Abstract
Early blight (EB), caused by Alternaria solani, is a serious problem in tomato production. Plant growth-promoting rhizobacteria promote plant growth and inhibit plant disease. The present study explored the bio-efficacy of synergistic effect of rhizobacterial isolates and ginger powder extract (GPE) against tomato EB disease, singly and in combination. Six fungal isolates from symptomatic tomato plants were identified as A. solani on the basis of morphological features i.e., horizontal septation (6.96 to 7.93 µm), vertical septation (1.50 to 2.22 µm), conidia length (174.2 to 187.6 µm), conidial width (14.09 to 16.52 µm), beak length (93.06 to 102.26 µm), and sporulation. Five of the twenty-three bacterial isolates recovered from tomato rhizosphere soil were nonpathogenic to tomato seedlings and were compatible with each other and with GPE. Out of five isolates tested individually, three isolates (St-149D, Hyd-13Z, and Gb-T23) showed maximum inhibition (56.3%, 48.3%, and 42.0% respectively) against mycelial growth of A. solani. Among combinations, St-149D + GPE had the highest mycelial growth inhibition (76.9%) over the untreated control. Bacterial strains molecularly characterized as Pseudomonas putida, Bacillus subtilis, and Bacillus cereus and were further tested in pot trials through seed bacterization for disease control. Seeds treated with bacterial consortia + GPE had the highest disease suppression percentage (78.1%), followed by St-149D + GPE (72.2%) and Hyd-13Z + GPE (67.5%). Maximum seed germination was obtained in the bacterial consortia + GPE (95.0 ± 2.04) followed by St-149D + GPE (92.5 ± 1.44) and Hyd-13Z + GPE (90.0 ± 2.04) over control (73.8 ± 2.39) and chemical control as standard treatment (90.0 ± 2). Ginger powder extracts also induce the activation of defence-related enzymes (TPC, PO, PPO, PAL, and CAT) activity in tomato plants. These were highly significant in the testing bacterial inoculants against A. solani infection in tomato crops.
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Introduction
Tomato (Lycopersicon esculentum Mill.) is an economically significant crop sown worldwide. After potatoes, it is known to be the second most consumable crop [1]. In the year 2018, around 182 MT of tomatoes were grown in an area of 4.76 MH in more than 150 countries [2]. According to the Government of Punjab, In 2017–18, a total of 414,645 tonnes of tomatoes were produced, covering an area of 41,731 hectares. In 2017–18, it was grown on 8274, 24,968, 5354, and 3135 hectares in Punjab, Sindh, Baluchistan, and Khyber Pakhtunkhwa (KP), with respective production totaling 109,445, 182,198, 37,556, and 85,446 tonnes [3]. Tomato is a very nutritious crop and is considered an important constituent of a balanced diet due to the existence of the high amount of different vitamins like Vitamin A, B & C and some minerals[2, 4]. Tomato exhibits antimicrobial and radical scavenging activity that may help to fight against carcinogenic compounds [5].
One of the most significant constraints in tomato production is diseases. It lowers the product's quantity along with its commercial worth. Tomato plants are threatened by a variety of devastating diseases due to viruses, nematodes, bacteria, and fungi [6]. Fungal infections are far more prone to cause significant harm [7]. Solanaceae family members, including tomato, eggplant, pepper, and potato are susceptible to many phytopathogenic fungal strains[8]. Alternaria solani, a phytopathogenic fungus, causes EB disease in tomato plants, damaging tomato crops by reducing crop yield by about 50% worldwide [9].
The quality and quantity of tomato production have been declined by means of several pests and diseases, respectively [10]. Furthermore, the Alternaria fungus could lead to disease in all plant parts (stem collar rotting, leaf blight, and lesions in fruits), causing serious harm at any phase of growth [11]. Alternaria solani is an air-born soil hindering fungus that mainly causes destructive yield loss in crops, approximately 80% yield loss has been accounted in tomato crops [4]. The most common devastating EB tomato disease (A. solani), mainly showed utmost symptoms on the stem, foliage, and fruits, leading to the severity of defoliation, affecting the photosynthetic rate, stunted growth, and loss of yield, respectively [12, 13]. In order to, overcome this problem chemical methods have been used, mainly expensive fungicides, not considered a long-lasting solution, and the most important concern is not appropriate for environmental and public health as well as responsible for fungicide resistance development in A. solani [4, 14, 15]. In contrast, researchers found alternative modified modern biocontrol methods to suppress the activity of pathogens. Many studies have revealed that biocontrol technologies are not only environmentally friendly, long-term useful, effective against diseases, and healthy, but they also considerably improve the quality and quantity of tomato crop yield output [14].
Plants act as major natural elicitors against pathogens and rhizospheric zone associated with the variety of microbiomes, which can help in plant growth, stress tolerance, and control of phytopathogens. Plant products and biocontrol agents are ecofriendly and have potential against a wide range of plant infections. Several plant species explored for natural compounds that are effective against phytopathogenic fungi [16]. Recently, many studies with some modifications revealed that plant extracts along with PGPR have been considered the utmost strategy for the management and control of diseases [17, 18]. Ginger (Zingiber officinale) show antifungal activity against various microbes due to the presence of monoterpenoids, sesquiterpenoids, phenolic compounds, and its derivatives, aldehydes, ketones, alcohols, esters, which make it an interesting alternative to synthetic antimicrobials [19, 20]. Recent studies have reported the antifungal activities of ginger extract and ginger essential oil against Fusarium oxysporum and Colletotrichum falcatum respectively [21, 22].
Similarly, investigation and evaluation of beneficial PGPR strains along with some plant extracts, composting, and biochar amendments are used to enhance soil fertility and suppressed the pathogenic mechanism [2], despite all PGPR being useful for the enhancement of crop yield and improvement both qualitatively and quantitatively [4, 23]. Amongst the novel and innovative organic charcoal-like products biochar obtained from a raw organic source (such as green waste, wood chips, poultry manure, etc.) has revealed significant and promising effects against many phytopathogen [24]. Moreover, mycorrhizal fungi are also extensively used to suppress the disease mechanism of A.solani and provide protection from the destructive loss of tomato crops [25].
PGPR not only work against infections but also stimulates growth regulators, boosting the quality of crops. They support plant growth and reduce EB disease incidence in tomato crops against A. solani [2]. PGPR produces HCN, siderophores, and P-solubilizing enzymes that stimulate plant development [26, 27]. Bacillus and Pseudomonas spp. improves disease resistance and plants. The use of bacterial inoculants is a useful tool for managing plant dieases [28]. PGPR are widely present in agricultural soil and display important properties which make them efficient but their antagonistic potential against the EB of tomatoes particularly from Pakistan has not been studied extensively. The current study was designed to evaluate the antimicrobial activity of PGPR alone and combined with GPE against A. solani under in vitro conditions and pot trials.
Materials and methods
Collection of diseased plants and pathogen isolation
During a field survey in December 2020, infected leaves showing early blight symtoms were seen and purchased from a local market there in zipped bags from J.K Forms and markets, Faisalabad, Pakistan. All the collected samples were transferred to the Department of Botany, GC Women University Sialkot, Pakistan, and were stored at 4 °C until further use. The collected samples were processed for the isolation of Alternaria sp. by following the method reported by Babu et al. [4]. Leaf samples were cleaned under running tap water to remove all the soil particles. The infected leaves were chopped down into small segments, surface sterilized with a 0.5% NaOCl olution for 2–3 min, washed thrice with sterile distilled water, dried on 3-layered blotter paper, and plated on PDA containing Petri dishes under aseptic conditions. Petri dishes were incubated at 26 °C for 5–7 days. The growing fungus was further purified on PDA media and stored at 4 °C until further use in experiments.
Identification and morphological characterization of A. solani
A. solani was identified microscopically by comparing it with the morphological features already reported [29, 30]. The morphological features including colony color, colony margins, mycelial growth, horizontal and vertical septation, sporulation, length and width of conidia, and beak length of three type fungal isolates representing different locations (AS-1, AS-3, and AS-5) were observed under a light microscope (40X power lens).
Pathogenicity assay
The pathogenicity assay of six A. solani isolates was performed on a susceptible tomato (variety; Rio Grande) by performing detached leaf assay previously reported by Babu et al. [4]. In brief, 7 days old culture of A. solani grown on potato dextrose agar (PDA) media was flooded with sterile distilled water (SDW) to prepare a conidial suspension. The conidial load in the suspension was maintained at 5 × 104 conidia ml−1 by using haemocytometer. Randomly, 10 healthy leaves from 4-week old tomato seedlings were collected, washed with tap water, followed by rinsing with SDW, blot dried, and placed on the wet blotter paper on the Petri plates in three replicates. All the collected leaves were covered with wet blotter on the upper lids of the Petri plates. The leaves were injected with 50 µL conidial suspension of A. solani at the center while the leaves treated with 50 µL SDW served as control treatments. All the treatments were kept at 25 ± 2 °C, monitored for three weeks for disease symptoms development. Observations on disease severity were taken by following disease rating scale; 0 = no lesions on leaflets, 1 = 1–10% leaf area damaged, 2 = 11–25% leaf area damaged, 3 = 26–50% leaf area damaged, 4 = 51–75% leaf area damaged, and 10 = 100% symptoms on tomato leaves. A. solani isolate depicting the highest disease severity was selected to use in further experiments.
Isolation of rhizobacteria
For the isolation of bacterial strains, rhizospheric soil was sampled from the healthy tomato fields located at JK Agriculture Farm Faisalabad, Pakistan. Rhizobacteria were isolated by following the procedure of Hibar et al. [31]. In brief, 1 g rhizospheric soil was serially diluted in distilled water and dilutions from 10–2 to 10–7 were prepared. Afterward, 0.1 ml aliquot was spread on solidified NA media (give full form of media) and placed at 26 ± 2 °C for 48 h.
Compatibility among rhizobacterial strains
The methodology of Fukui et al. [32] was followed to study the compatibility among the rhizobacterial strains. In repeated experiments, bacterial strains were cross streaked on the same NA containing Petri plates in triplicate followed by incubation at 26 ± 2 °C for 72 h. Bacterial growth inhibition data was taken from each treatment for 48 and 72 h of incubation.
Preparation of GPE
Fresh, plump ginger roots with smooth skin and few creases were washed and grated followed by sun drying. Spice grinder was used to pulverize the dried ginger and powder was kept cold in dark. The extract was made by mixing a small amount of ginger powder with a ratio of 1 part ginger powder to 9 parts water.
Compatibility of GPE with rhizobacterial isolates
The compatibility of GPE with bacterial strains viz, Hyd-01F, Hyd-13Z, Gb-T23, St-149D, and Ft-G43 was tested on NA medium in a repeated experiment. In this assay, 48 h-old bacterial cultures were spread on solidified NA plates. Three small paper discs (5 mm) were placed at equidistance to each other on each petri plate. After this, 10 µL of the 10%, 15%, and 20% GPE were loaded to sterile filter paper discs. Similarly, discs treated with 10 µL of 100 ppm streptomycin sulfate and dH2O served as control treatments. All the plates were incubated at 26 ± 2 °C for 48 h and development of inhibition zones around the discs were observed. Halo zones formation indicated the incompatibility between the GPE and bacterial strains while the absence of inhibition zones confirmed the compatibility [32].
In-vitro anti-mycotic efficacy of individual and combined application of rhizobacteria and GPE
The dual culture methodology [33] was followed to test the efficacy of individual and combined application of bacterial strains (Hyd-01F, Hyd-13Z, Gb-T23, St-149D, and Ft-G43) and GPE on mycelial growth of A. solani in-vitro. For this, sterilized filter paper discs (5 mm) were placed on one side of the PDA containing Petri plates. Discs were treated with 6 µL of 48 h old bacterial strains and GPE individually. For combined applications, 3 µL of individual bacterial strain and GPE was placed on the sterilized filter paper discs aseptically. Actively growing mycelial plugs (9 mm) from 7 day old A. solani culture were placed on the other side of the plate. The control treatments contained filter paper discs spotted with distilled water only. Plates were kept at 26 ± 2 °C for 7 days. The repeated experiments were performed with three repeates for each treatment. Data on fungal mycelial growth inhibition % was taken from each treatment by given formula:
Where C = Mycelial growth in Control (cm); T = Mycelial growth in Treatment (cm).
Biochemical assay
Various biochemical assays were performed for the identification of PGPR. The Gram staining assay was performed by following the procedure of Vincent and Humphrey [34] while the KOH solubility assay was carried out following the methodology as described by Kirsop and Doyle [35]. Gram staining was performed by employing crystal violet, iodine, ethanol, and safranin successively to a bacterial smear, allowing for color fixation and differentiation. The Gram staining was further confirmed by KOH assay as follows: fresh bacteria were spread on clear glass slides and were treated with a solution of 3% KOH and mixed properly. The development of a mucoid thread indicated that the bacterium is Gram negative while its absence indicated that the bacterium is Gram positive. The Catalase test was performed by mixing one drop of 3% H2O2 with freshly grown bacterial cultures on a slide. Gas bubbles development indicated catalyse activity [36]. The carbohydrate fermentation assay was done according to the methodology proposed by Aneja [37], while the hydrogen sulfide (H2S) test was carried out as described by Warren et al. [38]. An oxidase test was performed as described by Hayward [39] and the development of dark purple color within a half minute confirmed the positive result. According to Hugh and Leifson [40], an oxidative fermentation test was performed, while NO3− reduction test and gelatin hydrolysis activity were performed by following the methodology used by Thankamani and Dev [41]. Lastly, fluorescence emission was observed using King’s B medium by following the standard protocol of Howell and Stipanovic [42].
Molecular characterization of bacterial isolates
The genomic DNA of all the bacterial strains was extracted using GeneJet Genomic DNA Isolation Kit (@Thermo Scientific Waltham, USA) according to the mentioned protocol. The 16S rRNA genes of the bacterial strains were amplified using universal primer pair 27F (5´ -AGAGTTTGATC-MTGGCTCAG- 3´) and 1492R (5´ -GGTTACCTTGTTAC-GACTT- 3´), respectively by PCR. The amplified PCR products were visualized under a UV transilluminator and were purified from the bands (approx;1500 bp) using Gel and PCR Clean-Up System (Promega, USA). The bacterial species were determined by 16S rRNA genes sequencing. The obtained forward and reverse sequences were joined together in the DNASTAR program. The final sequences were BLAST to retrieve the identical bacterial sequences. All the sequences were then aligned in CLUSTALW. The phylogenetic tree was made using MEGA X program (version 10.1.7) with 1000 bootstraps. The Neighbor-Joining method was followed to study the evolutionary relationships between our bacterial isolates sequences and all the retrieved sequences [23].
Pathogenicity and seed germination study of potential rhizobacterial strains
Pathogenicity and effect of rhizobacterial isolates namely, Hyd-01F, Hyd-13Z, Gb-T23, St-149D, and Ft-G43 on seed germination were studied by following the paper towel method of Sudisha et al. [43]. In this assay, five tomato seeds (var: Rio grande) were surface cleaned with 1% NaOCl for 2 min followed by washing 3 times in dH2O and dried on blotter paper. Tomato seeds were then treated with 0.1% sterilized CMC as an adhesive material followed by dipping in 30 mL of each bacterial suspension containing 1 × 107 cfu/mL for 2 h. Seeds treated with distilled water only were control treatments for comparison. Bacterized seeds (25 seeds) were then aseptically placed on a moist double-layered paper towel in trays. All the trays were placed at 28 ± 2 °C for 15 days. There were three trays per treatment. After 07 days, seed germination percentage (SGP) was recorded by using the formula:
Data on plumule and radical length (cm) and disease were recorded 15 days after treatment. The Seedling Vigor index (SVI) was calculated by following the formula:
Effect of rhizobacteria and GPE applications on EB disease and plant growth promotion
A repeated pot experiment was set up to study the effect of individual and combined application of bacterial isolates (Hyd-01F, Hyd-13Z, Gb-T23, St-149D, and Ft-G43) and GPE on suppressing EB disease incidence and plant growth promotion by following the procedure of Rasool et al. [2]. Tomato seeds (vir; Rio grande) were surface cleaned with 1% NaOCl, washed 3 times in dH2O, and blotter dried before bacterization. Seeds were treated with 0.1% CMC as an adhesive material followed by dipping in 30 mL of individual bacterial suspensions for 2 h. Five bacterized seeds were then sown in plastic pots (10 L) containing 8 kg of sterilized potting mixture i.e., sand: clay: farm yard manure at the rate of 1:1:1 [44]. At four weeks-old seedlings, rhizospheric soil was flooded with 15 mL bacterial suspension individually. The conidial suspension was formulated from a week old A. solani culture grown on a PDA medium. For this, an actively growing culture ofA. solani was flooded with distilled water and Shaked well to free the conidia from mycelial mates, filtered through muslin cloth, and conidial concentration was kept 1 × 106 conidia ml–1 with the help of a hemocytometer[45]. After 1 day of soil flooding with bacterial isolates, tomato seedlings were treated with A. solani conidial suspension until run-off with the help of a hand-held sprayer [13]. Relative humidity (~ 70%) required for EB disease development was maintend by spraying the plants with distilled water.
Ginger powder extract (25 g/L) was prepared in distilled water and applied as a foliar application on individual and combined treatments along with bacterial isolates. Plants sprayed with Antracol (70% WP) at 0.2% level served as a positive control, while the plants inoculated with fungal conidial suspension alone were kept as a negative control. Pots were placed under controlled conditions and other agronomic activites were kept the same for all the treatments. The experiment was conducted under CRD design with 4 repeats. The treatments include; T1 = Hyd-01F + A. solani; T2 = Hyd-13Z + A. solani; T3 = Gb-T23 + A. solani; T4 = St-149D + A. solani; T5 = Ft-G43 + A. solani; T6 = Bacterial consortia + A. solani; T7 = GPE + A. solani; T8 = Hyd-01F + GPE + A. solani; T9 = Hyd-13Z + GPE + A. solani; T10 = Gb-T23 + GPE + A. solani; T11 = St-149D + GPE + A. solani; T12 = Ft-G43 + GPE + A. solani; T13 = Bacterial consortia (Detail of consortia) + GPE + A. solani; T14 = Antracol (Positive control); T15 = Negative control.
Data on disease control was recorded three weeks after the treatment applications while data on plant growth traits (seed germination, plomule length, radical length, vigor index, shoot length, root length, fresh shoot weight, dry shoot weight, fresh root weight and dry root weight) was recorded 45 days after transplantation. Disease severity was recorded on 0–4 disease rating scale of Li and Dong [46] while the data on the percent disease index (PDI) was calculated by following the formula of McKinney [47] as given below;
Chlorophyll contents
Briefly, chlorophyll contents and carotenoids were determined by adopting the procedure of Hiscox and Israelstam [48]. In this test, 1 g of fresh tomato leaf samples was finely chopped into small segments, ground using a pestle and mortar with 100 mL of an 80% acetone solution (v/v), and subsequently filtered through Whatman No. 1 filter paper. The resulting solution, comprising 100 mL in 80% aqueous acetone, was prepared. The optical density of the prepared mixture was measured using a spectrophotometer at 649 nm and 665 nm wavelengths. Chlorophyll concentration in leaf samples were calculated using the formulas of Holm-Hansen and Riemann [49] given below;
Where;
Ca = Concentration of chlorophyll (a)
Cb = Concentration of chlorophyll (b)
Defense-related enzymes in tomato plants
Metabolic and biochemical indicators for plant resistance against A. solani were determined in leaves samples collected from 60 days old plants.
Total phenolics
The Folin-Ciocalteu method was followed to determine the total phenolics as per Rasool et al. [2]. In this test, 1 g fresh tomato leaf samples were mixed in 10 mL ethanol (80%) and agitated at 70 °C for 15 min. After this, 200 μL extract was mixed with Folin Ciocalteau reagent (500 μL) and placed at 25 °C for 3 min. To this solution, 800 μl/0.8 ml of 7.5% saturated Na2CO3 was added followed by incubation for 30 min at 45 °C. Absorbance was taken using a UV–Visible spectrophotometer at 765 nm against a blank. The total phenolic contents were recorded against the standard curve reference number.
Total protein contents
A modified method of Khan et al. [50] was used to determine the total protein contents. In this test, 0.5 g fresh leaf samples were mixed in 10 mL cold Na3PO4 buffer (100 mM; pH 7.4). The prepared mixture was stirred at 12,000 rpm for 15 min at 4 °C and the final supernatant of crude enzyme extract was obtained. The total protein contents were quantified spectroscopically using bovine serum albumin as a standard.
Peroxidase (PO)
Peroxidase activity test was performed by adopting the methodology of Hammerschmidt et al. [51]. In this assay, PO activity was determined by using solution containing enzyme extract (0.5 mL), 1.5 mL of pyrogallol (0.05 M) and 0.5 mL H2O2 (1%) followed by incubation at room temperature. Change in absorbance was recorded spectrophotometrically at 420 nm wavelength at 30 s intervals for 3 min against a standard. The PO activity was measured as Katal/mg of the total proteins.
Polyphenol oxidase (PPO)
The methodology of Hyder et al. [52] was followed to quantify the Polyphenol oxidase activity (PPO) as an indicator of defense induction against A. solani. The assay was performed by preparing a mixture of crude enzyme extract (200 mL) and 1.5 mL of 0.1 M Na3PO4 buffer. In the reaction mixture, 200 mL of 0.01 M catechol was loaded to initiate reaction and analyzed spectroscopically at a wavelength of 495 nm.
Phenylalanine ammonia lyase (PAL)
The activity of Phenylalanine ammonia-lyase was determined according to the methodology of Whetten and Sederoff [53]. The reaction mixture was prepared by adding 100 mL of the enzyme, 500 mL of 50 mM Tris HCL, and 600 mL of 1 mM L-phenylalanine and incubation for 1 h. The reaction was stopped by adding 2N HCL to the reaction mixture, followed by adding toluene (1.5 mL) in it, vortex for 30 s, and centrifugation (1000 rpm) for 5 min. Toluene fraction was separated and toluene phase was determined spectrophotometrically at 290 nm against the toluene as blank. Standard curve was constructed using cinnamic acid in toluene. PAL reaction was represented as Katal/mg of total proteins.
Catalase (CAT) activity
The catalytic activity was determined spectrophotometrically in two phases by following the methodology of Dhindsa et al. [54]. The reaction mixture contains 400 μL of 5% H2SO4, enzyme extract (100 μL), and 1 mL of 0.1 M H2O2. In the reaction mixture-1 (Rm1), H2SO4 was added along with the other reagents and the mixture was vortexed at 26 ◦C for 30 s before taking the readings while in the case of mixture-2 (Rm2), H2SO4 was added after vertexing reaction mixture at 26 ◦C for 1 min. The absorption was taken @ 270 nm using a spectrophotometer. The difference (Rm1—Rm2) represented catalase activity which was shown in Unit; min−1 g −1 of protein () (reference number).
Statistical analysis
Data was analyzed in Statistix 8.1 and MS Excel 365. Experiments were conducted in CRD with three replicates. Mean values were calculated, and means were compared by ANOVA using LSD @ 5% (P ≤ 0.05). The correlation analysis was performed in MS Excel 365.
Results
Inoculum and morphological characterization of A. solani
A total of six fungal isolates (As-1, As-2, As-3, As-4, As-5, and As-6) were recovered from the collected symptomatic tomato plant samples on PDA media containing Petri plates. All the recovered isolates of A. solani displaying the highest disease virulence were identified based on peculiar morphological features. Fungal isolates displayed dark brown, irregular colonies with aerial mycelial growth. Morphological features i.e., horizontal septation (6.96 to 7.93 µm), vertical septation (1.50 to 2.22 µm), conidia length (174.2 to 187.6 µm), conidial width (14.09 to 16.52 µm), beak length (93.06 to 102.26 µm), and sporulation is presented in Table 1.
Virulence confirmation of A. solani
A total of six A. solani isolates were subjected to virulence confirmation on tomato plants (Variety; Rio Grandy) in a detached leaf assay. All the tested isolates showed variability in response to producing characteristic EB symptoms and the results are presented in Fig. 1. Among all the fungal isolates, As-3 produced the highest disease incidence-DI of 76.7% followed by As-5 (63.3%) and As-1 (60%) while the lowest disease incidence was shown by As-6 (43.3%). On a disease rating scale, As-3 showed the highest disease severity-DS (4; 51–75% leaf area infected) while As-1, As-2, and As-5 showed DS (3; 26–50% leaf area infected).
Pathogenicity assay to confirm the virulence of A. solani on tomato plants under controlled conditions. DI % = Disease Incidence percentage; DS = Disease Severity on Disease Rating Scale
Biochemical assay
Bacterial isolates with strong antagonistic ability were subjected to various biochemical tests and the results are presented in Table 2. Four bacterial isolates viz., Hyd-01F, Hyd-13Z, and Gb-T23 showed positive test results for Gram staining while St-149D and Ft-G43 showed a negative reaction. The Gram stain results were confirmed with the KOH test. The result of the Catalase test reveals that all the bacteria were catalase positive. Additionally, the Carbohydrate fermentation test was positive for Hyd-13Z, St-149D, and Ft-G43 while the test was negative for Gb-T23. All the bacterial isolates except Hyd-01F showed positive results for the Hydrogen Sulphide production test whereas, all the bacterial isolates showed a positive response toward the Oxidase test. In addition, Hyd-13Z, Gb-T23, and St-149D were positive for the Oxidative fermentative test whereas the test was not done for Ft-G43. All bacterial strains displayed positive test results for NO3− reduction and Gelatin hydrolysis. Of all the tested bacterial strains, Hyd-01F, Hyd-13Z, and St-149D revealed negative test results for Fluorescence emission-FLE while Gb-T23 and Ft-G43 reflected positive test results.
Isolation and compatibility among the bacterial strains and GPE
Five independent soil samples collected from the tomato rhizosphere were used to recover 23 bacterial isolates displaying variation in colony characters and color. Based on in vitro dual culture assay against the most virulent strain of A. solani, 05 potential bacterial isolates viz., Hyd-01F, Hyd-13Z, Gb-T23, St-149D, and Ft-G43 were selected and subjected to compatibility study among the bacterial strains and also with the GPE at 10%, 15%, and 20% concentration levels. The collected results showed that none of the rhizobacterial strains were inhibited by each other, suggesting that all the bacterial strains were compatible if used in consortium form. Compatibility studies of GPE and rhizobacterial antagonists indicated that the GPE at all concentration levels were also compatible with bacterial isolates.
Effect of individual and combined application of rhizobacteria and GPE on the mycelial growth of A. solani in-vitro
A total of 23 bacterial isolates were studied for their antagonistic potential again the highly virulent strain of A. solani (As-3). Out of all the tested bacteria, 05 (22%) isolates were found highly effective antagonists against A. solani. All five bacterial isolates individually and in a combination with GPE showed a varied response in suppressing the mycelial growth of A. solani. Among all the bacterial isolates, St-149D showed highest mycelial inhibition (56.3%) of A. solani followed by Hyd-13Z (48.3%) and Gb-T23 (42.0%) over the untreated control. However, the combined application of rhizobacterial isolates and GPE resulted in maximum mycelial inhibition of A. solani. Among all the combinations, St-149D + GPE resulted in the highest percentage of mycelial growth inhibition (76.9%) followed by Hyd-13Z + GPE (67.6%) while Ft-G43 + GPE showed 46.6% mycelial growth inhibition over untreated control. Individual application of GPE showed 46.6% mycelial growth inhibition of A. solani (Table 3).
Molecular identification of isolated bacterial strains
Rhizobacterial isolates reflecting antagonistic potential were characterized based on 16S ribosomal DNA gene partial sequencing. The bacterial sequences of our isolates (≈ 1500 bp) along with corresponding reference bacterial isolates are displayed in Table 4. It is reflected in the phylogenetic tree that bacterial strains Hyd-01F and Hyd-13Z showed 99.9% identity with Bacillus subtilis accessions LC178546 and AB192294 (Fig. 2). Similarly, bacterial strains Gb-T23, St-149D, and Ft-G43 showed maximum sequence similarity with B. cereus, Pseudomonas putida, and Pseudomonas fluorescens respectively.
Phylogenetic analysis on the basis of 16S rRNA sequences (approx.1500 bp) displaying relationships between the sequences of representative bacterial isolates and closely related strains. The closely related sequences of bacterial strains were retrieved from NCBI (https://www.ncbi.nlm.nih.gov/)
In vitro assessment of pathogenicity and effect of rhizobacterial strains on tomato seed germination and vigor index
The results of the pathogenicity assay revealed that all the bacterial strains were non-pathogenic and did not produce symptoms in the tomato seedlings. All the bacterial agents improved the tomato seed germination ranging from 85.0 ± 3.54 to 93.2 ± 1.97% over untreated control 76.2 ± 2.39. Our tested bacterial strains significantly improved the plumule (9.60 ± 0.47 to 10.45 ± 0.40%) and radical length (3.25 ± 0.12 to 4.28 ± 0.22%) in tomato seedlings as compared to untreated control, where the plumule and radical length were recorded 7.80 ± 0.39 and 3.40 ± 0.12% respectively. A significant increase in seedling vigor index is also noticed over untreated control as presented in Table 5.
Testing of rhizobacterial strains and plant extract on early blight disease control and plant growth promotion
The individual and co-inoculated effect of rhizobacterial strains and GPE on seed germination, EB disease suppression, and growth promotion in tomato plants was examined in the presence of A. solani (AS-3) in a repeated pot trial. Our results showed that tomato seeds treated with individual rhizobacteria and in combination with the GPE showed varied responses on EB disease suppression and seed germination as presented in Table 6. Seeds treated with bacterial consortia + GPE showed the highest disease suppression percentage of 78.1% followed by St-149D + GPE (72.2%) and Hyd-13Z + GPE (67.5%) while the response of individual application of rhizobacterial applications was ranged from 30.5 to 66.2%. The individual application of bacterial consortia and GPE showed disease suppression percentages of 57% and 51.1%, respectively, and were less effective than Antracol as standard control (69.6%). In the case of tomato seed germination, all the tested bacterial strains alone, in consortia form, and combination with GPE significantly improved the seed germination. Maximum seed germination percentage was recorded in the bacterial consortia + GPE (95.0 ± 2.04) followed by St-149D + GPE (92.5 ± 1.44) and Hyd-13Z + GPE (90.0 ± 2.04) over the control (73.8 ± 2.39) and chemical control as standard treatment (90.0 ± 2). The individual applications of rhizobacterial strains in the presence of A. solani showed seed germination ranging from 79.3 ± 1.49 to 88.8 ± 1.25 percent. The seed treatment with GPE individually displayed 79.5 ± 2.1 percent seed germination while bacterial consortia showed 87.5 ± 3.23 percent tomato seed germination in the presence of A. solani. ( disease percent incidence is minimum in Antracol treatment but percent disease control in maximum in the bacterial consortia + GPE).
All the tested variables alone and in combination with GPE significantly influenced the plant growth parameters in the presence of virulent A. solani inoculum (Table 7). Among all the treatments, bacterial consortia + GPE and St-149D + GPE significantly increased the shoot length to 141.3 ± 1.75 and 138.3 ± 0.85 respectively. Tomato shoot length ranged from 109.3 ± 2.66 to 122.8 ± 2.39 in individual treatments of bacterial strains while the shoot length ranged from 123.8 ± 1.8 to 138.3 ± 0.85 in the treatments of bacterial strains in combination with GPE. Of all the treatments, GPE showed the minimum increase in shoot length (113.0 ± 1.68). In the case of root length, bacterial consortia + GPE significantly increased the root length (23.0 ± 1.68) as compared to individual applications of bacterial strains and in combination with GPE where the root length was recorded ranging from 15.8 ± 1.75 to 20.3 ± 1.25 and 16.3 ± 1.11 to 21.5 ± 0.65 respectively. GPE alone was observed as least effective in increasing the root length (15.3 ± 2.39).
Tomato plants treated with bacterial isolates alone and in combination with GPE sustained A. solani induced decrease in root and shoot fresh weight and dry weight (Table 2). The maximum fresh and dry shoot weights (228.0 and 38.0 g respectively) were recorded for the plants treated with a combined application of bacterial consortia and GPE in the presence of A. solani. Among the individual bacterial treatments in the presence of A. solani, fresh and dry shoot weight ranged from 181.5 to 205.3 g and 21.0 to 27.0 g respectively. While fresh and dry shoot weight of plants treated with the combined applications of individual bacterial strains and GPE was recorded at 208.8 to 227.5 g and 25.8 to 39.8 g respectively. In the case of fresh and dry root weight, all the treatments improved the FRW and DRW over the control and standard control as presented in Table 7. Amon all the treatments, A. solani inoculated plants treated with the bacterial consortia and GPE significantly increased the FRW (3.6 g) and DRW (1.55 g) as compared to the plants challenged with A. solani (control). Plants treated with the bacterial strains + GPE significantly increased the FRW (2.7 to 3.4 g) and DRW (1.03 to 1.38 g) as compared to the individual treatments of bacteria strains (2.3 to 2.9 g) and (0.93 to 1.15 g) respectively.
Chlorophyll contents
The photosynthetic pigments were significantly reduced in the plants challenged with A. solani (Fig. 3). All the bacterial treatments individually and in combination with GPE significantly improved the Chlorophyll contents and carotenoids. In the case of Chlorophyll a content, A. solani infected plants challenged with bacterial consortia + GPE significantly increased Chlorophyll a (30.525 mg/g) followed by Hyd-13Z + GPE (26.875 mg/g) and St-149D + GPE (25.85 mg/g) while all other treatments including individual applications of PGPR and GPE showed less effectiveness in enhancing the Chlorophyll a content. Similarly, in the case of Chlorophyll b, total Chlorophyll and Carotenoids, A. solani infected plants inoculated with a combined application of bacterial consortia and GPE significantly improved the photosynthetic pigments as compared to all other treatments (individual bacterial applications and GPE) in the presence of A. solani inocula. On the other side, photosynthetic pigments were observed significantly lower in the plants challenged with A. solani (control).
Estimation of Photosynthetic pigments in tomato plants treated with individual bacterial inoculants and in combination with GPE in the presence of pathogenic A. solani
Defense related enzymes induction in tomato plants
Total phenolic contents-TPC
Tomato plants inoculated with A. solani grown under individual and combined applications of bacterial strains and GPE showed a significant increase in TPC over the plants challenged with A. solani as a control treatment as presented in Fig. 4a. The phenolic contents were observed highest in the tomato plants' co-inoculation of bacterial consortia + GPE (16.54 mg/g of fresh weight) followed by St-149D + GPE (14.5 mg/g) and Hyd-13Z + GPE (13.73 mg/g) over control treatment (6.63 mg/g fresh weight). The phenolic contents were recorded ranging from 10.18 to 11.78 mg/g fresh weight in plants treated with individual bacterial agentsin the presence of A. solani. On the other side, tomato plants individually treated with bacterial consortia (12.25 mg/g of fresh weight) and GPE (11.58 mg/g of fresh weight) produced low TPC as compared to the combined application of bacterial consortia and GPE.
Detection and quantification of defense-related enzyme induction in plants challenged with A. solani under influence of individual bacterial inoculants and combined application with GPE. a Represent total phenolic contents; (b) = Total protein contents; (c) = PO; (d) = PPO; e = PAL and (f) = Catalase activity
Total protein contents
The analyzed data displayed a strong interaction of A. solani inoculated plants treated with the individual bacteria strains and in combination with GPE in producing the total protein contents (Fig. 4b). In the case of tomato plants treated with individual bacterial isolates in the presence of A. solani showed total protein contents ranged from 0.21 to 0.31 mg/g fresh weight, while the total protein contents were recorded ranging between 0.30 to 0.38 mg/g fresh weight of the plants treated with individual bacterial isolates in combination with GPE. Among all the treatments, bacterial consortia + GPE produced significantly high total protein contents (0.47 mg/g fresh weight) as compared to bacteria consortia (0.33 mg/g) and GPE (0.24 mg/g).
Peroxidase activity-PO
All the treatments induced the defense enzymes in the tomato plants over control where only A. solani was applied as shown in Fig. 4c. In tomato plants, treated with consortia + GPE, a notable increase in PO activity of 1.19 Katal/mg total proteins was observed followed by St-149D + GPE (1.13 Katal/mg of total proteins) and Hyd-13Z + GPE (1.01 Katal/mg total proteins) and individual application of St-149D (1.02 Katal/mg total proteins). PO activity ranged from 0.81 to 1.02 Katal/mg total proteins. Among all the treatments, minimum PO activity (0.81 Katal/mg total proteins) was recorded in the plants inoculated with Gb-T23 bacterial isolates in the presence of A. solani.
Polyphenol oxidase (PPO)
An increase in PPO activity in tomato leave samples was recorded in all the treatments over the control. The collected data showed that bacterial consortia + GPE application in the presence of A. solani showed maximum PPO activity (2.56 Katal/mg total proteins) followed by St-149D + GPE (2.36 Katal/mg total proteins) and Hyd-13Z + GPE (2.15 Katal/mg total proteins) whereas, the minimum PPO induction was recorded in Gb-T23 + GPE (1.90 Katal/mg total proteins). In the case of individual applications of bacterial strains, and GPE, PPO activity ranged from 1.76 to 2.10 Katal/mg total proteins as presented in Fig. 4d.
Phenylalanine ammonia-lyase (PAL)
PAL activity was recorded as significantly higher in all the plants inoculated with individual bacterial isolates, consortia, and in combination with GPE in the presence of A. solani. PAL activity was high in the bacterial consortia + GPE group (1.97 Katal/mg total proteins followed by St-149D + GPE (1.85 Katal/mg total proteins) and Hyd-13Z + GPE (1.75 Katal/mg total proteins) when compared to positive control treatment (0.63 Katal/mg total proteins). In the case of inoculation with individual bacterial stains, PAL activity ranged from 1.06 to 1.48 Katal/mg of total proteins while individual applications of bacterial consortia and GPE showed PAL production of 1.64 and 1.53 Katal/mg of total proteins respectively (Fig. 4e).
Catalase (CAT) activity
Catalase production was recorded as significantly high in all the treatment groups over the control as presented in Fig. 4f. Among all the treatments, bacterial consortia + GPE in the presence of A. solani showed the highest CAT production (59.68 U min−1 g−1 of protein) whereas, in all other bacterial combinations with GPE, CAT production ranged from 47.18 to 51.88 U min−1 g−1 of protein over the control treatment where CAT production was recorded 13.53 U min−1 g−1 of protein. In case of individual bacterial treatments in the presence of A. solani, CAT activity was observed ranging from 35.95 to 43.38 U min−1 g−1 of protein. In the case of bacterial consortia in the presence of A. solani, CAT activity was recorded at 50.78 U min−1 g−1 of protein and 45.35 U min−1 g−1 of protein in the individual GPE group.
Discussion
The present study investigated the potential of synergistic interactions between rhizobacterial isolates and ginger powder extract (GPE) against Early Blight (EB) disease caused by Alternaria solani in tomato plants. The individual and combined effects of the discovered bacterial isolates and GPE on suppressing A. solani were both studied. The findings of this study provide useful insights into disease control techniques that are both sustainable and environmentally friendly.
A total of twenty-three strains of soil rhizobacteria were tested against A. solani to identify and characterize promising biological control isolates. Five strains, identified as Pseudomonas putida St-149D, Pseudomonas fluorescens Ft-G43, Bacillus subtilis Hyd-13Z, Bacillus subtilis Hyd-01F, and Bacillus cereus Gb-T23 with potential plant growth promoting activities, were found to show enhanced antagonistic activity against A. solani infection. The inhibition of mycelial growth in vitro was between 37–57% as compared to control. The inhibitory efficacy of Pseudomonas and Bacillus against A. solani may be attributed to the existence of antibiotic substances such as Surfactin, bacillomycin, zwittermycin A, pyoluteorin, pyrrolnitrin, pyocyanin, iturin, and 2,4-diacetylphloroglucinol [14, 55]. These antibiotic substances can inhibit fungal growth by targeting their cellular processes [56, 57]. Antibiotic substances derived from PGPRs provide a sustainable and ecologically sound substitute for synthetic fungicides. These compounds have the ability to be generated through bacterial proliferation in the rhizosphere and exert a biostimulatory influence on plant development and offer defense against a range of pathogens.
Treatment with GPE achieved mycelial inhibition of 46.6% suggesting it be an effective compound for the control of A. solani. Other plant extracts such as A. indica, A. sativum, P. lysterophorus, and D. stramonium have been also reported as potential inhibitors of A. solani [58]. Besides, several researches have found that GPE possesses a broad spectrum antimicrobial properties and acts as fungicide by preventing spore formation and germination and the distortion of the hyphae of different phytopathogens [59], such as Fusarium oxysporum, Botritys cinerea [60], Alternaria alternate [61], Fusarium solani [62], among others. Also, the combination of GPE with the bacteria Bacillus cereus Gb-T23 and Pseudomonas fluorescens Ft-G43 maintained fungal inhibition compared to treatment with GPE alone, while the combination of this compound with Bacillus subtilis Hyd-01F, Hyd-13Z, and Pseudomonas putida St-149D has demonstrated an increased antifungal potential. The antimicrobial and inhibitory properties of extracts derived from plants, such as ginger powder extract, have been the subject of numerous studies demonstrating their potential for managing pests and pathogens. It has been demonstrated that the concurrent implementation of these two agents has the potential to exploit their synergistic or complementary interactions in order to efficiently manage fungal diseases of crop plants [63, 64].
Under in vitro conditions, it was found that seed bacterized with the PGPR (St-149D, Ft-G43, Hyd-13Z, Hyd-01F, and Gb-T23) enhanced seed germination and other growth indicators. Similar results were reported under in vitro and controlled conditions with strains of this bacteria genera in tomato plants [65,66,67] and other vegetable plants [68, 69]. Seed germination depends on environmental conditions and the balance of abscisic acid/gibberellins ratio to promote dormancy-breaking. According to numerous studies, the use of PGPR facilitate seed germination and seedling growth, possibly due to the synthesis of gibberellic acid [69]. However, germinating seeds are vulnerable to living and nonliving factors including pathogen infection[70].
The current study suggests that the application of PGPR in combination with GPE increases tomato seed germination in presence of the phytopathogen and effectively manages the EB disease of tomatoes in a pot trial. However, the germination percentage remained unchanged at 90% when Bacillus subtilis Hyd-13Z and GPE were applied in combination. Furthermore, a significant increase was noted when Pseudomonas putida St-149D bacteria were combined with GPE (92%).
In addition, a reduction in the percentage of disease incidence was noticed with the later treatment compared to the chemical treatment, achieving a disease suppression of 78.1% suggesting a synergistic action of biocontrol agents and plant products. These results are similar to those of Latha et al. [14] who showed that a talc based mixture of Zimmu leaf extract and PGPR reduced the percent disease severity by 18% over the controls, and also improved seed germination and fruit yield. In this regard, it has been reported that the use of microbial consortia, composed of compatible PGPR, could lead to reduced disease incidence through synergistic action[71], besides, this could be advantageous when dealing with many plant diseases [14].
In addition to eliciting defense against EB disease, all treatments also promoted plant growth, where the application of the bacterial consortium with the GPE obtained the best results in shoot and root length, and their dry and fresh weights. Even though the fungicide application at its recommended dose provided effective disease control however, it poses risk to human health, pesticide resistance, and environmental impact would be potential issues. The combination of biological control agents with synthetic pesticides could both reduce the risk of the emergence of pesticide resistance and improve disease control compared to that obtained applying the biological control agent individually [72]. Various studies have shown that combinations of biological control agents with fungicides are more effective than single treatments. For example, [73] reported that the co-application of difenoconazole with B. amyloliquefaciens synergistically increased the efficacy of the fungicide against Fusarium wilt. Therefore, the development of biocontrol strategies using PGPR should have both biocontrol and growth-promoting potential for the sustainability of crops, such as tomatoes.
All above ground parts of the tomato plant might be harmed by EB. Due to insufficient leaf area, oxidative explosion, and increased activity of chlorophyll-degrading enzymes and chlorophyllase under disease conditions, the plant is unable to absorb light, which slows down the rate of photosynthesis [74]. This was observed in Fig. 3, as a sharp decrease of chlorophyll (a, b) and carotenoids. However, Alternaria-infected plants treated with PGPRs alone and in combination with GPE showed an increase in the chlorophyll a, b, total chlorophyll, and carotenoids compared with the Antracol treatment. Likewise, Awan et al. [75] reported the interactive effect of the B. subtilis with plant nutrients conferred resistance in the infected tomato plants against EB by altering the chlorophyll contents, carotenoids, and phenolics. This can be attributed to the role of PGPR in N2 fixation along with IAA production and phosphate metabolizing tendencies [76].
Stimulation of plant growth by rhizobia could also be due to the suppression of plant diseases. This suppression induced by PGPR may be direct, through inhibition of pathogen growth, or indirect, through the activation of plant defense mechanisms, through the production of several compounds including phenolic [77]. Phenolic compound functions are diverse in plants, ranging from involvement in growth improvement, reproduction, and defense against stressors [78]. There are reports of increased phenolic compounds in the soil in response to the plant defense participating in the ISR, repelling pathogens due to their inhibitory actions. Our results revealed that all the treatments showed different responses in total phenol content, but the increase of total phenolic could be explained as a defense mechanism, which may induce resistance, through lignin synthesis to strengthen the plant cell wall and induction of barrier against A. solani [68].
Indirectly, PGPR control plant pathogens by activiating plant defense mechanisms through proteins production [5]. In this study, protein contents were also increased in all the treatments. Our findings are aligned to the study of Awan et al. [75]. Furthermore, antioxidant enzyme contribute significantly in plant resistance induction against abiotic and biotic stresses, particularly phenylalanine ammonia-lyase (PAL), peroxidase (PO), polyphenol oxidase (PPO), catalase (CAT), among other enzymes. Our study suggests that the utilization of bacterial isolates with plant extracts may aid in overcoming the infection by increasing the production of defense-related enzymes. Tomato plants treated with the bacterial consortium and GPE presented higher values of PO, PPO, PAL, and CAT in comparison with the positive and negative control [79, 80]
Conclusion
The present study provide evidence that P. putida St-149D, P. fluorescens Ft-G43, B. subtilis Hyd-13Z, B. subtilis Hyd-01F and B. cereus Gb-T23 were compatible and effectively inhibited the growth of A. solani. The combination of PGPR strains with GPE suppress EB disease and improve tomato plant growth. Besides, higher levels of defensive enzymes, and phenolic compounds may have contributed to suppress EB infection. Therefore, based on in vitro and pot assays, the combination of the bacterial consortium (Ft-G43, Hyd-13Z, Hyd-01F, Gb-T23 and St-149 D) with GPE is a promising alternative to control EB disease in tomatoes.
Availability of data and materials
The datasets containing bacterial DNA sequances used in the current study deposited and are available in the National Center for Biotechnology Information repository under the link https://www.ncbi.nlm.nih.gov/nucleotide/. The submitted accessions No. are ON891846, ON878096, ON892078, ON892115 and ON892085.
References
Khan AL, Waqas M, Kang SM, Al-Harrasi A, Hussain J, Al-Rawahi A, Al-Khiziri S, Ullah I, Ali L, Jung HY, et al. Bacterial endophyte Sphingomonas sp. LK11 produces gibberellins and IAA and promotes tomato plant growth. J Microbiol. 2014;52(8):689–95.
Rasool M, Akhter A, Haider MS. Molecular and biochemical insight into biochar and Bacillus subtilis induced defense in tomatoes against Alternaria solani. Sci Hortic. 2021;285: 110203.
Ali S, Khan J, Jadoon A, Riaz M, Khan A. Evaluation of farmers socioeconomic characteristics influencing tomato output in district Peshawar, Khyber Pakhtunkhwa, Pakistan. Sarhad J Agric. 2020;36(3):894–9.
Babu AN, Jogaiah S. Ito S-i, Nagaraj AK, Tran L-SP: Improvement of growth, fruit weight and early blight disease protection of tomato plants by rhizosphere bacteria is correlated with their beneficial traits and induced biosynthesis of antioxidant peroxidase and polyphenol oxidase. Plant Sci. 2015;231:62–73.
Attia MS, El-Sayyad GS, Abd Elkodous M, El-Batal AI. The effective antagonistic potential of plant growth-promoting rhizobacteria against Alternaria solani-causing early blight disease in tomato plant. Sci Hortic. 2020;266: 109289.
El-Nagar A, Elzaawely AA, Taha NA, Nehela Y. The antifungal activity of gallic acid and its derivatives against Alternaria solani, the causal agent of tomato early blight. Agronomy. 2020;10(9): 1402.
Almeida F, Rodrigues ML, Coelho C. The still underestimated problem of fungal diseases worldwide. Front Microbiol. 2019;10:214.
Mohamed AA, Salah MM, El-Dein MMZ, EL-Hefny M, Ali HM, Farraj DAA, Hatamleh AA, Salem MZ, Ashmawy NA. Ecofriendly bioagents, Parthenocissus quinquefolia, and Plectranthus neochilus extracts to control the early blight pathogen (Alternaria solani) in tomato. Agronomy. 2021;11(5):911.
Hernández-Ochoa JS, Levin LN, Hernández-Luna CE, Contreras-Cordero JF, Niño-Medina G, Abelardo CM, Iosvany LS, Gutiérrez-Soto G. Antagonistic potential of Macrolepiota sp. against Alternaria Solani as causal agent of early blight disease in tomato plants. Gesunde Pflanzen. 2020;72(1):69–76.
O’Connell S, Rivard C, Peet MM, Harlow C, Louws F. High tunnel and field production of organic heirloom tomatoes: Yield, fruit quality, disease, and microclimate. HortScience. 2012;47(9):1283–90.
Faheed F, Abd-Elaah G, Mazen A. Alleviation of disease effect on tomato plants by heat shock and salicylic acid infected with Alternaria solani. Int J Agric Biol. 2005;7:783–9.
Agamy R, Alamri S, Moustafa MF, Hashem M. Management of tomato leaf spot caused by Alternaria tenuissima Wiltshire using salicylic acid and Agrileen. Int J Agric Biol. 2013;15(2):266.
Chaerani R, Groenwold R, Stam P, Voorrips RE. Assessment of early blight (Alternaria solani) resistance in tomato using a droplet inoculation method. J Gen Plant Pathol. 2007;73:96–103.
Latha P, Anand T, Ragupathi N, Prakasam V, Samiyappan R. Antimicrobial activity of plant extracts and induction of systemic resistance in tomato plants by mixtures of PGPR strains and Zimmu leaf extract against Alternaria solani. Biol Control. 2009;50(2):85–93.
Chavan VA, Yumlembam RA, Sewakram K, Borkar SG. Fungicide resistance in Alternaria leaf blight pathogen in tomato crop grown in Satara District. J Pharm Phytochemistry. 2017;6(6):1736–9.
Fawcett C, Spencer D. Plant chemotherapy with natural products. Annu Rev Phytopathol. 1970;8(1):403–18.
da Silva MLP, Moen FS, Liles MR, Feng Y, Sanz-Saez A. Orange peel in combination with selected PGPR strains as seed treatment can improve soybean yield under field conditions. Plant Soil. 2023;491:401–20.
Suriani NL, Suprapta DN, Indrayani AW, Herlambang S, Resiani NMD, AL-Shwaiman HA, Al Khulaifi MM, Elgorban AM, Datta R, Gunawan S. The synergistic action of three piper plant extracts and biofertilizer for growth promotion and biocontrol of blast disease in red rice. Sustainability. 2021;13(18): 10412.
Lim WY, Wong CW. Inhibitory effect of chemical and natural anti-browning agents on polyphenol oxidase from ginger (Z ingiber officinale Roscoe). J Food Sci Technol. 2018;55:3001–7.
Gao Y, Lu Y, Zhang N, Udenigwe CC, Zhang Y, Fu Y. Preparation, pungency and bioactivity of gingerols from ginger (Zingiber officinale Roscoe): a review. Crit Rev Food Sci Nutr. 2022;62:1–26.
Abdullahi A, Khairulmazmi A, Yasmeen S, Ismail I, Norhayu A, Sulaiman M, Ahmed O, Ismail M. Phytochemical profiling and antimicrobial activity of ginger (Zingiber officinale) essential oils against important phytopathogens. Arab J Chem. 2020;13(11):8012–25.
Bordoh PK, Ali A, Dickinson M, Siddiqui Y. Antimicrobial effect of rhizome and medicinal herb extract in controlling postharvest anthracnose of dragon fruit and their possible phytotoxicity. Sci Hortic. 2020;265:109249.
Kumar S, Stecher G, Tamura K. MEGA7: Molecular Evolutionary Genetics Analysis version 7.0 for bigger datasets. Mol Biol Evol. 2016;33(7):1870–4.
Zhang X, Gao B, Zheng Y, Hu X, Creamer AE, Annable MD, Li Y. Biochar for volatile organic compound (VOC) removal: Sorption performance and governing mechanisms. Biores Technol. 2017;245:606–14.
Fritz M, Jakobsen I, Lyngkjær MF, Thordal-Christensen H, Pons-Kühnemann J. Arbuscular mycorrhiza reduces susceptibility of tomato to Alternaria solani. Mycorrhiza. 2006;16:413–9.
Pii Y, Mimmo T, Tomasi N, Terzano R, Cesco S, Crecchio C. Microbial interactions in the rhizosphere: beneficial influences of plant growth-promoting rhizobacteria on nutrient acquisition process. A review. Biol Fertil Soils. 2015;51:403–15.
Backer R, Rokem JS, Ilangumaran G, Lamont J, Praslickova D, Ricci E, Subramanian S, Smith DL. Plant growth-promoting rhizobacteria: context, mechanisms of action, and roadmap to commercialization of biostimulants for sustainable agriculture. Front Plant Sci. 2018;9: 1473.
Kaur H, Nyochembeng LM, Mentreddy SR, Banerjee P, Cebert E. Assessment of the antimicrobial activity of Lentinula edodes against Xanthomonas campestris pv. vesicatoria. Crop Prot. 2016;89:284–8.
Leslie JF, Summerell BA. The Fusarium laboratory manual. John Wiley & Sons; 2008
Varma PK, Singh S, Gandhi S, Chaudhary K. Variability among Alternaria solani isolates associated with early blight of tomato. Commun Agric Appl Biol Sci. 2006;71(4):37–46.
Hibar K, Edel-Herman V, Steinberg C, Gautheron N, Daami-Remadi M, Alabouvette C, El Mahjoub M. Genetic diversity of Fusarium oxysporum populations isolated from tomato plants in Tunisia. J Phytopathol. 2007;155(3):136–42.
Fukui R, Schroth M, Hendson M, Hancock J. Interaction between strains of pseudomonads in sugar beet spermospheres and their relationship to pericarp colonization by Pythium ultimum in soil. Phytopathol. 1994;84(11):1322–30.
Dennis C, Webster J. Antagonistic properties of species-groups of Trichoderma: II. Production of volatile antibiotics. Trans Br Mycologic Soc. 1971;57(1):41-IN44.
Vincent J, Humphrey B. Taxonomically significant group antigens in Rhizobium. Microbiology. 1970;63(3):379–82.
Sharma SK, Kumar R, Vaishnav A, Sharma PK, Singh UB, Sharma AK. Microbial cultures: maintenance, preservation and registration. Modern tools and techniques to understand microbes. 2017. p. 335–67
Lelliott RA, Stead DE. Methods for the diagnosis of bacterial diseases of plants. Blackwell Scientific Publications; 1987. p. 216.
Aneja K. Experiments in microbiology, plant pathology, tissue culture and mushroom production technology. New Age International Limited; 2001. p. 568.
Warren YA, Citron DM, Merriam CV, Goldstein EJ. Biochemical differentiation and comparison of Desulfovibrio species and other phenotypically similar genera. J Clin Microbiol. 2005;43(8):4041–5.
Hayward A. A method for characterizing Pseudomonas solanacearum. Nature. 1960;186(4722):405–6.
Hugh R, Leifson E. The taxonomic significance of fermentative versus oxidative metabolism of carbohydrates by various gram negative bacteria. J Bacteriol. 1953;66(1):24–6.
Thankamani V, Dev M. Bacillus isolates VTGP. AD. 30808 Alcaligenes sp., Exiguobacterium sp., B. pumilus and B. fusiformis producing extracellular alkaline proteases, amylases and cellulases-a preliminary report. Res Biotechnol. 2011;2(1):20–30.
Howell C, Stipanovic R. Suppression of Pythium ultimum-induced damping-off of cotton seedlings by Pseudomonas fluorescens and its antibiotic, pyoluteorin. Phytopathology. 1980;70(8):712–5.
Sudisha J, Niranjana S, Sukanya S, Girijamba R, Lakshmi Devi N, Shekar Shetty H. Relative efficacy of strobilurin formulations in the control of downy mildew of sunflower. J Pest Sci. 2010;83:461–70.
Naz F, Rauf CA, Abbasi NA, Haque I, Ahmad I. Influence of inoculum levels of Rhizoctonia solani and susceptibility on new potato germplasm. Pak J Bot. 2008;40(5):2199–209.
Zheng H, Zhao J, Wang T, Wu X. Characterization of A lternaria species associated with potato foliar diseases in C hina. Plant Pathol. 2015;64(2):425–33.
Li J-G, Dong Y-H. Effect of a rock dust amendment on disease severity of tomato bacterial wilt. Antonie Van Leeuwenhoek. 2013;103:11–22.
McKinney H. A new system of grading plant diseases. J Agric Res. 1923;26(2):195–218.
Hiscox J, Israelstam G. A method for the extraction of chlorophyll from leaf tissue without maceration. Can J Bot. 1979;57(12):1332–4.
Holm-Hansen O, Riemann B. Chlorophyll a determination: improvements in methodology. Oikos. 1978;30:438–47.
Khan N, Bano A, Babar MA. Metabolic and physiological changes induced by plant growth regulators and plant growth promoting rhizobacteria and their impact on drought tolerance in Cicer arietinum L. PLoS ONE. 2019;14(3): e0213040.
Hammerschmidt R, Nuckles E, Kuć J. Association of enhanced peroxidase activity with induced systemic resistance of cucumber to Colletotrichum lagenarium. Physiol Plant Pathol. 1982;20(1):73–82.
Hyder S, Gondal AS, Rizvi ZF, Atiq R, Haider MIS, Fatima N, Inam-ul-Haq M. Biological control of chili damping-off disease, caused by Pythium myriotylum. Front Microbiol. 2021;12: 587431.
Whetten RW, Sederoff RR. Phenylalanine ammonia-lyase from loblolly pine: purification of the enzyme and isolation of complementary DNA clones. Plant Physiol. 1992;98(1):380–6.
Dhindsa RS, Plumb-Dhindsa P, Thorpe TA. Leaf senescence: correlated with increased levels of membrane permeability and lipid peroxidation, and decreased levels of superoxide dismutase and catalase. J Exp Bot. 1981;32(1):93–101.
Yu G, Sinclair J, Hartman G. Ber tagnol li BL Production of iturin A by Bacillus amyloliquefaciens suppressing Rhizoctonia solani. Soil Biol Biochem. 2002;34(7):955–63.
Khedher SB, Kilani-Feki O, Dammak M, Jabnoun-Khiareddine H, Daami-Remadi M, Tounsi S. Efficacy of Bacillus subtilis V26 as a biological control agent against Rhizoctonia solani on potato. CR Biol. 2015;338(12):784–92.
Zhang D, Yu S, Yang Y, Zhang J, Zhao D, Pan Y, Fan S, Yang Z, Zhu J. Antifungal Effects of Volatiles Produced by Bacillus subtilis Against Alternaria solani in Potato. Front Microbiol. 2020;11: 1196.
Karthika S, Varghese S, Jisha M. Exploring the efficacy of antagonistic rhizobacteria as native biocontrol agents against tomato plant diseases. 3 Biotech. 2020;10:1–17.
El Khetabi A, Lahlali R, Ezrari S, Radouane N, Nadia L, Banani H, Askarne L, Tahiri A, El Ghadraoui L, Belmalha S. Role of plant extracts and essential oils in fighting against postharvest fruit pathogens and extending fruit shelf life: a review. Trends Food SciTechnol. 2022;120:402–17.
Polo KJJ, Campos HLM, Olivera CC, Nakayo JLJ, Flores JWV. Biofungicide for the control of botrytis cinerea and fusarium oxysporum: a laboratory study. Chem Eng Trans. 2021;87:517–22.
Rizwana H. Exploiting antifungal potential of ginger for the management of Alternaria alternata, the cause of leaf spot disease of spinach. Mycopath. 2016;13(2):97–104.
Xi K-Y, Xiong S-J, Li G, Guo C-Q, Zhou J, Ma J-W, Yin J-L, Liu Y-Q, Zhu Y-X. Antifungal Activity of Ginger Rhizome Extract against Fusarium solani. Horticulturae. 2022;8(11): 983.
Kisiriko M, Anastasiadi M, Terry LA, Yasri A, Beale MH, Ward JL. Phenolics from medicinal and aromatic plants: Characterisation and potential as biostimulants and bioprotectants. Molecules. 2021;26(21): 6343.
Hyder S, Gondal AS, Rizvi ZF, Riaz N, Iqbal R, Ali I, Ali A, Eldin SM. Use of botanical extracts and bacterial inoculants for the suppression of Alternaria solani causing Early Blight disease in Tomato. Research Squire (PrePrint) 2023. Available at SSRN 4536473.
Cendales TC, González CAR, Cuásquer CPV, Alzate OAT, Rodríguez AH. Efecto de Bacillus sobre la germinación y crecimiento de plántulas de tomate (Solanum lycopersicum L). Acta Biológica Colombiana. 2017;22(1):37.
Rivera-Conde MI, Aranda-Ocampo S, Carrillo-Castañeda G, Gijón-Hernández AR, Bueno-Aguilar GM. Effect of fluorescent Pseudomonas on tomato seed germination and seedling vigor. Revista Chapingo Serie horticultura. 2018;24(2):121–31.
Widnyana IK, Javandira C. Activities Pseudomonas spp. and Bacillus sp. to stimulate germination and seedling growth of tomato plants. Agric Agric Sci Proc. 2016;9:419–23.
Ureche MAL, Pérez-Rodriguez MM, Ortiz R, Monasterio RP, Cohen AC. Rhizobacteria improve the germination and modify the phenolic compound profile of pepper (Capsicum annum L.). Rhizosphere. 2021;18: 100334.
Pérez-García L-A, Sáenz-Mata J, Fortis-Hernández M, Navarro-Muñoz CE, Palacio-Rodríguez R, Preciado-Rangel P. Plant-Growth-Promoting Rhizobacteria Improve Germination and Bioactive Compounds in Cucumber Seedlings. Agronomy. 2023;13(2): 315.
Carrera-Castaño G, Calleja-Cabrera J, Pernas M, Gómez L, Oñate-Sánchez L. An updated overview on the regulation of seed germination. Plants. 2020;9(6): 703.
Minchev Z, Kostenko O, Soler R, Pozo MJ. Microbial consortia for effective biocontrol of root and foliar diseases in tomato. Front Plant Sci. 2021;12:01–12.
Singh UB, Sahu A, Sahu N, Singh R, Renu S, Singh D, Manna M, Sarma B, Singh H, Singh K. Arthrobotrys oligospora-mediated biological control of diseases of tomato (Lycopersicon esculentum Mill.) caused by Meloidogyne incognita and Rhizoctonia solani. J Appl Microbiol. 2013;114(1):196–208.
Xu X, Wang Y, Lei T, Sohail MA, Wang J, Wang H. Synergistic effects of Bacillus amyloliquefaciens SDTB009 and difenoconazole on Fusarium wilt of tomato. Plant Dis. 2022;106(8):2165–71.
Albalawi MA, Abdelaziz AM, Attia MS, Saied E, Elganzory HH, Hashem AH. Mycosynthesis of Silica Nanoparticles Using Aspergillus niger: Control of Alternaria solani Causing Early Blight Disease, Induction of Innate Immunity and Reducing of Oxidative Stress in Eggplant. Antioxidants. 2022;11(12): 2323.
Awan ZA, Shoaib A, Iftikhar MS, Jan BL, Ahmad P. Combining biocontrol agent with plant nutrients for integrated control of tomato early blight through the modulation of physio-chemical attributes and key antioxidants. Front Microbiol. 2022;13: 807699.
Mishra N, Sundari SK. Native PGPM consortium: a beneficial solution to support plant growth in the presence of phytopathogens and residual organophosphate pesticides. J Bioprocess Biotech. 2015;5(202):2.
Al-Ani RA, Adhab MA. Bean yellow mosaic virus (BYMV) on broadbean: Characterization and resistance induced by Rhizobium leguminosarum. J Pure Appl Microbiol. 2013;7(1):135–42.
Wallis CM. Galarneau ER-A: Phenolic compound induction in plant-microbe and plant-insect interactions: a meta-analysis. Front Plant Sci. 2020;11:580753.
Cochard B, Giroud B, Crovadore J, Chablais R, Arminjon L, Lefort F. Endophytic PGPR from tomato roots: isolation, in vitro characterization and in vivo evaluation of treated tomatoes (Solanum lycopersicum L.). Microorganisms. 2022;10(4): 765.
Adedayo AA, Babalola OO, Prigent-Combaret C, Cruz C, Stefan M, Kutu F, Glick BR. The application of plant growth-promoting rhizobacteria in Solanum lycopersicum production in the agricultural system: a review. PeerJ. 2022;10: e13405.
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The authors extend their appreciation to the Researchers supporting project number (RSP2024R185), King Saud University, Riyadh, Saudi Arabia.
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Open Access funding enabled and organized by Projekt DEAL. Researchers supporting project numbers (RSP2024R185), King Saud University, Riyadh, Saudi Arabia and (373/IPFP-II(Batch-I)/SRGP/NAHE/HEC/2020/38,35), Higher Education Commission (HEC), Islamabad, Pakistan.
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Conceptualization, S.H., A.S. and A.S.G.; methodology, S.H., A.S.G. and Z.F.R.; soft-ware, N.R.; investigation, S.H.; writing—original draft preparation, S.H., R.I. and A.R.K; writing—review and editing, A.S.G., M.S.E., K.M.A., M.H.R. and M.R.; visualization, M.H.R. and R.I.; funding acquisition, M.H.R., M.R., R.I., M.S.E, and K.M.A. All of the authors contributed significantly to the completion of this review, conceiving and designing the review, and writing and improving the paper.
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Hyder, S., Gondal, A.S., Sehar, A. et al. Use of ginger extract and bacterial inoculants for the suppression of Alternaria solani causing early blight disease in Tomato. BMC Plant Biol 24, 131 (2024). https://doi.org/10.1186/s12870-024-04789-z
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DOI: https://doi.org/10.1186/s12870-024-04789-z