Compost Enhances Forage Yield and Quality of River Saltbush in Arid Conditions

Abstract

High temperatures and water scarcity are among the main obstacles to producing fodder in arid regions. Saltbush shrubs are used for livestock in many arid regions, especially in saline conditions, due to their high salt tolerance. The produced forage materials under these saline conditions are often low in quantity and quality. This article presents field studies that were conducted for two growing seasons to evaluate the forage yield and quality of river saltbush (Atriplex amnicola Paul G. Wilson) as a function of compost application. The plants were cultivated in saline soil (15 dS m⁻¹), and compost was added at four rates (0, 5, 10, and 15 t ha⁻¹). River saltbush plant produced 9.23−15.60 t ha⁻¹ of stems and 4.25−7.20 t ha⁻¹ of leaves yearly (over all the treatments). The crude protein (CP) ranged between 48−70 g kg⁻¹ in the stems and between 160−240 g kg⁻¹ in the leaves (over all the treatments). The forage yield, crude protein, dry matter, and mineral contents of the tested plant increased significantly (p < 0.05) due to compost addition. The application of 5, 10, and 15 t ha⁻¹ of compost reduced the Na⁺ concentrations in the leaves by 14, 16, and 19% (as means of two years) compared with the control. In the same trend, these rates reduced the oxalate concentrations in the leaves by 38, 30, and 29% (as means of two years) compared with the control. Our results show that compost application improves the activity of polyphenol oxidase (PPO) and catalase (CAT). Compost reduces the adverse impacts of soil salinity by improving the photosynthesis process and increasing the activity of antioxidant defense. Compost also enhances the growth of river saltbush plants cultivated in saline soils, thus, enhancing their value as animal feed. Halophyte plants can be used to utilize saline soils that are not suitable for traditional production. Compost addition is a good agricultural strategy to increase growth and reduce the negative effects of salts.

1. Introduction

Saline lands are spread in many areas of the world and may reach 1128 million hectares, and most of these lands are located in arid and semi-arid regions [1,2]. Soil salinity inhibits plant growth through osmotic effects, specific-ion toxicity, and/or shortage and disorders of some nutrients [3]. Saline soils cannot be cultivated with traditional field crops; for example, when wheat (Triticum aestivum) and cowpea (Vigna unguiculata) plant are cultivated in a soil with an ECe 10 dS m⁻¹ (ECe is the salinity of the soil saturation extract), their yields are reduced by 50% [4]. Arid conditions lead to the formation of saline soils that are more suitable for growing halophytic plants to provide the world with animal feed. Halophyte plants are defined as those with the ability to grow and flourish in ≥200 mM NaCl [5]. Among the halophyte flora, river saltbush (Atriplex spp.) has been used as promising forage plants for livestock [6]. At higher levels of salinity, it can give high dry matter (15–22 t DM ha⁻¹ year⁻¹), which means great hope in supplying forage for livestock [6,7,8].

Atriplex spp. has a high content of crude protein and is valuable as animal feed ingredients [9,10]. Halophyte plants are promising, due to their potential of being a feed resource, especially in arid regions and poor soils [6]. Traditional forage crops, such as alfalfa and corn, have high nutritional value and yield compared to the halophyte forage [11,12], but these plants have very low ability to grow in saline soils compared to halophyte forages [7,8,13].

Soil organic amendments have high water holding capacity, cation exchange capacity (CEC), chelation ability and are considered as good nutrient resources [9,14]. Organic amendments are cost-effective, easy-to-use techniques, environmentally and agronomically sound practice to mitigate soil salinity [2,15]. Compost is commonly used as an organic amendment that can be used in this regard [16]. Compost assists cultivated crops to overcome the negative impacts of soil salinity through improving the soil quality characteristics, such as aeration, permeability, aggregation, nutrients availability and uptake, water holding capacity, activity of soil microbes and enzymes, and reducing the toxic elements uptake [17,18,19]. Compost has another role in increasing plant tolerance and mitigating salt stress by increasing the activity of antioxidant enzymes and salt tolerance defense [14,17,20].

Despite the high ability of halophyte plants to tolerate salt stress, they lose a large part of their quality and production capacity [5,21,22]. The ability of halophyte plants to adapt to salt stress can be used to utilize saline soils that are not suitable for growing traditional crops, but the appropriate agricultural strategies should be used to increase growth and reduce the negative effects of salts. There is little information available about the effect of compost in reducing the negative effects of salinity on the quantity and quality of the fodder yield of the halophytic plants. This study investigates the effect of compost on increasing the yield and quality of the fodder yield of river saltbush plants. The study explores the role of compost in increasing the activity of antioxidant enzymes in river saltbush plants.

2. Material and Methods

2.1. Site Description and Field Experiments

Twenty-day-old seedlings of Atriplex amnicola Paul G. Wilson were transplanted on 15 May 2016 in a private farm located at Gerga, Sohag, Egypt (26°17′44.4″ N 31°46′40.0″ E). Seedlings of A. amnicola were achieved from the Center of Desert Agriculture (Assiut University, Assiut, Egypt). The experimental site is characterized by a hot climate in summer and cold in winter without rainfall. The soil of the experimental site was sandy loam soil with EC_e of 15 dS m⁻¹, and according to Chhabra [23], the experimental site was saline soil and classified as Typic Torripsamments [24].

Table 1. Basic properties of the studied soil and compost.

Properties (Units)	Value
Texture	Sandy loam
CaCO3 (g kg−1)	52 ± 4
pH	8.20 ± 0.07
Salinity (dS m−1)	15.07 ± 0.72
Organic Carbon (g kg−1)	3.0 ± 0.2
Exchangeable sodium percent	14
Available N (mg kg−1)	100 ± 5
Available P (Olsen) (mg kg−1)	5.5 ± 0.2
Available K (mg kg−1)	200 ± 12

shows the properties of the studied soil. The seedlings were cultivated at 3 × 3 m² spacing with a plant density of 1000 plant ha⁻¹. The experiment consisted of four compost rates, namely, 0, 5, 10, and 15 t ha⁻¹. The compost rates were mixed with the topsoil layer (0–20 cm) before plant cultivation and during the preparation of soil in the first year and the beginning of the second year. After the plant cutting in the first season, we added the compost then mixed it with the soil by hoeing machine. The experimental unit was 100 m². The experiment was repeated in the same location, and the treatments were applied to the same plots each year. The experiment was arranged in a randomized complete block design (RCBD) with five replicates. The plants were irrigated with groundwater (EC = 2.5 dS m⁻¹) by using an adjusted surface irrigation system. The aboveground parts of the plants were cut yearly and divided into leaves and stems. The plants were harvested two times during the experiment period, the first was done during May 2017, and the second was done during May 2018. The plants were harvested when they were one year old from the beginning of cultivation.

2.2. Soil Characterization

Composite soil sample (0–20 cm) was collected randomly from the experimental site before cultivation to assess the physical and chemical characteristics (Table 1). The soil was air-dried and ground to pass through a 2-mm sieve. Particle-size distribution of the soil sample was performed using the pipette method that was described by Burt [25]. Soil pH was measured using a digital pH meter in a 1:1 suspension of soil-to-water ratio. The organic matter content of the soil was determined using the dichromate oxidation method as described by Wakley and Black [25]. Total carbonates in the soil were estimated using the calcimeter method and calculated as CaCO₃ [25]. The electrical conductivity (ECe) was estimated in soil paste to water extract using the salt bridge method [25]. The total nitrogen, available phosphorus, and potassium were determined according to Burt [25].

2.3. Plant Analysis

The plant samples were weighed, cleaned, washed with tap and distilled water, air dried, then dried in an oven at 70 °C until a constant weight, then ground, and stored for chemical analysis. Plant samples were digested in H₂SO₄ and H₂O₂ as described by Parkinson and Allen [26], and then analyzed for the different elements: nitrogen (N), phosphorus (P), chloride (Cl), sodium (Na), potassium (K), and calcium (Ca). Phosphorus was measured by spectrophotometer (Unico 2000UV, Unico photometers & spectrophotometers, Ontario, Canada). Chloride in the digested plant samples was measured by titration with silver nitrate after neutralizing the pH of plant samples [25]. Sodium and potassium were measured by the flame photometer method (Jenway 7PFP, manufacturer: Jenway, Stafford, UK). The P, Na, K, and Cl concentrations in the plant samples were determined according to Burt [25]. Calcium (Ca) in the digested plant samples was measured by the Inductivity Coupled Plasma Emission Optical Emission Spectrometry (ICP-OES, Thermo iCAP 6000 series, manufacturer: Thermo Scientific, Kleve, Germany). Dry matter (DM), moisture content (MC), organic matter (OM), crude protein (CP), fat content, and crude fiber (CF) in the leaves and stems of river saltbush plants were measured according to animal nutrition and product quality laboratory manual [27]. Organic matter and dry matter were determined by oven drying of the forage material, while the crude protein was determined by measuring the nitrogen content by micro-Kjeldahl distillation unit (Gerhrdit s10Vabodest, Germany). The crude fiber was determined by boiling with H₂SO₄ and oven drying at 550 °C for 3 h. Crude fat was extracted by petrol ether and then determined by the Soxhlet apparatus (Soxtherm S306 A, Gerhardt GmbH, Wiesbaden, Germany). The activity of catalase (CAT) was determined after the extraction by 50 mM potassium phosphate buffer (pH 7) and 10 mM H₂O₂, as described in Chandlee and Scandalios [17,28]. The activity of polyphenol oxidase (PPO) was evaluated after the extraction by 50 mM potassium phosphate buffer (pH 7.0) and 40 mM pyrogallol according to Rady [17], and Kumar and Khan [29]. The activity of peroxidase (POX) was determined after the extraction by 50 mM potassium phosphate buffer (pH 7.0) and 40 mM pyrogallol and 1 mM H₂O₂ [17,29]. SPAD 502 plus (Konica Minolta, Inc., Tokyo, Japan) was used to measure the chlorophylls in the leaves of river saltbush. Oxalates were extracted from the oven-dried leaves by 0.25 N HCl and then titrated by 0.02 N KMnO₄, as described in Naik et al. [30].

2.4. Compost Characterization

Compost was made from chicken feces and corn wastes (2:1 w/w).

Table 2. Basic properties of the studied compost.

pH	Salinity (dS m−1)	Organic Carbon (g kg−1)	N (g kg−1)	P (g kg−1)	K (g kg−1)
8.22 ± 0.1	5.25 ± 0.3	240 ± 12	20 ± 2	15.70 ± 2.3	35 ± 3

shows the properties of the compost used in the current study. Organic matter in compost was measured by the loss-on-ignition method [31]. Dried compost samples (2.0 g) were digested with H₂O₂ and H₂SO₄ as described in the plant analysis section. The total N, P, and K concentrations were measured in the digest extract by the same methods in the plant analysis section. The pH of compost was evaluated in a 1:5 suspension with a pH meter, and the electrical conductivity (EC) of the 1:5 extract was determined with an EC meter [25].

2.5. Data Analysis

The obtained results were checked by Shapiro–Wilk test for normality. The Analysis of Variance (ANOVA) was used to test the significance of differences between the treatments. The collected data were statistically analyzed by using the MSTAT computer program (MSTAT-C, Michigan State University, Michigan, USA) [32]. Means were compared using Duncan multiple range tests at a 5% level of probability. All data in tables and figures are means (±standard deviation) of five replicates.

3. Results

3.1. Effects of Compost Addition on the Mineral Content of River Saltbush

Compost addition significantly increased the concentrations of N, P, and K in the leaves of river saltbush in the first and second years (

Table 3. Effect of compost treatments on the mineral content of leaves and stems of river saltbush plants (g kg⁻¹).

	2017						2018
	Na	K	Cl	P	Ca	N	Na	K	Cl	P	Ca	N
	Leaves
Control	40 ± 2.1 a	20 ± 1.1 b	35 ± 1.3 a	2.0 ± 0.11 b	9 ± 0.4 a	26 ± 1.05 b	44 ± 2.2 a	20 ± 1.0 b	32 ± 1.1 a	2.2 ± 0.18 b	4.8 ± 0.5 a	32 ± 1.03 b
COM5	35 ± 1.5 b	23 ± 0.8 b	33 ± 1.7 a	2.2 ± 0.14 b	4.8 ± 0.3 a	35 ± 2.07 a	38 ± 1.6 b	24 ± 0.7 a	28 ± 1.6 a	2.1 ± 0.16 b	4.7 ± 0.4 a	37 ± 1.06 a
COM10	34 ± 2.5 b	26 ± 1.2 a	33 ± 1.8 a	2.9 ± 0.17 a	4.9 ± 0.2 a	34 ± 1.07 a	35 ± 2.2 b	25 ± 1.3 a	30 ± 1.7 a	2.8 ± 0.16 a	4.8 ± 0.2 a	38 ± 1.07 a
COM15	32 ± 1.8 b	27 ± 1.3 a	34 ± 2.0 a	2.8 ± 0.18 a	5.0 ± 0.2 a	32 ± 1.04 a	36 ± 1.2 b	27 ± 1.4 a	31 ± 2.1 a	2.9 ± 0.17 a	5.1 ± 0.3 a	35 ± 1.05 a
Ft	*	*	ns	*	ns	*
Fy	ns	ns	ns	ns	ns	ns
Fy×t	*	ns	*	ns	ns	**
	Stems
Control	15 ± 0.5 a	11 ± 0.4 a	13 ± 0.7 a	1.1 ± 0.14 a	1.9 ± 0.1 a	8.0 ± 0.04 a	15 ± 0.4 a	13 ± 0.5 a	12 ± 0.6 a	1.2 ± 0.10 a	1.8 ± 0.1 a	9.6 ± 0.03 a
COM5	15 ± 0.7 a	10 ± 0.7 a	13 ± 0.8 a	1.0 ± 0.15 a	1.8 ± 0.1 a	8.0 ± 0.04 a	13 ± 0.7 a	11 ± 0.7 a	13 ± 0.8 a	1.1 ± 0.12 a	1.7 ± 0.1 a	11.2 ± 0.04 a
COM10	16 ± 0.4 a	12 ± 0.5 a	10 ± 0.6 a	0.9 ± 0.08 a	1.8 ± 0.1 a	7.7 ± 0.05 a	14 ± 0.3 a	12 ± 0.6 a	10 ± 0.7 a	0.8 ± 0.08 a	1.8 ± 0.1 a	8.0 ± 0.06 a
COM15	14 ± 0.4 a	10 ± 0.5 a	9 ± 0.4 a	1.0 ± 0.11 a	1.9 ± 0.1 a	8.0 ± 0.03 a	12 ± 0.5 a	11 ± 0.6 a	11 ± 0.6 a	1.1 ± 0.12 a	1.8 ± 0.1 a	11.2 ± 0.03 a
Ft	ns	ns	*	ns	ns	ns
Fy	ns	ns	ns	ns	ns	ns
Fy×t	ns	**	ns	*	*	ns

COM₅ = 5 t of compost ha⁻¹, COM₁₀ = 10 t of compost ha⁻¹, and COM₁₅ = 15 t of compost ha⁻¹. * p < 0.05, ** p < 0.01, ns: non-significant. Means (±SD) denoted by the same letter refers to non-significant differences based on Duncan’s test at p < 0.05. F_t, F_y, and F_y×t refer to the F value of the treatments, years, and the interaction of treatments and years.

). Sodium (Na) concentrations in leaves tissues of river saltbush plants were reduced significantly due to compost addition. The addition of 5, 10, and 15 t ha⁻¹ of compost (COM₅, COM₁₀, and COM₁₅) reduced Na concentrations in the leaves by 13, 15, and 20% in the first year, while these decreases were 14, 16, and 18% in the second year. Nitrogen, P, and K increased significantly due to compost addition. COM₅, COM₁₀, and COM₁₅ increased N in the leaves by 46, 30, and 23% in the first year by 16, 19, and 9% in the second year. COM₅, COM₁₀, and COM₁₅ increased K in the leaves by 15, 30, and 35% in the first year, while these increases were 20, 25, and 35% in the second year. COM₁₀ and COM₁₅ increased P in the leaves by 45 and 40% in the first year and by 27 and 32% in the second year.

3.2. Effect of Compost on Some Biochemical Compounds of Leaves

Chlorophyll in river saltbush responded significantly to the addition of compost (Figure 1). The addition of 5, 10, and 15 t ha⁻¹ of compost (COM₅, COM₁₀, and COM₁₅) elevated the chlorophyll in the leaves by 37, 27, and 33% over the non-amended soil in the first year, while these increases were 46, 50, and 43% in the second year. Compost significantly reduced the oxalate content in the leaves of river saltbush plants (Figure 1). COM₅, COM₁₀, and COM₁₅ decreased the oxalic acid by 41, 24, and 26% compared with the control in the first year and by 34, 36, and 32% in the second year.

The activity of polyphenol oxidase (PPO) and catalase (CAT) was affected by the compost treatments, while the peroxidase (POX) activity was not affected by the treatments (

Table 4. Effect of compost on antioxidant enzyme activities (unit mg⁻¹ protein) in the leaves of river saltbush plants.

2017				2018
	CAT	PPO	POX	CAT	PPO	POX
Control	4.2 ± 0.0 b	2.7 ± 0.0 b	2.4 ± 0.0 a	4.1 ± 0.0 b	2.6 ± 0.0 b	2.7 ± 0.0 a
COM5	4.8 ± 0.0 a	3.2 ± 0.0 a	2.6 ± 0.0 a	5.0 ± 0.0 a	3.4 ± 0.0 a	2.4 ± 0.0 a
COM10	5.0 ± 0.0 a	3.2 ± 0.0 a	2.5 ± 0.0 a	5.2 ± 0.0 a	3.1 ± 0.0 a	2.5 ± 0.0 a
COM15	5.2 ± 0.0 a	3.3 ± 0.0 a	2.4 ± 0.0 a	5.0 ± 0.0 a	3.5 ± 0.0 a	2.6 ± 0.0 a
Ft	**	**	***
Fy	ns	ns	ns
Fy×t	*	*	ns

COM₅ = 5 t of compost ha⁻¹, COM₁₀ = 10 t of compost ha⁻¹, and COM₁₅ = 15 t of compost ha⁻¹. CAT = catalase, PPO = polyphenol oxidase and POX = peroxidase. * p < 0.05, ** p < 0.01, *** p < 0.001, ns: non-significant. Means (±SD) denoted by the same letter refers to non-significant differences based on Duncan’s test at p < 0.05. F_t, F_y, and F_y×t refer to the F value of the treatments, years, and the interaction of treatments and years.

). Compost significantly increased the activity of PPO and CAT in the two growing seasons compared with the control. COM₅, COM₁₀, and COM₁₅ increased CAT by 14, 19, and 24% over the control in the first year, while these increases were 22, 27, and 22% in the second season. COM₅, COM₁₀, and COM₁₅ increased the activity of PPO by 19, 19, and 22% over the control in the first season, while these increases were 31, 19, and 35% in the second growing season.

3.3. Effect of Compost on Yield and Chemical Composition of River Saltbush

The addition of compost significantly enhanced the forage yield of river saltbush plants in both studied years (Figure 2). River saltbush plant produced 9.23–15.60 t ha⁻¹ of stems and 4.25–7.20 t ha⁻¹ of leaves yearly. The addition of 5, 10, and 15 t ha⁻¹ of compost (COM₅, COM₁₀, and COM₁₅) increased the stems yield by 35, 49, and 47% over the control in the first year, while these increases were 39, 46, and 49% in the second year. COM₅, COM₁₀, and COM₁₅ increased the leaves yield by 28, 40, and 44% in the first year, while these increases were 26, 32, and 51% in the second year.

Composting the increased dry matter and crude protein in the first and second years (

Table 5. Effect of compost treatments on the chemical composition of leaves and stems of river saltbush plants (g kg⁻¹).

	2017						2018
	MC	DM	OM	CP	Fat	CF	MC	DM	OM	CP	Fat	CF
	Leaves
Control	730 ± 35 b	200 ± 8 a	780 ± 33 b	160 ± 11 b	12 ± 1.2 a	210 ± 9 a	730 ± 40 b	250 ± 6 a	700 ± 28 b	200 ± 9 c	10 ± 1.1 a	120 ± 6 a
COM5	800 ± 40 a	210 ± 7 a	810 ± 28 a	220 ± 8 a	14 ± 1.0 a	100 ± 9 b	860 ± 37 a	240 ± 5 a	810 ± 25 a	230 ± 8 ab	12 ± 1.1 a	100 ± 7 b
COM10	850 ± 32 a	210 ± 8 a	830 ± 25 a	210 ± 7 a	14 ± 1.0 a	120 ± 8 b	850 ± 38 a	270 ± 8 a	850 ± 22 a	240 ± 5 a	13 ± 1.3 a	110 ± 8 b
COM15	860 ± 40 a	200 ± 8 a	810 ± 40 a	200 ± 8 a	12 ± 1.1 a	100 ± 7 b	880 ± 32 a	270 ± 7 a	820 ± 30 a	220 ± 7 b	10 ± 1.3 a	105 ± 5 b
Ft	**	**	***	**	ns	***
Fy	ns	ns	ns	ns	ns	ns
Fy×t	*	*	ns	ns	ns	*
	Stems
Control	520 ± 22 b	480 ± 15 a	890 ± 55 b	50 ± 3 a	11 ± 1.4 a	270 ± 8 a	590 ± 24 a	450 ± 15 a	920 ± 50 a	60 ± 4 a	10 ± 1.2 a	220 ± 8 a
COM5	620 ± 18 a	480 ± 18 a	910 ± 65 a	50 ± 2 a	12 ± 1.2 a	160 ± 9 b	560 ± 18 a	470 ± 17 a	910 ± 58 b	70 ± 3 a	12 ± 1.1 a	140 ± 5 b
COM10	615 ± 25 a	480 ± 20 a	900 ± 50 a	48 ± 3 a	11 ± 1.0 a	130 ± 8 b	500 ± 27 b	500 ± 20 a	890 ± 60 d	50 ± 2 a	11 ± 1.0 a	150 ± 9 b
COM15	650 ± 26 a	450 ± 15 a	910 ± 58 a	50 ± 2 a	11 ± 1.1 a	140 ± 7 b	570 ± 22 a	490 ± 19 a	900 ± 62 c	70 ± 4 a	12 ± 1.4 a	160 ± 9 b
Ft	**	**	*	ns	ns	***
Fy	ns	*	ns	ns	ns	*
Fy×t	ns	ns	ns	ns	ns	ns

COM₅ = 5 t of compost ha⁻¹, COM₁₀ = 10 t of compost ha⁻¹, and COM₁₅ = 15 t of compost ha⁻¹, MC = moisture content, DM = dry matter, OM = organic matter, CP = crude protein, CF = crude fiber. * p < 0.05, ** p < 0.01, *** p < 0.001, ns: non-significant. Means (±SD) denoted by the same letter refers to non-significant differences based on Duncan’s test at p < 0.05. F_t, F_y, and F_y×t refer to the F value of the treatments, years, and the interaction of treatments and years.

). Moisture content, organic matter, and crude protein were increased significantly due to compost application. In general, the dry matter and crude protein in the leaves were higher than in the stems. The crude protein (CP) ranged between 48–70 mg kg⁻¹ in the stems and between 160–240 mg kg⁻¹ in the leaves. COM₅, COM₁₀, and COM₁₅ increased CP by 38, 31, and 25% in the first year, while these increases were 15, 20, and 10% in the second year.

4. Discussion

Halophyte plants tolerate high concentrations of salt, whether in soil or irrigation water, but saline leads to reduced productivity and quality [5,22]. Soil salinity inhibits plant growth through osmotic effects, specific-ion toxicity, and/or shortage and disorders of some nutrients [33,34,35]. The findings of the current study show that the role of compost addition increased the salt tolerance of river saltbush plants grown in the sandy loam saline soils, which had a salinity of 15 dS m⁻¹. Compost improved the dry matter and crude protein and the forage yield of river saltbush. Compost enhances the salt tolerance by increasing the soil quality, nutrient uptake, reducing the adsorb of toxic elements, e.g., Na⁺ and Cl⁻, and improving the physiological defense of the plants [2,14,15,36].

Our study clearly indicated that the compost addition had a positive role in increasing the essential plant nutrients uptake and reducing the uptake of Na⁺. The increases in nutrients uptake, due to compost addition, are may be due to the improvement of soil quality [14]. Organic matter in the applied compost may lead to an improvement in aeration and consequently an optimal root growth, thereby an increase in the nutrient uptake and growth [14,18,37]. K The application of composted organic materials significantly enhanced the N, P, and uptake by corn plants compared to the control, and the increase was proportional with the addition rates [18]. Compost is rich with organic materials and has a high cation exchange capacity which may reduce Na uptake [16]. Organic amendment added to saline-irrigated basil plants (Ocimum basilicum) minimized Na⁺ adsorb by 47% compared to the untreated plants [16]. Compost may absorb the soluble salts from the soil solution and reduce their availability for plant uptake [14,16,38,39,40,41].

Application of compost to saline soil enhanced the photosynthesis process and increased the chlorophyll in the leaves of river saltbush plants. The increase in chlorophyll might be due to increasing plant growth and minimizing salt stress [14,16]. Under salt stress, halophyte plants tend to reduce the synthesis of chlorophyll and increase some osmotic regulations, e.g., oxalic acid [42]. It is clear that compost in the current study reduced the negative effects of salts by activating the antioxidant enzyme defense. The liberation of the plant from salt stress led to directing the plant energy towards the synthesis of chlorophyll and growth, and thus, increased the dry matter production and the crude protein and dry matter of the resulting fodder crop. The addition of soil organic amendments increased the activity of antioxidant enzymes in tomato and maize plants [17,20]. The addition of compost improved plant growth and alleviated salt stress by increasing the uptake of macro- and micro-nutrients, which are released through the decomposition of organic matter [43,44]. Moreover, the increase in the growth could be due to the compostability in increasing the water holding capacity [9,45,46,47].

River saltbush plants cultivated on saline soils (15 dS m⁻¹) produce 13.48 to 22.80 t ha⁻¹ of dry matter yearly. Despite the high levels of salinity, halophyte plants can give high dry matter (15–22 t dry matter ha⁻¹ year⁻¹), which means great hope in supplying forage cultivation for livestock [6,7,8]. The addition of 15 t ha⁻¹ of compost caused remarkable increases in the yield and crude protein and dry matter. Similar results for the positive impacts of compost in enhancing the yield and crude protein of the halophyte plants were found [9,48,49,50,51,52].

5. Conclusions

Arid climatic conditions cause the formation of saline soils that are not suitable for the production of traditional crops. In this two-year field study, the saline soil had a salinity of 15 dS m⁻¹, and was used in the production of river saltbush—a halophytic forage plant. Compost was added to the plants to improve the soil quality and enhance growth. The findings of the current study revealed the role of compost in increasing the productivity and quality of river saltbush plants grown in saline soil. River saltbush plants produced 18 t ha⁻¹ of dry matter yearly when cultivated in saline soils. The produced forage material is valuable as animal feed, due to its high crude protein. The obtained results represent a promising opportunity to utilize saline land in arid regions to produce animal fodder. Compost should be added to halophyte plants to lessen the adverse effects of salts on the quality of the forage material. Compost assists river saltbush in overcoming the negative impacts of salinity through enhancing the nutrient uptake, photosynthesis process, and activity of antioxidant enzymes. Considering that the addition of compost increased crude protein and reduced crude fiber, then we can speculate that also the nutritional value of the forage increased. Several field studies must be done to find out the best agricultural practices that improve the quality and productivity of the halophyte plants under saline conditions.