Sterol Regulatory Element-Binding Protein Sre1 Mediates the Development and Pathogenicity of the Grey Mould Fungus Botrytis cinerea
by
Ye Yuan
1,†, 
Shengnan Cao
1,2,†,
Jiao Sun
1,
Jie Hou
1,
Mingzhe Zhang
1,
Qingming Qin
1,3 and
Guihua Li
1,* 1
College of Plant Sciences, Jilin University, Changchun 130062, China
2
College of Fisheries and Life Science, Dalian Ocean University, Dalian 116023, China
3
Christopher S. Bond Life Sciences Center, Department of Molecular Microbiology and Immunology, School of Medicine, The University of Missouri, Columbia, MO 65211, USA
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Int. J. Mol. Sci. 2025, 26(3), 1365; https://doi.org/10.3390/ijms26031365
Submission received: 26 November 2024
/
Revised: 30 January 2025
/
Accepted: 4 February 2025
/
Published: 6 February 2025
(This article belongs to the Special Issue Plant Responses to Biotic and Abiotic Stresses)
Abstract
:The grey mould fungus Botrytis cinerea is a dangerous plant pathogen responsible for substantial agricultural losses worldwide. The pathogenic mechanisms still have many unclear aspects, and numerous new pathogenic genes remain to be identified. Here, we show that the sterol regulatory element-binding protein Sre1 plays an important role in the development and pathogenicity of B. cinerea. We identified a homologue of gene SRE1 in the B. cinerea genome and utilized a reverse genetics approach to create the knockout mutant Δsre1. Our results demonstrate that SRE1 is essential for conidiation, as Δsre1 produced only 3% of the conidia compared to the wild-type strain. Conversely, Δsre1 exhibited increased sclerotium production, indicating a negative regulatory role of SRE1 in sclerotium formation. Furthermore, ergosterol biosynthesis was significantly reduced in the Δsre1 mutant, correlating with increased sensitivity to low-oxygen conditions. Pathogenicity assays revealed that Δsre1 had significantly reduced virulence, although it maintained normal infection cushion formation and penetration capabilities. Additionally, SRE1 was found to be crucial for hypoxia adaptation, as Δsre1 showed abnormal germination and reduced growth under low-oxygen conditions. These findings suggest that SRE1 mediates the development and pathogenicity of B. cinerea by regulating lipid homeostasis and facilitating adaptation to host tissue environments.
1. Introduction
Grey mould is a common and severe fungal disease affecting plants worldwide. It can manifest on various parts of host plants, including leaves, stems, flowers, and fruits, and is often prevalent in cool, humid climates [1]. This disease is particularly problematic in the greenhouse for the production of horticultural crops. Under conditions of low temperature (around 20 °C) and high humidity (relative humidity above 90%), once the disease occurs, no host plant is spared; in severe cases, it can lead to reduced crop yields or even total crop loss [2].
The occurrence of grey mould is not limited to the growth stages of field crops; it can also arise during the harvesting, storage, and transportation of fruits and vegetables. Consequently, the economic losses attributed to grey mould globally can reach between USD 10 billion and USD 100 billion annually [3]. According to a worldwide survey among plant pathologist, grey mould was ranked as the second most important fungal disease of plants, following rice blast disease [4].
The primary pathogenic fungus responsible for grey mould is Botrytis cinerea, which has a wide host range, capable of infecting over 1400 plant species across 586 genera [5,6]. The severe impact of B. cinerea has resulted in significant economic losses worldwide. The completion of the whole-genome sequencing and the development of various molecular techniques have established B. cinerea as an important model organism in the study of molecular plant pathology [4,7].
B. cinerea is a typical necrotrophic plant pathogen. Under natural conditions, conidia serve as the main source of initial and secondary infections in host plants. Upon germination, conidia form a germ tube that penetrates the host through structures such as appressoria or infection cushions [8,9]. After invading host cells, B. cinerea secretes various pathogenic factors, including cutinases, cell wall-degrading enzymes (Pme1, Pg1, etc.), toxins (botrydial and botcinic acid), oxalic acid, sRNAs, metal chelating proteins (Ibp, etc.) and cell death-inducing proteins (Xyg1, Rae, etc.) [3,10,11,12,13,14], which can kill the host or suppress its defence responses. This allows the pathogen to exploit the host’s nutrient (such as host cell wall components) for its growth and reproduction, leading to the formation of extensive mycelia and conidia. At the later stages of infection, the mycelium of B. cinerea forms sclerotium, a melanized resting body, which enables it to overwinter. The environmental conditions required for the production of conidia and sclerotia are often quite different. For the model strain B05.10, light can induce conidia production, while incubation in the dark promotes sclerotia formation [5].
Lipid homeostasis in mammalian cells is controlled by a family of sterol regulatory element binding protein (SREBP) transcription factors [15]. Hughes et al. (2005) first characterized the SREBP transcription factor Sre1 as a crucial oxygen sensor in fission yeast Schizosaccharomyces pombe [16]. Sre1 regulates the expression of genes involved in sterol biosynthesis (e.g., ERG25, which encodes a key enzyme involved in ergosterol biosynthesis), as a response to low level of sterol and oxygen availability. This dual role highlights the importance of Sre1 in maintaining cellular homeostasis under varying environmental conditions.
Sre1 plays important roles in orchestrating the transcriptional response to anaerobic conditions [17]. The binding of Nro1 to the prolyl hydroxylase Ofd1 is oxygen-dependent, regulating the stability of Sre1. This mechanism ensures that Sre1 levels are adjusted according to oxygen availability, thereby fine-tuning the expression of genes involved in sterol metabolism and other anaerobic processes [18]. Ergosterol acts as a critical regulator of Sre1 processing [19]. Sre1 and Mga2 are coordinately regulated, which is essential for the adaptive response to hypoxia [20]. The unassembled ribosomal protein uS12/Rps23 undergoes prolyl dihydroxylation, which affects the stability and function of Sre1, thereby influencing the hypoxic response and overall cellular adaptation [21]. Sre1 is also involved in the regulation of carotenogenesis in the red yeast Xanthophyllomyces dendrorhous [22,23]. This suggests that Sre1 may have diverse functions beyond sterol regulation.
Sre1 has been implicated in the virulence of several pathogenic fungi. For instance, in Cryptococcus neoformans, Sre1 is essential for oxygen sensing and sterol homeostasis, which are critical for its virulence [24,25]. The regulation of Sre1 in response to hypoxia allows C. neoformans to adapt to the host environment, enhancing its pathogenic potential [26]. Additionally, studies on Magnaporthe oryzae, the rice blast fungus, have shown that Sre1 is involved in the hypoxic response, which is crucial for its invasive growth within host cells [27]. In the insect fungal pathogen Beauveria bassiana, BbSre1 has been shown to control oxidative stress response and lipid homeostasis, further emphasizing the importance of Sre1 in fungal pathogenicity [28]. Furthermore, the role of Sre1 in Clonostachys rosea, a biocontrol agent, highlights its involvement in fungicide tolerance (such as prothioconazole, an inhibitor of sterol biosynthesis targeting the C14-demethylase Erg11) and antagonism, suggesting that Sre1 may play a role in the ecological fitness of fungi [29].
Comparative studies of Sre1 across different fungal species have highlighted its evolutionary conservation, with the exception of the absence of Sre1 in Microsporidia and most Basidiomycota species [30]. While the core functions of Sre1 in regulating lipid metabolism are conserved, variations in its regulatory mechanisms and target genes have been observed, reflecting the adaptation of different fungal species to their specific ecological niches [30]. This diversity presents opportunities for further exploration of Sre1’s role in fungal biology and its potential applications in biotechnology and medicine. Whether Sre1 plays an important role in the pathogenicity of B. cinerea remains unclear. Here, we identified a homologue of SRE1 in B. cinerea. Disruption of this gene suppressed B. cinerea conidiation and pathogenicity but promoted its sclerotium production. We found that the knockout mutant Δsre1 exhibited low level of ergosterol biosynthesis and increased sensitivity to low-oxygen conditions, suggesting that SRE1 mediates development and pathogenesis of B. cinerea, likely via maintaining lipid homeostasis and regulation of its adaptation to the host tissue environments.
2. Results
2.1. Identification, Knockout, and Genetic Complementation of the B. cinerea Gene SRE1
We used the S. pombe SRE1 protein sequence (NP_595694.1) as a reference and identified a homologous gene BCIN_01g05780 in the B. cinerea genome. The open reading frame of B. cinerea SRE1 consists of 2848 nucleotides, containing two exonic regions, with the coding region comprising 2679 nucleotides that encode 892 amino acids.
To confirm whether SRE1 plays a crucial role in the growth, development, and pathogenicity of B. cinerea, we employed a reverse genetics approach to knock it out by replacement with the hygromycin resistance gene HPH (Figure 1a).
We introduced the knockout fragment into the wild-type strain B05.10 via the Agrobacterium tumefaciens-mediated transformation (ATMT) method. After screening for hygromycin resistance, we obtained a total of 105 transformants. PCR amplifications were used to identify knockout mutants. The transformants that tested positive for upstream and downstream recombination, and negative for the SRE1 fragment were identified as the knockout mutant Δsre1. Among these, 16 were confirmed as homozygous knockout mutants (Figure 1b), and mutant #21 was selected for further study.
To confirm the following observed defective phenotypes were indeed due to the deletion of SRE1, we constructed an ectopic genetic complemented strain, Δsre1-c, based on the aforementioned Δsre1 mutant. We first amplified the complete SRE1 gene (including its native promoter, coding region, and terminator) from the wild-type strain, then cloned and transformed it into the knockout mutant Δsre1. After screening for G418 resistance, we obtained four transformants of Δsre1-c (Figure 1c). Strain #1 was selected for further investigation. RT-PCR analysis indicated that SRE1 mRNA was undetectable in Δsre1, while its level in the complemented strain Δsre1-c was recovered near to those of the wild-type strain (Figure 1d).
2.2. SRE1 Is Required for B. cinerea Conidiation but Dispensable for Conidial Morphogenesis and Germination
To confirm whether SRE1 is involved in the growth and development of B. cinerea, we first analyzed the growth of the Δsre1 on potato dextrose agar (PDA) plates. We found that both the colony morphology and growth rate were normal, showing no significant differences compared to the wild-type and complemented strains (Figure 2a,b). This indicates that SRE1 is dispensable for vegetative growth.
Conidia are the primary means of dissemination and infection for B. cinerea. Next, we assessed the conidiation level of the mutant strain. Our results showed that after 12 days of cultivation on complete medium (CM) plates, Δsre1 produced significantly fewer conidia, amounting to only about 3% of the conidia produced by the wild-type B05.10 strain. In contrast, the complemented strain Δsre1-c exhibited normal conidiation (Figure 2c,d). This result indicates that SRE1 is required for B. cinerea conidiation. Additionally, we found that the absence of SRE1 did not affect the morphology (Figure 2e) or germination (Figure 2f) of conidia.
2.3. SRE1 Mediates Sclerotium Production and Ergosterol Biosynthesis in B. cinerea
Sclerotia play a crucial role in helping B. cinerea withstand adverse environmental conditions for completing its life cycle. To clarify the role of SRE1 in sclerotium formation in B. cinerea, we inoculated wild-type B05.10, Δsre1, and Δsre1-c on CM plates and induced sclerotium formation by incubating them in the dark at 20 °C. The results indicated that the deletion of SRE1 led to the production of a significantly higher number of sclerotia, approximately six times that of the wild-type and Δsre1-c (Figure 3a,b), suggesting that SRE1 negatively mediates sclerotium production.
In the fission yeast S. pombe, Sre1 acts as a transcription factor that promotes ergosterol biosynthesis when its level is low. To determine whether Sre1 in B. cinerea has a similar function, we measured the ergosterol content in the relevant strains. We found that the deletion of SRE1 resulted in a significant reduction in the ergosterol content in mycelia, approximately half that of the wild-type strain. In contrast, the ergosterol level in the complemented strain was significantly restored (Figure 3c). This result indicates that Sre1 similarly regulates ergosterol biosynthesis in B. cinerea.
We treated the various strains with the antifungal drug imidazole to observe its effect on conidial germination. Surprisingly, the results showed that Δsre1 exhibited increased resistance levels (Figure 4; Figure S1), indicating that SRE1 may negatively mediate resistance to this agent in B. cinerea.
2.4. SRE1 Is Required for B. cinerea Virulence but Dispensable for Its Infection Cushion Formation and Penetration
To verify whether SRE1 is involved in the pathogenic process of B. cinerea, we inoculated detached green bean leaves with mycelial plugs from the wild-type strain B05.10, Δsre1, and Δsre1-c, respectively. At 72 h post inoculation (HPI), we observed that the lesion size caused by Δsre1 was significantly reduced compared to the wild-type B05.10, with only about one-third size of the wild-type lesions. In contrast, the pathogenicity of the complemented strain Δsre1-c was significantly enhanced compared to the mutant (Figure 5a,e). Similar results were obtained using conidial suspensions for inoculation (Figure 5b). These results indicate that SRE1 plays an important role in the pathogenic process of B. cinerea.
Infection cushion is a crucial structure for B. cinerea to penetrate the host. To confirm whether the reduced pathogenicity of Δsre1 is related to the development of the infection cushion, we inoculated conidial suspensions of the wild-type B05.10, Δsre1, and Δsre1-c onto glass slides to induce the formation of infection cushions. The results showed that Δsre1 could form infection cushions normally, and their morphology was also normal (Figure 5c). We further analyzed the penetration ability of the relevant strains on onion epidermis and found that the penetration capability of the mutant was also normal, with no significant differences compared to the wild-type and complemented strain (Figure 5d,f). These results indicate that the deletion of SRE1 did not affect the early infection process of B. cinerea (including the development of infection structures and penetration), implying that SRE1 may mediate B. cinerea pathogenicity by participating in the regulation of its adaptation to the host tissue environment after penetration.
2.5. SRE1 Is Involved in Hypoxia Adaptation of B. cinerea
In the fission yeast S. pombe, the SREBP transcription factor Sre1 serves as a crucial oxygen sensor and plays important roles in orchestrating the transcriptional response to anaerobic conditions [17]. To determine whether Sre1 of B. cinerea is also involved in hypoxic response, we first treated the conidia of relevant strains with the hypoxia-mimicking agent cobalt chloride (CoCl2) to observe their germination under low-oxygen conditions. CoCl2 has been widely used as a hypoxia-mimicking agent in many organisms [31]. The results showed that the germination of Δsre1 conidia was abnormal, with a significantly higher proportion of conidia germinating with three germ tubes compared to the wild-type and complemented strains, which typically only with 1–2 germ tubes (Figure 6a,b).
Next, we treated the mycelia of each strain with the same hypoxia-mimicking conditions in liquid media. Quantitative analysis revealed that the growth of Δsre1 under low-oxygen conditions was significantly lower than that of the wild-type and complemented strains (Figure 6c, right panel). However, under normal conditions, there were no significant differences in growth among the strains (Figure 6c, left panel). These results indicate that SRE1 plays an important role in the hypoxia adaptation of B. cinerea.
3. Discussion
In this study, we demonstrate that the sterol regulatory element-binding protein Sre1 is crucial for the development and pathogenicity of the grey mould fungus B. cinerea. Our findings provide new insights into how SRE1 mediates key aspects of fungal biology, including conidiation, sclerotium formation, virulence, and adaptation to host environments. These processes are tightly connected to lipid homeostasis, particularly ergosterol biosynthesis, and the ability of B. cinerea to cope with hypoxic conditions during infection.
Our finding indicates the significant role of B. cinerea SRE1 in regulating ergosterol biosynthesis. In the Δsre1 mutant, ergosterol content was reduced by approximately 50%, which aligns with the known function of SRE1 in regulating sterol biosynthesis pathways in other fungi [16,32]. Ergosterol, the primary sterol in fungal membranes, is crucial for maintaining membrane integrity and fluidity, which is essential for various cellular processes including growth, signalling, and stress responses. Reduced ergosterol levels in the mutant strain Δsre1 may explain some of the observed developmental defects and altered stress responses, such as increased resistance to the antifungal drug imidazole, which targets ergosterol biosynthesis [32]. This observation could open new avenues for exploring how B. cinerea manages drug resistance and lipid metabolism during pathogenesis.
A striking observation from the study is that SRE1 is essential for B. cinerea conidiation. The Δsre1 mutant exhibited severely reduced conidiation (only about 3% of the wild-type level), highlighting the importance of SRE1 in fungal reproduction and dispersal. Conidiation is a critical step in the lifecycle of B. cinerea, as conidia serve as the primary infectious propagules, facilitating pathogen spread [4]. An earlier study has shown that the mutant of M. oryzae SRE1 exhibits increased conidiation [27]. These finding indicate that SRE1s regulate conidial formation in a species-specific manner among fungi.
Sclerotium production is another key aspect of B. cinerea biology that is regulated by SRE1. This study revealed that Δsre1 mutant produces significantly more sclerotia, a structure crucial for the pathogen’s survival under unfavourable conditions [5]. This finding suggests that SRE1 negatively regulates sclerotium formation, possibly through its role in sterol biosynthesis and lipid homeostasis. This suggests that Sre1 may act as a switch, promoting conidiation while inhibiting sclerotium formation, a strategy that helps the fungus adapt to changing environmental conditions. In contrast, lack of SRE1 may shift the balance toward survival strategies, such as enhanced sclerotium formation, at the expense of reproductive dispersal (conidiation). The possibility that the enhanced sclerotia formation in the SRE1 mutant is an indirect effect of reduced conidiation cannot yet be excluded, because the induction conditions for their development are quite different in the wild-type strain B05.10 [5], which suggests that their development may be antagonistic.
Our finding shows that SRE1 plays a role in hypoxia adaptation of B. cinerea. In line with previous work in other fungal species, where SRE1 is a key regulator of the response to low-oxygen conditions [16,17,26,27], we observed that the Δsre1 mutant exhibited impaired conidial germination and mycelial growth under hypoxic conditions. The use of CoCl2, a commonly used hypoxia-mimicking agent [21], revealed a distinct germination phenotype, with a higher proportion of conidia producing multiple germ tubes, which could be indicative of abnormal metabolic responses in the absence of SRE1. Additionally, the growth of the mutant in liquid culture under low-oxygen conditions was significantly reduced compared to the wild-type and complemented strains, further underscoring the critical role of SRE1 in the hypoxic stress response. These results suggest that SRE1 is a central player in the fungal adaptation to oxygen-limited environments during infection, a phenomenon that has also been highlighted in C. neoformans [26].
The role of SRE1 in pathogenicity was another focal point of our study. The Δsre1 mutant exhibited significantly reduced virulence of B. cinerea. This reduced pathogenicity occurred despite normal formation of infection cushions and penetration ability, indicating that SRE1 does not affect the initial stages of infection, but may instead be important for the pathogen’s adaptation to the host environment post-penetration. Similar observations were reported in M. oryzae, where the hypoxic response controlled by SRE1 was found to be critical for its invasive growth within host cells [27]. Thus, our results suggest that SRE1 mediates B. cinerea pathogenicity through its role in lipid homeostasis and adaptation to the hypoxic conditions typically encountered in host tissues.
The findings from this study open several interesting avenues for future research. First, further investigations into the molecular mechanisms by which SRE1 regulates sclerotium formation and conidiation are needed. It would be valuable to explore whether SRE1 influences these processes directly through gene regulation or indirectly through its impact on lipid metabolism. Additionally, the role of SRE1 in fungal interactions with plant immune responses remains an important area for exploration. Studies could investigate whether and how SRE1-mediated lipid homeostasis affects the secretion of virulence factors and immune-modulating proteins, as seen in other pathogeneses [3]. Lastly, given the central role of SRE1 in fungal hypoxic responses, it would be interesting to assess the potential of SRE1 as a therapeutic target for controlling B. cinerea and other plant pathogens, especially considering its involvement in virulence and adaptation to stress conditions [28].
In conclusion, this study demonstrates that SRE1 plays a multifaceted role in the development and pathogenicity of B. cinerea. It regulates key processes such as conidiation, sclerotium formation, ergosterol biosynthesis, and adaptation to hypoxic environments. These findings highlight the importance of lipid homeostasis and hypoxia adaptation in fungal pathogenesis and suggest that targeting SRE1 could offer new strategies for managing grey mould disease in agricultural systems. For example, it may be possible to use SRE1 (or its protein product) as a molecular target to inhibit conidiation and pathogenicity of B. cinerea through methods such as spray-induced gene silencing.
4. Materials and Methods
4.1. Fungal Strains and Culture Conditions
4.2. Gene Knockout and Genetic Complementation
Vectors and primers used in this study are listed in Table S2 and Table S3, respectively. The gene replacement method was used for SRE1 knockout. The vector pXEH, containing the hygromycin resistance gene HPH [35], was used to construct the knockout vector. The 5′- and 3′- homologous flanks of SRE1 were amplified and cloned into pXEH in the upstream and downstream of HPH, respectively. The resultant vector pSRE1-ko was transformed into A. tumefaciens strain AGL-1 as previously described [36]. The ATMT method was used to obtain fungal transformants as previously described with minor modification [37]. The cocultivation was performed on cellophane. The transformants were selected on PDA supplemented with 100 mg/L hygromycin.
The vector pXEG, resistant to G418, was used to generate the complemented strain ∆sre1-c. The full fragment of SRE1 was amplified by PCR and cloned into pXEG to generate the complemented vector, which was then transformed into ∆sre1 via the ATMT method. The resultant transformants were selected on PDA plates containing 50 mg/L G418 [38].
4.3. Fungal Developmental Assays
The development analysis of B. cinerea strains were performed as previously described [36]. Briefly, the growth of the tested strains was determined by measuring the radial diameter of colonies in mm on PDA at 3 DPI. Conidial number per plate was calculated at 12 DPI of CM cultures. Conidial suspensions (105 conidia/mL) in 1/2 potato dextrose broth (PDB) were used for the measurement of conidial morphology and germination. For sclerotial formation, strains were cultivated on CM at 20 °C in darkness for 15 DPI. For infection cushion observation, 10 μL conidial suspensions (105 conidia/mL in 1/2 PDB) of the tested strains were inoculated on glass slides and cultured at 20 °C and observed at 16–24 DPI.
4.4. Pathogenicity and Penetration Assays
Pathogenicity and penetration assays were performed as previously described [34]. Briefly, mycelial plugs (5 mm in diameter) or conidial droplets (2 × 105 conidia/mL in 1/2 PDB, 10 µL) were inoculated on green bean leaves, incubated in plastic containers with high humidity at 20–25 °C, and observed at 3 DPI. For the penetration assay, conidial droplets were inoculated on onion epidermis. After incubation, the inoculated epidermis was stained with lactophenol aniline blue and observed microscopically.
4.5. Hypoxia Adaptation Assays
Prepare conidial suspensions (2 × 105 conidia/mL, containing 50 mM glucose) of the tested B. cinerea strains. The hypoxia-mimicking agent CoCl2 [31] was added at concentrations of 0, 100, 200 μM, respectively; incubate and observe conidial germinations at 4–8 HPI.
For analyzing the effects of hypoxia on mycelial growth, 2 mL conidial suspensions (1 × 106 conidia/mL) of the tested B. cinerea strains were inoculated into 100 mL liquid CM supplemented with 0, 200 μM CoCl2 respectively, and incubated unshaking (with shaking as control of normoxia) for 7 days. Mycelia were harvested, dried at 45 °C for 24 h, and weighted for biomass quantification.
4.6. Quantification of Ergosterol
For ergosterol extraction, the tested strains of B. cinerea was cultured on PDA plates covered with sterile cellophane at 20 °C for 7 days. Mycelia were gently scraped off cellophanes, and total ergosterol was extracted and analyzed as previously described [41].
4.7. Imidazole Sensitivity Assay
Prepare conidial suspensions (2 × 105 conidia/mL, containing 50 mM glucose) of the tested B. cinerea strains. Add 1 μL, 2 μL, 5 μL, or 10 μL of 1 mol/L imidazole solution to 1 mL conidial suspensions prepared above and mix well. Then, take 10 μL of each conidial suspension and place it on a glass slide and incubate them in a humid and dark condition at 20 °C. Conidial germinations were observed under a microscope at 4 HPI and 8 HPI.
4.8. Statistical Analysis
All the quantitative data presented in this study represent results from triplicate experiments independently performed at least three times. To easily compare the results from different independent experiments, the data of controls including mycelial growth, lesion size, conidiation, and so forth, were normalized as 1 or 100% in each independent experiment. The significance of the data was assessed using Student’s t-tests. And the p-value lower than 0.05 was considered to be statistically significant.
Supplementary Materials
The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ijms26031365/s1.
Author Contributions
Conceptualization, G.L. and Q.Q.; methodology, Y.Y., S.C., G.L., J.S. and J.H.; formal analysis, Y.Y., S.C. and G.L.; investigation, Y.Y. and S.C.; resources, G.L. and Q.Q.; data curation, Y.Y. and G.L.; writing—original draft preparation, G.L. and Y.Y.; writing—review and editing, G.L. and Y.Y.; visualization, G.L. and Y.Y.; supervision, G.L., Q.Q. and M.Z.; project administration, G.L. and Q.Q.; funding acquisition, G.L. and Q.Q. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the National Natural Science Foundation of China (No. 32372489) and the Natural Science Foundation of Jilin Province, China (No. 20220101279JC). The APC was funded by the National Natural Science Foundation of China (No. 32372489).
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
All data included in this study are contained within the article and Supplementary Materials [35,38,42].
Acknowledgments
The authors would like to thank the anonymous reviewers for their constructive comments on this article.
Conflicts of Interest
The authors declare no conflicts of interest.
References
- Billon-Grand, G.; Rascle, C.; Droux, M.; Rollins, J.A.; Poussereau, N. pH modulation differs during sunflower cotyledon colonization by the two closely related necrotrophic fungi Botrytis cinerea and Sclerotinia sclerotiorum. Mol. Plant Pathol. 2012, 13, 568–578. [Google Scholar] [CrossRef] [PubMed]
- Cabot, C.; Gallego, B.; Martos, S.; Barcelo, J.; Poschenrieder, C. Signal cross talk in Arabidopsis exposed to cadmium, silicon, and Botrytis cinerea. Planta 2013, 237, 337–349. [Google Scholar] [CrossRef] [PubMed]
- Weiberg, A.; Wang, M.; Lin, F.M.; Zhao, H.; Zhang, Z.; Kaloshian, I.; Huang, H.D.; Jin, H. Fungal small RNAs suppress plant immunity by hijacking host RNA interference pathways. Science 2013, 342, 118–123. [Google Scholar] [CrossRef]
- Dean, R.; Van Kan, J.A.; Pretorius, Z.A.; Hammond-Kosack, K.E.; Di Pietro, A.; Spanu, P.D.; Rudd, J.J.; Dickman, M.; Kahmann, R.; Ellis, J.; et al. The Top 10 fungal pathogens in molecular plant pathology. Mol. Plant Pathol. 2012, 13, 414–430. [Google Scholar] [CrossRef] [PubMed]
- Elad, Y.; Fillinger, S. Botrytis—The Fungus, the Pathogen and Its Management in Agricultural Systems; Springer: New York, NY, USA, 2016. [Google Scholar] [CrossRef]
- Petrasch, S.; Knapp, S.J.; van Kan, J.A.L.; Blanco-Ulate, B. Grey mould of strawberry, a devastating disease caused by the ubiquitous necrotrophic fungal pathogen Botrytis cinerea. Mol. Plant Pathol. 2019, 20, 877–892. [Google Scholar] [CrossRef]
- Amselem, J.; Cuomo, C.A.; van Kan, J.A.; Viaud, M.; Benito, E.P.; Couloux, A.; Coutinho, P.M.; de Vries, R.P.; Dyer, P.S.; Fillinger, S.; et al. Genomic analysis of the necrotrophic fungal pathogens Sclerotinia sclerotiorum and Botrytis cinerea. PLoS Genet. 2011, 7, e1002230. [Google Scholar] [CrossRef]
- Choquer, M.; Rascle, C.; Goncalves, I.R.; de Vallee, A.; Ribot, C.; Loisel, E.; Smilevski, P.; Ferria, J.; Savadogo, M.; Souibgui, E.; et al. The infection cushion of Botrytis cinerea: A fungal ’weapon’ of plant-biomass destruction. Environ. Microbiol. 2021, 23, 2293–2314. [Google Scholar] [CrossRef] [PubMed]
- Aguileta, G.; Lengelle, J.; Chiapello, H.; Giraud, T.; Viaud, M.; Fournier, E.; Rodolphe, F.; Marthey, S.; Ducasse, A.; Gendrault, A.; et al. Genes under positive selection in a model plant pathogenic fungus, Botrytis. Infect. Genet. Evol. 2012, 12, 987–996. [Google Scholar] [CrossRef]
- Choquer, M.; Fournier, E.; Kunz, C.; Levis, C.; Pradier, J.M.; Simon, A.; Viaud, M. Botrytis cinerea virulence factors: New insights into a necrotrophic and polyphageous pathogen. FEMS Microbiol. Lett. 2007, 277, 1–10. [Google Scholar] [CrossRef]
- Zhu, W.; Ronen, M.; Gur, Y.; Minz-Dub, A.; Masrati, G.; Ben-Tal, N.; Savidor, A.; Sharon, I.; Eizner, E.; Valerius, O.; et al. BcXYG1, a Secreted Xyloglucanase from Botrytis cinerea, Triggers Both Cell Death and Plant Immune Responses. Plant Physiol. 2017, 175, 438–456. [Google Scholar] [CrossRef]
- Liu, L.; Gueguen-Chaignon, V.; Goncalves, I.R.; Rascle, C.; Rigault, M.; Dellagi, A.; Loisel, E.; Poussereau, N.; Rodrigue, A.; Terradot, L.; et al. A secreted metal-binding protein protects necrotrophic phytopathogens from reactive oxygen species. Nat. Commun. 2019, 10, 4853. [Google Scholar] [CrossRef]
- You, Y.; Suraj, H.M.; Matz, L.; Herrera Valderrama, A.L.; Ruigrok, P.; Shi-Kunne, X.; Pieterse, F.P.J.; Oostlander, A.; Beenen, H.G.; Chavarro-Carrero, E.A.; et al. Botrytis cinerea combines four molecular strategies to tolerate membrane-permeating plant compounds and to increase virulence. Nat. Commun. 2024, 15, 6448. [Google Scholar] [CrossRef]
- Zhang, X.; Zhang, Z.; Chen, T.; Chen, Y.; Li, B.; Tian, S. Characterization of two SGNH family cell death-inducing proteins from the horticulturally important fungal pathogen Botrytis cinerea based on the optimized prokaryotic expression system. Mol. Hortic. 2024, 4, 9. [Google Scholar] [CrossRef]
- Rawson, R.B. The SREBP pathway—Insights from Insigs and insects. Nat. Rev. Mol. Cell Biol. 2003, 4, 631–640. [Google Scholar] [CrossRef] [PubMed]
- Hughes, A.L.; Todd, B.L.; Espenshade, P.J. SREBP pathway responds to sterols and functions as an oxygen sensor in fission yeast. Cell 2005, 120, 831–842. [Google Scholar] [CrossRef] [PubMed]
- Todd, B.L.; Stewart, E.V.; Burg, J.S.; Hughes, A.L.; Espenshade, P.J. Sterol regulatory element binding protein is a principal regulator of anaerobic gene expression in fission yeast. Mol. Cell Biol. 2006, 26, 2817–2831. [Google Scholar] [CrossRef] [PubMed]
- Lee, C.Y.; Stewart, E.V.; Hughes, B.T.; Espenshade, P.J. Oxygen-dependent binding of Nro1 to the prolyl hydroxylase Ofd1 regulates SREBP degradation in yeast. EMBO J. 2009, 28, 135–143. [Google Scholar] [CrossRef] [PubMed]
- Porter, J.R.; Burg, J.S.; Espenshade, P.J.; Iglesias, P.A. Ergosterol regulates sterol regulatory element binding protein (SREBP) cleavage in fission yeast. J. Biol. Chem. 2010, 285, 41051–41061. [Google Scholar] [CrossRef] [PubMed]
- Burr, R.; Stewart, E.V.; Espenshade, P.J. Coordinate Regulation of Yeast Sterol Regulatory Element-binding Protein (SREBP) and Mga2 Transcription Factors. J. Biol. Chem. 2017, 292, 5311–5324. [Google Scholar] [CrossRef] [PubMed]
- Clasen, S.J.; Shao, W.; Gu, H.; Espenshade, P.J. Prolyl dihydroxylation of unassembled uS12/Rps23 regulates fungal hypoxic adaptation. Elife 2017, 6, e28563. [Google Scholar] [CrossRef]
- Gomez, M.; Campusano, S.; Gutierrez, M.S.; Sepulveda, D.; Barahona, S.; Baeza, M.; Cifuentes, V.; Alcaino, J. Sterol regulatory element-binding protein Sre1 regulates carotenogenesis in the red yeast Xanthophyllomyces dendrorhous. J. Lipid Res. 2020, 61, 1658–1674. [Google Scholar] [CrossRef] [PubMed]
- Gutierrez, M.S.; Campusano, S.; Gonzalez, A.M.; Gomez, M.; Barahona, S.; Sepulveda, D.; Espenshade, P.J.; Fernandez-Lobato, M.; Baeza, M.; Cifuentes, V.; et al. Sterol Regulatory Element-Binding Protein (Sre1) Promotes the Synthesis of Carotenoids and Sterols in Xanthophyllomyces dendrorhous. Front. Microbiol. 2019, 10, 586. [Google Scholar] [CrossRef] [PubMed]
- Chang, Y.C.; Bien, C.M.; Lee, H.; Espenshade, P.J.; Kwon-Chung, K.J. Sre1p, a regulator of oxygen sensing and sterol homeostasis, is required for virulence in Cryptococcus neoformans. Mol. Microbiol. 2007, 64, 614–629. [Google Scholar] [CrossRef] [PubMed]
- Chun, C.D.; Liu, O.W.; Madhani, H.D. A link between virulence and homeostatic responses to hypoxia during infection by the human fungal pathogen Cryptococcus neoformans. PLoS Pathog. 2007, 3, e22. [Google Scholar] [CrossRef]
- Bien, C.M.; Espenshade, P.J. Sterol regulatory element binding proteins in fungi: Hypoxic transcription factors linked to pathogenesis. Eukaryot. Cell 2010, 9, 352–359. [Google Scholar] [CrossRef]
- Choi, J.; Chung, H.; Lee, G.W.; Koh, S.K.; Chae, S.K.; Lee, Y.H. Genome-Wide Analysis of Hypoxia-Responsive Genes in the Rice Blast Fungus, Magnaporthe oryzae. PLoS ONE 2015, 10, e0134939. [Google Scholar] [CrossRef] [PubMed]
- Zhao, X.; He, Z.; Gao, Y.; Kan, Y.; Jiao, Y.; Liu, Y.; Huang, S.; Luo, Z.; Zhang, Y. Sterol Regulatory Element-Binding Protein, BbSre1, Controls Oxidative Stress Response, Peroxisome Division, and Lipid Homeostasis in an Insect Fungal Pathogen. J. Agric. Food Chem. 2023, 71, 12250–12263. [Google Scholar] [CrossRef] [PubMed]
- Piombo, E.; Tzelepis, G.; Ruus, A.G.; Rafiei, V.; Jensen, D.F.; Karlsson, M.; Dubey, M. Sterol regulatory element-binding proteins mediate intrinsic fungicide tolerance and antagonism in the fungal biocontrol agent Clonostachys rosea IK726. Microbiol. Res. 2024, 289, 127922. [Google Scholar] [CrossRef] [PubMed]
- Ruan, R.; Chen, Y.; Li, H.; Wang, M. Functional diversification of sterol regulatory element binding proteins following gene duplication in a fungal species. Fungal Genet. Biol. 2019, 131, 103239. [Google Scholar] [CrossRef]
- Ingavale, S.S.; Chang, Y.C.; Lee, H.; McClelland, C.M.; Leong, M.L.; Kwon-Chung, K.J. Importance of mitochondria in survival of Cryptococcus neoformans under low oxygen conditions and tolerance to cobalt chloride. PLoS Pathog. 2008, 4, e1000155. [Google Scholar] [CrossRef]
- Ruan, R.; Wang, M.; Liu, X.; Sun, X.; Chung, K.R.; Li, H. Functional analysis of two sterol regulatory element binding proteins in Penicillium digitatum. PLoS ONE 2017, 12, e0176485. [Google Scholar] [CrossRef] [PubMed]
- Zhang, Y.; Liu, Y.; Jia, C.; Qin, J.; Li, B.; Shi, W.; Zhang, Y.; Hou, J.; Qin, Q.; Zhang, M.; et al. Correction to “The Fungal Transcription Factor BcTbs1 from Botrytis cinerea Promotes Pathogenicity via Host Cellulose Degradation”. J. Agric. Food Chem. 2024, 72, 23643. [Google Scholar] [CrossRef] [PubMed]
- Sun, J.; Sun, C.H.; Chang, H.W.; Yang, S.; Liu, Y.; Zhang, M.Z.; Hou, J.; Zhang, H.; Li, G.H.; Qin, Q.M. Cyclophilin BcCyp2 Regulates Infection-Related Development to Facilitate Virulence of the Gray Mold Fungus Botrytis cinerea. Int. J. Mol. Sci. 2021, 22, 1694. [Google Scholar] [CrossRef]
- Feng, H.Q.; Li, G.H.; Du, S.W.; Yang, S.; Li, X.Q.; de Figueiredo, P.; Qin, Q.M. The septin protein Sep4 facilitates host infection by plant fungal pathogens via mediating initiation of infection structure formation. Environ. Microbiol. 2017, 19, 1730–1749. [Google Scholar] [CrossRef]
- Cao, S.N.; Yuan, Y.; Qin, Y.H.; Zhang, M.Z.; de Figueiredo, P.; Li, G.H.; Qin, Q.M. The pre-rRNA processing factor Nop53 regulates fungal development and pathogenesis via mediating production of reactive oxygen species. Environ. Microbiol. 2018, 20, 1531–1549. [Google Scholar] [CrossRef] [PubMed]
- Mullins, E.D.; Chen, X.; Romaine, P.; Raina, R.; Geiser, D.M.; Kang, S. Agrobacterium-Mediated Transformation of Fusarium oxysporum: An Efficient Tool for Insertional Mutagenesis and Gene Transfer. Phytopathology 2001, 91, 173–180. [Google Scholar] [CrossRef] [PubMed]
- Tang, M.; Wang, Y.; Wang, K.; Zhou, Y.; Zhao, E.; Zhang, H.; Zhang, M.; Yu, H.; Zhao, X.; Li, G. Codon Optimization Enables the Geneticin Resistance Gene to Be Applied Efficiently to the Genetic Manipulation of the Plant Pathogenic Fungus Botrytis cinerea. Plants 2024, 13, 324. [Google Scholar] [CrossRef] [PubMed]
- Chi, M.H.; Park, S.Y.; Lee, Y.H. A Quick and Safe Method for Fungal DNA Extraction. Plant Pathol. J. 2009, 25, 108–111. [Google Scholar] [CrossRef]
- Lecellier, G.; Silar, P. Rapid methods for nucleic acids extraction from Petri dish-grown mycelia. Curr. Genet. 1994, 25, 122–123. [Google Scholar] [CrossRef] [PubMed]
- Barreira, J.C.M.; Oliveira, M.B.P.P.; Ferreira, I.C.F.R. Development of a Novel Methodology for the Analysis of Ergosterol in Mushrooms. Food Anal. Methods 2014, 7, 217–223. [Google Scholar] [CrossRef]
- Quidde, T.; Osbourn, A.; Tudzynski, P. Detoxification of α-tomatine by Botrytis cinerea. Physiol. Mol. Plant Pathol. 1998, 52, 151–165. [Google Scholar] [CrossRef]
Figure 1.
Generations of Botrytis cinerea SRE1 knockout mutants and its genetic complemented strains. (a) Strategy for generation of SRE1 knockout strain Δsre1 via gene replacement approach. WT, the wild-type strain B05.10; pSRE1-ko, SRE1 knockout vector. HPH, the hygromycin resistance gene. (b) Screening of Δsre1 strains. Numbers 1–23 indicate partial selected transformants. PCR amplifications were used for detecting HPH recombination (rec) and SRE1 loss in transformants, respectively, with indicated primers. Up-rec, upstream recombination; down-rec, downstream recombination. (c) Verification of the complemented strain Δsre1-c. (d) Relative SRE1 expression level in the indicated strains determined by quantitative reverse transcription PCR. M, DNA marker D2000. ND, not detected. Data represent means ± standard deviations (SD) from at least three independent experiments. *, ***, significance at p < 0.05, 0.001, respectively.
Figure 1.
Generations of Botrytis cinerea SRE1 knockout mutants and its genetic complemented strains. (a) Strategy for generation of SRE1 knockout strain Δsre1 via gene replacement approach. WT, the wild-type strain B05.10; pSRE1-ko, SRE1 knockout vector. HPH, the hygromycin resistance gene. (b) Screening of Δsre1 strains. Numbers 1–23 indicate partial selected transformants. PCR amplifications were used for detecting HPH recombination (rec) and SRE1 loss in transformants, respectively, with indicated primers. Up-rec, upstream recombination; down-rec, downstream recombination. (c) Verification of the complemented strain Δsre1-c. (d) Relative SRE1 expression level in the indicated strains determined by quantitative reverse transcription PCR. M, DNA marker D2000. ND, not detected. Data represent means ± standard deviations (SD) from at least three independent experiments. *, ***, significance at p < 0.05, 0.001, respectively.
Figure 2.
SRE1 is required for B. cinerea conidiation but dispensable for conidial morphogenesis and germination. (a) Colony of tested strains cultured on PDA at 3 days post inoculation (DPI). (b) Quantification of the colony sizes (determined by the relative colony diameter). (c) Conidiation on CM plates at 12 DPI. (d) Quantification of the relative conidiation of the indicated strains (determined by the relative conidial number per plate). (e) Conidial morphology of tested strains. Bar = 10 μm. (f) Conidial germination of tested strains at 4 h post inoculation (HPI). Bar = 10 μm. Data represent means ± standard deviations (SD) from at least three independent experiments. ***, significance at p < 0.001.
Figure 2.
SRE1 is required for B. cinerea conidiation but dispensable for conidial morphogenesis and germination. (a) Colony of tested strains cultured on PDA at 3 days post inoculation (DPI). (b) Quantification of the colony sizes (determined by the relative colony diameter). (c) Conidiation on CM plates at 12 DPI. (d) Quantification of the relative conidiation of the indicated strains (determined by the relative conidial number per plate). (e) Conidial morphology of tested strains. Bar = 10 μm. (f) Conidial germination of tested strains at 4 h post inoculation (HPI). Bar = 10 μm. Data represent means ± standard deviations (SD) from at least three independent experiments. ***, significance at p < 0.001.
Figure 3.
SRE1 mediates sclerotium production and ergosterol biosynthesis in B. cinerea. (a) Deletion of SRE1 in B. cinerea increases sclerotial production. The tested strains were cultured on CM at 20 °C in darkness and observed at 15 DPI. (b) Quantification of sclerotium production (determined by the relative sclerotial number per plate). (c) Quantification of ergosterol content (determined by the relative ergosterol content per gram of mycelium fresh weight). Data represent means ± standard deviations (SDs) from at least three independent experiments. *, **, ***, significance at p < 0.05, 0.01, 0.001, respectively.
Figure 3.
SRE1 mediates sclerotium production and ergosterol biosynthesis in B. cinerea. (a) Deletion of SRE1 in B. cinerea increases sclerotial production. The tested strains were cultured on CM at 20 °C in darkness and observed at 15 DPI. (b) Quantification of sclerotium production (determined by the relative sclerotial number per plate). (c) Quantification of ergosterol content (determined by the relative ergosterol content per gram of mycelium fresh weight). Data represent means ± standard deviations (SDs) from at least three independent experiments. *, **, ***, significance at p < 0.05, 0.01, 0.001, respectively.
Figure 4.
Deletion of SRE1 increases B. cinerea resistance to antifungal drug imidazole. Conidial suspensions (containing 50 mM glucose) of each strain were treated with 0, 2, 5, and 10 mM imidazole, respectively. Conidial germinations were observed at 4 h post inoculation (HPI).
Figure 4.
Deletion of SRE1 increases B. cinerea resistance to antifungal drug imidazole. Conidial suspensions (containing 50 mM glucose) of each strain were treated with 0, 2, 5, and 10 mM imidazole, respectively. Conidial germinations were observed at 4 h post inoculation (HPI).
Figure 5.
SRE1 is required for B. cinerea virulence but dispensable for its infection cushion formation and penetration. (a) Mycelial plugs of each strain were inoculated on green bean leaves and the lesions were photographically documented at 3 DPI. (b) Conidial suspensions of each strain were inoculated on green bean leaves and the lesions were photographically documented at 3 DPI. (c) Infection cushion formation of tested strains at 20 HPI. (d) Onion epidermis penetration of the test strains at 12 HPI. Successful penetrations are indicated by red arrows. (e) Quantification of lesion size (determined by the relative lesion area per inoculation) caused by the indicated strains on green bean leaves shown in (a). (f) Quantification of penetration (determined per conidium) by the indicated strains on onion epidermis shown in (d). Data represent means ± standard deviations (SDs) from at least three independent experiments. *, ***, significance at p < 0.05, 0.001, respectively.
Figure 5.
SRE1 is required for B. cinerea virulence but dispensable for its infection cushion formation and penetration. (a) Mycelial plugs of each strain were inoculated on green bean leaves and the lesions were photographically documented at 3 DPI. (b) Conidial suspensions of each strain were inoculated on green bean leaves and the lesions were photographically documented at 3 DPI. (c) Infection cushion formation of tested strains at 20 HPI. (d) Onion epidermis penetration of the test strains at 12 HPI. Successful penetrations are indicated by red arrows. (e) Quantification of lesion size (determined by the relative lesion area per inoculation) caused by the indicated strains on green bean leaves shown in (a). (f) Quantification of penetration (determined per conidium) by the indicated strains on onion epidermis shown in (d). Data represent means ± standard deviations (SDs) from at least three independent experiments. *, ***, significance at p < 0.05, 0.001, respectively.
Figure 6.
SRE1 is involved in hypoxia adaptation. (a) Conidial suspensions (containing 50 mM glucose) of each strain were treated with 100 or 200 μM cobalt chloride (CoCl2), a hypoxia-mimicking agent. Conidial germinations were observed at 4 HPI. Germ tubes are indicated by red arrows. (b) Quantification of abnormal conidial germination in hypoxia-mimic with 100 μM CoCl2. (c) Quantification of mycelial biomass cultured in normoxia or in hypoxia-mimic with 100 μM CoCl2. Data represent means ± standard deviations (SD) from at least three independent experiments. **, ***, significance at p < 0.01, 0.001, respectively.
Figure 6.
SRE1 is involved in hypoxia adaptation. (a) Conidial suspensions (containing 50 mM glucose) of each strain were treated with 100 or 200 μM cobalt chloride (CoCl2), a hypoxia-mimicking agent. Conidial germinations were observed at 4 HPI. Germ tubes are indicated by red arrows. (b) Quantification of abnormal conidial germination in hypoxia-mimic with 100 μM CoCl2. (c) Quantification of mycelial biomass cultured in normoxia or in hypoxia-mimic with 100 μM CoCl2. Data represent means ± standard deviations (SD) from at least three independent experiments. **, ***, significance at p < 0.01, 0.001, respectively.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2025 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Yuan, Y.; Cao, S.; Sun, J.; Hou, J.; Zhang, M.; Qin, Q.; Li, G. Sterol Regulatory Element-Binding Protein Sre1 Mediates the Development and Pathogenicity of the Grey Mould Fungus Botrytis cinerea. Int. J. Mol. Sci. 2025, 26, 1365. https://doi.org/10.3390/ijms26031365
AMA Style
Yuan Y, Cao S, Sun J, Hou J, Zhang M, Qin Q, Li G. Sterol Regulatory Element-Binding Protein Sre1 Mediates the Development and Pathogenicity of the Grey Mould Fungus Botrytis cinerea. International Journal of Molecular Sciences. 2025; 26(3):1365. https://doi.org/10.3390/ijms26031365
Chicago/Turabian StyleYuan, Ye, Shengnan Cao, Jiao Sun, Jie Hou, Mingzhe Zhang, Qingming Qin, and Guihua Li. 2025. "Sterol Regulatory Element-Binding Protein Sre1 Mediates the Development and Pathogenicity of the Grey Mould Fungus Botrytis cinerea" International Journal of Molecular Sciences 26, no. 3: 1365. https://doi.org/10.3390/ijms26031365
APA StyleYuan, Y., Cao, S., Sun, J., Hou, J., Zhang, M., Qin, Q., & Li, G. (2025). Sterol Regulatory Element-Binding Protein Sre1 Mediates the Development and Pathogenicity of the Grey Mould Fungus Botrytis cinerea. International Journal of Molecular Sciences, 26(3), 1365. https://doi.org/10.3390/ijms26031365
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
