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1188 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 4, p. 1188-1197, July/Aug. 2019 
http://dx.doi.org/10.14393/BJ-v35n4a2019-42190 

PRESERVATION AND MACERATION OF AMAZON AÇAI LEAFLET 
TISSUE TO OBTAIN GENOMIC DNA 

 
PRESERVAÇÃO E MACERAÇÃO DE TECIDO DE FOLÍOLOS DE AÇAÍ DA 

AMAZÔNIA PARA OBTENÇÃO DE DNA GENÔMICO 
 

Hellen Sandra Freires da Silva AZÊVEDO1; Polinar Bandeira RUFINO2;  
José Marlo Araújo de AZEVEDO3; Luciélio Manoel da SILVA4;  

Lúcia Helena de Oliveira WADT5; Tatiana de CAMPOS6 
1. Doutoranda em Biodiversidade e Biotecnologia – Fundação Oswaldo Cruz – FIOCRUZ, Rede Bionorte, Porto Velho, RO, Brasil, 

hellenfreires@gmail.com; 2. Graduada em Biomedicina – Faculdade Meta – FAMETA, Rio Branco, AC, Brasil.; 3. Professor, Doutor, 
Instituto Federal do Acre – IFAC, Cruzeiro do Sul, AC, Brasil.; 4. Analista da Empresa Brasileira de Pesquisa Agropecuária – Embrapa 

Acre, Rio Branco, AC, Brazil.; 5. Pesquisadora, Doutora, Empresa Brasileira de Pesquisa Agropecuária – Embrapa Rondônia, Porto 
Velho, RO, Brasil.; 6. Pesquisadora, Doutora, Empresa Brasileira de Pesquisa Agropecuária – Embrapa 

Acre, Rio Branco, AC, Brasil, tatiana.campos@embrapa.br. 
 

ABSTRACT: The objective of this study was to test the efficiency of preservation and maceration 
methods for Euterpe precatoria leaflet tissue to obtain genomic DNA for molecular studies. The leaflets of E. 
precatoria were collected in an experimental field at Embrapa Acre, Brazil. The study was conducted in a 
completely randomized design with 10 replicates, in a 12 × 2 factorial structure, with 12 storage treatments 
(fresh; lyophiliser 3 days; refrigerator 3, 5, and 7 days; silica gel 7, 10, 20, and 30 days; and transport buffer 3, 
5, and 7 days) and two leaf tissue maceration methods (liquid nitrogen and the TissueLyser®). Statistically 
significant differences in the obtained DNA concentration were found between the maceration and storage 
treatments. The TissueLyser® macerator produced higher DNA concentrations when compared to liquid 
nitrogen. For the storage treatments, five groups were formed based on DNA concentration when macerated 
with the TissueLyser® and two groups when macerated with liquid nitrogen. The DNA concentrations ranged 
from 285.00 ng/µ L (7 days in transport buffer) to 702.00 ng/µ L (30 days in silica gel) when the leaflets were 
macerated with liquid nitrogen, and from 572.73 ng/µ L (30 days in silica gel) to 2,850.00 ng/µ L (3 days in 
lyophiliser) using the TissueLyser® macerator. The DNA purity (A260/A280 nm) varied from 1.30 to 1.70 
when the leaflets were macerated with liquid nitrogen and from 1.30 to 1.90 with the TissueLyser® macerator. 
Despite the variations in leaf tissue preservation and DNA concentration, all treatments were effective for DNA 
isolation and it was possible to amplify genomic regions of microsatellite markers by PCR. It was concluded 
that leaflets of E. precatoria stored in a lyophiliser and processed with an automatic macerator resulted in 
satisfactory DNA for molecular studies. 
 

KEYWORDS: Açaí-solteiro. CTAB method. DNA isolation. Euterpe precatoria. 
 
INTRODUCTION 

 
The açaizeiro (Euterpe precatoria Mart.), 

popularly known as açaí-solteiro or açaí-do-
amazonas, is a single-stemmed palm tree belonging 
to the family Arecaceae. It is found naturally in the 
northern region of Brazil, in the states of Acre, 
Rondônia, Amazonas, and Pará. It occurs as solitary 
stems in large populations with different density 
levels in flooded and dryland areas (BUSSMANN; 
ZAMBRANA, 2012).  

The E. precatoria species has multiple uses 
including palm heart extraction, production of bio-
jewellery, and use in medicine. The most utilised 
part is the mesocarp, from which a thick liquid 
known as "açaí juice" is extracted. This liquid is 
very nutritious and has a high calorific value 

(YUYAMA et al., 2011). It is widely consumed in 
the Brazilian Amazon within all socioeconomic 
levels of the population. In the international market, 
it has been highly regarded for its nutritional 
qualities, being rich in phenolic compounds, 
anthocyanins, and substances with high antioxidant 
elements (YAMAGUCHI et al., 2015). Despite its 
importance, the exploitation of E. precatoria is still 
extractivism-based. 

For this reason, genetic analyses are of great 
importance since they can increase knowledge of 
the diversity, genetic structure, and crossing rate of 
natural populations. Molecular markers are useful 
tools to define appropriate conservation and 
management strategies, and to inform the collection 
of germplasm for use in breeding programs 
(SARTORETTO; FARIAS, 2010). 

Received: 09/05/18 
Accepted: 05/12/18 



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The method of tissue maceration may affect 
the quality of the DNA obtained and most studies 
use liquid nitrogen or automatic macerators. 
However, liquid nitrogen is not always easily 
accessible because its transport involves the risk of 
explosion, it must be stored in special containers, 
and it is expensive. These factors limit the routine 
use of liquid nitrogen in many laboratories, 
including those located in the Amazon. Several 
studies have investigated alternative methods to 
macerate leaflets, especially in fibrous palms 
(IBRAHIM et al., 2010; IHASE et al., 2016). 
Ibrahim et al. (2010) used sterilized sand with buffer 
to macerate mature leaves of date palm (Phoenix 
dactylifera). Ihase et al. (2016) macerated leaves of 
oil palm (Elaeis guineensis) in a crucible with 
buffer. Both studies were successful in extracting 
DNA. 

We are not aware of any previous studies of 
the storage and maceration of leaflet tissue in E. 
precatoria. The development of simpler and cheaper 
alternative methods to obtain DNA of sufficient 
quantity and quality is essential for molecular 
studies. The objective of this study was to test the 
efficiency of various preservation and maceration 
methods on E. precatoria leaflet tissue to obtain 
genomic DNA for molecular studies. 
 
MATERIAL AND METHODS 

 
To evaluate different methods of storage 

and maceration, mature leaflets were collected from 
an experimental field at Embrapa Acre, Rio Branco, 
AC, Brazil. The study was conducted in a 
completely randomized design with 10 replicates, in 
a 12 × 2 factorial design, with 12 storage treatments 
(fresh; lyophiliser 3 days; refrigerator 3, 5, and 7 
days; silica gel 7, 10, 20, and 30 days; and transport 
buffer 3, 5, and 7 days) and two leaf tissue 
maceration methods (liquid nitrogen and 
TissueLyser®). 

For the silica gel treatments, silica gel was 
used to dehydrate the leaflets over four different 
periods (7, 10, 20, and 30 days). The samples were 
stored in a plastic bag and kept out of the light at an 
average temperature of 27 °C. The silica gel was 
replaced as necessary according to the saturation 
indicator. Fresh leaflets were stored in microtubes 
and cooled with ice. In the lyophiliser treatment, 
leaflets were dehydrated in a lyophiliser (Terroni 
Enterprise II) for 72 h. 

The six remaining treatments were stored in 
a refrigerator: leaflets wrapped in newspaper 
changed daily and stored in plastic bags for 3, 5, and 
7 days; and leaflets stored for 3, 5, and 7 days in 

microtubes containing 1 mL of transport buffer (300 
μl of CTAB 2% buffer; 700 μl of absolute ethanol). 

Leaf tissues subjected to the twelve storage 
treatments were macerated using two methods: I) 
Mechanical maceration (TissueLyser®, Qiagen): the 
leaflets were cut into small pieces with scissors and 
placed in Eppendorf tubes containing two stainless 
steel spheres and 2% CTAB, then the microtubes 
were packed in the TissueLyser® machine; II) 
Maceration with liquid nitrogen: the leaflets were 
placed in a porcelain mortar, then macerated with 
liquid nitrogen using a pestle until a fine powder 
was obtained, then transferred to microtube 
containing 2% CTAB. 

Total genomic DNA was extracted 
following the protocol described by Doyle and 
Doyle (1990), using 100 mg of leaf tissue for each 
treatment. After maceration using one of the 
methods described above, the samples were 
incubated for 60 minutes in a water bath at 65 °C 
with 700 μL of preheated extraction buffer 
containing 698.6 μL of 2% CTAB solution and 1.4 
μL of β-mercaptoethanol. During the incubation 
procedure, the microtubes were manually stirred 
every 10 minutes for homogenisation. Following 
incubation, the microtubes were removed from the 
water bath and cooled to room temperature. In the 
fume cupboard, 600 μL of chloroform and isoamyl 
alcohol (24:1) was added, and the microtubes were 
manually stirred for 5 minutes. 

Centrifugation was performed at 13,000 rpm 
for 15 minutes. The upper (aqueous) phase was 
transferred (160 μL) to a new microtube. Then, 400 
μL of cold isopropanol (-20 °C) was added, and the 
samples were incubated at -20 °C for 30 minutes. 

The microtubes were centrifuged at 13,000 
rpm for 15 minutes, and the supernatant was 
discarded. The pellets were washed twice in 300 μL 
of absolute ethanol and twice in 70% ethanol by 
centrifugation at 13,000 rpm for 5 and 10 minutes, 
respectively. The pellets were then resuspended in 
50 μL of TE buffer (10 mM Tris-HCl, pH 8.0; 1 
mM EDTA), then incubated at 37 °C in an air 
forced circulation oven for 1 hour, and then stored 
in the refrigerator. 

Subsequently, the samples were 
electrophoresed on a 0.8% agarose gel (0.5X TBE 
buffer under 120 volts and 400 milli-amperes for 1 
hour) to check DNA integrity. DNA purity indices 
were quantified in an 8000A spectrophotometer 
(Metash) and the ratio of A260/A280 was used to 
estimate the purity of the DNA (GREEN; 
SAMBROOK, 2012). 

The DNA was quantified in a 
spectrophotometer at 260 nm wavelength. The 



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concentration of DNA was estimated from the 
equation: DNA concentration (ng) = OD reading 
(Optical Density) 260 × 50 × dilution factor 
(SAMBROOCK et al., 1989). 

To evaluate the DNA quality, polymerase 
chain reaction was used. Nine microsatellite 
markers (EE2, EE8, EE23, EE32, EE45, EE47, 
EE52, EE52 and EE59) developed for E. edulis 
(Gaiotto et al., 2001) were used. Reactions were 
made containing the following: 5 ng of genomic 
DNA; 10 mM Tris-HCl, 50 mM KCl; 0.25 mM of 
each dNTP; 0.25 mg/mL BSA (Bovine Serum 
Albumin); 2.0 mM MgCl2; 0.2 μM of each primer; 
and 1 U of Taq DNA polymerase and sterile 
ultrapure water. Amplifications were performed in a 
thermocycler (Analitik Jena). The samples were 
submitted to the following amplification steps: 94°C 
for 1 minute, followed by 30 cycles at 94°C for 1 
minute, annealing temperature set for each primer 
for 1 minute and 72°C for 1 minute, followed by a 
final extension step at 72°C for 5 minutes. 

The estimates of DNA concentrations for 
the different treatments were subjected to analysis 
of variance (ANOVA) and, when significant 
differences were observed, the means were grouped 

by the Scott-Knott test at the 1% significance level. 
The analysis was performed using the statistical 
package SISVAR (FERREIRA, 2011).  

 
RESULTS AND DISCUSSION 

 
The general appearance of E. precatoria 

leaflets varied among the different storage methods 
(Figure 1). The leaflets kept in the refrigerator (3 to 
5 days) and transport buffer (3, 5, and 7 days) 
displayed excellent preservation. These treatments 
remained similar in appearance and characteristics 
to the fresh leaflets (Figure 1A) and did not suffer 
any changes in leaf tissue. All treatments in 
transport buffer presented leaf turgidity similar to 
that of fresh tissue. 

In contrast, the treatments maintained in the 
lyophiliser (3 days), refrigerator (7 days), and silica 
gel (7, 10, 20, and 30 days) showed changes in leaf 
tissue (Figure 1B and 1C). The leaflets stored in the 
lyophiliser (3 days) presented a completely 
dehydrated visual appearance and light green 
colour. The leaflets kept in the refrigerator (7 days) 
showed partially dehydrated tissue and the same 
light green colouration. 

 

 
Figure 1. Euterpe precatoria leaflets in different storage treatments: A) Fresh leaflets, B) Refrigerator (7 days), 

and C) Silica gel (30 days). 
 
Leaflets stored in silica gel were gradually 

dehydrated as the colour indicator changed. The loss 
of water was more noticeable in the first three days. 
A gradual uniform bleaching also occurred in the 
leaflets with deterioration in some parts (Figure 1C). 
The use of silica for storage is still viable since 
unaffected parts of the leaflets may be used for 
subsequent DNA extraction. The changes in colour 
in the leaf tissue are related to the chlorophyll loss 

resulting from a period of preservation and 
dehydration. Chlorophyll pigments are relatively 
unstable and sensitive to light, time, heating, 
oxygen, and chemical degradation (SCHIOZER; 
BARATA, 2007). 

Our results corroborate those reported in the 
literature for some species of plants where the use of 
fresh, frozen, and cooled leaf tissue have been the 
predominant methodologies for preservation of 



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biological material for subsequent genomic DNA 
extraction (SILVA et al., 2010; MESQUITA et al., 
2015). In the present study, storage of leaflets in 
transport buffer for one week also proved to be a 
viable methodology for the preservation of plant 
tissue, since these leaflets retained the 
characteristics of fresh leaflets. 

Despite producing colour alteration in plant 
tissue, the silica gel method has been commonly 
used in the preservation of leaf samples of palm 
species such as “tucumanzeiro” (A. aculeatum), 
“açaizeiro” (E. oleracea), and “jauari” (A. jauari) 
(MILANI et al., 2009; OLIVEIRA et al., 2010; 
OLIVEIRA et al., 2014). The silica gel storage 
method has several advantages over other methods, 
owing to its simplicity, low cost, and the minimal 
space required for transport and storage in the 
laboratory. 

However, for Neotropical savanna species, 
the use of silica gel was not recommended for 
preservation of leaves prior to DNA extraction 
(FERES et al., 2005). However, these authors report 
that environmental conditions could have activated 
dehydration mechanisms in these plants and suggest 
that the silica gel preservation method may still be 
effective for other species (FERES et al., 2005). E. 
precatoria occurs in a different environment with 
high humidity.  

In the present study, variation in the 
integrity of extracted DNA was observed among 

treatments. All liquid nitrogen treatments presented 
better DNA integrity than that observed in the 
TissueLyser® treatments. The liquid nitrogen 
treatment samples clearly exhibited defined 
fragments on the gel, without smears, indicating that 
DNA degradation had not occurred. Danner et al. 
(2011) also obtained good quality DNA from 
“jabuticabeira” (Plinia cauliflora) tree leaves when 
macerated with liquid nitrogen whereas they 
detected degradation in samples macerated directly 
in CTAB buffer. The use of liquid nitrogen to 
macerate leaf tissue is advantageous because it 
allows rapid freezing and as a result, it avoids DNA 
degradation (DANNER et al., 2011). However, 
attainment, cost, and storage are the obstacles for its 
use in many laboratories (IBRAHIM et al., 2010; 
IHASE et al., 2016), such as those located in the 
Amazon. 

Samples macerated in the TissueLyser® 
presented DNA oxidation (Figure 2A). During the 
steps of DNA precipitation with cooled isopropanol 
and pellet formation by centrifugation, a dark brown 
colouration was observed in the samples macerated 
with the TissueLyser®, while the samples 
macerated with liquid nitrogen were clean and 
translucent (Figure 2B). The formation of dark DNA 
precipitates may occur due to the covalent 
attachment of oxidized polyphenols to the DNA 
(PETERSON et al., 1997). 

 

 
 

Figure 2. A) Comparative centrifugation profile of E. precatoria leaflets macerated and washed with 
chloroform and isoamyl alcohol: (I) macerated with liquid nitrogen, and (II) an oxidized sample 
obtained from TissueLyser® process. B) (I) lighter pellet produced from maceration with liquid 
nitrogen, in contrast to (II) darker pellet resulting from TissueLyser® maceration. 

 
The DNA purity ranged from 1.30 to 1.70 

when treatments were macerated with liquid 
nitrogen and from 1.30 to 1.90 when macerated with 
the TissueLyser® (Figure 3).  

 
 
 



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Figure 3. Analysis of purity of DNA extracted from E. precatoria leaflets from twelve types of storage and two 
maceration methods (liquid nitrogen and TissueLyser®). 

 
The absence of RNA was observed in all 

samples. According to Green and Sambrook (2012), 
the recommended range for absorbance ratios 
(A260/A280) is 1.70 to 2.00 indicating pure DNA. 
The low purity of DNA (A260/A280<1.7) observed 
in the present study for some storage and maceration 
treatments may have been due to the contaminants 
released during cell lysis, or an insufficient number 
of chloroform washes. Mature leaflets have varying 
levels of polysaccharides, polyphenols, and other 
secondary metabolites that represent the main 
obstacles encountered in the purification of plant 
DNA, and require adaptations to the DNA 
extraction procedure (SILVA et al., 2010; SIKA et 
al., 2015). 

Previous studies have confirmed that palm 
species (Elaeis guineensis, Phoenix dactylifera, 
Dypsis madagascariensis) that grow in tropical 
regions have leaves with a waxy cuticle and high 
fibre content that are rich in polysaccharides and 
polyphenols (ANGELES et al., 2005). It is known 
that the presence of such compounds may reduce or 
even inhibit the activity of DNA polymerases and 
restriction enzymes. The presence of these 
compounds in large amounts is the main issue found 
in the purification of genomic DNA from plant 
tissues (NUNES et al., 2011, SIKA et al., 2015). 

In general, the use of young leaves is 
recommended to obtain DNA with higher purity, 
since these only contain low concentrations of 
phenolic compounds (MITTON et al., 1979). 
However, adult individuals of E. precatoria may 
reach up to 20 m in height and the youngest leaflets 
are at the top of the plant (YAMAGUCHI et al., 
2015). Therefore testing of methodologies and 
refinement of protocols is fundamental, especially 
when using molecular techniques, since the quality 
of genomic DNA is crucial. 

A significant difference in the DNA 
concentration obtained was observed between the 
storage interaction and the maceration type, with the 
unfolding of direct and inverse interactions (Table 
1). 

When the maceration method was analysed 
independently of the storage method, the 
TissueLyser® macerator produced higher 
concentrations of DNA when compared to liquid 
nitrogen. With TissueLyser® maceration, five 
distinct groups of storage methods were observed 
based on DNA concentration. However, when using 
liquid nitrogen maceration, only two groups were 
observed. 

 

 



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Table 1. Unfolding averages of interactions between DNA concentrations extracted from Euterpe precatoria 
leaflets using different storage and maceration methods. 

Conservation and storage types Maceration method  (ng/µ L) 
Treatments  Liquid nitrogen TissueLyser® 

Fresh leaflets 545.00 *Ba 1912.50 Ab 
Lyophiliser (3days) 660.00 Ba 2850.00 Aa 
Refrigerator (3 days) 512.50 Aa 705.00 Ae 
Refrigerator (5 days) 543.90 Ba 1100.00 Ad 
Refrigerator (7 days) 600.00 Ba 1705.00 Ab 
Silica gel (7 days) 362.50 Bb 1652.50 Ab 
Silica gel (10 days) 685.00 Ba 1395.00 Ac  
Silica gel (20 days) 537.50 Ba 955.56 Ad 
Silica gel (30 days) 702.50 Aa 572.73 Ae 
Transport buffer (3 days) 327.50 Bb 1602.50 Ab 
Transport buffer (5 days) 450.00 Bb 827.50 Ae 
Transport buffer (7 days) 285.00 Bb 1662.50 Ab 
**CV (%) 29.64 

*Means followed by the same letter are not statistically different from each other according to the Scott-Knott test (p≥0.01). 
**Coefficient of variation (CV). 
 

For the treatments involving TissueLyser® 
maceration, the leaflets stored in the lyophiliser (3 
days) showed the highest DNA concentration, 
followed by fresh leaflets, refrigerator (7 days), then 
silica gel (7 days) and transport buffer (3 and 7 
days) which did not differ statistically. Lower DNA 
concentrations were observed for storage in the 
refrigerator (3 days), silica gel (30 days), and 
transport buffer (5 days). 

The lyophilisation methodology with 
TissueLyser® maceration presented the highest 
DNA concentration when compared to other 
methods of organic matter drying. The main 
advantage of lyophilisation is the reduction of the 
water content in the tissues and, consequently, the 
reduction of catabolic processes in the cells, since a 
less fluid environment decreases the catalytic 
activity of nucleases and proteases (NUNES et al., 
2011). Lyophilised leaf tissues allow better 
interaction between the extraction buffer and the dry 
tissue. With less fluid in the tissue, there is less 
dilution of the extraction buffer and therefore its 
activity is improved (NUNES et al., 2011). The use 
of dehydrated tissue facilitates the disruption of the 
cell walls and consequently produces higher yields 
of DNA. Although the entire lyophilisation process 
requires about 72 hours for complete leaflet 
dehydration, its applicability is certainly satisfactory 
(NUNES et al., 2011; PEDRAL et al., 2015). 

Mazza and Bittencout (2000) obtained DNA 
of good quality and quantity extracted from 
lyophilised Araucaria angustifolia. These authors 
claim that the use of a lyophiliser eliminated the 

need for liquid nitrogen during maceration. The 
results of another study showed that the 
combination of lyophilisation with PVP improves 
the quality and quantity of extracted DNA (NUNES 
et al., 2011). 

In the present study, all TissueLyser® 
macerated treatments presented higher 
concentrations of DNA (572.73 to 2,850.00 ng/μL) 
when compared to those macerated with liquid 
nitrogen and this can be explained by the 
characteristics of the equipment. Stirring at a high 
speed together with stainless steel spheres facilitates 
the disruption of the cell walls and, as a result, more 
cells are broken to release DNA molecules 
compared with liquid nitrogen maceration. This is 
corroborated by the high DNA concentration 
observed when the lyophiliser treatment was 
combined with TissueLyser® maceration. The 
tissue dehydration, the use of stainless steel spheres, 
and the higher agitation and velocity were 
determining factors in the higher yield of DNA 
obtained. Another advantage of the TissueLyser® 
equipment is the ability to macerate 48 samples at 
once, while with liquid nitrogen only one sample is 
macerated at a time. 

The treatments using the lyophiliser (3 
days), refrigerator (3, 5, and 7 days), silica gel (10, 
20, and 30 days), and fresh leaflets macerated with 
liquid nitrogen produced the highest concentrations 
of DNA. The silica gel treatments (7 days) and all 
transport buffer treatments produced the lowest 
DNA concentrations. 



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The DNA concentrations obtained from the 
silica gel treatments (10, 20, and 30 days) were the 
same as those for the fresh and lyophilised leaflet 
samples, although the silica gel treatments did not 
produce satisfactory tissue preservation. The 
concentration of DNA extracted from Elaeis 
guineensis was similar to that found in the present 
study when using liquid nitrogen to macerate the 
leaf tissue, with concentrations ranging from 496.00 
to 572.00 ng/μL (IHASE et al., 2016). The 
concentrations of DNA extracted from E. oleraceae 
ranged from 40.00 to 313.00 ng/μL when extracted 
from fresh leaves, kept frozen with ice, and 
macerated with liquid nitrogen (COSTA; 
OLIVEIRA 2002). 

All the storage and maceration treatments 
resulted in positive PCR amplification (Figure 4) 
and therefore provided satisfactory genetic material 
for molecular analyses. The optimal annealing 
temperature varied among the evaluated loci (Table 
2). Loci EE41 and EE47 had the lowest annealing 
temperature (45.8 °C), and locus EE45 had the 
highest annealing temperature (57.3 °C). The results 
also confirmed the transferability of loci from E. 
edulis to E. precatoria (AZÊVEDO et al., 2017). 
These results indicated that DNA extracted from 
leaflets of E. precatoria did not contain 
contaminants such as polysaccharides and 
secondary metabolites, which could affect DNA 
quality (SIKA et al., 2015). 

 

 
 

Figure 4. Agarose gel electrophoresis of Euterpe precatoria DNA amplified with microsatellite locus EE8. 
Lanes 1–12: twelve storage treatments macerated with TissueLyser® automatic equipment; Lane 
13: label (1 kb Fermentas®); Lanes 14–25: twelve storage treatments macerated with liquid 
nitrogen. 

 
Table 2. Characteristics of nine heterologous microsatellite markers for Euterpe precatoria. 

Loci TA (ºC) 
 

Fragment size (bp) 
 

GenBank 

EE2 55.4 87-90 AF328879 
EE8 50.2 122-143 AF328872 

EE32 55.4 190-195 AF328883 
EE41 45.8 107-122 AF328884 
EE45 57.3 109-110 AF328887 
EE47 45.8 255-270 AF328874 
EE52 53.6 205-210 AF328888 
EE54 50.2 120-124 AF328876 
EE59 50.2 108-120 AF328885 

TA (°C): Annealing temperature; bp: Base pairs. 
 
Several methodologies for plant DNA 

isolation are available. However, modifications are 
necessary according to the peculiarities of each 
species. For the species E. precatoria, the tests of 
storage and maceration of mature foliar tissue were 
important because they provide options for further 
studies to use simple and low-cost techniques for 
extraction of DNA of sufficient quality for use in 
genetic analyses.  

 
ACKNOWLEDGEMENTS 
 

This work was supported by grants from 
Embrapa Acre. The authors thank Coordenação de 
Aperfeiçoamento de Pessoal de Nível Superior 
(CAPES) for granting doctorate scholarships and 
also the colleague Eduardo Soares for the 
collaboration in the layout of the figures. 

 
 
 



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RESUMO: O objetivo deste estudo foi testar a eficiência de métodos de preservação e maceração de 

tecidos de folíolos de Euterpe precatoria para obter DNA genômico para estudos moleculares. Os folíolos de E. 
precatoria foram coletados no campo experimental da Embrapa Acre, Brasil. O estudo foi conduzido em 
delineamento inteiramente casualizado com 10 repetições, em esquema fatorial 12 × 2, com 12 tratamentos de 
armazenamento (fresco; liofilizado 3 dias; geladeira 3, 5, e 7; sílica gel 7, 10, 20 e 30 dias e tampão de 
transporte 3, 5 e 7 dias) e dois tipos de maceração do tecido foliar (nitrogênio líquido e TissueLyser®). Para a 
variável concentração de DNA houve diferença estatística entre os tipos maceração e de armazenamento. O 
macerador TissueLyser® apresentou maiores concentrações de DNA quando comparado ao nitrogênio líquido. 
Para os tipos de armazenamento verificou-se formação de cinco grupos quando macerados TissueLyser® e dois 
grupos quando macerados com nitrogênio líquido. As concentrações de DNA variaram de 285,00 ng/µ L (7 dias 
em tampão de transporte) a 702,00 ng/µ L (30 dias em sílica gel) quando maceradas com nitrogênio líquido. 
Quando maceradas com macerador TissueLyser® variaram de 572,73 ng/µ L (30 dias em sílica gel) a 2.850,00 
ng/µ L (3 dias em liofilizador). A pureza do DNA (A260/A280 nm) variou de 1,30 a 1,70 quando os folíolos 
foram macerados com nitrogênio líquido e de 1,30 a 1,90 quando macerados em macerador TissueLyser®. 
Apesar das variações na conservação e concentração dos tecidos foliares, todos os tratamentos foram eficazes 
para o isolamento do DNA e amplificaram regiões de marcadores microssatélites. Concluiu-se que folíolos de 
E. precatoria armazenados em liofilizador e macerados com macerador automático resultaram em DNA 
satisfatório para estudos moleculares. 
 

PALAVRAS-CHAVE: Açaí-solteiro. Euterpe precatoria. Isolamento de DNA. Método CTAB. 
 
 

REFERENCES 
 
ANGELES, J. G. C.; LAURENA, A. C.; TECSON-MENDOZA, E. M. Extraction of genome DNA from lipid, 
polysaccharides, and polyphenols rich coconut (Cocos nucifera L.). Plant Molecular Biology Reporter, 
Düsseldorf, v. 23, n. 1, p. 297-298, 2005. http://dx.doi.org/10.1007/BF02772760 
 
AZÊVEDO, H. S. F. S.; BENVINDO, F. D.; CAVALCANTE, L. N.; HAVERROTH, M.; WADT, L. H. O.; 
CAMPOS, T. Transferability of heterologous microsatellite loci between species of Euterpe genus. Genetics 
and Molecular Research, Ribeirão Preto, v. 16, n. 4, p. 1-7, 2017. http://dx.doi.org/10.4238/gmr16039825 
 
BUSSMANN, R. W.; ZAMBRANA, N. Y. P. Facing global markets-usage changes in Western Amazonian 
plants: the example of Euterpe precatoria Mart. and E. oleracea Mart. Acta Societatis Botanicorum Poloniae, 
Warsaw, v. 81, n. 4, p. 257-281, 2012. http://dx.doi.org/10.5586/asbp.2012.032 
 
COSTA, M. R.; OLIVEIRA, M. S. P. Extração de DNA de açaizeiro a partir de folhas. Belém: Embrapa 
Amazônia Oriental, 2002. 22 p. (Embrapa Amazônia Oriental. Documentos, 127). 
 
DANNER, M. A.; SASSO, S. A. Z.; BITTENCOURT, J. V. M.; CITADIN, I. Proposta de protocolo para 
extração de DNA de jabuticabeira. Ciência Florestal, Santa Maria, v. 21, n. 2, p. 363-367, 2011. 
http://dx.doi.org/10.5902/198050983241 
  
DOYLE, J. J.; DOYLE, J. L. Isolation of plant DNA from fresh tissue. Focus, v. 12, n. 1, p. 13-15, 1990. 
 
FERES, F.; SOUZA, A. P.; AMARAL, M. C.; BITTRICH, V. Avaliação de métodos de preservação de 
amostras de plantas de Savanas Neotropicais para a obtenção de DNA de alta qualidade para estudos 
moleculares. Revista Brasileira de Botânica, São Paulo, v. 28, n. 2, p. 277-283, 2005. 
 
FERREIRA, D. F. Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia, Lavras, v. 35, n. 6, 
p. 1039-1042, 2011. http://dx.doi.org/10.1590/S0100-84042005000200008. 
 



1196 
Preservation and maceration...  AZÊVEDO, H. S. F. S. et al. 

Biosci. J., Uberlândia, v. 35, n. 4, p. 1188-1197, July/Aug. 2019 

GAIOTTO, F. A.; BRONDANI, R. P. V.; GRATTAPAGLIA, D. Microsatellite markers for heart of palm 
Euterpe edulis and E. oleracea Mart. (Palmae). Molecular Ecology Notes, Portland, v. 1, n. 1, p. 86-88, 2001. 
https://doi.org/10.1046/j.1471-8278.2001.00036.x 
 
GREEN, M. R.; SAMBROOK, J. Molecular cloning: a laboratory manual. New York: Cold Spring Harbor 
Laboratory, 2012. 628 p. 
 
IBRAHIM, A. A.; BAKIR, M. A.; KHAN, H. A.; AHAMED, A. A. simple method for DNA extraction from 
mature date palm leaves: impact of sand grinding and composition of lysis buffer. International Journal of 
Molecular Sciences, Fribourg, v. 11, n. 9, p. 3149-3157, 2010. https://doi.org/10.3390/ijms11093149 
 
IHASE, O. L.; HORN, R.; ANOLIEFO, G. O.; EKE, C. R. Development of a method for DNA extraction from 
oil palm leaves and the effects of pH and ionic strength on nucleic acid quantification. Journal of Biological 
Methods, Beijing, v. 3, n. 2, p. 37-42, 2016. https://doi.org/10.14440/jbm.2016.80 
 
MAZZA, M. C. M.; BITTENCOURT, J. V. M. Extração de DNA de tecido vegetal de Araucaria angustifolia 
(Araucariaceae). Boletim de Pesquisa Florestal, Colombo, n. 41, p. 12-17, 2000. 
 
MESQUITA, A. C. O.; FIGUEIRÓ, A. A.; COUTO, K. R.; OLIVEIRA, M. F. Optimization of soybean DNA 
extraction under diferente storage and development periods. Bioscience Journal, Uberlândia, v. 31, n. 4, p. 
1102-1106, 2015. http://dx.doi.org/10.14393/BJ-v31n4a2015-28343 
 
MILANI, M.; DANTAS, F. V.; MARTINS, W. F. S. Divergência genética em mamoneira por caracteres 
morfológicos e moleculares. Revista Brasileira de Oleaginosas e Fibrosas, Campina Grande, v. 13, n. 2, p. 
61-71, 2009. 
 
MITTON, J. B.; LINHART, Y. B.; STURGEON, K. B.; HAMRICK, J. L. Allozyme polymorphism detected in 
mature needle tissue of ponderosa pine. Journal of Heredity, College Station, v. 70, n. 2, p. 86-89, 1979. 
https://doi.org/10.1093/oxfordjournals.jhered.a109220 
 
NUNES, C. F.; FERREIRA, J. L.; FERNANDES, M. C. N.; BREVES, S. D. S. An improved method for 
genomic DNA extraction from strawberry leaves. Ciência Rural, Santa Maria, v. 41, n. 8, p. 1383-1389, 2011. 
http://dx.doi.org/10.1590/S0103-84782011000800014 
 
OLIVEIRA, L. D. S.; RAMOS, S. L. F.; LOPES, M. T. G.; DEQUIGIOVANNI, G.; VEASEY, E. A.; 
MACÊDO, J. L. V.; BATISTA, J. S.; FORMIGA, K. M.; LOPES, R. Genetic diversity and structure of 
Astrocaryum jauari (Mart.) palm in two Amazon river basins. Crop Breeding and Applied Biotechnology, 
Viçosa, v. 14, n. 3, p. 166-173, 2014. http://dx.doi.org/10.1590/1984-70332014v14n3a25 
  
OLIVEIRA, M. S. P.; SANTOS, J. B.; AMORIM, E. P.; FERREIRA, D. F. Variabilidade genética entre 
acessos de açaizeiro utilizando marcadores microssatélites. Ciência e Agrotecnologia, Lavras, v. 34, n. 5, p. 
1253-1260, 2010. http://dx.doi.org/10.1590/S1413-70542010000500025. 
 
PEDRAL, A. L.; BARBOSA, J. S.; SANTOS, G. R.; XAVIER, A. C. R. Caracterização físico-química de 
folhas da Moringa oleífera desidratadas por secagem convectiva e liofilização. Revista Brasileira de Produtos 
Agroindustriais, Campina Grande, v. 17, n. 1, p. 33-39, 2015. 
 
PETERSON, D. G.; BOEHM, K. S.; STACK S. M. Isolation of milligram quantities of nuclear DNA from 
tomato (Lycopersicon esculentum), a plant containing high levels of polyphenolic compounds. Plant 
Molecular Biology Reporter, Düsseldorf, v. 15, n. 2, p. 148-153, 1997. http://dx.doi.org/10.1007/BF02812265 
 
SAMBROOK, J.; FRITSCH, E. F.; MANIATIS, T. Molecular cloning: a laboratory manual. Cold New York: 
Spring Harbor Laboratory, 1989. 1546 p. 
 



1197 
Preservation and maceration...  AZÊVEDO, H. S. F. S. et al. 

Biosci. J., Uberlândia, v. 35, n. 4, p. 1188-1197, July/Aug. 2019 

SARTORETTO, L. M.; FARIAS, P. C. M. Diversidade genética e técnicas biotecnológicas. Unoesc & 
Ciências, Joaçaba, v. 1, n. 2, p. 155-162, 2010. 
 
SCHIOZER, A. L.; BARATA, L. E. S. Estabilidade de Corantes e Pigmentos de Origem Vegetal. Revista 
Fitos, Jacarepaguá, v. 3, n. 1, p. 1-19, 2007. 
SILVA, M. N. D. Extração de DNA genômico de tecidos foliares maduros de espécies nativas do cerrado. 
Revista Árvore, Viçosa, v. 34, n. 6, p. 973-978, 2010. http://dx.doi.org/10.1590/S0100-67622010000600002 
 
SIKA, K. C.; KEFELA, T.; ADOUKONOU-SAGBADJA, H.; AHOTON, L.; SAIDOU, A.; BABA-MOUSSA, 
L.; BAPTISTE, L. J. N. O.; KOTCONI, S. O.; GACHOMO, E. A simple and efficient genomic DNA 
extraction protocol for large scale genetic analyses of plant biological systems. Plant Gene, Mus, v. 1, n. 1, p. 
43-45, 2015. https://doi.org/10.1016/j.plgene.2015.03.001 
 
YAMAGUCHI, K. K. L.; PEREIRA, L. F. R.; LAMARÃO, C. V.; LIMA, E. S. Amazon acai: Chemistry and 
biological activities: A review. Food Chemistry, Norwich, v. 179, n. 15, p. 137-151, 2015. 
http://dx.doi.org/10.1016/j.foodchem.2015.01.055 
 
YUYAMA, L. K. O.; AGUIAR, J. P. L.; SILVA FILHO, D. F.; YUYAMA, K. Caracterização físico-química 
do suco de açaí de Euterpe precatoria Mart. oriundo de diferentes ecossistemas amazônicos. Acta Amazonica, 
Manaus, v. 41, n. 4, p. 545-552, 2011. http://dx.doi.org/10.1590/S0044-59672011000400011