Determination of Nutrient Contents and In vitro Gas Production Values of Some Legume Forages Grown in the Harran Plain Saline Soils

Article information

Asian-Australas J Anim Sci. 2014;27(6):825-831
1Department of Animal Science, Faculty of Agriculture, Harran University, TR-63100 Şanlıurfa, Turkey.
2Department of Animal Science, Faculty of Agriculture, Ondokuz Mayıs University, TR 55139, Samsun, Turkey.
3Department of Soil Science, Faculty of Agriculture, Harran University, TR-63100, Şanlıurfa, Turkey.
4Department of Field Crops, Faculty of Agriculture, Harran University, TR-63100, Şanlıurfa, Turkey.
*Corresponding Author: M. Boga. Tel: +90-3883114527, Fax: +90-3883118437, E-mail: mboga@nigde.edu.tr
Bor Vocational School, Niğde University, TR 51240, Nigde, Turkey
Received 2013 November 14; Revised 2014 January 08; Accepted 2014 January 31.

Abstract

The aim of this study was to determine the nutritive value of some legume species in salt-affected soils of South-East Anatolian region using chemical composition and in vitro gas production kinetics. In this study, Lotus corniculatus, Trifolium alexandrinum, Medicago sativa were sown and tested in four different locations. A 3 by 4 factorial design with 3 legume species and 4 salt levels (non salty electrical conductivity (EC)<4 dS/m; low salt: 4 dS/m>EC<8 dS/m, medium saline: 8 dS/m>EC<16 dS/m and high salt: 16 dS/m>EC) was used in the study. Results indicated that salinity and plants had no significant effect on ash and ether extract. Dry matter (DM), acid detergent fiber, digestible dry matter, dry matter intake (DMI) were affected by plant, salinity and plant×salinity interaction. On the other hand neutral detergent fiber, relative feed value (RFV), and DMI were affected by salinity and plant×salinity interaction. Mineral contents were affected by plant species, salinity and salinity×plants interactions. In vitro gas production, their kinetics and estimated parameters such as were not affected by salinity whereas the gas production up to 48 h, organic matter digestibility, metabolizable energy (ME), and net energy lactation (NEL) were affected by plant and plant×salt interaction. Generally RFVs of all species ranged from 120 to 210 and were quite satisfactory in salty conditions. Current results show that the feed value of Medicago sativa is higher compared to Lotus corniculatus and Trifolium alexandrinum.

INTRODUCTION

Salinity and sodicity are major challenges for South Anatolian Region of Turkey, especially the Sanliurfa Harran plain. Crop production has increased in the area by rising water tables with the start of the Atatürk Dam irrigation. As water tables rise they bring salts from deep in the soil profile to the surface. It is predicted that increasing salt levels in soils will lead to marked reductions in yields of forage plants grown in the region (Taban et al., 1999). In Harran Plain dryland salinity has already reached 132,000 ha of irrigated agricultural land from total 225,000 ha of Harran area (Aydemir et al., 2005). Although Legumes as fodder crop are more sensitive to salinity than Poaceae, use of salt resistant plants such as some perennial and annual legumes (for example Medicago sativa, Lotus corniculatus, Trifolium alexandrinum) offer an opportunity to reduce the feed shortages associated with soil salinity and to improve the productivity of salt-affected land.

In vitro gas production has been developed as a predictive tool of nutrient content and in vitro DM digestibility has been widely used (Menke and Steingass, 1988; Getachew et al., 2004) to assess the nutritional quality of feeds due to its high correlation with in vivo digestibility. Although the mechanisms of salt injury and salt tolerance of whole plants have been studied extensively, the effects of salt stress on nutrient content, in vitro gas production, organic matter degradability, metabolic and net energy lactation levels of these legume plants hay have not been determined.

The objective of this study was to determine the feed values of different legume hays (Medicago sativa, Lotus corniculatus, Trifolium alexandrinum) grown in salt-affected soils of South-east Anatolian region as assessed by gas production parameters, intake, and digestibility and nutrient composition.

MATERIALS AND METHODS

This study was conducted over the period from autumn 2006 to autumn 2009 at University of Harran (Sanliurfa province) and University of Cukurova (Adana province) of the Republic of Turkey. Cultivation area was between Urfa mountains in north and Turkey-Syria border in south. All of the samples were grown at Harran plain and Akçakale from Sanliurfa province and the salt levels in these regions were identified in four different locations and then they were grouped according to their level of salt. Harran University in the northern region was not salty but Akçakale was very heterogeneous in terms zone salinity and salinity levels ranged between 10 and 21 electrical conductivity (EC) dS/m. The university district represented unsalted soils (2–6 EC dS/m) but the salt level was detected as low, medium, high in Akçakale plain. The experiments began in autumn 2006 and lasted for three years. This study was aimed to test the nutrient content of different of glycophyte legume species growing in different salt-affected soils by in vitro gas production. So we chose three leguminous crops to study the effect of salinity on plant nutrient use and in vitro parameters. Trial was transformed into salinity plant species interactions (3×4). A 3 by 4 factorial design with 3 legume species and 4 salt levels as main effects was used. Soil salinity was expressed as EC. Three species of legumes were tested in two different locations having four saline levels (non salty EC<4 dS/m; low salt: 4 dS/m>EC<8 dS/m, medium saline: 8 dS/m>EC<16 dS/m and high salt: 16 dS/m>EC). Studies were conducted in natural areas and plants were sown in these lands. Soil salinity was measured twice a year. Ground water height or water table did not change significantly during the experiments. There was no problem associated with excessive irrigation and drainage. Therefore, no change occurred in the level of salinity (EC) in the experiments.

The study experimental design was randomized 3 blocks according to topographical characteristics to determine the effects on the legume species after three years by taking account some necessary nutrient aspects such as metabolic and net energy content via in vitro gas production technique. Three legume species were harvested in the beginning of blooming by cutting at ground level and then were field-dried. After that the samples were ground in a laboratory mill to pass through a 1 mm screen for chemical analyses and for incubation in in vitro gas production assays. Dry matter, crude protein, ash and ether extract of feeds were analyzed according to AOAC (1998) procedure. Crude protein was calculated as N×6.25. Acid detergent fiber (ADF) and neutral detergent fiber (NDF) analysis were based on the method of Van Soest et al. (1991) using ANKOM fiber analyzer. All chemical analyses were carried out in triplicate for each replication of plants.

Ca, Na, Mg, and K analyses in plants

Representative 500 g moist plant samples taken from each plot were dried at 70°C until constant weight. After drying, solutions of ground plants with a mixture of perchloric acid were subjected to the process of wet burning. Mineral substances from the plant solution after the burning process were determined by reading with ICP-OES (Chapman and Prat, 1982).

Calculation of relative feed value, digestible dry matter, and dry matter intake

Relative feed value (RFV) is a widely accepted forage quality index in the marketing of hays in the United States of America. The RFV combines the estimates for forage digestibility and intake into a single number and it is calculated from estimation of ADF and NDF (Ward, 2008). The RFV index was estimated the digestible dry matter (DDM) of the samples from ADF values, and was calculated the dry matter intake (DMI) potential (as a percent of body weight, BW) from NDF values. The index was then calculated as DDM multiplied by DMI as a % of BW and divided by 1.29 (Jerenyama and Garcia, 2004).

DDM=88.9-(0.779×%ADF)DMI (%of BW)=120/(%NDF)RFV=(DDM×DMI)/1.29

In vitro gas production technique

Three Holstein cows aged 5 years with ruminal cannulas (average live weight 650 kg) were used to provide rumen fluid for the in vitro gas production technique. Rumen fluid was obtained from the fistulated cows fed twice daily (08.30 to 16.30) with a diet containing corn silage (60%) and concentrates (40%) (Table 3).

Mineral components of legume plants cultivated from different salt-affected fields

Approximately 200 mg dry weight of samples was weighed in triplicate into 100 mL calibrated glass syringes following the procedures of Menke and Steingass (1988). The syringes were pre-warmed at 39°C before the injection of 30 mL rumen fluid-buffer mixture (1:2) into each syringe and incubated in a water bath at 39°C. Gas volumes were recorded at 0, 3, 6, 9, 12, 24, 48, 72, and 96 h of incubation. Cumulative gas production data were fitted to the model of Ørskov and McDonald (1979) by NEWAY computer package program.

y=a+b(1-e-ct)

Where, a, the gas production from the immediately soluble fraction (mL); b, the gas production from the insoluble fraction (mL); c, the gas production rate constant for the insoluble fraction (mL/h); a+b, potential gas production (mL); t, incubation time (h); y, gas produced at time “t”. Organic matter digestibility (OMD), metabolizable energy (ME) (Menke et al., 1979) and net energy lactation (NEL) (Menke and Steingass, 1988) contents of forages were estimated using equations given below:

OMD (%)=14.88+0.889GP+0.45CP+0.651AME (MJ/kgDM)=2.20+0.136GP+0.0574CPNEL(MJ/kgDM)=0.101GP+0.051CP+0.112EE

Where; GP, 24 h net gas production (mL/200 mg DM); CP, crude protein (%); A, Ash content (%); EE, Ether extracts (%).

Statistical analysis

Study was repeated 3 years and each year was taken as a block. But plant samples by combining three years were analyzed to compare nutrient contents, gas production parameters, energy, DDM and OMD values using General Linear Model (GLM) of Minitab (Version 16.0, 2006) package programs. All parameters from 3 Legume species with 4 salinity levels were analyzed using 3×4 factorial designs. Multiple comparisons among individual means were made with Minitab 16.0 in factorial designs.

RESULTS

Nutrient contents of legume species grown in soils with four salt levels

Chemical compositions of all forages are presented in Table 2. The dry matter content of each legume plant significantly changed among species and showed significant change with the salt levels, and the interaction of species by salinity. Trifolium alexandrinum had highest DM content.

Chemical compositions, RFVs, DDMs and DMIs of samples used in the study

Results indicated that salinity and plants had no significant effect on ash and ether extract. Dry matter (DM), ADF, DDM, DMI were affected by plant, salinity and plant×salinity interaction. On the other hand NDF, RFV, and DMI were affected by salinity and plant×salinity interaction. Generally RFVs of all species ranged from 120 to 210 and were quite satisfactory in salty conditions. Mineral contents also were affected by plant species, salinity and salinity×plants interactions.

In vitro gas production kinetics and estimated parameters such as were not affected by salinity whereas the gas production up to 48 h, OMD, ME, and NEL was affected by plant and plant x salt interaction.

DISCUSSION

The nutrient components of all plants were relatively similar for four salinity levels except for Lotus corniculatus (Table 2). This may be attributed to its characteristic structure. Lotus corniculatus is more resistant compared to Medicago sativa. According to Bakir (1985); Lotus corniculatus has been reported to be resistant to soil salinity of 12 to 16 dS/m. For this reason, Lotus corniculatus is recommended in hot, arid regions such as the Harran plain. All components, especially CP is enough to cover ruminant nutrient requirements. According to El Shaer (2010), most of salt tolerant fodders attain reasonable CP, although they have high ash content. Furthermore, such plants grown in saline soils are usually fairly poor in energy and high in CP (Le Houérou et al., 1982). These studies showed that salt stress tended to enhance CP content of Lotus corniculatus compared other legume species. The increase in CP content of this forage is likely attributed to its structural properties. Leaf loss of Lotus corniculatus was the greatest during drying (Aydemir et al., 2011). But it was not main subject of this study and fresh and dry matter yield were not provided. Leaf loss caused an increase in NDF. NDF is inversely proportional to HP in plants. Lower CP in Lotus corniculatus can be attributed to the high NDF content and leaf loss (Table 2). On the other hand, Fougere et al. (1991) suggested that salt stress induced a large increase in the amino acid and carbohydrate contents in some legume plants. Salt tolerant plant species contain high crude protein and salt and low metabolic energy (Norman et al., 2002). But, it is known that salt stress generally decreases productivity in all plants. The CP content averaged 19% in legume plants used in the present study which was enough to cover the protein requirements of small ruminants.

The ADF content of Lotus corniculatus decreased with increasing soil salinity levels. The specific effects of ADF on feed intake are already known. The DMI of Trifolium alexandrinum showed low values due to the increased salt levels in soil. Soil salinity has been reported to negatively influence feed intake and digestibility because of thenreduction in nitrogen uptake (Mashhady et al., 1982). Absence of significant changes in nutrient content of alfalfa indicated that these alfalfa varieties growing on saline soils can produce high to moderate consumable biomass for livestock feeding at four salt levels (4dS/m<EC<16 dS/m) of soil series. The specific mechanisms of tolerance to salinity that are used by alfalfa are unknown (Smith, 1998). Alfalfa plants utilize salt exclusion as a mechanism to cope with salinity issues and they do exclude Na+ but do not exclude Cl (Brown and Hayward, 1956; Lauchb, 1984). Alfalfa is more salt tolerant because it is able to regulate the uptake and translocation of Na+ and Cl to prevent excessive accumulation of these ions in leaves (Munns, 2005).

Salinity resulted in a significant accumulation of some minerals (except Ca) especially in Medicago sativa. Data on mineral content revealed that K retention was significantly affected by the levels of soil salinity in Lotus corniculatus. Salinity caused a cubic accumulation of Na mineral especially in Lotus corniculatus and Trifolium alexandrinum. Jia et al. (2008) suggested that high salt levels impose both ionic and osmotic stresses on plants, resulting in an excessive accumulation of sodium (Na) in plant tissues. Because the mentioned minerals were higher in the Akçakale region than the Harran region (Ikizce soil series), some of the mineral contents of plants such as Mg, Na, K, and Ca were higher in this area. Suyama et al. (2007) reported more Na accumulation for ‘Salado’ alfalfa grown under irrigation with drainage water causing soil salinity of 5.2 to 6.4 dS/m. It is well known that at a whole plant level, salinity stress induces an increase in Na, as well as a decrease K and Ca concentrations (Lutts, 1996). Salinity also causes the rate of photosynthesis to decrease and causes the nutrient uptake and Ca++ transport to decrease (Taban and Katkat, 2000). Although concentrations of Mg, Na and K were higher than the level of non-salty soils, the concentrations are still within the maximum tolerance levels for sheep and beef cattle specified by NRC (1984, 1985). As stated by Masters et al. (2001), sheep can tolerate a sodium chloride intake in feed of about 100 to 150 g/d provided that they have access to a non saline drinking water. Although the high Na and K content may limit feed intake, K did not lead to a reduction in feed consumption due to reduced K in Lotus corniculatus. However, we do not know whether these forages growing under salty conditions are consumed less than in current conditions because this trial was not an in vivo study. Therefore more in vivo studies are required to determine the effect on the feed intake of ruminants. There were no significant differences among groups with salinity levels in terms of the in vitro gas production, the immediately soluble fraction a, the gas production from the insoluble fraction b and the rate of gas production constant from the insoluble fraction c (p<0.05) (Table 4). This can be attributed to the similar ash, CP and ether extract values in salinity conditions for each plant. In this study, the nutrient content of all species was at a similar level for microbial fermentation. It is well documented that the nutrient contents of feeds effect their potential production of gas quantity and level of gas produced tends to decrease or increase with changing chemical content of feeds (Doane et al., 1997; Abdulrazak et al., 2000). Poor energy of plants in saline soils is frequently seen (Abdulrazak et al., 2000). All varieties had approximately ME of 7.2 MJ/kg DM. In general, ME values below 7 MJ/kg DM are considered to be unacceptable for beef cattle and goats (NRC, 1981;1984). Varieties with ME values between 7 and 9 MJ/kg DM are suitable for low production or maintenance level of beef cattle but not acceptable for dairy cattle and rapidly growing calves.

In vitro gas production (mL) parameters and ME, NEL and OMD values of Legume species

The Hay Marketing Task Force of the American Forage and Grassland Council (AFGC) endorses the use of RFV as a measure of forage quality (Linn and Martin, 2008). According to the Quality Grading Standard assigned by the Hay Market Task Force of AFGC, the RFV values were founded as “Premium” 2 or “Prime” for all legume species in current study and they were quite satisfactory levels in salty soil conditions (all plants ranged from 120.1 to 210.2; Table 2).

In conclusion, this study showed that these legume species can be used as salt tolerant forages for ruminant diets in areas with soil salinity. These glycophyte species (especially Medicago sativa) can meet forage quality standards and they yield highly edible biomass on saline lands where non-salt tolerant species cannot grow. In these areas, a shortage of feed resources is a common problem and is considered as a major constraint to increasing livestock productivity. The DMI and RFV did not show a negative trend under current salinity conditions except Trifolium alexandrinum (Table 2). Where animal production systems are based on forage from soils with higher salt concentrations more attention should be given to Trifolium alexandrinum if salt free water is in limited supply. On the other hand, salinity does not have a significant impact on the nutritional value of these plants under all salinity conditions. Provided sufficient water consumption, accumulation of mineral elements in Medicago sativa and Lotus corniculatus plants does not limit the DM consumption.

Chemical compositions of forage and concentrate fed to animals

ACKNOWLEDGMENTS

We thank project owners (TOVAG-106O145) for allowing us use of plant materials and we are grateful to Agricultural Faculty members of Harran University for their help extended in identification. We are also most grateful to the Harran University of Şanlıurfa, Cukurova University of Adana, and Ondokuz Mayıs University of Samsun-Turkey for permission to work and analyses in the feed laboratory.

References

Abdulrazak SA, Fujihara T, Ondilek JK, Orskov ER. 2000;Nutritive evaluation of some Acacia tree leaves from Kenya. Anim Feed Sci Technol 85:89–98.
AOAC. 1998. Officinal Methods of Analysis 16th Editionth ed. AOAC International. Gaithersburg, MD, USA:
Aydemir S, Cullu MA, Polat T, Sonmez O, Dikilitas M, Akil H. 2008. Harran Plain soils facing salinity problems and their possible amelioration status. In : Proceedings of the Irrigation and Salinity Conference; 12–13 June 2008; Sanliurfa, Turkey. p. 45–62.
Aydemir S, Polat T, Çullu MA, Kaya C, Sönmez O, Hacıkamiloğlu B, Dikilitaş M, Yurtseven S, Doğan E, Sürücü A, Karakaş S. 2011. Adaptation of glycohyte and halophyte fodder crops to the Saline Soils of Harran Plain and their amendatory effects on physico-chemical characateristics of soil. Tubitak Project Report. Project No: 106 O 145
Bakir O. 1985. Pasture Improvement Strategies Ankara University. Ankara: p. 272.
Brown JW, Hayward HE. 1956;Salt tolerance of alfalfa varieties. Agron J 48:18–20.
Chapman HD, Pratt PF. 1982. Methods of analysis for soils, plants and water. Methods of Soil Analysis Part 1: Physical and Mineralogical Methods 2nd Editionth ed. Agronomy Series No: 9. Am. Soc. Agronomy and Soil Sci. Soc. Am. Inc. Publisher. Madison, Wisconsin USA:
Doane PH, Schofield P, Pell AN. 1997;Neutral detergent fiber disappearance and gas and volatile fatty acid production during the in vitro fermentation of six forages. J Anim Sci 75:3342–3352.
El Shaer HM. 2010;Halophytes and salt-tolerant plants as potential forage for ruminants in the Near East region. Small Rumin Res 91:3–12.
Fougere F, Le Rudulier D, John G. 1991;Streeter effects of salt stress on amino acid, organic acid, and carbohydrate composition of roots, bacteroids, and cytosol of alfalfa (Medicago sativa L.). Plant Physiol 96:1228–1236.
Getachew G, Robinson PH, De Peters EJ, Taylor SJ. 2004;Relationships between chemical composition, dry matter degradation and in vitro gas production of several ruminant feeds. Anim Feed Sci Technol 111:57–71.
Jeranyama P, Garcia AD. 2004. Understanding relative feed value (RFV) and relative forage quality (RFQ) Cooperative Extension Service, South Dakota State University; Brookings, SD, USA: http://pubstorage.sdstate.edu/AgBio_Publications/articles/exex8149.pdf. Accesed September 27, 2011.
Jia YX, Sun L, He F, Wan LQ, Yuan QH, Li XL. 2008;Analysis of effects of salt stress on absorption and accumulation of mineral elements in elymus spp. using atomic absorption spectrophotometer. Guang Pu Xue Yu Guang Pu Fen Xi 28:2984–2988.
Lauchb A. 1984. Salt exclusion: An adaptation of legume for crops and pastures under saline condition. Salinity Tolerance in Plants. Strategies for Crop Improvement In : Stoples RC, Toenniessen GH, eds. John Willey and Sons. Tolonto, Canada: p. 171–187.
Linn JG, Martin NP. 1999. Forage quality tests and interpretations University of Minnesota Extension Service. Minneapolis: 1989. (MN AG-FO-02637).
Lutts S, Kinet JM, Bouharmont J. 1996;Effects of salt stress on growth, mineral nutrition and proline accumulation in relation to osmotic adjustment in rice (Oryza sativa) cultivars differing in salinity resistance. Plant Growth Regul 19:207–218.
Mashhady AS, Sayed HI, Heakal MS. 1982;Effect of soil salinity and water stresses on growth and content of nitrogen, chloride and phosphate of wheat and triticale. Plant Soil 68:207–216.
Menke KH, Raab L, Salewski A, Steingass H, Fritz D, Schneider W. 1979;The estimation of the digestibility and metabolizable energy content of ruminant feedingstuffs from the gas production when they are incubated with rumen liquor in vitro. J Agric Sci Camb 93:217–222.
Menke KH, Steingass H. 1988;Estimation of the energetic feed value obtained from chemical analysis and in vitro gas production using rumen fluid. Anim Res Dev 28:7–55.
Munns R. 1993;Physiological processes limiting plant growth in saline soils: Some dogmas and hypotheses. Plant Cell Environ 16:15–24.
Norman HC, Masters DG, Dynes RA, Henry DA. 2002;Live weight change and wool growth in young sheep grazing a mixed saltbush and balansa clover pasture. Anim Prod Aust 24:334.
NRC. 1981. Nutrient Requiremets of Domestic Animals N015. Nutrient Requirements of Goats National Academy Press. Washington, DC, USA:
NRC. 1984. Nutrient Requiremets of Small Ruminants National Academy Press. Washington, DC, USA:
NRC. 1985. Nutrient Requiremets of Beef Cattle Ruminants National Academy Press. Washington, DC, USA:
Ørskov E, Mcdonald I. 1979;The estimation of protein degradability in the rumen from incubation measurements weighted according to rate of passage. J Agric Sci Camb 92:499–503.
Smith SE. 1998. Evaluating salt tolerance: some experiences with nondormant alfalfa. In : Proceedings of the 36th North American Alfalfa Improvement Conference; August 2–6 1998; Bozeman, MT, USA.. p. 24–25.
SPSS. 2006. Windows Evaluation Version (Base 15.0) Chicago, IL, USA:
Suyama H, Benes SE, Robinson PH, Getachew G, Grattan SR, Grieve CM. 2007;Biomass yield and nutritional quality of forage species under long-term irrigation with saline-sodic drainage water: Field evaluation. Anim Feed Sci Technol 135:329–345.
Taban S, Katkat V. 2000;Effect of salt stress on growth and mineral elements concentrations in shoot and root of maize plant. J Agric Sci 6:119–122.
Van Soest PJ, Robertson JB, Lewis BA. 1991;Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. J Dairy Sci 74:3583–3597.
Ward R. 2008. Relative feed value (RFV) vs. relative forage quality (RFQ) http://www.foragelab.com/Media/RFV_vs_RFQ-CVAS%20Perspective.pdf. Accesed January 20, 2014.

Article information Continued

Table 1

Chemical compositions of forage and concentrate fed to animals

Feeds DM (g/kg) CP EE CF Ash NDF ADF
——— g/kg DM ———
Forage (Corn silage) 318.3 105.7 35.1 236.1 88.8 453.6 296.1
Concentrates 907.9 281.4 44.3 96.2 60.7 266.9 93.4

DM, dry matter; CP, crude protein; EE, ether extracts; NDF, neutral detergent fiber, ADF, acid detergent fiber.

Table 2

Chemical compositions, RFVs, DDMs and DMIs of samples used in the study

Plants Salinity DM NDF ADF Ash (%) CP (%) EE (%) RFV DDM DMI
Lotus curniculatus Non salt 92.5ab 44.5c 40.5e 10.8a 14.9a 2.4ab 120.1a 57.3a 2.7a
Low salt 92.9abc 44.2c 37.2cde 11.4ab 17.6ab 2.9ab 126.7a 59.9abc 2.7a
Medium salt 93.2cde 39.3bc 34.4bcd 12.9bc 18.2b 3.2ab 128.4a 62.1bcd 2.6a
High salt 92.0a 29.9a 27.5a 13.3c 18.9b 2.5ab 210.2c 67.5e 4.1c
Trifolium alexandrinum Non salt 94.9f 34.8ab 31.5.5ab 12.2abc 19.9bc 2.1ab 167.2b 65.8de 3.4b
Low salt 94.4def 42.4bc 32.7bc 11.7abc 17.6bc 2.0a 139.2ab 63.5bcde 2.8ab
Medium salt 94.8f 40.8bc 37.6de 11.3abc 17.6bc 3.2b 132.9a 59.6ab 2.9ab
High salt 94.2de 43.6bc 36.7cd 13.1c 20.3 2.9ab 128.6a 60.3abc 2.8ab
Medicago sativa Non salt 94.6def 39.7bc 32.6bc 11.7abc 22.4cd 2.0ab 153.2ab 63.2bcde 3.1ab
Low salt 93.3bcd 39.9bc 32.1ab 10.9a 22.8d 2.6ab 149.8ab 63.9cde 3.0ab
Medium salt 94.6ef 36.2ab 30.9ab 12.2abc 23.3d 2.2ab 170.3b 64.6de 3.4b
High salt 92.4a 36.2ab 30.6ab 11.6abc 22.6cd 2.7ab 169.1b 65.1de 3.3b
SEM 0.1 0.6 0.5 0.2 0.3 0.1 3.3 0.5 0.05
Plants ** NS * NS ** NS NS * NS
Salinity ** ** ** NS NS NS ** ** **
Plants×salinity * ** ** NS NS NS ** ** **

RFV, relative feed value; DDM, digestible dry matter (% of body weight); DMI, dry matter intake (% of body weight); DM, dry matter; NDF, neutral detergent fiber; ADF, acid detergent fiber; CP, crude protein; EE, ether extracts; SEM, standard error of means; NS, no significant differences.

*

p<0.05;

**

p<0.01.

a–e

Significance between individual means was identified using the Duncan’s multiple comparative tests.

Table 3

Mineral components of legume plants cultivated from different salt-affected fields

Mineral components(ppm) Salinity level

Non-salty Low salty Medium salty High salty
Lotus curniculatus K 18.6 19.3 13.8 11.5
Na 144.6 138.4 172.7 150.5
Ca 94.9 103.5 98.1 100.3
Mg 16.3 32.5 30.8 29.1
Trifolium alexandrinum K 26.0 36.6 28.5 32.8
Na 145.3 70.9 155.2 137.3
Ca 105.9 134.5 81.3 102.2
Mg 13.3 26.1 20.3 24.3
Medicago sativa K 9.0 12.7 19.5 17.8
Na 140.0 126.7 168.1 171.4
Ca 115.0 93.6 93.1 93.6
Mg 15.7 23.3 20.9 21.1
SEM 0.41 1.34 1.10 0.58
Legume species ** ** * **
Salinity level ** ** ** **
Legume species×salinity level ** ** ** *

SEM, standart error mean.

*

p<0.05;

**

p<0.01.

Table 4

In vitro gas production (mL) parameters and ME, NEL and OMD values of Legume species

Plants Salinity 3 6 9 12 24 48 72 96 a b c OMD ME NEL
Lotus curniculatus Non salt 2.6b 5.9b 10.3b 14.7b 26.9cd 35.5ab 40.1bc 41.5bc −3.7abc 46.0 0.04 46.2f 6.7e 3.7ef
Low salt 2.0b 5.4bc 10.5b 15.3b 27.7cd 38.5ab 41.6abc 43.1abc −5.2c 49.1 0.05 48.2ef 7.0cde 4.0def
Medium salt 5.5a 8.9a 13.9a 18.8a 31.2ab 40.3a 44.3ab 45.9ab −1.5ab 47.1 0.05 51.6bc 7.5ab 4.4abc
High salt 2.5b 5.8bc 10.0b 14.2b 25.4d 30.7b 38.1bc 39.9bc −2.2abc 42.6 0.04 46.9ef 6.8de 3.8ef
Trifolium alexandrinum Non salt 1.9+ 5.2c 10.0b 14.7b 26.9cd 37.0ab 40.0bc 41.5bc −5.0c 47.2 0.05 48.3def 7.0cde 3.9def
Low salt 6.0+ 8.7a 13.7a 18.5a 30.5abc 39.4ab 43.7abc 45.3abc −0.8a 46.6 0.04 51.7abcd 7.6abc 4.3bcd
Medium salt 2.4ab 5.7bc 9.8b 13.8b 27.7cd 29.8b 37.1c 38.8bc −2.1abc 41.5 0.04 45.5f 6.6e 3.7ef
High salt 2.1b 5.5bc 10.8b 15.5b 28.2bcd 38.8ab 42.1abc 43.6abc −5.3c 49.5 0.05 49.5cdef 7.2bcd 4.2cde
Medicago sativa Non salt 5.8a 8.9a 13.9a 18.7a 31.0ab 40.2a 44.1ab 45.8ab −1.2a 47.4 0.04 53.3ab 7.7a 4.5ab
Low salt 2.5b 5.8bc 10.1b 14.4b 26.3d 34.6b 39.1c 40.6c −3.6bc 44.9 0.04 49.3cdef 7.1cde 4.1de
Medium salt 1.9b 5.7bc 10.0b 14.8b 26.7d 37.1ab 40.1c 41.6bc −5.0c 47.4 0.05 49.9cde 7.2bcd 4.1de
High salt 5.9a 9.1a 14.3a 19.1a 31.8a 41.0a 45.2a 46.8a −1.3a 48.5 0.04 54.1a 7.8a 4.7a
SEM 0.2 0.04 0.08 0.1 0.2 0.4 0.3 0.4 0.1 0.5 0.001 0.2 0.03 0.02
Plants * ** ** ** ** * NS NS NS NS NS ** ** **
Salinity NS NS NS NS NS NS NS NS NS NS NS NS NS NS
Plants×salinity ** ** ** ** ** ** ** ** * * * ** ** **

ME, metabolizable energy; NEL, net energy lactation; OMD, organic matter digestibility; a, the gas production from the immediately soluble fraction (mL); b, the gas production from the insoluble fraction (mL); c, the gas production rate constant for the insoluble fraction (mL/h); SEM, standard error of means; NS, no significant differences.

*

p<0.05;

**

p<0.01.

a–f

Significances between individual means were identified.