American Journal of Plant Sciences
Vol.08 No.10(2017), Article ID:79030,10 pages
10.4236/ajps.2017.810161

A Rapid Method for Measuring Seed Protein Content in Cowpea (Vigna unguiculata (L.) Walp)

Yuejin Weng1, Ainong Shi1*, Waltram Second Ravelombola1, Wei Yang1, Jun Qin1, Dennis Motes2, David Octor Moseley3, Pengyin Chen4

1Department of Horticulture, University of Arkansas, Fayetteville, AR, USA

2Vegetable Research Center, University of Arkansas, Alma, AR, USA

3Department of Crop, Soil and Environment, University of Arkansas, Fayetteville, AR, USA

4Fisher Delta Research Center, College of Agriculture, Food and Natural Resources, University of Missouri, Portageville, MO, USA

Copyright © 2017 by authors and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY 4.0).

http://creativecommons.org/licenses/by/4.0/

Received: August 14, 2017; Accepted: September 10, 2017; Published: September 13, 2017

ABSTRACT

Cowpea (Vigna unguiculata (L.) Walp), a legume crop that is grown in the worldwide, provides beneficial proteins for human consumption and animal feeding. In comparison, Rapid N analyzer as traditional method, has been widely used to measure protein content through the percentage of total nitrogen in the seed’s grounded powder. Near-Infrared Reflectance (NIR) has commonly been used to measure protein content in soybean seeds using whole grain without the need of seed grinding, which makes it possible to obtain fast results at a lower cost-per-analysis than the traditional combustion method. The specific objective of this study is to test a rapid method for measuring cowpea seed protein content by the NIR analyzer comparing to the traditional rapid N analyzer. A total of 240 cowpea genotypes were used in this study, including six seed coat colors, black, blackeye, browneye, cream, pinkeye, and red with 40 cowpea genotypes. The results showed that a linear relationship exists between the NIR analyzer and the Rapid N analyzer in the six different color groups. The correlation efficiency (r) between the seed protein contents from NIR and Rapid N was higher for pinkeye seed (r = 0.867), blackeye (0.771), cream (0.729), browneye (0.700), and red (0.623), respectively, but lower for black seeds, indicating that the NIR analyzer can be used to measure protein content for cowpea seeds with the five types of seed coat except black. Overview, the cowpea seed protein content measured from the NIR analyzer showed a little higher seed protein content. A series of regression models with different seed coat color have been built to adjust to protein content of colorful cowpea seeds from the NIR analyzer. But, it is not recommended to use for black color seeds due to a very low correlation efficiency (r) value with 0.184.

Keywords:

Cowpea, Seed Protein Content, Protein Measurement Method, Rapid N Analyzer, Near-Infrared Reflectance (NIR), Vigna unguiculata

1. Introduction

Cowpea (Vigna unguiculata (L.) Walp), a legume crop that is grown worldwide, provides beneficial proteins for human consumption, animal feeding, and the environment [1] - [6] . The largest acreage to grow cowpea is in Africa, with Nigeria and Niger predominating. Besides Africa, Brazil, West Indies, India, United States, Burma, Sri Lanka, Yugoslavia, and Australia also have large cowpea production [3] [5] . Dry seed production is estimated at 1.24 million tons annually in the world. Cowpea is grown as a food crop, but also as a canned vegetable product (both for the greens and the green peas), a cover crop, and as fodder. Cowpea primarily provides protein, soluble sugar, amino acids, vitamins, and minerals [1] [7] [8] .

The greatest value of cowpea seed is its rich protein content as traditional food to customers, in particular, it can provide sources of protein to improve the nutritional status of resource-poor subsistence family in developed countries in the world [9] [10] . Carnovale et al. [1] compared protein contents from cowpea commercial cultivars and from International Institute of Tropical Agriculture (IITA) improved lines and found that both sources had similar seed protein content (22.4% for commercial and 21.9% for IITA). Itatat et al. [11] reported that the seed protein content ranged from 20.57% to 24.95% among eleven cowpea genotypes. However, Afiukwa et al. [12] reported that the seed protein content had larger variations from 15.06% to 38.5%, with a mean of 25.99% in cowpea dry seeds.

There are several ways to measure protein concentration in agricultural products, and each of them has its own advantages and disadvantages [13] . The Kjeldahl method is a classical method for the quantitative determination of organic nitrogen in chemical substances like ammonia. It was developed in 1883 by a brewer Johann Kjeldahl [14] . A sample is digested with a strong acid (sulfuric acid) so that it releases nitrogen which can be determined by a suitable titration technique. The amount of protein present is then calculated from the nitrogen concentration of the sample. Because the Kjeldahl method does not measure the protein content directly, a conversion factor (F) is needed to convert the measured nitrogen concentration to a protein concentration. A conversion factor of 6.25 (equivalent to 0.16 g nitrogen per gram of protein) is used for many applications, however, this is only an average value, and each protein has a different conversion factor depending on its amino-acid composition. A number of improvements have been made to speed up the process and to obtain more accurate measurements. New techniques for protein measurement are becoming more popular than the chemical Kjeldahl method due to its complex three steps: digestion, neutralization, and titration. Absorbent UV light at 280 nm is other different method for protein measurement. Bradford colorimetric assay based on the interaction between Coomassie brilliant blue and the arginine and aromatic residues. Rapid N, a nitrogen/protein analyzer which presents the fast, safe, and environmentally friendly alternative to the classical method, has been widely used to measure protein content through the percentage of total nitrogen in the seeds’ grounded powder. With the high temperature and pure oxygen condition, nitrogen is liberated by combustion. The nitrogen is then isolated from other combustion products. A thermal conductivity detector measures the nitrogen content in the sample. Protein content is determined by the combustion method and a conversion factor of 6.25 was used to convert total nitrogen to protein.

Near-Infrared Reflectance (NIR), a spectroscopic method that sets new standards in protein analysis according to the near-infrared region of the electromagnetic spectrum (from about 700 - 2500 nm), has commonly been used to measure protein content in whole grain, such as soybean seeds, without the demand of grinding. It is possible to achieve fast, no-damage, and low cost-per- analysis results compared to the traditional method of combustion for total nitrogen when applied to determine protein content [15] . The DA 7250 NIR analyzer is the third generation diode array NIR instrument from Perten Company, Sweden, designed specifically for analysis in agricultural industries. Okonya and Maass [3] (2014) successfully used Near Infrared Spectrometry to determine the crude protein content of leaves from six cowpea genotypes, and found that the protein content in leaves in these genotypes averaged 30%.

In order to test for an accurate, reliable, rapid, non-destructive, and inexpensive method to measure protein content in cowpea, the specific objectives of this study were to evaluate the NIR methods of measuring cowpea seed protein content and to determine the possible relationship with classical protein measurement methods.

2. Materials and Method

2.1. Cowpea Seed Materials and Measuring

A total of 240 cowpea genotypes including 214 USDA GRIN cowpea germplasm accessions and 26 Arkansas cowpea breeding lines were used in this study, including six seed coat colors, black, blackeye, browneye, cream, pinkeye and red with 40 cowpea genotypes each. Experiment was conducted in two locations at University of Arkansas experiment station in Fayetteville (FY) and Alma, Arkansas, USA in 2016. The randomized complete block design (RCBD) was used in each location with three replicates. Each plot consisted of planted in a single 15-feet row length and 3-feet width, where there were 16 to 20 plants grown with 6-inch distance between two plants. The plots were maintained without any pesticides or herbicides during the growing season. Cowpea seeds were harvested by plot individually. After cleaning and drying for a few of weeks, 100 grams of whole grain was collected and prepared to measure protein content using INR DA7250. After measuring for protein content by NIR DA7250, 5 g each sample was ground by coffer grinding (Hamilton Beach) for 1 minute. 0.11 - 0.15 g of ground flours were passed through sieve 25# (bore diameter 850 µm) and prepared to protein content measure by Rapid N method.

Cowpea has a rich diversity of seed coat color, including black, brown, blue, cream, green, grey, mix (two or more colors), and purple, red, tan, and yellow color. In this study, six most popular cowpea seed color types in market: black, blackeye, browneye, cream, pinkeye and red color were used with 40 accessions each (Figure 1). Black color: Seeds dry down to an intense black color and have no noticeable “eye”. An example of black color is the released cultivar “Ebony”; Blackeye: The seeds come out of the pod clean and free, the white hilum is surrounded by black, which shows excellent market type; Browneye: The white hilum is surrounded by brown or dark brown color; Pinkeye: These are the more popular color of cowpea seed for consumption in markets, their white hilum is surrounded by pink color or light-red; Cream: Seeds of these types are generally cream colored and have no noticeable “eye”, it looks like soybean seed, but smaller size; Red color: Seeds of these types have a red colored coat and have no noticeable “eye”. The advanced breeding line “07-303” serves as an example of red color. Therefore, an objective of this study is to investigate whether cowpea seed coat color affects the measurement of protein content by NIR.

In this experiment, two soybean cultivars, “Osage” and “Ozark” were used as controls. NIR analyzer DA7250 has been used in soybean for measuring seed protein content and has been a good method regarding specificity and steadiness to measure whole grain protein content. Both “Osage” and “Ozark” showed a protein content of 42.82% - 43.54% and 39.41% - 40.56% in four time measurements, respectively. Repeated test showed that NIR analyzer method had the specificity and steadiness for protein content measurement of grain seeds.

2.2. Equipment of Cowpea Seed Protein Content Measurement

For NIR method, total protein content of the cowpea seeds was measured by the third generation diode array NIR instrument DA 7250 NIR analyzer, produced in Perten Company, Sweden. In contrast, same sample with powder was measured by analyzing the percentage of nitrogen by combustion using Rapid N III instrument, which is a product from the Elementar Company, a world’s leading

Figure 1. Cowpea seed coat color pattern: (a) Black seed; (b) Blackeye seed; (c) Browneye seed; (d) Cream seed; (e) Pinkeye seed; and (f) Red seed.

manufacturer of analytical instrumentation in Germany. The equipments for both methods were provided at the laboratories of Department of Crop, Soil and Environment, University of Arkansas, USA.

2.3. Data Collection and Analysis

Analysis of cowpea seed protein data was performed by analysis of variance (ANOVA) using the general linear models procedure of JMP Genomics 7. The relationship between the Rapid N III and NIR method was evaluated by the correlation coefficient (r).

Calculations of the correlation coefficient (r) are usually used to compare the results of two methods of measurement of the same substance [16] . The result is usually expressed as a regression line Y = aX + b, a formula in which “a” is the slope of the line called regression coefficient, and “b” is the intercept on the ordinate. Often, “r” the correlation coefficient is calculated. If “r” and “a” are close to unity and “b” close to zero, the two methods are said to agree with each other. The value of “r”, ranging from 0 to 1, is usually a matter of judgment.

3. Results and Discussion

In this study, a total of 240 cowpea genotypes including 214 cowpea germplasm accessions and 26 breeding lines were measured their seed protein contents by the NIR and Rapid N method (Table 1 and Figure 2). Overview, the analytical results showed significant variability for all the attributes and the values ranged

Table 1. Cowpea seed protein contents in six seed coat colors by two measurement methods.

Figure 2. Distributions of seed protein (%) of six seed coat colors: black seed, blackeye seed, browneye seed, cream seed, pinkeye seed, and red seed measured by two methods with NIR DA 7250 [Protein (%) by NIR] and by Rapid N III [Protein (%) by Elementar] among 40 cowpea genotypes, respectively.

from 21.03% to 29.69% and averaged 25.53% for protein by Rapid N III and ranged from 28.76% to 37.75% with an average of 34.03% by NIR (Table 1), indicating the cowpea seed protein content had large variation among 240 cowpea genotypes regardless of the analytical methods. The wide diversity of cowpea seed color was categorized into six groups with black, blackeye, browneye, cream, pinkeye, and red color in this study. The mean, standard deviation (Std Dev), maximum, minimum, range, variance, standard error (Std Err), and coefficient of variation (CV)among the six different color groups were estimated (Table 1). Most of distributions of seed protein (%) of six seed coat colors measured by two methods with NIR DA 7250 [Protein (%) by NIR] and by Rapid N III [Protein (%) by Elementar] among 40 cowpea genotypes showed a near normal with a large range great than 6% (Figure 2, Table 1), indicating the 40 samples in each seed color was an random sample with a large range and a big variance.

It is observed that the NIR method gave higher seed protein content than that from the Rapid N method in each of the six different color groups (Table 1, Figure 2 and Figure 3). Because it has more sensitive to different wavelengths from the range of colors of the cowpea seed, the NIR method gives higher seed protein content which is higher than real protein content in cowpea seeds, which is caused by the NIR analyzer. Although protein content measured by NIR DA 7250 had higher content than those by Rapid N III, the trend of seed protein

Figure 3. Cowpea seed protein content (%) by NIR DA 7250 and by rapid N III.

content in each of the six seed color showed same among the 40 samples (Figure 3), indicating the value of seed protein content measured by NIR can be adjusted by Rapid N with a regression model.

A regression model between the two methods for each of the six seed colors was postulated from this research. Although protein content measured by NIR DA 7250 expressed higher than that by Rapid N III, the correlation between the two methods was strong with an high correlation coefficient (r) value of 0.690 combined all genotypes of the six seed colors. Different r values among the six color groups were observed (Table 2). The r values of pinkeye, blackeye, cream, and browneye color cowpea were very high, measured at 0.867, 0.771, 0.729 and 0.700, respectively. The strong correlation between the two methods for the pinkeye, blackeye, cream, and browneye color cowpea provides us to adjust a protein content value from NIR analyzer to a closer real protein value from Rapid N method through a linear regression model. But black seeded cowpea had a very low r value with 0.184, indicating that the NIR method is not suitable for cowpea seeds with black or dark color coat. As the red seeds, a mediate r value with 0.623 was estimated (Table 2, Figure 4), indicating we may use the NIR method to measure the protein content in red cowpea seeds.

In this study, a linear regression Y = aX + b was postulated for each color (Table 2, Figure 4), in which “a” is the slope of the line and “b” is the intercept on the ordinate. If “b” is close to 1 and “a” close to zero, the two methods provide similar results. Because there were different r values between the two methods for each seed color, we developed separately linear regression model for each seed color and a total of six models were created for the six texted seed colors (Table 2, Figure 4). From Figure 2, five colors except black seeds fit a linear relationship from the distributions (Figure 4). From Table 2, we can see the “b” values are greater than 0.75 for blackeye, cream, pinkeye and red, close to 0.7 for browneye but less than 0.24 for black seed, indicating we can use the linear regression model to transfer each protein content value by NIR (X) to protein content value (Y) for five seed colors except black seeds. Therefore, the protein content in cowpea seeds can be directly measured by NIR analyzer as a fast measuring method.

In addition to good measurement data, the two methods have their own characteristics. Both near infrared Reflectance and Rapid N approaches were

Table 2. The correlation coefficient (r) and regression model between the two measurement methods among six seed coat colors.

Figure 4. The correlation coefficient (r) and regression model between the two measuring methods among six seed coat colors.

comparable in accuracy and reproducibility for measuring cowpea seed protein contents. Rapid N takes analytical technology to protein concentration measurement through nitrogen/protein analyzer according to the principle of catalytic tube combustion in an oxygenated CO2 atmosphere and high temperatures. It represents the fast, safe and environmentally friendly alternative to the classical Kjeldahl method. However, comparing with NIR, it looks more time to grand the seeds to powder and it costs (Table 3). NIR analyzer is an easier, faster, more economic, and non-damaging method to measure protein content in cowpea seeds. Therefore NIR analyzer method has been recommended to be directly used in measuring protein content in cowpea seeds with five seed colors of blackeye, browneye, pinkeye, cream and red seeds and through a linear regression model each color, the protein content value from NIR analyzer can be

Table 3. The comparison of two methods for seed protein content measurement.

adjusted to a correct value. However, the dark color cowpea seeds (black) are not suitable for seeds protein content measurement by NIR.

4. Conclusion

From this study, the protein content in cowpea seeds had a big variation from both methods among the tested 40 cowpea genotypes in each of the six seed color groups (Table 1, Figure 1 and Figure 2), but the NIR analyzer gave a greater value than the Rapid N III (Table 1 and Figure 3). However, a strong correlation was observed between the two methods with a high correlation coefficient among five seed colors of blackeye, browneye, pinkeye, cream and red except black seeds. The correlation efficiencies (r) between the two methods are 0.867, 0.771, 0.729, 0.700, and 0.623 for pinkeye, blackeye, cream, browneye, and red, respectively, indicating that NIR analyzer can be used to measure protein content for cowpea seeds with the five types of seed coat, excepting black color seeds (r = 0.184) (Table 2). The linear regression model was built to adjust to seed protein content from cowpea seeds for each of five seed color groups, respectively when NIR analyzer DA 7250 are applied (Table 2, Figure 4) in order to obtain the accurate seed protein content in different color type, thus provides a reliable and fast method to measure seed protein content in cowpea seeds using NIR analyzer. In additions, the NIR analyzer should be a better method to measure the protein content as whole grain in cowpea seeds without destruction and also it is a low-cost method and easy to operate in lab (Table 3). Therefore, it has great promise to be adopted as a rapid performed method to measure seed protein content for cowpea breeding program to improve protein contention.

Cite this paper

Weng, Y.J., Shi, A., Ravelombola, W.S., Yang, W., Qin, J., Motes, D., Moseley, D.O. and Chen, P.Y. (2017) A Rapid Method for Measuring Seed Protein Content in Cowpea (Vigna unguiculata (L.) Walp). American Journal of Plant Sciences, 8, 2387-2396. https://doi.org/10.4236/ajps.2017.810161

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