1. Introduction
Legumes are considered the second most important source of human food after cereals, with pulses including only those species belonging to the legume family and whose product is represented by dry grain to be used as it is, according to the FAO classification [
1]. Legumes have a key role in crop rotation, especially for their nitrogen-fixing ability, which is particularly advantageous for cereals [
2]. Grain legumes are a valuable source of food proteins, but also of other nutrients such as starch, dietary fiber, vitamins, minerals and phenols [
3]. In order to encourage political actions to promote the cultivation of these valuable crops, the FAO declared 2016 to be “the International year of Pulses” (ONU A/RES/68/231).
Chickpea (
Cicer arietinum L.) is the third most important legume crop in the world, following the common bean and the pea, and one of the major ones cultivated in the Mediterranean basin, with an increasing trend of cultivation also in Italy [
1].
Chickpea is one of the earliest cultivated vegetables, starting around 7450 years ago in the Middle East [
4]. There are two main commercially available types of chickpea grown in the world: desi and kabuli seed types. The former has a small seed with a dark irregular-shaped seed coat and is grown on semi-arid land, especially Asia and Africa, while the latter is larger than the desi chickpea, has a thin light-colored seed coat and is normally grown in temperate regions of the world, including Europe, North Africa, West Asia, North America and Australia [
5]. The chickpea is also well adapted to temperate environments, such as the Mediterranean basin, due to its tolerance to moderate water deficit. Its main limitation is represented by ascochyta blight (AB) caused by
Ascochyta rabiei Pass., which can lead to severe loss of grain production [
6].
Chickpea seed is generally rich in carbohydrates (54–71%), including starch and dietary fiber, physiological active compounds and good-quality protein (18–26%). Proteins are stored in membrane-bound organelles (protein bodies) and are a store of amino acids for developing seedlings. As for other legumes, chickpea proteins are classified according to their solubility into albumins (soluble in water; 10–14%), globulins (soluble in salt solutions; 55–60%), prolamins (hydro-alcoholic solutions; 2–3%) and glutelin (acid/alkali solutions; 18%). Globulins are composed of the two major groups, classified on the basis of the sedimentation index into 11s legumin and 7s vicilin and convicilin, which belong to the cupin superfamily. Within albumin fraction, the major component is represented by 2s albumin, which consist of two subunits of 8–10 kDa and 4–5 kDa, linked by two di-sulfide bounds. This fraction is rich in cysteine; meanwhile, chickpea proteins are generally poor in sulfur amino acids. Other minor proteins include lectins, protease inhibitors and lipoxygenase [
3,
7].
In recent years, research activities have been focused on the exploration and characterization of chickpea germplasm, in order to pursue breeding goals of biotic (AB) and abiotic resistance and nutritional quality [
8,
9,
10]. Furthermore, the increasing interest in spreading pulses in crop systems is leading to the development of agronomic and crop physiology studies in order to promote environmental and economic sustainability [
11,
12,
13]. Experimental studies on the improvement of chickpea productivity and food quality under organic farming are necessary to achieve sustainable goals. Nowadays, little information is available on this topic, in particular with respect to the effect on health quality. However, preliminary studies seem encouraging [
14,
15].
The aim of the current study was to explore genetic variability in terms of response to different farming systems; in order to do this, eight different chickpea genotypes were cultivated under organic and conventional management and both agronomic and quality performances were evaluated in relation to the changes in protein composition, assessed by electrophoresis analysis.
2. Materials and Methods
2.1. Field Experiments
Two experimental field trials, under conventional and organic management, were carried out at Foggia at the experimental farm of the Council for Agricultural Research and Economics, CREA-CI, Foggia (41°27′03” N, 15°30′06” E), during two consecutive crop years (2013/14 and 2014/15, referred to as 2014 and 2015, respectively). The genetic material adopted in the experiments included eight different chickpea (
Cicer arietinum L.) genotypes selected within Italian germplasm. The seed characteristics are detailed in
Table 1.
A complete randomized block design was used, with three replicates, within organic and conventional cropping systems (OCS and CCS, respectively). The OCS was based at a field that had been managed under organic farming for the previous 14 years and no chemical inputs had been used as fertilizers or for weed control. The experimental plots were seeded on a field that was left fallow during the previous year. The soil used under the organic farming system was a clay loam (Typic Chromoxerert) with the following physical and chemical characteristics: 36.9 g kg−1 clay, 50.5 g kg−1 silt, 12.5 g kg−1 sand, 15 mg kg−1 available phosphorus (Olsen method), 800 mg kg−1 exchangeable potassium, 1.4 g kg−1 total N and 21 g kg−1 organic matter, pH 8. An adjacent silt loam soil (Typic Chromoxerert) was adopted for the CCS experiment, with the following physical and chemical characteristics: 15.9 g kg−1 clay, 48.7 g kg−1 silt, 35.4 g kg−1 sand, 28 mg kg−1 available phosphorus (Olsen method), 690 mg kg−1 exchangeable potassium, 1.0 g kg−1 total N and 21g kg−1 organic matter, pH 7.8.
Under the CCS, plots received 76 kg ha−1 P2O5 at pre-seeding and 30 kg ha−1 N applied at seedbed preparation as diammonium phosphate. Treatments with herbicides (Pendimethalin, 796 g a.i. ha−1) and fungicides (Azoxystrobin, 200 g a.i. ha-1) were applied according to local standard practices. The field trial included plots where the previous crop was durum wheat.
The soil preparation of the organic and conventional fields consisted of ploughing, hoeing and harrowing twice before sowing. The plots consisted of three 7.5-m long rows that were 50 cm apart (inter-row), which were sown with 50 seeds m
−2 at the beginning of December (sowing at 12 December 2013 and at 12 December 2014, respectively, for the two growing seasons), under wet conditions. A marked difference in terms of weed pressure occurred between the two cropping systems, with higher values under the OCS experiments (
Table S1, Supplementary Material).
2.2. Weather Conditions
Rainfall distribution and monthly mean maximum and minimum temperatures relative to 2014 and 2015 crop years are reported in
Figure 1. The first year was wetter than the second one (445.6 mm in 2013/14 vs. 237.6 mm in 2014/15), both in the early and late growing stages. A more comparable temperature distribution was observed between the two crop years, with a monthly mean of daily T° max above 40 °C in the late part of grain maturation in the first crop year (June 2014), which was generally slightly warmer.
The two crop seasons differed in terms of biotic stress, with a markedly higher incidence of ascochyta blight (AB) in the wetter 2014 (10.0% vs. 0.6% of diseased plants, in 2014 and 2015, respectively).
2.3. Agronomic Characterization and Seed Quality
At maturity, seeds were harvested and grain yield (GY, in kg ha−1) and seed weight (GW, in mg) were determined and expressed on a dry matter basis. The number of seeds per m2 (GNO) was calculated by dividing GY by GW. Seed nitrogen (N) concentration was measured with the Dumas combustion method (Leco FP528), and grain nitrogen uptake (GNU, in kg of N ha−1) was calculated by multiplying GY to grain N concentration. Crude protein content (PC) was determined by multiplying grain N concentration x 6.25. Grains were ground in a Cyclotec 1093 mill (Tecator, Sweden) for chemistry analysis on proteins.
2.4. Water-Holding Capacity
Grain water-holding capacity (WHC) was determined according to a modified protocol adapted from [
16]. Briefly, 5 g of flour (dry weight) was suspended in 50 mL of distilled water, mixed thoroughly for 30 min and then centrifuged at 5000 rpm for 10 min. The free water was removed from the wet flour which was then weighed. The average of two determinations was reported in grams of water per gram of flour.
2.5. Protein Extraction and SDS-PAGE Analysis
Soluble proteins were extracted from a protocol adapted from [
17]. Briefly, 100 mg of grounded flour was suspended with 1 mL of extraction buffer (50 mM Tris–HCl, pH 7.8, 5 mM EDTA, 0.1% 1,4-dithiothreitol) for 1 h at room temperature with constant mixing and centrifuged at 10,000 g for 30 min. The supernatant, containing the total soluble proteins, was used to prepare samples for SDS-PAGE. The protein content in the supernatant was quantified according to the Bradford protocol. For each sample, 10 μL of extracted proteins was separated by SDS-PAGE (at 12%) using an SE 600 apparatus (Hoefer, Inc., Holliston, MA, USA). Gels were stained with Coomassie Brilliant Blue G250 and digitally acquired (Epson Perfection V750pro) [
18]. Molecular weight markers, from 10 to 250 kDa, were used (Bio-Rad Co). Image analysis of gels was performed by ImageQuant TL software (Amersham Biosciences). The relative amount of each protein band abundance was determined by densitometric analysis and expressed as a percentage of the total protein amount in each gel lane. The expression of four groups of proteins was assessed on denaturated protein bands [
19]: 7s convicilin (~68–70 kDa), 7S vicilin (~43, 50 and 53 kDa subunits), 11s legumin (~37 and ~25 kDa as acid subunit α- and basic subunit β-, respectively), lectin (~32 kDa) and 2s albumin (~11 kDa), and the ratio between 7s vicilin and 11s legumin (7s-V/11s-L) was then assessed.
2.6. Statistical Analysis
For each cropping system (OCS and CCS), the responses of the agronomic and quality parameters were subjected to a two-way (genotype, year, genotype x year) analysis of the variance (ANOVA) and means were separated by Tukey’s honestly significant difference (HSD, p ≤ 5%). Furthermore, the means of the OCS and the CCS were statistically compared using Student’s t-test, and percent change was reported according to this formula: 100 × (OCS − CCS)/CCS. The Pearson correlation analysis between agronomic and quality parameters and protein composition was also carried out. Statistical analysis was performed by JMP software (Version 8.0.2, SAS Institute Inc., 2009).
4. Discussion
The results from the field trials showed a marked influence of genetic variability and environment and suggested an effect of crop management on grain yield and its components. The highest productivity achieved by chickpea genotypes, under lower rainfall conditions, is in agreement with a previous study in Mediterranean environments where the authors observed that the highest seed yield was obtained with about 390 mm of rainfall and that wetter conditions led to a decrease in crop production [
20]. The authors suggested that excessive rainfall may led to a negative effect due to waterlogging on chickpea plants. Similar results were obtained in the same environment with different irrigation regimes: irrigation application greater than 170 mm decreased chickpea GY and water use efficiency as well due to ascochyta blight (AB) infection [
21]. Furthermore, in another study on chickpeas grown under Mediterranean conditions [
6], the authors stated that the lower production under wetter conditions might also be ascribable to higher biotic stress pressure. Under our experimental conditions, the higher rainfall was associated to a higher weed pressure that competed for nutrient availability and AB that limited the crop development. Insufficient crop soil nutrient availability and the effects of diseases and pests are generally associated to a significantly low grain yield under organic management [
22]. Indeed, conditions of optimal humidity and temperature during reproductive stages can be favorable for AB, with possible loss of production [
23]; this helps to explain the large gap between CCS and OCS that occurred in the wettest year. The organic farming condition suffered more from the wetter weather of the first year, which stimulated weed growth and, thus, limited nutrients uptake and the radiation interception of chickpeas.
A wide genetic variability was observed in terms of grain productivity within the chickpea genotypes. The best agronomic performances are generally obtained by the genotypes with the highest adaptability [
8]. In a previous study conducted under Mediterranean conditions, the cultivar Sultano showed a higher GY with respect to Pascià [
6]. Those differences might be also ascribable to genetic AB resistance under specific favorable conditions. Furthermore, under our experimental conditions, the cultivar Sultano showed an interesting suitability for organic farming, as previously suggested [
6], followed by Nero Senise. The use of suitable genetic resources may have a key role in promoting sustainable crop production, including pulses under low-input organic farming systems.
A reduced variability was observed in relation to PC between CCS and OCS [
22], which showed an effect of management only under better environmental conditions. The higher PC observed under organic farming in the first crop season was inversely related to GY, with a consequent N concentration effect in grains [
24]. Under conventional management, however, the highest production in the second crop year was consistent with the highest PC. This was possibly due to the generally better physiological response of the crop that, under less limiting conditions with respect to organic farming (weed competition), took advantage of the highest N amount, ordinarily applied before sowing in conventional management on chickpea [
6]. This practice is recommended within crop rotations with cereals, taking into account the reduced N fixation that generally occurs with chickpea compared to other pulses [
25]. Indeed, N uptake in chickpea is strongly influenced by N supply in soil, which, as a consequence, regulates final grain yield [
26].
Despite a moderate genetic effect on protein concentration, a large variability in terms of protein composition was observed in the current study. In recent years, the evidence of an existing genetic diversity in terms of seed protein composition was exploited in cultivated pulses, including chickpeas [
8,
17,
27,
28]. Most of the information on pulse protein composition was obtained by electrophoretic separation and is relative to genetic diversity [
8,
29,
30], while less data are available on the effect of environmental [
31] or agronomic factors [
32]. In our study, the interaction of genotypic factor under different crop managements (organic vs. conventional) showed a marked significant variability. The predominance of 7s vicilin and 11s legumin is in accordance with the literature on pulse storage proteins [
3,
27,
33]. Both proteins are classified on the basis of the sedimentation coefficient, and they are generally oligomeric proteins, trimers for 7s vicilin and hexamer for 11s legumin [
3]. A large variability exists in literature in terms of the prevalence of the two proteins. In a study conducted on pea genotypes, a higher proportion of vicilin than legumin was observed, in a range from 1.6 to 8.2 [
27]; furthermore, in a second experiment conducted on pea, a higher legumin prevalence over vicilin was found [
32]. The values observed in the current investigation (0.63–2.23) are in line with the ranges reported in the literature. In our study, vicilin and legumin were mainly responsible for changes in protein composition and were also found to be strongly influenced by environmental and agronomic factors. The existence of a significant variability in terms of the proportion of 7s and 11s globulins was already observed in pea [
32] in relation to both environment (crop season and crop site) and management (seed density). The authors observed a negative relationship between 7s-V/11s-L and protein content; this trend was in accordance with ours in the most productive crop year, and this ratio was generally negatively associated to grain yield. In addition, different soil mineral availability can also affect chickpea seed composition [
34].
Changes in chickpea protein composition may have relevance both for technological [
28] and health aspects [
35]. Besides the direct consumption of chickpea as food, there is also an increasing interest in the use of chickpea flour as a protein additive in cereal flour [
36] or as gluten-free flour [
37] and also for sustainable goals [
38]. Different physicochemical tests are adopted to estimate the technological performances of a food matrix. Among these, the water-holding capacity is the ability of a protein matrix to absorb and physically retain water against gravity by bound, hydrodynamic and capillary interactions [
39]; indeed, fiber may also contribute to increase WHC. The values observed in the current study are in the range comprised within the literature for pulses [
40], with the higher values observed in the black and small seeds being in accordance with previous findings [
10]. The genetic variability found may be a useful basis for industrial application, in particular for chickpea flour consumption and also in addition to cereal flours with different technological attitudes [
41]. The differences in SDS-PAGE profiling may help to explain the rheological properties of the flours in order to individuate the major protein fractions responsible for technological performance in pulses [
16]. The variation observed in water absorption capacity in chickpea cultivars is suggested to be due to differences in hydrophilic groups in protein concentrates [
29].
As for health aspects, four peptides (ALEPDHR, TETWNPNHPEL, FVPH and SAEHGSLH) obtained from hydrolysate chickpea legumin after digestion have recently been proposed for their antioxidant properties [
42]; in addition, the 50-kDa subunit of vicilin and the 20-kDa basic subunit of legumin were reported as putative chickpea allergens [
43]. The reduced convicilin (7s globulin) content is in accordance with [
27], which also found no correlation with the amount of vicilin and legumin in pea.
The reduced lectin variability was associated to lower values in the more productive conventional management. Legume lectins, with their rich hydrophobic amino acid regions that allow interactions with other molecules, are known for their antinutritional properties [
44], in particular their hemagglutinating capacity. However, chickpea lectin may depress starch digestion, leading to a lower glycemic index [
45]. An interesting genotypic variability was found in our study with lower content in the black-seed genotype Nero Senise, which showed high adaptability and good productivity in the investigated Mediterranean environment.
The 2s albumin, which consists of two subunits, generally accounts for ~10% of legume storage proteins, in accordance with the values observed in our study, but ~50% of total sulfur content, as cysteine amino acid [
7]. Although under our experimental conditions, it showed few changes, Nero Senise showed a higher content than other genotypes, suggesting a possible implication in terms of amino acid composition with more sulfur-rich ones.
The observed changes in protein composition suggest an important effect of crop management, in particular organic farming, associated to genetic differences in terms of crop and quality response. These changes seem related to agronomic traits and technological performances and can be further explored by a proteomic approach.