Changes in Some Nutritional and Mineral Components of Nerica Rice Varieties as Affected by Field Application with Mycorrhiza and Chemical Fertilizer in Northern Cameroon ()
1. Introduction
Rice (Oryza sp.) is the staple food source for half of the world population, making a major cereal crop [1] . It belongs to the family of graminaceae, the botanical genus Oryza, and comprises a total of 23 species of which only two are cultivated: Oryza sativa and Oryza glaberrima originated respectively from Asia and West Africa. Nerica, which means New Rice for Africa, is an interspecific hybrid resulting from crossing between the Asiatic rice (Oryza sativa) and the exotic African rice (Oryza glaberrima). These hybrids are known to exhibit better agronomic performances and high protein content compared to their parents [2] . These advantages could significantly contribute to alleviate the food insecurity and improve the nutrition of population of our different developing countries. Production of rice in sub-sahara African countries is constrained by abiotic and biotic factors, the availability of water and nutrients remaining the major limiting factors. Hence, Nerica varieties were introduced in a bit to show promising yield potentials in marginal soils compared to existing local varieties [3] . To sustainably achieve this yield potential, application of Arbuscular Mycorrhiza Fungi (AMF) is necessary. The most significant outcome of AMF, which is a symbiotic association between plant roots and a fungus [4] , has been reported as the improvement of nutrient uptake by the host plant [5] , and the modification of water status in water deficient plants [6] [7] .
The nutritional, ecological and economical focuses on rice are of great importance: cardio-vascular and infant diseases due to excess or deficiency in food diet in oligo-elements and macro-nutriments are widely spread in Asia and Africa, and particularly in non-irrigated rice growing areas; the deficiency in iron is common due to anemia that mostly affects pregnant women and children ingesting high quantity of this cereal. Any improvement of rice grain quality in macro-nutriments and oligo-elements content could then help reducing the severity of nutritional problems. In African countries, demographic explosion invites researchers to think of long terms solutions for a sustainable production strategy of competitive rice grain quality without affecting the environment. Although a more efficient solution could be the diversification of food diets or their improvement with green legumes and meat, their access is never evident to farmers with low income due to the high cost in the market. Moreover, intensive input of inorganic fertilizers degrades the environment, causing water pollution and soil contamination through phytotoxicity, ammonia volatilization and nitrate accumulation [8] . Biological agriculture technics seem to be appropriate and adapted as low cost and environmental friendly strategy to be mastered by farmers. One of these strategies which is the use of mycorrhizal biofertilizers has been reported to improve cowpea [9] , and rice [10] growth and yield.
In addition, the predominant component present in the endosperm or inner part of rice kernel is carbohydrate, and consists of 85% - 90% of starch, 2% pen- tose and 1% sugars [11] . Different rice varieties may have different unique texture after cooking, linked to their main constituent which is starch, and that governs the final texture of cooked rice. The starch fraction is made up of amylose and amylopectin that determines the cooking quality of rice [12] [13] . Thus, starch characteristics determine the amylose content and gelatinization temperature [14] [15] . Rice varieties with amylose content below 6% remain sticky following cooking [16] . According to the same author, some consumers would prefer non sticky rice varieties which have higher amylose content of between 25% - 30%. Apart from starch, protein is the second most abundant component in rice, and its quality is high compared to other protein sources. The average protein content is 7% in milled rice and 8% in brown rice [13] . Grain quality is the most important factor in rice production as it is directly related to market value, and thus, influences farmer incomes. However, to date, little is known about the changes in grain quality over time and how fertilizer application can influence grain quality. Some evidence indicates deterioration in grain quality in modern high yielding cultivars [17] . With the current trend of regular and high consumption rate of rice in the diet, there is a need to overlook the variability in nutrient concentations within different rice varieties.
From our basic knowledge, although few studies have recently focused on interactions between Nerica and mycorrhizal inoculation [18] [19] , none has yet compared this biofertilizer to chemical input, as far as nutritional quality and elemental mineral content of rice grains are concerned. Therefore, this study was investigated to assess the variations in nutritional and mineral compositions of Nerica grains harvested form field applied mycorrhiza and chemical fertilizer. It is expected that mycorrhiza-rice symbiosis would not only increase Nerica rice yield through stimulated nutrients uptake, but also would improve rice grains nutritional quality.
2. Material and Methods
2.1. Experimental Location
Field experiments were located at in Yagoua within the SEMRY plantation along the Logone river in agro-ecological zone I, and Wakwa-Ngaoundere in agro- ecological zone II, as previously described [20] .
2.2. Biological and Chemical Materials
Mycorrhizal fertilizer was produced at the University of Ngaoundere, and was a mixture of soil, root fragments and spores of the genus Glomus and Gigaspora (10 à 25 spores/1 g of soil). The chemical fertilizers-NPK (fertilizer®), with the formula 14:24:14 was purchased from a chemical fertilizer shop in Ngaoundere and Yagoua, the two main towns of the respective study sites. Nerica grains were provided by the Africa Rice Centre, and were a composite of five Nerica varieties namely: FKR56-N; FKR58-N; FKR60-N; FKR62-N and DIR-95. The main characteristics of rice seeds were previously described [20] .
2.3. Experimental Design and Treatments
The experiment was carried out in a split-splot (4 × 5) × 3 design, where seeds were harvested from fertilized plants or not (treatments), while the five Nerica varieties were the sub-treatments. The main treatments were seeds from: mycorrhiza applied plants (TM); chemical fertilizer applied plants (TE); mycorrhiza-chemical fertilizer applied plants (TEM); and the control (T0). Each treatment was replicated three times.
2.4. Assessment of Elemental Nutrients
Elemental seed nutrients such as N, P, Fe, Mg were determined after solubilization of ashes by concentrated Hydrochloric Acid [21] . Iron and phosphorus contents were evaluated through the colorimetric method described by Rodier [22] . Magnesium contents were titrimetrically assessed using the EDTA method [23] .
3. Assessment of Nutritional Components
3.1. Isolation of Starch
Starch was prepared using the alkaline deproteination method [24] , with some modification. Averagely 1.5 g of rice flour was suspended in 6 ml of 0.05 N NaOH at 4˚C for 1 h with shaking, spun at 250 g (Model CR412 centrifuge, Saint-Herblain, France) for 5 min. The supernatant and the top sticky protein layer were poured off. After three more deproteinations, flour was agitated overnight in 6 ml 0.05 N NaOH at 4˚C. Starch was suspended in deionized water, neutralized with HCl, washed three more times with deionized water, rinsed with methanol, and lyophilized. Starch lipid was removed with 85% (v/v) methanol using a Soxhlet apparatus for 16 h.
3.2. Determination Amylose (AC) and Amylopectin (AP) Contents
Initially 40 mg of pure potato amylose was weighed into a beaker. Then 1 ml of 95% ethanol and 9 ml of 1 N NaOH was added and the mixture was heated in a boiling water bath for 15 minutes. The solution was allowed to cool to room temperature before transferring into a 100 ml volumetric flask. The solution was topped up with distilled water. Aliquots of 1 ml, 2 ml, 3 ml, 4 ml and 5 ml of the aforementioned solution were transferred to 100 ml volumetric flasks covered with aluminium foils. Then series of standard solutions were prepared by adding 0.2 ml, 0.4 ml, 0.6 ml, 0.8 ml and 1 ml of 1 N Acetic acid solution respectively. Then, 2 ml of 0.2% Iodine solution was added to each of the flasks and shaken. All the prepared solutions were kept in a dark box for 20 minutes before absorbance measurement using UV-light spectrophotometer. Standard curve was drawn against the absorbance and amylose concentration. The blank solution was prepared by adding 5 ml of 0.09 N NaOH to 100 ml volumetric flask, and 1 ml of 1 N acetic acid-Iodine solution and kept in dark for 20 min. before measurement of absorbance at 620 nm. The same procedure was carried out for samples using 100 mg of rice flour instead of standard amylose. But 5 ml of starch solution was reacted with 1 ml of 1 N acetic and 2 ml of 0.2% iodine instead of preparing a series of solutions. Absorbance was also measured at 620 nm. The amylose content of sample was determined as described by Juliano [25] , Perez and Juliano [26] .
Amylopectin content was calculated using the following equation, that uses the average amylose content value in the calculation [27] .
Amylopectin (%) = 1 − Amylose%
3.3. Evaluation of Protein Content
Protein content was determined as described by Wireko-Manu and Amamoo [28] , following the standard method [29] . Hence, each air dried sample (2 g) was weighed into 500 ml long-necked kjeldahl flask and moistened with 10 ml distilled water. A full spatula of kjeldahl catalyst (mixture of 1 part selenium + 10 parts CUSO4+ 100 parts Na2SO4) was added followed by 20 ml concentrated H2SO4. The solution was digested until colourless fluid that was cooled down and decanted and made up to the mark with distilled water into a 100 ml volumetric flask. An aliquot of 10 ml of digested sample was transferred into 100 ml kjeldahl distillation flask and made up to the mark with distilled water. Twenty (20) ml of 40% sodium hydroxide was added to the content of the distillation flask. Distillate was collected over 10 ml of 4% boric acid and 3 drops of methyl red in a 200 ml conical flask. The presence of nitrogen gave a light blue colour. The collected distillate (about 100 ml) was titrated with 0.1 N HCL till the blue colour changed to grey and then suddenly flashed to pink. A blank determination was carried out without a sample. Crude protein was estimated by multiplying the value obtained for percentage nitrogen content by a factor of 6.25.
4. Statistical Analysis
Data collected were subjected to Analysis of variance (ANOVA) mixed model at 5% probability level using a Statgraphic Plus computer package version 5.0. Means were separated between treatments using the Least Significant Difference (LSD). All graphical illustrations were configured using Excel spread sheet. Correlations between parameters were assessed using the SPSS computer package.
5. Results and Discussions
5.1. Rice Seed Mineral Contents
Cu, Fe, Mn, Zn, Na, Ca, K, Mg, S, P, and B are important essential micronutrients in the human diet. Deficiency of these microelements can result to serious diseases [30] . The rate of fertilizer application and the native fertility of paddy fields have been reported to affect the mineral element levels of rice [31] . There was variation in mineral composition among rice varieties samples in both agro-ecological zones 1 (Yagoua) and 2 (Wakwa).
5.2. Phosphorus (P)
Phosphorus, the second most widely limiting nutrient in soil after nitrogen [32] , is a critical macronutrient for plant growth. In tropical agro-ecosystems soil, P deficiency is a major limitation to crop production [33] . In this study, inoculation of rice plantlets with mycorrhiza at sowing and subsequent application of chemical fertilizer-NPK resulted in accumulation of phosphorus in harvested seeds (Figure 1).
P content in rice ranked from 87.26 mg/100 g in the control T0 (variety FKR58-N) to 232.72 mg/100 g seed flower in treatment TEM (variety FKR62-N) at Wakwa, and from 85.50 mg/100 g in the control T0 (variety FKR58-N) to 254.57 mg/100 g seed flower in treatment TEM (variety FKR62-N) at Yagoua. These responses were significantly more pronounced in seeds from chemical applied or mycorrhizal inoculated plants than in seeds from control plants for all the sowing varieties investigated. The results varied from one cropping season to another within experimental site, and from one experimental site to another. However, for a cropping season within experimental site, the seed phosphorus concentration differed from one seed variety to another, with seeds from rice variety FKR62-N and FKR56-N significantly accumulating more P than other rice varieties after inoculation. As far as treatments are concerned, seeds harvested from TEM and TE treated plants accumulated more P than those from TM and control plants. These elevated concentrations are attributed to mycorrhiza, che- mical fertilizer-NPK (14-24-14), or their synergistic effects. Mycorrhiza has been reported to improve nutrient uptake in inoculated plants through increment of the exploration area around the plant rhizosphere, where the host plant can uptake nutrients [4] [5] . These nutrients are assimilated by the host plant and are found in different plants parts such as leaves, roots or seeds [34] . Rice P seed content obtained fall within the range of 106.07 - 259.66 mg/100 g repoorted by Odenigbo et al. [35] in rice varieties from Nigeria and Cameroon, and between 100.32 - 198.97 mg/100 g in milled rice samples from Ghana [36] . However, P content values were higher than 73.0 ± 8.04 mg/100 g reported in a Nigerian milled rice [37] .
5.3. Iron (Fe)
The iron concentration varied from one rice variety to another, as well as from one treatment to another (Figure 2). The Fe content in rice was comprised between 1.16 - 3.94 mg/100 g seed flour, respectively in the control (variety FKR56-N) and TEM treatment (FKR62-N) at Wakwa. At Yagoua, the corresponding
Figure 1. Changes in rice seed phosphorus contents as affected by treatments at Yagoua and Wakwa.
Figure 2. Changes in rice seed iron contents as affected by treatments at Yagoua and Wakwa.
values were 2.09 - 3.60 mg/100 g seed flour, respectively in the control and TEM treatment of the rice variety FKR62-N). Rice varieties FKR58-N, FKR60-N and FKR62-N had the highest iron concentration in their seeds. Iron concentration in seeds was increased by treatments TE, TEM and TM as compared to that of the control T0 at both Wakwa and Yagoua experimental sites. When plants were applied with the chemical fertilizer-NPK (treatment TE), the seed Fe concentration did not differ significantly from one rice variety to another, either at Wakwa or Yagoua during each of the cropping season. Fe rice content of 46.3 ± 2.11 mg/ 100 g was detected in a Nigerian milled rice [37] , which is more than 10 folds higher than values obtained from this study. The relative low Fe content in Nerica suggests that these varieties may be resistant to Fe accumulation in seeds.
5.4. Nitrogen (N)
The most important nutrient involved in mycorrhizal symbiosis was reported as P, but seems to involve also other nutrients. P nutrition of soils is critical for the efficient use of inorganic N fertilizer. While N is the most limiting nutrient generally in soil, it has been shown that deficiency of soil P reduces the efficiency of N use by crops [38] . Our investigations reveal the contribution of treatments TE, TEM, TM to a significant improvement of N accumulation in rice (Figure 3). This was observed during cropping seasons 1 and 2 and in each of the experimental site. Apart from the rice variety FKR56-N for which treatment TE improved N accumulation in seed (3.66 mg/g seed at Wakwa 1, 3.99 mg/100 g seed at Yagoua 1), treatments TEM and TM significantly improved the N seed content in all the studied varieties than other treatments. The highest seed N contents were 4.02 and 4.06 mg/100 g seed flour, respectively at Wakwa 2 and Yagoua 2 for the seed variety FKR56-N applied with both chemical fertilizer-NPK and mycorrhiza (treatment TEM). The seed N content in treatment control (T0) was always significantly lower than that of other treatments in both experimental sites (Wakwa, Yagoua).
An increase in grain nitrogen content following increased in nitrogen fertilizer application at particular levels was recently reported by Yoseftabar et al. [39] . The maximum nitrogen contents in rice grain (2.50 mg/100 g) was obtained at 100 and 125 kg N ha−1 [40] . In this study, we used mycorrhiza, which does not only improve P uptake, but other ntrients including nitrogen [5] . Similarly, other studies also reported enhanced Fe, Mn, Cu, and Zn accumulation in rice and wheat grains, as the result of N application [41] .
Figure 3. Changes in rice seed nitrogen contents as affected by treatments at Yagoua and Wakwa.
5.5. Magnesium (Mg)
Mg seed content differred from one rice variety to another, and withing the rice variety from one treatment to another at both Wakwa and Yagoua experimental fields (Figure 4). The highest Mg seed content at Wakwa was obtained in the rice variety FKR 58-N (188.94 mg/100 g seed flour at Wakwa 1, 128.00 mg/100 g seed flour at Wakwa 2), when plants were submitted to treatment TEM. In all the studied varieties, the Mg seed content was always significantly lower in the control treatment (T0) than in other treatments, the lowest content (103.15 mg/100 g seed flour) accounting for the rice variety (FKR58-N). At Yagoua, treatment TEM also improved the Mg seed content more than in other treatments, and in all the studied varieties, with the highest content observed in rice variety FKR58- N (181.79 mg/100 g seed flour) at Yagoua 1. During the second cropping season at Yagoua (Yagoua 2), Mg seed content was instead improved by treatment TM (mycorrhiza alone) in all the rice varieties, except for variety FKR58-N, for which treatment chemical fertilizer-NPK (TE) was the most efficient. However, compared to results obtained at Wakwa, Mg seed content did not significantly differ between treatments applied on varieties FKR56-N, FKR60-N and DIR-95.
The Mg seed content at Wakwa was not higher than 188 mg/100 g or 181 mg/ 100 g seed flour at Yagoua. These values fall within the range of between 112.41 - 324.83 mg/100 g reported by Odenigbo et al. [35] , which is higher than 67.0 ± 7.12 mg/100 g revealed in a Nigerian milled rice [37] .
5.6. Rice Nutritional Seed Quality
Based on their nutritional quality attributes, consumers and farmers should be better informed on the choice of rice varieties, although the nutritional values of
Figure 4. Changes in rice seed magnesium contents as affected by treatments at Yagoua and Wakwa.
rice vary with different varieties, soil fertility, fertilizer application and other environmental conditions.
5.7. Starch
Starch is the major dietary source of carbohydrates and is the most abundant storage polysaccharide in plants. Total starch in seed ranged from 68.25% in the control of variety FKR62-N, to 76.36% and 76.5%, respectively in treatment TEM for variety FKR58-N at Wakwa 1, and variety FKR62-N at Wakwa 2 (Table 1). During the first and second cropping seasons at Wakwa or Yagoua, the application of rice plants with mycorrhiza (TM) or chemical fertilizer-NPK (TE) significantly improved the starch content in seed (p < 0.02), although this was not true for the local variety DIR-95 at Wakwa 1 (p = 0.45). At Yagoua, the lowest starch content in seed was found in treatment T0 of the rice variety FKR60-N (63.84%), whereas the highest accounted for treatment TEM of the rice variety FKR62-N (77.38%) at Yagoua 1 (Table 2). Starch values obtained in the present study were lower than those in the range 81.23% - 92.73% reported by Omar et al. [42] , although still greater than starch content of between 68.73% - 70.24% from different rice cultivars [43] . These variations were attributed to varietal difference [44] .
5.8. Amylopectin
Amylopectin content in rice was determined from that of amylose [27] . Thus, the higher the amylose content, the lower that of amylopectin. For a given treatment, the seed amylopectin content significantly differed from one rice variety to another, and within a variety from one treatment to another. Treatment TEM best increased the amylopectin seed content more than other treatments. The seed amylopectin content of the control was the lowest of all the treatments either at Wakwa (Table 1), or Yagoua (Table 2) experimental sites. In both sites, the seed amylopectin content ranged between 43.64% and 54.18%, corresponding to amylose content from between 45.82% and 56.36%. Rice has been classified into several groups based on its amylose content, and was categorized as waxy (1% - 2%), very low amylose (2% - 12%), low amylose (12% - 20%), intermediate amylose (20% - 24%), and high amylose (>24%) contents [45] [46] . According to this classification, all the rice varieties used in the present study fall under high amylose rice, and therefore, their textures in cooked form should be less sticky and harder. Previous studies on amylose content have suggested that high amylose rice varieties yield a harder and less sticky rice upon cooking, and have stipulated that hardness is positively correlated with the amylose content of rice [47] . Similarly, the amylose content in Sri Lankans rice was revealed to be non sticky, with higher content of between 25% - 30% [48] [49] . Amyolse content in starch maize was reported as 74.44%, corresponding to an amylopectin content of 25.60% [50] , thus lower than that of starch rice obtained from this study. The considerable variation in amylose and amylopectin contents in rice was reported to be attributed to elevated temperature that significantly decreased
Table 1. Variation in nutritional components in rice varieties as affected by treatments at Wakwa.
For each cropping season and for each nutritional parameter, values in a column affected by the same letter as a lower case are not significantly different at the level of probability indicated. For treatment of a particular nutritional parameter, values in a row affected by the same letter as a upper case are not significantly different at the level of probability indicated.
Table 2. Variation in nutritional components in rice varieties as affected by treatments at Yagoua.
For each cropping season and for each nutritional parameter, values in a column affected by the same letter as a lower case are not significantly different at the level of probability indicated. For treatment of a particular nutritional parameter, values in a row affected by the same letter as a upper case are not significantly different at the level of probability indicated.
the amylose content, thus increasing the amylopectin content [47] [51] . Surprisingly, although temperature at Yagoua experimental site (27˚C - 34˚C) was higher than that of Wakwa (18˚C - 25˚C), it did not affect the amylose and amylopectin contents in studied rice varieties. The more amylose there is, the slower is the digestion of rice, and the lower is the glycemic index [52] . This finding suggests that all our studied varieties which fall within higher amylose content category may positively have effect on blood sugar.
5.9. Proteins
Protein content in seeds was significantly lower in the control than in any other treatment applied on plants at Wakwa or Yagoua experimental sites. The highest seed protein content was obtained when plants were applied with chemical fertilizer-NPK, mycorrhiza or both, treatment TEM being the best. The rice variety FKR56-N was found to accumulate averagely more seed protein (24.35%) at Wakwa 1/Yagoua 1, against 17.66% at Wakwa 2/Yagoua 2 (Table 1 and Table 2). This was higher than the range obtained by Edeogu et al. [53] , who analyzed the proximate composition of rice in Ebonyi Sate. According to the same authors, this was attributed to prolonged parboiling which lowers the protein content of rice and some other environmental and edaphic factors. Chemical fertilizers provide plant with nutrients, particularly N, P, K, while mycorrhiza improve nutrient uptake of these nutrients. Since N and P are involved in protein synthesis, it is obvious to find plant applied with chemical fertilizers or mycorrhiza expressing more proteins than control plants. After carbohydrate, protein is the second most abundant constituent of rice [54] . Rice protein is of very high quality as compared to other food crops. Some of the rice varieties had varying levels of protein which could be said to be 2.5 folds high when compared to the reported values of Eggum et al. [55] . This might be as a result of genotype and environmental differences. Besides genotypic variation, edaphic factors were suggested to lower the protein content of rice [2] . This variation was also reported to be due to genetic factors or the mineral content of the soil [56] . Varietal difference in protein was attributed to several factors including environmental stresses such as salinity and alkalinity, temperatures, diseases, total nitrogen in the soil and other minerals such as molybdenum and total chlorine which tend to increase the grain protein content [44] . The results obtained from this study are very high compared to those of earlier studies reported by Pederson and Eggum [57] . Since all samples in the present study were submitted to the same degree of milling, the observation of varied proximate composition is attributed to varietal differences and different planting locations. Numerous factors influencing nutritive value of crops at different locations have been reported to include soil type, fertilizer application, climate, harvest time, handling and storage of crop before analysis [58] [59] .
6. Conclusion
At the end of this study varied levels of nutritional and mineral composition among a local rice and Nerica varieties were evidenced. The local DIR-95 variety had values close to those of Nerica varieties in all the parameters assessed. Protein contents in investigated varieties were high and ranged from 17.66% - 24.35%. The local rice (DIR-95) and Nerica varieties of the present study failed within high amylose rice. Seeds from mycorrhiza and chemical fertilizer applied plants had mineral and nutritional values superior to those of seeds from other treatments. The results of this study could be exploited by rice consumers in their choice regarding the mineral and nutritional compositions, with more attention on Nerica FKR62-N variety. Hence, it could be recommended along with local DIR-95 variety under mycorrhiza inoculation in the field.
Acknowledgements
The authors are grateful to Institute for Agricultural Research and Development (IRAD, Yaounde) and the AfricaRice for their financial support.