Indonesian Journal of Halal Research, 3, 2 (2021): 70-74 

E-ISSN: 2657-0165 

P-ISSN: 2656-3754 

DOI: 10.15575/ijhar.v3i2.12123 

https://journal.uinsgd.ac.id/index.php/ijhar/ 

In Silico Analysis of Actin Gene as a Candidate for DNA 

Non-Halal Detection Base on Real-Time PCR 
 

Seagames Waluyo1*, Jekmal Malau2, Muhareva Raekiansyah3, Edwin Yulian4, Imam Hardiman5 

 
1,2,3,4,5PT. Sciencewerke Indonesia, Jl. Palmerah Barat No.25, RT.1/RW.15, Palmerah, Kec. Palmerah, Kota 

Jakarta Barat, Daerah Khusus Ibukota Jakarta 11480, Indonesia 
5Department of Pharmacy, Faculty of Pharmacy and Science, Universitas Prof. Dr. HAMKA, Jl. Delima II Gg. 

4, RT.9/RW.3, Malaka Sari, Kec. Duren Sawit, Kota Jakarta Timur, Daerah Khusus Ibukota Jakarta 13460, 

Indonesia 
e-mail: games.agro@gmail.com*1, jekmal@sciencewerke.com2, m.raekiansyah@gmail.com3, 

edwin.yulian@yahoo.com4, imam@sciencewerke.com5 

 
*Corresponding Author 

Received: June 02, 2021; Accepted: August 29, 2021 

 

Abstract: Actin genes are genes that are common in organisms, and their expression is constitutive. These genes 

are used for gene normalization and internal control of DNA extraction, but the actin gene is not widely used for 

halal certification tests. Bioinformatic studies help to analyze the experiment through in silico more deeply before 

the experiment is carried out in laboratory, making it more efficient and time effective. uMelt is an analysis to 

predict the melting curve of target amplification in real-time PCR. Real-time PCR has been widely used for 

screening and detection of pork content in a product. This research aimed to explore actin gene as a candidate for 

testing pork using qPCR. The study was carried out in two main stages, namely alignment of the DNA sequence 

and analysis of the melting curve using the uMelt approach. The results showed a set of actin genes containing 

conserved regions that can be used as degenerate primers with different family-type coverages. Melting curve 

prediction with uMelt shows differences in tm peaks so as the types of samples can be easily identified. The use of 

bioinformatic applications such as uMelt helps in the simulation of predicting the melting curve to increase the 

precision of the analysis. 

Keywords: Actin gene, halal product, real-time PCR, uMelt 

 

1. Introduction 
Indonesia is the largest Muslim country with 87.18% of its citizens is Muslims. Therefore, the 

potential of halal market is promising. To protect Muslim citizens, the Indonesian government has an 

agency to regulate halal-guaranteed products, namely BPJPH (Halal Product Security Agency) 

(Aminuddin, 2016). Halal-guaranteed products include raw materials, production processes to the final 

product (Faridah, 2019). One of the concerns is the use of pork and its derivatives. Pork is widely used 

for meatball mixtures, emulsions, and trypsinization in cell culture, vaccines, candies, and medicine. It 

gives a challenge to develop a robust, accurate, and sensitive method for pork detection. 

Real-time PCR (qPCR) as a DNA-based detection has been widely used to detect porcine. This 

method is able to detect at the level of the raw material to the end product (Rachmawati et al., 2018; 

Raharjo et al., 2019; Widayat et al., 2019). The advantage of this method is high level of accuracy and 

sensitivity to detect and quantify target in samples. The advantages of this method are high sensitivity, 

high specificity, and no post-analysis after the PCR process is complete. The amplification process runs 

in a live stream (real-time) on the monitor screen. Intercalating dye and probe are types of fluorescent 

dye in use because the accumulated fluorescence of this chemical is equal to the number of amplicons 

produced. In addition, the PCR composition consists of DNA template, primer and master mix 

containing real-time PCR buffer, Taq polymerase, nucleotides, fluorescence dye (S. A. Bustin, 2004).   

Primer is a key component in determining the success of porcine detection with qPCR. Primers 

work by starting the amplification of genetic material by annealing at very specific sites on DNA.  qPCR 

has been successfully used to detect porcine DNA contamination in food products such as bread, 

meatballs and candies, and non-food products, such as bread brushes, moisturizers, soaps, cosmetics, 

and capsules (M. J. Kim & Kim, 2019; Y. S. Kim et al., 2018; Mohamad et al., 2018; Mustaqimah et 

al., 2021; Septiani, 2021; Sudjadi et al., 2016; Tan et al., 2020; Tanabe et al., 2007; Widayat et al., 2019). 

Currently, primer Cytochrome oxidase I (co1) and Cytochrome B (cyb) gene located in mtDNA region 

is popular for porcine-specific detection. The problem with this target is that it is very specific to the pig 

mailto:games.agro@gmail.com
mailto:jekmal@sciencewerke.com
mailto:m.raekiansyah@gmail.com
mailto:edwin.yulian@yahoo.com
mailto:imam@sciencewerke.com


Indonesian Journal of Halal Research, 3, 2 (2021): 70-74  71 of 74 

In Silico Analysis of Actin Gene as a Candidate for DNA Non-Halal Detection Base on Real-Time PCR 

species but cannot detect the presence of other sources outside of its species. Therefore, other alternative 

targets are needed to be able to screen for the presence of other sources.   

The β-actin (act) gene has a high conserved region, ability in eukaryotic cells, and stable 

expression in cell (Zhu et al., 2013). This gene serves as endogenous gene in PCR such as normalization 

expression gene, quality control DNA extraction, and amplification PCR (Rebouças et al., 2013; Waluyo 

et al., 2016; Panina et al., 2018). Presently, this gene has also been successfully used in digital PCR 

(dPCR) for the quantification of porcine contamination (Cai et al., 2014; Tan et al., 2020). The act gene 

is present in all eukaryotic cells, so that this gene has the potential to be used for non-halal contamination 

screening in products. The in-silico approach can be used for identification of candidate primers, PCR 

amplicon, and melting curve prediction. This study aims to explore the actin gene through in silico for 

the detection of the presence of porcine and its accompaniment for the detection of non-halal 

contaminants.  
 

2. Materials and Methods 
2.1. Sample Preparation  

Sample Act (actin) gene sequences were taken from NCBI (National Center for Biotechnology 

Information) (https://www.ncbi.nlm.nih.gov/nucleotide) in FASTA format. The sequences analyzed 

were obtained from cattle (Bos taurus); horse (Equus caballus); dog (Canis lupus familiaris); 

orangutans (Pongo abelii); chicken (Gallus gallus); porcine (Sus sucrofa), and rat (Rattus novergius) 

with accession number NCBI is NM_173979.3; NM_001081838.1; NM_205518.1; NM_001195845.2; 

NM_001133354.1; XM_003124280.5 and NM_031144.3. 

 

2.2.  In-silico Analysis 
The experiment used 2 steps; the first was the sequence alignment using BioEdit software (Hall, 

2007), and the second is predicting the melting curve using uMelt (Dwight et al., 2014). Each sequence 

was downloaded and joined together in a FASTA format file. The ClustalW protocol was used in 

BioEdit software to align from multiple sequences. Furthermore, the preserved region was selected as 

the amplification of target region and used as the forward and reverse primary sets with a size of < 200 

bp. The amplification region contained a specific region of each sample sequence. Next, the 

amplification regions were analyzed using uMelt (https://www.dna-utah.org/umelt/quartz/um.php). The 

amplification region sequence was entered into the sequence box. The prediction curves used conditions 

of Mono + 20 mM and free Mg ++ 3 mM and readings every 0.1ºC. Each curve produced a Tm 

(temperature melting) value, and the next image was carried out, all the melting curve images were 

overlaid. 

 

3. Results and Discussion 
Sequence analysis used BioEdit software to generate PCR primer and amplicon candidates by 

aligning the sequences. The size amplicon candidates are 131 bp containing conserved sequences as 

PCR primers and species-specific regions. The conserve sequence as generated primer with sequence is 

forward 5'-GCTACAGCTTCACCACCAC-3' and reverse 5'-TAGCTCTTCTCCAGGGA-3'. Primer 

was the main component in qPCR to start amplification and will be hybridized to the target region. Good 

characteristic primers selected have GC content percentage of 55% in forward and 52% in reverses at 

annealing temperatures of 56.46°C and 52.42°C. Harpin analysis showed that each primer has 4 

structures of Self complementarity and Self 3' complementarity forward is 0 and reverse is 4. This 

analysis is in accordance with the description of the mFold analysis which shows the presence of a 

harpin structure at 4 amplicon points (Figure 2). Good qPCR primer design was amplicon <150 bp, GC 

content between 40 - 60% with melting temperature of 55 – 65°C (S. Bustin & Huggett, 2017; Taylor 

et al., 2010). 



Indonesian Journal of Halal Research, 3, 2 (2021): 70-74  72 of 74 

Seagames Waluyo et al. 

 
Figure 1. Alignment analysis using BioEdit to identify candidate generate primer in actin gene 

 

 
Figure 2. Mfold analysis amplicon target from generates primer actin (https://www.idtdna.com/calc/analyzer). 

 

The uMelt program is aimed to predict the melting temperature (Tm) to differentiate each sample. 

Between general primers, there is a specific region which is able to distinguish specific regions from 

each species. The variant nucleotide will produce different melting temperatures. The results showed 

that the Tm amplicon candidate value of the selected area has a high range between 85–89ºC, and each 

curve could differentiate one from the other (Table 1). Dogs and rat have Tm samples which are not 

significant, so it will be difficult to distinguish them, both are non-halal types. Interestingly, the curve 

of porcine is significantly separated from the others due to the lower Tm temperature (84.9ºC), so it 

makes a quick indicator of its presence (Figure 3).  

 
Table 1. Specific Temperature Tm from candidate amplicon for Each Target 

Species B. taurus E. caballus C. lupus familiaris P. abeli G. gallus S. sucrofa R. novergius 

Tm (ºC) 88.9 87.8 88.2 85.7 89.2 84.9 88.1 

 

https://www.idtdna.com/calc/analyzer


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In Silico Analysis of Actin Gene as a Candidate for DNA Non-Halal Detection Base on Real-Time PCR 

 
Figure 3. The Curve of Tm Values Analyzed by uMelt in Each Target 

 

The uMelt had successfully predicted the Tm value of each sample as shown in the form of a 

melting curve. Differences in Tm values varied greatly between 0.1 to 4.3ºC, so that there was no overlap 

between targets. It was interesting that the peak of porcine had a considerable distance compared to the 

others. The lowest Tm value was 84.9ºC and had a difference of 2.5ºC when compared to the others 

(Figure 3). The advantage of this software was that Tm simulation paid attention to the reagent 

composition such as the MgCl+ content, salt, and the reading resolution, so that it was closer to actual 

conditions. In addition, this analysis was useful for predicting the profile of the post-PCR curve, so that 

it could reduce the experiment time. 

The melting curve was matched between uMelt and the qPCR machine. Melt peak parameter (– 

df/dr compared to temperature) resulted from the conversion of post qPCR. The data generated is the 

TM value calculated from the %GC percent and the size of the amplicon. Processed by the qPCR 

machine, the amplicons produced from the amplification step were denatured from the annealing 

temperature to 95ºC with a reading of each increase of 0.5 – 0.01ºC. SYBR and Evagreen are types of 

intercalating dye to produce a melting curve. This reagent is compatible with all types of qPCR 

machines. Thus, the development of detection using intercalating dye using a melting curve has the 

potential to be widely used in qPCR machines. 

 

4. Conclusion 
The results of the in-silico analysis of actin gene show the melting curve can easily distinguish of 

porcine and other species to determine halal products. The success of differentiating the source is due 

variation sequence in specific region that produces a specific Tm. Further research, laboratory testing of 

candidate primers using PCR on various sample sources is needed to prove the accuracy of Tm 

predictions.  

 

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