Endocytic protein Pal1 regulates appressorium formation and is required for full virulence of Magnaporthe oryzae

Endocytosis plays key roles during infection of plant-pathogenic fungi, but its regulatory mechanisms are still largely unknown. Here, we identified a putative endocytosis-related gene, PAL1, which was highly expressed in appressorium of Magnaporthe oryzae, and was found to be important for appressorium formation and maturation. Deletion of PAL1 significantly reduced the virulence of M. oryzae due to defects in appressorial penetration and invasive growth in host cells. The Pal1 protein interacted and colocalized with the endocytosis protein Sla1, suggesting it is involved in endocytosis. The Δpal1 mutant was significantly reduced in appressorium formation, which was recovered by adding exogenous cAMP and 3-isobutyl-1-methylxanthine (IBMX). Moreover, the phosphorylation level of Pmk1 in Δpal1 was also reduced, suggesting Pal1 functions upstream of both the cAMP and Pmk1 signalling pathways. As a consequence, the utilization of glycogen and lipid, appressorial autophagy, actin ring formation, localization of septin proteins, as well as turgor accumulation were all affected in the Δpal1 mutant. Taken together, Pal1 regulates cAMP and the Pmk1 signalling pathway for appressorium formation and maturation to facilitate infection of M. oryzae.     

MoWhi2 regulates appressorium formation and pathogenicity via the MoTor signalling pathway in Magnaporthe oryzae

Magnaporthe oryzae causes rice blast disease, which seriously threatens the safety of food production. Understanding the mechanism of appressorium formation, which is one of the key steps for successful infection by M. oryzae, is helpful to formulate effective control strategies of rice blast. In this study, we identified MoWhi2, the homolog of Saccharomyces cerevisiae Whi2 (Whisky2), as an important regulator that controls appressorium formation in M. oryzae. When MoWHI2 was disrupted, multiple appressoria were formed by one conidium and pathogenicity was significantly reduced. A putative phosphatase, MoPsr1, was identified to interact with MoWhi2 using a yeast two-hybridization screening assay. The knockout mutant ΔMopsr1 displayed similar phenotypes to the ΔMowhi2 strain. Both the ΔMowhi2 and ΔMopsr1 mutants could form appressoria on a hydrophilic surface with cAMP levels increasing in comparison with the wild type (WT). The conidia of ΔMowhi2 and ΔMopsr1 formed a single appressorium per conidium, similar to WT, when the target of rapamycin (TOR) inhibitor rapamycin was present. In addition, compared with WT, the expression levels of MoTOR and the MoTor signalling activation marker gene MoRS3 were increased, suggesting that inappropriate activation of the MoTor signalling pathway is one of the important reasons for the defects in appressorium formation in the ΔMowhi2 and ΔMopsr1 strains. Our results provide insights into MoWhi2 and MoPsr1-mediated appressorium development and pathogenicity by regulating cAMP levels and the activation of MoTor signalling in M. oryzae.     

MoCDC14 is important for septation during conidiation and appressorium formation in Magnaporthe oryzae

As a typical foliar pathogen, appressorium formation and penetration are critical steps in the infection cycle of Magnaporthe oryzae. Because appressorium formation and penetration are closely co‐regulated with the cell cycle, and Cdc14 phosphatases have an antagonistic relationship with cyclin‐dependent kinases (CDKs) on proteins related to mitotic exit and cytokinesis, in this study, we functionally characterized the MoCDC14 gene in M. oryzae. The Mocdc14 deletion mutant showed significantly reduced growth rate and conidiation. It was also defective in septum formation and nuclear distribution. Septation was irregular in Mocdc14 hyphae and hyphal compartments became multi‐nucleate. Mutant conidia often showed incomplete septa or lacked any septum. During appressorium formation, the septum delimiting appressoria from the rest of the germ tubes was often formed far away from the neck of the appressoria or not formed at all. Unlike the wild‐type, some mutant appressoria had more than one nucleus at 24 h. In addition to appressoria, melanization occurred on parts of the germ tubes and conidia, depending on the irregular position of the appressorium‐delimiting septum. The Mocdc14 mutant was also defective in glycogen degradation during appressorium formation and appressorial penetration of intact plant cells. Similar defects in septum formation, melanization and penetration were observed with appressorium‐like structures formed at hyphal tips in the Mocdc14 mutant. Often a long fragment of mutant hyphae was melanized, together with the apical appressorium‐like structures. These results indicate that MoCDC14 plays a critical role in septation, nuclear distribution and pathogenesis in M. oryzae, and correct septum formation during conidiogenesis and appressorium formation requires the MoCdc14 phosphatase.     

CGI-58 facilitates lipolysis on lipid droplets but is not involved in the vesiculation of lipid droplets caused by hormonal stimulation

A lipid droplet (LD)-associated protein, perilipin, is a critical regulator of lipolysis in adipocytes. We previously showed that Comparative Gene Identification-58 (CGI-58), a product of the causal gene of Chanarin-Dorfman syndrome, interacts with perilipin on LDs. In this study, we investigated the function of CGI-58 using RNA interference. Notably, CGI-58 knockdown caused an abnormal accumulation of LDs in both 3T3-L1 preadipocytes and Hepa1 hepatoma cells. CGI-58 knockdown did not influence the differentiation of 3T3-L1 adipocytes but reduced the activity of both basal and cAMP-dependent protein kinase-stimulated lipolysis. In vitro studies showed that CGI-58 itself does not have lipase/esterase activity, but it enhanced the activity of adipose triglyceride lipase. Upon lipolytic stimulation, endogenous CGI-58 was rapidly dispersed from LDs into the cytosol along with small particulate structures. This shift in localization depends on the phosphorylation of perilipin, because phosphorylated perilipin lost the ability to bind CGI-58. During lipolytic activation, LDs in adipocytes vesiculate into micro-LDs. Using coherent anti-Stokes Raman scattering microscopy, we pursued the formation of micro-LDs in single cells, which seemed to occur in cytoplasmic regions distant from the large central LDs. CGI-58 is not required for this process. Thus, CGI-58 facilitates lipolysis in cooperation with perilipin and other factors, including lipases.     

MoOpy2 is essential for fungal development,pathogenicity, and autophagy in Magnaporthe oryzae

The development and pathogenicity of the fungus Magnaporthe oryzae, the causal agent of destructive rice blast disease, require it to perceive external environmental signals. Opy2, an overproduction-induced pheromone-resistant protein 2, is a crucial protein for sensing external signals in Saccharomyces cerevisiae. However, the biological functions of the homologue of Opy2 in M. oryzae are unclear. In this study, we identified that MoOPY2 is involved in fungal development, pathogenicity, and autophagy in M. oryzae. Deletion of MoOPY2 resulted in pleiotropic defects in hyphal growth, conidiation, germ tube extension, appressorium formation, appressorium turgor generation, and invasive growth, therefore leading to attenuated pathogenicity. Furthermore, MoOpy2 participates in the Osm1 MAPK pathway and the Mps1 MAPK pathway by interacting with the adaptor protein Mst50. The interaction sites of Mst50 and MoOpy2 colocalized with the autophagic marker protein MoAtg8 in the preautophagosomal structure sites (PAS). Notably, the ΔMoopy2 mutant caused cumulative MoAtg8 lipidation and rapid GFP-MoAtg8 degradation in response to nitrogen starvation, showing that MoOpy2 is involved in the negative regulation of autophagy activity. Taken together, our study revealed that MoOpy2 of M. oryzae plays an essential role in the orchestration of fungal development, appressorium penetration, autophagy and pathogenesis.     

橡胶树暹罗炭疽菌Zn2Cys6型转录因子CsGcc1的生物学功能

【背景】暹罗炭疽菌（Colletotrichum siamense）是一种重要的病原真菌,可以引起炭疽病,给全球橡胶产业带来巨大的经济损失。Zn₂Cys₆型转录因子是真菌特有的锌指类转录因子,通常参与调控真菌的生长发育过程。【目的】在暹罗炭疽菌中鉴定了一个与稻瘟病菌Gcc1同源的Zn₂Cys₆型转录因子CsGcc1,并研究其功能。【方法】根据同源重组原理构建CsGCC1的基因敲除突变体,并通过营养生长、H₂O₂敏感性、分生孢子产生及萌发、玻璃纸试验和致病性分析,明确CsGcc1的功能。【结果】CsGcc1编码一个含有646个氨基酸的蛋白,而且含有一个GAL4结构域。CsGCC1基因在培养36 h的菌丝及分生孢子中具有较高的表达量。CsGCC1基因敲除突变株营养生长速率降低且对H₂O₂更加敏感。相较于野生型菌株,突变株的分生孢子产量、萌发率及附着胞形成率均降低。此外,CsGCC1的敲除可以明显降低分生孢子的穿透能力,突变株对橡胶叶片的致病力减弱。【结论】Zn₂Cys₆型转录因子CsGcc1参与调控暹罗炭疽菌的营养生长、氧化应激、分生孢子发育及致病性等过程。     

Peroxisomal fission is induced during appressorium formation and is required for full virulence of the rice blast fungus

Peroxisomes are involved in various metabolic processes and are important for virulence in different pathogenic fungi. How peroxisomes rapidly emerge in the appressorium during fungal infection is poorly understood. Here, we describe a gene, PEF1, which can regulate peroxisome formation in the appressorium by controlling peroxisomal fission, and is required for plant infection in the rice blast fungus Magnaporthe oryzae. Targeted deletion of PEF1 resulted in a reduction in virulence and a delay in penetration and invasive growth in host cells. PEF1 was particularly expressed during appressorial development, and its encoding protein was co‐localized with peroxisomes during appressorial development. Compared with the massive vesicle‐shaped peroxisomes formed in the wild‐type appressorium, the Δpef1 mutant could only form stringy linked immature peroxisomes, suggesting that PEF1 was involved in peroxisomal fission during appressorium formation. We also found that the Δpef1 mutant could not utilize fatty acids efficiently, which can improve significantly the expression level of PEF1 and induce peroxisomal fission. As expected, the Δpef1 mutant showed reduced intracellular production of reactive oxygen species (ROS) during appressorium formation and induced ROS accumulation in host cells during infection. Taken together, PEF1‐mediated peroxisomal fission is important for fungal infection by controlling the number of peroxisomes in the appressorium.     

胶孢炭疽菌C2H2型转录因子CgGcp1的生物学功能

【背景】胶孢炭疽菌(Colletotrichum gloeosporioides)可以寄生于多种植物,侵染方式多样,能够引起严重的农业危害。在胶孢炭疽菌中,CgGcp1是一个C2H2型的转录因子,关于其生物学功能的研究未见报道。【目的】明确CgGcp1的生物学功能,为深入解析该病菌的致病机制奠定一定的理论依据。【方法】构建CgGCP1基因的敲除载体,利用同源重组得到敲除突变体。通过表型分析,包括营养生长、胁迫响应、孢子产生、附着胞形成及致病性分析等,明确该基因的生物学功能。【结果】CgGCP1基因敲除突变体生长速率较野生型减慢,对SDS、刚果红、NaCl和甘油更加敏感,孢子产量显著降低,附着胞的形成率降低且侵入能力减弱,在橡胶叶片上的致病力明显下降。【结论】CgGcp1参与调控胶孢炭疽菌营养生长、细胞壁完整性、分生孢子产生、附着胞形成与侵入和致病性。     

Effects of ultraviolet radiation, simulated or as natural sunlight, on conidium germination and appressorium formation by fungi with potential as mycoherbistats

Solar radiation, particularly its UV wavelengths, greatly influences conidium survival and this study looked at the impact of radiation and its interactions with temperature on Plectosporium alismatis and Colletotrichum orbiculare, two fungi that are potential mycoherbistats. UV radiation, rather than temperature, was found to be the primary cause of conidium mortality; however, there were interactions between these factors leading to the enhancement of the lethal effects of UVB on conidium germination at high temperatures. C. orbiculare was more sensitive than P. alismatis with conidium germination being halved by UVB doses of 1.47 and 13.1 kJ m^-2, respectively, for the two pathogens. Conidium mortality was dose-dependent and for P. alismatis exposed to a dose of 3.7 kJ m^-2 reciprocity was observed. However, for C. orbiculare equivalent doses were not reciprocal as higher doses for short periods were more lethal than lower doses of longer duration. Low UVB doses only caused delays in conidium germination, whereas higher doses killed conidia and caused delays in the germination of any survivors. Radiation also affected appressorium formation. Appressorium formation was stimulated by UVA and was dose dependent with P. alismatis requiring a higher dose than C. orbiculare to initiate formation. Microcycle conidiation by P. alismatis was observed following exposure to sunlight. This knowledge of how conidia of these potential mycoherbistats react to climate suggests that rapid conidium germination and appressorium formation could be achieved by manipulation of the time at which they are applied in the field. Conidia could be applied so that they receive sufficient UVA to stimulate appressorium formation but without receiving a dose that would significantly affect conidium germination. However, for this, additional protection from UVB may be needed.     

Structure of a CGI-58 Motif Provides the Molecular Basis of Lipid Droplet Anchoring

Triacylglycerols (TGs) stored in lipid droplets (LDs) are hydrolyzed in a highly regulated metabolic process called lipolysis to free fatty acids that serve as energy substrates for β-oxidation, precursors for membrane lipids and signaling molecules. Comparative gene identification-58 (CGI-58) stimulates the enzymatic activity of adipose triglyceride lipase (ATGL), which catalyzes the hydrolysis of TGs to diacylglycerols and free fatty acids. In adipose tissue, protein-protein interactions between CGI-58 and the LD coating protein perilipin 1 restrain the ability of CGI-58 to activate ATGL under basal conditions. Phosphorylation of perilipin 1 disrupts these interactions and mobilizes CGI-58 for the activation of ATGL. We have previously demonstrated that the removal of a peptide at the N terminus (residues 10–31) of CGI-58 abrogates CGI-58 localization to LDs and CGI-58-mediated activation of ATGL. Here, we show that this tryptophan-rich N-terminal peptide serves as an independent LD anchor, with its three tryptophans serving as focal points of the left (harboring Trp²¹ and Trp²⁵) and right (harboring Trp²⁹) anchor arms. The solution state NMR structure of a peptide comprising the LD anchor bound to dodecylphosphocholine micelles as LD mimic reveals that the left arm forms a concise hydrophobic core comprising tryptophans Trp²¹ and Trp²⁵ and two adjacent leucines. Trp²⁹ serves as the core of a functionally independent anchor arm. Consequently, simultaneous tryptophan alanine permutations in both arms abolish localization and activity of CGI-58 as opposed to tryptophan substitutions that occur in only one arm.     

Scanning electron microscopy of the conidia produced by the mycelial form of Paracoccidioides brasiliensis

The conidia produced by the mycelial form of Paracoccidioides brasiliensis were examined by scanning electron microscopy for the first time. Several different conidial types were characterized. These included intercalary arthroconidia, several types of septate conidia that are formed from other conidia, pedunculate conidia, and terminal hyphal conidia. In addition, the ultrastructure of the supporting pedestal of the pedunculate conidium was found to be separated from the mother conidium by a septum in some instances, and at other times it was not.     

Participation of Oryza sativa leaf wax in appressorium formation by Pyricularia oryzae

Appressorium formation of Pyricularia oryzae P2 on cover-glass coated with each of the components of rice leaf wax was examined. Wax esters, aldehydes and alcohols, having polar groups and low contact angles, promoted appressorium formation, but alkanes, non-polar molecules having high contact angles, had no effects. Germination of conidia, however, was not aftected with those constituents.     

The MAP1-LC3 conjugation system is involved in lipid droplet formation

Lipid droplets (LDs) are ubiquitous in eukaryotic cells, while excess free fatty acids and glucose in plasma are converted to triacylglycerol (TAG) and stored as LDs. However, the mechanism for the generation and growth of LDs in cells is largely unknown. We show here that the LC3 lipidation system essential for macroautophagy is involved in LD formation. LD formation accompanied by accumulation of TAG induced by starvation was largely suppressed in the hepatocytes that cannot execute autophagy. Under starvation conditions, LDs in addition to autophagosomes were abundantly formed in the cytoplasm of these tissue cells. Moreover, LC3 was localized on the surface of LDs and LC3-II (lipidation form) was fractionated to a perilipin (LD marker)-positive lipid fraction from the starved liver. Taken together, these results indicate that the LC3 conjugation system is critically involved in lipid metabolism via LD formation.     

MoSNF1 regulates sporulation and pathogenicity in the rice blast fungus Magnaporthe oryzae

The protein kinase Snf1 is a major component of the glucose derepression pathway in yeast and a regulator of gene expression for the cell wall degrading enzyme (CWDE) in some plant pathogenic fungi. To address the molecular function of Snf1 in Magnaporthe oryzae, which causes the rice blast disease, MoSNF1 was cloned and functionally characterized using gene knock-out strategies. MoSNF1 functionally complemented the growth defect of the yeast snf1 mutant on a non-fermenting carbon source. However, the growth rate of the Δmosnf1 mutant on various carbon sources was reduced independent of glucose, and the expression of the CWDE genes in the mutant was induced during derepressing condition like the wild type. The pre-penetration stage including conidial germination and appressorium formation of the Δmosnf1 was largely impaired, and the pathogenicity of the Δmosnf1 was significantly reduced. Most strikingly, the Δmosnf1 mutant produced only a few conidia and had a high frequency of abnormally shaped conidia compared to the wild type. Our results suggest that MoSNF1 is a functional homolog of yeast Snf1, but its contribution to sporulation, vegetative growth and pathogenicity is critical in M. oryzae.     

Unique regulation of adipose triglyceride lipase (ATGL) by perilipin 5, a lipid droplet-associated protein

Lipolysis is a critical metabolic pathway contributing to energy homeostasis through degradation of triacylglycerides stored in lipid droplets (LDs), releasing fatty acids. Neutral lipid lipases act at the oil/water interface. In mammalian cells, LD surfaces are coated with one or more members of the perilipin protein family, which serve important functions in regulating lipolysis. We investigated mechanisms by which three perilipin proteins control lipolysis by adipocyte triglyceride lipase (ATGL), a key lipase in adipocytes and non-adipose cells. Using a cell culture model, we examined interactions of ATGL and its co-lipase CGI-58 with perilipin 1 (perilipin A), perilipin 2 (adipose differentiation-related protein), and perilipin 5 (LSDP5) using multiple techniques as follows: anisotropy Forster resonance energy transfer, co-immunoprecipitation, [(32)P]orthophosphate radiolabeling, and measurement of lipolysis. The results show that ATGL interacts with CGI-58 and perilipin 5; the latter is selectively expressed in oxidative tissues. Both proteins independently recruited ATGL to the LD surface, but with opposite effects; interaction of ATGL with CGI-58 increased lipolysis, whereas interaction of ATGL with perilipin 5 decreased lipolysis. In contrast, neither perilipin 1 nor 2 interacted directly with ATGL. Activation of protein kinase A (PKA) increased [(32)P]orthophosphate incorporation into perilipin 5 by 2-fold, whereas neither ATGL nor CGI-58 was labeled under the incubation conditions. Cells expressing both ectopic perilipin 5 and ATGL showed a 3-fold increase in lipolysis following activation of PKA. Our studies establish perilipin 5 as a novel ATGL partner and provide evidence that the protein composition of perilipins at the LD surface regulates lipolytic activity of ATGL.     

Identification and functional characterization of a lipid droplet protein CtLDP1 from an oleaginous yeast Candida tropicalis SY005

Proteins residing in lipid droplets (LDs) of organisms exhibit diverse physiological roles. Since the LD proteins of yeasts are largely unexplored, we have identified a putative LD protein gene, CtLDP1 in the oleaginous yeast Candida tropicalis SY005 and characterized its function. The increased lipid accumulation in SY005 could be correlated with enhanced (~2.67-fold) expression of the CtLDP1 after low-nitrogen stress. The N-terminal transmembrane domain similar to perilipin proteins and the amphipathic α-helices predicted in silico, presumably aid in targeting the CtLDP1 to LD membranes. Heterologous expression of CtLDP1-mCherry fusion in Saccharomyces cerevisiae revealed localization in LDs, yet the expression of CtLDP1 did not show significant effect on LD formation in transformed cells. Molecular docking showed favourable interactions of the protein with sterol class of molecules, but not with triacylglycerol (TAG); and this was further experimentally verified by co-localization of the mCherry-tagged protein in TAG-deficient (but steryl ester containing) LDs. While oleic acid supplementation caused coalescence of LDs into supersized ones (average diameter = 1.19 ± 0.12 μm; n = 160), this effect was suppressed due to CtLDP1 expression, and the cells mostly exhibited numerous smaller LDs (average diameter = 0.46 ± 0.05 μm; n = 160). Moreover, CtLDP1 expression in pet10Δ knockout strain of S. cerevisiae restored multiple LD formation, indicating functional complementation of the protein. Overall, this study documents functional characterization of an LD-stabilizing protein from an oleaginous strain of Candida genus for the first time, and provides insights on the characteristics of LD proteins in oleaginous yeasts for future metabolic engineering.