Fruiting body-associated Pseudomonas contact triggers ROS-mediated perylenequinone biosynthesis in Shiraia mycelium culture

Yan Jun Ma; Xin Ping Li; Jia Hui Li; Li Ping Zheng; Jian Wen Wang

doi:10.1186/s40643-025-00946-w

Bioresources and Bioprocessing ›› 2025, Vol. 12 ›› Issue (1) DOI: 10.1186/s40643-025-00946-w

Research

research-article

Fruiting body-associated Pseudomonas contact triggers ROS-mediated perylenequinone biosynthesis in Shiraia mycelium culture

Author information +

History +

PDF

Abstract

Perylenequinones (PQs) from Shiraia fruiting bodies serve as potent photosensitizers for anticancer and antimicrobial photodynamic therapy (PDT). Although these fruiting bodies harbor diverse endophytic bacteria, their interactions with the host fungus remain poorly understood. In this study, we used an in vitro confrontation bioassay to investigate the interaction between Shiraia sp. S9 and dominant Pseudomonas isolates, analyzing fungal transcriptional responses and PQ biosynthesis. Comparative assessment of co-cultures with freely suspended live P. fulva SB1 versus dialysis membrane-separated bacteria revealed that direct physical contact is essential for eliciting fungal PQ production, particularly extracellular secretion of hypocrellin A (HA), HC, and elsinochrome A-C. Bacterial elicitation with P. fulva SB1 at 400 cells/mL stimulated both intracellular PQ biosynthesis and extracellular secretion, resulting in a total PQ yield of 362.2 mg/L, a 2.4-fold increase over axenic cultures. RNA-seq analysis after 24 h of co-culture identified 646 differentially expressed genes (DEGs), with 445 upregulated and 201 downregulated, showing significant enrichment in oxidative stress defense, carbohydrate metabolism, and membrane transport functions. Bacterial contact induced reactive oxygen species (ROS) generation, specifically O₂^·− and H₂O₂, which mediated increased membrane permeability and enhanced HA production. This was achieved through upregulation of key genes involved in central carbon metabolism, polyketide synthase (PKS) for PQ biosynthesis, and major facilitator superfamily (MFS) transporter for PQ exudation. Our work provides the first evidence that the contact-dependent ROS signaling by endophytes within fruiting bodies regulates fungal secondary metabolism, offering novel insights into bacterial-fungal interactions and establishing an effective co-culture strategy for enhanced production of bioactive PQs.

Keywords

Shiraia / Pseudomonas / Fruiting body / Physical contact / Reactive oxygen species / Perylenequinones

Cite this article

Download citation ▾

Yan Jun Ma, Xin Ping Li, Jia Hui Li, Li Ping Zheng, Jian Wen Wang. Fruiting body-associated Pseudomonas contact triggers ROS-mediated perylenequinone biosynthesis in Shiraia mycelium culture. Bioresources and Bioprocessing, 2025, 12(1): DOI:10.1186/s40643-025-00946-w

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	AguirreJ, HansbergW, NavarroR. Fungal responses to reactive oxygen species. Med Mycol, 2006, 44(sup1): 101-107.

[2]	AltschulSF, GishW, MillerW, MyersEW, LipmanDJ. Basic local alignment search tool. J Mol Biol, 1990, 215(3): 403-410.

[3]	AyudhyaSPN, RiffianiR, OzakiY, OndaY, NakanoS, AimiT, ShimomuraN. Isolation of bacteria from fruiting bodies of Rhizopogon Roseolus and their effect on mycelial growth of host mushroom. Mushroom Sci Biotechnol, 2019, 27(4): 134-139.

[4]	BaoZY, XieYC, XuCL, ZhangZB, ZhuD. Biotechnological production and potential applications of hypocrellins. Appl Microbiol Biotechnol, 2023, 107(21): 6421-6438.

[5]	BarbieriE, GuidiC, BertauxJ, Frey-KlettP, GarbayeJ, CeccaroliP, SaltarelliR, ZambonelliA, StocchiV. Occurrence and diversity of bacterial communities in Tuber magnatum during truffle maturation. Environ Microbiol, 2007, 9(9): 2234-2246.

[6]	BelozerskayaTA, GesslerNN, IsakovaEP, DeryabinaYI. Neurospora crassa light signal transduction is affected by ROS. J Signal Transduct, 2012, 20121791963.

[7]	BraatN, KosterMC, WöstenHAB. Beneficial interactions between bacteria and edible mushrooms. Fungal Biol Rev, 2022, 39: 60-72.

[8]	ChenSC, QiuCW, HuangT, ZhouWW, QiYC, GaoYQ, ShenJW, QiuLY. Effect of 1-aminocyclopropane-1-carboxylic acid deaminase producing bacteria on the hyphal growth and primordium initiation of Agaricus bisporus. Fungal Ecol, 2013, 6(1): 110-118.

[9]	DaiDQ, PhookamsakR, WijayawardeneNN, LiWJ, Jayarama BhatD, XuJC, TaylorJE, HydeKD, ChukeatiroteE. Bambusicolous fungi. Fungal Divers, 2017, 82(1): 1-105.

[10]	DengHX, ChenJJ, GaoRJ, LiaoXR, CaiYJ. Adaptive responses to oxidative stress in the filamentous fungal Shiraia bambusicola. Molecules, 2013, 2191118.

[11]	DengHX, GaoRJ, LiaoXR, CaiYJ. Characterization of a major facilitator superfamily transporter in Shiraia bambusicola. Res Microbiol, 2017, 168(7): 664-672.

[12]	EbellLF. Variation in total soluble sugars of conifer tissues with method of analysis. Phytochemistry, 1969, 8(1): 227-233.

[13]	EsteyEP, BrownK, DiwuZ, LiuJX, William LownJ, MillerGG, MooreRB, TulipJ, McPheeMS. Hypocrellins as photosensitizers for photodynamic therapy: a screening evaluation and pharmacokinetic study. Cancer Chemother Pharmacol, 1996, 37(4): 343-350.

[14]	Fiegler-RudolJ, KapłonK, KotuchaK, MośM, SkabaD, Kawczyk-KrupkaA, WienchR. Hypocrellin-mediated PDT: a systematic review of its efficacy, applications, and outcomes. Int J Mol Sci, 2025, 2694038.

[15]	Frey-KlettP, BurlinsonP, DeveauA, BarretM, TarkkaM, SarniguetA. Bacterial-fungal interactions: hyphens between agricultural, clinical, environmental, and food microbiologists. Microbiol Mol Biol Rev, 2011, 75(4): 583-609.

[16]	GoharD, PõldmaaK, TedersooL, AslaniF, FurneauxB, HenkelTW, SaarI, SmithME, BahramM. Global diversity and distribution of mushroom-inhabiting bacteria. Environ Microbiol Rep, 2022, 14(2): 254-264.

[17]	KanehisaM, ArakiM, GotoS, HattoriM, HirakawaM, ItohM, KatayamaT, KawashimaS, OkudaS, TokimatsuT, YamanishiY. KEGG for linking genomes to life and the environment. Nucleic Acids Res, 2008, 36(suppl1): D480-D484.

[18]	KhirallaA, MohammedAO, YagiS. Fungal perylenequinones. Mycol Prog, 2022, 21338.

[19]	LangmeadB, SalzbergSL. Fast gapped-read alignment with bowtie 2. Nat Methods, 2012, 9(4): 357-359.

[20]	Lara-OrtízT, Riveros-RosasH, AguirreJ. Reactive oxygen species generated by microbial NADPH oxidase NoxA regulate sexual development in. Mol Microbiol, 2003, 50(4): 1241-1255.

[21]	LeiXY, ZhangMY, MaYJ, WangJW. Transcriptomic responses involved in enhanced production of hypocrellin A by addition of triton X 100 in submerged cultures of Shiraia bambusicola. J Ind Microbiol Biotechnol, 2017, 44(10): 1415-1429.

[22]	LiHX, XiaoY, CaoLL, YanX, LiC, ShiHY, WangJW. Cerebroside C increases tolerance to chilling injury and alters lipid composition in wheat roots. PLoS ONE, 2013, 89e73380.

[23]	LiQ, LiXL, ChenC, LiSH, HuangWL, XiongC, JinX, ZhengLY. Analysis of bacterial diversity and communities associated with Tricholoma Matsutake fruiting bodies by barcoded pyrosequencing in Sichuan province, Southwest China. J Microbiol Biotechnol, 2016, 26(1): 89-98.

[24]	LiYT, YangC, WuY, LvJJ, FengX, TianXF, ZhouZZ, PanXY, LiuSW, TianLW. Axial chiral binaphthoquinone and perylenequinones from the stromata of are SARS-CoV-2 entry inhibitors. J Nat Prod, 2021, 84(2): 436-443.

[25]	LiXP, ShenWH, WangJW, ZhengLP. Production of fungal hypocrellin photosensitizers: exploiting bambusicolous fungi and elicitation strategies in mycelium cultures. Mycology, 2025, 16(2): 593-616.

[26]	LiuYX, HydeKD, AriyawansaHA, LiWJ, ZhouDQ, YangYL, ChenYM, LiuZY. Shiraiaceae, new family of. Ascomycota) Phytotaxa, 2013, 103(1): 51-60.

[27]	LiuB, BaoJY, ZhangZB, YanRM, WangY, YangHL, ZhuD. Enhanced production of perylenequinones in the endophytic fungus Shiraia sp. Slf14 by calcium/calmodulin signal transduction. Appl Microbiol Biotechnol, 2018, 102(1): 153-163.

[28]	LivakKJ, SchmittgenTD. Analysis of relative gene expression data using real-time quantitative PCR and the 2^–∆∆CT method. Methods, 2001, 25(4): 402-408.

[29]	LuCS, MaYJ, WangJW. Lanthanum elicitation on hypocrellin A production in mycelium cultures of Shiraia bambusicola is mediated by ROS generation. J Rare Earth, 2019, 37(8): 895-902.

[30]	MaGY, KhanSI, JacobMR, TekwaniBL, LiZQ, PascoDS, WalkerLA, KhanIA. Antimicrobial and antileishmanial activities of hypocrellins A and B. Antimicrob Agents Chemother, 2004, 48(11): 4450-4452.

[31]	MaYJ, LuCS, WangJW. Effects of 5-azacytidine on growth and hypocrellin production of Shiraia bambusicola. Front Microbiol, 2018, 92508.

[32]	Ma YJ, Zheng LP, Wang JW (2019a) Bacteria associated with Shiraia fruiting bodies influence fungal production of hypocrellin A. Front Microbiol 10:2023. https://doi.org/10.3389/fmicb.2019.02023

[33]	MaYJ, ZhengLP, WangJW. Inducing perylenequinone production from a bambusicolous fungus Shiraia sp. S9 through co-culture with a fruiting body-associated bacterium Pseudomonas fulva SB1. Microb Cell Fact, 2019, 181121.

[34]	MaYJ, GaoWQ, ZhangF, ZhuXT, KongWB, NiuSQ, GaoK, YangHQ. Community composition and trophic mode diversity of fungi associated with fruiting body of medicinal Sanghuangporus vaninii. BMC Microbiol, 2022, 221251.

[35]	Mearns-SpraggA, BreguM, BoydKG, BurgessJG. Cross-species induction and enhancement of antimicrobial activity produced by epibiotic bacteria from marine algae and invertebrates, after exposure to terrestrial bacteria. Lett Appl Microbiol, 1998, 27(3): 142-146.

[36]	MulrooneyCA, O’BrienEM, MorganBJ, KozlowskiMC. Perylenequinones: Isolation, synthesis, and biological activity. Eur J Org Chem, 2012, 2012(21): 3887-3904.

[37]	O’BrienEM, MorganBJ, MulrooneyCA, CarrollPJ, KozlowskiMC. Perylenequinone natural products: total synthesis of hypocrellin A. J Org Chem, 2010, 75(1): 57-68.

[38]	OhSY, KimM, EimesJA, LimYW. Effect of fruiting body bacteria on the growth of Tricholoma Matsutake and its related molds. PLoS ONE, 2018, 132e0190948.

[39]	PanWS, ZhengLP, TianH, LiWY, WangJW. Transcriptome responses involved in Artemisinin production in L. under UV-B radiation. J Photoch Photobio B, 2014, 140(1): 292-300.

[40]	Partida-MartinezLP, HertweckC. Pathogenic fungus harbours endosymbiotic bacteria for toxin production. Nature, 2005, 437(7060): 884-888.

[41]	RenXY, LiuYX, TanYM, HuangYH, LiuZY, JiangXL. Sequencing and functional annotation of the whole genome of. Genes Genomes Genet, 2020, 10(1): 23-35.

[42]	RobertsA, PachterL. Streaming fragment assignment for real-time analysis of sequencing experiments. Nat Methods, 2013, 10(1): 71-73.

[43]	SbranaC, AgnolucciM, BediniS, LeperaA, ToffaninA, GiovannettiM, NutiMP. Diversity of culturable bacterial populations associated to Tuber borchii ectomycorrhizas and their activity on T. borchii mycelial growth. FEMS Microbiol Lett, 2002, 211(2): 195-201.

[44]	SchlechtLM, PetersBM, KromBP, FreibergJA, HänschGM, FillerSG, Jabra-RizkMA, ShirtliffME. Systemic Staphylococcus aureus infection mediated by Candida albicans hyphal invasion of mucosal tissue. Microbiology, 2015, 161(1): 168-181.

[45]

SeelbinderB, ChenJ, BrunkeS, MeyerA-C, de Oliveira LinoFS, ChanK-F, LoosD, ImamovicL, TsangC-C, LamR, SridharP-k, KangS, HubeK, WooB, SommerPC-y, PanagiotouMOA. Antibiotics create a shift from mutualism to competition in human gut communities with a longer-lasting impact on fungi than bacteria. Microbiome, 2020, 8133.

[46]	ShinHJ, RoHS, KawauchiM, HondaY. Review on mushroom mycelium-based products and their production process: from upstream to downstream. Bioresour Bioprocess, 2025, 123.

[47]	SlanzonGS, YuanM, Estera–MolinaK, ChewA, BlazewiczSJ, AllenM, FirestoneMK, Pett–RidgeJ, NguyenNH. Quantitative stable isotope probing (qSIP) and cross-domain networks reveal bacterial fungal interactions in the hyphosphere. Microbiome, 2025, 13109.

[48]	SplivalloR, DeveauA, ValdezN, KirchhoffN, Frey-KlettP, KarlovskyP. Bacteria associated with truffle-fruiting bodies contribute to truffle aroma. Environ Microbiol, 2015, 17(8): 2647-2660.

[49]	SteffanBN, VenkateshN, KellerNP. Let’s get physical: bacterial-fungal interactions and their consequences in agriculture and health. J Fungi, 2020, 64243.

[50]	SuYJ, YinXY, RaoSQ, CaiYJ, ReuhsB, YangYJ. Natural colourant from Shiraia bambusicola: stability and antimicrobial activity of hypocrellin extract. Int J Food Sci Technol, 2009, 44(12): 2531-2537.

[51]	SuYJ, SunJ, RaoSQ, CaiYJ, YangYJ. Photodynamic antimicrobial activity of hypocrellin A. J Photochem Photobiol B, 2011, 103(1): 29-34.

[52]	ThevissenK, TerrasFRG, BroekaertWF. Permeabilization of fungal membranes by plant defensins inhibits fungal growth. Appl Environ Microbiol, 1999, 65(12): 5451-5458.

[53]	TongZW, MaoLW, LiangHL, ZhangZB, WangY, YanRM, ZhuD. Simultaneous determination of six perylenequinones in Shiraia sp. Slf14 by HPLC. J Liq Chromatogr Relat Technol, 2017, 40(10): 536-540.

[54]	TongXX, WangF, ZhangH, BaiJ, DongQ, YueP, JiangXY, LiXR, WangL, GuoJL. iTRAQ-based comparative proteome analyses of different growth stages revealing the regulatory role of reactive oxygen species in the fruiting body development of Ophiocordyceps sinensis. PeerJ, 2021, 9e10940.

[55]	TongulB, TarhanL. The effect of menadione-induced oxidative stress on the in vivo reactive oxygen species and antioxidant response system of Phanerochaete Chrysosporium. Process Biochem, 2014, 49(2): 195-202.

[56]	TrapnellC, WilliamsBA, PerteaG, MortazaviA, KwanG, van BarenMJ, SalzbergSL, WoldBJ, PachterL. Transcript assembly and quantification by RNA-Seq reveals unannotated transcripts and isoform switching during cell differentiation. Nat Biotechnol, 2010, 28(5): 511-515.

[57]	VareseGC, PortinaroS, TrottaA, ScanneriniS, Luppi-MoscaAM, MartinottiMG. Bacteria associated with Suillus grevillea sporocarps and ectomycorrhizae and their effects on in vitro growth of the mycobiont. Symbiosis, 1996, 21(2): 129-147

[58]	WangH, PengL, DingZY, WuJY, ShiGY. Stimulated laccase production of Pleurotus ferulae JM301 fungus by Rhodotorula mucilaginosa yeast in co-culture. Process Biochem, 2015, 50(6): 901-905.

[59]	WangG, RanH, FanJ, KellerNP, LiuZ, WuF, YinW-B. Fungal-fungal cocultivation leads to widespread secondary metabolite alteration requiring the partial loss-of-function VeA1 protein. Sci Adv, 2022, 8eabo6094.

[60]	WangWJ, LiXP, ShenWH, HuangQY, CongRP, ZhengLP, WangJW. Nitric oxide mediates red light-induced perylenequinone production in Shiraia mycelium culture. Bioresour Bioprocess, 2024, 112.

[61]	Xiang QJ, Luo LH, Liang YH, Chen Q, Zhang XP, Gu YF (2017) The diversity, growth promoting abilities and anti-microbial activities of bacteria isolated from the fruiting body of Agaricus bisporus. Pol J Microbiol 66(2):201–207. doi: 10. 5604/01.3001.0010.7837

[62]	XuR, LiXP, ZhangX, ShenWH, MinCY, WangJW. Contrasting regulation of live Bacillus cereus 1 and its volatiles on Shiraia perylenequinone production. Microb Cell Fact, 2022, 211172.

[63]	XuR, HuangQY, ShenWH, LiXP, ZhengLP, WangJW. Volatiles of Shiraia fruiting body-associated Pseudomonas Putida 24 stimulate fungal hypocrellin production. Syn Syst Biotechnol, 2023, 8(3): 427-436.

[64]	YangHL, WangY, ZhangZB, YanRM, ZhuD. Whole genome shotgun assembly and analysis of the genome of Shiraia sp. strain Slf14, a novel endophytic fungus producing huperzine A and hypocrellin A. Genome Announc, 2014, 2(1): e00011-e00014.

[65]	YaoYY, PanLL, SongWL, YuanYZ, YanSZ, YuSQ, ChenSL. Elsinochrome A induces cell apoptosis and autophagy in photodynamic therapy. J Cell Biochem, 2023, 124(9): 1346-1365.

[66]	YouBJ, LeeMH, TienN, LeeMS, HsiehHC, TsengLH, ChungYL, LeeHZ. A novel approach to enhancing Ganoderic acid production by Ganoderma lucidum using apoptosis induction. PLoS ONE, 2013, 81e53616.

[67]	ZhangKX, ChenX, ShiXF, YangZY, YangL, LiuD, YuFQ. Endophytic bacterial community, core taxa, and functional variations within the fruiting bodies of Laccaria. Microorganisms, 2024, 12112296.

[68]	ZhangX, WeiQL, TianLW, HuangZX, TangYB, WenYD, YuFQ, YanXX, ZhaoYC, WuZQ, TianXF. Advancements and future prospects in hypocrellins production and modification for photodynamic therapy. Fermentation, 2024, 1011559.

[69]	Zheng LP, Huang QY, Li XP, Zhou JQ, Wang JW (2025) Interplay between Shiraia and its fruiting body-associated Rhodococcus sp. 3 via hypocrellin A and carotenoid biosynthesis, mycology. https://doi.org/10.1080/21501203.2025.2531888

[70]	ZhouLL, ShenWH, MaYJ, LiXP, WuJY, WangJW. Structure characterization of an exopolysaccharide from a Shiraia-associated bacterium and its strong eliciting activity on the fungal hypocrellin production. Int J Biol Macromol, 2023, 226: 423-433.