Major Fungal Pathogen Research Articles

Whole Genome Sequencing and Comparative Genomic Analysis of Pseudomonas aeruginosa SF416, a Potential Broad-Spectrum Biocontrol Agent Against Xanthomonas oryzae pv. oryzae

Rice is one of the most important staple crops worldwide. However, the bacterial blight of rice caused by Xanthomonas oryzae pv. oryzae (Xoo) poses a major threat to the production of rice. In this study, we isolated and identified the strain Pseudomonas aeruginosa SF416, which exhibited significant antagonistic activity against Xoo, from a soil sample collected in a winter wheat field in Shannanzhalang County, Tibet, China. The bacterial solution (BS) and cell-free supernatant (CFS) of SF416 had significant prevention effects for the bacterial blight of rice, with an efficacy of 45.1% and 34.18%, respectively, while they exhibited a slightly lower therapeutic efficiency of 31.64% and 25.09%. The genomic analysis showed that P. aeruginosa SF416 contains genes involved in cell motility, colonization, cold and hot shock proteins, antibiotic resistance, and plant growth promotion. SF416 also harbors two sets of phenazine-1-carboxylic acid (PCA) synthesis gene clusters, phz1 (phzA1-G1) and phz2 (phzA2-G2), and other phenozine product-synthesis--related genes phzS, phzM, and phzH, as well as genes in the SF416 genome that share high similarity with the ones in the genomes of P. aeruginosa M18, suggesting that the two sets of PCA synthesis gene clusters are responsible for the antagonistic effect of SF416 against Xoo. A comparative antiSMASH analysis revealed that P. aeruginosa SF416 contains 17 gene clusters related to secondary metabolite synthesis, 7 of which, encoding for pyochelin, azetidomonamide A/B, L-2-amino-4-methoxy-trans-3-butenoic acid, hydrogen cyanide, pyocyanine, pseudopaline, and bicyclomycin, are conserved in strains of P. aeruginosa. Moreover, SF416 can produce protease and siderophores and display a broad-spectrum antagonistic activity against various major plant pathogenic bacteria and fungi. The results suggest that P. aeruginosa SF416 could be a potential candidate agent for the bacterial blight of rice.

Adaptation of Candida albicans to specific host environments by gain-of-function mutations in transcription factors.

The yeast Candida albicans is usually a harmless member of the normal microbiota in healthy persons but is also a major fungal pathogen that can colonize and infect almost every human tissue. A successful adaptation to environmental changes encountered in different host niches requires an appropriate regulation of gene expression. The zinc cluster transcription factors are the largest family of transcriptional regulators in C. albicans and are involved in the control of virtually all aspects of its biology. Under certain circumstances, mutations in these transcription factors that alter their activity and the expression of their target genes confer a selective advantage, which results in the emergence of phenotypically altered variants that are better adapted to new environmental challenges. This review describes how gain-of-function mutations in different zinc cluster transcription factors enable C. albicans to overcome antifungal therapy and to successfully establish itself in specific host niches.

Effectiveness of plant extracts against Alternaria leaf blight (Alternaria alternata) infecting tomato

Tomato (Lycopersicon esculentum Mill.) is one of the most remunerative and widely grown vegetables in the world. This crop is affected by major fungal pathogens (viz., early blight, late blight, wilt, collar rot, damping off and powdery mildew), among them early blight (Alternaria alternata) is considered as most important one. Among the phyto-extracts tested, the majority were found effective in inhibiting the radial growth of test fungus and highest inhibition was in neem, garlic and turmeric extracts at 10 % concentration which recorded 80.86, 79.34 and 75.24 % inhibition, respectively.

Effectiveness of systemic fungicides against tomato early blight (Alternaria alternata)

Tomato (Lycopersicon esculentum Mill.) is one of the most remunerative and widely grown vegetables in the world. This crop is affected by major fungal pathogens (viz., early blight, late blight, wilt, collar rot, damping off and powdery mildew), among them early blight (Alternaria alternata) is considered as most important one. Among the fungicide tested, the majority were found effective in inhibiting the radial growth of test fungus and highest inhibition was observed in propiconazole 25 EC at 250 and 500 ppm concentration; difenoconazole 25 EC and tebuconazole 25.9 EC at 500 ppm concentration which were equally effective and completely inhibited the mycelial growth and proved significantly superior over rest of the treatments.

Improved Broad Spectrum Antifungal Drug Synergies with Cryptomycin, a Cdc50-Inspired Antifungal Peptide.

Fungal infections in humans are difficult to treat, with very limited drug options. Due to a confluence of factors, there is an urgent need for innovation in the antifungal drug space, particularly to combat increasing antifungal drug resistance. Our previous studies showed that Cdc50, a subunit of fungal lipid translocase (flippase), is essential for Cryptococcus neoformans virulence and required for antifungal drug resistance, suggesting that fungal lipid flippase could be a novel drug target. Here, we characterized an antifungal peptide, Cryptomycinamide (KKOO-NH2), derived from a 9-amino acid segment of the C. neoformans Cdc50 protein. A fungal killing assay indicated that KKOO-NH2 is fungicidal against C. neoformans. The peptide has antifungal activity against multiple major fungal pathogens with a minimum inhibitory concentration (MIC) of 8 μg/mL against C. neoformans and Candida glabrata, 16 μg/mL against Candida albicans and C. auris, and 32 μg/mL against Aspergillus fumigatus. The peptide has low cytotoxicity against host cells based on our hemolysis assays and vesicle leakage assays. Strikingly, the peptide exhibits strong drug synergy with multiple antifungal drugs, including amphotericin B, itraconazole, and caspofungin, depending on the specific species on which the combinations were assayed. The fluorescently labeled peptide was detected to localize to the plasma membrane, likely inhibiting key interactions of Cdc50 with membrane proteins such as P4 ATPases. Cryptococcus cells exposed to sub-MIC of peptide showed increased reactive oxygen species production and intracellular calcium levels, indicating a peptide-induced stress response. Decreased intracellular proliferation within macrophages was observed after 30 min of peptide exposure and 24 h coincubation with macrophages, providing a potential translational mechanism to explore further in vivo. In aggregate, the synergistic activity of our KKOO-NH2 peptide may offer a potential novel candidate for combination therapy with existing antifungal drugs.

Development of a Multiplex PCR Assay to Detect Neofusicoccum parvum and Botryosphaeria dothidea in Walnut.

In walnut orchards, frequent symptoms of cankers and dieback (fruit blight, twig and branch cankers up to tree death) are caused by different agents, in particular by Botryosphaeriaceae, primarily Neofusicoccum parvum and Botryosphaeria dothidea. This study aimed at developing a sensitive, rapid, specific and internally controlled multiplex PCR assay for the detection of these species. The ability of the multiplex PCR, with an internal inhibition control (i.e. E. coli DNA), to specifically and successfully detect members of the two targeted species was validated using 11 different isolates for each fungal target (inclusivity) and 20 tree-associated fungal species different from B. dothidea or N. parvum (exclusivity). Applicability to plant materials was further investigated and showed an absence of amplification for asymptomatic husk or twig samples while the amplification profiles of symptomatic tissues ranged from no amplification to amplification of both species, in correlation with the observed fungal contamination level. In conclusion, we developed a rapid diagnostic tool for simultaneous detection of two major fungal pathogens of walnut. Although this protocol was tailored for walnut husks and twigs, applicability to any plant sample contaminated by these pathogens can be considered.

Giant transposons promote strain heterogeneity in a major fungal pathogen.

No "one size fits all" option exists for treating fungal infections in large part due to genetic and phenotypic variation among strains. Accounting for strain heterogeneity is thus fundamental for developing efficacious treatments and strategies for safeguarding human health. Here, we report significant progress towards achieving this goal by uncovering a previously hidden mechanism generating heterogeneity in the major human fungal pathogen Aspergillus fumigatus : giant transposons called Starships that span dozens of kilobases and mobilize fungal genes as cargo. By conducting the first systematic investigation of these unusual transposons in a single fungal species, we demonstrate their contributions to population-level variation at the genome, pangenome and transcriptome levels. The Starship atlas we developed will not only help account for variation introduced by these elements in laboratory experiments but will serve as a foundational resource for determining how Starships shape clinically-relevant phenotypes, such as antifungal resistance and pathogenicity.

Molecular identification and morphological characterisation of multiple fungal pathogens of triticale in Northern Kazakhstan

Background and Aim. Тtriticale is classified as an amphidiploids and is the first grain crop created by humans, possessing high yield potential along with favorable biochemical and technological characteristics. For a long time, it was believed that triticale, during selection, inherited disease resistance from wheat and resistance to abiotic factors from rye. However, in recent years, there have been several reports that triticale is to fungal diseases, which reduces the quality of the harvested crop. The aim of our study is to examine and characterize the fungal pathogens of triticale in Northern Kazakhstan, and conduct molecular-genetic identification of the main fungal pathogens.MaterialsandMethods. The study was conducted of triticale from two varieties, Dauren and Rossika. Primary fungal isolation was carried out on agarized nutrient media, with preliminary identification using microscopy. Molecular genetic analysis was performed to determine the species of fungi. Results. During the study, we isolated five major fungal pathogens from different parts of the plant. Data on the percentage of infection by the main fungal pathogens were provided. Three of them are pathogens of alternariosis – Alternaria alternate (more common in grains 39%, in leaves and scales of seeds 19-21%), fusariosis – Fusarium tricinctum (occurrence: in roots 57%, in grains 17%, in leaves 10%) and helminthosporiosis – Bipolaris sorokiniana (occurrence in roots and leaves 0.83%) of grain crops, which can lead to a decrease and loss of yield due to their production of mycotoxins. A cultural and morphological description of the main fungal pathogens of grain crops was provided. Moleculargenetic identification was carried out using the ribosomal marker ITS (internal transcribed spacer).Conclusion. According to result of our research, we characterized and molecular-genetically identified the most common fungi found on different parts of the triticale plant.

Regulatory insight for a Zn2Cys6 transcription factor controlling effector-mediated virulence in a fungal pathogen of wheat.

The regulation of virulence in plant-pathogenic fungi has emerged as a key area of importance underlying host infections. Recent work has highlighted individual transcription factors (TFs) that serve important roles. A prominent example is PnPf2, a member of the Zn2Cys6 family of fungal TFs, which controls the expression of effectors and other virulence-associated genes in Parastagonospora nodorum during infection of wheat. PnPf2 orthologues are similarly important for other major fungal pathogens during infection of their respective host plants, and have also been shown to control polysaccharide metabolism in model saprophytes. In each case, the direct genomic targets and associated regulatory mechanisms were unknown. Significant insight was made here by investigating PnPf2 through chromatin-immunoprecipitation (ChIP) and mutagenesis approaches in P. nodorum. Two distinct binding motifs were characterised as positive regulatory elements and direct PnPf2 targets identified. These encompass known effectors and other components associated with the P. nodorum pathogenic lifestyle, such as carbohydrate-active enzymes and nutrient assimilators. The results support a direct involvement of PnPf2 in coordinating virulence on wheat. Other prominent PnPf2 targets included TF-encoding genes. While novel functions were observed for the TFs PnPro1, PnAda1, PnEbr1 and the carbon-catabolite repressor PnCreA, our investigation upheld PnPf2 as the predominant transcriptional regulator characterised in terms of direct and specific coordination of virulence on wheat, and provides important mechanistic insights that may be conserved for homologous TFs in other fungi.

Manipulation of host phagocytosis by fungal pathogens and therapeutic opportunities.

An important host defence mechanism against pathogens is intracellular killing, which is achieved through phagocytosis, a cellular process for engulfing and neutralizing extracellular particles. Phagocytosis results in the formation of matured phagolysosomes, which are specialized compartments that provide a hostile environment and are considered the end point of the degradative pathway. However, all fungal pathogens studied to date have developed strategies to manipulate phagosomal function directly and also indirectly by redirecting phagosomes from the degradative pathway to a non-degradative pathway with the expulsion and even transfer of pathogens between cells. Here, using the major human fungal pathogens Aspergillus fumigatus, Candida albicans, Cryptococcus neoformans and Histoplasma capsulatum as examples, we discuss the processes involved in host phagosome-fungal pathogen interactions, with a focus on fungal evasion strategies. We also discuss recent approaches to targeting intraphagosomal pathogens, including the redirection of phagosomes towards degradative pathways for fungal pathogen eradication.

The putative prenyltransferase Nus1 is required for filamentation in the human fungal pathogen Candida albicans.

Candida albicans is a major fungal pathogen of humans that can cause serious systemic infections in vulnerable immunocompromised populations. One of its virulence attributes is its capacity to transition between yeast and filamentous morphologies, but our understanding of this process remains incomplete. Here, we analyzed data from a functional genomic screen performed with the C. albicans Gene Replacement And Conditional Expression collection to identify genes crucial for morphogenesis in host-relevant conditions. Through manual scoring of microscopy images coupled with analysis of each image using a deep learning-based method termed Candescence, we identified 307 genes important for filamentation in tissue culture medium at 37°C with 5% CO2. One such factor was orf19.5963, which is predicted to encode the prenyltransferase Nus1 based on sequence homology to Saccharomyces cerevisiae. We further showed that Nus1 and its predicted interacting partner Rer2 are important for filamentation in multiple liquid filament-inducing conditions as well as for wrinkly colony formation on solid agar. Finally, we highlight that Nus1 and Rer2 likely govern C. albicans morphogenesis due to their importance in intracellular trafficking, as well as maintaining lipid homeostasis. Overall, this work identifies Nus1 and Rer2 as important regulators of C. albicans filamentation and highlights the power of functional genomic screens in advancing our understanding of gene function in human fungal pathogens.

Step-wise evolution of azole resistance through copy number variation followed by KSR1 loss of heterozygosity in Candida albicans.

Antimicrobial drug resistance poses a global health threat, requiring a deeper understanding of the evolutionary processes that lead to its emergence in pathogens. Complex evolutionary dynamics involve multiple mutations that can result in cooperative or competitive (clonal interference) effects. Candida albicans, a major fungal pathogen, displays high rates of copy number variation (CNV) and loss of heterozygosity (LOH). CNV and LOH events involve large numbers of genes and could synergize during evolutionary adaptation. Understanding the contributions of CNV and LOH to antifungal drug adaptation is challenging, especially in the context of whole-population genome sequencing. Here, we document the sequential evolution of fluconazole tolerance and then resistance in a C. albicans isolate involving an initial CNV on chromosome 4, followed by an LOH on chromosome R that involves KSR1. Similar LOH events involving KSR1, which encodes a reductase in the sphingolipid biosynthesis pathway, were also detected in independently evolved fluconazole resistant isolates. We dissect the specific KSR1 codons that affect fluconazole resistance and tolerance. The combination of the chromosome 4 CNV and KSR1 LOH results in a >500-fold decrease in azole susceptibility relative to the progenitor, illustrating a compelling example of rapid, yet step-wise, interplay between CNV and LOH in drug resistance evolution.

A Brg1-Rme1 circuit in Candida albicans hyphal gene regulation.

Major Candida albicans virulence traits include its ability to make hyphae, to produce a biofilm, and to damage host cells. These traits depend upon expression of hypha-associated genes. A gene expression comparison among clinical isolates suggested that transcription factor Rme1, established by previous studies to be a positive regulator of chlamydospore formation, may also be a negative regulator of hypha-associated genes. Engineered RME1 overexpression supported this hypothesis, but no relevant rme1Δ/Δ mutant phenotype was detected. We reasoned that Rme1 may function within a specific regulatory pathway. This idea was supported by our finding that an rme1Δ/Δ mutation relieves the need for biofilm regulator Brg1 in biofilm formation. The impact of the rme1Δ/Δ mutation is most prominent under static or "biofilm-like" growth conditions. RNA sequencing (RNA-seq) of cells grown under biofilm-like conditions indicates that Brg1 activates hypha-associated genes indirectly via repression of RME1: hypha-associated gene expression levels are substantially reduced in a brg1Δ/Δ mutant and partially restored in a brg1Δ/Δ rme1Δ/Δ double mutant. An rme1Δ/Δ mutation does not simply bypass Brg1, because iron homeostasis genes depend upon Brg1 regardless of Rme1. Rme1 thus connects Brg1 to the targets relevant to hypha and biofilm formation under biofilm growth conditions.IMPORTANCECandida albicans is a major fungal pathogen of humans, and its ability to grow as a surface-associated biofilm on implanted devices is a common cause of infection. Here, we describe a new regulator of biofilm formation, RME1, whose activity is most prominent under biofilm-like growth conditions.

Efficacy of Commercial Biocontrol Products for the Management of Verticillium and Fusarium Wilt in Greenhouse Tomatoes: Impact on Disease Severity, Fruit Yield, and Quality

Verticillium dahliae (Vd) and Fusarium oxysporum f. sp. lycopersici (Fol) are two major fungal pathogens that infect tomato plants, causing significant challenges in their control since both pathogens can persist in the soil for several years even in the absence of a host plant and no effective fungicides are available at present. This study investigated the efficacy of two biocontrol formulations, Clonotri (containing Trichoderma and Clonostachys microorganisms) and Strepse (comprising Streptomyces and Pseudomonas microorganisms), against Vd and Fol and their impact on tomato fruit quality and yield under greenhouse conditions. The pathogenicity experiment demonstrated that the Clonotri formulation, containing Trichoderma and Clonostachys spores, significantly reduced Fusarium wilt disease by 32% compared to the control group. However, in the Vd pathogenicity experiment, the formulations did not exhibit disease reduction, although treatment with Strepse, containing Streptomyces and Pseudomonas microorganisms, resulted in a preserved total fruit number when compared to uninfected plants. Analysis of fruit quality attributes revealed no significant differences among the various interventions. Furthermore, Fol infection in the first fruit set significantly increased fruit firmness, while Vd infection resulted in elevated levels of total soluble solids in fruits. These findings demonstrate that the evaluated biocontrol formulations provide a degree of protection against fungal wilt pathogens in tomato plants and can increase yield in greenhouse conditions while having minimal impact on overall fruit quality attributes.

Determining the Main Infection Courts in Sweet Cherry Trees of the Canker Pathogens Calosphaeria pulchella, Cytospora sorbicola, and Eutypa lata.

The major fungal canker pathogens causing branch dieback of sweet cherry trees in California include Calosphaeria pulchella, Cytospora sorbicola, and Eutypa lata. These pathogens have long been known to infect cherry trees mainly through pruning wounds. However, recent field observations revealed numerous shoots and fruiting spurs exhibiting dieback symptoms with no apparent pruning wounds or mechanical injuries. Accordingly, this study was conducted to assess the incidence of the three pathogens in symptomatic terminal shoots and dying fruiting spurs, in addition to the wood below pruning wounds in branches. Surveys were conducted in five sweet cherry orchards across three counties in California. We also investigated the possibility that leaf scars, bud scars, and wounds resulting from fruit picking could serve as infection courts for Cal. pulchella, Cyt. sorbicola, and E. lata by means of artificial inoculations in the field. Orchard surveys revealed that Cal. pulchella had the highest pathogen incidence below pruning wounds in branch samples, followed by Cyt. sorbicola and E. lata. Among terminal shoots with dieback symptoms and dying fruiting spurs, Cyt. sorbicola was the most prevalent, followed by Cal. pulchella. Results from field inoculations indicated that fruit-picking wounds could serve as important infection courts for Cal. pulchella, Cyt. sorbicola, and E. lata, with average pathogen recovery of 41.5, 63, and 36.2%, respectively. Results also indicated that leaf and bud scars could serve as an entry site for Cyt. sorbicola, although recovery was relatively low. The present study is the first to identify harvest-induced wounds on fruiting spurs of sweet cherry as an important infection court of Cal. pulchella, Cyt. sorbicola, and E. lata.

Genome-wide patterns of noncoding and protein-coding sequence variation in the major fungal pathogen Aspergillus fumigatus.

Aspergillus fumigatus is a deadly fungal pathogen, responsible for >400,000 infections/year and high mortality rates. A. fumigatus strains exhibit variation in infection-relevant traits, including in their virulence. However, most A. fumigatus protein-coding genes, including those that modulate its virulence, are shared between A. fumigatus strains and closely related nonpathogenic relatives. We hypothesized that A. fumigatus genes exhibit substantial genetic variation in the noncoding regions immediately upstream to the start codons of genes, which could reflect differences in gene regulation between strains. To begin testing this hypothesis, we identified 5,812 single-copy orthologs across the genomes of 263 A. fumigatus strains. In general, A. fumigatus noncoding regions showed higher levels of sequence variation compared with their corresponding protein-coding regions. Focusing on 2,482 genes whose protein-coding sequence identity scores ranged between 75 and 99%, we identified 478 total genes with signatures of positive selection only in their noncoding regions and 65 total genes with signatures only in their protein-coding regions. Twenty-eight of the 478 noncoding regions and 5 of the 65 protein-coding regions under selection are associated with genes known to modulate A. fumigatus virulence. Noncoding region variation between A. fumigatus strains included single-nucleotide polymorphisms and insertions or deletions of at least a few nucleotides. These results show that noncoding regions of A. fumigatus genes harbor greater sequence variation than protein-coding regions, raising the hypothesis that this variation may contribute to A. fumigatus phenotypic heterogeneity.

Distribution and Etiology of Gummosis Syndrome Associated with Apricot Fruit Trees of Gilgit-Baltistan, Pakistan

Gummosis syndrome is a serious disease of apricot trees in Gilgit Baltistan (GB), Pakistan. The symptoms of gummosis syndrome on branches, twigs, and the trunk of apricot trees include oozing of a gummy or resinous material, lesions or cankers, bark discoloration, and the disintegration of bark integrity. The disease can weaken branches and twigs, making them more susceptible to breakage. In severe cases, affected branches can die back. In this study, we investigated the fungal species associated with gummosis syndrome in apricots across four districts in GB: Nagar, Hunza, Gilgit, and Ghizer. We recovered a total of 40 isolates from different locations of above four districts, and the most frequently isolated fungal species was Botryodiplodia theobromae. Fusarium solani was also isolated from several locations, and Neoscytalidium spp. were isolated from a few locations in Nagar and Hunza. The spatial distribution of gummosis syndrome in apricots in GB is not uniform. The disease is more prevalent in the northern and western parts of GB, and in areas with higher elevations and cooler temperatures. The Nagar district is the most affected by gummosis syndrome, followed by Ghizer District. Our findings suggest that Botryodiplodia theobromae is the major fungal pathogen associated with gummosis syndrome in apricots in GB. Fusarium solani and Neoscytalidium spp. may also play a role in the disease. The spatial distribution of gummosis syndrome in GB suggests that environmental factors, such as elevation and temperature, may contribute to the disease. Further research is needed to develop effective control measures for gummosis syndrome in apricots in GB. This research should focus on identifying resistant apricot varieties, developing new and more effective fungicides, and developing integrated pest management (IPM) programs.

Riboflavin alleviates the occurrence of anthracnose caused by Colletotrichum gloeosporioides in postharvest mango and the possible mechanisms involved

Colletotrichum gloeosporioides is a major pathogenic fungus that causes anthracnose in stored mangoes, and it exhibits higher pathogenicity compared to Colletotrichum acutatum. This study primarily investigates the mechanism by which riboflavin prevents mango anthracnose caused by Colletotrichum gloeosporioides. In vitro experiments demonstrated that a concentration of 1.0 mmol L−1 riboflavin exhibited a strong inhibitory effect on spore germination of Colletotrichum gloeosporioides strains isolated from different major mango-producing regions in China, surpassing the efficacy of the chemical agent pyrimethanil. Furthermore, mango fruits infected with Colletotrichum gloeosporioides and treated with 1.0 mmol L−1 riboflavin exhibited a significant reduction in disease index. The mechanism behind this is that riboflavin not only generated reactive oxygen species (ROS) but also induced the production of ROS in the fruit during the early stages of storage, directly killing Colletotrichum gloeosporioides. Additionally, riboflavin activated phenylalanine ammonia lyase (PAL) and peroxidase (POD), leading to the production of total phenols and lignin, enhancing the fruit's disease resistance. Riboflavin also increased the activity of β-1,3-glucanase (GLU) and chitinase (CHI), which can disrupt the cell wall of Colletotrichum gloeosporioides. Moreover, riboflavin enhanced the activity of superoxide dismutase (SOD) and catalase (CAT) in the fruit, reducing weight loss percentage and minimizing the degradation of total soluble solids (TSS). These findings highlight the efficacy of riboflavin in preventing and controlling mango anthracnose.

Sandalwood Oils of Different Origins Are Active In Vitro against Madurella mycetomatis, the Major Fungal Pathogen Responsible for Eumycetoma.

In the search for new bioactive agents against the infectious pathogen responsible for the neglected tropical disease (NTD) mycetoma, we tested a collection of 27 essential oils (EOs) in vitro against Madurella mycetomatis, the primary pathogen responsible for the fungal form of mycetoma, termed eumycetoma. Among this series, the EO of Santalum album (Santalaceae), i.e., East Indian sandalwood oil, stood out prominently with the most potent inhibition in vitro. We, therefore, directed our research toward 15 EOs of Santalum species of different geographical origins, along with two samples of EOs from other plant species often commercialized as "sandalwood oils". Most of these EOs displayed similar strong activity against M. mycetomatis in vitro. All tested oils were thoroughly analyzed by GC-QTOF MS and most of their constituents were identified. Separation of the sandalwood oil into the fractions of sesquiterpene hydrocarbons and alcohols showed that its activity is associated with the sesquiterpene alcohols. The major constituents, the sesquiterpene alcohols (Z)-α- and (Z)-β-santalol were isolated from the S. album oil by column chromatography on AgNO3-coated silica. They were tested as isolated compounds against the fungus, and (Z)-α-santalol was about two times more active than the β-isomer.

Bacillus amyloliquefaciens: a versatile antimicrobial Firmicute for the suppression of wilt caused by Ralstonia pseudosolanacearum in tomato

ABSTRACT Rhizosphere bacteria based biological control strategy is an eco-friendly approach to protect crops from various plant diseases. Among these, spore-forming Bacillus, abundant in the rhizosphere, provide unique advantages for plant health. This study focused on characterising two tomato rhizosphere-associated Bacillus amyloliquefaciens strains (Trb7 and Trb11), highly effective against the bacterial wilt pathogen Ralstonia pseudosolanacearum in vitro. Species identification was based on partial 16S rRNA gene sequencing, supported by phylogenetic analysis. Five antimicrobial peptide (AMP) genes (surfactin, fengycin, bacilysin, subtilin, and spore protein) were detected in both the isolates of B. amyloliquefqciens using specific molecular markers. Greenhouse trials showed that prophylactic application of these isolates led to an 83.4% reduction in tomato bacterial wilt, with only 16.6% wilt incidence compared to the 100% in the R. pseudosolanacearum-inoculated control. Moreover, these B. amyloliquefaciens isolates exhibited plant-growth-promoting traits in vitro. Interestingly, they also showed significant inhibition of mycelial growth against Sclerotium rolfsii and Alternaria alternata, major fungal pathogens in tomatoes. Overall, our findings highlight the potent bactericidal role of B. amyloliquefaciens isolates in suppressing R. pseudosolanacearum in tomatoes. Key highlights Two among the 100 Bacillus displayed antibacterial activity against Ralstonia pseudosolanacearum. Antibacterial firmicutes was identified as Bacillus amyloliquefaciens through the 16S rRNA gene sequence analysis. Five AMP genes (srfAA, fenD, bacA, spas, and spoVG) were identified in the isolates. Delivery of B. amyloliquefaciens drenching on rhizosphere significantly reduced wilt. Additionally, B. amyloliquefaciens showed the antifungal activity on Sclerotium rolfsii and Alternaria alternata.