ISSN: 0215-6334 | e-ISSN: 1907-770X Vol.
32 No.
2, 2025: 242 -253
DOI: 10.
11598/btb.
The Southeast Asian Journal of Tropical Biology THE POTENTIAL OF Enhalus acoroides AS A BIOSTIMULANT TO ENHANCE MAIZE GROWTH
AND DROUGHT TOLERANCE
Made Pharmawati1*.
Luh Putu Wrasiati2 .
I Made Anom Sutrisna Wijaya3 and Kadambot H.
Siddique4 Biology Study Program.
Faculty of Mathematics and Natural Sciences.
Udayana University.
Jimbaran 80361.
Bali.
Indonesia Agroindustrial Technology Study Program.
Faculty of Agricultural Technology.
Udayana University.
Jimbaran, 80361.
Bali.
Indonesia Agricultural Engineering and Biosystems Study Program.
Udayana University.
Jimbaran, 80361.
Bali.
Indonesia The UWA Institute of Agriculture.
University of Westren Australia.
WA 6001 Perth.
Australia
HIGHLIGHTS
ABSTRACT
Drought poses a significant challenge to crop productivity.
Biostimulant Potential of Enhalus with maize particularly vulnerable.
Enhancing maize tolerance A Positive Effects of E.
acoroides on to drought stress is crucial, and one promising approach involves using biostimulants derived from natural sources.
Maize Growth A Reduction in H2O2 (Oxidative The seagrass Enhalus acoroides is a potential biostimulant due Stres.
by Enhalus acoroides extract to its rich phytochemical composition, including phenols, tannins, flavonoids, and pigments, such as chlorophyll, lutein, pheophytin, and beta-carotene.
These compounds exhibit antioxidant activity, suggesting their potential role in enhancing plant resilience to drought stress.
This study evaluated the effects of E.
acoroides extract on maize growth under drought conditions Article Information during the seedling phase and analyzed biochemical changes in Received : 10 March 2025 maize plants treated with the extract.
The extract was prepared Revised : 8 April 2025 using 10% dried E.
acoroides leaves with a chloroform-to-ethanol Accepted : 8 April 2025 solvent ratio of 9 : 1 .
and subsequently dissolved in distilled *Corresponding author, e-mail:
water for final concentrations of 0.
05%, 0.
1%, 0.
15%, 0.
made_pharmawati@unud.
The results demonstrated that E.
acoroides extract enhanced plant height, increased shoot and root fresh and dry Reviewers:
Additionally, plants sprayed with E.
acoroides extract Prof Ketut Budaraga & Anonymous exhibited higher total sugars and protein content in the shoots as compared to non-sprayed plants.
Under 20% polyethylene glycol (PEG)-induced drought stress, control plants showed severe leaf wilting, whereas extract-treated plants only had mild wilting.
The chlorophyll, reducing sugars, total N, and tocopherol contents were also higher in extract-treated plants under PEG stress than in untreated controls.
These findings indicate the potential of E.
acoroides extract as a biostimulant for improving drought tolerance in maize.
Keywords: antioxidant, drought stress, maize Seagrass extract as biostimulant for maize growth - Pharmawati et al.
INTRODUCTION
Maize (Zea mays L.
) is a vital cereal crop belonging to the Poaceae family, serving as a major source of nutrients and phytochemicals with significant health benefits (Shah et al.
regions such as Africa.
Latin America, and Asia, maize contributes more than 20% of the daily caloric intake (Shiferaw et al.
Compared to wheat and rice, maize is highly versatile, with applications in food, animal feed, industrial processing, and bioenergy production (Grote et Maintaining stable maize production is essential, given its diverse roles in agricultural and food systems.
In Indonesia, maize production has fluctuated, with dried maize kernel production .
% moisture conten.
77 million tonnes in 2023, representing a 10.
61% decline from 16.
million tonnes in 2022 (Badan Pusat Statistik Climate change, particularly prolonged drought periods linked to global warming, is a major factor affecting maize productivity (Herlina & Prasetyorini 2.
Drought stress significantly hampers maize growth, primarily due to inadequate water availability in the root zone and excessive transpiration from leaves, where water loss outpaces absorption (Nieves-Cordones et al.
Physiologically, drought stress disrupts cell division and differentiation, reduces turgor pressure, alters enzymatic activity, impairs photosynthetic energy production, and leads to the accumulation of reactive oxygen species (ROS) (Jothimani & Arulbalachandran 2.
The seedling and flowering stages are particularly sensitive to drought stress.
Research has shown that photosynthesis rates in maize significantly decrease when soil moisture levels drop to 50% of field capacity.
Furthermore, soil moisture measurements have indicated that levels close to the wilting threshold point .
soil moistur.
can severely stress the plant (Shao et Sustainable agricultural technologies are needed to mitigate the adverse effects of drought.
Biostimulants, organic substances applied to plants, seeds, or soil, have emerged as a promising solution to enhance nutrient efficiency, improve stress tolerance, and promote plant growth (Bulgari Melo et al.
Biostimulants are derived from various sources, including microorganisms, such as bacteria, yeasts, and fungi, either as live organisms or as metabolites (Rouphael 2.
Additionally, plant-derived biostimulants can be extracted from different plant parts, such as seeds, leaves, and roots, across various botanical families, including Amaryllidaceae.
Brassicaceae.
Ericaceae.
Fabaceae.
Fagaceae.
Moringaceae.
Plantaginaceae.
Poaceae.
Rosaceae.
Solanaceae.
Theaceae, and Vitaceae (Yakhin et al.
Marine-derived biostimulants, particularly macroalgae extracts, have also shown promising For example, water extracts from Ulva rigida enhance wheat growth when applied as a foliar spray (Latique et al.
Likewise, extracts from Ascophyllum nodosum improve drought tolerance by increasing proline levels, a key non-enzymatic antioxidant (Rasul et al.
Polyphenols, fucoidans, and alginates found in macroalgae exhibit strong antioxidant activity, which helps mitigate ROS damage under drought conditions (Wang et al.
Using biostimulants also promotes sustainable agriculture by enhancing crop productivity while reducing reliance on chemical fertilizers (Xu & Geelen 2.
Despite the growing interest in plant and algal biostimulants, seagrasses remain an underexplored Seagrasses are marine flowering plants that contribute to primary productivity, carbon sequestration, and habitat formation for marine life (Jalaludin et al.
Among them.
Enhalus acoroides is widely distributed in Indonesia and is characterized by its long leaf blades.
Seagrasses thrive in intertidal zones, providing ecological benefits, such as carbon sequestration and nutrient cycling, which help mitigate the effects of global warming (Stankovic et al.
A recent study highlighted the bioactive potential of E.
Extracts obtained from its leaves using a chloroform-to-ethanol solvent .
contain phenolic compounds, tannins, flavonoids, and pigments such as chlorophyll, lutein, pheophytin, and beta-carotene (Pharmawati & Wrasiati 2.
These compounds possess strong antioxidant properties, suggesting their possible role in plant stress tolerance.
The potential of acoroides extract as a biostimulant for drought tolerance in maize remains unexplored.
This study assessed the effects of E.
extract on maize growth under drought stress during the seedling phase and analyzed biochemical changes induced by extract application, providing insights into its potential role as a droughttolerance biostimulant.
BIOTROPIA Vol.
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MATERIALS AND METHODS
Sample Collection and Extraction Leaves of E.
acoroides were collected from Semawang Beach.
Bali.
They were washed, airdried, and then oven-dried at 50 AC for 24 hours.
The dried leaves were ground and sieved through a 60-mesh sieve.
A 20 g sample of the powdered leaves was extracted using a Soxhlet extractor (PyrexA) with 200 mL of chloroform : ethanol .
: .
for 3 hours.
The extract was filtered, and the filtrate was evaporated using a rotary evaporator (IKAARV.
Soxhlet extraction was performed following the method of Abubakar and Haque .
with modifications, using chloroform : ethanol as the solvent, as chloroform extracts from various plant species have been reported to exhibit significant antioxidant activities (Uddin et Syamkumar et al.
The resulting crude extract .
%) was diluted in distilled water to prepare concentrations of 0.
05%, 0.
1%, 0.
2%, and 0.
The extracts were stored in a refrigerator until use.
The effectiveness of E.
acoroides extract was evaluated in two separate experiments.
The first experiment assessed its effect on maize growth at the vegetative stage, while the second examined its potential as a drought mitigation agent.
Both experiments were conducted in the greenhouse of the Biology Study Program.
Faculty of Mathematics and Natural Sciences.
Udayana University.
Bali.
Indonesia from June to September 2024.
Experiment 1: Enhalus acoroides Treatment Commercial hybrid maize seeds (Pertiwi variet.
were purchased from an agricultural store in Denpasar.
Bali.
The seeds were sterilized by soaking in 10% sodium hypochlorite for 10 minutes, then rinsed with water and soaked for 12 hours.
Germination was carried out in trays containing rockwool media and commercial hydroponic A and B liquid nutrients.
After 7 days, uniform seedlings were selected and transferred to a hydroponic system with perlite media and AB mix nutrients for an additional 7-day acclimatization period.
Following acclimatization, seedlings were sprayed with E.
acoroides extract at the specified concentrations .
mL per plan.
, while control plants received distilled water.
Treatments were applied twice weekly for four weeks.
At the end of the experiment, plants were harvested.
The experiment was conducted using a randomized block design with four replications.
Data Collection Plant height was measured at harvest .
our weeks after the first E.
acoroides treatmen.
Fresh and dry weights of both aboveground and belowground plant parts were recorded.
Reducing sugars content was determined by preparing a glucose standard curve using 0, 20, 40, 60, 80, and 100 ppm anhydrous glucose.
For each concentration, 1 mL of glucose was mixed with 1 mL of NelsonAos reagent, heated for 10 minutes, cooled, and treated with 1 mL of arsenomolybdate solution.
After adding 7 mL of distilled water, absorbance was measured at 540 nm.
For plant samples, 1 g of tissue was dissolved in 100 mL of distilled water, filtered, and processed similarly.
Reducing sugars content was calculated based on Apriyantono et al.
Nitrogen content was measured using the Kjeldahl method.
A 0.
1 g sample was hydrolyzed 5 g of Kjeldahl tablet and 5 mL of HCCSOCE in a heat block.
After cooling, 25 mL of distilled water, 25 mL of 50% NaOH, and three drops of phenolphthalein were added.
The mixture was distilled, and the distillate was collected in 10 mL of 3% boric acid.
Titration was performed using 1 N HCl until the solution changed from blue to light yellow.
The volume of HCl used was recorded, and nitrogen content was calculated following Sudarmadji et al.
Experiment 2: PEG treatment Two weeks after acclimatization, seedlings were sprayed with 5 mL of E.
acoroides extract at concentrations of 0.
05%, 0.
1%, 0.
15%, 0.
2%, and Treatments were applied twice weekly for three weeks.
Subsequently, the nutrient solution was replaced with a 20% PEG6000 solution to induce drought stress, while spraying with E.
acoroides extract continued twice weekly for an additional week.
Data Collection At the end of the experiment, plants were harvested, and chlorophyll content was analyzed using spectrophotometry.
Leaves were ground in 100% acetone, and chlorophyll a, chlorophyll b, and total chlorophyll concentrations were measured at 647 nm and 664 nm, following the method of Lichtenthaler & Buschmann .
Reducing sugars and total protein contents of the shoots were analyzed using previously described Seagrass extract as biostimulant for maize growth - Pharmawati et al.
Tocopherol content was determined using the method described by Wong et al.
A 0.
5 g sample was dissolved in 5 mL of toluene and To 2 mL of the filtrate, 0.
5 mL of toluene, 75 mL of 2,2-bipyridine .
07% w/v in 95% ethano.
, and 0.
25 mL of FeClCEA6HCCO .
2% w/v in 96% ethano.
were added.
Ethanol was added to bring the total volume to 5 mL.
Absorbance was measured at 520 nm using a spectrophotometer.
A tocopherol standard curve was prepared using concentrations ranging from 100 ppm to 1,500 ppm in toluene.
Antioxidant activity (IC.
was determined following the method of Amin & Lee .
stock solution of 4 g 1,1-Diphenyl-2-picrylhydrazyl (DPPH) in 100 mL methanol was prepared.
A 1
mL aliquot was mixed with 1 mL of ethanol and incubated for 30 minutes, after which absorbance was measured at 517 nm.
For plant extracts, a 03 g sample was dissolved in 5 mL of methanol.
Serial dilutions .
, 20, 30, 40, and 50 AAL) were prepared in test tubes and adjusted to 1,000 AAL with methanol.
Each solution was mixed with 1,000 AAL of DPPH, vortexed, and incubated for 30 minutes.
Absorbance was measured at 517 nm, and the inhibition percentage was calculated as described by Amin & Lee .
In vivo detection of H2O2 in roots was performed using histochemical 3,3Ao-diaminobenzidine (DAB) staining, following Daudi & OAoBrien .
Roots were immersed in a 1 mg/mL DAB solution .
H 3.
and incubated under light at 25 AC for 8 hours before decolorization by immersion in 96% The presence of H2O2 was indicated by deep brown coloration resulting from the reaction of DAB with H2O2 catalyzed by plant peroxidases.
Data Analysis All data were statistically analyzed using analysis of variance (ANOVA) in MINITAB 20.
Mean differences were evaluated using TukeyAos comparison test at a significance level of P < 0.
RESULTS AND DISCUSSION
Spraying with E.
acoroides extract promoted significant increases in maize plant height.
shown in Figure 1, differences in plant appearance are evident between control plants and those treated with various extract concentrations after four weeks of application .
t 5 weeks ol.
Quantitative analysis revealed that E.
extract significantly influenced plant height difference (P < 0.
Heights were significantly greater (P < 0.
in plants treated with 0.
15%, 0.
2%, and 0.
25% compared to the control, with the 0.
15% concentration producing the tallest plants (Fig.
Foliar application of E.
acoroides extract also significantly increased shoot and root fresh and dry weights.
Figure 3 shows that fresh shoot weight was higher in plants treated with as little as 0.
05% extract, while fresh root weight significantly increased at 0.
15%, 0.
2%, and 0.
Figure 1 Visual comparison of five-week-old maize plants after four weeks of treatment with varying concentrations of E.
acoroides extract Notes: Treatments: a = Control .
o spra.
b = 0.
c = 0.
d = 0.
e = 0.
and f = 25% extract.
Bar = 10 cm BIOTROPIA Vol.
32 No.
2, 2025
Figure 2 Plant height of five-week-old maize plants after four weeks of treatment with varying concentrations of E.
acoroides extract Notes: Different letters above the bars indicate significant differences among treatments (P < 0.
Figure 3 Shoot and root fresh weights of five-week-old maize plants after four weeks of treatment with varying concentrations of E.
acoroides extract Notes: Different letters above the bars indicate significant differences among treatments (P < 0.
Figure 4 Shoot and root dry weights of five-week-old maize plants after four weeks of treatment with varying concentrations of E.
acoroides extract Notes: Different letters above the bars indicate significant differences among treatments (P < 0.
Seagrass extract as biostimulant for maize growth - Pharmawati et al.
Table 1 Reducing sugars content and total N content in five-week-old maize shoots after four weeks of treatment with varying concentrations of E.
acoroides extract Concentration (%) Reducing sugars (%) N (%) 40 A 0.
86 A 0.
14 A 0.
37 A 0.
65 A 0.
00 A 0.
75 A 0.
82 A 0.
78 A 0.
45 A 0.
55 A 0.
78 A 0.
Notes: Data presented as mean A standard deviation.
Different letters in the same column indicate significant differences (P < 0.
concentrations (P < 0.
A similar trend was observed for dry shoot weight (Fig.
, while dry root weight was significantly greater in plants treated with 0.
1%, 0.
15%, and 0.
25% extract compared to dry root weight in control plants.
The observed improvements on plant height and biomass may be attributed to bioactive compounds and nutrients in the seagrass extract.
Like seaweed extracts.
acoroides likely promotes growth by releasing plant growth hormones.
Previous studies have shown that extracts from various seaweed species contain auxins, cytokinins, and abscisic acid (Yalyn et al.
and have even been shown to upregulate genes involved in auxin biosynthesis in Beta vulgaris, thereby enhancing lateral root development and nutrient uptake (Bertoldo et al.
Table 1 summarizes the effects of E.
extract on reducing sugars and total N content in maize shoots.
Both parameters began to increase at the 0.
1% extract concentration, indicating enhanced metabolic activity and nutrient assimilation in treated plants.
Reducing sugars are key products of photosynthesis and serve as the primary energy source for plant cells.
Glucose has been reported to influence the expression of genes that promote the activity of nitrate reductase, a key enzyme in the nitrogen assimilation pathway (Ma et Increased nitrogen availability supports the synthesis of enzymes involved in carbohydrate metabolism, thereby promoting sugar utilization and energy generation (Zhang et al.
Figure 5 Visual comparison of six-week-old maize plants sprayed after three weeks of twice-weekly treatment with varying concentrations of E.
acoroides extract followed by one week of PEG-induced drought stress Notes: a = Control .
o extract, no PEG).
b = PEG only.
c = 0.
05% extract PEG.
d = 0.
1% extract PEG.
e = 0.
15% extract PEG.
f = 0.
2% extract PEG.
g = 0.
25% extract PEG.
PEG = Polyethylene glycol.
Bar = 10 cm.
BIOTROPIA Vol.
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Figure 6 Maize roots of six-week-old maize plants sprayed after three weeks of twice-weekly treatment with varying concentrations of E.
acoroides extract followed by one week of PEG-induced drought stress Notes: a = Control .
o extract, no PEG).
b = PEG only.
c = 0.
05% extract PEG.
d = 0.
1% extract PEG.
e = 0.
15% extract PEG.
f = 0.
2% extract PEG.
g = 0.
25% extract PEG.
PEG = Polyethylene glycol.
Bar = 5 cm Figure 7 H2O2 accumulation in roots and leaves of six-week-old maize plants sprayed after three weeks of twice-weekly treatment with varying concentrations of E.
acoroides extract followed by one week of PEG-induced drought stress Notes: a = Control .
o extract, no PEG).
b = PEG only.
c = 0.
05% extract PEG.
d = 0.
1% extract PEG.
e = 0.
15% extract PEG.
f = 0.
2% extract PEG.
g = 0.
25% extract PEG.
PEG = Polyethylene glycol.
Bar = 2 cm The increase in reducing sugars and nitrogen content is comparable to effects observed with seaweed extracts.
For example, an aqueous extract of Sargassum johnstonii increased reducing sugars levels in Lycopersicon esculentum when applied at concentrations above 0.
1% (Kumari et al.
Although research on seagrass-derived biostimulants is limited, seaweed extracts have been studied extensively and are known to enhance seed germination, biomass yield, and overall plant quality (Ali et al.
Kumar et al.
The phenolic compounds, tannins, and flavonoids present in E.
acoroides likely contribute to these observed benefits.
Seagrass extract as biostimulant for maize growth - Pharmawati et al.
Table 2 Chlorophyll a, chlorophyll b, and total chlorophyll concentrations in six-week-old maize plants sprayed after three weeks of twice-weekly treatment with varying concentrations of E.
acoroides extract .
05%, 0.
1%, 0.
15%, 0.
2%, and 0.
25%) followed by one week of PEG-induced drought stress Treatment Chlorophyll a (AAg/cm.
Chlorophyll b (AAg/cm.
Total chlorophyll (AAg/cm.
Control 25 A 0.
83 A 1.
08 A 2.
PEG only 21 A 1.
95 A 0.
15 A 1.
05% PEG
02 A 2.
16 A 0.
18 A 1.
1% PEG
28 A 2.
05 A 2.
34 A 3.
15% PEG
36 A 0.
45 A 4.
80 A 3.
2% PEG
08 A 2.
14 A 2.
22 A 1.
25% PEG
44 A 2.
26 A 1.
69 A 3.
Notes: Data presented as mean A standard deviation.
Different letters in the same column indicate significant differences (P < 0.
PEG = Polyethylene glycol.
Polyethylene glycol (PEG) induces drought stress by reducing root water uptake.
In the PEG treatment, plants pre-treated with E.
extract for three weeks exhibited faster growth and less severe drought symptoms.
During the one-week PEG treatment .
ith continued extract application twice weekl.
, treated plants maintained less desiccation compared to the controls, which leaves became dry and curled (Fig.
The PEG treatment reduced lateral root development, resulting in smaller root systems and root browning (Fig.
This damage is likely due to tissue dehydration and osmotic stress-induced cell death (Saepudin et al.
In vivo HCCOCC detection revealed higher oxidative stress in PEG-only-treated plants than the control and the E.
acoroides-treated plants (Fig.
The extract may enhance root development, thus improving nutrient uptake and reducing oxidative stress by increasing tocopherol levels and internal antioxidant activity.
This antioxidant effect has also been observed with Sargassum wightii extract applications to Abelmoschus esculentus under salt stress (Khan et al.
Table 2 presents the chlorophyll content in control plants .
o extract, no PEG) and PEGtreated plants .
prayed and non-sprayed with E.
acoroides extrac.
Maize plants treated with PEG alone exhibited 17.
8%, 24.
61%, and 20.
declines in chlorophyll a, chlorophyll b, and total chlorophyll, respectively.
Studies have reported that PEG-induced osmotic stress significantly decreases chlorophyll levels, negatively affecting photosynthesis and overall plant growth (Nio et al.
Rao et al.
Spraying PEG-treated plants with E.
acoroides extract increased chlorophyll content, with significant effects starting with the 1% extract.
Table 3 presents the levels of reducing sugars, total N, tocopherol, and IC50 in control and PEG-treated maize plants, with and without acoroides extract application.
The PEG-only treatment decreased reducing sugars content, consistent with the findings in Phaseolus vulgaris, where PEG-induced osmotic stress decreased reducing sugars levels (Torres-Hernandez et al.
This reduction may be attributed to the inactivation of -amylase, the enzyme responsible for starch hydrolysis (Torres-Hernandez et al.
However, spraying E.
acoroides extract three weeks before and during PEG treatment increased reducing sugars levels.
Significant increases (P < .
started at the 0.
1% extract concentration, suggesting that E.
acoroides extract helps counteract the adverse effects of PEG-induced stress.
Total N levels were the highest in plants treated 2% and 0.
25% E.
acoroides extract under PEG-induced drought stress.
Tocopherol content significantly increased in plants sprayed with the highest extract concentration .
25% PEG).
The increase in tocopherol content in plants sprayed with E.
acoroides extract can be driven by the bioactive compounds present in the extract.
Bioactive compounds, such as flavonoids and BIOTROPIA Vol.
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Table 3 The levels of reducing sugars, total nitrogen (N), tocopherol, and antioxidant activity (IC.
in six-week-old maize plants sprayed after three weeks of twice-weekly treatment with varying concentrations of E.
acoroides extract .
05%, 0.
1%, 0.
15%, 0.
2%, and 0.
25%) followed by one week of PEG-induced drought stress Treatment Reducing sugars (%) N (%) Tocopherol (%) IC50 Control 08 A 0.
03 A 0.
67 A 60.
80 A 64.
PEG only 60 A 0.
97 A 0.
32 A 29.
81 A 9.
05% PEG
32 A 0.
03 A 0.
89 A 5.
19 A 31.
1% PEG
46 A 0.
04 A 0.
54 A 36.
85 A 10.
15% PEG
69 A 0.
06 A 0.
03 A 17.
06 A 24.
2% PEG
80 A 0.
14 A 0.
11 A 37.
64 A 9.
25% PEG
91 A 0.
31 A 0.
02 A 37.
72 A 30.
Notes: Data are presented as mean A standard deviation.
Different letters in the same column indicate significant differences (P < 0.
PEG = Polyethylene glycol.
polyphenols, exhibit strong antioxidant properties, which can protect tocopherols from oxidative degradation, thereby increasing their stability and bioavailability (Domynguez-Valencia et al.
Plant extracts can enhance tocopherol production through elicitation, which stimulates the plant's defense mechanisms, leading to increased biosynthesis of tocopherols (Almagro et al.
The IC50 value, which represents the concentration required to reduce oxidative stress by 50%, significantly decreased with increasing extract concentration from 0.
15% to 0.
acoroides extract, suggesting that E.
extract helps mitigate abiotic stress by enhancing antioxidant activity.
This reduced stress lowers ROS .
eactive oxygen specie.
accumulation, as indicated by lower HCCOCC levels (Fig.
A previous study on Zostera marina, another seagrass species, found that its aqueous extract increased the activity of antioxidant enzymes in salt-stressed tomato plants (Vinoth et al.
The bioactive compounds in acoroides, phenolics, flavonoids, and pigments, likely increased plant growth by exerting hormonal effects similar to those of seaweed extracts.
CONCLUSION
Spraying Enhalus acoroides extract significantly enhanced maize growth by increasing plant height and shoot and root biomass, as well as by improving reducing sugars and total N contents.
Under PEG-induced drought stress.
acoroides extract alleviated stress-related damage.
Enhalus acoroidestreated plants exhibited higher chlorophyll levels and reduced oxidative stress, as indicated by lower HCCOCC accumulation.
Additionally, spraying with E.
acoroides extract increased reducing sugars, total nitrogen, and tocopherol levels, suggesting improved stress tolerance.
These findings highlight the potential of E.
acoroides extract as a biostimulant for enhancing plant growth and drought resilience in maize cultivation.
Further research is needed to explore its applicability across different crops and environmental conditions.
ACKNOWLEDGMENTS
The authors acknowledge the Directorate General of Higher Education for funding this research through the Fundamental Research Scheme.
No.
102/E5/PG.
PL/2024, dated 11 June 2024, and No.
B/519-32/UN14.
A/PT.
03/2024,
dated 12 June 2024.
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