Overexpression of the crgA gene abolishes light requirement for carotenoid biosynthesis in Mucor circinelloides

Light irradiation changes the regulation pattern of BtCrgA on carotenogenesis in Blakeslea trispora

CrgA has been shown to be a negative regulator of carotenogenesis in some filamentous fungi, while light irradiation is an inducible environmental factor for carotenoid biosynthesis. To clarify the relationship between CrgA and light-inducible carotenogenesis in Blakeslea trispora, the cis-acting elements of the btcrgA promoter region were investigated, followed by the analyses of correlation between the expression of btcrgA and carotenoid structural genes under different irradiation conditions. A variety of cis-acting elements associated with light response was observed in the promoter region of btcrgA, and transcription of btcrgA and carotenoid structural genes under different irradiation conditions was induced by white light with a clear correlation. Then, RNA interference and overexpression of btcrgA were performed to investigate their effects on carotenogenesis at different levels under irradiation and darkness. The analyses of transcription and enzyme activities of carotenoid structural gene, and accumulation of carotenoids among btcrgA-interfered, btcrgA-overexpressed, and wild-type strains under irradiation and darkness indicate that btcrgA negatively regulates the synthesis of carotenoid in darkness, while promotes the carotenogenesis under irradiation regardless of reduced or overexpression of btcrgA .

Relation between CarS expression and activation of carotenogenesis by stress in Fusarium fujikuroi

Fusarium fujikuroi, a model organism for secondary metabolism in fungi, produces carotenoids, terpenoid pigments with antioxidant activity. Previous results indicate that carotenoid synthesis in F. fujikuroi is stimulated by light or by different stress conditions and downregulated by a RING finger protein encoded by carS gene. Here, we have analyzed the effects of three stressors, nitrogen scarcity, heat shock, and oxidative stress. We compared them with the effect of light in the wild type, a carS mutant that overproduces carotenoids, and its complemented strain. The assayed stressors increase the synthesis of carotenoids in the three strains, but mRNA levels of structural genes of carotenogenesis, carRA and carB, are only enhanced in the presence of a functional carS gene. In the wild-type strain, the four conditions affect in different manners the mRNA levels of carS: greater in the presence of light, without significant changes in nitrogen starvation, and with patent decreases after heat shock or oxidative stress, suggesting different activation mechanisms. The spores of the carS mutant are more resistant to H₂O₂ than those of the wild type; however, the mutant shows a greater H₂O₂ sensitivity at the growth level, which may be due to the participation of CarS in the regulation of genes with catalase domains, formerly described. A possible mechanism of regulation by heat stress has been found in the alternative splicing of the intron of the carS gene, located close to its 3′ end, giving rise to the formation of a shorter protein. This action could explain the inducing effect of the heat shock, but not of the other inducing conditions, which may involve other mechanisms of action on the CarS regulator, either transcriptionally or post-transcriptionally.

A Negative Regulator of Carotenogenesis in Blakeslea trispora

As an ideal carotenoid producer, Blakeslea trispora has gained much attention due to its large biomass and high production of β-carotene and lycopene. However, carotenogenesis regulation in B. trispora still needs to be clarified, as few investigations have been conducted at the molecular level in B. trispora In this study, a gene homologous to carotenogenesis regulatory gene (crgA) was cloned from the mating type (-) of B. trispora, and the deduced CrgA protein was analyzed for its primary structure and domains. To clarify the crgA-mediated regulation in B. trispora, we used the strategies of gene knockout and complementation to investigate the effect of crgA expression on the phenotype of B. trispora In contrast to the wild-type strain, the crgA null mutant (ΔcrgA) was defective in sporulation but accumulated much more β-carotene (31.2% improvement at the end) accompanied by enhanced transcription of three structural genes (hmgR, carB, and carRA) for carotenoids throughout the culture time. When the wild-type copy of crgA was complemented into the crgA null mutant, sporulation, transcription of structural genes, and carotenoid production were restored to those of the wild-type strain. A gas chromatography-mass spectrometry (GC-MS)-based metabolomic approach and multivariate statistical analyses were performed to investigate the intracellular metabolite profiles. The reduced levels of tricarboxylic acid (TCA) cycle components and some amino acids and enhanced levels of glycolysis intermediates and fatty acids indicate that more metabolic flux was driven into the mevalonate (MVA) pathway; thus, the increase of precursors and fat content contributes to the accumulation of carotenoids.IMPORTANCE The zygomycete Blakeslea trispora is an important strain for the production of carotenoids on a large scale. However, the regulation mechanism of carotenoid biosynthesis is still not well understood in this filamentous fungus. In the present study, we sought to investigate how crgA influences the expression of structural genes for carotenoids, carotenoid biosynthesis, and other anabolic phenotypes. This will lead to a better understanding of the global regulation mechanism of carotenoid biosynthesis and facilitate engineering this strain in the future for enhanced production of carotenoids.

Light regulates a Phycomyces blakesleeanus gene family similar to the carotenogenic repressor gene of Mucor circinelloides

The transcription of about 5-10 % of the genes in Phycomyces blakesleeanus is regulated by light. Among the most up-regulated, we have identified four genes, crgA-D, with similarity to crgA of Mucor circinelloides, a gene encoding a repressor of light-inducible carotenogenesis. The four proteins have the same structure with two RING RING Finger domains and a LON domain, suggesting that they could act as ubiquitin ligases, as their M. circinelloides homolog. The expression of these genes is induced by light with different thresholds as in other Mucoromycotina fungi like Blakeslea trispora and M. circinelloides. Only the P. blakesleeanus crgD gene could restore the wild type phenotype in a M. circinelloides null crgA mutant suggesting that P. blakesleeanus crgD is the functional homolog of crgA in M. circinelloides. Despite their sequence similarity it is possible that the P. blakesleeanus Crg proteins do not participate in the regulation of beta-carotene biosynthesis since none of the carotene-overproducing mutants of P. blakesleeanus had mutations in any of the crg genes. Our results provide further support of the differences in the regulation of the biosynthesis of beta-carotene in these two Mucoromycotina fungi.

Carotenoid Biosynthesis in Fusarium

Many fungi of the genus Fusarium stand out for the complexity of their secondary metabolism. Individual species may differ in their metabolic capacities, but they usually share the ability to synthesize carotenoids, a family of hydrophobic terpenoid pigments widely distributed in nature. Early studies on carotenoid biosynthesis in Fusariumaquaeductuum have been recently extended in Fusarium fujikuroi and Fusarium oxysporum, well-known biotechnological and phytopathogenic models, respectively. The major Fusarium carotenoid is neurosporaxanthin, a carboxylic xanthophyll synthesized from geranylgeranyl pyrophosphate through the activity of four enzymes, encoded by the genes carRA, carB, carT and carD. These fungi produce also minor amounts of β-carotene, which may be cleaved by the CarX oxygenase to produce retinal, the rhodopsin's chromophore. The genes needed to produce retinal are organized in a gene cluster with a rhodopsin gene, while other carotenoid genes are not linked. In the investigated Fusarium species, the synthesis of carotenoids is induced by light through the transcriptional induction of the structural genes. In some species, deep-pigmented mutants with up-regulated expression of these genes are affected in the regulatory gene carS. The molecular mechanisms underlying the control by light and by the CarS protein are currently under investigation.

Complete Genome Sequence of a High Lipid-Producing Strain of Mucor circinelloides WJ11 and Comparative Genome Analysis with a Low Lipid-Producing Strain CBS 277.49

The genome of a high lipid-producing fungus Mucor circinelloides WJ11 (36% w/w lipid, cell dry weight, CDW) was sequenced and compared with that of the low lipid-producing strain, CBS 277.49 (15% w/w lipid, CDW), which had been sequenced by Joint Genome Institute. The WJ11 genome assembly size was 35.4 Mb with a G+C content of 39.7%. The general features of WJ11 and CBS 277.49 indicated that they have close similarity at the level of gene order and gene identity. Whole genome alignments with MAUVE revealed the presence of numerous blocks of homologous regions and MUMmer analysis showed that the genomes of these two strains were mostly co-linear. The central carbon and lipid metabolism pathways of these two strains were reconstructed and the numbers of genes encoding the enzymes related to lipid accumulation were compared. Many unique genes coding for proteins involved in cell growth, carbohydrate metabolism and lipid metabolism were identified for each strain. In conclusion, our study on the genome sequence of WJ11 and the comparative genomic analysis between WJ11 and CBS 277.49 elucidated the general features of the genome and the potential mechanism of high lipid accumulation in strain WJ11 at the genomic level. The different numbers of genes and unique genes involved in lipid accumulation may play a role in the high oleaginicity of strain WJ11.

Malic enzyme activity is not the only bottleneck for lipid accumulation in the oleaginous fungus Mucor circinelloides

Commercial interest in microbial lipids is increasing due to their potential use as feedstock for biodiesel production. The supply of NADPH generated by malic enzyme (ME; NADP+-dependent; EC 1.1.1.40) has been postulated as being the rate-limiting step for fatty acid biosynthesis in oleaginous fungi, based mainly on data from the zygomycete Mucor circinelloides studies. This fungus contains five genes that code for six different ME isoforms. One of these genes, malA, codes for the isoforms III and IV, which have previously been associated with lipid accumulation. Following a strategy of targeted integration of an engineered malA gene, a stable strain overexpressing malA and showing high ME activity has been obtained, demonstrating the feasibility of this strategy to overexpress genes of biotechnological interest in M. circinelloides. This is the first report showing the integration and overexpression of a gene in Zygomycetes. Unexpectedly, the genetically modified strain showed a lipid content similar to that of a prototrophic non-overexpressing control strain, suggesting that another limiting step in the fatty acid synthesis pathway may have been revealed as a consequence of the elimination of malic enzyme-based bottleneck. Otherwise, the fact that prototrophic strains showed at least a 2.5-fold increase in lipid accumulation in comparison with leucine auxotrophic strains suggests that a wild-type leucine biosynthetic pathway is required for lipid accumulation. Moreover, increasing concentrations of leucine in culture medium increased growth of auxotrophs but failed to increase lipid content, suggesting that the leucine synthesized by the fungus is the only leucine available for lipid biosynthesis. These results support previous data postulating leucine metabolism as one of the pathways involved in the generation of the acetyl-CoA required for fatty acid biosynthesis.

Genetic basis of carotenoid overproduction in Fusarium oxysporum

The phytopathogenic fungus Fusarium oxysporum is a model organism in the study of plant-fungus interactions. As other Fusarium species, illuminated cultures of F. oxysporum exhibit an orange pigmentation because of the synthesis of carotenoids, and its genome contains orthologous light-regulated car genes for this biosynthetic pathway. By chemical mutagenesis, we obtained carotenoid overproducing mutants of F. oxysporum, called carS, with upregulated mRNA levels of the car genes. To identify the regulatory gene responsible for this phenotype, a collection of T-DNA insertional mutants obtained by Agrobacterium mediated transformation was screened for carotenoid overproduction. Three candidate transformants exhibited a carS-like phenotype, and two of them contained T-DNA insertions in the same genomic region. The insertions did not affect the integrity of any annotated ORFs, but were linked to a gene coding for a putative RING-finger (RF) protein. Based on its similarity to the RF protein CrgA from the zygomycete Mucor circinelloides, whose mutation results in a similar carotenoid deregulation, this gene (FOXG_09307) was investigated in detail. Its expression was not affected in the transformants, but mutant alleles were found in several carS mutants. A strain carrying a partial FOXG_09307 deletion, fortuitously generated in a targeted transformation experiment, exhibited the carS phenotype. This mutant and a T-DNA insertional mutant holding a 5-bp insertion in FOXG_09307 were complemented with the wild type FOXG_09307 allele. We conclude that this gene is carS, encoding a RF protein involved in down-regulation of F. oxysporum carotenogenesis.

Protein-DNA interactions in the promoter region of the Phycomyces carB and carRA genes correlate with the kinetics of their mRNA accumulation in response to light

Carotene biosynthesis in Phycomyces is photoinducible and carried out by phytoene dehydrogenase (encoded by carB) and a bifunctional enzyme possessing lycopene cyclase and phytoene synthase activities (carRA). A light pulse followed by periods of darkness produced similar biphasic responses in the expression of the carB and carRA genes, indicating their coordinated regulation. Specific binding complexes were formed between the carB-carRA intergenic region and protein extracts from wild type mycelia grown in the dark or 8min after irradiation. These two conditions correspond to the points at which the expression of both genes is minimal, suggesting that these binding complexes are involved in the down-regulation of photocarotenogenesis in Phycomyces. Protein extracts from carotene mutants failed to form the dark retardation complex, suggesting a role of these genes in the regulation of photocarotenogenesis. In contrast, protein extracts from phototropic mutants formed dark retardation complexes identical to that of the wild type.

A RING-finger photocarotenogenic repressor involved in asexual sporulation in Mucor circinelloides

Mucor circinelloides responds to blue light by activating the biosynthesis of carotenoids and bending its sporangiophores towards the light source. The CrgA protein product acts as a repressor of carotene biosynthesis, as its inactivation leads to the overaccumulation of carotenoids in both the dark and the light. We show here that asexual sporulation in Mucor is also stimulated by light and that the crgA gene is involved in sporulation, given that lack of crgA function affects both carotenogenesis and the normal production of spores. A small interference RNA (siRNA) gene silencing approach was used to block the biosynthesis of carotenoids and to demonstrate that abnormal sporulation in crgA mutants is not a consequence of a defective production of carotenes. These results reveal an active role for the predicted CrgA product, a RING-finger protein, in the control of cellular light-regulated processes in Mucor.

Non-AUG translation initiation of a fungal RING finger repressor involved in photocarotenogenesis

The RING finger protein CrgA acts as a negative regulator of light-induced carotene biosynthesis in the fungus Mucor circinelloides. Sequence analysis of the crgA coding region upstream of the first AUG codon revealed the existence of an additional non-canonical RING finger domain at the most N-terminal end of the protein. The newly identified RING finger domain is required for CrgA to regulate photocarotenogenesis, as deduced from site-directed mutagenesis experiments. The role of both RING finger domains in the stability of CrgA has been investigated in a yeast system. Wild type CrgA, but not the RING finger deleted forms, is highly unstable and is stabilized by inhibition of the proteasome function, which suggests that native CrgA is degraded by the proteasome and that active RING finger domains are required for proteasome-mediated CrgA degradation. To identify the translation start of CrgA, a mutational analysis of putative initiation codons in the 5' region of the crgA gene was accomplished. We demonstrated that a GUG codon located upstream of the first AUG is the sole initiator of CrgA translation. To our knowledge, this is the first report of a naturally occurring non-AUG start codon for a RING finger regulatory protein. A combination of suboptimal translation initiation and proteasome degradation may help to maintain the low cellular levels of CrgA observed in wild type cells, which is probably required for accurate regulation of photocarotenogenesis.

Distinct white collar-1 genes control specific light responses in Mucor circinelloides

Light regulates many developmental and physiological processes in a large number of organisms. The best-known light response in the fungus Mucor circinelloides is the biosynthesis of beta-carotene. Here, we show that M. circinelloides sporangiophores also respond to light, exhibiting a positive phototropism. Analysis of both responses to different light wavelengths within the visible spectrum demonstrated that phototropism is induced by green and blue light, whereas carotenogenesis is only induced by blue light. The blue regulation of both responses suggests the existence of blue-light photoreceptors in M. circinelloides. Three white collar-1 genes (mcwc-1a, mcwc-1b and mcwc-1c) coding for proteins showing similarity with the WC-1 photoreceptor of Neurospora crassa have been identified. All three contain a LOV (light, oxygen or voltage) domain, similar to that present in fungal and plant blue-light receptors. When knockout mutants for each mcwc-1 gene were generated to characterize gene functions, only mcwc-1c mutants were defective in light induction of carotene biosynthesis, indicating that mcwc-1c is involved in the light transduction pathway that control carotenogenesis. We have also shown that positive phototropism is controlled by the mcwc-1a gene. It seems therefore that mcwc-1a and mcwc-1c genes control different light transduction pathways, although cross-talk between both pathways probably exists because mcwc-1a is involved in the light regulation of mcwc-1c expression.

Transformation of Mucor circinelloides with Autoreplicative Vectors Containing Homologous and Heterologous ARS Elements and the Dominant Cbxr Carboxine-Resistance Gene

Mucor circinelloides transformants prototrophic to leucine and resistant to carboxine (Leu(+) Cbx(r)) have been obtained by treatment of protoplasts with plasmid constructs containing homologous leuA gene and adjacent autonomously replicating sequences (ARS) element combined with the Cbx(r)(carboxine-resistance) gene of Ustilago maydis and ARS sequences from this basidiomycete (plasmid pGG37) or from the 2 mu plasmid of Saccharomyces cerevisiae (plasmid pGG43). The presence in the same plasmid molecule of the M. circinelloides leuA gene and adjacent ARS element together with heterologous ARS elements produced an increase in the transformation frequency of about 65-120%. The presence of autoreplicating plasmid molecules in the transformants was demonstrated by mitotic stability experiments, by Southern analysis, and by the rescue of plasmids from transformed bacterial cells.

Heterologous expression of astaxanthin biosynthesis genes in Mucor circinelloides

Most Mucor species accumulate beta-carotene as the main carotenoid. The crtW and crtZ astaxanthin biosynthesis genes from Agrobacterium aurantiacum were placed under the control of Mucor circinelloides expression signals. Expression vectors containing the bacterial genes were constructed, and PEG-mediated transformations were performed on a selected M. circinelloides strain. Transformants that exhibited altered carotene production were isolated and analyzed. Southern analysis showed that all plasmids behave as autoreplicative elements. Northern analysis detected the actual heterologous transcription products, whereas thin layer chromatography and high-performance liquid chromatography studies revealed the presence of new carotenoid compounds and intermediates among the transformants.

Light induction of the carotenoid biosynthesis pathway in Blakeslea trispora

A gene of Blakeslea trispora has been cloned by heterologous hybridization with the Mucor circinelloides crgA gene, a repressor of light-inducible carotenogenesis. This gene is the ortholog of the M. circinelloides crgA, since it was able to restore the wild-type phenotype of a null crgA mutant of M. circinelloides. The expression of B. trispora crgA gene is light-induced and photoadapted, as occurs for M. circinelloides crgA. Light induction and photoadaptation of B. trispora crgA was also observed in M. circinelloides, which suggests that the mechanisms involved in light regulation are basically conserved between these filamentous fungi. Conservation of the regulatory pathway that controls carotene biosynthesis was supported by the light-induced and photoadapted expression of all structural carotenogenic genes of B. trispora. Consequently, the beta-carotene content of dark grown mycelia of B. trispora increased upon illumination with white light.

The RING-finger domain of the fungal repressor crgA is essential for accurate light regulation of carotenogenesis

Mucor circinelloides responds to blue light by activating the biosynthesis of carotenoids. Gene crgA acts as a repressor of this light-regulated process, as its inactivation leads to overaccumulation of carotenoids in both the dark and the light. The predicted CrgA protein contains different recognizable structural domains, including a RING-finger zinc-binding motif, several glutamine-rich regions, a putative nuclear localization signal and an isoprenylation domain. To gain insight into the specific mode of action of the CrgA protein, we sought to define the CrgA domains critical for the light regulation of carotenogenesis. For this, mutant crgA alleles harbouring missense or deletion mutations in conserved residues of those domains were generated, and their functionality was assessed by testing their ability to complement a null crgA mutation. Point mutations of the amino-terminal RING-finger domain abrogated the ability of CrgA to repress carotenogenesis in the dark, as did the deletion of a poly glutamine-rich region at the carboxyl domain of CrgA. In contrast, mutations of the isoprenylation domain only slightly affected the CrgA function in carotenogenesis. The results identify two functional domains presumably involved in protein-protein interaction in the CrgA protein and suggest a role for the ubiquitin-proteasome pathway in the light regulation of carotenogenesis in fungi.

Metabolic engineering of the astaxanthin-biosynthetic pathway of

This review describes the different approaches that have been used to manipulate and improve carotenoid production in Xanthophyllomyces dendrorhous. The red yeast X. dendrorhous (formerly known as Phaffia rhodozyma) is one of the microbiological production systems for natural astaxanthin. Astaxanthin is applied in food and feed industry and can be used as a nutraceutical because of its strong antioxidant properties. However, the production levels of astaxanthin in wild-type isolates are rather low. To increase the astaxanthin content in X. dendrorhous, cultivation protocols have been optimized and astaxanthin-hyperproducing mutants have been obtained by screening of classically mutagenized X. dendrorhous strains. The knowledge about the regulation of carotenogenesis in X. dendrorhous is still limited in comparison to that in other carotenogenic fungi. The X. dendrorhous carotenogenic genes have been cloned and a X. dendrorhous transformation system has been developed. These tools allowed the directed genetic modification of the astaxanthin pathway in X. dendrorhous. The crtYB gene, encoding the bifunctional enzyme phytoene synthase/lycopene cyclase, was inactivated by insertion of a vector by single and double cross-over events, indicating that it is possible to generate specific carotenoid-biosynthetic mutants. Additionally, overexpression of crtYB resulted in the accumulation of beta-carotene and echinone, which indicates that the oxygenation reactions are rate-limiting in these recombinant strains. Furthermore, overexpression of the phytoene desaturase-encoding gene (crtI) showed an increase in monocyclic carotenoids such as torulene and HDCO (3-hydroxy-3',4'-didehydro-beta,-psi-carotene-4-one) and a decrease in bicyclic carotenoids such as echinone, beta-carotene and astaxanthin.

Two classes of small antisense RNAs in fungal RNA silencing triggered by non-integrative transgenes

Transformation of Mucor circinelloides with self-replicative plasmids containing a wild-type copy of the carotenogenic gene carB causes silencing of the carB function in 3% of transformants. Genomic analyses revealed a relationship between silenced phenotype and number of copies of plasmids. This phenotype results from a reduction of the steady-state levels of carB mRNA, a reduction that is not due to differences in the level of transcription, indicating that silencing is post-transcriptional. Small sense and antisense RNAs have been found to be associated with gene silencing in M. circinelloides. Two size classes of small antisense RNAs, differentially accumulated during the vegetative growth of silenced transformants, have been detected: a long 25-nucleotide RNA and a short 21-nucleotide RNA. Secondary sense and antisense RNAs corresponding to sequences of the endogenous gene downstream of the initial triggering molecule have also been detected, revealing the existence of spreading of RNA targeting in fungi. These findings, together with the self-replicative nature of the triggering molecules, make M. circinelloides a suitable organism for investigating some unresolved questions in RNA silencing.

Alternative splicing of transcripts from crtI and crtYB genes of Xanthophyllomyces dendrorhous

Xanthophyllomyces dendrorhous is one of the relevant sources of the carotenoid astaxanthin. In this paper, we describe for the first time cloning of unexpected cDNAs obtained from the crtI and crtYB genes of X. dendrorhous strain UCD 67-385. The cDNA of the crtI gene conserves 80 bp of the first intron, while the cDNA of the crtYB gene conserves 55 bp of the first intron and lacks 111 bp of the second exon. The crtI and crtYB RNAs could be spliced in alternative splice sites, which produced alternative transcripts which could not be translated to active CRTI and CRTYB proteins since they had numerous stop codons in their sequences. The ratio of mature mRNA to alternative mRNA for the crtI gene decreased as a function of the age of the culture, while the cellular content of carotenoids increased. It is possible that splicing to mature or alternative transcripts could regulate the cellular concentrations of phytoene desaturase and phytoene synthase-lycopene cyclase proteins, depending on the physiological or environmental conditions.

Cloning, characterization and heterologous expression of the Blakeslea trispora gene encoding orotidine-5'-monophosphate decarboxylase

The pyrG gene of the fungus Blakeslea trispora, encoding orotidine-5'-monophosphate decarboxylase (OMPD) enzyme, was cloned by heterologous hybridization of a genomic library with the Mucor circinelloides pyrG gene. The deduced amino acid sequence of the B. trispora pyrG gene is highly similar to the OMPD from other organisms. Hybridization analyses revealed that the only copy of this gene present in the genome of B. trispora is constitutively expressed. Heterologous complementation of a mutant of M. circinelloides deficient in OMPD activity with the B. trispora pyrG gene and promoter sequence confirmed the function of this gene. This functional complementation demonstrates that heterologous expression in M. circinelloides might be used to investigate the function of genes of B. trispora.

Cloning of glyceraldehyde-3-phosphate dehydrogenase-encoding genes in Mucor circinelloides (Syn. racemosus) and use of the gpd1 promoter for recombinant protein production

Three genes (gpd1, gpd2, and gpd3) encoding glyceraldehyde-3-phosphate dehydrogenase were isolated from the dimorphic zygomycete Mucor circinelloides by PCR using degenerated primers. Transcription of gpd1 could be detected during vegetative growth under both aerobic and anaerobic conditions, whereas neither gpd2 nor gpd3 transcription was detected, indicating that gpd1 is the major transcribed gpd gene. The transcription of gpd1 was regulated by carbon source. The gpd1 promoter was successfully used for recombinant expression of genes of both homologous (crgA encoding a regulator of carotene biosynthesis) and heterologous (gox1 from Aspergillus niger encoding glucose oxidase; GOX) nature. Growth of a gox1 transformant strain resulted in the secretion of enzymatically active GOX. The potential advantages of using a dimorphic fungus for heterologous protein production are discussed.

A bifunctional enzyme with lycopene cyclase and phytoene synthase activities is encoded by the carRP gene of Mucor circinelloides

Using functional analyses in Escherichia coli and Mucor circinelloides, it has been shown that a single M. circinelloides gene (carRP) codes for a protein with two different enzymatic activities, lycopene cyclase and phytoene synthase, which are encoded by independent genes in organisms other than fungi. This gene was identified using complementation tests among different classes of carotenoid mutants of M. circinelloides. The carRP gene product contains two domains: the R domain is located at the N-terminus and determines lycopene cyclase activity; the P domain is located at the C-terminus and displays phytoene synthase activity. The R domain is functional even in the absence of the P domain, while the latter needs the proper R domain conformation to carry out its function. The carRP gene is closely linked to the phytoene dehydrogenase (carB) gene, and the promoter regions of both genes are located within only 446 bp. Northern analyses show a co-ordinated regulation of the expression of both genes by blue light. Several motifs found in this promoter region suggest a bi-directional mode of transcription control.