SQU Journal for Science, 2016, 21(1), 1-6 

© 2016 Sultan Qaboos University  

 
1 

 

  

Detection of Unlabeled Genetically Modified 
Soybean in the Omani Market 

Nabila Al-Sadqi
1
* and Aliya S. Alansari

2 

1*
Department of Academic Affairs, Directorate General of Technological Education, Ministry of 

Manpower. 
2
Department of Biology, College of Science, Sultan Qaboos University, P.O.Box: 36, 

PC 123, Al-Khod, Muscat, Sultanate of Oman. *Email: Nabila.AL-Sadqi@manpower.gov.om. 

ABSTRACT: This study aimed to screen for products containing Genetically Modified (GM) food in the Omani 

market using detection methods for the presence of Roundup Ready Soybean, Bt176 and MON810 maize in food 

products and to quantify it in positive samples using real time Polymerase Chain Reaction (PCR). A total of 100 food 

samples were collected randomly from markets in Oman. Out of 59 samples, 8  (13.5%) were successfully amplified 

with the maize plant specific PCR. GM screening showed negative for all samples, which indicated low or no GM 

maize in the samples tested. Out of 57 soy containing samples, 40 (70%) were successfully amplified by the soybean 

plant specific PCR. Six samples out of the 40 (15%) were found positive for GM using P35S-cf3/P35S-cr4 and HA-

nos118-f/HA-nos118-r, primer pairs and using GMO5/GMO9 and GMO7/GMO8 primer pairs for specific detection 

of Roundup Ready Soybean. Real time PCR (TaqMan™ system) was carried out for the positive Roundup Ready 

Soybean samples and results showed that 2 out of the positive GM soy samples contained more than 5%; a Soy 

Formula for Infants (imported) sample contained 21% GM soybean and raw soybean seeds (imported in bulk amounts 

and packed in Oman)  contained 88% GM soybean. The results demonstrate for the first time the presence of GM-soy 

in food products in the Omani market, reinforcing the need for the use of qualitative and quantitative methods for GM 

detection in food products. 

 

Keywords: Genetically modified food; GMO detection; PCR; Soybean.     

 الكشف عن الصويا المعذلة جينيا والغير معرفة  في السوق العماني

 ةعلياء األنصاريية والصادق ةبيلن

 
طرق جزٌئٌه الهدف من هذه الدراسة هو الكشف عن المواد المعدلة جٌنٌا فً المنتجات الغذائٌة المتواجدة فً األسواق العمانٌة, وذلك بإتباع : الملخص

( ونوعٌن من الذرة Soybean Roundup  Readyمعتمدة ودقٌقة للكشف عن تواجد ثالثة أنواع منها : نوع من حبوب الصوٌا المعدلة جٌنٌا  )
(. وباإلضافة إلى ذلك فقد تم تقدٌر نسبه الصوٌا المعدلة جٌنٌا فً العٌنات  الموجبة وذلك باستخدام تقنٌة MON810, Bt176الصفراء المعدلة جٌنٌا )

Real time PCR .  جمعت مئة عٌنة عشوائٌا من األسواق المحلٌة فً السلطنة. بواسطه تفاعل البلمرة المتسلسل و كانت نسبه  نجاح الكشف عن
     بلغث النسبة   (  وبالنسبة إلى العٌنات التً تحتوي علً الصوٌا95من  8) %13.5غذائٌة التً تحتوي علً  الذرة وجود الذرة  فً عٌنات المواد ال

(. لم ٌتم الكشف عن أي محتوي معدل وراثٌا بالنسبة  لعٌنات المواد الغذائٌة التً تحتوي على  الذرة, بٌنما أظهرت النتائج وجود 95من  04)70%
و الزوج  HA-nos118-f/HA-nos118-r و  P35S- cf3/P35S-cr4 ستخدام الزوج التمهٌدي بأ( 04من  6% )59بنسبه صوٌا معدلة جٌنٌا 

من الصوٌا المعدلة جٌنٌا. و قدرت نسبه    Roundup Ready Soybeanنوع للكشف عن  GMO5/GMO9 and GMO7/GMO8التمهٌدي 
% من 9. ووجد أن اثنٌن من هذه العٌنات تحتوٌان على نسبة أكبر من Real time PCRمحتوى الصوٌا المعدلة فً العٌنات الموجبة  بواسطة 

% و األخرى لحبوب صوٌا مستوردة بكمٌات كبٌره ومعبأة 65الصوٌا المعدلة جٌنٌا, أحداها لمسحوق حلٌب مستورد لألطفال وقدرت النسبة  فٌه ب 
وبشدة الحاجة إلى استخدام طرق الكشف عن المنتجات  المعدلة جٌنٌا ومشتقاتها نوعٌا %. وهذه النتائج تعزز 88فً السلطنة وقدرت النسبة  فٌها ب 

 وكمٌا لمراقبه المواد المعدلة جٌنٌا  المستوردة والمتوافرة فً األسواق دون بٌانات.
 

 .الكشف عن المواد المعدلة جينيا ،المنتجات الغذائية ،المواد المعدلة جينيا: الكلمات المفتاحية

1. Introduction 

echnological breakthroughs in plant genetic engineering have enabled scientists to directly introduce novel 

genes into a variety of economically important crops, such as soybean, corn, cotton, etc. [1]. Genetically T 



NABILA AL-SADQI AND ALIYA ALANSARI 

 

 
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modified organisms (GMO) are produced to provide higher yield and nutritional and economic benefits to 

consumers, such as longer shelf-life, enhanced flavour, reduced allergenicity and enhanced health or wellness 

attributes. The new generation of GM foods with enhanced quality attributes or nutritional benefits elicits much 

greater public acceptance than previous products [2]. 

There are certain benefits of GM food; a study on Bt-Corn found that it has significantly reduced levels of 

fumonisin (which is amycotoxin derived from Fusarium) when produced in a region where the European corn borer 

(ECB) is an important pest [3]. Women who consume a diet heavy in unprocessed corn or lightly processed corn 

(e.g., corn meal) contaminated with Fumonisin B1 or FB1 ( the most prevalent members of a family of toxins known 

as fumonisin) are at significantly higher risk of having a baby with neural tube defects (NTDs) because FB1 

interferes with the uptake of folate in maternal cells [3]. 

However, there are major concerns regarding GM foods, such as the risk of allergy in humans and the potential 

negative environmental effects of modified crops.  

A study was carried out on crop-to-crop gene flow using farm scale sites of fodder maize (Zea mays L.) in the 

UK, and reported that gene flow was detected in 30% of the samples (40 out of 135) at 150 m from the GM source, 

and events of GM to non-GM gene flow were detected at distances up to and including 200 m from the GM source 

[4]. With increasing use of GM crops, expanding from 1.7 million hectares in 1996 to 44.2 million hectares in 2000, 

gene-flow is an important consideration in the contamination of conventionally or organically grown crops [5]. A 

further valid argument made about GM foods is that little is kno wn about the long-term effects of GM crops on the 

environment, microorganisms, animals, and humans [6]. 

Therefore, there is a growing public demand for transparency and accountability in terms of GMOs in the 

market place [1]. Regulators and governments have come  under  pressure  to  strengthen  labeling requirements for 

GM foods. More than 35 countries have developed some form of labeling requirement, including China (0% 

threshold), the European Union (EU) (0.9% threshold), Australia and New Zealand (1% th reshold), South Korea 

(3% threshold) and Japan and Taiwan (5% threshold) [1]. In order to support legislation, reliable, accurate methods 

for identification of GMOs in raw materials and food products are required [5,7,8]. Many analytical methods are 

available, including PCR methods for screening and for qualitative and quantitative detection of GMOs [5,9,10,11]. 

A review of methods has been published [12]. 

Oman was one of the countries that signed the Cartagena Protocol on Biosafety at the Convention on 

Biological Diversity in 2000. GMOs are not grown in Oman and the overall attitude of Omani consumers to GMOs 

is negative, although they are generally of the opinion that the government should allow importation of GM food if 

clearly labeled. When respondents were questioned about clearly labeled GM foods, the majority of respondents 

(59%) were happy to see them imported, if clearly labeled (Unpublished results of PhD study). There is, therefore, a 

need to label GM products in Oman in order to fulfill consumer demand for clear labeling of GMOs, to overcome 

the lack of GMO detection in Oman and to meet the demand s of the biosafety protocol. The Central  Laboratories  

for  Food  and  Water  in  Oman, which  undertakes  a  range  of analyses on food do not analyze for GMOs or GM 

foods [13]. 

However, there is a proposal, prepared by the Ministry of Environment and Climate Affairs in collaboration 

with academic institutions and relevant organizations, for a national biosafety framework that will support the 

implementation of the biosafety protocol.  

In this study, DNA extraction of different food products was performed . Plant specific, screening of GMOs 

and specific detection for Roundup Ready Soybean, Bt-176 maize and MON810 maize were carried out. In addition, 

the amount of GM soy in positive samples using quantitative real time PCR was semi-quantified. 

2.    Materials and Methods  

2.1  Sample Collection 

A total of 100 food samples, including raw soybean, maize seeds and processed products containing soya and/or 

maize ingredients were collected during March - April 2008. Samples were collected randomly from four superstores 

in the capital area of Oman (Muscat). These stores are located in the districts of Al-Qurum, Madinat As’Sultan Qaboos, 

Al-Hail and Al-Khod. The samples analyzed were: 8 varieties of baby foods, 2 types of  burgers, 3 types of cake mixes, 

5 types of canned foods, 2 types of cereals, 3 types  of chips (fries), 1 type of chocolate drink mix, 5 varieties of 

confectionary, 3 types of cookies, 2 types of cornflour, 4 varieties of corn puffs, 4 types of corn seeds, 5 types of dried 

noodles, 1 type of fish cake, 2 types of franks, 2 types of fruit yoghurts, 2 types of frozen meals, 6 types of meal mixes, 

2 types of sauces, 1 type of seasoning mix, 3 types of soup mixes, 1 type of soya bread, 1 type of soya cream, 3 types 

of soya milk, 1 type of soya pellets, 4 types of soya seeds, 1 type of spring rolls, 7 types of sweet biscuits (cookies), 7 

types of sweet mixes, 2 types of sweet rolls, 1 type of thick cream and 4 types  of  tofu. The information on the labels 



DETECTION OF UNLABELED GENETICALLY MODIFIED SOYBEAN IN OMAN 

 

 
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of the food samples collected was checked, and it indicated that  59%  of  the samples collected contained maize and 

57% contained soy. 

Institute for Reference Materials and Measurements (IRMM)-certificated soybean and maize reference material 

was obtained commercially (Sigma-Aldrich, St. Louis, MO). For MON 810 Maize, CRM was IRMM-413, 77119 (0% 

GM), 79521 (0.5% GM) and 76182 (5% GM). For Bt-176 Maximizer Maize, CRM was IRMM-422R, 91528 (0% 

GM), 14724 (0.5% GM) and 19074 (5% GM). For Roundup Ready Soybean, CRM was IRMM-410S, 83063 (0% 

GM), 81751 (0.5% GM) and 93109 (5% GM). 

2.2   DNA Extraction 

DNA was extracted using the Cetyltrimethyl Ammonium Bromide (CTAB) method [11] with some 

modifications. The extraction buffer contained 1% CTAB, 1.4M NaCl, 0.1M Tris-HCl (pH 8), 0.02M EDTA (pH 8), 

0.5% w/v PVP and 0.1% v/v β-Mercaptoethanol. 

DNA from reference materials was extracted by the same method. DNA concentration was measured for all 

samples (100) and the 9 controls using a NanoDrop ND-000 Spectrophotometer. The concentration of DNA for PCR 

was diluted to 50 ng/µl. 

2.3  Plant Specific PCR for Maize and Soybean 

Due to the high risk of cross contamination of samples and reagents, individual PCR steps were performed 

separately in terms of physical space and equipment [5,11,13]. PCR reaction with water instead of DNA extract was 

carried out with every mix as a reagent control and, with every set of samples, a series of positive and negative 

controls were run to ensure the accuracy of the results [5,11].  

To confirm the presence and quality of DNA extracted from maize and/or soybean containing samples, primers 

ZEIN3/ZEIN4 specific to the maize zein gene (ze 1, coding for a 10-kb protein) and GMO3/GMO4  specific  to  

soybean  lectin  gene  (le  1) were used [11]. 

The PCR master-mix was set up in a total volume of 50 µl using 26.25 µl MilliQ water, 2.5 µl Glycerol (50%), 

5 µl 10x Buffer (of 1x concentration), 5µl MgCl2 (2.5 mM, Applied Biosystems, USA), 5µl dNTPs (0.2mM, 

Promega, USA), 0.25µl Taq. polymerase (0.025U/µl Inno), 0.5 µl of each primer, (0.5 µM, Sigma, USA) and 5 µl of 

DNA (5 ng/µl). The PCR program for primer pair ZEIN 3 & 4 was: initial denaturation for 3 min at 95ºC, 

denaturation for 1 min at 96 ºC, annealing for 1 min at 57 ºC, extension for 1 min at 72 ºC, number of cycles 50, final 

extension for 3 min at 72 ºC. The PCR program for primer pair GMO 3 & 4 was: initial denaturation for 3 min at     

95 ºC, denaturation for 30 sec. at 95 ºC, annealing for 30 sec at 63 ºC, extension for 30 sec at 72 ºC, number of cycles 

40, final extension for 3 min at 72 ºC. 

2.4  Screening for Promoters and Terminators 

The detection of the 35S promoter and nos terminator by PCR was carried out for screening. The identification 

of one of these regulatory sequences in soybean or maize containing samples indicates GMO presence. In Roundup 

Ready Soybean, the identification of both 35S promoter and the nos terminator is possible, whereas only the 35S 

promoter is present in the Bt-176 and MON810 Maize [11]. 

The PCR master-mix was set up as detailed, with 0.5 µl of each primer, P35S-cf3 and P35S-cr4 for 35S and 

HA-nos 118-f and HA-nos 118-r  for nos (0.5 µM, Sigma, USA) and 5 µl of DNA (5 ng/µl). 

The PCR program for primer pairs P35S-cf3, P35S-cr4 and HA-nos 118-f, HA-nos 118-r was: initial 

denaturation for 3 min at 95 ºC, denaturation for 25 sec at 95 ºC, annealing for 30 sec at 62 ºC, extension for 45 sec at 

72 ºC; number of cycles 50, final extension for 7 min at 72 ºC. 

2.5   Detection of Roundup Ready Soybean 

Primer pairs GMO5/GMO9 and GMO7/GMO8 were used for specific detection of Roundup Ready® Soybean 

[11]. 

The PCR master-mix was set up in a total volume of 25 µl with 0.1µl of each primer, GMO5 and GMO9 (0.5 

µM, Sigma, USA) and 2 µl of DNA (5 ng/µl). 

The PCR program for primer pair GMO5 and GMO9 was: initial denaturation for 3 min at 95 ºC, denaturation 

for 30 sec at 95 ºC, annealing for 30 sec at 60 ºC; extension for 40 sec at 72 ºC, number of cycles 25, final extension 

for 3 min at 72 ºC. After amplification, 0.5 µl of the previous PCR product was added to 24.5 µl of the master-mix for 

a second PCR (nested PCR) with 0.1µl of each primer GMO7 and GMO8 (0.5 µM, Sigma, USA). 

 

 

 

 

 



NABILA AL-SADQI AND ALIYA ALANSARI 

 

 
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The PCR program for primer pair GMO7 and GMO8 was: initial denaturation for 3 min at 95 ºC, 

denaturation for 30 sec at 95 ºC, annealing for 30 sec at 60 ºC, extension for 40 sec at 72 ºC, number of cycles 35, 

final extension for 3 min at 72 ºC. 

2.6  Quantification of Roundup Ready Soybean using Real Time PCR 

 RT-PCR was carried out to determine the ratio of target GM DNA to the total of the species DNA. Applied 

Biosystem ABI PRISM ™ 7700 detector instrument (TaqMan
TM

) was used. The primer pairs used for real time 

PCR were: reference gene primers and probe, Le-F, Le-R, Le-Probe and trans-gene primers and probe; RR-F, 

RR-R, RR-Probe [11]. 

2.7 Agarose Gel Electrophoresis 

 The extracted DNA was subjected to electrophoresis on a 1% agarose gel at a constant voltage                      

(75 V for 15 min); PCR products were checked on a 2% agarose gel (75V  for  30 min)  and  nested  PCR  on  a  

2.5%  agarose  gel  (100V  for  30  min) containing ethidium bromide in 1XTBE buffer.  The visualization was 

performed under UV light and the images were captured with a digital camera (Casio, EX-Z1000) for 

documentation. 

3. Results and Discussion 

3.1 DNA Extraction 

The modified CTAB method yielded a good amount of DNA for all controls and food samples. Most of the 

samples under UV radiation showed a clear heavily illuminated area of DNA. The DNA extraction method used 

was satisfactory for most of the products, which ranged from raw seeds to processed food. 

The quantity of DNA extracted ranged from 16.23 to 5454 ng/μl. 

3.2 Plant Specific PCR for Maize and Soybean 

Out of  57  samples  containing  soybean  in  their  ingredients, 40 samples (70%) were positive for soybean 

plant specific PCR, and out of 59 samples containing maize in their ingredients (all were processed), 8 samples 

(13.5%) were positive for maize plant specific PCR. A study by Cardarelli et al. showed that the analysis of 

products containing maize seemed to be more difficult, probably due to the low concentration of maize 

ingredients or to some processing steps in food production that strongly contributed to the failure of DNA 

extraction [5]. In addition, the treatment during food production processes, such as heating, high pressure and the 

physical processing are known to affect the DNA content. This was found in a study on maize samples screened 

for GM maize, where the corn samples investigated contained corn starch, corn grits, hydrolyzed corn starch, or 

corn flour [8]. 

3.3 Screening for Promoters and Terminators 

PCR was carried out for maize samples using primer pair P35S-cf3 and P35S-cr4. A band of 123bp 

indicates the presence of GM. 

Six soybean samples out of 40 showed clear positive in both the 35S promoter and nos terminator reactions, 

15% of soybean samples were GM soybean (Table 1). Although there were about the same number of samples 

containing maize (59) and soya (57), none of the maize-containing food were GM positive. The negative GM 

maize results in this study may indicate that Oman’s source of maize is not a GM maize producer. However, 

having highly processed samples can potentially interfere with the PCR detection.  This is clearly demonstrated 

by having only 5 samples detected out of 59 samples with the maize specific PCR.  

3.4 Detection of Roundup Ready Soybean 

For specific detection of  Roundup Ready Soybean, standard controls, 2% GM and 5% GM, were used. The 

six samples, which were positive with both screening PCRs (35S and nos) were also positive for the specific PCR 

detection of Roundup Ready Soybean. One was raw soybean seeds and five were processed foods (Table 1). 

In previous studies where the primer pair GMO5/GMO9 and GMO7/GMO8 were used in the nested PCR the 

sensitivity was 0.01% [14]. The results of this study agree with  these findings because all six GM soybean 

samples checked for Roundup Ready® Soybean were positive. 

 

 



DETECTION OF UNLABELED GENETICALLY MODIFIED SOYBEAN IN OMAN 

 

 
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3.5  Quantification of Roundup Ready Soybean Real Time PCR 

Real time PCR (TaqMan™ system) was carried out for the six Roundup Ready soybean samples and the 

controls, Roundup Ready Soybean 0%, Roundup Ready Soybean 2%, Roundup Ready Soybean 5% and a DNA 

negative control sample. 

Two of the samples contained higher amounts of GM than the 5% control. One sample, raw soybean seeds 

imported and packed in Oman, contained 88% GM soybean and the second sample, a Soy Formula for Infants, 

contained 21% GM soybean (Table 1). Neither sample was labeled as containing GM, although analysis showed that 

the GM ingredients exceeded the legal threshold (1%) level of GM content in a food product. 

More of the samples could have contained GM, but with it failing to be detected due to method limitations, such 

as the quality of DNA extracted from highly processed food products possibly being affected by degradation 

processes. The process of DNA and protein detection faces difficulties when processed and highly refined food 

products are involved, e.g. starch, sugar or vegetable oils. Sometimes food products are subjected to extensive food 

processing stages which could affect their ingredients and GMO origin. This can result in the possibility of non-

detectable GM DNA or proteins [15].  

 

Table 1. Results of PCR for soybean samples 

Product Number of 

Samples 

Soybean 

Plant Specific 

Screening Detection RT PCR 

   Promoter Terminator RR Soybean  GM % 

Baby Food 8 5 1 1 1 21 

Soya Seeds 4 4 1 1 1 88 

Soya Pellets 1 1 0 0 0 0 

Soya Milk 3 3 0 0 0 0 

Soya Bread  1 1 0 0 0 0 

Sweets  18 5 0 0 0 0 

Biscuits 10 8 1 1 1 0 

Tofu 4 4 0 0 0 0 

Frozen Meals 5 1 1 1 1 0 

Canned Meats 5 2 0 0 0 0 

Burgers  2 2 2 2 2 0 

Franks  2 2 0 0 0 0 

Mixes 11 1 0 0 0 0 

Noodles 5 1 0 0 0 0 

4.  Conclusion 

Using PCR-based methods we detected and quantified the presence of GM foods in a collection of 100 samples 

from the market. The results demonstrate the availability of unlabeled GM soybean products containing higher 

percentages than the limit for labeling (1%) in the Omani food market.  This indicates the need for better control and 

labeling of GM food products in Oman, to address public concerns about GM foods and their potential health and 

environmental risks, the consumer right to choose, and also  to support the implementation of the recently proposed 

National Biosafety Framework for Oman.  

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Received  22 October 2014 

Accepted  8 June 2015