From the School of Environmental and Evolutionary
Biology, University of St. Andrews, St. Andrews, Fife KY16 9TH,
United Kingdom and the ¶ Department of Microbiology,
Monash University, Clayton, Victoria 3168, Australia
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ABSTRACT |
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The product of the Aspergillus nidulans cnxF gene was found by biochemical analysis of cnxF mutants to be involved in the conversion of precursor Z to molybdopterin. Mutants cnxF1242 and cnxF8 accumulate precursor Z, while the level of molybdopterin is undetectable. The DNA sequence of the cnxF gene was determined, and the inferred protein of 560 amino acids was found to contain a central region (residues around 157 to 396) similar in sequence to the prokaryotic proteins MoeB, which is thought to encode molybdopterin synthase sulfurylase, ThiF, required for thiamine biosynthesis, and HesA, involved in heterocyst formation, as well as eukaryotic ubiquitin-activating protein E1. Based on these similarities, a possible mechanism of action is discussed. Sequence comparisons indicate the presence of one and possibly two nucleotide binding motifs, Gly-X-Gly-X-X-Gly, as well as two metal binding Cys-X-X-Cys motifs in this central region of the CnxF protein. Seven in vivo generated A. nidulans cnxF mutants were found to have amino acid substitutions of conserved residues within this central region of similarity to molybdopterin synthase sulfurylase, indicating that these seven amino acids are essential and that this domain is crucial for function. Of these seven, the cnxF1285 mutation results in the replacement of Gly-178, the last glycine residue of the N-proximal Gly-X-Gly-X-X-Gly motif, indicating that this motif is essential. Mutation of the conserved Arg-208, also probably involved in nucleotide binding, leads to a loss-of-function phenotype in cnxF200. Alteration of Cys-263, the only conserved Cys residue (apart from the metal binding motifs), in cnxF472 suggests this residue as a candidate for thioester formation between molybdopterin synthase and the sulfurylase. Substitution of Gly-160 in two independently isolated mutants, cnxF21 and cnxF24, results in temperature-sensitive phenotypes and indicates that this residue is important in protein conformation. The C-terminal CnxF stretch (residues 397-560) shows substantial sequence conservation to a yeast hypothetical protein, Yhr1, such conservation between species suggesting that this region has function. Not inconsistent with this proposition is the observation that mutant cnxF8 results from loss of the 34 C-terminal residues of CnxF. There is no obvious similarity of the CnxF C-terminal region with other proteins of known function. Two cnxF transcripts are found in low abundance and similar levels were observed in nitrate- or ammonium-grown cells.
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INTRODUCTION |
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The molybdenum cofactor is a ubiquitous molecule found in most organisms from bacteria to humans and is required for activity by a number of molybdoenzymes, including nitrate reductase and xanthine dehydrogenase (also known as purine hydroxylase I) (1). The first biochemical studies, by Nason and co-workers (2, 3) and Ketchum and Swarin (4) in the early 1970s, which indirectly demonstrated the existence of a molybdenum-containing component, made use of fungal cell-free extracts of the Neurospora crassa nit-1 mutant lacking the cofactor but containing apo-nitrate reductase. The presence and universality of the cofactor in bacterial cell-free extracts as well as acid-treated enzymes from diverse sources of biological material, such as cow milk or fowl liver, was suggested by their ability to reconstitute holo-nitrate reductase after mixing that source with nit-1 crude extracts. Later, Garrett and Cove (5) predicted the presence of the cofactor, using a similar approach, in the fungus Aspergillus nidulans.
Direct chemical studies by Rajagopalan (Refs. 1 and 6, and articles therein) suggested that the molybdenum cofactor of liver sulfite oxidase consists of a novel pterin called molybdopterin linked by its 6-alkyl side chain to a dithiolene group which coordinates molybdenum. Further biochemical and genetic work carried out in the prokaryote Escherichia coli has provided valuable information regarding the events that take place leading to the biosynthesis of a prokaryotic molybdenum cofactor variant, molybdopterin guanine dinucleotide (reviewed in Refs. 1 and 7). The proposed structure of the molybdenum cofactor and intermediates and their biosynthesis from a guanosine derivative are summarized in Fig. 1.
Even earlier than the biochemical work, genetic studies of molybdenum cofactor synthesis had been initiated by Cove and Pateman (8) and Pateman et al. (9). Using the fungus A. nidulans, they isolated mutants resistant to chlorate, an analogue of nitrate toxic to wild-type cells. One particular class of chlorate-resistant mutants was unable to utilize either nitrate or purines such as adenine, hypoxanthine, and xanthine as sole sources of nitrogen. This inability to grow on nitrate and hypoxanthine was found to be due to the concomitant diminution of nitrate reductase and xanthine dehydrogenase activities. Cove and Pateman (8) astutely suggested that such mutants were defective in the synthesis of a cofactor common to both nitrate reductase and xanthine dehydrogenase and designated the mutants cnx (common component for nitrate reductase and xanthine dehydrogenase). Five cnx loci (namely cnxABC, cnxE, cnxF, cnxG, and cnxH) were identified (8, 9). With the exception of the complex cnxABC locus that is involved in the first section of the pathway (Fig. 1), namely the biosynthesis of the pterin precursor Z from a guanosine derivative (10), little or no information is available to suggest the function of cnx gene products or the nature of the pathway in eukaryotes.
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We report here the isolation of the A. nidulans cnxF gene, analysis of the wild-type and mutant sequences, levels of precursor Z and molybdopterin intermediates in cnxF mutants, and the likely nature of CnxF involvement in molybdenum cofactor biosynthesis.
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EXPERIMENTAL PROCEDURES |
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Aspergillus nidulans Strains, Plasmids, Media, and Transformation-- The wild-type strain used was G051 (biA1). Strains cnxF2, cnxF7, and cnxF8 were original mutants described by Cove and Pateman (8) and Pateman et al. (9). Further cnxF mutants were selected in this study on the basis of resistance to chlorate (11) using chemically generated mutagenesis (8, 9). In this regard, N-methyl-N'-nitro-N-nitrosoguanidine was used to obtain mutant strains cnxF119, cnxF200, cnxF472, cnxF480, cnxF1242, cnxF1228, and cnxF1285 while 1,2,7,8-diepoxyoctane was used for cnxF142, cnxF1224, and cnxF1193. Chlorate was used at a concentration of 200 mM with proline as the sole source of nitrogen at 37 °C as described previously (8, 9). Assignment of mutations to cnx loci was carried out by the heterokaryotic complementation test, i.e. growth of pair-wise heterokaryons on nitrate as the sole nitrogen source against representative cnx mutants, cnxA9, cnxB11, cnxC3, cnxE3, cnxF7, cnxG4, and cnxH4 (8, 9). Standard Aspergillus growth media and handling techniques were as described by Clutterbuck (12). For transcript analysis, cultures were grown at 37 °C for 16 h in liquid minimal medium containing 10 mM sodium nitrate or 5 mM ammonium tartrate as the sole nitrogen source (13).
Molecular Methods--
Standard procedures were used for
propagation of cosmids and for subcloning and propagation of plasmids
in E. coli strain DH5. Conditions employed here for
A. nidulans Southern and Northern blot analysis were as
described previously (14). Nucleotide sequence of the A. nidulans wild-type cnxF gene was determined on both
strands of genomic and cDNA clones using a Sequenase Version 2 DNA
sequencing kit according to manufacturer instructions (Amersham plc,
UK). This sequence can be found under GenBankTM accession
number AF055287. For primer extension analysis, mRNA was prepared
from mycelium grown in minimal medium containing 10 mM
sodium nitrate as the sole nitrogen source at 25 °C for 18 h,
using a Quickprep mRNA purification kit (Pharmacia plc, UK).
mRNA (2 mg) was hybridized with 5' 32P end-labeled
primer FP2 (5'-GTTGCGTTCGCACTCGC, position +383) at 52 °C for 1 h and reverse-transcribed using a Primer Extension System as
recommended by the manufacturer (Promega). The extension product was
compared on a denaturing sequencing gel with a DNA sequence ladder
prepared using the same end-labeled primer with pSTA508 as template.
The A. nidulans cosmid library was purchased from the Fungal
Genetics Stock Center (Kansas City, KS).
Fungal Cloning by Complementation of Mutant Phenotypes-- An argB-based A. nidulans genomic bank cleaved by BamHI together with the autonomously replicating A. nidulans vector pHELP consisting of pUC18 and AMA1, an A. nidulans sequence with replication activity, were used to transform A. nidulans cells, basically the approach described by Gems and Clutterbuck (15). After transformation of the mutant cnxF7, nitrate-utilizing colonies were purified on selective medium (i.e. minimal medium containing nitrate as the sole source of nitrogen).
Hybrid plasmid molecules, containing pHELP and argB with cnxF7 complementing sequences, created by in vivo recombination and/or DNA ligation events (15) were isolated by conventional A. nidulans DNA extraction procedures and transferred or "rescued" by transforming E. coli DH5Polymerase Chain Reaction Amplification and Mutant DNA Sequence Determination-- Genomic DNA was prepared from mycelia grown in liquid culture for 16-18 h at 25 °C using a Nucleon BACC2 Kit (Scotlab Ltd, UK). DNA was cleaved with EcoRI, and around 100 ng was amplified using 2.5 units/ml Dynazyme (Flowgen) or 2.5 units/ml Taq DNA polymerase (Boehringer Mannheim), 1 µM each primer, and 100 µM dNTPs. Cycling conditions were 94 °C for 1 min, 50 °C for 20 s, 72 °C for 50 s for 1 cycle followed by 30 cycles of 94 °C for 10 s, 50 °C for 20 s, and 72 °C for 50 s. The entire cnxF coding region was amplified in three overlapping sections using primers FP1 and FP2 (5'-ACCCAGTATTGTTGGTA and 5'-GTTGCGTTCGCACTCGC, positions -321 to +383), primers FP3 and FP4 (5'-CAACAGCACGGAGCTACAG and 5'-GTCTTGTCTCCAGGCGGCT, positions +200 to +1077), and primers FP5 and FP6 (5'-CGGCATCGGCACTACGGA and 5'-CCTTGTCCTCTGTTGAGC, positions +1005 to +1851). Following removal of PCR1 primers and unincorporated nucleotides by the Glassmax DNA Isolation Spin Cartridge System (Life Technologies), the amplified DNA was sequenced directly in a single strand only by automated DNA sequencing using an ABI 373 A fluorescence sequencing apparatus and PRISM Ready Reaction DyeDeoxy Terminator Cycle Sequencing Kit (Applied Biosystems), with the PCR primers at a concentration of 10 µM. Additional 17-mer primers used for sequencing were FPS7 (+36), FPS8 (+542), and FPS9 (+1440). Sequences were compared with the wild-type using Sequencher (Gene Codes Corp.).
HPLC Analysis of Molybdopterin Form A and Compound Z Levels in Oxidized and Dephosphorylated Cell-free Extracts from A. nidulans Wild-type and cnxF Mutant Strains-- Levels of form A dephosphorylated and compound Z, as a measure of molybdopterin and precursor Z, respectively, were determined by HPLC using the method described by Johnson and Rajagopalan (16, 17) with modifications detailed in Unkles et al. (10), following growth of the cells in minimal medium containing 10 mM proline plus 10 mM sodium nitrate as the only nitrogen sources for 16 h at 30 °C and 250 rpm.
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RESULTS |
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Determination of Precursor Z and Molybdopterin Levels in Wild-type and Mutant Strains-- The data presented in Fig. 2 show the levels of precursor Z and molybdopterin, measured as their oxidized derivatives compound Z and form A dephosphorylated, respectively, in the wild-type and the mutant cnxF1242 (likely to be a null mutant as the mutation results in an intron boundary change, see below for details of the nucleotide lesion). The wild-type and mutant were grown with nitrate plus proline as the only nitrogen sources, a growth regime that permits the growth of cnxF mutants and yields appreciable levels of precursor Z and molybdopterin in wild-type cells. The level of precursor Z was observed to be markedly increased in the mutant cnxF1242 to a value 9-fold of that of the wild-type (Fig. 2A). In contrast, molybdopterin is undetectable in the mutant strain (Fig. 2B). Similar levels of precursor Z and molybdopterin were observed in the cnxF8 mutant strain (the mutation resulting in the loss of the C-terminal 34 amino acid residues, see below) grown under the same conditions.2 These results suggest that the cnxF product is involved in the conversion of precursor Z to molybopterin.
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Molecular Cloning of the A. nidulans cnxF Gene-- A 27-kb plasmid was isolated following co-transformation of the autonomously replicating A. nidulans plasmid pHELP with an A. nidulans argB-based genomic library as described under "Experimental Procedures." This recombinant plasmid repaired the phenotype of the cnxF7 mutation, i.e. restoration of growth on nitrate as the sole nitrogen source. The size and the restriction endonuclease digestion pattern of the rescued plasmid3 indicated that in vivo recombination events had occurred between pHELP and the gene library. Therefore, to avoid potential problems of sequence rearrangement within the rescued plasmid, a genomic copy of the cnxF gene was isolated from an A. nidulans cosmid library. HindIII and BamHI fragments of the rescued plasmid were first identified, which did not hybridize to pHELP or to argB, and these fragments were then used as hybridization probes to isolate eight cosmids from the library of chromosome 7 (18), on which the cnxF gene was shown previously to reside (8, 9). Three of these cosmids were subsequently shown to complement another cnxF mutation, i.e. cnxF8, at high frequency. The complementing region of one of these (W17D04) was identified, by transformation of each of eight possible BamHI-generated fragments, as a 4-kb BamHI fragment that was subcloned into pUC13 and designated pSTA508. This recombinant vector complemented the cnxF8 mutation and was used as a template for DNA sequence determination.
Structure of the cnxF Gene-- A unique open reading frame encodes a protein of 560 amino acid residues (Fig. 3). Since no N-terminal data is available for the CnxF protein, we can only speculate as to the identity of the translational initiation codon. However, this ATG (nucleotide position +1) is the first in-frame ATG downstream from a major transcriptional start point that has been mapped at around 80 base pairs upstream.4 Comparison of the DNA sequence of genomic and an RT-PCR product, generated using primers FP3 and FP4,3 allowed the identification of two typical short fungal introns (86 and 62 base pairs) (19) interrupting the putative CnxF protein coding region.
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Analysis of the Predicted Protein-- Comparisons to the SwissProt protein data base using Blastp (20) showed that fungal CnxF shares considerable similarity with amino acid sequences belonging to an E. coli enzyme encoded by the moeB gene (21). This protein has also been shown to be required for the conversion of precursor Z to molybdopterin (22, 23). It appears to be involved in sulfur transfer and was recently termed molybdopterin synthase sulfurylase although the mechanisms and substrates are poorly defined (1). The A. nidulans CnxF protein, at 560 residues, is much larger than the 249 residues of MoeB, the CnxF protein having a 150-residue extension at the N-terminus and an amino acid extension of 161 residues to the C-terminus relative to MoeB. The relevant section (residues 157 to 396) of CnxF homology with E. coli MoeB is presented in Fig. 4A. Inspection of this section of the CnxF sequence reveals the presence of two potential nucleotide binding Gly-rich motifs (Gly-X-Gly-X-X-Gly) starting at residue positions 173 and 189. Comparative analysis of this region also shows substantial similarity with a priori functionally unrelated proteins containing this Gly motif, in particular E. coli ThiF, required in the synthesis of thiamine (24), and HesA, involved in heterocyst formation in the cyanobacterium, Anabaena (25). Additionally, CnxF in common with MoeB (1) shares up to 36% identity with the yeast (Fig. 4B), plant, and human ubiquitin activating enzyme E1 (Uba1), a protein which also harbors the Gly-containing catalytic domain for nucleotide binding (26). The Gly-rich motifs of other, and functionally unrelated, nucleotide binding proteins often have associated with them several amino acid residues which are thought to be important for nucleotide binding (27, 28). Certain of these residues are also associated with the first Gly-rich sequence of CnxF, shown boxed in Fig. 4, A and B. These include a stretch of hydrophobic residues following the first Gly-rich motif encompassing a highly conserved Ala at position 186 in CnxF (conserved in MoeB, ThiF, HesA, and Uba1), a negatively charged Asp residue at position 197 (conserved in MoeB and ThiF), and a basic Arg residue at position 208 (conserved in MoeB, ThiF, HesA, and Uba1). The second Gly-X-Gly-X-X-Gly motif of CnxF (boxed in Fig. 4, A and B) is not conserved in MoeB, ThiF, or HesA but is present in Uba1 (Fig. 4B). However, this second motif does not appear to have those residues, conserved in equivalent positions, which are found in association with the first Gly-rich sequence.
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Characterization of cnxF Mutants-- From several hundred cnx mutants isolated on the basis of chlorate resistance at 37 °C and determined by lack of growth on nitrate or hypoxanthine as sole nitrogen source, ten in this study were found to be cnxF mutants after complementation in heterokaryons resulting in growth on nitrate as sole nitrogen source (see "Experimental Procedures"). Nine of these (cnxF119, cnxF200, cnxF472, cnxF480, cnxF1193, cnxF1224, cnxF1228, cnxF1242, and cnxF1285) were found to be temperature non-conditional, i.e. were unable to grow on either sole nitrogen source and were chlorate-resistant at the two temperatures tested (25 and 37 °C). One mutant, cnxF142, failed to grow on nitrate or hypoxanthine at both temperatures, was fully chlorate-resistant at 37 °C, but showed almost wild-type sensitivity at 25 °C. In addition, five mutants (cnxF2, cnxF7, cnxF8, cnxF21, and cnxF24) originally isolated by Pateman and Cove (8, 9) were checked again phenotypically. The mutants cnxF2, cnxF7, and cnxF8 failed to grow on nitrate or hypoxanthine and were resistant to chlorate at both temperatures as expected from the reported work. The two reported temperature-sensitive mutants, cnxF21 and cnxF24, while growing significantly better on nitrate and showing sensitivity to chlorate at the permissive temperature, i.e. 25 °C as expected (30), completely failed to grow on hypoxanthine as the nitrogen source at the permissive temperature. Both mutants showed the expected phenotype at 37 °C, i.e. failure to grow on nitrate or hypoxanthine and resistance to chlorate. It was also noted that there were marked differences in growth and conidiation between cnxF21 and cnxF24 on complete medium.
Sequence Analysis of Randomly in Vivo Generated cnxF
Mutants--
Of the 15 mutations described above, 7 resulted from
amino acid substitutions, the positions of which are shown in Fig.
4A. Four mutations were found to change highly conserved Gly
residues and included the three with temperature-sensitive
phenotypesboth cnxF21 and cnxF24 result in the
same alteration of Gly-160 to Asp while in cnxF142, residue
Gly-342 is converted to Ser. The fourth, a non-conditional mutation,
namely cnxF1285, was found to alter Gly-178 to Asp, the last
Gly residue of the N-proximal Gly-X-Gly-X-X-Gly
motif. Three further interesting mutants that also substitute highly
conserved amino acids are mutation cnxF200, which converts
Arg-208 to Gln, mutation cnxF472, which forms Tyr from the
Cys-263 residue, and finally, mutation cnxF119, where Glu-293 is changed to Lys.
cnxF Expression-- In Northern blot experiments, two weakly hybridizing transcripts of 1.9 and 2.55 kb present in poly(A)+ mRNA were observed after several days exposure to x-ray film using a probe derived from the cnxF coding region only (Fig. 5). Although the presence of more than one transcript is not uncommon in fungi as demonstrated by the control actA transcripts (31) in Fig. 5, Southern blot analysis confirms that there is a single copy of the cnxF gene in A. nidulans.2 The 2.55-kb transcript is present in higher abundance than the 1.9-kb one, and the relative abundance of both transcripts was similar in mRNA isolated from nitrate or ammonium grown cells. Approximately equal loadings of mRNA were present for each condition as judged by the hybridization intensity of actA, a constitutively expressed A. nidulans gene encoding actin (31). In contrast to cnxF, the actin transcript was visible after a few hours of autoradiographic exposure.
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DISCUSSION |
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The Aspergillus nidulans cnxF gene, identified by Cove and Pateman (8, 9) more than 3 decades ago, is required for the conversion of precursor Z to molybdopterin (Fig. 1). This conclusion comes from the biochemical analysis of the null mutant strain cnxF1242 which accumulates precursor Z to levels 9-fold higher than those found in the wild-type and which has a marked reduction in the level of molybdopterin, the product of the enzymatic conversion of precursor Z. A section of the CnxF protein is similar in amino acid sequence to E. coli MoeB, an enzyme which is thought to activate molybdopterin synthase, by transferring sulfur atoms to the small subunit of the synthase (22). Consequently, this enzyme was termed molybdopterin synthase sulfurylase recently (1), although the details of the mechanism and substrate(s) involved in the sulfur transfer reaction to molybdopterin synthase are poorly defined. In a sulfur-charged state, molybdopterin synthase appears to be in an active form to add dithiolene sulfur to the pterin side chain of precursor Z to give molybdopterin. In A. nidulans cnxF mutants, the failure to synthesize molybdopterin (and the molybdenum cofactor) resulting in the loss of activity of the molybdoenzymes nitrate reductase and xanthine dehydrogenase, is presumably due, at least in part, to the lack of the sulfur transfer system.
The eukaryotic CnxF protein, with 560 amino acid residues, is considerably larger than the prokaryotic MoeB (249 residues), with N- and C-terminal amino acid extensions of 150 and 161 residues, respectively. However, whether there are additional functions in these additional regions is uncertain. Data base similarity searching reveals little obviously significant similarity to other characterized proteins. Also, no potential function can be inferred from the position of amino acid substitution mutations analyzed since all (seven) residue changes are found in the CnxF region similar to MoeB (i.e. residues 153 to 398), with none observed in the 150-residue N-terminus or the 161-residue C-terminus extensions. This may suggest that the MoeB-homologous stretch is the most important or the only functional domain contained within the CnxF protein. At some variance with this suggestion, however, is the finding that the cnxF8 mutation in the C-terminal extension results in the lack of molybdopterin production.1 This particular mutation generates a frameshift at residue 522, placing a stop four codons distal. The mutant protein, therefore, missing 34 C-terminal amino acids may be generally unstable and/or subject to proteolysis with the resultant loss of sulfurylase activity. An alternative explanation would suggest that the last 38-residue stretch of CnxF is required specifically for function in eukaryotes. In support of this proposition is the observation that there is high similarity of the C-terminal 161 amino acids of CnxF to hypothetical yeast proteins identified by DNA sequencing.
The central portion of the CnxF protein (between residues 157 and 393) is clearly similar to further bacterial proteins, ThiF and HesA (Fig. 4A), and to yeast (Fig. 4C), plant, and human E1 ubiquitin activating protein (designated Uba1 in yeast). There is no immediately obvious physiological relationship between CnxF and ThiF, HesA, or Uba1 proteins. ThiF is thought to be involved in the synthesis of the thiazole ring of vitamin B1 in E. coli (25), while HesA is expressed following heterocyst induction in the cyanobacterium, Anabaena, and is required for efficient nitrogen fixation possibly by participating in electron transfer to nitrogenase (24). Uba1 is a ubiquitin activating enzyme that forms a thioester linkage between the C-terminal Gly of ubiquitin and a Cys within Uba1 during activation of ubiquitin as part of the process for ubiquitin-targeted degradation of proteins (32). In the ubiquitin system, this reaction is followed by transfer of the ubiquitin to another carrier protein, with the formation of a new thioester linkage. The suggestion has been made (1) that the mechanism, by which the proposed sulfurylase transfers sulfur to molybdopterin synthase, may resemble the process of ubiquitin activation by Uba1. By analogy, in the molybdopterin synthase sulfurylase reaction, molybdopterin synthase would form a thioester with CnxF. However, subsequent transfer of molybdopterin synthase to another protein would not occur, but instead a sulfide, possibly created by the metal center of CnxF, would be transferred to the carboxyl group of the synthase, creating a thiocarboxylate. The reactive thiocarboxylate of the molybdopterin synthase would then be the source of sulfur for the conversion of precursor Z to molybdopterin. The fact that ubiquitin, the small subunit of E. coli molybdopterin synthase, ThiC (a protein encoded by a cistron in the ThiF operon), and HesB (a protein from the HesA operon) all have C-terminal or near C-terminal Gly-Gly amino acid residues lends support to this hypothesis. The Cys residue at position 263 of CnxF, alteration of which leads to loss-of-function in mutant cnxF472, and which is conserved in MoeB, ThiF, and HesA is a strong candidate for thioester formation between the synthase and sulfurylase, being the only Cys residue conserved between CnxF, MoeB, ThiF, and HesA (apart from the Cys-X-X-Cys motifs) and positioned as it is within a short highly conserved region.
The CnxF primary sequence shows the presence of features typical of nucleotide binding sites for NAD, NADP, GTP, or ATP (residues 173 to 208). In this potential nucleotide binding region, the core motif Gly-X-Gly-X-X-Gly (residues 173 to 178) is very highly conserved. Replacement of the last conserved Gly with Asp (residue 178) in the cnxF1285 mutant strain results in loss-of-function, supporting the proposal that this motif is essential for enzyme function. Evidence regarding the functional importance of this site in other enzyme systems comes from the recent site-directed mutagenesis of E. coli pyridine nucleotide transhydrogenase showing that the first Gly residue is also essential for function (28). Another intriguing parallel is that CnxF loss-of-function occurs when the highly conserved Arg-208 is replaced by Glu in A. nidulans mutant strain cnxF200. In the case of E. coli transhydrogenase, replacement of the Arg residue that locates at an identical distance 36 residues downstream from the first Gly residue to that in CnxF also leads to loss of activity. This basic residue of the transhydrogenase is thought to interact with the 2'-phosphate of NADP(H) and is not found in a comparable position in proteins which possess NAD(H)-binding sites, but the crucial role played by this Arg residue is unclear. That the Arg residue is not found at these positions in NAD binding sites, it may be concluded that NADP, GTP, or ATP is the binding nucleotide. The functionality of the other Gly-X-Gly-X-X-Gly motif (CnxF residues 189-194) is unclear. However this motif may not be required for nucleotide binding since it is not found in association with other residues recognized in other nucleotide binding proteins and is not conserved in the prokaryotic proteins MoeB, ThiF, or HesA although there is a second Gly-X-Gly-X-X-Gly motif in yeast Uba1.
Two temperature-sensitive mutants (cnxF21 and cnxF24) result in an identical nucleotide change (G to A) to alter the Gly-160 residue to Asp, a result verified by resequencing further strain copies of these mutants. These are likely to be independently isolated mutations as reported originally since the two strains can be distinguished by their subtly different morphological phenotype. Their temperature-sensitive phenotype, i.e. growth on nitrate at 25 °C but not 37 °C would suggest that the enzyme has some activity at 25 °C but not 37 °C, and indicates that the Gly residue at position 160 is important to permit correct protein folding and hence catalysis. Also, it should be noted that both cnxF21 and cnxF24 mutants fail to grow on hypoxanthine at both temperatures. This totally mutant phenotype at both temperatures on hypoxanthine is in accord with other A. nidulans cnx temperature-conditional mutants such as cnxA140 (10), cnxC20 (33), and several cnxH strains (30). It was suggested by these workers that xanthine dehydrogenase (purine hydroxylase I) has a more stringent requirement for the molybdopterin cofactor than nitrate reductase. The cnxF142 mutation is phenotypically distinct from cnxF21 and cnxF24 in that this mutant fails to grow on nitrate and hypoxanthine at both temperatures but is chlorate-resistant (mutant) at 37 °C while sensitive (wild-type) at 25 °C. It is not clear what the basis of this phenotype is, but the mutation results in change of the highly conserved Gly-343 to Ser although it suggests that, at 25 °C, either no cofactor is formed or the cofactor is synthesized but is in some way defective in its dithiolene chelation of molybdenum.
The regulation of molybdenum cofactor biosynthesis was first studied by Garrett and Cove in A. nidulans (5). Using an assay for formation of nitrate reductase activity in vitro similar to the nit-1 assay (in the Introduction), they observed levels of cofactor consistent with a degree of regulation depending on the nitrogen source and suggested that its formation is ammonium-repressed. Transcript analysis presented here shows that cnxF is expressed at the same level in cells grown with ammonium or nitrate as the sole nitrogen source. In contrast, the cnxABC transcript level is considerably higher in cells grown with nitrate than ammonium (10), which might suggest that, if there is transcriptional control of the molybdopterin biosynthetic genes, it is exerted on the cnxABC locus, at least, but not cnxF.
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ACKNOWLEDGEMENTS |
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We are grateful for receipt of the autonomously replicating plasmid pHELP from Dr. A. J. Clutterbuck, University of Glasgow, United Kingdom, and the argB-based A. nidulans genomic library from Dr. M. Penalva, Madrid, Spain. We also thank Dr. H. B. Nicholas, Pittsburgh Supercomputing Center, for helpful suggestions on amino acid similarity searching and significance of the CnxF C terminus.
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FOOTNOTES |
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* This research was funded in part by the United Kingdom Biotechnology and Biology Science Research Council (BBSRC).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF055287.
Recipient of a research scholarship from and present address
at: The University of Mu'tah, P. O. Box 7, Karak, Jordan.
§ Present address: Institute of Biomedical Sciences, University of Dundee, Dundee DD1 4HN, United Kingdom.
** Recipient of a Royal Society (London) travel award for study in Australia.
To whom correspondence should be addressed. Tel.: 03-9905-4323;
Fax: 03-9905-4811; E-mail: shiela.unkles{at}med.monash.edu.au.
1 The abbreviations used are: PCR, polymerase chain reaction; HPLC, high performance liquid chromatography; kb, kilobase(s).
2 I. S. Heck, unpublished data.
3 S. E. Unkles, unpublished data.
4 M. V. C. L. Appleyard, unpublished data.
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REFERENCES |
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