Abstract
In the current study, 51 endophytic bacteria were isolated from 5 different xerophytic plants. Their drought tolerance properties were screened in vitro, and from these, four endophytes with tolerance up to − 1.5 MPa water potential were further selected and identified as Acinetobacter sp. Eo3, Pseudomonas sp. Ni5, Bacillus safensis Ni7, and Stenotrophomonas sp. C3. Due to biosafety concern, Acinetobacter sp. Eo3 and Pseudomonas sp. Ni5 were excluded from further investigation, while B. safensis Ni7 and Stenotrophomonas sp. C3 were subjected to detailed study. The drought tolerance properties of these endophytes were evaluated in vivo using Capsicum annuum L. by analysing the growth parameters (leaf number, root number, shoot length, and plant fresh weight) as well as physiological and biochemical parameters (stomatal index, relative water content, chlorophyll content, and carbohydrate accumulation) of bacteria-treated and control seedlings. Here, treatment with B. safensis Ni7 and Stenotrophomonas sp. C3 was found to result in statistically significant enhancement (P ≤ 0.001) of the measured parameters of plants when compared with the control groups. In the case of fresh weight itself, Ni7 and C3 treatment was found to result in values of 157.76 and 142.8 mg, respectively, and was statistically significant enhancement as the same for nutrient broth and distilled water control were 73.3 mg and 70.5 mg only. Additionally, the endophyte-treated seedlings displayed significant improvement in other growth parameters even under induced drought stress. These findings highlight the potential of xerophytic-derived bacterial endophytes to have significant role in mitigating the drought stress effects in plants with the promises for field application.
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Introduction
Drought is a common stress factor that reduces the global agricultural production. Approximately 42% of the Indian land area is affected by drought, with 6% of this region experiencing extremely dry conditions, which substantially reduces the agricultural output. Climate change and global warming further accelerate the intensity of drought and its after effects [1]. As sessile systems, plants are continuously and directly subjected to the severity of drought stress and hence it is one of the most severe abiotic stress encountered by plants [2]. Numerous methods have been preconized to impart drought tolerance in agriculturally important crops that encompasses the traditional breeding, genetic engineering, and various agronomic cultural practices. Other technologies including molecular breeding and genome editing tools are still at its infancy and yet to make an impact on crop productivity especially the drought tolerance. Therefore, there is an urgent requirement of alternative strategies to impart drought tolerance in economically important crop plants [3]. Depending on the severity and duration of exposure, low-moisture stress in plants can lead to hampering of crop physiological as well as biochemical performance with cascade of phenotypes such as physiological wilting and retarded plant growth, reduced quality, and yield [4]. However, long-term drought stress can have catastrophic effects, resulting in the breakdown of chloroplasts and starch granules and altered photochemical and photorespiratory activities [5, 6].
Plant microbiome has recently been identified to significantly influence the plant growth and response to the stress factors. Various genera of bacteria, like Bacillus, Serratia, Pseudomonas, Paenibacillus, etc., have already been reported to get associated with plants as endophytes, rhizobacteria or phyllosphere organisms [7,8,9]. The functional contribution by beneficial bacteria can be considered to empower plants to mitigate the effects of abiotic stress factors. At the same time, the global market for microbial formulations to enhance plant growth and yield under biotic and abiotic stress conditions is increasing. Using microorganisms for plant stress management is effective as it is sustainable and environmentally friendly. Recent studies have also been reported the plants surviving in drought-prone areas to have systematically shaped microbiomes to retain the valuable colonizers [10]. Thus, it is presumed that endophytes colonizing in arid plants could have an advantage over others to adapt in the arid environment to confer beneficial effects to the cultivated plants. However, attempts are limited to exploit the endophytic bacteria of arid plants for mitigating the drought in agriculturally important crops. Given the impact of drought on plant growth and productivity, using endophytes to reduce the drought severity is a practicable, dependable, and reliable strategy [11]. In the current study, endophytes were isolated from xerophytic Nerium indicum L., Euphorbia hirta L., Emblica officinalis L., Calotropis gigantea L., and Cereus hexagonus (L.) Mill by expecting such microorganisms present in these plants to have the ability to confer resistance to biotic and abiotic stress factors along with their plant growth-promoting properties. Because, endophytes have already been reported to have an essential role in host health, food supply, and stress management executed through numerous ways [12, 13]. They can improve the growth characteristics of plants, allowing them to absorb more water [14,15,16]. Increased metabolism of specific amino acids, proteins, and other secondary metabolites [17, 18] has also been linked to the endophyte-mediated drought resistance in plants. In addition, the regulation of abscisic acid concentration [19, 20] and osmotic capacity [21,22,23,24] via the accumulation of osmolytes, such as carbohydrates, has been linked to drought resistance in endophyte-treated plants.
In the present study, Capsicum annuum L. was chosen to investigate the drought-alleviating mechanisms of the selected endophytes. This is an economically important crop and already known to be sensitive to drought, as its optimal growth and metabolism require adequate water. By inducing the colonization of potential endophytes on drought-sensitive plants, this research intends to improve their drought tolerance. Endophyte-based drought control will be a cost-effective and environmentally favourable method under current conditions. Based on the results of the study, the endophytes selected for the study may have significant agricultural implications to be exploited for managing arid stress in economically important plants.
Materials and Methods
Collection of Plant Samples
Stem and leaf samples from five different xerophytic plants were collected from the garden of the Department of Botany, Catholicate College, Pathanamthitta, Kerala, India. These included Nerium indicum L., Euphorbia hirta L., Emblica officinalis L., Calotropis gigantea L., and Cereus hexagonus (L.) Mill.
Isolation of Endophytic Bacteria from Selected Plant Samples
According to the previous methodology, stem and leaves of selected plants were used to isolate the endophytic bacteria [25]. Here, the plant parts were cleaned with distilled water and then treated with Tween 80 for 10 min. After that, the samples were treated with 2% sodium hypochlorite for 10 min, followed by 70% alcohol for 30 s. The plant parts were finally washed several times with sterile distilled water, and the last wash was plated onto nutrient agar (NA) medium as control. The surface-sterilized plant samples were further macerated, and the extract was subjected to serial dilution and plating. In addition, the surface-sterilized plant materials were also directly inoculated on nutrient agar. All the plates were further incubated for 3–4 days at room temperature and observed periodically. Morphologically distinct colonies obtained from these were selected, purified, and used for further studies.
Screening of Endophytic Bacterial Isolates for Drought Tolerance Properties
Screening of the isolates for drought stress tolerance was performed with trypticase soy broth (TSB) supplemented with various concentrations of poly ethylene glycol (PEG) 6000 to provide the varying water potentials of − 0.25, − 0.5, − 0.75, − 1, − 1.25, and − 1.5 MPa (Megapascal). The overnight grown cultures of all the isolated endophytic bacteria with the adjusted optical density (OD) of 0.1 at 600 nm were inoculated into the above media. Growth of the isolates at various stress levels was then estimated by measuring the OD at 600 nm after incubating it at 28 °C for 24 h [26]. The relative growth rate of each isolate at maximum water-stressed condition (− 1.5 MPa) was then calculated [27].
Identification of Selected Endophytic Bacteria
After in vitro drought tolerance analysis, all the selected endophytic bacteria were subjected to various morphological and biochemical tests as per Bergey’s manual of systematic bacteriology. For the biochemical characterization, a combination of 12 biochemical tests (HiAssorted™ KB002, HiMedia, Mumbai, India) were used. These tests were based on the principle of change in pH, change in colour, and utilization of the substrate by bacterial isolates. For molecular identification, genomic DNA was extracted from selected bacterial isolates using HiPurA® Bacterial Genomic DNA Purification Kit (MB505-50PR), HIMEDIA. The presence of genomic DNA was further confirmed by agarose gel electrophoresis. The genomic DNA extracted was used for PCR using the universal primers specific to 16S rRNA, such as 16S F (5′- GAG TTT GAT CCT GGC TCA G-3′) and 16S R (5′-GAT ATT ACC GCG GCG CCT G-3′) [25]. The formation of PCR products was confirmed by agarose gel electrophoresis followed by sequencing at AgriGenome, Kakkanad, Cochin, Kerala. The sequence data thus obtained were further subjected to analysis in EzBioCloud. The sequence data of type strains of each isolates was collected from LPSN database and used for the phylogenetic analysis using the Maximum likelihood method with 1000 bootstraps by MEGA X [28].
In planta Drought Tolerance Analysis on C. annuum L. Seedlings Through the Supplementation of Selected Bacteria
After the biochemical and molecular identification of biologically active endophytes, two of the four selected endophytes were omitted due to biosafety concerns and the other two were selected for further investigation. To study the in vivo drought tolerance effects of the selected endophytes, seeds of C. annuum were surface-sterilized using 1% sodium hypochlorite solution for 10 min followed by treatment with 70% ethanol for 30 s. The seeds were then washed several times with sterile distilled water, soaked in sterile distilled water for three days, and allowed to germinate [25]. Here, four distinct experimental groups were used. The first and second groups were kept as the negative controls, in which the seeds were treated with distilled water and uninoculated nutrient broth, respectively. The third group comprised of seeds primed with Ni7 and the fourth group included seeds primed with C3. Each group consisted of ten seeds, organized into triplicates. For the third and fourth groups, Ni7 and C3 were used at a concentration of 108 CFU/mL for the treatment. Here, the germinated seedlings of C. annuum were dipped in respective bacterial cultures of third and fourth groups for 2 h. In the same way, seeds of first and second groups were treated with respective controls for 2 h. All the treated and control seedlings were planted in grow bags containing sterile soil. Following four weeks of growth under normal conditions, a drought period was induced by withholding the watering for 11 days. After the induced drought period, the plants were harvested and subjected to assessment for various growth parameters, including leaf number, root number, shoot length, and fresh weight. Moreover, physiological attributes such as stomatal index, relative water content, chlorophyll content, and carbohydrate levels were also evaluated [25].
Physiological and Biochemical Analyses
Physiological and biochemical parameters such as stomatal index, relative water content, chlorophyll content, and carbohydrate accumulation were checked for the treated plants.
For the analysis of the stomatal index, leaf materials obtained from each treatment sets including the controls were gently cleaned with running tap water to eliminate the dust and debris. The bottom epidermal layer was further carefully pulled off with fingertips, followed by staining with safranine solution and microscopic examination. The number of stomata present in the microscopic field was then counted three times using various preparations of the same experimental set and the stomatal index was calculated as described before [29].
Stomatal index (%) = S/(S + E) × 100.
S is number of stomata in the microscopic field, E is number of epidermal cells in the microscopic field.
At the same time, relative water content of plant samples was analysed by using the previously described method [30],
RWC = (Fresh weight − Dry weight)/(Turgid weight − Dry weight) × 100.
Fresh weight: the weight of the sample immediately after the harvest, Dry weight: weight of the sample after drying. Turgid weight: weight of the sample after soaking it in water for 3/4 h.
For the chlorophyll estimation, 500 mg of dried leaf tissue was suspended in 2 mL of DMSO (dimethyl sulfoxide) followed by incubation for 20 min at 60 °C in a water bath. The supernatant was then collected, and 3 mL of DMSO was further to the residue. After the processing described above, the first and second supernatants were pooled and made up to 10 mL with DMSO and the absorbance was measured at 663, and 645 nm with DMSO as the control [31]. The chlorophyll concentration was estimated using the following equation as described below [32].
Chlorophyll a/tissue (mg/g) = 12.7 (A663) − 2.69 (A645) × V/1000 × W,
Chlorophyll b/tissue (mg/g) = 22.9 (A645) − 4.68 (A663) × V/1000 × W,
Total chlorophyll/tissue (mg/g) = 20.2 (A645) + 8.02 (A663) × V/1000 × W.
A is absorbance at specific wavelength, V is final volume of chlorophyll extract in DMSO, W is fresh weight of tissue extracted.
For the carbohydrate accumulation analysis, quantification was done using Anthrone method. Here, anthrone reagent was made by dissolving the anthrone powder in concentrated H2SO4 at a ratio of 2 g anthrone for 1 L conc. H2SO4. For the analysis, 1 g of plant tissue was extracted and resuspended in 10 mL of distilled water. 5 mL of anthrone reagent was added to 1 mL of the test sample while the blank was prepared by 1 mL distilled water with 5 mL of reagent. The standard solution was composed of 1 mL glucose (200 g/mL) solution and 5 mL of the reagent. Following the experiment, the optical density (OD) at 620 nm was measured. From the standard curve plotted with known concentrations of glucose, the carbohydrate concentration was calculated as described before [33].
Statistical Analysis
Statistical analysis of variance (One-way ANOVA) was performed using GraphPad Prism 5.0. The significant difference among all the experimental data were compared with Dunnett’s multiple comparison tests [34].
Results
Isolation of Endophytic Bacteria from Different Plant Samples
In the study, a total of 51 distinct bacterial isolates were obtained from N. indicum (8), E. hirta (8), E. officinalis (12), C. gigantea (4), and C. hexagonus (19) through serial dilution and plating. The absence of microbial growth in the control plates after one week of incubation further confirmed the obtained isolates as endophytes.
Screening of Endophytic Bacterial Isolates for Drought Tolerance
All the 51 bacterial isolates were screened in vitro for the drought tolerance property by culturing it in trypticase soy broth supplemented with different concentrations of PEG 6000. Here, four isolates (Eo3, Ni5, Ni7, and C3) could be observed to tolerate up to − 1.5 MPa water potential during their growth in the selected medium. The growth was calculated by taking the OD at 600 nm and the relative growth of each isolate was calculated by comparing their growth in non-stressed medium (Fig. 1). Here the isolate Eo3 was found to have maximum relative growth under stressed condition among the four, followed by Ni7. The isolate C3 was shown to have growth comparable to Ni5. The difference between growth under non-stressed and a maximum stressed condition was chosen as measurement for the drought tolerance activity [35].
Identification of Selected Endophytic Bacteria
The isolates Eo3, Ni5, and C3, which were found to be Gram-negative and the Gram-positive Ni7 were selected for further identification. Here, oxidase and catalase tests were found to be positive for Ni5 and Ni7, and both were negative for C3. However, Eo3 was found to be oxidase-negative and catalase-positive. The identification of selected endophytic bacteria was confirmed further by sequencing of 1500 bp region of its 16S rRNA gene. The sequence data were further used for the identification using EzBioCloud (https://www.ezbiocloud.net/), and from this, Eo3 was found to have 99.57% similarity with Acinetobacter variabilis NIPH2171, Ni5 to have 100% identity with Pseudomonas otitidis MCC10330, the Ni7 with 100% identity to Bacillus safensis FO-36b and C3 with 99.11% similarity to Stenotrophomonas maltophilia MTCC 434 (Table 1). All the sequence data were submitted to NCBI GenBank under the accession numbers OR290931, OR290932, OR290933, and OR290934, respectively, for Acinetobacter sp. Eo3, Pseudomonas sp. Ni5, B. safensis Ni7, and Stenotrophomonas C3 sp. Further, phylogenetic analysis has been done with selected type strains from LPSN using the Maximum likelihood method with1000 bootstraps by MEGA X (Fig. 2).
In Planta Drought Tolerance Analysis on C. annuum L. Seedlings Through the Supplementation of Selected Bacteria
From the isolated bacteria, B. safensis Ni7 and Stenotrophomonas C3 sp. were selected for further detailed analysis. The isolates Acinetobacter sp. Eo3, P. otitidis Ni5 were omitted from further study due to biosafety concern with them. Drought was induced in 4-week-old C. annuum seedlings for 11 days. After this, the control plants were observed to become withered and desiccated, whereas the B. safensis Ni7 (Ni7) and Stenotrophomonas C3 sp. (C3), treated plants were not significantly damaged (Fig. 3). Upon comparison with the distilled water (DW) and nutrient broth (NB)-treated control plants, endophyte-treated plants had a considerable increase in their fresh weight. Regarding the leaf number, Ni7-treated seedlings showed an average value of 5.4 and was 5.6 for the C3 treated. These were statistically significant (degree of freedom, DF = 3, F value, F = 57.90, and P value, P < 0.001) when compared with the 4.1 and 3.33 observed for the NB, and DW treated control plants. The highest number of roots was also observed for the Ni7 treatments, with the statistically significant value of 4.8 (degree of freedom, DF = 3, F value, F = 23.48, and P value, P < 0.001). The values for the same was 3.03 for the distilled water-treated plants and 3.6 for NB-treated plants. For the shoot length, the Ni7 and C3-treated seedlings showed values of 6.82 and 6.61 cm (degree of freedom, DF = 3, F value, F = 37.42, and P value, P < 0.001) and was significantly high when compared to the 5.15 and 5.88 cm values obtained for the DW- and NB-treated plants, respectively. The overall fresh weight of the seedlings was also significantly high for Ni7 treated (157.76 mg), and C3 treated (142.8) seedlings (degree of freedom, DF = 3, F value, F = 86.81, and P value, P < 0.001). Because the same for DW- and NB-treated seedlings were having values of only 70.5 and 73.3 mg, respectively (Fig. 4a and b).
Physiological and Biochemical Analyses
Besides the above-mentioned morphological parameters, the selected physiological and biochemical parameters were also analysed for the treated plants (Table 2). Here, Ni7-treated seedlings were found to have the highest stomatal index of 21.72, while the same for C3-treated, DW-treated, NB-treated seedlings were 18.37, 15.009, and 18.4, respectively. The Ni7-treated seedlings could be least affected by the induced drought stress when compared with others by maintaining their internal water content. In others, the stomata might have decreased to reduce the water loss through stomatal openings under the induced drought stress condition. The Ni7-treated seedlings also exhibited the highest RWC of 61.43. In contrast, the DW-treated seedlings exhibited the lowest RWC of 30.31 and the same for C3 and NB-treated seedlings were 48.97 and 43.41, respectively. The results of chlorophyll estimation under drought stress indicated the seedlings treated with Ni7 to have higher photosynthetic activity (0.4041 mg/g) followed by C3-treated seedlings with chlorophyll content of 0.3206 mg/g. At the same time, NB-treated and DW-treated seedlings showed a chlorophyll content of 0.2591 and 0.2002 mg/g, respectively. Carbohydrate accumulation was also analysed in the study for each experimental set. Since the carbohydrates can function as osmolytes under stress conditions, its accumulation might provide mechanistic insight into the drought resistance observed in the study. Here, Ni7-treated seedlings were found to have high accumulation of carbohydrates (930 µg/ml), followed by C3 treated seedlings (926 µg/ml). At the same time, DW-treated seedlings showed the lowest concentration of carbohydrates (690 µg/ml). For NB-treated seedlings (850 µg/ml), it was also lower than the Ni7 and C3 treatments. From the results of the study, B. safensis Ni7 can be considered to have enhanced efficiency than the Stenotrophomonas C3 sp. in providing the drought tolerance to C. annuum.
Discussion
Biotic and abiotic stress factors are the most influential environmental factors affecting the agricultural productivity worldwide. Due to the climatic changes, drought has been one of the common abiotic stresses that negatively influence the plant growth. The conventional breeding and genetic engineering methods which are routinely being employed to mitigate the negative effects of drought stress on plants are not sufficient to successfully manage the stress under field conditions. Therefore the application of endophytic bacteria, which have already been demonstrated to have protective effects on various plant species have immense applications to be exploited for the same. Hence, the study has been designed to isolate drought-resistant endophytes from various xerophytic plants in order to analyse the translation of their drought-protective properties to sensitive plants. Drought stress could reduce the soil water content, which further increases the salt concentration and, consequently, the osmotic stress and ion toxicity in plants. Drought can also severely affect the plant physiology, leaf structure, nutrient uptake, photosynthetic activity, and seedling germination [17, 36]. Various strategies have been employed by plants to deal with the drought-induced stress. As part of this, plants have been reported to induce a cascade of events involving signal transduction, induction of stress-responsive genes, activation or inactivation of functional proteins, and responses in specific cell organelles such as chloroplasts, mitochondria, and peroxisomes [36]. Plants have also been reported to secrete stress hormones and reactive oxygen species (ROS) to regulate the cellular physiology, which allows plants to function normally [37, 38]. However, only limited reports are available on the use of beneficial microbes for plant drought management. It is already acknowledged that plant microbial communities play a crucial role in maintaining or enhancing the plant growth and fitness under diverse environmental conditions. However, using beneficial microbes for the drought management has received little attention [38]. Studies have reported the remarkable potential of endophytes in drought stress mitigation and growth promotion in plants. A recent study reported that the property of Paenibacillus polymyxa and Fusarium oxysporum to alleviates drought stress and enhances plant growth, make them suitable candidates for utilization as biofertilizers [39]. According to another study, it is recommended to inoculate Festuca ovina seeds with Azotobacter and Pseudomonas in order to enhance their growth and development characteristics, particularly under drought conditions [40].
The current study evaluated two endophytic bacterial strains, B. safensis Ni 7 and Stenotrophomonas C 3 sp., for their drought tolerance effects in C. annuum L. seedlings, as both were demonstrated to have in vitro drought tolerance. A recent study has reported that Bacillus wiedmannii, a rhizobacterium isolated from the wheat rhizosphere, exhibits remarkable potential in enhancing the growth properties, including germination percentage (PG), germination rate (GV), and seed vigour index (SV), in wheat plants under water-deficit conditions [41]. The application of Cronobacter Y501, a plant growth-promoting rhizobacterium, has been found to optimize various growth attributes of maize, including biomass, plant height, and root viability in drought environments. The bacterial inoculation also facilitated the recovery of chlorophyll content, reduction in MDA accumulation, and activation of SOD, catalase, and peroxidase [42]. The potential of endophytic bacteria to adapt to the altered osmotic conditions is a crucial factor in determining their ability to survive and support plant growth under harsh environments. The accumulation of suitable solutes/osmolytes such as carbohydrates, glutamate, proline, and glycine during their growth in PEG 6000-containing media might have accounted for the drought tolerance of B. safensis Ni7 and Stenotrophomonas C3 sp. as per previous report [43]. Exopolysaccharides, oxidase, carbonic anhydrase, and catalase synthesis by bacteria under the water-stressed conditions have already been reported previously [44,45,46]. Several endophytic bacterial strains isolated from Ananas comosus, such as Bacillus sp., Providencia sp., and Staphylococcus spp., have also been demonstrated to enhance the drought tolerance, growth, and disease resistance in Vigna radiata [26, 45]. Endophytic bacterial strains isolated from other plant species have also been demonstrated to confer drought tolerance up to − 1.02 matric potential [26]. Four endophytic bacteria isolated in the current study such as B. safensis Ni7, Stenotrophomonas C3 sp., Acinetobacter sp. Eo3, and P. otitidis Ni5 have also been shown to have drought tolerance up to − 1.5 MPa. The in planta analysis on 4-week-old C. annuum seedlings using the selected bacteria B. safensis Ni7 and Stenotrophomonas sp. C3 further confirmed their superior drought tolerance properties. Here, the control plants began to wilt on the third day under simulated drought conditions, whereas the bacteria-treated plants remained healthy. In a previous study, S. maltophilia was identified for enhancing the drought tolerance in the Gemiza-9 wheat cultivar [47].
Plants have already been reported to use diverse mechanisms for drought stress management. The changes in the root architecture are considered to be one of the primary strategies used by plants for increasing the drought resistance [46]. To adapt to the changing environment, roots can alter their morphology and structural properties [36, 48]. Osmotic adjustment is another strategy used by plants to overcome the destruction caused by the drought stress. Here, the active accumulation of carbohydrates and organic or inorganic solutes is one of the essential physiological responses considered to be activated under drought stress [49]. Hence, the concentration of carbohydrates accumulated in treated plants was also calculated in the present study. Here, endophyte-treated plants were found to accumulate more carbohydrates than the control plants. The relative water content of plants has also been studied to determine their ability to retain water. Compared to other seedlings, those treated with B. safensis Ni7 was observed to have a higher RWC, and it might be one of the most effective criteria to evaluate the plant tissue under water deficiency [50].
From the results of the current study, drought resistance and plant growth-promoting properties of endophytic bacteria might have been favoured the plant growth under the induced drought stress especially in the case of B. safensis Ni7. Further research is required to identify the active drought resistance mechanisms induced in endophyte-treated plants to translate these for field application.
Conclusions
The potential role of bacterial endophytes has been less investigated with respect to drought stress management. Thus, the current study has demonstrated the endophytic bacterial strains to have the potential to alleviate the drought stress in C. annuum seedlings through diverse mechanisms. Here, two endophytic bacteria isolated from the xerophytic plants were found to have the ability to protect plants from drought stress. By treating the isolated bacteria with C. annuum seedlings, the seedlings were found to withstand the drought conditions. Based on the morphological and physiological characteristics of endophyte-treated and drought protected plants, there is great scope for translating these to manage the drought tolerance in drought-sensitive plants under field conditions. However, future investigations at the omics level are required to unravel the global mechanisms involved to explore their potential in other crops for the fulfilment of the goal of sustainable crop production.
Data Availability
All data and material were transparent in the study.
Code Availability
Not applicable.
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The authors acknowledge KSCSTE-PAIR Project for funding this study and KSCSTE SRS for the instrumentation support.
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EKR and JK contributed to the study conception and design. Experiments, analysis, and first draft of the manuscript were prepared by SJ. The manuscript was revised and corrections were included by EKR. All authors commented on the previous versions of the manuscript. All authors read and approved the final manuscript.
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Four endophytic bacterial species 16S rRNA gene sequences were deposited in NCBI with the accession numbers Acinetobacter sp. Eo3 (OR290931), Pseudomonas sp. Ni 5 (OR290932), Bacillus safensis Ni 7(OR290933), and Stenotrophomonas sp. C3 (OR290934).
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Juby, S., Krishnankutty, R.E. & Kochupurakkal, J. Drought-Alleviating Effects of Endophytic Bacteria Isolated from Xerophytic Plants on Capsicum annuum L. Seedlings. Curr Microbiol 80, 403 (2023). https://doi.org/10.1007/s00284-023-03494-8
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DOI: https://doi.org/10.1007/s00284-023-03494-8