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Review

Regulation of Secondary Metabolism in the Penicillium Genus

1
Toxalim (Research Centre in Food Toxicology), Université de Toulouse, INRAE, ENVT, INP-Purpan, UPS, 31027 Toulouse, France
2
Institute for Agricultural and Fisheries Research (ILVO), member of Food2Know, Brusselsesteenweg 370, 9090 Melle, Belgium
3
Centre D’analyse et de Recherche, Unité de Recherche Technologies et Valorisations Agro-Alimentaires, Faculté des Sciences, Université Saint-Joseph, P.O. Box 17-5208, Mar Mikhael, Beirut 1104, Lebanon
4
Laboratory of Microbiology, Department of Life and Earth Sciences, Faculty of Sciences I, Lebanese University, Hadath Campus, P.O. Box 5, Beirut 1104, Lebanon
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2020, 21(24), 9462; https://0-doi-org.brum.beds.ac.uk/10.3390/ijms21249462
Submission received: 9 November 2020 / Revised: 3 December 2020 / Accepted: 8 December 2020 / Published: 12 December 2020
(This article belongs to the Special Issue Molecular Biology and Chemistry of Mycotoxins and Phytotoxins)

Abstract

:
Penicillium, one of the most common fungi occurring in a diverse range of habitats, has a worldwide distribution and a large economic impact on human health. Hundreds of the species belonging to this genus cause disastrous decay in food crops and are able to produce a varied range of secondary metabolites, from which we can distinguish harmful mycotoxins. Some Penicillium species are considered to be important producers of patulin and ochratoxin A, two well-known mycotoxins. The production of these mycotoxins and other secondary metabolites is controlled and regulated by different mechanisms. The aim of this review is to highlight the different levels of regulation of secondary metabolites in the Penicillium genus.

1. Introduction

Studies have estimated the existence of at least 2.2–3.8 million fungal species on Earth, from which only around 10% have been isolated and described [1,2]. Penicillium, one of the most common fungi in a various range of habitats, has a worldwide distribution and a large economic impact on human life. This genus is of great importance in numerous and diverse fields, such as food spoilage, biotechnology, plant pathology, and medicine [3,4], and currently contains 483 accepted species [5]. Several of these species, classified as pre- and post-harvest pathogens, can lead to catastrophic decay in food crops, as described by Frisvad and Samson [6], Pitt and Hocking [7], and Samson et al. [8]. Penicillium can also produce a varied range of secondary metabolites, including several harmful mycotoxins [9], antibacterial [10,11,12,13,14] and antifungal compounds [15], immunosuppressants, and cholesterol-lowering agents [16,17,18,19]. The most iconic example of a drug of fungal origin is penicillin, the first antibiotic substance in history [20].
The biosynthesis of several secondary metabolites, such as mycotoxins, depends on several environmental cues including the substrate, pH, temperature, water activity, interrelationships with other microorganisms, and the interactions of these different factors in the natural environment [21,22,23].
Secondary metabolites are products of enzymatic cascades starting when backbone enzymes such as polyketide synthases (PKSs), non-ribosomal peptide synthetases (NRPSs), terpene cyclases (TCs), and dimethylallyl tryptophan synthases (DMATSs) catalyze, respectively, the rearrangement or condensation of simple primary metabolites, such as acetyl-CoA, amino acids, or isoprene units, resulting in more complex secondary metabolites [24]. Different metabolic pathways can lead to their formation (Figure 1). Fungal secondary metabolites are classified into five categories according to their structures and their precursors: polyketides, cyclic terpenes, non-ribosomal peptides, indole alkaloids, and hybrids (Figure 1) [25]. Other enzymes named tailoring enzymes are also needed and interfere in the catalysis of subsequent reactions in the biosynthetic pathways of mycotoxins. The structural diversity of mycotoxins results from the variety of chemical reactions (cyclization, aromatization, glycosylation, hydroxylation, methylation, acetylation, and epoxidation) involved in their biosynthesis [26] and leads to their broad spectrum of biological properties and functions. The combined involvement of backbone enzymes in the same biosynthesis pathway infinitely broadens this structural diversity of secondary metabolites. This diversity is also enriched by the infrequent existence of crosstalk between different biosynthetic pathways [27].
Enzymes are activated at the same time, and the newly synthesized intermediates are consecutively metabolized by the following enzymes. This phenomenon is possible due to the cluster organization of the genes encoding the enzymes involved in the biosynthesis of the metabolites in the same chromosomal region. These genes are often co-activated by a specific transcription factor (TF) located within the clusters [28]. Based on bioinformatics analysis and other studies, it was proven that fungal genomes exhibit different and numerous predicted secondary metabolite clusters. A recent review estimated the number of fungal biosynthetic gene clusters (BGCs) at several million [29]. For the two well-known genera of Aspergillus and Penicillium alone, which contain 446 and 483 species, respectively [5], the number of non-redundant clusters is approximately 25,000. In filamentous fungi, the activation of specific TFs and the resulting production of fungal secondary metabolites is controlled at a higher hierarchical level by global TFs. Understanding the mechanisms underlying mycotoxin biosynthesis contributes to defining/identifying strategies or mechanisms to regulate them and reduce their production [30].
Numerous studies have focused on regulators impacting the formation of secondary metabolites in Aspergillus, Penicillium, and Fusarium, but few reviews have explored the complex and multi-layered regulation of fungal secondary metabolism [31,32,33,34]. While several excellent articles reviewed the different regulatory mechanisms known for Aspergillus [29,35,36,37], this review aims to deepen the understanding of the regulation of secondary metabolism in Penicillium and highlight all the regulatory mechanisms that can occur.

2. Regulation of Secondary Metabolism

For the synthesis of any secondary metabolite, the regulation of its cluster involves a number of factors for activation or repression. This regulation occurs at different levels. Most secondary metabolite clusters have genes encoding TFs that act directly on all other genes located within the cluster. Expression of these internal regulators also depends on other, more global TFs encoded by genes unrelated to the BGCs, which are themselves under the control of different physiological and/or environmental stimuli. An adaptation to a specific environment may also result in the biosynthesis of a certain secondary metabolite. This biosynthesis is connected and regulated by different signaling transduction pathways. Finally, epigenetic regulation, including modification of the chromatin and nucleosome structure, can yield transcriptional control and impact secondary metabolite synthesis extensively [38]. In the following section, the different regulatory systems studied in Penicillium will be discussed.

2.1. Specific Transcription Factors/Cluster-Specific Regulators

Gene clusters involved in secondary metabolite biosynthesis often include a gene encoding a TF that specifically acts and modulates the expression of the other genes in that cluster (e.g., patL, calC, and ctnA in patulin, calbistrin, and citrinin biosynthetic pathways, respectively). This gene has a switching role within the cluster (Figure 2). The TFs regulate gene expression by binding specifically to the promoters of the genes involved.
Several studies comparing TF sequences have shown that these TFs can be classified into different families based on the similarities in their protein sequences. We can distinguish between zinc finger proteins, proteins called helix-turn-helix, and leucine zippers [43]. Nevertheless, almost 90% of the potential gene clusters involved in the synthesis of fungal polyketides belong to the family of zinc finger TFs (Cys2His2, Cys4, or Zn(II)2Cys6) [43,44,45]. Proteins of the Zn(II)2Cys6 family are found exclusively in fungi and yeasts [46], and the C6 type zinc finger DNA binding protein motif (Cys6) is frequently encountered in TFs. Cys6 has been identified on more than 80 proteins found mainly in fungi [43] and is generally considered a transcriptional activator (Table 1). Only in Saccharomyces cerevisiae are the zinc finger proteins (ARGR2, LEU3, and UME6) activators and repressors [47,48,49,50]. Subsequently, the number of proteins belonging to the Zn(II)2Cys6 family has increased significantly due to the number of fungal genomes that have since been sequenced. Numerous examples of Zn(II)2Cys6 TFs identified as being involved in the secondary metabolism of fungi genera other than Penicillium have been largely described in the literature. As examples, we can quote AflR (aflatoxins), Bik5 (bikaverin), and CtnA (citrinin) for Aspergillus, Fusarium, and Monascus, respectively (Table 1).
Gliotoxin, a secondary fungal metabolite belonging to the class of epipolythiodioxopiperazines (ETPs) and characterized by the presence of a sulfur-bridged dioxopiperazine ring [91], is produced by some Aspergillus and Penicillium species, such as Penicillium lilacinoechinulatum [92], a strain of this species was misidentified as Penicillium terlikowskii in a study by Waring et al. [92,93]. Within its cluster, a Zn(II)2Cys6 finger transcription regulator, GliZ, was identified to be responsible for gliotoxin induction and regulation. A mutation of the gliZ (∆gliZ) gene in Aspergillus fumigatus resulted in the loss of gliotoxin production, while overexpression of gliZ increased the production of gliotoxin [94,95]. In P. lilacinoechinulatum, a homologous gene is present in the genome, but the heterologous complementation of the A. fumigatusgliZ mutant with PlgliZ failed to restore gliotoxin production [58]. The mlcR gene encoding a putative 50.2-kDa protein characterized by a Zn(II)2Cys6 DNA-binding domain was shown to be involved in the regulation and biosynthesis of ML-236B (compactin) in Penicillium citrinum [96].
Another gene encoding PatL, a specific TF in Penicillium expansum, was shown to affect patulin production [85]. The protein encoded by this gene has two conserved domains, one of which encodes a Cys6 DNA binding site and the other of which was found in the TFs of the superfamily of zinc finger TFs. Orthologous genes of patL involved in the patulin metabolic pathway were found in other filamentous fungi genomes, such as Penicillium griseofulvum, Penicillium paneum, Penicillium vulpinum, Penicillium carneum, Penicillium antarcticum [97], and Aspergillus clavatus [98]. Sometimes, BGCs such as the sorbicillin gene cluster can contain two genes encoding TFs. In this example, SorR1, a Zn(II)2Cys6 factor, acts as an activator for the expression of all genes located within the cluster. The second zinc finger TF (SorR2) controls the expression of the sorR1 gene [86]. Few cases of TFs belonging to the basic leucine zipper (bZIP) family have been reported to act as specific TFs of secondary metabolite pathways. These TFs include ZEB2, SimL, and OtaR1. The latter TF is present in the OTA cluster in Aspergillus ochraceus, Aspergillus westerdijkiae, Aspergillus carbonarius, and Penicillium nordicum. Its inactivation in A. ochraceus leads to the complete inhibition of OTA production [63]. SimL regulates the production of the well-known immunosuppressant drug cyclosporine [62]. The transcripts of genes located within the zearalenone gene cluster were not detected when the zeb2 gene encoding bZIP was deleted [61,99]. TqaK, another gene encoding a bZIP protein, was reported to be located inside the tryptoquialanine gene cluster in Penicillium aethiopicum. The deletion of tqaK led to tryptoquialanine production equal to only one-twentieth that of the parental strain [87]. An orthologous gene is also present in the genome of Penicillium digitatum, another tryptoquialanine-producing species. Thus far, OtaR1 and TqaK are the only bZIP proteins identified to be directly involved in secondary metabolite biosynthesis in Penicillium.

2.2. Environmental Signals and Associated Regulators

In the previous section, we reviewed specific TFs described in Penicillium that are cluster-specific. However, numerous regulatory elements affected by environmental cues modulate the expression of fungal secondary metabolite clusters and do not reside within the cluster itself. They are considered to be global regulators (Figure 3). Among them, CreA, AreA, Nmc, PacC, Skn7, Yap1, VeA, LaeA, BrlA, PcRFX1, PcFKH1, Pcz1, and NsdD have been mentioned and are discussed in the following.
In the fungal kingdom, the synthesis of secondary metabolites is often a response to environmental or ecological changes and is dependent on the developmental stage of the producing species. The activation of a biosynthetic pathway is influenced by the composition of the substrate on which the fungus grows—in particular, the carbon source and the nitrogen source. Glucose and other assimilable sugars can suppress secondary metabolite pathways mediated by CreA, a protein displaying two Cys2His2 zinc finger domains. For example, the biosynthesis of penicillin in Penicillium chrysogenum was shown to be largely regulated by glucose, sucrose and, to a lesser extent, by other sugars (maltose, fructose, and galactose). Cepeda-García et al. [100] showed clear evidence of the involvement of the CreA factor in the catabolic repression of penicillin biosynthesis and the expression of the pcbAB gene, encoding the first enzyme of the penicillin pathway in P. chrysogenum. The authors applied an RNAi strategy attenuating creA gene expression. Transformants expressing small interfering RNAs for creA showed greater production of penicillin. By contrast, a recent study showed that the deletion of creA in P. expansum strains leads to the absence of patulin production in apples [101], although expression of the pat genes is increased. Regarding the nitrogen source, a similar regulatory mechanism called nitrogen metabolite repression exists in Ascomycetes. For instance, a concentration of ammonium above 40 mM caused a repression in the expression of uidA, a promoterless gene for β-glucuronidase in Escherichia coli, when fused to the promoters of pcbAB (acvA) and pcbC, two genes encoding the two first enzymes of the penicillin pathway in P. chrysogenum [102]. In P. griseofulvum (formerly P. urticae), the production of patulin was also affected when ammonium ions were added to the culture medium [103]. On the other hand, the presence of 30 mM ammonium chloride results in a significant decrease in isoepoxydon dehydrogenase (idh) and 6-methylsalicylic synthase (6-msas) transcripts, key genes in the pathways of patulin biosynthesis [104,105]. This nitrogen metabolite repression is mediated by AreA, a Cys2Cys2-type zinc finger TF [31]. This regulatory factor binds to the intergenic region of acvA-pcbC [106] in response to nitrogen and mediates the regulation of penicillin biosynthesis in P. chrysogenum [107]. The idh (patN) and 6-msas (patK) genes interact with the NrfA protein, an orthologue of the AreA protein in P. griseofulvum, through several putative GATA sites located on their promoter. The nmc gene, encoding the AreA orthologous factor, has been characterized in Penicillium roqueforti. This protein, which displays at least 94% identity with that of homologous fungal proteins (AreA in Aspergillus) [108], is induced and upregulated by nitrogen starvation, but no data regarding its impact on P. roqueforti secondary metabolites have already been published.
Another well-known environmental stimulus that induces or represses the secondary metabolism in filamentous fungi is the pH of the substrate. This regulation is mediated by PacC, the key factor of pH fungal regulation [109]. This TF displays three putative Cys2His2 zinc fingers [110]. In the genus Aspergillus, a neutral to alkaline extra-cellular pH is required for the activation of PacC via two proteolytic steps [111]. These steps are mediated by the pal (palA, palB, palC, palF, and palI) pathway [109]. The final mature form of this protein activates the expression of genes expressed under alkaline conditions and, by contrast, represses the transcription of genes expressed under acidic conditions. Many examples of PacC’s involvement in the regulation of biosynthetic pathways in Aspergillus or Fusarium species have been reported in the literature [65,112,113]. Suárez and Peñalva [114] showed that Penicillium pacC transcript levels were higher under alkaline than acidic growth conditions and elevated in later stages of growth. The level of the pcb transcripts followed the same trend, leading to increased production of penicillin under alkaline pH. Barad et al. [115] also studied the link between ammonia accumulation, the activation of pacC, and the synthesis of patulin in P. expansum. The authors concluded that an accumulation of ammonia during nutritional limitation in P. expansum could lead to a modification of the ambient environmental pH, a signal for the activation of pacC, as well as other alkaline induced genes leading to an accumulation of secondary metabolites, such as patulin.
Barad et al. [116] analyzed the role of PacC in the regulation of D-gluconic acid (GLA) production and patulin accumulation in P. expansum. On the one hand, their results showed that GLA production plays a role in the activation of patulin production. On the other hand, this study, based on the characterization of pacC-RNAi mutants of P. expansum, concluded that PacC plays a key role in the regulation of GLA accumulation via the transcriptional regulation of gox2, the most important gene involved in GLA production in P. expansum. This regulation of GLA production through PacC largely affects patulin accumulation in the mutants. A recent publication reported that the production of patulin is completely inhibited in the null mutant Pe∆pacC strain when grown at pH > 6.0 [117]. In P. digitatum, PacC was reported to regulate the expression of genes encoding polygalacturonase PG2 and pectin lyase PNL1, enzymes both involved in the degradation of the citrus cell wall [118].
Osmotic and oxidative stress are considered to be other environmental cues to which filamentous fungi should respond in order to survive. Most of the relevant knowledge comes from the yeast S. cerevisiae and the fungal genus Aspergillus. Skn7, a TF involved in the osmotic and oxidative stress responses in S. cerevisiae [119], has also been identified in Talaromyces (formerly Penicillium) marneffei. The gene skn7 from the latter was used to complement a skn7-disrupted strain of S. cerevisiae and seemed to be involved in the oxidative stress response in the yeast [120]. This result indicates the highly conserved nature of skn7 between the two organisms. Montibus et al. [121] suggested that skn7 could be involved in the regulation of fungal secondary metabolism. A recent study seemed to confirm this hypothesis since the deletion of Afskn7 resulted in a drastic decrease in aflatoxin B1 production in Aspergillus flavus [122]. Yap1, another TF, coordinates the interplay between oxidative stress and secondary metabolism. In Aspergillus parasiticus, the deletion mutant ∆yap1 exhibited an increase in aflatoxin production [123]. The same team later reported that the suppression of the yap1 orthologous gene led to increased OTA accumulation in Aspergillus ochraceus [124]. In T. marneffei, the mutant ∆yapA, a yap1 orthologous gene, was found to be sensitive to oxidative chemicals such as H2O2 or menadione and featured growth, germination, and conidiation delays [125]. For the genus Penicillium, the only works on orthologues Skn7 and Yap1 are mentioned above; their roles in the secondary metabolism of T. marneffei have not yet been investigated.
The development of filamentous fungi and their ability to produce secondary metabolites is largely influenced by light, as well. A velvet complex has been described in Aspergillus nidulans, and the VeA (velvet A) factor has been widely studied, as well as many proteins that seem to interact with it, such as VelB (velvet-like B), VosA (viability of spores A), VelC (velvet-like C), and the non-velvet protein LaeA (loss of aflR expression A), a methyltransferase involved in chromatin remodeling [126]. Depending on the fungal species, VeA is involved in different physiological processes, such as development, asexual and sexual reproduction, secondary metabolism, and virulence. The regulation mediated by this factor depends particularly on light. VeA was first characterized in A. nidulans, whose gene encodes a protein of 573 amino acids with a conserved domain at the N-terminus [127] and a nuclear localization sequence (NLS) [128]. At its C-terminus, a PEST domain (rich in proline (P), glutamic acid (E), serine (S), and threonine (T)) is present [129]. This PEST domain is also found in VeA orthologous proteins in A. parasiticus, A. fumigatus, and Neurospora crassa [130].
Stinnett et al. [128] studied the intracellular localization of VeA. This study demonstrated that this localization is dependent on light. In the dark, VeA is mainly located in the nucleus, whereas in the presence of light, VeA is mainly found in the cytoplasm. In the veA1 mutant [131], VeA is mostly found in the cytoplasm independently of light. In this mutant, the presence of a mutation on the transcription initiation codon led to a truncated protein where the first 36 amino acids were missing and, therefore, did not have a functional NLS, thus explaining the cytoplasmic localization of VeA. In the same study, it was demonstrated that the transfer of VeA into the nucleus depends on the importin α KapA and that a functional NLS is essential to allow the interaction of these two proteins.
To identify the proteins interacting with VeA, Bayram et al. [127] used the Tandem Affinity Purification (TAP) technique from a strain of A. nidulans expressing a VeA protein coupled to a TAP-tag at the C-terminus. In the dark, the proteins VelB, LaeA, and importin α KapA interact with VeA. Conversely, only VelB interacts with VeA in the presence of light. Using the yeast two-hybrid technique, these analyses confirmed the interactions of VeA–VelB and VeA–LaeA; however, no interaction was demonstrated between LaeA and VelB, suggesting that VeA acts as a bridge between these two proteins. In addition, fluorescence assays showed that the VeA–LaeA interaction occurs in the nucleus, while VeA and VelB interact in the nucleus and the cytoplasm. LaeA is located in the nucleus, and its interaction with VeA is nuclear. VelB must, therefore, be able to enter the nucleus despite the absence of NLS in its sequence. Bayram et al. [127] demonstrated that VeA helps VelB to enter the nucleus to form the velvet complex.
The results obtained in the various studies allowed Bayram et al. [127] to propose a mechanism (Figure 4) that coordinates the regulation of sexual development and the production of secondary metabolites in A. nidulans. In the dark, the VelB/VeA/LaeA complex controls and induces the epigenetic activity of LaeA, which consequently controls the expression of the genes of the clusters responsible for the synthesis of the secondary metabolites. In the presence of light, this interaction decreases because VeA is retained in the cytoplasm, and LaeA has low activity.
Despite its strong conservation among different fungal species, VeA has different roles, reflecting the diversity of fungal development patterns. Therefore, veA has a role in the regulation of secondary metabolism. The expression of genes involved in the synthesis of secondary metabolites is affected by VeA [132,133,134,135]. Kato et al. [132] demonstrated that in A. nidulans, VeA regulates the expression of genes involved in sterigmatocystin synthesis. Indeed, VeA is necessary for the expression of aflR, which encodes the TF specific to the biosynthetic pathway of this mycotoxin [136]. Similarly, the veA gene is required for the transcription of aflR and aflJ, another gene coding for a TF, also located within the aflatoxin/sterigmatocystin cluster in A. flavus [137,138]. Other studies revealed that VeA is needed for the synthesis of other secondary metabolites, such as cyclopiazonic acid and aflatrem in A. flavus [133], penicillin in A. nidulans [132], or trichothecenes in Fusarium graminearum [139]. In this last study, FgVe1 was shown to be a positive regulator of the virulence of F. graminearum. In Fusarium verticillioides, FvVe1 is necessary not only for the production of fumonisins but also for the infection of corn plants by the fungus [140]. In P. chrysogenum, veA controls penicillin biosynthesis [141]. Recently, it was shown that the disruption of veA in P. expansum quasi-totally altered patulin and citrinin production when the fungus was grown on the usual mycological media (Malt Extract Agar and Potato Dextrose Agar). This decrease in production is explained by a drastic decrease in the expression of patulin and citrinin genes [142]. This finding was confirmed in vivo, as no patulin was detected when the null mutant was developed in apples. In the same study, an analysis of the impact of VeA on the expression of all secondary metabolism backbone genes in P. expansum was performed from the genome of the d1 strain, including PKS, NRPS, terpene synthase, and DMATS genes. The expression analysis showed a positive or negative regulation of 15/35 backbone genes and supports the hypothesis that P. expansum’s secondary metabolism is modulated by the transcriptional regulator factor VeA. In a recent study, Li et al. [143] assessed the involvement of the proteins VeA, VelB, VelC, and VosA, belonging to the velvet family, in the regulation of patulin biosynthesis in P. expansum. The absence of VeA and VelB blocked the production of the mycotoxin, whereas the absence of VelC caused a drastic decrease in patulin production. In contrast, deletion of the vosA gene had no effect on the capacity of the fungus to synthesize patulin. These findings suggest the lack of involvement of VosA in the biosynthesis of patulin in P. expansum in contrast to the other three proteins (VeA, VelB, and VelC) of the velvet complex.
Baba et al. [144] also showed through gene deletion that veA plays critical roles in the production of the hypocholesterolemic lovastatin analogue compactin (ML-236B) in P. citrinum by controlling the expression of mlcR, the pathway-specific activator gene for compactin biosynthesis.
It was also shown that different components of the velvet complex may play opposite roles in the regulation of secondary metabolism. In P. chrysogenum, PcVelC, together with the velvet PcVeA (orthologue of VeA in P. chrysogenum) and the methyltransferase PcLaeA, induced penicillin production, and, in contrast, PcVelB acted as a repressor [141,145].
Under the conditions tested by Kosalkova et al. [146], LaeA controlled some secondary metabolism gene clusters in P. chrysogenum. Its overexpression resulted in a four-fold increase in pcbC and penDE expression, leading to a 25% increase in gene expression in penicillin biosynthesis, while its suppression significantly reduced the expression of these genes. In contrast, the absence of an expression level difference (∆laeA vs. wild type (WT)) for the rpt gene involved in the second step of the roquefortine biosynthetic pathway suggests that PclaeA does not regulate the biosynthesis of roquefortine C. The regulation of the secondary metabolism of P. expansum by laeA was investigated from two cultures on different media [147]. Of the 54 backbone genes examined, many appeared to be positively regulated by laeA, such as those involved in the biosynthesis of roquefortine C, an unknown ETP-like metabolite, and patulin. In Penicillium oxalicum, it has been shown that the putative methyltransferase LaeA controls, among other things, the expression of some secondary metabolic gene clusters [148]. However, the cluster predicted to be involved in roquefortine C/ meleagrin/oxaline biosynthesis was not affected by the suppression of the laeA gene in P. oxalicum. The difference observed between these studies regarding laeA regulation of the genes involved in the biosynthesis of roquefortine C could be due to the species used and the medium tested.
Zhu et al. [149] demonstrated the role of laeA in secondary metabolism regulation, conidial production, and stress responses in P. digitatum. The deletion of PdlaeA resulted in decreased expression of various secondary metabolite gene clusters, including the Tq cluster involved in tryptoquialanine biosynthesis. Deletion of this gene also affected the expression of several regulators of conidiation, including BrlA. A comparison between the WT and the null mutant Pd∆laeA strains revealed increased sensitivity of the null mutant strain under alkaline conditions. The loss of PdlaeA had no significant effect on the virulence of the null mutant strain. This work showed the involvement of laeA in the biosynthesis of several secondary metabolites, as well as the development and the adaptation of P. digitatum to its environment.
Yu et al. [150] showed that the overexpression of LaeA in the Penicillium dipodomyis marine-derived strain YJ-11 leads not only to morphological but also metabolic changes. Overexpression mutants displayed the ability to produce several sorbicillinoids, two of which are new compounds, as well as four known sorbicillin analogues. These results indicate that LaeA plays a key role in the activation of cryptic genes that are silent under normal laeA expression.
Kumar et al. [151] showed the effects of the intrinsic factors of apples in modulating patulin accumulation and on laeA and pat gene expression in apples colonized by P. expansum. The authors used two apple varieties, Golden Delicious and Granny Smith, which have similar total soluble solid value profiles at the time of ripening but different pH values and malic acid concentrations. These factors differentially affected the expression of LaeA along with the expression of the patulin cluster genes and, therefore, patulin accumulation. To understand the complexity of these interactions, in vitro studies were performed. These studies proved that sucrose and malic acid concentrations and pH are all involved, in association with chlorogenic acid and epicatechin, in a complex interaction system that modulates the regulation and production of patulin.
Penicillium brocae HDN-12-143 is a fungus isolated from marine sediments that has strong potential for the biosynthesis of secondary metabolites. Wang et al. [152] studied the effect of overexpression of the laeA gene on the secondary metabolism of P. brocae. This overexpression revealed that four compounds could be isolated, including fumigatin chlorohydrin and a new polyketide compound, iso-fumigatin chlorohydrin. In summary, the results indicate that LaeA can suppress or activate the expression of gene clusters and that its overexpression can induce the production of new secondary metabolites.
In Aspergillus, VeA is responsible for the activation or repression of general genes such as brlA [134,153]. BrlA is a C2H2-type zinc finger TF which is part of the central regulatory pathway (CRP) controlling the expression of genes specific to asexual reproduction. The conformation of brlA is complicated and comprises two overlapping transcription units, brlAα and brlAβ [154]. Expression of the brlA gene was studied in P. oxalicum strains, initially identified as Penicillium decumbens, by Qin et al. [155], and the expression levels of 7/28 gene clusters of secondary metabolism were regulated in a ∆brlA deletion strain. The cluster involved in the roquefortine C/meleagrin/oxaline biosynthetic pathway was downregulated. In a P. chrysogenum brlA-deficient mutant, the production of penicillin V was not affected, whereas a reduction of almost 99% was determined via HPLC analysis accompanied by a drastic downregulation of the expression of penicillin biosynthetic genes in a stuA-deficient strain [156]. Moreover, the deletion of laeA reduced the conidiation in P. oxalicum, and the expression of brlA was downregulated [148]. A recent study in P. expansum showed that the brlA gene not only affects the stage of conidiation of the fungus but also affects the biosynthesis of secondary metabolites. Zetina-Serrano et al. [157] showed that the suppression of brlA results in a strain devoid of conidia and that the production of communesins and derivatives was drastically decreased, whereas the production of chaetoglobosins and derivatives increased. Neither patulin nor citrinin production was affected by the suppression of brlA.
PcRFX1 is a TF that was characterized in P. chrysogenum by Domínguez-Santos et al. [158]. PcRFX1 is the orthologue of the regulatory proteins CPCR1 and RFxA in Acremonium chrysogenum and T. marneffei, respectively. Knockdown and overexpression techniques of the Pcrfx1 gene have proven that PcRFX1 regulates pcbAB, pcbC, and penDE transcription and thereby controls penicillin biosynthesis. PcRFX1 was also suggested to be involved in the control of the pathways of primary metabolism.
PcFKH1, another TF of the winged-helix family, also positively regulates penicillin biosynthesis in P. chrysogenum by binding to the pcbC promoter, interacting with the promoter region of the penDE gene and controlling other genes such as phlA and ppt encoding phenylacetyl CoA ligase and phosphopantetheinyl transferase [159].
The pcz1 gene (Penicillium C6 zinc domain protein 1), encoding a Zn(II)2Cys6 protein and controlling the growth and development processes of the fungus, has also been described in P. roqueforti. It was suggested to participate in the physiological processes in this fungus and plays a key role in regulating its secondary metabolism [160,161]. The silencing of pcz1 in P. roqueforti resulted in the downregulation of the brlA, abaA, and wetA genes of the CRP [160]. In pcz1 downregulated strains, the production of the metabolites roquefortine C, andrastin A, and mycophenolic acid was severely reduced; however, when pcz1 was overexpressed, only mycophenolic acid was overproduced, and levels of roquefortine C and andrastin A were decreased [161].
Finally, the PoxnsdD gene of P. oxalicum was characterized by He et al. [162]. This gene is an orthologue of the nsdD gene (initially isolated in A. nidulans) encoding a GATA-type zinc finger TF that was proven to be involved in the production of secondary metabolites. In the PoxΔnsdD strain, the 230 differentially expressed genes identified covered 69 putative BGCs. Among them, 11 were predicted to produce aspyridone, emericellin, citrinin, leucinostatins, roquefortine C/meleagrin, beauvericin, cytochalasin, malbrancheamide, and viridicatumtoxin.

2.3. Signal Transduction Pathways

In general, fungi present a very dynamic and structured cell wall. During the cell cycle, organisms need to adapt quickly to changes under environmental conditions and imposed stresses and thus regulate the composition and structural organization of their cell wall [163,164,165]. All these factors influence the biosynthesis of secondary metabolites in the fungus. Numerous signaling pathways activate and regulate the growth and differentiation of filamentous fungi and initiate secondary metabolite biosynthesis under specific conditions. These signaling pathways sense and transduce signals external to TFs that, in turn, activate the expression of genes that could be involved in the biosynthesis of certain secondary metabolites. The cyclic adenosine monophosphate (cAMP)/protein kinase A (PKA), calcineurin/calmodulin, TOR, and mitogen-activated protein kinase are the most studied pathways [34]. The production of many secondary metabolites has been associated with one of these transduction signals and specific active molecules. Among the different signaling pathways listed, we focus on those that affect only the secondary metabolism of Penicillium, starting with the cAMP pathway.

2.3.1. cAMP Pathways

Heterotrimeric G proteins are considered to be important components of these signal transduction pathways. They can integrate a variety of signals and then transduce them to downstream signaling cascades. Most filamentous fungi have three Gα proteins belonging to classes I, II, or III [166]. Gα subunits belonging to class I are involved in many aspects related not only to the development of the fungus or its pathogenicity but also its secondary metabolism, which is not the case for Gα subunits of classes II and III. The deletion of genes encoding class II Gα proteins showed negligible effects on fungal metabolism [167,168], while those of class III are involved in fungal development and pathogenicity [169,170,171]. Alterations have been observed in the secondary metabolism of different fungi, including P. chrysogenum [172] and T. marneffei [173]. The pga1 gene, encoding subunits of subgroup I Gα protein in P. chrysogenum, has been shown to affect the production of three secondary metabolites: penicillin, chrysogenin, and roquefortine C. The deletion of pga1 induces a decrease in the production of roquefortine C and penicillin by regulating the expression of pcbAB, pcbC, and penDE, the three structural biosynthetic genes of the penicillin cluster. Chrysogenin biosynthesis is enhanced, and roquefortine and penicillin biosynthesis is upregulated by the presence of a dominant activating pga1 (G42R) allele or a constitutively active Pga1 [172]. Based on a proteomic analysis, Carrasco-Navarro et al. [174] suggested that Pga1 signaling affects penicillin biosynthesis by acting on the primary metabolism pathways that are also involved in cysteine, ATP, and NADPH biosynthesis. They also propose a model for the Pga1-mediated signal transduction pathway.

2.3.2. The Osmostress Response Pathway

Usually, inhibition of the HOG (high osmolarity glycerol) signaling pathway negatively affects the production of metabolites; in other words, challenging osmotic conditions activate the cascade of the HOG MAP kinase signal, thereby activating several osmo-regulated genes or downstream TFs by phosphorylation. In their study, Stoll et al. [175] showed that NaCl induced production of OTA in correlation with the phosphorylation status of the HOG MAP kinase in P. nordicum and Penicillium verrucosum. The activation of HOG phosphorylation and the concomitant OTA biosynthesis suggest a link between the two processes and that this regulation may be mediated by the HOG MAP kinase signal transduction pathway. This was confirmed by inactivating the hog gene in P. verrucosum, making the fungus unable to produce OTA under high NaCl conditions. The biosynthesis of citrinin, another P. verrucosum toxin, was not affected. This could be explained by the subsequent work of Schmidt-Heydt et al. [176], which showed the impact of high oxidative stress conditions on citrinin biosynthesis. Indeed, by increasing Cu2+ concentrations in a growth medium, P. verrucosum shifts the biosynthesis of its secondary metabolism from OTA to citrinin. Increasing amounts of external cAMP reduce citrinin biosynthesis depending on the concentration chosen and suggest that citrinin biosynthesis is regulated by a cAMP/PKA signaling pathway.

2.4. Epigenetic Regulation

As previously discussed, Penicillium species, including other fungi, produce a set of bioactive secondary metabolites that are not essential to their survival. Genes for biosynthesis and the regulation of secondary metabolites in fungi are not evenly distributed over the genomes and tend to be sub-telomerically located [177]. The manipulation of global epigenetic regulators has contributed to the study of many unknown secondary metabolites, and many histone modifications have been associated with the regulation of secondary metabolism gene clusters [178,179]. The epigenetic phenomena that can occur are reversible, and many changes in the gene expression levels of the fungus do not alter the DNA sequence and can occur throughout the fungus life cycle. Fungal epigenetic regulation involves mainly histone modifications, such as methylation, acetylation, and sumoylation. Histone proteins are the primary protein components of chromatin and, through their modifications, regulation can be limited to a specific region of the chromosome and, therefore, affect some genes. This supports the advantage of grouping secondary metabolism genes into clusters. The first involvement of the epigenetic regulation of secondary metabolites described in the literature was that of the A. nidulans histone deacetylase coded by hdaA, an orthologue of the histone deacetylase hdaA1 gene of S. cerevisiae. Deletion of this gene caused the activation of two secondary metabolite gene clusters. In the same paper, treatment of the P. expansum culture with trichostatin A, a histone deacetylase (HDAC) inhibitor, resulted in the overproduction of several non-determined metabolites [179].
In P. chrysogenum, hdaA appears to be a key regulator of the secondary metabolism of the fungus. Deletion of hdaA induced a significant effect on the expression of numerous PKS and NRPS-encoding genes. A downregulation of the NRPS encoded gene associated with the BGC of chrysogine was also observed. This observation was confirmed by Ding et al. [180]. In parallel, transcriptional activation of the BGC of sorbicillinoids occurs, which is associated with the detection of a new compound produced only under these conditions. These results obtained by Guzman-Chavez et al. [181] suggest the existence of crosstalk between BGCs. In a recent study, the disruption of hdaA led to an upregulation of the meleagrin/roquefortine C biosynthesis gene cluster, accompanied by higher meleagrin production [180].
Akiyama et al. [182] investigated the involvement of clr3 in Penicillium brasilianum physiology. Clr3 is a homologue of the class 2 histone deacetylase hda1 in S. cerevisiae. On the one hand, the deletion of clr3 resulted in decreased fungal growth under oxidative stress conditions. In addition, various secondary metabolites, such as austin-related meroterpenoids, brasiliamides, cyclodepsipeptides, and mycotoxins, including verruculogen and penicillic acid, were downregulated in the null mutant ∆clr3 strain. On the other hand, epigenetic modulation was studied using suberoylanilide hydroxamic acid (SAHA), a histone deacetylase inhibitor, and nicotinamide. These treatments also resulted in reduced secondary metabolite biosynthesis. Together, these findings suggest that clr3 plays a key role in the regulation of secondary metabolism in P. brasilianum.
By growing Penicillium variabile on a maltose medium in the presence of 5-azacytidine (a DNA methyltransferase inhibitor), varitatin A synthesis was induced [183]. In addition, by growing it on a potato-based medium in the presence of SAHA, seven polyketides were induced, including three known wortmannilactones (E, F, and H), as well as new varilactones (A-B) and wortmannilactones (M-N) [184]. In cultures treated with 50 μM of 5-azacytidine, Penicillium citreonigrum formed exudates, which are droplets rich in primary and secondary metabolites, inorganic substances, and proteins/enzymes and are known as guttates. These exudates were very rich in different compounds compared to the control. Indeed, 5-azacytidine induced the formation of six azaphilones (fungal metabolites with diverse biological activities), pencolide, and two new meroterpenes [185]. The addition of 5-azacytidine to the culture medium of Penicillium funiculosum also altered the metabolic profiles of this fungus [186]. Two new prenyleudesmane diterpenoids were extracted from the culture and exhibited cytotoxic and antibacterial activities. Eupenicillium sp. LG41, an endophytic fungus, was exposed to an epigenetic modulation using nicotinamide, a NAD+-dependent HDAC inhibitor [187]. This led to the production of many compounds: eupenicinicols C and D, along with eujavanicol A and eupenicinicol A. El-Hawary et al. [188] showed that cultures of a marine-derived strain of Penicillium brevicompactum exposed to nicotinamide and sodium butyrate result in the production of phenolic metabolites. In the presence of nicotinamide, many compounds, including p-anisic acid, benzyl anisate, syringic acid, and sinapic acid, were isolated and identified. Sodium butyrate also enhanced the production of anthranilic acid and ergosterol peroxide.
In one of the many studies to explore compounds with innovative structures and biological activities from endophytes of ancestral Chinese medicine, Guo et al. [189] used chemical epigenetic manipulation to evaluate the secondary metabolism of the Penicillium herquei strain, recovered from the fruiting body of Cordyceps sinensis. This latter has been used for thousands of years by the Chinese to boost longevity, endurance, and vitality. The DNA methyltransferase inhibitor, 5-aza-2-deoxycytidine, affected the production of secondary metabolites, purifying three previously unpublished polyketides with a pyran-2-one scaffold.
Ying et al. [190] showed that cultures of Penicillium sp. HS-11, isolated from the medicinal plant Huperzia serrata, produced two compounds in the presence of SAHA: 4-epipenicillone B and (R)-(+)-chrysogine, which are both absent under normal laboratory conditions.
The addition of 500 μM of suberoyl bis-hydroxamic acid, a Zn(II)-type or NAD+-dependent HDAC inhibitor, and 100 μM of nicotinamide (an NAD+-dependent HDAC inhibitor) to a culture of Penicillium sp. isolated from leaves of Catharanthus roseus improved the production of citreoviripyrone A and citreomontanin. In addition, nicotinamide enhanced the production of (−)-citreoviridin [191]. Xiong et al. [192] explored the role of the high-mobility group box protein, PoxHmbB, involved in chromatin organization and identified in P. oxalicum. The authors observed that conidiation and hyphae growth were delayed in a mutant PoxΔhmbB strain. PoxhmbB regulated the expression of genes encoding plant biomass-degrading enzymes and other genes involved in conidiation. Although the suppression of the orthologous gene resulted in an absence of sterigmatocystin production in A. nidulans [193], the involvement of this protein in the secondary metabolism of Penicillium has not yet been investigated.
Tannous et al. [194] evaluated the involvement of the epigenetic reader SntB in the pathogenicity and secondary metabolism of P. expansum. Firstly, the results showed that the deletion of sntB caused numerous phenotypic changes in the plant pathogen. In the absence of sntB, P. expansum showed delayed vegetative growth, reduced conidiation, an accelerated germination rate, and decreased virulence in apples. Secondly, the data showed that sntB played a key role in regulating secondary metabolism, especially patulin and citrinin biosynthesis. In addition, the role of sntB in the positive regulation of three TFs of secondary metabolism and virulence (LaeA, CreA, and PacC) was demonstrated. Finally, this study revealed the downregulation of sntB in response to environmental factors such as low temperature and high CO2 levels, conditions to which apples are subjected during storage. These findings suggest a possible method for integrating these epigenetic control strategies to fight post-harvest fruit rot.
Finally, the chromatin regulation of small molecule gene clusters allowed the specific control of secondary metabolism gene clusters and permitted filamentous fungi to modify chemical diversity and successfully exploit environmental resources. Epigenetic regulation is considered a promising strategy for investigating unknown secondary metabolite clusters, particularly because under certain laboratory culture conditions, many clusters can remain silent, making it difficult to elucidate their functions and regulatory mechanisms [195].

3. Conclusions

Fungal secondary metabolism is very broad, and this review focused on metabolism regulated in the Penicillium genus. Given the diversity of secondary metabolites, their key roles as virulence and pathogenicity factors, and their great medical and agricultural interest, further research should be conducted on these metabolites. This review highlighted how the production of these secondary metabolites is controlled and regulated. It discussed the different levels of regulation of secondary metabolites, including specific regulators, global TFs, transduction signaling pathways, and epigenetic regulation, as well as the combination of many different parameters affecting the biosynthesis pathways of metabolites. Many TFs that affect the expression of genes involved in secondary metabolism seem to belong to the category of zinc-binding proteins. LaeA and the velvet complex proteins are considered to be global regulators and are able to control many clusters at the same time. Although much is known about these global TFs and their regulatory proteins, more research is needed to explore the details that link them to the transcription of genes involved in secondary metabolite biosynthetic pathways. This would help us to better understand the molecular mechanisms underlying this complex regulatory network. The analysis of a large number of works related to secondary metabolism regulation in filamentous fungi revealed great complexity. This complexity is suggested by the observation of inter-species differences in the impact of a given TF gene deletion on the same biosynthetic pathway.
The study of the regulation of secondary metabolite biosynthesis in Penicillium is much less advanced than that in Aspergillus, and some orthologous genes already studied in Aspergillus (including rtfA, cpsA, rmtA, mtfA) should be investigated in Penicillium sp.

Author Contributions

Writing—original draft preparation, C.E.H.A., C.Z.-S., N.T., S.L., and O.P.; writing—review and editing, A.E.K., A.A., I.P.O., S.L., and O.P. All authors have read and agreed to the published version of the manuscript.

Funding

C.H.A. was supported by a doctoral fellowship funded by the Belgian Research Institute for Agriculture, Fisheries and Food and la Région Occitanie (France) under Grant 15050427. C.Z.-S. was supported by a doctoral fellowship funded by the Consejo Nacional de Ciencia y Tecnología (CONACYT) México, grant number CVU CONACYT 623107. N.T. was supported by a doctoral fellowship funded by The National Council for Scientific Research of Lebanon (CNRS-L). This research was funded by CASDAR AAP RT 2015, grant number 1508, by French National Research Agency, grant numbers ANR-15-CE21-0010-01 NEWMYCO and ANR-17-CE21-0008 PATRISK, and by International Cooperation Program CAPES/COFECUB (project number Sv 947/19).

Acknowledgments

We thank Selma P. Snini of the University of Toulouse (Toulouse, France) for Figure 4.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Abbreviations

BGCBiosynthetic gene cluster
bZIPBasic leucine zipper
CRPCentral regulatory pathway
DMATSDimethylallyl tryptophan synthase
ETPEpipolythiodioxopiperazine
HDACHistone deacetylase
HOGHigh osmolarity glycerol
NLSNuclear localization sequence
NRPSNon-ribosomal peptide synthetase
OTAOchratoxin A
PKSPolyketide synthase
SAHASuberoylanilide hydroxamic acid
TAPTandem Affinity Purification
TCTerpene cyclase
TFTranscription factor
WTWild Type

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Figure 1. Biosynthetic pathways of secondary metabolites. In grey boxes, the typical backbone of secondary metabolites. In grey, the main mycotoxins produced by these pathways. In red, the enzymes associated with each pathway. In blue, separate PKS and NRPS are involved in ochratoxin A (OTA) biosynthesis; NRPS: non-ribosomal peptide synthetase, PKS: polyketide synthase, TC: terpene cyclase, DMATS: dimethylallyl tryptophan synthase. In bold, mycotoxins produced by Penicillium species.
Figure 1. Biosynthetic pathways of secondary metabolites. In grey boxes, the typical backbone of secondary metabolites. In grey, the main mycotoxins produced by these pathways. In red, the enzymes associated with each pathway. In blue, separate PKS and NRPS are involved in ochratoxin A (OTA) biosynthesis; NRPS: non-ribosomal peptide synthetase, PKS: polyketide synthase, TC: terpene cyclase, DMATS: dimethylallyl tryptophan synthase. In bold, mycotoxins produced by Penicillium species.
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Figure 2. Gene clusters of the patulin biosynthesis pathway (the first one at the top) (15 genes, 40 kb) [39] and the citrinin biosynthesis pathway (the middle group) (nine genes, 22 kb) [40,41] in Penicillium expansum; cluster of the calbistrin biosynthesis pathway (the third one at the bottom) (13 genes, 35kb) in Penicillium decumbens [42].
Figure 2. Gene clusters of the patulin biosynthesis pathway (the first one at the top) (15 genes, 40 kb) [39] and the citrinin biosynthesis pathway (the middle group) (nine genes, 22 kb) [40,41] in Penicillium expansum; cluster of the calbistrin biosynthesis pathway (the third one at the bottom) (13 genes, 35kb) in Penicillium decumbens [42].
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Figure 3. Global regulatory proteins involved in the regulation of gene clusters involved in the production of various secondary metabolites in Penicillium (1) citrinin, (2) patulin, (3) penicillin G, (4) roquefortine C, and (5) PR-toxin, adapted from Brakhage [45].
Figure 3. Global regulatory proteins involved in the regulation of gene clusters involved in the production of various secondary metabolites in Penicillium (1) citrinin, (2) patulin, (3) penicillin G, (4) roquefortine C, and (5) PR-toxin, adapted from Brakhage [45].
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Figure 4. Operating model of the velvet complex in Aspergillus nidulans adapted from Bayram et al. [127]. In the presence of light, VeA is retained in the cytoplasm (-----), and LaeA has low activity. In the dark, VeA coupled to VelB is transported in the nucleus by the importin α KapA (——), and the velvet complex is formed with LaeA to activate the production of secondary metabolites and sexual development.
Figure 4. Operating model of the velvet complex in Aspergillus nidulans adapted from Bayram et al. [127]. In the presence of light, VeA is retained in the cytoplasm (-----), and LaeA has low activity. In the dark, VeA coupled to VelB is transported in the nucleus by the importin α KapA (——), and the velvet complex is formed with LaeA to activate the production of secondary metabolites and sexual development.
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Table 1. Examples of identified Zn(II)2Cys6 and leucine zipper transcription factor (TF) involvement in secondary metabolism in fungi; adapted and updated from Yin and Keller [46].
Table 1. Examples of identified Zn(II)2Cys6 and leucine zipper transcription factor (TF) involvement in secondary metabolism in fungi; adapted and updated from Yin and Keller [46].
TFBiosynthetic Gene ClusterTF FamilySpeciesReferences
AflR Aflatoxin/Sterigmatocystin Zn(II)2Cys6Aspergillus flavus
Aspergillus nidulans
Aspergillus parasiticus
[51,52,53,54,55]
AsaRAspergillic AcidZn(II)2Cys6Aspergillus flavus[56]
GliZ Gliotoxin Zn(II)2Cys6 Aspergillus fumigatus Penicillium lilacinoechinulatum [57,58]
XanCXanthocillinBasic Leucine zipperAspergillus fumigatus[59]
FapRFumagillin/PseurotinZn(II)2Cys6Aspergillus fumigatus[60]
ZEB2 Zearalenone Basic Leucine zipperFusarium graminearum[61]
SimL Cyclosporine Basic Leucine ZipperTolypocladium inflatum[62]
OtaR1 Ochratoxin A Basic Leucine zipper Aspergillus carbonarius Aspergillus ochraceus Aspergillus westerdijkiae Penicillium nordicum[63]
SirZ Sirodesmin PL Zn(II)2Cys6 Leptosphaeria maculans [58]
MlcR Compactin Zn(II)2Cys6 Penicillium citrinum [64]
Bik5 Bikaverin Zn(II)2Cys6 Fusarium fujikuroi [65]
DEP6 Depudecin Zn(II)2Cys6 Alternaria brassicicola [66]
ZFR1
FUM21
Fumonisin Zn(II)2Cys6 Fusarium verticillioides [67,68]
CTB8 Cercosporin Zn(II)2Cys6 Cercospora nicotianae [69]
GIP2 Aurofusarin Zn(II)2Cys6 Gibberella zeae [70]
CtnA Citrinin Zn(II)2Cys6Monascus purpureus
Monascus ruber
Penicillium expansum
[40,41,71]
LovE Lovastatin Zn(II)2Cys6 Aspergillus terreus [72,73]
ApdR Aspyridone Zn(II)2Cys6 Aspergillus nidulans [74]
CtnR Asperfuranone Zn(II)2Cys6 Aspergillus nidulans [75]
MdpE Monodictyphenone/
Emodin Analogs
Zn(II)2Cys6 Aspergillus nidulans [76]
Cmr1p Melanin Zn(II)2Cys6 Colletotrichum lagenarium [77]
Pig1p Melanin Zn(II)2Cys6 Magnaporthe grisea [77]
GsfR1 Griseofulvin Zn(II)2Cys6 Penicillium griseofulvum [78]
MokH Monacolin K Zn(II)2Cys6 Monascus pilosus [79]
CalC Calbistrin Zn(II)2Cys6 Penicillium decumbens [42]
CnsN Communesins Zn(II)2Cys6 Penicillium expansum [80]
Orf2 Varicidin A and B Zn(II)2Cys6 Penicillium variabile [81]
Orf10 PR-Toxin Zn(II)2Cys6Penicillium chrysogenum
Penicillium roqueforti
[82,83]
MacR Macrophorin Zn(II)2Cys6 Penicillium terrestris [84]
PatL Patulin Zn(II)2Cys6 Penicillium expansum [85]
SorR1
SorR2
Sorbicillin Zn(II)2Cys6 Penicillium chrysogenum [86]
TqaK Tryptoquialanines Basic leucine zipper Penicillium aethiopicum Penicillium digitatum [87,88]
Sol4 Solanapyrone Zn(II)2Cys6Ascochyta rabiei[89]
RolP Leucinostatin Zn(II)2Cys6Paecilomyces lilacinus[90]
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El Hajj Assaf, C.; Zetina-Serrano, C.; Tahtah, N.; Khoury, A.E.; Atoui, A.; Oswald, I.P.; Puel, O.; Lorber, S. Regulation of Secondary Metabolism in the Penicillium Genus. Int. J. Mol. Sci. 2020, 21, 9462. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms21249462

AMA Style

El Hajj Assaf C, Zetina-Serrano C, Tahtah N, Khoury AE, Atoui A, Oswald IP, Puel O, Lorber S. Regulation of Secondary Metabolism in the Penicillium Genus. International Journal of Molecular Sciences. 2020; 21(24):9462. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms21249462

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El Hajj Assaf, Christelle, Chrystian Zetina-Serrano, Nadia Tahtah, André El Khoury, Ali Atoui, Isabelle P. Oswald, Olivier Puel, and Sophie Lorber. 2020. "Regulation of Secondary Metabolism in the Penicillium Genus" International Journal of Molecular Sciences 21, no. 24: 9462. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms21249462

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