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78 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 1, p. 78-86, Jan./Feb. 2020 
http://dx.doi.org/10.14393/BJ-v36n1a2020-42265 

DEVELOPMENT OF QUANTITATIVE DETECTION METHOD FOR 
Meloidogyne incognita BY qPCR 

 
DESENVOLVIMENTO DO MÉTODO DE DETECÇÃO QUANTITATIVO PARA 

Meloidogyne incognita POR qPCR 
 

Camilla Martins de OLIVEIRA1; Ismail Teodoro de SOUZA JÚNIOR2;  
Nayane Oliveira ALMEIDA3; Marcos Augusto de FREITAS4; Mara Rúbia da ROCHA5;  

Silvana PETROFEZA6 
1. Doutoranda em Ciências Biológicas da Universidade Federal de Goiás – UFG, Goiânia, GO, Brasil. camillam.08@gmail.com; 2. Pós 

– doutorando em Fitossanidade da Universidade Federal de Pelotas - UFPEL; 3. Doutoranda em Agronomia – Fitossanidade da 
Universidade Federal de Goiás –UFG, Goiânia, GO, Brasil.; 4. Doutor, Fitopatologista da JEM Análise Agrícola, Aparecida de Goiânia, 
Brazil.; 5. Professora Titular, Doutora, Escola de Agronomia, Universidade Federal de Goiás – UFG, Goiânia, GO, Brasil.; 5. Professora 

Titular, Doutora, Instituto de Ciências Biológicas, Universidade Federal de Goiás – UFG, Goiânia, GO, Brasil. 
 
ABSTRACT: The root-knot nematode (Meloidogyne spp.) is the most important plant-parasitic 

nematode genus, they are the most common and destructive pathogens in this group. They produce some of the 
most drastic symptoms in plants and can significantly reduce the yield of crops. In order to achieve deploy an 
efficient method of plant-parasitic nematode management, is necessary an identification and quantification 
accurate and reliable of plant-parasitic nematodes. The aim of this study was to analyze samples in qPCR to 
detect and quantify M. incognita, in the field samples, comparing different methods of extraction of DNA and 
its efficacy in establishing the number of individuals. For this purpose the effectiveness of different DNA 
methods of extraction was compared through the values of CT intervals. For standard curve and method 
comparisons, we used nematodes multiplied in a greenhouse and carefully separated in the specific quantities of 
the experiments. For the number of individuals experiment field samples previously counted under an optical 
microscope were used. The DNA extraction was made from 100 nematodes by the methods: CTAB, Phenol: 
Chloroform and commercial kit (PureLink® Genomic DNA Kit, Invitrogen). In the comparative analysis using 
the three methods of DNA extracting from 100 nematodes, it was observed that commercial kit and CTAB 
methods obtained CT values similar. The CTAB method of extraction, showed less variation in the repeats and 
greater linearity of standard curve in comparison with other methods tested. So, it was possible to quantify the 
samples through the CT value intervals, established from different numbers of individuals (1, 10, 25, 100, 250, 
500 and 750), in field samples. This study demonstrated that qPCR technique is an alternative sensitive and 
reliable for the quantification of M. incognita to support laboratories of diagnose and field survey. 
 

KEYWORDS: Diagnostics. Monitoring. Root-knot nematode. Technique. 
 
INTRODUCTION 
 

Embrapa (2011) has estimated that nearly 
5% of the soybean annual production is lost due to 
the nematode’s action. The Brazilian Society of 
Nematology data have shown that the loss caused by 
the plant-parasitic nematodes in the country ranges 
from 5% to 35% considering the different kinds of 
culture. The Root-Knot nematodes (Meloidogyne 
Goeldi) are the most common and most destructive 
among this group of plant-parasitic nematodes. 
They can meaningfully reduce the culture’s 
production and are found in almost all the farming 
places around the world, attacking a wide range of 
hosts (BAILEY et al., 2008). This makes them 
extremely difficult to control. 

In order to be able to set an efficient method 
of handling these plant-parasitic nematodes, it is 

necessary a reliable identification of their species 
and quantification. These information are important 
to get an efficient control of the sustainable 
agriculture (CLAPP et al., 2000). The identification 
and quantification of the nematodes by most of the 
laboratories are done by the optical microscope. 
However, with the development of new tools of 
identification and measurement, there is an 
agreement in the scientific community that they 
must use these new techniques in order to get more 
accurate distinction of the species and quantification 
of the nematodes (SILVA et al., 2014). 

The qPCR is a technique based on the 
DNA’s analysis that allows the identification and 
quantification of the amplicon target by monitoring 
the fluorescence accumulation based on the 
threshold cycle’s value (CT) (HEID et al., 1996). 
The advantages of this technique are: facility in 

Received: 14/05/18 
Accepted: 10/02/19 



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Development of quantitative…  OLIVEIRA, C. M. et al. 

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http://dx.doi.org/10.14393/BJ-v36n1a2020-42265 

measurement, more sensitive, more accuracy, 
reproducibility, speed in analysis and better quality 
control and less risk of contamination (NOVAIS et 
al., 2004). 

The qPCR applicability to detect the plant-
parasitic nematodes has been tested in different 
researches, suggesting a practical approach for the 
Meloidogyne spp. quantification in field sampling 
(MADANI et al., 2008; BERRY et al., 2008; 
TOYOTA et al., 2008; ZHAO et al., 2010; MIN et 
al., 2011). Recent researches have discussed other 
kinds of nematodes of agronomic importance using 
this technique. Mokrini et al. (2013) have developed 
an accurate and fast method to detect and measure 
the Pratylenchus penetrans using the qPCR. 
Another research tested the qPCR’s sample in order 
to detect and quantify the P. neglectus, directly from 
nematode’s DNA extracted from the soil, to 
establish the applicability of field samples infested 
by this nematode in different population densities 
(YAN et al., 2011). These papers have shown a high 
linkage between the standard curve and the real 
number of nematodes. 

Different methods of DNA’s extraction 
have been tested to detect and quantify the 
nematodes by using different buffers of cell lysis 
like: NaOH (BERRY et al., 2008), Tween (YAN et 
al., 2011), NaCl (AL-BANNA et al., 2004; 
HOLTERMAN et al., 2006; MOKRINI et al., 
2013), Phenol-Chloroform (DONG et al., 2001; 
FRANÇOIS et al., 2007), Chloroform-alcohol 
(BULMAN; MARSHALL, 1997) and Triton X-100 
(ZHAO et al.,2010). It also has been used in 
different physical methods of DNA extraction to the 
cell lysis like Zirconia Beads and glass pearls 
(SATO et al., 2007; TOYOTA et al., 2008; MIN et 
al.,2011), as well as methods to develop the final 
quality of the DNA like commercial kits of DNA 
extraction and K protein (OLIVEIRA et al., 2009). 
The nematode development phase is also important 
since a few studies have shown extraction of DNA 
in a different life stage like second-stage juvenile 
(J2) and females (YAN et al., 2011; MIN et al., 
2011), eggs (CARNEIRO et al., 2004; TOYOTA et 
al., 2008), directly from galls (DONG et al., 2001; 
HU et al., 2011) and samples with a mix of some 
developmental stage (BERRY et al., 2008; YAN et 
al., 2011; MOKRINI et al., 2013). 

Assay of qPCR used for identification and 
quantification has also made it possible to deal with 
a big number of samples by automation that increase 
the velocity and accuracy of the extraction 
procedures. The quantitative PCR was also used in 
assays in the greenhouse (GAO et al., 2006) and in 
field to determine the effects of different treatments. 

Other samples with qPCR have provided ecologic 
tools to study and quantify specific species within 
populations (HOLTERMAN et al., 2006; SATO et 
al., 2007) and interaction studies where the 
nematodes are inside the host (GAO et al., 2006; 
FRANÇOIS et al., 2007).  

This study aimed to analyze samples using 
qPCR to detect and quantify M. incognita in study 
of the field samples, comparing different methods of 
extraction of DNA and its efficacy in establishing 
the number of individuals. This study suggests a 
practical approach to quantify M. incognita in field 
samples. 

 
MATERIAL AND METHODS 
 

The M. incognita isolate used in this study 
was obtained from inoculum source multiplied in 
tomato (Solanum lycopersicum) 'Santa Cruz', 
maintained in a greenhouse under controlled 
conditions of temperature (21°C to 30°C), in the 
Agronomy School of Universidade Federal de 
Goiás. The isolates were identified through a 
perineal cutting and an esterase profile according to 
the methodology described by Carneiro and 
Almeida (2001). The nematodes were extracted 
from the tomato roots by the method of Coolen and 
D'Herde (1972). For standard curve and method 
comparisons, we used nematodes multiplied in a 
greenhouse and carefully separated in the specific 
quantities of the experiments, with the aid of a 
magnifying glass. For standardization of the qPCR 
was used the absolute quantification method with 
diluted patterns of DNA for the construction of the 
calibration curve (90 ng to 0.000009 ng) and 
extraction of DNA by the CTAB method.  

To determine the number of individuals, 
preliminary tests were made and selected quantities. 
The test involved samples with 1, 10, 25, 100, 250, 
500 and 750 nematodes from field samples collected 
and sent to the laboratory. The samples were 
previously counted under optical microscope, and 
contained nematodes of different developmental 
stages, as well as free-living nematodes and other 
important genera. 

For the genomic DNA extraction, the 
methods were used: CTAB 
(Cetyltrimethylammonium bromide), described by 
Zolan and Pukilla (1986), the Phenol method: 
Chloroform described by Randig et al. (2002) and 
the commercial kit PureLink® Genomic DNA Kits 
(Invitrogen Corp., Carlsbad, CA, USA).  For the 
DNA extraction with CTAB, first, each suspension 
containing the nematodes were centrifuged at 
10.000 RPM for 5 min, and then the supernatant 



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Development of quantitative…  OLIVEIRA, C. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 1, p. 78-86, Jan./Feb. 2020 
http://dx.doi.org/10.14393/BJ-v36n1a2020-42265 

was removed. Then the contents of the tubes were 
frozen in liquid nitrogen and then macerated with a 
glass rod aid. Were added to the samples 800 µL of 
CTAB buffer (2% CTAB, 1.4 M NaCl, 20 mM 
EDTA, 100 mM Tris-HCL, pH 8.0 and 0.2% ß-
mercaptoethanol) preheated to 65°C. Thus, the 
material was incubated for over 1h at this 
temperature, with shaking every 10 min. Were 
added 600 µL of chloroform-isoamylalcohol and the 
tube was shaken manually for 10 min. It was 
centrifuged for 10 min at 10.000 rpm and 
transferred the aqueous phase to a new tube, then 
added 600 µL of isopropanol and mixed by tube 
inversion. Again, the material was centrifuged for 
10 min at 10.000 rpm. The supernatant was 
discarded and was added about 1 mL of ethanol 
70%, and then centrifuged for 10 min at 10.000 rpm. 
The supernatant was discarded, leaving the drying 
supernatant. The precipitate was resuspended in 20 
µl of sterile water (miliQ) and stored at -20 ° C until 
the use. 

For the extraction by the Phenol: 
Chloroform was used the method described by 
Randig et al. (2002). Briefly, nematodes were 
macerated in liquid nitrogen with the aid of a glass 
rod. To the macerate was added 500 μL of NIB 
buffer (0.1 M NaCl; 30 mM Tris pH 8; 10 mM 
EDTA; 0.7 mMβ-mercaptoethanol; 5 mM Triton - 
NPHO). After homogenization, the samples were 
centrifuged twice at 10.000 rpm for 2 min and the 
supernatant was removed. Then, were added 800 µL 
of homogenization buffer (0.1 M NaCl; 0.2 M 
saccharose; 10 mM EDTA) and 200 µL of lysis 
buffer (0,125 M EDTA; 0,5 M Tris pH 9.2; 2.3 % 
SDS). After homogenization, the samples were 
incubated at 55ºC for 30 min, followed by 10 min at 
ambient temperature. The purification was 
performed by adding 1 mL of buffered phenol (pH 
8.0), followed by the homogenization and 
centrifugation at 10.000 rpm for 3 min. The 
supernatant was recovered and then mixed with 500 
µL of phenol and 500 µL of chloroform, then 
centrifuged at 10.000 rpm for 3 min. To the 
supernatant was added 200 μL of ether and after 
centrifugation at 10.000 rpm for 3 min, this was 
removed with the aid of a micropipette. The 
precipitation was performed at -20°C for 30 min. 
Then a centrifugation was carried out at 10.000 rpm 

for 10 min. The supernatant was discarded and 70% 
ethanol was added. After centrifugation at 10,000 
rpm for 5 min, the ethanol was removed. The 
precipitate was dried at ambient temperature, 
recovered in 20 μL of sterile water (Milli-Q) and 
stored at -20°C. The commercial KIT PureLink® 
Genomic DNA Kits (Invitrogen Corp., Carlsbad, 
CA, USA) were tested and the DNA extraction of 
the nematodes was performed as described in the 
protocol provided by the manufacturer. 

The oligonucleotides used in this 
experiment were developed by Toyota et al., (2008), 
RKNf- (5'GCT GGT GTC TAA GTG TTG CTG 
ATA C-3') and RKNr-(5'GAG CCT AGT GAT 
CCA CGA TAA G-3') which has an amplification 
product of 185 bp. The qPCR was performed in 
StepOnePlus ™ Real-Time PCR System device 
(Life Technologies, Foster City, CA, USA) in a 
final volume of 10 μL containing 5 mL of Master 
Mix SYBR GREEN (Applied Biosystems, Carlsbad, 
CA, USA) 0.2 μL of DNA, 0.2 μM of each 
oligonucleotide primer. The reaction conditions 
were: 95°C for 10 sec; 45 cycles of 95°C for 5 sec, 
60°C for 30 sec. Reactions were performed in 
triplicates and the results of the amplification curve 
and threshold cycle values (CT) were analyzed. 
 
RESULTS  

 
In the qPCR analysis it was observed that 

the reaction efficiency of amplification with the 
oligonucleotides proposed by Toyota et al. (2008), 
obtained from the calibration curve with DNA 
patterns, it was 110% and with a slope value of -
3.108 (Figure 1). These values are found within the 
range of -3.1 to -3.6 with 90-110% efficiency, 
which is considered to be a tolerable limit for the 
oligonucleotide amplification efficiency 
(RAYMAEKERS et al., 2009), demonstrating that 
the standard curve has obtained an acceptable 
oscillation. 

The correlation coefficient (R2) of the 
standard curve was 0.98, indicating a linear relation 
between the CT value and the amount of DNA 
(Figure 1). The accuracy of the qPCR data between 
the three replicates with standard deviations ranged 
between 0.003 to 0.263. 

 



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Figure 1. Calibration curve of DNA concentration (ng.μL-1) of Meloidogyne incognita in relation to the 

threshold cycle (CT). 
 
In this study, two series of different 

dilutions were used to confirm the obtained result, 
which illustrates the sensitivity and linearity of the 
detection a wide range of DNA amount, where were 
obtained dilutions of 90 to 0.00009 ng.μL-1 of the 
DNA patterns of M. incognita (Table 1). In the 
study of François et al. (2007), was obtained a R2 of 

0.99 in a serial dilution of the DNA of 
Bursaphelenchus xylophilus (Steiner e Buhrer) 
Nickle, and obtained a dilution of 10 to 0.00001 
ng.μL-1 with quantification by TaqMan-PCR 
demonstrating high efficiency in the standard curve. 

 

 
Table 1. Confidence interval of 99% between the mean values of the CT to the quantify of the extraction with 

CTAB. 
Individuals number Mean CT Standard deviation CI (99%) - + 

1 27 2.21 1.89 24.89 28.48 
100 19 0.59 1.05 17.86 19.86 
250 17 1.56 0.74 16.33 17.73 
750 15 1.08 0.61 14.87 16.03 

 
In the comparative analysis of the 

efficiency, estimated by CT obtained in qPCR, from 
the three DNA extraction methods (CTAB, Phenol: 
Chloroform and the PureLink® Genomic DNA Kits 
used from a sample of 100 nematodes (Figure 2) it 
was observed that the obtained results by CTAB 
method and commercial kit were with close CT 
values. Were observed low variations in CT values 
in samples extracted by the three methods, in the 
range of 100 individuals, these values were between 
18 and 23 (Figure 2). The CT mean with the CTAB 
method was 18 and the extracted samples with 
Phenol: Chloroform was 19 for 100 nematodes and 
with a standard deviation of 0.58 for the repetitions. 

The obtained CIs for the amount of 100 
nematodes (Table 1), with the method of extraction 
by CTAB was between 17.86 to 19.86 corroborating 
the data obtained by François et al. (2007) for 
Bursaphelenchus xylophilus (BERRY Et al., 2008) 
for M. javanica, P. zeae and Xiphinema elongatum,  
(TOYOTA et al., 2008) for M. incognita 
(MOKRINI et al., 2013) and for P. penetrans, who 
obtained values of 15-20, 17-20, 20-21 and 24.4, 
respectively, however Mokrini et al., (2013) worked 

with an amount of 80 nematodes. In all the cases, 
the CT values are close even when submitted to 
different methods of DNA extraction and different 
species of nematodes, confirming the accuracy of 
this analysis. 

Based on the obtained results, the extraction 
method with CTAB was chosen for DNA extraction 
of ranges 1, 10, 25, 100, 250, 500 and 750 
nematodes. The qPCR data had demonstrated a 97% 
amplification efficiency (Figure 3), being the R2 
value = 0.93. The standard deviations between the 
repetitions of the triplicates of each analysis range 
were between 0.58 and 3.2.  
The mean CT data for the calculation of the 
confidence interval CI (Table 1) were validated with 
different random samples of the field, initially 
counted under an optical microscope and then made 
the DNA extraction of these samples and quantified 
by qPCR, being all the CTs obtained suitable to the 
established ranges by the initial count. The 
validation with field samples is important to 
demonstrate the reliability and accuracy of the used 
method. 



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Figure 2. Comparison between the CT means of the field samples obtained with different methods of DNA 

extraction (CTAB, phenol: chloroform and PureLink® Genomic DNA Kit).  
 
 
 

 
Figure 3. Amplification curve of the separated samples by amounts and extracted with CTAB. 
 
DISCUSSION 

 
As in the study of Mokrini et al. (2013), a 

serial dilution from P. penetrans DNA resulted in a 
standard curve which shows a highly significant 
linearity between CT values and dilution rate (R2 = 
0.99; slope = -3.23; E = 104 %). The tests of 
Mokrini et al. (2013) showed a high correlation 
between the real numbers of nematodes and 
detected numbers by the qPCR. Studies have shown 
that a linear regression of CT values against the 
logarithm of the DNA concentration to potato cyst 
nematode (MADANI et al., 2007, 2008) and 
Meloidogyne spp. (TOYOTA et al., 2008). In these 
studies, serial dilutions of DNA were used as a 
model to generate a standard curve to evaluate the 
correlation between the mean CT and the estimate 
of the microscopic counts of the individual number 
in each sample.  

In the comparative analysis of the 
efficiency, estimated by CT obtained in qPCR, from 
the three DNA extraction methods (Figure 2) the 
results showed differents from the observed in the 
study of Zhao et al. (2010), in which comparison 
was made of different concentrations Triton X-100 
method, which obtained with the comparison of the 

field analysis of samples containing 1 to 200 
individuals a standard curve with low efficiency. 
These same authors have reported an 
underestimation of the nematodes number of 45%, 
wherein the slope was 0.5521, R2 = 0.7154. In 
contrast, using the CT value there was an 
overestimation which was shown by Toyota et al. 
(2008) where the slope was 1.515 and the R2 = 
0.9391. 

In the present study was observed that in 
samples with large amounts of nematodes, above 
750 individuals, the DNA was not extracted 
efficiently and consequently varies in relation to the 
sample, and thus do not present linearity with other 
data. This confirms the study of Zhao et al. (2010), 
where the sample with 1000 individuals did not 
show linearity as all other samples for the CT 
values. This suggests that the maximum number of 
nematodes must be lower than 1000 individuals in 
obtaining a good quality of the standard curve. 
According to the same authors, the same volume of 
lysis solution used for an individual was also 
applied in 1000 individuals, which can be carried 
more proteins and/or lipids in the sample containing 
1000 individuals, which may have negatively 
affected the result of the PCR in real time. In the 



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Development of quantitative…  OLIVEIRA, C. M. et al. 

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http://dx.doi.org/10.14393/BJ-v36n1a2020-42265 

study of Mokrini et al. (2013), the used DNA 
extraction method was stable and able to extract 
DNA from up to 80 individuals. However, five 
individuals were the maximum number of 
nematodes suggested to be used in the DNA 
extraction method, as described by Holterman et al. 
(2006).  

In addition to the difficulties in the DNA 
extraction of the nematodes, we have in the 
Meloidogyne genus, that the number of cells has an 
increase during the different stages of their 
development. This data for this analysis does not 
have a great influence on the estimating of the 
number of nematodes in a field sample because the 
degree of precision required for agronomic and 
ecological studies will be much determined by 
factors such as a good sampling and an efficient 
extraction (MOKRINI et al., 2013). This result was 
confirmed in our research, since in the same sample 
had nematodes in different stages of development, 
since the goal was to have a greater approximation 
of the conditions found in the field, because in 
routine analysis of different life stages of these 
nematodes are not processed in conjunction, 
considering the most frequently used extraction 
methods. 

The qPCR is gaining approval for the 
detection of pathogens. This method combines the 
amplification and detection steps in a single reaction 
in a closed tube, which minimizes the risk of sample 
contamination (WONG; MEDRANO, 2005). The 
advantages of using the qPCR in general  are: 
possibility of quantitative detection of pathogens, 
potential for the use in a high number of samples 

and the absence of the need for post-PCR analysis, 
besides the rapidly of obtaining the data (≤ 1 to 2 h) 
(SCHAAD et al., 2002; DE BOER; WARD, 2007). 

These results demonstrate the potential of 
this essay to provide a rapid, accurate and sensitive 
identification and molecular quantification of the 
root-knot nematode. The methodology for 
quantifying nematodes by qPCR presents an option 
that may in the future include other species of 
economic importance. The qPCR does not require 
experience in the taxonomy and morphology of 
nematodes, and can be used as a tool for quick 
diagnosis in the research and also in diagnostic 
laboratories and extension services to indicating the 
correct pest management. 

 
CONCLUSIONS 
 

The CTAB method (ZOLAN; PUKILLA, 
1986) has proved to be the more indicated for M. 
incognita DNA extraction compared with the 
commercial KIT (PureLink® Genomic DNA Kits 
(Invitrogen Corp., Carlsbad, CA, USA) and the 
method of Phenol: Chloroform (RANDIG et al., 
2002).  

It is possible to quantify M. incognita from 
soil and roots samples by PCR in real time. 

 
ACKNOWLEDGMENT 

 
The authors thank to Fundação de Amparo à 

Pesquisa do Estado de Goiás (Fapeg) for the 
financial support given to this research. 

 
 

 
RESUMO: Os nematoides-das-galhas (Meloidogyne spp.) é o gênero de fitonematoide mais 

importante, são os patógenos mais comuns e destrutivos deste grupo. Eles produzem alguns dos sintomas mais 
drásticos nas plantas e podem reduzir significativamente o rendimento das culturas. Para conseguir implantar 
um método eficiente de manejo de nematoides parasitas de plantas, é necessária a identificação e quantificação 
precisa e confiável dos fitonematoides. O objetivo deste estudo foi analisar amostras em qPCR para detectar e 
quantificar M. incognita, em amostras de campo, comparando diferentes métodos de extração do DNA e sua 
eficácia no estabelecimento do número de indivíduos. Para este propósito, a eficácia de diferentes métodos de 
extração de DNA foi comparada através dos valores dos intervalos de Ct. Para comparações padrão de curvas e 
métodos, usamos nematoides multiplicados em casa de vegetação e cuidadosamente separados nas quantidades 
específicas dos experimentos. Para o número de indivíduos, foram utilizadas amostras de campo previamente 
contadas sob um microscópio óptico. A extração de DNA foi realizada a partir de 100 nematoides, pelos 
métodos: CTAB, Phenol: Clorofórmio e kit comercial (PureLink® Genomic DNA Kit, Invitrogen). Na análise 
comparativa utilizando os três métodos de extração de DNA a partir de 100 nematoides, observou-se que o kit 
comercial e os métodos de CTAB obtiveram valores de CT semelhantes. O método de extração CTAB 
apresentou menor variação nas repetições e maior linearidade da curva padrão em comparação com os demais 
métodos testados. O coeficiente de correlação (R2) da curva padrão foi de 0,98 indicando uma relação linear 
entre o valor de Ct e a quantidade de padrões de DNA variando de 90 a 0,00009 ng.μL-1. Assim, foi possível 
quantificar as amostras através dos intervalos de valores de CT, estabelecidos a partir de diferentes números de 
indivíduos (1, 10, 25, 100, 250, 500 e 750), em amostras de campo. Este estudo demonstrou que a técnica de 



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Development of quantitative…  OLIVEIRA, C. M. et al. 

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http://dx.doi.org/10.14393/BJ-v36n1a2020-42265 

qPCR é uma alternativa sensível e confiável para a quantificação de M. incognita, para apoiar laboratórios de 
diagnóstico e levantamentos de campo. 
 

PALAVRAS-CHAVE: Diagnose. Monitoramento. Nematoide das galhas. Técnica. 
 
 
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