1. Introduction
Sugar beet (
Beta vulgaris var.
saccharifera, L.) serves as an essential and indispensable sugar supply for the natural sweetener industry. Due to its lower water consumption compared to sugar cane, Egypt is focusing on expanding its domestic sugar production by fostering sugar beet cultivation to bridge the sugar deficit. However, the sugar crop faces recurring challenges from various biotic pathogens including fungi, bacteria, viruses, and nematodes, leading to substantial declines in production [
1,
2,
3,
4].
Fusarium species are among the most dangerous fungi that cause crop root infections, which diminish root production as well as sugar percentage and juice purity [
5]. These pathogens cause different destructive diseases on the crop including Fusarium yellows triggered by
F. oxysporum f. sp.
betae [
6], Fusarium root rot triggered by
F. oxysporum f. sp.
radicis-betae [
7,
8], Fusarium stalk rot induced by
F. solani [
9], and the rotting of stored beet root caused by
F. culmorum,
F. cerealis,
F. redolens, and
F. graminearum [
10].
Fusarium root rot has become increasingly common, particularly across numerous sugar beet growing areas, potentially as a result of the increased planting of susceptible varieties. The disease is distinguished by leaf withering, interveinal chlorosis, and discoloration of the root’s vascular tissues, often leading to the death of the plant [
11]. Furthermore, the pathogen produces an extensive amount of macroconidia, microconidia, and chlamydospores that may persist in the soil for more than 10 years and infect over 80% of sugar beet cultivars [
12]. Given the toxicity potential, the highly diverse range of Fusarium species associated with sugar beet, and economic losses, crop management against these pathogens is critical. Although chemical fungicides are commonly employed to manage many plant diseases, their abuse and indiscriminate usage have resulted in severe impacts on human, animal, and environmental health. As a result, its applicability should be restricted [
3]. Furthermore, climate change and the emergence of fungicide resistance are also reducing the efficacy of synthetic chemicals. Biological management has evolved as a viable, effective, and safe alternative technique for managing fungal phytopathogens in recent decades [
13]. A novel approach in disease management and plant growth enhancement entails utilizing bacterial and fungal bioagents instead of relying on synthetic chemical inputs [
14,
15,
16]. Isolating microorganisms, particularly actinobacteria, stands out due to their capability to produce secondary metabolites like antibiotics and extracellular enzymes. This method is highly efficient and effective in the discovery of new bioactive metabolites [
17]. Almost 80% of antibiotics are derived from actinobacteria, mostly from the genera
Streptomyces and
Micromonospora [
18,
19].
Streptomyces alone is accountable for roughly 75% of most bioactive compounds, which encompasses antibiotics [
20,
21]. The capacity of this genus to synthesize antibiotics and various other bioactive components provides an evolutionary advantage, allowing it to adapt to various and variable stressful conditions. Furthermore, because of the complexity of their metabolism, they have been able to colonize many ecosystems and employ a wide array of carbon and nitrogen sources.
In the same regard, Actinobacteria, mainly
Streptomyces, have emerged as crucial contributors to play a significant role in controlling soil-borne plant pathogens in rhizosphere soil. They achieve this by generating enzymes that degrade fungal cell walls as well as producing antifungal compounds [
13,
22]. Additionally, actinobacteria may safeguard plant roots from infections and stimulate plant development through the release of plant growth-promoting compounds, minerals, and nutrients, or boosting the proliferation of beneficial microbes [
23,
24]. Actinobacteria’ modes of action for plant root protection have been reported to include antibiosis, parasitism, the production of extracellular hydrolytic enzymes, competition for iron, and the induction of systemic resistance in the host plant [
21,
25]. Continued research endeavors are vital to bolster disease resistance, explore novel biological control agents, and establish sustainable management practices. Employing this multifaceted approach is essential to safeguarding sugar beet crops and ensuring stable production despite the challenges posed by
Fusarium-related diseases. This study aimed to isolate
Streptomyces strains from the rhizosphere of healthy sugar beet plants and assess their potential as biocontrol agents against the fungal phytopathogen
F. oxysporum, aiming to understand their interaction and potential positive impacts on sugar beet. These findings are valuable in the quest for novel natural bioagents possessing potent antifungal activities for the sugar beet industry.
2. Material and Methods
2.1. Sampling and Isolation of Actinobacteria
Sugar beet plants were collected in sterile bags from different governorates of Egypt, Beni-Suef (28°91′ N; 30°95′ E), Giza (30°02′ N; 31°20′ E), Fayoum (29°42′ N; 31°03′ E), and Kafrelsheikh (31°06′ N; 30°84′ E) during the 2020/2021 growing season. Five samples were collected from each location. Plant roots were shaken gently to eliminate loosely adhering soils. The soil samples were air-dried by spreading samples over sheets of paper at room temperature for 15 days to reduce the number of vegetative bacteria. Soil samples from each site were then mixed and subsequently used for the isolation.
The selective isolation of actinobacteria from the rhizosphere of healthy sugar beet plants was performed via soil dilution plate technique method on starch casein medium. The composition of this medium consisted of soluble starch (10 g), KNO3 (2 g), casein (0.3 g), K2HPO4 (2 g), MgSO4.7H2O (0.05 g), CaCO3 (0.02 g), FeSO4.7H2O (0.01 g), and agar (15 g).
The process began by serially diluting air-dried soil samples by aseptically adding 1 g of soil to 9 mL of sterilized distilled water (10−1), the mixture was shaken vigorously using a vortex, followed by further tenfold dilutions up to 10−4. Each soil dilution was distributed by dropping 100 µL of it over the surface of the isolation plates and spreading it with a sterile glass spreader under aseptic conditions. Five replicate plates were made for each dilution. The plates were then incubated for 15 days at 30 °C, which is an optimal temperature for actinobacterial growth.
Colonies of actinobacteria were selected according to their morphological characteristics and were purified several times by streaking in the same isolation medium and subsequently used for further studies. For long-term preservation, cultures were kept at −80 °C in 15% glycerol. Glycerol acted as a cryoprotectant, preventing ice crystal formation during freezing and safeguarding the actinobacterial cells from damage.
2.2. Source of Fungal Pathogen
The pathogenic
Fusarium oxysporum f. sp.
radicis-betae F186, previously isolated from diseased sugar beet plants exhibiting typical Fusarium root rot symptoms [
26] was generously provided by the culture collection of the Maize and Sugar Crops Department at the Plant Pathology Research Institute, Agricultural Research Center in Giza, Egypt. For subsequent research purposes, it was cultured on potato dextrose agar medium (PDA).
2.3. In Vitro Screening of Antagonistic Activity
The antagonistic effect of isolated actinobacteria against the fungal pathogen was performed through an in vitro plate confrontation method on potato dextrose agar (PDA) medium. Fungal cylinders of well-grown and sporulated 7 days old culture agar discs (8 mm diameter) were centrally placed on PDA plates. Meanwhile, a loopful of each isolated actinobacterium at 7 days old was streaked along the periphery of the plate, maintaining a distance of 3 cm from the fungal disc. Control plates contained fungal discs without actinobacterial application. All plates were left to incubate at 28 °C for 5 days or till the fungal pathogen populated the entire surface of the control plates. Fungal growth cessation or the discernible zones of inhibition were considered a criterion for positive effect. Additionally, the average colony diameter of phytopathogenic fungus was assessed in both the treatment and control groups. The fungal radial growth inhibition rates were estimated using the formula , where C and T represented the mean colony diameters (cm) of phytopathogenic fungi in the control and treatment, respectively.
2.4. Identification of the Most Potent Actinobacteria
The cultural characteristics of the selected potent actinobacteria, which showed a high ability to produce antimicrobial metabolites were investigated on the International Streptomyces Project ISP media. Observations included growth patterns, the coloration of mature sporulating aerial surfaces, substrate mycelium color as viewed from the opposite side, and diffusible soluble pigments. Cultures aged 7 days were assessed on ISP1, ISP2, ISP4, ISP6, and PDA media to ascertain these characteristics. The determination of colors was conducted through comparison with chips available from the ISCC-NBS color charts (Standard Samples No. 2106).
The amylolytic and protease activity of the potent actinobacteria were tested by inoculating them on starch agar and skim milk agar medium, respectively [
27]. Catalase and gelatinase activity were performed on modified Bennett’s agar medium (MBA) [
28]. To determine cellulolytic efficiency, mineral salt agar supplemented with carboxymethyl cellulose (CMC) as the sole carbon source was employed [
29]. The detection of secreted chitinase activity was performed in a chitinase test medium amended with colloidal chitin [
30].
The most potent actinobacterial strains were molecularly identified. Genomic DNA extraction from each isolate was performed using the GeneJET plant genomic DNA purification kit (Thermo Scientific, Lithuania), following the manufacturer’s instructions. Subsequently, the DNA concentration was determined using Nanodrop One (Merc, Thermo Scientific). The prokaryotic universal primers, forward (27F: 5′-AGTT TGATCMTGGCTCAG-3′ and reverse 1492R: 5′-GGTTACCTTGTTACGACTT-3′), were employed to amplify the 16S rRNA gene sequence [
31]. The PCR thermocycling parameters consisted of an initial denaturation at 95 °C for 3 min, followed by 32 cycles of denaturation at 94 °C for 30 s, annealing at 55 °C for 1 min, extension at 72 °C for 2 min, final extension at 72 °C for 10 min, and finally holding at 4 °C. The PCR reactions were executed using an Applied Biosystems 2720 thermal cycler. Subsequently, the amplified DNA products were electrophoretically separated on a 1.2% (
w/
v) agarose gel in 1×TBE buffer and visualized under a UV transilluminator using an EZ view. The molecular weights of the PCR products were estimated by comparison with the DNA marker weights VC 100 bp plus DNA ladder and VC 1 kbp plus DNA ladder. The purification and sequencing of the PCR products were performed by Macrogen (Macrogen, Inc., Korea). The obtained 16S rRNA gene sequences were aligned and compared with the NCBI GenBank database using the BLAST tool to extract homologous sequences for phylogenetic analysis. The phylogenetic tree was constructed using the neighbor-joining method with MEGA X software [
32]. Bootstrap values (1000 repetitions) indicating the proportion of replicate trees in which connected taxa clustered together are presented next to the branches.
2.5. Effect of the Antagonistic Isolates on Sugar Beet Root Diseases in Greenhouse
The most potent actinobacteria that showed high inhibition and antagonistic effect against the phytopathogen F. oxysporum (F186) were evaluated for their effectiveness in controlling root rot disease in the greenhouse trial during the growing season 2021/2022.
2.5.1. Preparation of Pathogen Inoculum
A pathogen inoculum was prepared by growing F. oxysporum on autoclaved sorghum grains in 500 mL glass bottles for 15 days at room temperature. The resulting growth of the pathogen was used to inoculate the sterile potted soil before planting.
2.5.2. Preparation of Microbial Suspensions
Actinobacterial suspensions were prepared and adjusted to 10
6 CFU mL
−1 as described by Errakhi et al. [
33]. The seeds of three varieties, namely Toro c.v., Kwamera c.v., and Cleopatra c.v., were employed in this study. The seeds were rinsed with tap water and then surface sterilized with 5% sodium hypochlorite. Afterward, they were washed three times with sterile distilled water. Subsequently, seeds were coated separately by being soaked in the spore suspension of actinobacteria amended with Tween 80 solution (0.05%) for 4 h. Then, they were left to dry under a laminar flow hood.
Thereafter, five seeds were cultivated immediately in each pot (no. 40) with three replicates. Seeds soaked in sterile distilled water acted as a control. On the other hand, seeds covered with the commercial fungicide Metalaxyl M + fludioxonil (1 cm/kg) served as a positive control. Metalaxyl M + fludioxonil was employed in this study due to its effectiveness against Fusarium species, causing the suppression of hyphal growth and adverse impacts on hyphal morphology, including cell wall breakdown, withering hyphae, and excessive septation. A randomized complete block was used in the experimental design.
The applied treatments were categorized as follows: negative control: untreated and uninfected plants; infected control: plants infected with F. oxysporum F186 but left untreated; SB3-15+F: plants treated with Streptomyces strain SB3-15 and infected with F. oxysporum F186; SB2-23+F: plants treated with Streptomyces strain SB2-23 and infected with F. oxysporum F186; SB3-15: plants treated with SB3-15 but uninfected; SB2-23: plants treated with SB2-23 but uninfected; and fungicide: plants treated with the commercial fungicide Metalaxyl M + fludixonil (1 cm/kg) and infected with F. oxysporum F186.
2.6. Disease Assessments
The evaluation of pre- and post-emergence damping-off was conducted at two specific intervals, namely 15 days and 45 days after planting, following the methodology outlined by El-Argawy et al. [
34].
where
n = the number of non-emerged seeds and
B = the total number of seeds sown.
where
n = the number of dead plants and
E = the total number of emerging plants.
For each treatment and replicate, disease severity (DS) and disease incidence (DI) were evaluated on all sugar beet plants. The degree of root rot was determined according to [
6] with the following rating scale: 0 = healthy sugar beet plant; 1 = mildly stunted to severely stunted plant, leaves may be wilted; 2 = leaves chlorotic, necrosis at leaf margins; 3 = crown drying out and becoming brown to black, leaves withering; and 4 = plant death. The following equation was used to compute the disease severity%:
where
n is the number of pathogenic plants at the same severity level,
b represents the severity level,
T represents the total number of examined plants, and
M represents the maximum severity level.
2.7. Growth Attributes and Yield Evaluation
Plants from each treatment were carefully uprooted and cleaned under running tap water 180 days after seeding. Thereafter, vegetative growth characteristics such as total fresh weight (gm), root weight (gm), root length (cm), and root diameter (cm) were assessed according to [
35]. However, the sugar beet quality parameters (sucrose%, extractable sugar %, potassium %, α-amino nitrogen %, sodium %, and sugar loss to molasses %) were evaluated at Al-Fayoum sugar company laboratories.
2.8. Statistical Analysis
The data underwent statistical analysis using SPSS software for Windows version 25.0. Initially, all comparisons were assessed through a one-way analysis of variance (ANOVA) test. To identify significant differences among treatment means, Duncan’s multiple range test was employed at a significance level of p ≤ 0.05. Furthermore, the least significant difference (LSD) was utilized to evaluate variations between treatment means with a 5% probability level.
4. Discussion
Fusarium root rot affecting sugar beet is recognized as one of the most detrimental soil-borne fungal diseases globally, significantly impeding the sustainable advancement of the sugar industry [
7,
36]. The extensive use of chemical fungicides has resulted in severe concerns related to human health and environmental pollution. Consequently, biological control strategies are being explored as viable and sustainable alternatives [
37]. Actinobacteria exhibit a remarkable capacity to counteract the harmful impacts associated with synthetic fungicides while also demonstrating positive effects on plant growth, underscoring their crucial role in maintaining ecosystem resilience [
38]. Over recent decades,
Streptomyces has emerged to act as a weapon, serving as a defense mechanism against phytopathogen infections and enhancing crop yield [
21,
39,
40]. In this study, of the 37 actinobacterial isolates obtained from sugar beet rhizosphere soil, 15 exhibited significant antifungal activity against the tested phytopathogen
F. oxysporum F186. This finding highlights the potential utilization of these isolates for controlling phytopathogenic diseases. The antagonistic activity of actinobacteria against phytopathogens can be achieved through diverse mechanisms such as antibiosis, nutrient competition, the release of degradative enzymes, induced resistance, and the production of nitrous oxide [
13,
41]. In our study, we assessed the antagonistic effects of isolated actinobacteria through antibiosis, wherein secondary metabolites from actinobacterial strains diffuse in the agar medium, inhibiting the growth of the
F. oxysporum pathogen. Notably, actinobacterial strains SB3-15 and SB2-23 exhibited the most potent inhibition of growth against
F. oxysporum F186.
The morphological and physiological characterization of these selected strains demonstrated their capability to generate various hydrolytic enzymes like cellulases, amylases, proteases, gelatinases, catalases, and chitinases. The antifungal mechanism of these strains might be associated with their ability to produce such hydrolytic enzymes. Even though strain SB2-23 did not exhibit amylase activity, it displayed the superior inhibition of
F. oxysporum growth. This outcome underscores the significant role of chitinases in the biocontrol behavior of
Streptomyces against root rot pathogens in sugar beet, as previously discussed by Karimi et al., 2012 [
42]. Moreover, these outcomes are consistent with findings from other researchers [
43,
44], who documented the correlation between the biocontrol efficacy of various
Streptomyces species and the production of hydrolytic enzymes like chitinases, proteases, and cellulases. These enzymes are known to disrupt the cell walls of fungi, leading to the leakage of cellular contents and subsequently inhibiting the growth of phytopathogenic fungi [
45]. Multiple previous studies have also highlighted the potential of actinobacteria to influence the growth of
Fusarium spp. by generating hydrolytic enzymes [
46,
47,
48,
49,
50,
51]. Moreover,
Streptomyces possess the capacity to inhabit plant root surfaces, survive in diverse soil types, and generate spores, enabling their prolonged existence even in varying extreme conditions [
52].
Streptomyces strains exhibit a wide array of antibiotics and volatile organic compounds that function against pathogens, disrupting fungal cell-to-cell communication. Additionally, they produce an array of enzymes that degrade the cell walls of fungi [
19,
53,
54].
However, the capability of a strain to suppress disease in vitro may not necessarily translate to its effectiveness as a biocontrol agent in vivo, as the strain may not demonstrate its potential in natural circumstances [
55]. Therefore, in vivo pot experiments were conducted under natural conditions to evaluate the effectiveness of employing
Streptomyces strains SB3-15 and SB2-23 as biocontrol agents against root rot disease triggered by
F. oxysporum. Damping-off disease, induced by
F. oxysporum F186, hinders seed germination and early seedling emergence, leading to the decay of germinating seeds and young seedlings. Our findings demonstrated that
Streptomyces strains SB3-15 and SB2-23 exhibited substantial efficacy in reducing the number of damping-off occurrences and enhancing plant survival rates. Additionally, they lessened disease severity compared to the infected control by directly impacting the pathogen and positively influencing seed germination rates [
56]. Moreover, isolate SB2-23 exhibited the highest protective activity with high efficacy ranging from 91.06 to 94.77% compared to chemical fungicide (86.44 to 92.36%). Several
Streptomyces spp. and their bioactive substances have been demonstrated to be effective biocontrol agents against a variety of plant diseases [
46,
57,
58,
59]. Recent research has highlighted the antimicrobial properties of phenolic compounds, such as phenol 2,4-bis(1,1-dimethylethyl) and phenol 2,2- methylenebis[6-(1,1-dimethylethyl)-4-methyl], extracted from
Streptomyces strain H3-2 due to their ability to eliminate free radicals. Additionally, compounds like alkane (4,6- dimethyldodecane) and olefin (benzene, 1,2,3- trimethoxy-5-(2- propenyl)-) identified in the GC-MS fractions have demonstrated strong antimicrobial activity, showcasing the potent biocontrol efficiency of
Streptomyces sp. H3-2 against banana Fusarium wilt disease [
15].
Furthermore, the present study revealed that the application of the two
Streptomyces strains, SB3-15 and SB2-23, significantly enhanced multiple growth attributes in sugar beet. This enhancement was observed in increased total weight, root fresh weight, root diameter, and root length when compared to negative and infected controls. Additionally, these applications exhibited heightened resistance against Fusarium root rot. These findings align with prior research [
60], which supports the hypothesis that the plant-associated
Streptomycetes give a variety of plant benefits and enhanced root weight, shoot, and root length of sugar beet compared to the non-inoculated treatments. Additionally, the enhancement observed in sugar beet growth attributes corroborates with findings reported in several earlier studies [
61,
62].
Streptomyces are acknowledged for their production of phytohormones such as ethylene, gibberellic acid, indole-3-acetic acid (IAA), phenylacetic acid, cytokines, and ACC deaminases [
18,
40]. Several phytohormones perform critical roles in controlling the growth of plant parts at various stages of development [
63]. PGPRs may synthesize phytohormones comparable to those synthesized by plants, which aid in plant development [
64]. Furthermore, they participate in plant defense responses against numerous diseases [
65,
66]. IAA synthesized by
Streptomyces strains increased root length and surface area, which enhances nutrient absorption from the soil [
13]. However, in all growth variables evaluated, the sugar beet Cleopatra variety treated with SB2-23 outperformed the two varieties statistically. The improvement in sugar beet root growth features caused by the application of SB2-23 and/or SB3-15 might be related to these strains’ crucial function in controlling root rot and boosting plant development [
67,
68].
In addition, it can be noted that the distinct effect of SB3-15 and SB2-23 strains on the sucrose percentage of sugar beet varieties is somewhat growth promoting, as it accelerates seed germination, closer canopy, plant growth to reach the storage stage earlier, which is considered more suitable for sugar translocation and accumulation [
69,
70]. Sugar beet varieties, on the other hand, fluctuate greatly in sucrose percentage content. Toro sugar beet variety achieved a higher sucrose% value. Meanwhile, the Cleopatra variety had the lowest value of this feature. This finding satisfied researchers that this trait is strongly correlated with genetic make-up [
71,
72]. Furthermore, treated sugar beet with SB2-23 in the presence or absence of soil infestation with
F. oxysporum F186 attained the highest extractable sugar followed by SB2-15 without significance between them; however, both of them statistically surpassed the other treatments. This result is in agreement with [
71,
73]. Moreover, juice impurities, i.e., K, Na, and alpha amino nitrogen and sugar loss to molasses differed significantly among sugar beet varieties. Toro variety exhibited the lowest Na and K, while the lowest sugar loss to molasses was recorded by Kwamera. On the other hand, the highest values of alpha-amino nitrogen were of Toro and Cleopatra varieties, respectively. Varieties may be differed in their nutrient absorption ability reflecting the genetic makeup among varieties [
74]. In this context, previous studies, namely [
71,
75], indicated noticeable variations among beet varieties in terms of their quality attributes. The application of
Streptomyces SB2-15 and SB2-23 resulted in a significant reduction of alpha-amino N across all varieties, especially in Kwamera. This reduction is crucial as elevated levels of alpha-amino N in storage roots can hinder sucrose extractability [
76,
77]. These findings indicate a potential future use of
Streptomyces strains as effective agents for biological control against pathogenic fungi.