Search Results (123)

A novel actinobacterial strain, designated E54^T, was isolated from a hyper-arid desert soil sample collected from the Kumtagh Desert in Dunhuang, Gansu Province, China. Phylogenetic analysis based on 16S rRNA gene sequences placed strain E54^T within the genus Lentzea, showing highest similarity to Lentzea waywayandensis DSM 44232^T (98.9%) and Lentzea flava NBRC 15743^T (98.5%). However, whole-genome comparisons revealed that the average nucleotide identity (ANI) and digital DNA–DNA hybridization (dDDH) values between E54^T and these related strains were below the thresholds for species delineation. Strain E54^T exhibited typical morphological characteristics of the genus Lentzea, forming a branched substrate. It grew optimally at 28–30 °C, pH 7.0–9.0, and tolerated up to 10% NaCl. The cell wall contained meso-diaminopimelic acid, the predominant menaquinone was MK-9(H₄), and major fatty acids included iso-C_16:0. The polar lipid profile comprised diphosphatidyl glycerol, phosphatidyl ethanolamine, phosphatidyl inositol, hydroxyphosphatidyl ethanolamine, and an unidentified lipid. The characteristic amino acid type of the cell wall was meso-DAP. Whole-cell hydrolysis experiments revealed the characteristic cell wall sugar fractions: ribose and galactose. The genome of strain E54^T is approximately 8.0 Mb with a DNA G+C content of 69.38 mol%. Genome mining revealed 39 biosynthetic gene clusters (BGCs), including non-ribosomal peptide synthetases (NRPS), polyketide synthases (PKS), terpenes, and siderophores. Comparative antiSMASH-based genome analysis across 38 Lentzea strains further demonstrated the genus’ remarkable biosynthetic diversity. NRPS and type I PKS (T1PKS) were the most prevalent BGC types, indicating a capacity to synthesize structurally complex and pharmacologically relevant metabolites. Together, these findings underscore the untapped biosynthetic potential of the genus Lentzea and support the proposal of strain E54^T as a novel species. The strain E54^T (=JCM 34936^T = GDMCC 4.216^T) should represent a novel species, for which the name Lentzea xerophila sp. nov. is proposed. Full article

Trichoderma spp. produce diverse secondary metabolites with biological activity. This study explored the antimicrobial, antibiofilm, antioxidant, and cytotoxic properties of metabolites from two native Trichoderma strains, 10BR1 and UEPA AR12, isolated from rhizospheric soils. Organic extracts from both strains demonstrated broad-spectrum antimicrobial activity, inhibiting Gram-positive and Gram-negative bacteria, as well as various Candida species, with notable efficacy against Staphylococcus aureus (MICs: 15.6–31.25 µg/mL). The extracts also showed antibiofilm activity, with UEPA AR12 exhibiting the highest inhibition against Escherichia coli (81.8%), Enterococcus faecalis (92.8%), Candida albicans (87.9%), and Candida parapsilosis (89.3%). Antioxidant activity, assessed via DPPH assay, revealed a dose-dependent radical scavenging effect (12.88% to 39.67% at 7.8–1000 µg/mL). Cytotoxicity assays indicated that UEPA AR12 extracts were more cytotoxic (IC₅₀: 202.5–234.3 µg/mL) than 10BR1 (IC₅₀: 368.7–602.1 µg/mL) in non-tumor cells, with similar trends in tumor cells (Huh7). HPLC/MS analysis identified 21 metabolites in the extracts. Genomic analyses, supported by rpb2 gene and phylogenetic clustering, confirmed that both strains were T. afroharzianum. FUNGISMASH revealed multiple biosynthetic gene clusters, predominantly Type I polyketide synthase (T1PKS). Additionally, targeted genomic analyses did not detect mycotoxin-related genes. These findings highlight the antimicrobial, antibiofilm, and antioxidant potentials of these strains, positioning them as sources of bioactive metabolites for pharmaceutical applications. Full article

This study investigated Morchella importuna strain degeneration during repeated subculturing and employed metabolomics, transcriptomics, and other techniques to explore its molecular mechanisms. Significant metabolic and transcriptional differences were observed between normal mycelia (NM) and degenerated mycelia (DG). Metabolomic analysis revealed 699 differentially expressed metabolites (DEMs) that were predominantly enriched in secondary metabolite biosynthesis pathways, particularly flavonoids and indole alkaloids. Total flavonoid content was markedly higher in NM than in DG, with most flavonoid compounds showing reduced levels in degenerated strains. Transcriptomic profiling revealed 2691 differentially expressed genes (DEGs), primarily associated with metabolic pathways and genetic information processing. Integrated analysis showed that metabolic dynamics were regulated by DEGs, with pyruvate metabolism being significantly enriched. The FunBGCeX tool identified biosynthetic gene clusters (BGCs) in the M. importuna genome, highlighting the critical role of the non-reducing polyketide synthase (NR-PKS) gene in flavonoid biosynthesis. This gene exhibited significantly downregulated expression in DG strains. These findings indicate that M. importuna degeneration resulted from systemic dysregulation of gene expression networks and metabolic pathway reorganization. The results presented herein also provide theoretical insights into degeneration mechanisms and potential prevention strategies for this edible fungus. Full article

The long-term coexistence of sea cucumber-associated microorganisms with their host enables them to jointly withstand the unique marine ecological environment, and possess great potential for producing various natural products. However, under conventional laboratory conditions, most biosynthetic gene clusters (BGCs) in these microorganisms remain silent, necessitating the establishment of effective activation strategies for exploring bioactive secondary metabolites (SMs). Histone acetylation status regulates chromatin structure and plays a crucial role in cellular physiology and fungal secondary metabolism. Penicillium sclerotiorum SD-36 was isolated from sea cucumbers in our previous study. Genome sequencing results indicate that this strain harbors as many as 52 BGCs, suggesting it holds a wealth of genetic resources essential for synthesizing diverse SMs. Here, we describe the impact of a class 1 histone deacetylase (HDAC), PsHos2, on secondary metabolism of sea cucumber-associated Penicillium sclerotiorum SD-36. The colony morphology and SM profile of ΔPsHos2 exhibited significant changes, with the emergence of multiple new compound peaks. Six compounds, including five azaphilones, which are characterized by a pyranoquinone core structure, were isolated from ΔPsHos2, and seventeen unreported potential azaphilone-related nodes were obtained using molecular networking based on LC-MS/MS. Transcriptome analysis revealed that PsHos2 influenced the expression of 44 BGC core genes. Specifically, seven genes within cluster 86.1, the putative BGC for azaphilones, were upregulated, including two polyketide synthase (PKS) genes. The results indicate that regulation based on class 1 HDACs is an important strategy for enhancing SM synthesis in sea cucumber-associated fungi and expanding the resources of marine natural products. Full article

Phlebopus portentosus is an edible and medicinal ectomycorrhizal mushroom with delicious and high nutritional value. However, the mechanism of secondary metabolite biosynthesis in P. portentosus is still unclear. In this study, the genomics, metabolomics, and transcriptomics were integrated to reveal the biosynthesis mechanism of secondary metabolites in P. portentosus under different cultivation conditions. The 31.4 Mb genome of P. portentosus YAF023 with 15 scaffolds was assembled by Illumina and Nanopore sequencing and annotated, and 206 cytochrome P450s, 201 carbohydrate-active enzymes, 186 transcription factors, 18 terpene synthases (TPSs), and 5 polyketide synthases (PKSs) were identified. Multi-omics analysis showed that PpPKS1 is probably involved in the biosynthesis of Ethyl orsellinate; PpPKS2 and PpPKS5 are probably involved in the synthesis of 6-Methylsalicylic acid and Cytochalasin Z5, respectively; PpTRI5 was involved in the tetracyclic sesquiterpene β-type trichodiene compounds; and PpSTCs was involved in the synthesis of β-copaene analogs or derivatives. Co-expression network analysis and binding site prediction of the promoter regions suggested that PpHOX4 and PpHSF1 regulated the gene expression of PpPKS1, and Ppzf-C2H2 32 and PpHSF5 regulated the gene expression of PpSTCs 8, and PpSTCs 3, respectively. This study will provide an important foundation for further development and utilization of secondary metabolites of P. portentosus. Full article

Cystic fibrosis (CF) patients experience higher risks of colorectal cancer but the pathogenesis is unclear. In the general population, polyketide synthase-positive (pks⁺) E. coli is implicated in intestinal carcinogenesis via the production of colibactin; however, the relevance in CF is unknown. In this study, we investigate pks⁺E. coli prevalence in CF and potential associations between pks⁺E. coli, gastrointestinal inflammation, and microbiome dynamics with fecal calprotectin and 16SrRNA gene taxonomic data. Cross-sectional analysis demonstrated no difference in pks⁺E. coli carriage between CF patients and healthy controls, 21/55 (38%) vs. 26/55 (47%), p = 0.32. Pks⁺E. coli was not associated with significant differences in mean (SD) calprotectin concentration (124 (154) vs. 158 (268) mg/kg; p = 0.60), microbial richness (159 (76.5) vs. 147 (70.4); p = 0.50) or Shannon diversity index (2.78 (0.77) vs. 2.65 (0.74); p = 0.50) in CF. Additionally, there was no association with exocrine pancreatic status (p = 0.2) or overall antibiotic use (p = 0.6). Longitudinally, CF subjects demonstrated intra-individual variation in pks⁺E. coli presence but no significant difference in overall prevalence. Future investigation into the effects of repeat exposure on risk profile and analysis of older CF cohorts is necessary to identify if associations with colorectal cancer exist. Full article

Monacolin K (MK), a secondary metabolite produced by Monascus spp. with the ability to inhibit cholesterol production, is structurally identical to lovastatin produced by Aspergillus terreus. In the lovastatin biosynthetic pathway, the polyketide synthase (PKS) encoded by lovB must work together with the enoyl reductase encoded by lovC to ensure lovastatin production. However, it is unclear whether mokA and mokE in the MK gene cluster of Monascus spp., both of which are highly homologous to lovB and lovC, respectively, also have the same functions for MK biosynthesis. In the current study, the high-yielding MK M. pilosus MS-1 was used as the research object, and it was found that the enoyl reductase domain of MokA may be non-functional due to the lack of amino acids at active sites, a function that may be compensated for by MokE in the MK synthesis pathway. Then, the mokE-deleted (ΔmokE), -complemented (ΔmokE::mokE), and -overexpressed (PgpdA-mokE) strains were constructed, and the results showed that ΔmokE did not produce MK, and ΔmokE::mokE restored MK synthesis, while the ability of PgpdA-mokE to produce MK was increased by 32.1% compared with the original strain MS-1. These results suggest that the MokA synthesized by Monascus spp. must be assisted by MokE to produce MK, just as lovastatin produced by A. terreus, which provides clues for further genetic engineering to improve the yield of MK in Monascus spp. Full article

Nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) play crucial roles in the development and pathogenicity of the entomopathogenic fungus Beauveria bassiana. However, they are among the few biosynthetic gene clusters with unknown functions in B. bassiana. To investigate the role of the hybrid PKS–NRPS synthetase gene BBA_09856 in B. bassiana, we constructed a mutant strain, ∆BBA09856-WT, by deleting the BBA_09856 gene through Agrobacterium-mediated transformation. We then analyzed the biological characteristics of the mutant strain and the virulence of the mutant strain toward Ostrinia furnacalis larvae, as well as its antagonistic effects against the phytopathogen Botrytis cinerea. We found that the average growth rate of the three mutant strains, ∆BBA09856-WT, was significantly higher compared to the wild-type (WT) strain on the 15th day of culture on potato dextrose agar (PDA) plates (7.01 cm vs. 6.30 cm, p < 0.01). Additionally, the average spore production(3.16 × 10⁷/cm² vs. 9.95 × 10⁶/cm², p < 0.001) and germination rate (82.50% vs. 54.72%, 12 h, p < 0.001) were significantly different between the three mutant strains, ∆BBA09856-WT, and the WT strain. The average survival rates of O. furnacalis infected with the WT strain and the three mutant strains, ∆BBA09856-WT, after 8 days were 61.66%, and 30.00%, respectively, indicating that the pathogenicity of the tested mutant strains was significantly greater than that of the WT strain. The results of the dual culture test indicated that the inhibitory rates of the WT and ∆BBA09856-WT strains against B. cinerea were 40.25% and 47.65%, respectively (p < 0.001). Similarly, in the dual culture test, the WT strain reduced the growth of B. cinerea by 9.90%, while the ∆BBA09856-WT exhibited a significantly greater inhibition rate of 28.29% (p < 0.05). The diameters of disease spots, measured 6 d after inoculation with B. cinerea in the tomato treatment groups, revealed significant differences in endophytic colonization between the WT and ∆BBA09856-WT strains in the WT+Bc and ∆BBA09856-WT+Bc treatment groups (15.26 mm vs. 12.16 mm, p < 0.01). Notably, ∆BBA09856-WT exhibited enhanced virulence toward O. furnacalis larvae and increased antagonistic activity against B. cinerea. Our results indicate that the gene BBA_09856 may have a negative correlation with the development and virulence of B. bassiana toward the insect pest O. furnacalis larvae, as well as its antagonism against B. cinerea. These findings suggest that molecular techniques, such as gene editing, could be employed to develop superior strains of B. bassiana for the biological control of plant diseases and insect pests. Full article

This study presents the first comprehensive genomic analysis of Cryptoporus qinlingensis, a classical folk medicine and newly identified macrofungus from the Qinling Mountains. Utilizing advanced sequencing technologies, including PacBio HiFi and Hi-C, we achieved a high-quality chromosome-level genome assembly. The genome, sized at 39.1 Mb, exhibits a heterozygosity of 0.21% and contains 21.2% repetitive sequences. Phylogenetic analysis revealed a recent divergence of C. qinlingensis from Dichomitus squalens approximately 212.26 million years ago (MYA), highlighting the rapid diversification within the Polyporaceae family. Comparative genomic studies indicate significant gene family contraction in C. qinlingensis, suggesting evolutionary adaptations. The identification of a tetrapolar mating system, along with the analysis of CAZymes and P450 genes, underscores the genomic complexity and ecological adaptability of this species. Furthermore, the discovery of 30 biosynthetic gene clusters (BGCs) related to secondary metabolites, including polyketide synthase (PKS), non-ribosomal peptide synthetase (NRPS), and terpene synthesis enzymes, opens new avenues for exploring bioactive compounds with potential medicinal applications. This research not only enriches our understanding of the Cryptoporus genus but also provides a valuable foundation for future studies aiming to harness the therapeutic potential of C. qinlingensis and to further explore its ecological and evolutionary significance. Full article

Lactobacillus is a key genus of probiotics commonly utilized for the treatment of oral infections The primary aim of our research was to investigate the probiotic potential of the newly isolated Levilactobacillus brevis DPL5 strain from human breast milk, focusing on its ability to combat biofilm-forming pathogens such as Staphylococcus aureus. Employing in vitro approaches, we demonstrate L. brevis DPL5′s ability to endure at pH 3 with survival rates above 30%, and withstand the osmotic stress often found during industrial processes like fermentation and freeze drying, retaining over 90% viability. The lyophilized cell-free supernatant of L. brevis DPL5 had a significant antagonistic effect against biofilm-producing nasal strains of Staphylococcus aureus, and it completely eradicated biofilms at subinhibitory concentrations of 20 mg·mL⁻¹. Higher concentrations of 69 mg·mL⁻¹ were found to have a 99% bactericidal effect, based on the conducted probability analysis, indicating the production of bactericidal bioactive extracellular compounds capable of disrupting the biofilm formation of pathogens like S. aureus. Furthermore, genome-wide sequencing and analysis of L. brevis DPL5 with cutting-edge Nanopore technology has uncovered over 50 genes linked to probiotic activity, supporting its ability to adapt and thrive in the harsh gut environment. The genome also contains multiple biosynthetic gene clusters such as lanthipeptide class IV, Type III polyketide synthase (T3PKS), and ribosomally synthesized, and post-translationally modified peptides (RiPP-like compounds), all of which are associated with antibacterial properties. Our study paves the way for the further exploration of DPL5, setting the stage for innovative, nature-inspired solutions to combat stubborn bacterial infections. Full article

Irpex lacteus is an edible and medicinal macrofungus with significant biological activity and broad pharmaceutical prospects that has received increasing attention in recent years. Although it is an important resource for macrofungi, knowledge of it remains limited. In this study, we sequenced, de novo assembled, and annotated the whole genome of I. lacteus using a PacBio Sequel II sequencer. The assembled 41.83 Mb genome contains 13,135 predicted protein-coding genes, 83.44% of which have searchable sequence similarity to other genes available in public databases. Using genome-based bioinformatics analysis, we identified 556 enzymes involved in carbohydrate metabolism and 103 cytochrome P450 proteins. Genome annotation revealed genes for key enzymes responsible for the biosynthesis of secondary metabolites, such as terpenoids and polyketides. Among them, we identified 14 terpene synthases, 8 NRPS-like enzymes, and 4 polyketide synthases (PKS), as well as 2 clusters of biosynthetic genes presumably related to terpene synthesis in I. lacteus. Gene family analysis revealed that the MYB transcription factor gene family plays an important role in the growth and development of I. lacteus. This study further enriches the genomic content of I. lacteus, provides genomic information for further research on the molecular mechanism of I. lacteus, and promotes the development of I. lacteus in the fields of drug research and functional food production. Full article

Irumamycin (Iru) is a complex polyketide with pronounced antifungal activity produced by a type I polyketide (PKS) synthase. Iru features a unique hemiketal ring and an epoxide group, making its biosynthesis and the structural diversity of related compounds particularly intriguing. In this study, we performed a detailed analysis of the iru biosynthetic gene cluster (BGC) to uncover the mechanisms underlying Iru formation. We examined the iru PKS, including the domain architecture of individual modules and the overall spatial structure of the PKS, and uncovered discrepancies in substrate specificity and iterative chain elongation. Two potential pathways for the formation of the hemiketal ring, involving either an olefin shift or electrocyclization, were proposed and assessed using ¹⁸O-labeling experiments and reaction activation energy calculations. Based on our findings, the hemiketal ring is likely formed by PKS-assisted double bond migration and TE domain-mediated cyclization. Furthermore, putative tailoring enzymes mediating epoxide formation specific to Iru were identified. The revealed Iru biosynthetic machinery provides insight into the complex enzymatic processes involved in Iru production, including macrocycle sculpting and decoration. These mechanistic details open new avenues for a targeted architecture of novel macrolide analogs through synthetic biology and biosynthetic engineering. Full article

Fungal secondary metabolites (SMs) have broad applications in biomedicine, biocontrol, and the food industry. In this study, whole-genome sequencing and annotation of Taiwanofungus gaoligongensis were conducted, followed by comparative genomic analysis with 11 other species of Polyporales to examine genomic variations and secondary metabolite biosynthesis pathways. Additionally, transcriptome data were used to analyze the differential expression of polyketide synthase (PKS), terpene synthase (TPS) genes, and transcription factors (TFs) under different culture conditions. The results show that T. gaoligongensis differs from other fungal species in genome size (34.58 Mb) and GC content (50.72%). The antibiotics and Secondary Metabolites Analysis Shell (AntiSMASH) analysis reveals significant variation in the number of SM biosynthetic gene clusters (SMBGCs) across the 12 species (12–29), with T. gaoligongensis containing 25 SMBGCs: 4 PKS, 6 non-ribosomal peptide synthetase (NRPS), and 15 TPS clusters. The TgPKS1 gene is hypothesized to be involved in the biosynthesis of orsellinic acid or its derivatives, while TgPKS2 might catalyze the synthesis of 6-methylsalicylic acid (6MSA) and its derivatives. The TgTRI5 genes are suggested to synthesize tetracyclic sesquiterpene type B trichothecene compounds, while TgPentS may be involved in the synthesis of δ-cadinol, β-copaene, and α-murolene analogs or derivatives. Comparative genomic analysis shows that the genome size of T. gaoligongensis is similar to that of T. camphoratus, with comparable SMs. Both species share four types of PKS domains and five distinct types of TPS. Additionally, T. gaoligongensis exhibits a high degree of similarity to Laetiporus sulphureus, despite belonging to a different genus within the same family. Transcriptome analysis reveals significant variation in the expression levels of PKS and TPS genes across different cultivation conditions. The TgPKS1 and TgPKS4 genes, along with nine TgTFs, are significantly upregulated under three solid culture conditions. In contrast, under three different liquid culture conditions, the TgPKS3, TgTRI5-1, and TgTRI5-2 genes, along with twelve TgTFs, exhibit higher activity. Co-expression network analysis and TgTFs binding site prediction in the promoter regions of TgPKS and TgTPS genes suggest that TgMYB9 and TgFTD4 regulate TgPKS4 expression. TgHOX1, TgHSF2, TgHSF3, and TgZnF4 likely modulate TgPKS3 transcriptional activity. TgTRI5-1 and TgTRI5-5 expression is likely regulated by TgbZIP2 and TgZnF15, respectively. This study provides new insights into the regulatory mechanisms of SMs in T. gaoligongensis and offers potential strategies for enhancing the biosynthesis of target compounds through artificial intervention. Full article

Bibenzyl compounds are one of the most important bioactive components of natural medicine. However, Dendrobium officinale as a traditional herbal medicine is rich in bibenzyl compounds and performs functions such as acting as an antioxidant, inhibiting cancer cell growth, and assisting in neuro-protection. The biosynthesis of bibenzyl products is regulated by bibenzyl synthase (BBS). In this study, we have cloned the cDNA gene of the bibenzyl synthase (DoBS1) from D. officinale using PCR with degenerate primers, and we have identified a novel type III polyketide synthase (PKS) gene by phylogenetic analyses. In a series of perfect experiments, DoBS1 was expressed in Escherichia coli, purified and some catalytic properties of the recombinant protein were investigated. The molecular weight of the recombinant protein was verified to be approximately 42.7 kDa. An enzyme activity analysis indicated that the recombinant DoBS1-HisTag protein was capable of using 4-coumaryol-CoA and 3 malonyl-CoA as substrates for dihydroresveratrol (DHR) in vitro. The Vmax and Km of the recombinant protein for DHR were 3.57 ± 0.23 nmol·min⁻¹·mg⁻¹ and 0.30 ± 0.08 mmol, respectively. The present study provides further insights into the catalytic mechanism of the active site in the biosynthetic pathway for the catalytic production of dihydroresveratrol by bibenzylase in D. officinale. The results can be used to optimize a novel biosynthetic pathway for the industrial synthesis of DHR. Full article

The formation of atroposelective biaryl compounds in plants and fungi is well understood; however, polyketide aglycone synthesis and dimerization in bacteria remain unclear. Thus, the biosynthetic gene cluster (BGC) responsible for antibacterial setomimycin production from Streptomyces nojiriensis JCM3382 was examined in comparison with the BGCs of spectomycin, julichromes, lincolnenins, and huanglongmycin. The setomimycin BGC includes post-polyketide synthase (PKS) assembly/cycling enzymes StmD (C-9 ketoreductase), StmE (aromatase), and StmF (thioesterase) as key components. The heterodimeric TcmI-like cyclases StmH and StmK are proposed to aid in forming the setomimycin monomer. In addition, StmI (P-450) is predicted to catalyze the biaryl coupling of two monomeric setomimycin units, with StmM (ferredoxin) specific to the setomimycin BGC. The roles of StmL and StmN, part of the nuclear transport factor 2 (NTF-2)-like protein family and unique to setomimycin BGCs, could particularly interest biochemists and combinatorial biologists. α-Glucosidase, a key enzyme in type 2 diabetes, hydrolyzes carbohydrates into glucose, thereby elevating blood glucose levels. This study aimed to assess the α-glucosidase inhibitory activity of EtOAc extracts of JCM 3382 and setomimycin. The JCM 3382 EtOAc extract and setomimycin exhibited greater potency than the standard inhibitor, acarbose, with IC₅₀ values of 285.14 ± 2.04 μg/mL and 231.26 ± 0.41 μM, respectively. Molecular docking demonstrated two hydrogen bonds with maltase-glucoamylase chain A residues Thr205 and Lys480 (binding energy = −6.8 kcal·mol⁻¹), two π–π interactions with Trp406 and Phe450, and one π–cation interaction with Asp542. Residue-energy analysis highlighted Trp406 and Phe450 as key in setomimycin’s binding to maltase-glucoamylase. These findings suggest that setomimycin is a promising candidate for further enzymological research and potential antidiabetic therapy. Full article