogen, Carlsbad, Calif.), and total RNA was isolated asdescribed by the manufacturer. RNA was incubated with 20 U ofRNase-free DNase I (Roche, Basel, Switzerland), and 5 µgof total RNA was reverse transcribed using an oligo(dT) primer(Isogen, Ijsselstein, The Netherlands) and SuperScript II RTenzyme (Invitrogen, Carlsbad, Calif.).

For real-time quantitative PCR, three serial dilutions (1:10,1:20, and 1:30) of the synthesized cDNA were amplified withtarget gene-specific primers (see Table S1 in the supplementalmaterial) using an iCycler iQ system (Bio-Rad, Hercules, Calif.).The following conditions were used: heat activation of DNA polymerasefor 15 min at 95°C; 42 cycles of PCR at 95°C for 30s, 55°C for 30 s, and 72°C for 40 s; and a final incubationat 72°C for 10 min. For each PCR product, melting curveswere determined according to the supplier's guidelines (Bio-Rad,Hercules, Calif.), ensuring specific amplification of the targetgene. Quantitative values were obtained as the threshold PCRcycle number (Ct) when the increase in the fluorescent signalof the PCR product showed exponential amplification. The targetgene mRNA level was normalized to that of AgACT1 (encoding ß-actin)in the same sample. The relative transcription level of thetarget gene was calculated using the 2^–Ct method, where ${Delta}$ ${Delta}$ Ct = (Ct_{target gene} – Ct_Ag_ACT1)_{condition X} – (Ct_targetgene – Ct_Ag_ACT1)_{condition Y} (19). The mean of the resultswas obtained after the 2^–Ct was calculated for three serialcDNA dilutions of each sample in triplicate, and the relativetranscription levels were expressed as means ± standarddeviations (SD).

N-terminal AgBAS1 tagging with GFP(S65T).
With PCR methods, an expression module containing a hygromycinresistance marker (Hyg^r) and the green fluorescent protein S65T[GFP(S65T)] coding region (20) in frame with the AgBAS1 ORFunder the control of the constitutive promoter of the glyceraldehyde3-phosphate dehydrogenase-encoding gene AgGPD was constructed.The wild-type AgBAS1 locus was replaced with the expressionmodule described above, and the replacement was verified bySouthern blot analysis.

Nuclear DNA was stained with the DNA-specific dye Hoechst 33342(HO) (Sigma, Steinheim, Germany). The fluorescence of the GFP-Bas1pfusion protein in living cells was monitored as previously described(26). Micrographs were acquired using a Photometrics Sensyscharge-coupled-device camera coupled to a Leica DMXRA microscopeequipped with Nomarski optics and epifluorescence.

Expression and purification of the N-terminal domain of the Bas1p from A. gossypii.
The DNA sequence corresponding to the N-terminal domain of theAgBas1 (amino acids 1 to 305) was PCR amplified and cloned intothe NdeI and XhoI site of the pET-28b expression vector (Novagen,Darmstadt, Germany) and used to transform the E. coli BL21 (DE3)strain. A single positive colony was inoculated in LB mediumplus kanamycin (50 µg/ml) and grown at 37°C untilthe A₆₀₀ reached 1. Induction of the His-tagged recombinantprotein was achieved by the addition of 1 mM isopropyl-ß-D-thiogalactopyranoside.After 1 h of induction, the cells were harvested and resuspendedin lysis buffer (50 mM NaH₂PO₄, pH 8; 10 mM Tris-HCl, pH 8;100 mM NaCl) containing protease inhibitor cocktail (Roche,Basel, Switzerland). Cells were disrupted by sonication for30 min, and the homogenates were centrifuged at 10,000 x g for10 min. The His-tagged recombinant protein was purified fromthe supernatant using a Talon (Clontech, Heidelberg, Germany)column, following the manufacturer's instructions. Pure fractionswere stored at –20°C until use.

Electrophoretic mobility shift assay.
Electrophoretic mobility shift assays (EMSAs) were performedessentially as described previously (15). The binding reactionwas performed over 30 min at room temperature. In each reaction,1 x 10⁵ to 5 x 10⁵ cpm of a labeled DNA probe (0.3 to 0.5 pmol)and 0.1 to 1 µg of recombinant His-AgN305Bas1 peptidewere used. The binding buffer was 20 mM Tris-HCl, 0.1 mM EDTA,10% glycerol (vol/vol), 100 mM NaCl, 0.01% Triton X-100 (vol/vol),and protease inhibitor cocktail (Roche, Basel, Switzerland).For competition binding reactions, the unlabeled competitorat 100- and 200-fold molar excess was used. A DNA fragment correspondingto the AgGPD promoter (384 bp) was used as nonspecific competitor.The reaction mixtures were loaded onto a 5 to 8% native polyacrylamidegel in 1x TBE (89 mM Tris-HCl, 89 mM boric acid, 2 mM EDTA [pH8.0]), electrophoresed, dried, and exposed to X-ray film at–80°C with an intensifying screen.

Construction of the ${Delta}$ C631BAS1 strain.
The truncated AgBAS1 gene was generated by PCR-mediated modifications.A PCR-derived module containing the 50-bp fragment upstreamfrom the codon encoding amino acid 631 of the AgBas1p followedby the ScADH1 terminator, the G418^r marker, and the 50-bp fragmentdownstream from the AgBAS1 stop codon were used to transformwild-type A. gossypii spores. The truncated Ag ${Delta}$ C631BAS1 genewas integrated in the BAS1 locus. As described above, homokaryoticclones were isolated, and the truncation of AgBAS1 gene wasconfirmed by Southern blotting (see Fig. 7A).

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FIG. 7. Characterization of the ${Delta}$ C631BAS1 strain. (A) Growth pattern of ${Delta}$ C631BAS1 strain grown in liquid MA2 rich medium in comparison with the wild-type and ${Delta}$ bas1 strains. (B) Relative transcription levels of purine and riboflavin genes in the wild-type (gray bars) and the ${Delta}$ C631BAS1 (white bars) strains grown in MA2 rich medium with (+ade) or without (–ade) an excess of adenine (0.1 g/liter). Transcription levels are normalized to the level of AgACT1 mRNA. The ratio of the relative transcription of the target gene was calculated as 2^–Ct, where ${Delta}$ ${Delta}$ Ct = ${Delta}$ Ct_MA2 ₊ _ade – ${Delta}$ Ct_MA2 _– _ade. An average of three separate cDNA dilutions from each target gene was obtained, and the relative transcription levels are expressed as log₂ ± SD.

RESULTS

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Results

Identification and characterization of a riboflavin-overproducing mutant.
From a collection of A. gossypii mutants generated by an insertionalmutagenesis method developed specifically for the purpose (33),a colony exhibiting a deep yellow color was selected (Fig. 2A);it proved to accumulate 5.5-fold (14.42 mg/g) more riboflavinthan the wild-type strain. The presence in the Himar1-derivedtransposon module of a G418 resistance (G418^r) selectable markerand the oriC replication origin allowed the recovery and identificationof the genomic integration site (see Materials and Methods fordetails). Once the integration site had been cloned and sequenced,primers were made to amplify the targeted ORF. DNA analysisrevealed that the Himar1-derived transposon had integrated intoa TA dinucleotide located 697 bp downstream from the initiationcodon. A BLAST search in the Ashbya Genome Database (http://agd.unibas.ch/)identified the target as a nonexperimentally characterized ORF(the database identified the gene as AFR297W, also designatedAgBAS1), a syntenic homolog of the S. cerevisiae BAS1 gene,which encodes a transcription factor of the Myb family (39).The predicted amino acid sequence of AFR297W was aligned withScBas1 and human c-Myb and showed low identity with ScBas1 (31.4%)and with human c-Myb (13.7%). However, the level of identityin the N-terminal domain was significantly higher (58.8% withScBas1 and 21.5% with human c-Myb); using the ScanProsite tool(http://www.expasy.org/tools/scanprosite/), it was possibleto identify the three signatures distinctive of the Myb family(15) (see Fig. S1 in the supplemental material). We also detecteda hypothetical BIRD interaction domain within the Afr297w sequence(residues 630 to 664) compared with ScBas1 BIRD domain, althougha low degree of identity (32.6%) was observed (see Fig. S1 inthe supplemental material). We thus assumed that AFR297W ORFcorresponded to the BAS1 homolog in A. gossypii and, consequently,the mutant strain described above was designated bas1-1.

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FIG. 2. Characterization of A. gossypii bas1 mutant strains. (A) Different A. gossypii strains were grown on solid SMM or SMM plus adenine (+ade; 0.1 g/liter). The bas1 mutants exhibit a yellow color due to riboflavin accumulation. (B) Right panel, schematic representation of the wild-type BAS1 and disrupted bas1::G418^r loci. Left panel, Southern blot analysis to confirm correct BAS1 disruption. Genomic DNA of the wild-type and ${Delta}$ bas1 strains was digested with PstI. P, PstI; X, XhoI; B, BamHI; S, SphI. (C) Growth pattern of A. gossypii wild type and ${Delta}$ bas1 grown in liquid MA2 rich medium with (+ade) or without adenine supplementation (0.1 g/liter). (D) Microscopic phenotype of A. gossypii wild type and ${Delta}$ bas1 grown on liquid MA2 rich medium for 12 and 36 h. The germination delay of ${Delta}$ bas1 is restored by the addition of adenine (+ade; 0.1 g/liter). WT, wild type.

AgBAS1 inactivation causes riboflavin overproduction, adenine auxotrophy, and an extended trophic phase.
To confirm that the accumulation of riboflavin in the bas1-1mutant was caused by the inactivation of the AgBAS1 ORF, wedisrupted it in order to mimic the riboflavin overproductionphenotype found in the bas1-1 strain. An engineered disruptionmodule containing the dominant G418^r marker was used (see Materialsand Methods). AgBAS1 disruption was confirmed by analyticalPCR and Southern blotting (Fig. 2B). The new ${Delta}$ bas1 strain displayedthe same yellow color and the same level of riboflavin productionas the bas1-1 strain (Fig. 2A and Table 1), demonstrating thatBAS1 inactivation was responsible for the increased productionof vitamin B₂ in A. gossypii.

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TABLE 1. Riboflavin levels in the different A. gossypii strains used^a

To further characterize the bas1-1 and ${Delta}$ bas1 strains, we testedtheir ability to grow on minimal medium. As shown in Fig. 2A,the bas1-1 and ${Delta}$ bas1 strains were unable to grow unless adeninewas present in the medium. However, guanine, pyrimidines, oramino acids failed to rescue the wild-type phenotype (not shown).The adenine requirement indicates that BAS1 is essential forthe de novo biosynthesis of purines in A. gossypii and thatpurine salvage pathways are able to restore the synthesis ofAMP in a bas1 mutant when adenine is supplied.

Another interesting phenotype was associated with BAS1 inactivation.When ${Delta}$ bas1 spores were grown on rich medium, a slight delay (4to 6 h) in the time to germination, together with a significantlylong trophic phase (approximately 12 h), was observed comparedto the wild type (Fig. 2C-D). Supplementation of the mediumwith an excess of adenine corrected the delay in the time togermination for ${Delta}$ bas1 but failed to reduce the trophic-phasespan (Fig. 2C-D).

AgBas1p is localized to the nucleus of A. gossypii and binds to the AgADE4 promoter.
The subcellular localization of a transcription factor is expectedto be nuclear. Accordingly, we examined the subcellular localizationof AgBas1 using a GFP-BAS1 fusion under the control of the AgGPDpromoter. The strain carrying the GFP-BAS1 fusion showed nodifferences from the wild-type strain in terms of riboflavinproduction, adenine requirement, and growth (not shown). TheGFP-Bas1p fluorescence consistently colocalized with Hoechst33342 staining of nuclear DNA, confirming that AgBas1p was localizedto the nucleus (Fig. 3). This typical nuclear localization wasinvariably unaffected by the growth phase (Fig. 3).

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FIG. 3. AgBas1p is localized to the nuclei of A. gossypii. An A. gossyppi spore (left) and a hypha (right) expressing the GFP-Bas1p were stained with the DNA-selective dye Hoechst (HO) 33342 and viewed under epifluorescence optics. Upper images are the differential interference contrast (DIC) pictures; middle images represent the GFP channel, and lower images correspond to the HO channel of the same field.

Another essential feature of a transcription factor is its abilityto bind to promoter sequences. We therefore wished to investigatewhether AgBas1p was able to bind to the putative Bas1-bindingsites located in the AgADE4 promoter (16). The AgBas1 DNA-bindingdomain (amino acids 1 to 305) was expressed in E. coli BL21(DE3)using the pET-28b expression vector, and specific DNA bindingof the purified protein to different DNA probes from the AgADE4promoter was monitored by EMSA analysis. In a first experiment,the complete AgADE4 promoter (363 bp upstream from the initiationcodon) was analyzed using a distal 131-bp fragment (fragmentA) and a proximal 232-bp fragment (fragment B) as radioactiveprobes (Fig. 4A). The analysis revealed two different DNA-proteincomplexes formed with the distal probe (Fig. 4B, lane 2), indicatingthat two molecules of AgBas1p could be recruited to the AgADE4promoter. In Fig. 4, lane 2, the upper and lower bands correspondto fragment A, with two and one bound molecules of the AgBas1DNA-binding domain, respectively. Addition of a 10-fold molarexcess of unlabeled fragment completely abolished DNA-proteincomplex formation, confirming the specificity of the interaction(Fig. 4B, lane 3). In contrast, a similarly sized (384-bp) DNAfragment corresponding to the AgGPD promoter did not act asa competitor for AgBas1p (data not shown).

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FIG. 4. Identification of the DNA-binding site of AgBas1p by EMSA. (A) Structure of the AgADE4 promoter. Gray boxes indicate the Bas1-binding sites. The different probes used in the assays are depicted. (B) EMSA analyses using different probes: probe A, lanes 1 to 3; probe B, lanes 4 to 6; probe A1, lanes 7 to 9; probe A2, lanes 10 to 12, probe A3, lanes 13 to 15. An excess of the corresponding unlabeled probe was used in lanes 3, 6, 8, 11, and 14. No Bas1 DNA-binding domain peptide was included in lanes 1, 4, 7, 10, and 13.

When analyzing the sequence of the distal fragment A in detail,we were able to identify two putative heptanucleotide Bas1-bindingmotifs located at positions –247 and –321 from thestart codon (Fig. 4A). Therefore, we explored the ability ofthe AgBas1 DNA-binding domain to bind to each heptanucleotide.We designed three overlapping oligonucleotides that expandedthe fragment A to full-length. Oligonucleotide A1 containedthe Bas1-binding motif located at position –321, oligonucleotideA2 did not contain any motif, and oligonucleotide A3 containedthe heptanucleotide located at position –247 (Fig. 4A).EMSA analysis revealed that the AgBas1 DNA-binding domain causedgel retardation when combined with oligonucleotide A1 or A3(Fig. 4B, lanes 9 and 15), but not with A2. Again, an excessof unlabeled probes completely abolished DNA-protein complexformation (Fig. 4B). Based on these results, it may be concludedthat AgBas1p is a transcription factor that is able to bindto the two putative Bas1-binding motifs contained in the AgADE4promoter.

AgBas1p is involved in the adenine-mediated regulation of AgADE4 and AgSHM2 in A. gossypii.
The above results suggested an important role for AgBAS1 inthe biosynthesis of purine nucleotides and riboflavin. We thereforeinvestigated the transcription profiles of ADE4 and SHM2, whichhave been reported to be regulated by adenine limitation inA. gossypii (16, 35); PRS1 and PRS2, which control the synthesisof the purine precursor PRPP (A. Jiménez, M. A. Santos,and J. L. Revuelta, unpublished results); the IMD1 gene, whichdirects the first step of GMP biosynthesis; and all six RIBgenes in both wild-type and the ${Delta}$ bas1 strains.

Total RNA was isolated from cultures of the wild-type and ${Delta}$ bas1strains in the exponential phase (24 h) grown in rich medium,and real-time quantitative PCR was performed to test the transcriptionlevels of the ADE4, SHM2, PRS1, PRS2, IMD1, and RIB genes. Asshown in Fig. 5A, ADE4 and SHM2 transcription was considerablylower in the ${Delta}$ bas1 strain than in the wild-type strain, whereasPRS1, PRS2, IMD1, and the six RIB genes were unaffected by theBAS1 inactivation. This result indicates that Bas1 is a transcriptionfactor that activates the expression of ADE4 and SHM2 in A.gossypii.

We next analyzed whether the presence or absence of an excessof adenine in rich medium might affect the transcription levelof the above genes in the wild-type and ${Delta}$ bas1 strains. Our resultsrevealed that the addition of adenine clearly repressed thetranscription of ADE4 and SHM2 in the wild-type strain (Fig.5B). In contrast, adenine had no effect on ADE4 or SHM2 in the ${Delta}$ bas1 mutant, indicating that BAS1 was essential for the adenine-dependentregulation of both genes. The transcription levels of the othergenes analyzed were unaltered by the concentration of adeninein both the wild-type and the ${Delta}$ bas1 strains, confirming thatBas1 did not modulate their transcription (Fig. 5B).

Purine and riboflavin genes are inversely regulated during the growth of A. gossypii.
Riboflavin overproduction in A. gossypii occurs during the so-calledproduction phase, when the cultures reach a stationary phase.In addition, the riboflavin-overproducing phenotype of the bas1mutants suggests a direct link between the Bas1 function andriboflavin biosynthesis. We therefore checked the transcriptionpattern of purine and riboflavin genes in the A. gossypii wild-typeand ${Delta}$ bas1 strains along the growth curve in rich medium. Real-timequantitative PCR showed that the mRNA levels of purine genes(ADE4 and SHM2) in the wild type were highest during the trophicphase (12 to 36 h of culture) (Fig. 6, upper panel), when riboflavinproduction was minimal and growth was active. Thereafter, thetranscription of purine genes declined progressively, beinglowest during the productive phase (48 to 72 h) (Fig. 6, upperpanel). SHM2 transcription is increased at 72 h, but this effectseems to be independent of Bas1 regulation, since it also occursin the ${Delta}$ bas1 strain (see below). The RIB1 and RIB3 genes weremore actively transcribed than the purine genes during the productivephase (Fig. 6, upper panel). In fact, a previous report hadalready shown an increase in the promoter activity of RIB3 duringthe production phase (34). No differences in the transcriptionpattern of RIB genes between the wild type and ${Delta}$ bas1 strainswere seen (Fig. 6). With regard to purine genes, a deregulated,low, but constitutive transcription was evident in the ${Delta}$ bas1strain throughout the growth curve (Fig. 6, lower panel), demonstratingthat Bas1 was essential for accurate regulation of the purinepathway. Remarkably, the transcription levels of purine geneswere higher in the ${Delta}$ bas1 strain than in the wild type duringthe productive phase (Fig. 6, lower panel), indicating thata Bas1-independent basal transcription of the de novo purinegenes was occurring in the ${Delta}$ bas1 strain. However, such a transcriptionlevel did not provide enough purines to enable the growth ofthe ${Delta}$ bas1 mutant in the absence of extracellular adenine.

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FIG. 6. Transcription profiles of purine and riboflavin genes in wild-type and ${Delta}$ bas1 strains during the trophic and productive phases. Transcription profiling of the wild-type (WT) and ${Delta}$ bas1 strains grown in MA2 rich medium was achieved at different time points. In the wild-type strain (upper panel), the transcription of ADE4 and SHM2 decreased along the growth curve, whereas the transcription of RIB1 and RIB3 increased during the productive phase. In the ${Delta}$ bas1 strain (lower panel), ADE4 and SHM2 show a constitutive deregulated transcription. Transcription levels are normalized with the transcription rate of AgACT1.Data are representative of four experiments with similar results and are presented as log₂ of the 2^–Ct ( ${Delta}$ ${Delta}$ Ct = ${Delta}$ Ct_T – ${Delta}$ Ct_{12 h}). T, incubation time (h).

AgBas1 contains a C-terminal regulatory BIRD domain.
As described above, we identified a hypothetical C-terminalBIRD domain within the AgBas1p sequence (residues 632 to 743)(see Fig. S1 in the supplemental material). In order to verifythe functionality of this regulatory domain, we decided to removeit by PCR-mediated deletion using a G418^r selectable marker(see Materials and Methods). Homokaryotic G418^r clones carryingthe deletion module were confirmed by analytical PCR and Southernblotting (not shown). The new strain lacking the AgBas1 C-terminaldomain was designated ${Delta}$ C631BAS1. Deletion of the BIRD domainenhanced the capacity to produce riboflavin—the ${Delta}$ C631BAS1mutant was able to produce almost twice (24.28 mg/g) more riboflavinthan the ${Delta}$ bas1 mutant and 12-fold more riboflavin than the wildtype, hence also affording an intense yellow color to the colonies(Fig. 2A and Table 1). Unlike ${Delta}$ bas1, ${Delta}$ C631BAS1 was able to growin minimal medium without adenine supplementation (Fig. 2A).

The ${Delta}$ C631BAS1 strain also displayed a remarkable feature whenthe spores were cultured in rich medium. Like the ${Delta}$ bas1 mutant, ${Delta}$ C631BAS1 displayed a longer trophic phase than the wild type;however, germination time was not affected, unlike results for ${Delta}$ bas1 (Fig. 7A).

Analysis of the transcription pattern of the purine and riboflavingenes in the ${Delta}$ C631BAS1 strain revealed that ADE4 and SHM2 transcriptionwas highly activated and that the activation was insensitiveto extracellular adenine, since the mRNA levels of ADE4 andSHM2 were constitutively higher in the ${Delta}$ C631BAS1 strain thanin the wild type with adenine supplementation (Fig. 7B). However,the other genes analyzed did not show any change in transcriptionlevels when the ${Delta}$ C631BAS1 and the wild-type strains were compared(Fig. 7B). Our results suggest that the C-terminal BIRD domainof AgBas1p would be a regulatory domain and that the truncated ${Delta}$ C631Bas1p form would induce a constitutive transcriptional activationof ADE4 and SHM2, an increase in riboflavin production, anda delayed entry into the productive stationary phase.

DISCUSSION

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Discussion

The overproduction of riboflavin in A. gossypii is a physiologicalprocess that occurs when active growth finishes and thereforemust be somehow linked to the growth phase. It has been suggestedthat A. gossypii overproduces riboflavin as a detoxifying andprotective mechanism (37), although the molecular mechanismstriggering the riboflavin overproduction are largely unknown.

In this report, we show that AgBAS1 is involved in the regulationof the glycine and purine biosynthesis, which have been shownto increase riboflavin production when added to the medium (21,38). Furthermore, we constructed different bas1 mutants thatexhibit remarkable differences in their growth patterns andhigher levels of riboflavin production than the wild type. Inlight of this, we propose the AgBAS1 gene as a possible candidatefor a link between the glycine and purine pathways, the growthprofile, and riboflavin overproduction.

AgBAS1 was found as the target gene disrupted in a riboflavin-overproducingstrain, which had been selected in a screening of random insertionalmutants. Directed AgBAS1 gene disruption confirmed that BAS1inactivation in A. gossypii afforded a riboflavin overproductionphenotype. In addition, the ${Delta}$ bas1 strain required adenine supplementation,suggesting an important role for Bas1p in the biosynthesis ofpurines, as described for other organisms (4). The asymmetryof the purine salvage pathways (Fig. 1) explains why only adeninesupplementation, but not supplementation with either guanineor xanthine, enables the growth of the ${Delta}$ bas1 mutant, since adenylnucleotides can be transformed into guanyl nucleotides, butnot the opposite.

Real-time quantitative PCR experiments comparing mRNA profilesbetween the wild-type and ${Delta}$ bas1 strains showed that AgBas1p isessential for the transcriptional activation of ADE4 and SHM2and also for the adenine-mediated repression of those genes.The role of AgBas1p as a transcription factor is consistentwith the nuclear localization of a GFP-Bas1 fusion protein.Additionally, our EMSA experiments showed that the Myb-likeDNA-binding domain present in AgBas1p is able to bind the heptanucleotidelocated in the ADE4 promoter, which has been reported to bea Bas1-binding motif (15, 16). Such a binding motif has alsobeen found in the AgSHM2 promoter (M. A. Santos, L. Mateos,and J. L. Revuelta, unpublished results). Overall, this evidenceprompts us to consider AgBas1p to be a transcription factorthat regulates purine and glycine biosynthesis, as describedfor other organisms (4, 6). However, AgBas1p also seems to beeither directly or indirectly involved, through the purine pathway,in other physiological processes, such as detoxifying mechanismsor growth and morphogenesis, as discussed below.

Homology analyses identified a C-terminal regulatory domainwithin the AgBas1p sequence, called the BIRD domain in the yeastortholog (28), and the complete deletion of this hypotheticalBIRD domain in the AgBas1p was achieved. The ${Delta}$ C631BAS1 strainproduces higher levels of riboflavin than the ${Delta}$ bas1 mutant, isable to grow in medium lacking adenine, and shows a constitutiveactivation of the ADE4 and SHM2 genes. In light of these observations,it may be concluded that the C-terminal domain of AgBas1 wouldbe responsible for the adenine sensitivity, for masking thetrans-activation domain when adenine is present and, presumably,for the Bas2 interaction, as described previously for the yeastBIRD domain (28, 36). In fact, a ScBAS2 ortholog in A. gossypiihas recently been identified (L. Mateos, M. A. Santos, and J.L. Revuelta, unpublished results).

The ${Delta}$ bas1 and the ${Delta}$ C631BAS1 strains also display a prolonged trophicgrowth phase in comparison with the wild type. In addition,the ${Delta}$ bas1 strain exhibits a slight delay in the time to germination,together with other morphological defects in the hyphal structure.These effects may be directly related to the deregulation ofthe purine pathway in the ${Delta}$ bas1 and ${Delta}$ C631BAS1 strains. First,from the results described above, it may be assumed that thede novo purine pathway does not operate properly in the ${Delta}$ bas1mutant and that purines must be formed mainly through the salvagepathways, delaying the germination during the early steps ofgrowth. In fact, adenine supplementation corrected the germinationdefect in the ${Delta}$ bas1 mutant. Second, it has been reported thatlow levels of intracellular guanyl nucleotides are requiredfor entry into the stationary phase in S. cerevisiae and Bacillussubtilis (29, 32). The riboflavin overproduction phenotype shownby the ${Delta}$ bas1 and the ${Delta}$ C631BAS1 strains indicates that a high poolof GTP, the immediate precursor of riboflavin, must exist inboth strains, producing a delay in entry into the stationaryphase and extending the trophic phase. This hypothesis supportsthe notion that the guanyl nucleotide pool would be a signalthat controls the transition from the trophic phase to the stationaryproduction phase and suggests that an increased riboflavin productionand a delayed entry into the stationary phase would be two aspectsof the same phenomenon, i.e., a high GTP concentration. Indeed,the ${Delta}$ bas1 and ${Delta}$ C631BAS1 strains were more resistant to mycophenolicacid than the wild type (see Fig. S2 in the supplemental material),a phenotype associated with high intracellular levels of GTP(1, 23).

Nevertheless, the mechanisms inducing an increased intracellularconcentration of GTP, and hence an enhanced riboflavin overproduction,in the ${Delta}$ bas1 and the ${Delta}$ C631BAS1 strains must be different. ${Delta}$ C631BAS1shows a constitutive activation of the purine pathway that couldbe responsible for the high GTP levels and the increased riboflavinoverproduction observed. Supporting this notion, we have previouslydemonstrated that the level of transcription of AgADE4 is correlatedwith the production of riboflavin (16). The explanation forthe riboflavin overproduction phenotype in the ${Delta}$ bas1 strain is,however, less obvious. As evidenced by its adenine auxotrophy,purines must be formed mostly through the salvage pathways inthe ${Delta}$ bas1 strain. Under these conditions, the AMP deaminase enzymeactivity (Amd1) (24) establishes the asymmetry in the purinesalvage pathways and redirects the metabolic flux toward guanylnucleotides in competition with the adenylate kinase (Adk1)(18). In addition, the enzyme Xpt1 can metabolize xanthine andguanine toward GMP (12) (Fig. 1). The genes encoding these enzymeshave been annotated in the Ashbya Genome Database (http://agd.unibas.ch/)as S. cerevisiae syntenic orthologs (AGD gene identificationnumbers AGR187W, ABR204C, and ABL070C for AgADK1, AgAMD1, andAgXPT1, respectively). However, an HPT1 homolog, which restoresequilibrium by transforming hypoxanthine into IMP in other organisms(41), has not been identified; therefore, hypoxanthine cannotbe transformed to IMP in A. gossypii. Accordingly, the purinesalvage pathways in A. gossypii may lead to the production ofhigher amounts of guanyl than adenyl nucleotides; hence, the ${Delta}$ bas1 strain, which uses mostly the purine salvage pathways,may be able to synthesize higher amounts of the riboflavin precursorGTP than the wild type. Additionally, the AgSHM2 mRNA levelduring the first steps of growth was lower in the ${Delta}$ bas1 strainthan in the wild type, and it has been reported that disruptionof AgSHM2 produces glycine accumulation and enhanced riboflavinoverproduction (35). Indeed, riboflavin overproduction in the ${Delta}$ bas1 strain was inversely correlated with the SHM2 transcriptionlevel.

In sum, the results presented here suggest that the mechanismsleading to a high concentration of GTP are responsible for riboflavinoverproduction in A. gossypii. In addition, the BIRD domainfound in AgBas1p could be considered an intracellular sensorof the GTP concentration. High levels of GTP could induce arepression signal of the de novo purine pathway through a mechanismin which the Bas1 BIRD domain may be involved, masking the trans-activationdomain of Bas1. If the BIRD domain is indeed not functional,Bas1 must be constitutively active and the purine pathway mustsynthesize an excess of GTP, which must be detoxified throughriboflavin production. Nevertheless, the bas1 mutants show severalgrowth alterations affecting the transition from the trophicphase to the productive phase, and these effects indicate thatBas1 could be involved, either indirectly, through the purinepathway, or directly, in the regulation of other hitherto-undescribedgrowth-related pathways.

This work sheds further light on the complex role of BAS1 inthe physiology of A. gossypii. A feasible link between purineand glycine biosynthesis, riboflavin overproduction, and thetransition from the trophic to the stationary phase is established.Experiments are currently under way at our laboratory to explorethe precise mechanisms underlying some of the effects inducedby misregulation of the purine pathway.

ACKNOWLEDGMENTS

This work was supported in part by BASF AG and grants GEN2001-4707-C08-01and AGL2005-07245-C03-03 from the Ministerio de Educacióny Ciencia, Spain. L.M. is supported by a predoctoral fellowshipfrom the Universidad de Salamanca, Spain. A.J. is a recipientof a postdoctoral contract (Programa Juán de la Cierva)from the Spanish Ministerio de Educación y Ciencia.

We thank M. Martín and M. D. Sánchez for excellenttechnical help and N. Skinner for correcting the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Departamento de Microbiología y Genética, CSIC/Universidad de Salamanca, Campus Miguel de Unamuno, 37007 Salamanca, Spain. Phone: 34 923 294671. Fax: 34 923 224876. E-mail: revuelta{at}usal.es.

Supplemental material for this article may be found at http://aem.asm.org/.

REFERENCES

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