Isolation and sequence analysis of the fatty acid synthetase FAS2 gene from Penicillium patulum

Characterization of the novel antifungal chitosanase PgChP and the encoding gene from Penicillium chrysogenum

The protein PgChP is a new chitosanase produced by Penicillium chrysogenum AS51D that showed antifungal activity against toxigenic molds. Two isoforms were found by SDS-PAGE in the purified extract of PgChP. After enzymatic deglycosylation, only the smaller isoform was observed by SDS-PAGE. Identical amino acid sequences were obtained from the two isoforms. Analysis of the molecular mass by electrospray ionization-mass spectrometry revealed six major peaks from 30 to 31 kDa that are related to different levels of glycosylation. The pgchp gene has 1,146 bp including four introns and an open reading frame encoding a protein of 304 amino acids. The translated open reading frame has a predicted mass of 32 kDa, with the first 21 amino acids comprising a signal peptide. Two N glycosylation consensus sequences are present in the protein sequence. The deduced sequence showed high identity with fungal chitosanases. A high level of catalytic activity on chitosan was observed. PgChP is the first chitosanase described from P. chrysogenum. Given that enzymes produced by this mold species are granted generally recognized as safe status, PgChP could be used as a food preservative against toxigenic molds and to obtain chitosan oligomers for food additives and nutraceuticals.

Characterization of the novel antifungal protein PgAFP and the encoding gene of Penicillium chrysogenum

The strain RP42C from Penicillium chrysogenum produces a small protein PgAFP that inhibits the growth of some toxigenic molds. The molecular mass of the protein determined by electrospray ionization mass spectrometry (ESI-MS) was 6 494Da. PgAFP showed a cationic character with an estimated pI value of 9.22. Upon chemical and enzymatic treatments of PgAFP, no evidence for N- or O-glycosylations was obtained. Five partial sequences of PgAFP were obtained by Edman degradation and by ESI-MS/MS after trypsin and chymotrypsin digestions. Using degenerate primers from these peptide sequences, a segment of 70bp was amplified by PCR from pgafp gene. 5'- and 3'-ends of pgafp were obtained by RACE-PCR with gene-specific primers designed from the 70bp segment. The complete pgafp sequence of 404bp was obtained using primers designed from 5'- and 3'-ends. Comparison of genomic and cDNA sequences revealed a 279bp coding region interrupted by two introns of 63 and 62bp. The precursor of the antifungal protein consists of 92 amino acids and appears to be processed to the mature 58 amino acids PgAFP. The deduced amino acid sequence of the mature protein shares 79% identity to the antifungal protein Anafp from Aspergillus niger. PgAFP is a new protein that belongs to the group of small, cysteine-rich, and basic proteins with antifungal activity produced by ascomycetes. Given that P. chrysogenum is regarded as safe mold commonly found in foods, PgAFP may be useful to prevent growth of toxigenic molds in food and agricultural products.

A gene having sequence homology to isoamyl alcohol oxidase is transcribed during patulin production in Penicillium griseofulvum

The genes for the patulin biosynthetic pathway are most likely arranged in a cluster, as is often the case for other mycotoxins. With this in mind, GeneWalking has been performed to identify genes both upstream and downstream of the isoepoxydon dehydrogenase (idh) gene. A gene present in Penicillium griseofulvum NRRL 2159A had high sequence homology to the isoamyl alcohol oxidase (iao) gene and was detected downstream of the idh gene and in the same orientation. By virtue of the presence of a signal peptide sequence, the newly identified gene coded for a secreted protein with an FAD-binding domain and potential for N-glycosylation. An open reading frame consisted of 1946 nucleotides, containing four putative introns and encoding a 22 amino acid signal peptide. The 571 amino acid mature protein contained nine cysteine residues and had 11 potential N-linked glycosylation sites. Searches using GenBank indicated that Aspergillus terreus, A. oryzae, A. fumigatus, and Gibberella zeae contain genes coding for a putative isoamyl alcohol oxidase. When the translated query was compared with the translated database, the highest scores were seen with A. clavatus (E value of 0.00), A. fumigatus (E value of 8e(-142)), and A. oryzae and A. terreus (each having an E value of 2e(-141)). Reverse transcription-polymerase chain reaction analysis confirmed that the iao gene was transcribed. The amplified products were sequenced for confirmation of their identities. This is the first report of an isoamyl alcohol oxidase gene in a species of the genus Penicillium.

Roles of secondary metabolites from microbes

The common feature of the seemingly diverse array of biological activities exhibited by microbial secondary metabolites is their survival value for the producing organism. The propensity to form these compounds is unevenly distributed in microbial taxa and seems more closely associated with existence in a competitive environment than with phylogeny. The characteristic multibranched elaboration of secondary biosynthetic pathways and the marked species specificity of the end products are consistent with their evolution by an 'inventive' mechanism. The species specificity suggests that distinctive terminal reactions may be of recent origin. However, comparisons of the nucleotide sequence of genes involved in the biosynthesis of phenazine and polyketide metabolites with related genes of primary pathways indicate that the secondary pathways have not evolved exclusively within the organisms in which they are now found. Sequence similarities with related primary pathway genes in phylogenetically distant organisms suggest that gene transfer has played an important part in the evolution of secondary metabolism. The diversity of products may reflect the many roles for which secondary metabolites have been selected after the genes for their biosynthesis have transferred to organisms with different physiologies and different environment challenges.

Genes for polyketide secondary metabolic pathways in microorganisms and plants

Recent advances in molecular genetics have led to the isolation, sequencing and functional analysis of genes encoding synthases that catalyse the formation of several classes of polyketides. The structures of the genes and their protein products differ strikingly in the various examples. For Streptomyces aromatic polyketides, exemplified by granaticin and tetracenomycin, the synthases correspond to Type II (bacterial and plant) fatty acid synthases in consisting of distinct proteins for such processes as condensation, acyl carrier function and ketoreduction. In contrast, for actinomycete macrolides such as erythromycin, similar catalytic functions are performed by a set of multifunctional proteins resembling Type I (animal) fatty acid synthases, but with every step in chain-building being catalysed by a different enzymic domain. Penicillium patulum has a simple Type I synthase for 6-methylsalicylic acid. For plant chalcones and stilbenes, a single small polypeptide acts as a condensing enzyme for carbon chain-building and may be unrelated to any of the other polyketide and fatty acid synthases. Thus, although these systems share a common general mechanism of chain assembly, they must differ in the ways that synthase 'programming' has evolved to determine chain length, choice of chain starter and extender units, and handling of successive keto groups during chain assembly, and so control the great diversity of possible chemical products.

Constructing polyketides: from collie to combinatorial biosynthesis

In a new golden age, polyketides are investigated and manipulated with the tools of molecular biology and genetics; hybrid polyketides can be produced. Pharmaceutical companies hope to find new and useful polyketide products, including antibiotics, anthelminthics, and immunosuppressants. This review describes the past developments (largely chemical) on which the present investigations are based, attempts to make sense of the expanding scope of polyketides, looks at the shifting research focus around polyketides, presents a working definition in biosynthetic terms, and takes note of recent work in combinatorial biosynthesis. Also discussed is the failure of the classical enzymological approach to polyketide biosynthesis.

Aspergillus has distinct fatty acid synthases for primary and secondary metabolism

Aspergillus nidulans contains two functionally distinct fatty acid synthases (FASs): one required for primary fatty acid metabolism (FAS) and the other required for secondary metabolism (sFAS). FAS mutants require long-chain fatty acids for growth, whereas sFAS mutants grow normally but cannot synthesize sterigmatocystin (ST), a carcinogenic secondary metabolite structurally and biosynthetically related to aflatoxin. sFAS mutants regain the ability to synthesize ST when provided with hexanoic acid, supporting the model that the ST polyketide synthase uses this short-chain fatty acid as a starter unit. The characterization of both the polyketide synthase and FAS may provide novel means for modifying secondary metabolites.

Aberrant mitosis in fission yeast mutants defective in fatty acid synthetase and acetyl CoA carboxylase

Two fission yeast temperature-sensitive mutants, cut6 and lsd1, show a defect in nuclear division. The daughter nuclei differ dramatically in size (the phenotype designated lsd, large and small daughter). Fluorescence in situ hybridization (FISH) revealed that sister chromatids were separated in the lsd cells, but appeared highly compact in one of the two daughter nuclei. EM showed asymmetric nuclear elongation followed by unequal separation of nonchromosomal nuclear structures in these mutant nuclei. The small nuclei lacked electron-dense nuclear materials and contained highly compacted chromatin. The cut6+ and lsd1+ genes are essential for viability and encode, respectively, acetyl CoA carboxylase and fatty acid synthetase, the key enzymes for fatty acid synthesis. Gene disruption of lsd1+ led to the lsd phenotype. Palmitate in medium fully suppressed the phenotypes of lsd1. Cerulenin, an inhibitor for fatty acid synthesis, produced the lsd phenotype in wild type. The drug caused cell inviability during mitosis but not during the G2-arrest induced by the cdc25 mutation. A reduced level of fatty acid thus led to impaired separation of non-chromosomal nuclear components. We propose that fatty acid is directly or indirectly required for separating the mother nucleus into two equal daughters.

Purification and characterization of fatty acid synthetase from Cryptococcus neoformans

Fatty acid synthetase has been purified from Cryptococcus neoformans 450 fold to a specific activity of 3.6 units per mg protein with an overall yield of 23%. The purified enzyme contained two non-identical subunits, Mr approximately 2.1 x 10(5) and 1.8 x 10(5). Under optimum conditions, 100 mM KCl and pH 7.5, apparent K(m) values for the substrates were: Acetyl CoA, 19 microM; Malonyl CoA, 5 microM; and NADPH, 6 microM. Product inhibition patterns were determined to be: CoA, competitive versus acetyl CoA and malonyl CoA, uncompetitive versus NADPH; NADP, competitive versus NADPH, uncompetitive versus acetyl CoA and malonyl CoA; Palmitoyl CoA, competitive versus malonyl CoA, noncompetitive versus acetyl CoA and NADPH; Bicarbonate, uncompetitive versus malonyl CoA. These product inhibition patterns are consistent with the multisite ping-pong mechanism previously proposed for the avian fatty acid synthetase complex. The cryptococcal fatty acid synthetase was inhibited by the polyanionic polymers, heparin and dextran sulfate, an effect never before demonstrated for a fatty acid synthetase. This inhibition exhibited a marked dependence on the length of the polymer chain, with dextran sulfate fractions with Mr of 6 x 10(5) and above having Ki values below 100 nanomolar. A model is presented that involves initial binding of the anionic polymer to the enzyme complex at a region of high positive charge density, followed by interaction of the end of the tethered polymer with the catalytic site. This study represents the first purification of fatty acid synthetase from a basidiomycete.

Expression of an active adenylate-forming domain of peptide synthetases corresponding to acyl-CoA-synthetases

Peptide synthetases and acyl-CoA-synthetases form acyl adenylates which are transferred to CoA or enzyme-bound pantetheine. To verify the existence of an adenylate domain in peptide synthetases, a 60.8 kDa fragment of tyrocidine 1-synthetase was constructed by a 1,629 bp deletion, expressed in Escherichia coli, and characterized. The truncated multienzyme activated phenylalanine and substrate analogues with comparable kinetics as the over-expressed synthetase, as judged by ATP-[32P]PP(i) exchange reaction. Thus the N-terminal domain resembling an acyl-CoA-synthetase is an autonomous structural element. This N-terminal domain is followed by a cofactor binding domain, resembling acyl carrier proteins involved in polyketide formation.

Cerulenin-resistant mutants of Saccharomyces cerevisiae with an altered fatty acid synthase gene

Cerulenin, an antifungal antibiotic produced by Cephalosporium caerulens, is a potent inhibitor of fatty acid synthase in various organisms, including Saccharomyces cerevisiae. The antibiotic inhibits the enzyme by binding covalently to the active center cysteine of the condensing enzyme domain. We isolated 12 cerulenin-resistant mutants of S. cerevisiae following treatment with ethyl methanesulfonate. The mechanism of cerulenin resistance in one of the mutants, KNCR-1, was studied. Growth of the mutant was over 20 times more resistant to cerulenin than that of the wild-type strain. Tetrad analysis suggested that all mutants mapped at the same locus, FAS2, the gene encoding the alpha subunit of the fatty acid synthase. The isolated fatty acid synthase, purified from the mutant KNCR-1, was highly resistant to cerulenin. The cerulenin concentration causing 50% inhibition (IC50) of the enzyme activity was measured to be 400 microM, whereas the IC50 value was 15 microM for the enzyme isolated from the wild-type strain, indicating a 30-fold increase in resistance to cerulenin. The FAS2 gene was cloned from the mutant. Sequence replacement experiments suggested that an 0.8 kb EcoRV-HindIII fragment closely correlated with cerulenin resistance. Sequence analysis of this region revealed that the GGT codon encoding Gly-1257 of the FAS2 gene was altered to AGT in the mutant, resulting in the codon for Ser. Furthermore, a recombinant FAS2 gene, in which the 0.8 Kb EcoRV-HindIII fragment of the wild-type FAS2 gene was replaced with the same region from the mutant, when introduced into FAS2-defective S. cerevisiae complemented the FAS2 phenotype and showed cerulenin resistance.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure and metabolic control of the Yarrowia lipolytica peroxisomal 3-oxoacyl-CoA-thiolase gene

Using a Yarrowia lipolytica genomic library, several overlapping clones of the peroxisomal 3-oxoacyl-CoA-thiolase gene, POT1, were isolated. The library was prepared in the bacterial expression vector lambda gt11, thus allowing an immunological screening of recombinant bacteriophages with specific antibodies raised against purified peroxisomal thiolase. The isolated POT1 clones hybridized to a 1.4 kb RNA species, which was induced approximately 30-fold when oleate was the carbon source. A 3634-bp segment of the cloned DNA was sequenced. This segment contained, on both strands, three major overlapping open-reading frames of 678, 1122 and 1242 bp. Northern-hybridization analysis showed that only the largest of these reading frames was transcribed. It encodes a protein of 414 amino acids and molecular mass 43.059 kDa. Its deduced amino acid sequence has 30-60% identity and 50-70% sequence similarity when compared to other known thiolases. According to both the amount (68-71%) and location of conserved amino acids, the encoded protein belongs to the peroxisomal rather than the mitochondrial or cytoplasmic class of thiolases. Compared to bacterial and yeast cytosolic thiolases, the POT1 gene product contains a N-terminal extension of 25 amino acids which clearly differs from typical mitochondrial import signals. One of the isolated clones contained, in addition to the POT1 coding sequence, 784 bp of the corresponding 5' flanking region. Nevertheless, it was efficiently expressed in Escherichia coli suggesting the correct recognition of this fungal promoter by the prokaryotic transcriptional and translational machinery. The Y. lipolytica genomic POT1 gene was disrupted by replacing 120 bp of its coding sequence with 2.7 kbp of DNA including the Y. lipolytica LEU2 gene. The resulting delta pot1::LEU2 cells were free of immunologically cross-reacting thiolase. Western-blot analysis showed that the product of the non-disrupted gene had a molecular mass of approximately 42 kDa. This corresponds well to the molecular mass of purified Y. lipolytica peroxisomal thiolase. Disruption of POT1 abolished the ability of Y. lipolytica cells to grow on solid media with oleate as a carbon source. This inability to grow in the presence of oleate suggests both the catabolic function of POT1 and the absence of additional catabolic thiolases in Y. lipolytica. However, the delta pot1::LEU2 cells were unaffected in their ability to elongate externally added tridecanoic acid to its higher-chain-length homologues. Hence, another, POT1-independent and biosynthetic 3-oxoacyl-CoA thiolase must be responsible for this reaction in Y. lipolytica.

Gene cluster involved in melanin biosynthesis of the filamentous fungus Alternaria alternata

The filamentous fungus Alternaria alternata produces melanin, a black pigment, from acetate via 1,8-dihydroxynaphthalene. To isolate a fungal gene required for melanin biosynthesis, we transformed an A. alternata Brm1- (light brown) mutant with the DNA of a wild-type strain genomic library constructed by use of a cosmid carrying the hygromycin B phosphotransferase gene. When hygromycin B-resistant transformants were screened for melanin production, 1 of 1,363 transformants appeared to regain melanin production, as judged by black pigmentation of the cultured mycelia. The cosmid, named pMBR1, was recovered by packaging nuclear DNA of the melanin-producing transformant into lambda phage. The gene on pMBR1 that enables the Brm1- mutant to produce melanin was designated BRM1. In addition to the BRM1 gene, pMBR1 was found to carry two more genes involved in melanin biosynthesis. These two genes, designated ALM and BRM2, transformed A. alternata Alm- (albino) and Brm2- (brown) mutants, respectively, to the wild-type phenotype. The three genes are located within a ca. 30-kb genomic region in the order ALM-BRM1-BRM2. Analysis of the gene transcripts indicated approximate sizes of 7.2, 4.0, and 0.9 kb for ALM, BRM1, and BRM2, respectively. The BRM1 and BRM2 transcripts are generated from the same strand, but the ALM transcript is generated from the opposite strand. The three mRNA species accumulate in cultured mycelia of the wild-type strain synchronously with mycelial melanization. The essential roles of the three genes in melanin biosynthesis were confirmed by transformation-mediated gene disruption experiments.

Molecular characterization of the enniatin synthetase gene encoding a multifunctional enzyme catalysing N-methyldepsipeptide formation in Fusarium scirpi

The gene encoding the multifunctional enzyme enniatin synthetase from Fusarium scirpi (esyn1) was isolated and characterized by transcriptional mapping and expression studies in Escherichia coli. This is the first example of a gene encoding an N-methyl peptide synthetase. The nucleotide sequence revealed an open reading frame of 9393 bp encoding a protein of 3131 amino acids (M(r) 346,900). Two domains designated EA and EB within the protein were identified which share similarity to each other and to microbial peptide synthetase domains. In contrast to the N-terminal domain EA, the carboxyl terminal domain EB is interrupted by a 434-amino-acid portion which shows local similarity to a motif apparently conserved within adenine and cytosine RNA and DNA methyltransferases and therefore seems to harbour the N-methyl-transferase function of the multienzyme.

Purification and properties of 6-methylsalicylic acid synthase from Penicillium patulum

6-Methylsalicylic acid synthase has been isolated in homogeneous form from Penicillium patulum grown in liquid culture from a spore inoculum. The enzyme is highly susceptible to proteolytic degradation in vivo and in vitro, but may be stabilized during purification by incorporating proteinase inhibitors in the buffers. The enzyme exists as a homotetramer of M(r) 750,000, with a subunit M(r) of 180,000. 6-Methylsalicyclic acid synthase also accepts acetoacetyl-CoA as an alternative starter molecule to acetyl-CoA. The enzyme also catalyses the formation of small amounts of triacetic acid lactone as an oligatory by-product of the reaction. In the absence of NADPH, triacetic acid lactone is the exclusive enzymic product, being formed at 10% of the rate of 6-methylsalicylic acid. The enzyme is inactivated by 1,3-dibromopropan-2-one, leading to the formation of cross-linked dimers similar to that observed with type I fatty acid synthases. Acetyl-CoA protects the enzyme against the inactivation and inhibits dimer formation. An adaptation of the purification method for 6-methylsalicylic acid synthase may be used for the isolation of fatty acid sythase from Penicillium patulum.

Analysis of a polyketide synthesis-encoding gene cluster of Streptomyces curacoi

A gene cluster homologous to the beta-ketoacyl synthase-encoding gene, actl, was cloned by Southern blot hybridization from Streptomyces curacoi, and a 5469-bp fragment was sequenced. Analysis of the sequence revealed seven open reading frames (ORFs). A striking similarity to the whiE locus (encoding spore pigment synthesis) of Streptomyces coelicolor was found throughout the whole cluster, with conservation of the size and position of the seven ORFs. The structure of these two gene clusters suggests that they have a common origin, although the lower similarity in the noncoding regions suggests that the regulatory regions have diverged through evolution.

Secondary metabolism, inventive evolution and biochemical diversity--a review

Evidence now being obtained through nucleotide (nt) sequence analysis supports the concept that secondary metabolism has arisen by modification of existing primary metabolic reactions. Although amino acid sequence identity deduced from nt sequences of genes encoding proteins from related primary and secondary metabolic pathways is sufficient to indicate a common ancestry, the match is often better when genes in different rather than in the same species are compared. The information so far available suggests that gene transfer between organisms has been an important factor in the evolution of secondary metabolism. Many secondary pathways may be of relatively ancient origin and they may have arisen only infrequently. Much subsequent elaboration of the pathways has probably taken place after their acquisition by other species and so has been influenced by a variety of selective conditions. The characteristic diversity of secondary metabolites and their functions can be accounted for by the random manner in which the pathways initially evolved and have subsequently been exploited.

Molecular structure of the multifunctional fatty acid synthetase gene of Brevibacterium ammoniagenes: its sequence of catalytic domains is formally consistent with a head-to-tail fusion of the two yeast genes FAS1 and FAS2

The Brevibacterium ammoniagenes fatty acid synthetase (FAS) gene was isolated from a series of overlapping clones by both immunological and plaque hybridization screening of two independent gene libraries. From the isolated DNA a contiguous segment of 10,549 bp was sequenced in both directions. The sequenced DNA contained a very long (9312 nucleotides) open reading frame coding for a protein of 3104 amino acids and with a molecular mass of 327,466 daltons. Based on characteristic sequence motifs known from other FAS systems, seven different FAS active centres were identified at distinct locations within the polypeptide chain. Only one component enzyme, the 3-hydroxydecanoyl beta, gamma-dehydratase, has not yet been localized definitively within the gene. Translation is presumed to start from a GUG triplet located 25 nucleotides downstream of the transcriptional initiation site. There is a canonical Shine-Dalgarno sequence just before this start codon. Comparison of the B. ammoniagenes FAS sequence with those of other known fatty acid synthetases revealed a particularly high degree of similarity to the products of the two yeast genes, FAS1 and FAS2 (30% identical and 46% identical plus closely related amino acids). This similarity extends over the entire length of the genes and involves not only the primary sequences of individual component enzymes but also their sequential order within the multifunctional proteins. These data, together with those on the structure of other fatty acid synthetases, are interpreted in terms of a contribution of both primary structure and subunit cooperation to a conserved topology of functional domains common to all type I FAS complexes.

The fatty acid synthase (FAS) gene and its promoter in Rattus norvegicus

Screening of rat liver genomic libraries yielded 5 overlapping clones for rat fatty acid synthase (FAS). From these clones we determined the 18,170 bp sequence of the rat FAS together with 5,028 bp of the 5'-flanking region and 515 bp of the 3'-adjacent genomic sequence. The two FAS transcripts which differ only in the positions of their polyadenylation/termination sites consist of one untranslated and 42 translated exons. Surprisingly, the substrate binding site for enoyl reductase, one of the FAS component functions, is interrupted by an intron. The sizes and the boundaries of the individual domains could be mapped in relation to the exon/intron structure of the gene. These eight partial functions coincide with discrete units of exons. The acyl carrier protein with its prosthetic 4'-phosphopantetheine group is located within a single exon supporting the idea that rat FAS has evolved by gene fusion. Using primer extension the main transcription start site of the FAS mRNA in both hepatic and mammary gland tissues was located at 5,028 bp in the sequence determined. As expected of a gene which is pretranslationally regulated the 5'-flanking region contains, in addition to TATA and CAAT boxes, consensus sequences for several DNA binding proteins.

The pentafunctional FAS1 genes of Saccharomyces cerevisiae and Yarrowia lipolytica are co-linear and considerably longer than previously estimated

The fatty acid synthetase (FAS) gene FAS1 of the alkane-utilizing yeast Yarrowia lipolytica was cloned and sequenced. The gene is represented by an intron-free reading frame of 6228 bp encoding a protein of 2076 amino acids and 229,980 Da molecular weight. This protein exhibits a 58% sequence similarity to the corresponding Saccharomyces cerevisiae FAS beta-subunit. The sequential order of the five FAS1-encoded enzyme The sequential order of the five FAS1-encoded enzyme domains, acetyl transferase, enoyl reductase, dehydratase and malonyl/palmityl-transferase, is co-linear in both organisms. This finding agrees with available evidence that the functional organization of FAS genes is similar in related organisms but differs considerably between unrelated species. In addition, previously reported conflicting data concerning the 3' end of S. cerevisiae FAS1 were re-examined by genomic and cDNA sequencing of the relevant portion of the gene. Thereby, the translational stop codon was shown to lie considerably downstream of both published termination sites. The S. cerevisiae FAS1 gene thus has a corrected length of 6153 bp and encodes a protein of 2051 amino acids and 228,667 Da molecular weight.

Proteolytic events in the processing of secreted proteins in fungi

Secreted heterologous proteins have been found to be produced much less efficiently by fungi than secreted homologous ones. This could be due, at least in part, to proteolytic cleavage by site-specific endoproteases of the secretory pathway, similar to the yeast KEX2 protease and the mammalian dibasic endoproteinases found in secretory pathways. Mature secreted fungal proteins may be protected from such cleavage due to the absence of cleavable sites in exposed regions. A comparison of the dipeptide distributions of 33 secreted and 34 cytoplasmic proteins from fungal producers of extracellular enzymes indicated a significant bias for some doublets, including the basic dipeptides Lys-Arg, Arg-Arg and Arg-Lys which have also been demonstrated to be KEX2 substrates. Other combinations were also found to be rare in secreted proteins, which could indicate either a broader specificity of the considered endopeptidase, or the presence either in the secretory organelles or among the secreted proteins of additional proteases with different specificities. Experimental evidence that the Lys-Arg site is processed in Tolypocladium geodes was provided by cloning a synthetic prosequence upstream of a phleomycin resistance (Sh ble) gene and analyzing the N-terminus of the corresponding protein purified from the culture supernatant. This system also provides a tool for further studies of specific proteases of fungi.

The multifunctional 6-methylsalicylic acid synthase gene of Penicillium patulum. Its gene structure relative to that of other polyketide synthases

6-Methylsalicylic acid synthase (MSAS) from Penicillium patulum is a homomultimer of a single, multifunctional protein subunit. The enzyme is induced, at the transcriptional level, during the end of the logarithmic growth phase. After approximately 150-fold purification, a homogeneous enzyme preparation was obtained exhibiting, upon SDS gel electrophoresis, a subunit molecular mass of 188 kDa. By immunological screening of a genomic P. patulum DNA expression library, the MSAS gene together with its flanking sequences was isolated; 7131 base pairs of the cloned genomic DNA were sequenced. Within this sequence the MSAS gene was identified as a 5322-bp-long open reading frame coding for a protein of 1774 amino acids and 190,731 Da molecular mass. Transcriptional initiation and termination sites were determined both by primer extension studies and from cDNA sequences specially prepared for the 5' and 3' portions of the gene. The same cDNA sequences revealed the presence of a 69-bp intron within the N-terminal part of the MSAS gene. The intron contains the canonical GT and AG dinucleotides at its 5'- and 3'-splice junctions. An internal TACTGAC sequence, resembling the TACTAAC consensus element of Saccharomyces cerevisiae introns is suggested to represent the branch point of the lariat splicing intermediate. When compared to other known polyketide synthases, distinct amino acid sequence similarities of limited lengths were observed with some, though not all, of them. A comparatively low degree of similarity was detected to the yeast and Penicillium FAS or to the plant chalcone and resveratrol synthases. In contrast, a significantly higher sequence similarity was found between MSAS and the rat fatty acid synthase, especially at their transacylase, 2-oxoacyl reductase, 2-oxoacyl synthase and acyl carrier protein domains. Besides several dissimilar, interspersed regions probably coding for MSAS- and FAS-specific functions, the sequential order of the similar domains was colinear in both enzymes. The low similarity between the two P. patulum polyketide synthases, MSAS and FAS, possibly supports a convergent rather than a divergent evolution of both multienzyme proteins.

Antibiotics--cloning of biosynthetic pathways

Biosynthetic pathways leading to antibiotics have often been found to be clustered, and new organizational forms of multifunctional enzymes have been discovered. Such polyenzymes accomplish the synthesis of complex metabolites such as peptides or polyketides by a sequence of enzymatic reactions. So, reactions leading to the tripeptide precursor of beta-lactam antibiotics, ACV, or to the cycloundecapeptide cyclosporine have been fused into single polypeptide chain synthetases, respectively. In certain isofunctional sites restricted similarities have been detected.