International Journal of
Molecular Sciences
Article
Properties of Ginkgo biloba L.: Antioxidant
Characterization, Antimicrobial Activities, and
Genomic MicroRNA Based Marker Fingerprints
Katarína Ražná 1 , Zuzanna Sawinska 2 , Eva Ivanišová 3 , Nenad Vukovic 4 ,
Margarita Terentjeva 5 , Michal Stričík 6 , Przemysław Łukasz Kowalczewski 7 ,
Lucia Hlavačková 1 , Katarína Rovná 8 , Jana Žiarovská 1 and Miroslava Kačániová 9,10, *
1
2
3
4
5
6
7
8
9
10
*
Department of Plant Genetics and Breeding, Faculty of Agrobiology and Food Resources, Slovak University
of Agriculture, Tr. A. Hlinku 2, 949 76 Nitra, Slovakia; katarina.razna@uniag.sk (K.R.);
lucia.hlavackova1@gmail.com (L.H.); jana.ziarovska@uniag.sk (J.Ž.)
Department of Agronomy, Poznań University of Life Sciences, 11 Dojazd St., 60-632 Poznań, Poland;
zuzanna.sawinska@up.poznan.pl
Department of Technology and Quality of Plant Products, Faculty of Biotechnology and Food Sciences,
Slovak University of Agriculture, Tr. A. Hlinku 2, SK-94976 Nitra, Slovakia; eva.ivanisova@uniag.sk
Department of Chemistry, Faculty of Science, University of Kragujevac, P.O. Box 12, 34000 Kragujevac,
Serbia; nvchem@yahoo.com
Institute of Food and Environmental Hygiene, Faculty of Veterinary Medicine, Latvia University of Life
Sciences and Technologies, K. Helman, aiela 8, LV-3004 Jelgava, Latvia; margarita.terentjeva@llu.lv
Department of Economy, The Faculty of Business Economics, University of Economics in Bratislava,
852 35 Košice, Slovakia; michal.stricik@euke.sk
Institute of Food Technology of Plant Origin, Poznań University of Life Sciences, 31 Wojska Polskiego St.,
60-624 Poznań, Poland; przemyslaw.kowalczewski@up.poznan.pl
Department of Planting Design and Maintenance, Faculty of Horticulture and Landscape Engineering,
Slovak University of Agriculture, Tr. A. Hlinku 2, 94976 Nitra, Slovakia; katarina.rovna@uniag.sk
Department of Fruit Sciences, Viticulture and Enology, Faculty of Horticulture and Landscape Engineering,
Slovak University of Agriculture, Tr. A. Hlinku 2, 94976 Nitra, Slovakia
Department of Bioenergy, Food Technology and Microbiology, Institute of Food Technology and Nutrition,
University of Rzeszow, 4 Zelwerowicza St., 35601 Rzeszow, Poland
Correspondence: miroslava.kacaniova@gmail.com; Tel.: +421-376-414-715
Received: 7 April 2020; Accepted: 24 April 2020; Published: 27 April 2020
Abstract: The aim of this study was to characterize extracts from the leaves of Ginkgo biloba L. from
selected Slovakian localities in terms of the content of bioactive constituents, antioxidants and their
antimicrobial properties. The results indicated that the content of antioxidants was sample-specific,
and this specificity was statistically significant. Ginkgo biloba L. from the locality of Košice had the
best activity determined by the free radical scavenging activity (DPPH) (1.545 mg Trolox equivalent
antioxidant capacity (TEAC)/g fresh matter (FM)) as well as the molybdenum-reducing antioxidant
power (35.485 mg TEAC/g FM) methods. The highest content of total polyphenols (2.803 mg gallic
acid equivalent (GAE)/g FM) and flavonoids (4.649 µg quercetin equivalent (QE)/g FM) was also
detected in this sample. All samples of G. biloba leaf extracts showed significant antimicrobial activity
against one or more of the examined bacterial species, and Staphylococcus aureus subsp. aureus CCM
2461 was found to be the most susceptible (minimal inhibition concentration MIC50 and MIC90
values of 64.2 and 72.2 µg/mL, respectively). Based on the results it was concluded that Ginkgo
biloba L. extracts can be used as antimicrobial and antioxidant additives. Selected miRNA-based
molecular markers were used to examine the environmental adaptability of Ginkgo biloba L. An
almost-complete genotype clustering pattern based on locality was determined in the analysis that
involved a species-specific gb-miR5261 marker. Morphologically specific exemplar, cv. Ohatsuki,
was excluded.
Int. J. Mol. Sci. 2020, 21, 3087; doi:10.3390/ijms21093087
www.mdpi.com/journal/ijms
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Keywords: Ginkgo biloba; antimicrobial activity; polyphenols; flavonoids; antioxidant; microRNA;
miRNA-based markers
1. Introduction
Many plants are well known for a diverse range of bioactive molecules, making them a rich source of
different types of drugs. Most of the medicines used today are acquired from natural products that have
been used in traditional medicine [1–3]. The use of plant extracts and phytochemicals, well known for
their antioxidant and antimicrobial properties, can be of a great importance in therapeutic treatments. A
major part of the population of developing countries still uses traditional medicine based on the significant
antioxidant and antimicrobial properties of plants [4,5]. About 80% of individuals from well-developed
countries use traditional therapeutic treatments that are based on compounds obtained from medical plants.
Recently, a number of studies in various countries around the world have determined antioxidant and
antimicrobial effects of a wide range of plants, and proved their efficiency. Antioxidant and antimicrobial
agents are a result of the secondary metabolism of plants [6] which, therefore, should be investigated in
order to better understand their properties, safety and efficacy [7].
Ginkgo biloba L. is considered a living fossil as it has survived over millions of years [8]. It is one of the
oldest living tree species. Ginkgo survived without structural modifications for over 200 million years. It contains
a number of biologically active compounds that act as defense measures against insects, bacteria and fungi.
A number of secondary metabolites, such as terpenoids, polyphenols, organic acids and amino acids, have been
isolated from the plant [9]. Ginkgo biloba—especially its leaves—are rich sources of compounds with antioxidant
activity. The main compounds responsible for this kind of activity were identified as kaempferol, quercetin
and isorhamnetin. These flavonoids can scavenge and destroy free radicals, especially peroxide, hydrogen
peroxide, hydroxyl radical and singlet oxygen, which are connected with many diseases such as carcinogenesis,
inflammation, atherogenesis, as well as food deterioration. For this reason the naturally occurring antioxidants
in Ginkgo may be effective for different medical applications [10,11]. Ginkgo extracts are known for their
antiparasitic, antifungal, antioxidant, antibacterial, antiviral, and DNA protective activities [12–14]. In China,
Ginkgo extracts have been used for 5000 years to treat lung infectious diseases such as bronchitis and also as a
remedy for cardiovascular diseases [15]. Extracts from the leaves of Ginkgo have been used in Chinese medicine
from ancient times. In Western countries such as Germany and France, leaf extracts of Ginkgo biloba L. have been
used since the 1960s for treatment of atherosclerosis and cerebrovascular insufficiency [16,17]. It has also been
used to treat depression, memory loss, headaches and vertigo because of its positive effects on circulation [18].
Molecules of microRNA (miRNA) are highly conserved and hence can be useful for studying genetic
diversity among closely related genotypes [19] and related species [20]. These novel markers of functional
potential have been applied only to a limited extent in plant species. MicroRNA marker assays have been
performed in monocotyledonous species as foxtail millet [20], rice [19,21] and dicotyledonous Brassica
species [22]. So far, no reports have focused on genotyping of the gymnosperm Ginkgo biloba as a plant
with an interesting genetic background of environmental adaptability and medicinal importance.
The aim of this study was to investigate the chemical composition, antioxidant and antimicrobial
activity of ethanolic leaf extract of Ginkgo biloba L. from selected localities in Slovakia using in vitro
methods. Our results show new information about antimicrobial activity and characterization of
genotypes. Moreover, the potential of different types of microRNA molecular markers as a tool of
resolution and characterization of ginkgo genotypes with respect to microecological conditions and
the quantified parameters was also evaluated.
2. Results and Discussion
2.1. Quantitative Analysis of G. biloba Leaf Extracts
The results of quantitative analysis obtained by LC-MS/MS in data-dependent multiple reaction
monitoring (MRM) mode were given in Table 1.
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Table 1. The content (µg/g) of 15 phenolic compounds in the nine extract samples.
No.
tR
Compound
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
3.49
3.68
4.69
5.52
5.72
6.38
6.47
6.57
6.75
6.93
7.09
7.34
8.46
8.52
9.50
Syringic acid
Protocatechuic acid
Chlorogenic acid
Caffeic acid
Quercetin-3-O-rutinoside
p-Coumaric acid
Quercetin-3-O-glucoside
Kaempferol-3-O-glucoside
Isorhamnetin-O-glucoside
Luteolin-7-O-glucoside
Rosmarinic acid
Isorhamnetin
Luteolin
Quercetin
Kaempferol
Concentration (µg/g)
S1
S2
S3
S4
S5
S6
S7
S8
S9
149.23 ± 0.78
298.23 ± 1.69
168.65 ± 1.65
211.87 ± 2.02
366.11 ± 2.26
186.22 ± 0.58
111.59 ± 1.19
44.36 ± 0.21
3.56 ± 0.09
9.28 ± 0.12
59.26 ± 0.23
11.29 ± 0.08
41.26 ± 0.15
68.25 ± 0.14
17.52 ± 0.13
189.38 ± 0.98
111.23 ± 1.22
223.35 ± 1.98
165.35 ± 1.63
498.38 ± 2.89
97.35 ± 0.59
199.88 ± 0.77
31.44 ± 0.23
7.58 ± 0.08
14.46 ± 0.09
116.35 ± 1.11
29.23 ± 0.16
71.77 ± 1.69
223.99 ± 2.98
84.22 ± 1.26
49.33 ± 0.26
147.66 ± 1.98
109.88 ± 1.11
247.21 ± 2.68
287.23 ± 2.21
101.36 ± 1.25
144.58 ± 1.36
35.88 ± 0.15
6.25 ± 0.04
7.36 ± 0.08
99.89 ± 1.22
7.59 ± 0.03
11.23 ± 0.05
211.39 ± 1.29
36.29 ± 0.12
77.68 ± 0.54
133.28 ± 0.23
54.33 ± 0.12
111.28 ± 1.12
228.36 ± 1.99
198.88 ± 1.78
77.21 ± 0.38
27.12 ± 0.18
7.21 ± 0.11
1.54 ± 0.05
12.98 ± 0.03
3.23 ± 0.05
19.28 ± 0.14
122.44 ± 2.29
29.56 ± 0.37
38.23 ± 0.33
122.56 ± 0.28
57.69 ± 0.68
120.33 ± 1.56
211.23 ± 1.46
91.13 ± 1.43
222.34 ± 3.01
14.23 ± 0.07
1.28 ± 0.03
2.56 ± 0.02
7.59 ± 0.02
4.26 ±0.03
17.68 ± 0.08
158.68 ± 1.57
19.58 ± 0.08
133.58 ± 0.89
97.58 ± 0.79
244.36 ± 2.68
168.69 ± 1.58
387.77 ± 4.39
94.45 ± 1.25
146.55 ± 0.88
24.55 ± 0.79
4.54 ± 0.02
16.68 ± 0.08
77.68 ± 0.36
19.66 ± 0.12
31.11 ± 0.15
199.26 ± 1.28
56.47 ± 0.28
154.56 ± 0.78
277.38 ± 2.03
111.56 ± 1.86
285.69 ± 2.78
311.12 ± 3.21
177.58 ± 1.36
77.58 ± 1.25
39.88 ± 0.13
9.11 ± 0.04
17.14 ± 0.05
44.39 ± 0.38
24.29 ± 0.11
51.36 ± 0.69
58.11 ± 0.11
21.33 ± 0.27
197.36 ± 1.23
354.68 ± 3.05
97.33 ± 1.99
77.89 ± 1.27
226.25 ± 2.60
197.23 ± 2.68
56.28 ± 0.34
37.69 ± 0.45
3.11 ± 0.08
7.55 ± 0.03
69.99 ± 0.37
2.68 ± 0.04
111.23 ± 0.77
114.44 ± 0.46
9.35 ± 0.11
111.09 ± 1.16
322.21 ± 3.66
113.05 ± 1.53
135.42 ± 2.01
289.99 ± 2.25
177.07 ± 1.63
98.22 ± 0.47
29.28 ± 0.04
4.66 ± 0.11
11.69 ± 0.13
49.99 ± 0.45
36.55 ± 0.22
41.02 ± 0.28
77.68 ± 0.43
21.65 ± 0.16
S1—Rimavská Sobota; S2—Košice; S3—Budimír; S4—Vel’ký Blh; S5—Palárikovo; S6—Lučenec; S7—Topol’čianky; S8- Nová Ves; S9—Šurianky. Results are given as a mean value of three
measurements ± SD.
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As can be seen in Table 1, the most abundant compound present in all the extracts was
quercetin-3-O-rutinoside (211.23 µg/g to 498.38 µg/g). Chlorogenic acid and quercetin were the
dominant phenolics in sample S2 (223.35 µg/g and 223.99 µg/g, respectively). Other chemotaxonomic
markers of G. biloba leaf extracts, such as isorhamnetin, luteolin, kaempferol and their glycosides were
observed in small amounts. The exception is luteolin, which was abundant in sample S8 (111.23 µg/g).
2.2. Antioxidant Activity
While all the extracts showed antioxidant activity (Table 2), the best results were noted for samples
from the localities of Košice (1.545 mg Trolox equivalent antioxidant capacity (TEAC)/g fresh matter
(FM)) and Palárikovo (1.338 mg TEAC/g FM). Strong activity was also detected in samples from the
localities of Lučenec (1.333 mg TEAC/g FM) and Budimír (1.224 mg TEAC/g FM). Our results showed
that agro-ecological conditions can influence antioxidant activity. Several parameters, such as weather,
soil, varieties, stages of maturity and climatic conditions during the year, influence the amount of
bioactive compounds in medicinal herbs [23,24]. Kobus et al. [25] studied antiradical activity of water,
ethanolic and aqueous acetonic extracts from Ginkgo green and yellow leaves. Aqueous acetonic (4.89
mM TEAC/g dry matter) and ethanolic extracts (1.02 mM TEAC/g) from green leaves showed a greater
degree of eliminated DPPH radical than extracts from yellow Ginkgo leaves. In their study a very
interesting result was that water infusion extract from yellow leaves (2.91 mM TEAC/g) had better
activity than extract from green leaves (2.22 mM TEAC/g). Many studies confirmed that the scavenging
of DPPH radicals is connected from the spectrum of individual chemical components. The antiradical
properties of Ginkgo extracts, for which the flavonoid fraction is probably responsible, can eliminate
radicals such as the reactive oxygen species and reactive sulfur species. The content of individual types
of biologically active compounds are closely related to their accumulation levels over the course of
the growing season; during this time, both the proportions and forms of the bioactive compounds
vary [25–27].
Table 2. Antioxidant activity, total polyphenol and flavonoid content of Ginkgo extract from selected
Slovakian localities.
Sample/Locality
DPPH
(mg TEAC/g FM)
MRP
(mg TEAC/g FM)
TPC
(mg GAE/g FM)
TFC
(µg QE/g FM)
Rimavská Sobota
Košice
Budimír
Vel’ký Blh
Palárikovo
Lučenec
Topol’čianky
Nová Ves
Šurianky
0.394 ± 0.011b
1.545 ± 0.112a
1.224 ± 0.021a
0.502 ± 0.012b
1.338 ± 0.021a
1.333 ± 0.051a
0.558 ± 0.084b
0.395 ± 0.022b
0.997 ± 0.026b
25.377 ± 0.086e
35.485 ± 0.464a
26.226 ± 0.132d
26.306 ± 0.132d
20.748 ± 0.418g
32.545 ± 0.177b
26.266 ± 0.096d
21.621 ± 0.298f
26.835 ± 0.241c
2.428 ± 0.046b
2.804 ± 0.131a
1.967 ± 0.031d
1.695 ± 0.018e
2.107 ± 0.100c
2.755 ± 0.073a
1.785 ± 0.079e
1.476 ± 0.083f
2.095 ± 0.048cd
0.156 ± 0.015d
4.640 ± 0.025a
2.982 ± 0.113a
1.193 ± 0.001bcd
2.972 ± 0.045a
2.084 ± 0.057abc
0.676 ± 0.195d
2.351 ± 0.059ab
0.741 ± 0.015cd
Means ± standard deviations; TEAC – Trolox equivalent antioxidant capacity; MRP – molybdenum reducing power;
FM – fresh matter; TPC – total polyphenol content; TFC – total flavonoid content; GAE – gallic acid equivalent; QE –
quercetin equivalent; mean ± standard deviation; different letters in column indicate the mean values that were
significantly different.
The molybdenum reducing antioxidant power is based on the reduction of Mo(VI) to Mo(V) by
the extract and subsequent formation of green phosphate/Mo(V) complex at acid pH. This method
evaluates both water-soluble and fat-soluble antioxidants (total antioxidant capacity). The results
indicate (Table 2) that the highest reducing power was found in the sample from the locality of Košice
(35.485 mg TEAC/g FM) followed by samples from Lučenec (32.545 mg TEAC/g FM) and Šurianky
(26.835 mg TEAC/g FM) localities. It was noticed that the electron-donating capacity, reflecting the
reducing power of bioactive components, is associated with antioxidant activity. Antioxidants act as
reductants, and inactivation of oxidants by reductants can be described as redox reactions in which
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one reaction species is reduced at the expense of the oxidation of the other [28]. In the study of Kobus
et al. [25], the highest absorbance values, were determined in aqueous acetone extract of yellow leaves
which was followed by the water infusion from yellow leaves. Stefanovits-Banyai et al. [29] tested the
reducing power of extracts prepared from Ginkgo leaves. These authors described several factors which
can influence biological activity; they compared the reducing power of water infusion and ethanolic
extracts from leaves of individual Ginkgo samples. The aqueous extracts reduced iron to a lesser degree
than the ethanolic extracts. In their studies, however, the authors used 80% (v/v) ethanol solutions,
which—as noted by the authors—extract more polyphenols. It is the polyphenols that are probably
mainly responsible for reducing power compared with the water infusion preparations. In our study,
80% (v/v) ethanol was used, and it had a noticeable effect on both the qualitative and quantitative
composition of the extracts. Extracts and preparations from Ginkgo are nowadays very popular, mainly
in folk medicine. Medicinal effects of the extracts that are structured to free-radical scavenging and
reducing power properties include: inhibition of lipid peroxidation, facilitation of the maintenance of
the integrity and permeability of cell membranes, and protection of brain neurons against oxidative
stress and post-ischemic injury induced by free radicals [30–32].
2.3. Total Polyphenol and Flavonoid Content
Polyphenols are known to be the main plant bioactive compounds with strong biological activity
in the human body. These compounds can work as potential natural antioxidants in terms of their
efficiency to act as both able radical scavengers and metal chelators [33]. Therefore, it was worthwhile
to determine the total phenolic content in the Ginkgo leaf extracts. Total polyphenol content in the
tested samples (Table 2) ranged from 1.476 to 2.804 mg GAE/g FM, with the highest content in the
sample from the locality of Košice, followed by the sample from Rimavská Sobota. Similar to the
results of antioxidant activity, a strong correlation between locality and the amount of polyphenolic
compounds was observed. Free radical scavenging activity (DPPH) and total polyphenol content in
evaluated samples showed a medium correlation (R2 = 0.740, p < 0.05). Total flavonoid content in
evaluated samples (Table 2) ranged from 0.156 to 4.650 µg QE/g FM, with the best result in the sample
from the locality of Košice, followed by the sample from the locality of Budimír. Reducing power and
total flavonoid content in the evaluated samples showed a medium correlation (R2 = 0.757, p < 0.05),
implying that the phenolic compounds were the major contributors to the observed antioxidant activity.
Currently, according to Liu et al. [34], more than 34 flavonoids have been isolated from Ginkgo leaves
and more than 70 flavonoids have been tentatively identified by mass spectrometry. The major flavonol
glycosides in Ginkgo are the derivatives of quercetin, kaempferol and isorhamnetin linked with glucose
and rhamnose in different linkage forms and number. Kobus et al. [25] determined qualitatively the
composition of flavonols in the aqueous acetonic, ethanolic, and water infusion extracts of green
and yellow Ginkgo leaves. These authors found a significantly (p < 0.05) higher content of flavonol
aglycones in the extracts from yellow Ginkgo leaves. The highest amounts of these components were
determined in the aqueous acetonic extract from yellow leaves (4938 µg/g DM) and the water infusion
extract from yellow leaves (3146 µg/g DM), while the lowest were detected in the water infusion
extract from green leaves (878 µg/g DM) and the ethanolic extract from green leaves (512 µg/g DM).
Regarding the extract preparations from yellow Ginkgo leaves, the dominant flavonol was myricetin
accounting for 1683, 1116, and 680 µg/g DM in the yellow water, aqueous acetonic and ethanolic
extracts, respectively. In the extracts from green Ginkgo leaves, kaempferol, myricetin, and isorhamnetin
predominated in general and ranged from 153 to 661 µg/g DM extract. The quantitative differences
in the flavonol aglycone profiles for the preparations likely stem from the changes that occur within
Ginkgo trees during vegetative growth, primarily accumulation of polyphenols over the course of
a longer growth period, which is characteristic of yellow leaves. In our study we tested ethanolic
(80%) extracts from leaves. Ethanol is commonly used to extract tannins, polyphenols, and flavonols,
and usually ethanolic extracts showed a noticeable antioxidant capacity. During water extraction,
mainly anthocyanins and tannins leached into the polar solvent with only a small proportion of
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flavonols; hence, such preparations have lower antiradical-scavenging potentials [35]. Flavonoids
are responsible for health-promoting properties due to their high antioxidant capacity both in vivo
and in vitro systems. These compounds can raise human protective enzyme systems. Several clinical
studies have confirmed protective effects of flavonoids against many infectious (bacterial and viral)
and civilization diseases, such as cardiovascular and digestive disorders, cancers, and other age-related
health problems [36]. Being plant phytochemicals, flavonoids cannot be synthesized in humans and
animals; they are essential and must be delivered daily to the human body. Dietary intake of flavonoids
has been estimated from 100 to 1000 mg per day [37]. Ginkgo extracts and Ginkgo-related products
can enrich human diet in flavonoids due to high content of ginkgolides and bilobalides—unique and
specific flavonoid bioactive compounds identified only in Ginkgo [38].
2.4. Antimicrobial Activity with Disc Diffusion Method
The antimicrobial activity of leaf extracts of G. biloba varied with respect to the microorganisms
and the locality of G. biloba used for extraction (Tables 3 and 4). Disc diffusion method showed different
antimicrobial effects of G. biloba against two different group of bacteria. Antimicrobial activity of G.
biloba against E. coli, represented by inhibition zone diameter, ranged from 3.33 ± 1.53 mm (Šurianky)
to 11.00 ± 1.00 mm (Košice), against K. pneumoniae—from 5.00 ± 1.00 mm (Šurianky) to 9.00 ± 1.00 mm
(Košice), against S. enteritidis—from 4.67 ± 1.53 mm (Šurianky) to 12.33 ± 2.08 mm (Košice), against S.
sonei—from 4.00 ± 1.00 mm (Palárikovo) to 12.33 ± 1.53 mm (Košice), and against Y. enterocolitica—from
4.00 ± 1.00 mm (Lučenec) to 11.00 ± 1.00 mm (Košice).
Table 3. Antimicrobial activity of Gingko biloba against Gram negative bacteria (in mm).
Tested Gram-Negative Bacteria
Sample Locality
EC
KP
SE
SS
YE
Rimavská Sobota
Košice
Budimír
Vel’ký Blh
Palárikovo
Lučenec
Topol’čianky
Nová Ves
Šurianky
6.67 ± 1.53a
11.00 ± 1.00ab
6.00 ± 1.00b
8.00 ± 1.00c
4.00 ± 1.00bc
5.00 ± 1.00b
6.00 ± 1.73b
5.67 ± 1.53b
3.33 ± 1.53bc
6.67 ± 1.53
9.00 ± 1.00
7.33 ± 2.08
5.67 ± 1.53
5.00 ± 3.00
5.00 ± 1.00
6.67 ± 1.53
5.33 ± 1.53
5.00 ± 1.00
6.67 ± 1.53a
12.33 ± 2.08ab
5.00 ± 1.00b
5.00 ± 2.00b
5.00 ± 1.00b
6.67 ± 1.53b
6.67 ± 1.53b
5.33 ± 0.58b
4.67 ± 1.53b
5.33 ± 1.53a
12.33 ± 1.53ab
6.00 ± 1.00b
4.33 ± 0.58b
4.00 ± 1.00b
7.00 ± 1.00b
6.00 ± 2.65b
7.00 ± 1.00b
5.33 ± 0.58b
6.33 ± 1.53a
11.00 ± 1.00ab
7.00 ± 2.65
6.67 ± 1.53
5.00 ± 1.00b
4.00 ± 1.00b
5.33 ± 1.15b
5.67 ± 0.58b
5.67 ± 2.08b
EC - Escherichia coli CCM 3988, KP - Klebsiella pneumoniae CCM 2318, SE - Salmonella enterica subsp. enterica CCM
3807, SS - Shigella sonei CCM 1373, YE - Yersinia enterocolitica CCM 5671; different letters in column indicate mean
values that were significantly different.
Table 4. Antimicrobial activity of Gingko biloba against Gram positive bacteria (in mm).
Tested Gram-Positive Bacteria
Sample Locality
BT
CP
HI
LM
SA
Rimavská Sobota
Košice
Budimír
Vel’ký Blh
Palárikovo
Lučenec
Topol’čianky
Nová Ves
Šurianky
5.00 ± 1.00
8.00 ± 1.00a
3.00 ± 1.00a
2.67 ± 1.53a
3.00 ± 1.00a
3.33 ± 2.08a
4.33 ± 1.15a
2.00 ± 1.00a
3.00 ± 1.00a
6.00 ± 1.00
8.00 ± 2.65a
5.00 ± 1.00
3.67 ± 1.53a
4.00 ± 1.00
4.00 ± 1.00
6.00 ± 1.00
6.00 ± 1.00
3.67 ± 1.53a
6.67 ± 1.53
10.00 ± 2.00a
5.33 ± 1.53a
4.00 ± 1.00a
2.67 ± 2.08a
3.00 ± 1.00a
5.00 ± 1.00a
3.00 ± 1.00a
4.00 ± 1.00a
6.00 ± 1.00
6.00 ± 4.58a
6.00 ± 1.00
5.00 ± 1.00
5.33 ± 1.53
3.67 ± 1.53
5.00 ± 1.00
3.00 ± 1.00a
3.33 ± 1.53a
5.33 ± 1.53
8.00 ± 1.00a
6.00 ± 1.00
4.67 ± 2.08
5.00 ± 1.00
6.67 ± 1.53
3.33 ± 1.53a
4.00 ± 2.00
4.00 ± 1.00
BT—Bacillus thuringiensis CCM 19, CP—Clostridium perfringens CCM 4991, HI—Haemophilus influenzae CCM 4456,
LM—Listeria monocytogenes CCM 4699, SA—Staphylococcus aureus subsp. aureus CCM 2461; letter “a” in column
indicates the mean values that were significantly different.
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In the study of Sati et al. [39], it was reported that the diameter of growth inhibition zones of
Gram negative bacteria was between 2.33–6.17, 2.27–4.83, and 1.83–4.67 mm, when methanol, ethyl
acetate, and n-butanol extracts were tested (at concentration 40 mg/0.1 mL), respectively. In our study,
ethanol extract was shown to have the greatest antimicrobial effect on bacteria.
The results of antimicrobial activity tests of G. biloba, given as diameters of inhibition zones,
against B. thuringiensis ranged from 2.00 ± 1.00 mm (Nová Ves nad Žitavou) to 8.00 ± 1.00 mm
(Košice), against C. perfringens—from 3.67 ± 1.53 mm (Vel’ký Blh, Šurianky) to 8.00 ± 2.65 mm (Košice),
against H. influenzae—from 2.67 ± 2.08 mm (Palárikovo) to 10.00 ± 2.00 mm (Košice), against L.
monocytogenes—from 3.00 ± 1.00 mm (Nová Ves nad Žitavou) to 6.00 ± 4.58 mm (Košice) and against
S. aureus—from 3.33 ± 1.53 mm (Topol’čianky) to 8.00 ± 1.00 mm (Košice). The inhibition zones
of Gram-positive bacteria were 2.27–8.86, 2.23–7.66, and 2.13–5.37 mm for methanol, ethyl acetate,
and n-butanol extracts according to Sati et al. [39], in case of Gram-negative bacteria, the inhibition
diameters ranged between 2.33–6.17, 2.27–4.83 and 1.83–4.67 mm. Additionally, in our study, the
results on inhibition of Gram-positive bacteria by ethanol extracts of G. biloba were similar to those
previously reported [40]. Inhibition of Gram-positive bacteria and yeasts was reported by Mazzanti et
al. [41] who studied the antimicrobial activity G. biloba leaf extracts. Leaf extracts of G. biloba were not
efficient for inhibition of B. subtilis and E. coli in recent report of Fazal et al. [7]. The climatic conditions
in different localities where G. biloba leaves were harvested may influence the inhibition test results. G.
biloba leaves originating from a temperate climate may have increased antimicrobial activity against a
wider range of microorganisms. G. biloba leaf extract has been found to exhibit antimicrobial properties
against medically important pathogens, e.g., Pneumocystis carinii and Listeria monocytogenes [12,17].
Other parts of plants, not only the leaves, have also expressed the antimicrobial activity [42,43].
2.5. Minimal Inhibition Concentration (MIC)
Minimum inhibitory concentration of ethanol extracts of nine leaf samples of Ginkgo biloba
L. towards Gram negative bacteria are summarized in Table 5. The values of minimal inhibition
concentration MIC 50 and MIC 90 towards E. coli ranged from 85.3 and 99.6 µg/mL, respectively
(sample Košice), to 263.3 and 285.9 µg/mL, respectively (samples: Rimavská Sobota, Budimír, Vel’ký
Blh); MIC 50 and MIC 90 towards K. pneumoniae ranged from 85.3 and 99.6 µg/mL, respectively (sample
Košice), to 263.3 and 285.9 µg/mL (samples: Rimavská Sobota, Topol’čianky); MIC 50 and MIC 90
towards S. enterica ranged from 85.3 and 99.6 µg/mL, respectively (sample Košice), to 263.3 and 285.9
µg/mL, respectively (samples: Topol’čianky, Nová Ves nad Žitavou, Šurianky); MIC 50 and MIC 90
towards S. sonei ranged from 128.1 and 136.4 µg/mL, respectively (sample Košice), to 263.3 and 285.9
µg/mL, respectively (samples: Rimavská Sobota, Budimír, Vel’ký Blh, Lučenec); MIC 50 and MIC 90
towards Y. enterocolitica ranged from 85.3 and 99.6 µg/mL, respectively (sample Košice), to 263.3 and
285.9 µg/mL, respectively (sample Topol’čianky, Nová Ves nad Žitavou). We found that all the samples
showed similar antimicrobial activity when tested on Gram-negative bacteria. However, the sample
from the locality of Košice showed more potential for further research and the strongest antimicrobial
activity. Out of all the tested Gram-negative bacteria, E. coli, K. pneumoinae and Y. enterocolitica were
found to be the most susceptible to the crude extracts of Ginkgo biloba leaves.
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Table 5. Minimal inhibition concentration of Ginkgo biloba L. (µg/mL) for Gram-negative bacteria.
Tested Gram-Negative Bacteria
Sample/Locality
Rimavská Sobota
Košice
Budimír
Vel’ký Blh
Palárikovo
Lučenec
Topol’čianky
Nová Ves
Šurianky
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
EC
KP
SE
SS
YE
263.3
285.9
85.3
99.6
263.3
285.9
263.3
285.9
130.6
143.8
263.3
285.9
130.6
143.8
170.7
192.9
130.6
143.8
263.3
285.9
85.3
99.6
170.7
192.9
170.7
192.9
170.7
192.9
130.6
143.8
263.3
285.9
128.1
136.4
128.1
136.4
130.6
143.8
128.1
136.4
130.6
143.8
255.8
272.0
128.1
136.4
128.1
136.4
263.3
285.9
263.3
285.9
263.3
285.9
263.3
285.9
128.1
136.4
263.3
285.9
263.3
285.9
130.6
143.8
263.3
285.9
130.6
143.8
170.7
192.9
130.6
143.8
128.1
136.4
85.3
99.6
128.1
136.4
170.7
190.8
128.1
136.4
128.1
136.4
263.3
285.9
263.3
285.9
128.1
136.4
EC—Escherichia coli CCM 3988, KP—Klebsiella pneumoniae CCM 2318, SE—Salmonella enterica subsp. enterica
CCM 3807, SS—Shigella sonei CCM 1373, YE—Yersinia enterocolitica CCM 5671.
Minimum inhibitory concentration of ethanol extracts of nine leaf samples of Ginkgo biloba L.
towards Gram-positive bacteria are summarized in Table 6. The values of MIC 50 and MIC 90 towards
B. thuringiensis ranged from 85.3 and 99.6 µg/mL, respectively (sample Nová Ves nad Žitavou), to 263.3
and 285.9 µg/mL, respectively (samples: Rimavská Sobota, Budimír, Vel’ký Blh); MIC 50 and MIC 90
towards C. perfringens ranged from 128.1 and 136.4 µg/mL, respectively (samples: Rimavská Sobota,
Košice), to 263.3 and 285.9 µg/mL, respectively (sample Šurianky); MIC 50 and MIC 90 towards H.
influenzae ranged from 85.3 and 99.6 µg/mL, respectively (samples: Košice, Budimír), to 341.3 and 382.3
µg/mL, respectively (sample Topol’čianky); MIC 50 and MIC 90 towards L. monocytogenes ranged from
85.3 and 99.6 µg/mL, respectively (sample Košice), to 263.3 and 285.9 µg/mL, respectively (sample
Šurianky); MIC 50 and MIC 90 towards S. aureus ranged from 64.2 and 72.2 µg/mL, respectively (sample
Budimír), to 263.3 and 285.9 µg/mL, respectively (sample Šurianky). We found similar antimicrobial
activity in all the samples when tested against Gram-positive bacteria. Although, again, the sample
from Košice showed more potential for further research and the strongest antimicrobial activity. Out of
all tested bacteria, S. aureus was found to be the most susceptible to Ginkgo biloba extracts compared to
other bacteria.
Extracts of Ginkgo biloba obtained using methanol, hexane and dichloromethane were also
evaluated in terms of inhibitory activity against five Gram-positive bacterial strains in a study by
Tewari et al. [44]. The dichloromethane extract was the most effective against E. coli, P. aeruginosa and P.
fluorescens. The values of MIC ranged from 3.51 to 8.19 mg/mL. Another report on the antimicrobial
activity of G. biloba leaf extracts suggested that the methanol extract has the best activity [39]. In a
report by Bajpai et al. [45], the results of screening for antibacterial activity showed that the essential
oil form G. biloba leaves had a potential inhibitory effect on the cell viability of the tested pathogens.
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Table 6. Minimal inhibition concentration of Ginkgo biloba L. (µg/mL) for Gram-positive bacteria.
Tested Gram-Positive Bacteria
Sample/Locality
Rimavská Sobota
Košice
Budimír
Vel’ký Blh
Palárikovo
Lučenec
Topol’čianky
Nová Ves
Šurianky
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
MIC 50
MIC 90
BT
CP
HI
LM
SA
263.3
285.9
170.7
192.9
263.3
285.9
263.3
285.9
130.6
143.8
263.3
285.9
130.6
143.8
85.3
99.6
130.6
143.8
128.1
136.4
128.1
136.4
128.1
136.4
130.6
143.8
130.6
143.8
170.7
192.9
130.6
143.8
240.1
389.9
263.3
285.9
128.1
136.4
85.3
95.4
85.3
95.4
170.7
192.9
130.6
143.8
263.3
285.9
341.3
382.3
263.3
285.9
263.3
285.9
130.6
143.8
85.3
99.6
130.6
143.8
130.6
143.8
130.6
143.8
128.1
136.4
130.6
143.8
240.1
389.9
263.3
285.9
130.6
143.8
85.3
99.6
64.2
72.2
130.6
143.8
130.6
143.8
128.1
136.4
170.7
192.9
130.6
143.8
263.3
285.9
BT—Bacillus thuringiensis CCM 19, CP—Clostridium perfringens CCM 4991, HI—Haemophilus influenzae CCM
4456, LM—Listeria monocytogenes CCM 4699, SA—Staphylococcus aureus subsp. aureus CCM 2461.
Our study on the antimicrobial activity of Ginkgo biloba ethanol extracts showed results that
contrast with other available reports. Mazzanti et al. [41] reported that the antimicrobial activity of
three fractions of methanolic extracts of Ginkgo biloba leaves was effective towards Gram-positive
bacteria only. Lee and Kim [46] found that Ginkgo biloba leaf-derived materials inhibited Clostridium
perfringens and Escherichia coli, but did not inhibit anaerobic intestinal bacteria, such as Bifidobacterium
bifidum, a common and beneficial lactic acid bacteria, or Lactobacillus acidophilus. Sati and Joshi [47]
showed that the methanolic extract of Ginkgo biloba leaves inhibited Escherichia coli, Bacillus subtilis
and some plant pathogenic bacterial strains. Tao et al. [40] reported antibacterial/antifungal activities
and synergistic interactions between Ginkgo biloba polyprenols and eight compounds separated from
Ginkgo biloba L. leaf lipids against Salmonella enterica, Staphylococcus aureus and Aspergillus niger.
2.6. MicroRNA-Marker Assay
Next-generation sequencing has allowed identification of 202(m)/201(f) known and 174(m)/174(f)
novel miRNAs of male and female leaves of ginkgo that belong to 82 and 78 families [48]. In our
study we used DNA markers for microRNA designed according to miRNA sequences of Ginkgo biloba
identified in the above-mentioned report. They were sorted into three categories: highly conserved
(miR160), moderately conserved (miR482) and novel types of miRNA (miR75) families. Three primer
combinations were used to analyze nine genotypes of Ginkgo biloba grown in different areas of Slovakia.
Three types of the miRNA-based PCR primers were also used by Wang et al. [48] in their study. The first
type was designed based on the sequences of miR160, which is a member of a deeply conserved miRNA
family in the ginkgo genome. Their evolutionary conserved character suggests their specific role in
a variety of physiological processes in plants [48,49]. Moderately conserved miRNAs are presented
by miR482 which is involved in defense mechanisms of the gingko genome. The species-specific
miRNA5261 family may have a significant role in producing new functions in special species [48].
Finally, the novel miRNA type identified by high-throughput sequencing of the ginkgo genome is
gbl-miR75, which has a role in specific regulation of defensive processes.
A total of 211 miRNA fragments were amplified in nine ginkgo genotypes by three miRNA-based
molecular marker primer pairs. The number of bands produced per primer combination ranged from
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51 (gb-miR5261_F/gb-miR5261_R), 60 (gb-miR482F/gb-miR482R) to 100 (gb-miR160_F/gb-miR75_R).
The amplification properties of the miRNA-based markers are summarized in Table 7. It can be assumed
that miRNA-based primers combined in the same stem-loop structure are able to produce fragments
corresponding to precursor molecules of pre-miRNA. Fu et al. [22] suggested that miRNA-based
primers may likely amplify regions between neighboring miRNAs.
Table 7. Details of miRNA marker assay with various parameters revealing the discriminatory power
of each marker.
miRNA Marker
Number of
Loci
Number of
Polymorphic
Loci
Number of
Monomorphic
Loci
Number of
Unique Loci
Percentage of
Polymorphism
PIC
gb-miR160F/gb-miR75R
gb-miR482F/gb-miR482R
gb-miR5261F/gb-miR5261R
14
14
8
3
9
3
9
1
5
2
4
0
21.43
64.29
37.5
0.91
0.90
0.83
PIC: polymorphic information content.
Polymorphic information content was used to calculate allelic variation as the index of the
individual primers’ practical applications. Table 7 presents the PIC value of each of the miRNA-based
molecular marker. In general, PIC values of more than 0.5 indicate high polymorphism. The effect
of the individual primers was measured by number of polymorphic, monomorphic and unique
loci, percentage of polymorphism and PIC value were evaluated. These findings indicate that the
molecular markers based on conservatively different types of microRNA sequences of Ginkgo biloba
displayed different levels of polymorphism in all tested genotypes (Figures 1 and 2). The possibility of
a random combination of miRNA-based primers has the potential to generate more polymorphic loci.
The sensitivity of the software system utilized for the evaluation fragments based on default parameters
also allowed identification of unique miRNA loci. The unique loci were recorded in ginkgo genotypes
that originated from Topol’čianky (2 unique loci), Rimavská Sobota (2 unique loci), Palárikovo and
Budimír (one unique locus each).
Figure 1. PCR amplification profile generated with miRNA-based primer pair gb-miR160F/gb-miR75R
across 9 genotypes of Ginkgo biloba: G1—Nová Ves nad Žitavou, G2—Topol’čianky, G3—Lučenec,
G4—Vel’ký Blh, G5—Rimavská Sobota, G6—Palárikovo, G7—Šurianky, G8—Košice and G9—Budimír.
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Figure 2. PCR amplification profile generated with miRNA-based primer pair gb-miR482F &
gb-miR482R across 9 genotypes of Ginkgo biloba: G1—Nová Ves nad Žitavou, G2—Topol’čianky,
G3—Lučenec, G4—Vel’ký Blh, G5—Rimavská Sobota, G6—Palárikovo, G7—Šurianky, G8—Košice and
G9—Budimír.
Cluster analysis was performed for the data obtained from ginkgo trees from different localities
in Slovakia to analyze whether these markers could be applied for detection of antioxidant and
antimicrobial properties at the molecular level. Construction of a binary matrix for unweighted pair
group method with arithmetic mean (UPGMA) analysis was based on the records of peak profiles
from the SynGene GeneTools software. Each fragment was characterized in terms of the amount and
volume of the peak profile in pixels. Based on these features it was possible to capture the unique
loci and their specific position. Recorded profiles of miRNA fingerprints were analyzed under the
default setting threshold in the analytical software in a manner in which all observable fragments were
clearly identified
Hierarchical cluster trees (dendrograms) were constructed for each primer combination.
The accuracy of the clustering based on our data was verified by cophenetic correlation coefficient.
The values of the cophenetic correlation coefficients were as follows; 0.93 (cluster analysis by
gb-miR160_F/gb-miR75 R, 0.95 (cluster analysis by gb-miR482_F/gb-miR482 R) and 0.98 (cluster
analysis by gb-miR5261_F/gb-miR5261 R).
Application of different miRNA marker combinations resulted in the classification of nine ginkgo
genotypes into one main cluster and all of the other samples were distinct from this cluster. Two
genotypes from the western, one from the middle, one from the southern, and one from the eastern
localities were clustered together into one cluster by the combination of deeply conserved gb-miR160
and novel type gb-miR75 of miRNA markers, (Figure 3). The remaining genotypes from the localities
of Lučenec, Rimavská Sobota, Košice and Palárikovo were characterized by various levels of genetic
diversity. It was the latter group of genotypes that showed significant antioxidant activity, total
polyphenol and flavonoid content.
The miRNA markers based on the moderately conserved microRNAs family allowed grouping
of genotypes that reflected their locality. The trees from eastern (Košice and Budimír) and some
from the southern (Vel’ký Blh and Rimavská Sobota) parts of Slovakia were classified in two smaller
sub-clusters, while the genotypes from the western (Topol’čianky, Nová Ves nad Žitavou and Lučenec)
and some from the southern (Šurianky and Palárikovo) localities were classified individually one by
one according to their habitats (Figure 4). The ginkgo trees from Lučenec and Palárikovo belonged
to separate clusters, as was also the case with clustering based on gb-miR160 and gb-miR75, which
corresponds to their outstanding properties.
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Figure 3. Dendrogram constructed by using the unweighted pair group method using arithmetic
averages (UPGMA) cluster analysis of 9 genotypes of Ginkgo biloba on miRNA markers gb-miR160_F
& gb-miR75_R. G1—Nová Ves nad Žitavou, G2—Topol’čianky, G3—Lučenec, G4—Vel’ký Blh,
G5—Rimavská Sobota, G6—Palárikovo, G7—Šurianky, G8—Košice, G9—Budimír.
Figure 4. Dendrogram constructed by using unweighted pair group method using arithmetic averages
(UPGMA) cluster analysis of 9 genotypes of Ginkgo biloba on miRNA markers gb-miR482_F/gb-miR482_R.
G1—Nová Ves nad Žitavou, G2—Topol’čianky, G3—Lučenec, G4—Vel’ký Blh, G5—Rimavská Sobota,
G6—Palárikovo, G7—Šurianky, G8—Košice, G9—Budimír.
Interestingly, based on the species-specific gb-miR5261 markers, almost all the genotypes of ginkgo
were divided into three groups that corresponded to the location of growth (Figure 5). The major
group consisted of genotypes that originated from the western (Topol’čianky and Lučenec), eastern
(Košice and Budimír) and southern (Šurianky) localities. The second group consisted of trees from the
western (Nová Ves nad Žitavou) and southern (Palárikov) localities, one from each. Finally, in the third
group, trees from the southern (Vel’ký Blh and Rimavská Sobota) localities were grouped. The ginkgo
genotypes that originated from the southern and western localities failed to cluster within one group.
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Figure 5. Dendrogram constructed by using unweighted pair group method using arithmetic
averages (UPGMA) cluster analysis of 9 genotypes of Ginkgo biloba on miRNA markers gb-miR5261_F
& gb-miR5261_R. G1—Nová Ves nad Žitavou, G2—Topol’čianky, G3—Lučenec, G4—Vel’ký Blh,
G5—Rimavská Sobota, G6—Palárikovo, G7—Šurianky, G8—Košice, G9—Budimír.
The gingko leaves from Košice, Budimír, Lučenec, Rimavská Sobota and Šurianky localities were
outstanding in terms of antioxidant and antimicrobial properties. The highest total polyphenol and
flavonoid content was recorded in the samples from Košice, Budimír and Rimavská Sobota. As for the
molecular-marker assay analyses, some of the above-mentioned genotypes (from localities of Lučenec,
Rimavská Sobota and Košice) were excluded as individual exemplars, in particular by the analyses of
the combination of the deeply conserved and novel type of miRNA markers (gb-miR160 & gb-miR75)
as well as the moderately conserved markers (gb-miR482).
Predicted targets of miRNA160 include auxin response factor (ARF). This factor binds to promoters
of auxin response elements and was reported to have a role in plant responses to diverse environmental
factors [50]. The predicted targets of miRNA482 and gbl-miR75 represent genes encoding disease
resistance proteins (disease resistance protein RPM1; disease resistance protein RPS2; DNA-directed
RNA polymerases I, II, and III subunit RPABC1) [48]. This indicates that the defense mechanisms of
Ginkgo biloba represent a major part of all biological processes in which the miRNAs play specific and
essential roles. Our results demonstrate that the activity of these specific types of miRNA families was
evenly intensive in all the analyzed genotypes. An interesting feature of primers based on miRNA
sequences is that they can be combined randomly whereas SSR primers must be designed in fixed
pairs. Hence, combined miRNA-based primers have the potential to generate more polymorphic
fragments [22]. This was evidenced by our experimental data. The gb-miR160F/gbmiR75R primer
combination produced about 55% more miRNA fragments in comparison to uncombined primer
pair gb-miR482F/gbmiR482F. The miRNA markers are a dominant type of markers with putative
functionality. The polymorphism observed when miRNA-based primers are used may be related to
changes in regulation of expression of the target gene.
The applied type of molecular markers based on microRNAs is an appropriate tool for the
characterization of individual genotypes of Ginkgo biloba originating from different localities in Slovakia.
Moreover, it can be stated that miRNAs-based markers, targeted at the genetic determinants of
adaptability and resistance mechanisms of Ginkgo biloba, could be used to select specific individuals
with significant antimicrobial, antioxidant properties and morphological features.
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3. Materials and Methods
3.1. Plant Materials and Sample Preparation
Ginkgo biloba L. leaves were collected from selected localities of Slovakia (Rimavská Sobota, Košice,
Budimír, Vel’ký Blh, Palárikovo, Lučenec, Topol’činanky, Nová Ves nad Žitavou, Šurianky) during
the vegetation period of 2014 in the phase of maturity and stored at −50 ◦ C until DNA extraction.
The leaves were botanically identified at the Department of Genetics and Plant Breeding, Slovak
University of Agriculture in Nitra. All the analyses were performed in triplicate. DNA extraction was
performed form the pooled leaf material for each of the evaluated trees. All chemicals were analytical
grade and were purchased from CentralChem (Bratislava, Slovakia), Penta (Prague, Czech Republic),
Sigma–Aldrich (St. Louis, MO, USA) and Invitrogen (Camarillo, CA, USA).
The fresh leaves were used for preparation of ethanolic extracts. An amount of 1 g of each sample
was extracted with 20 mL of 80% ethanol for 24 h. After centrifugation at 4000× g in Rotofix 32 A
(Hettich Holding GmbH & Co. oHG, Kirchlengern, Germany) for 10 min, the supernatant was used
for the measurements with DPPH and phosphomolybdenum methods, as well as for the analyses of
total phenolic content and total flavonoid content.
For the antimicrobial activity and quantitative LC-MS/MS analysis the plant material was initially
dried at room temperature in the dark. After drying, the material was crushed and weighed. The leaf
powder was extracted with 96% ethanol p.a. (CentralChem, Bratislava, Slovakia) for 2 weeks, at a
solid-to-liquid ratio of 1:10 (w/v), at room temperature, and in the dark. Exposure to sunlight was
avoided in order to prevent the degradation of active compounds. Then, ethanol plant extracts were
filtered through the Whatman No. 1 filter paper and dried using a rotary evaporator (Stuart RE300DB,
Bibby Scientific Limited, Stone, UK) and vacuum pump (KNF N838.1.2KT.45.18, KNF Neuberger
GmbH, Freiburg, Germany). Evaporation was performed under vacuum at - 40 ◦ C in order to remove
ethanol. For the antimicrobial assay, the crude plant extracts were dissolved in dimethyl sulfoxide
(DMSO) (CentralChem, Bratislava, Slovakia) to 204.8 mg/100 mL as stock solution, which were stored
at - 16 ◦ C until use.
Total genomic DNA was extracted from leaves ground in liquid nitrogen according the protocol by
Padmalantha and Prasad [51]. The extracted DNA was quantified using an Implen NanoPhotometer® ,
and diluted to 70 ng/µL.
3.2. LC-MS/MS Quantitative Analysis
For quantitative examination, an Agilent 1200 series liquid chromatograph coupled to 6410B
triple-quadrupole mass spectrometer with electrospray ionization (ESI) was used (Agilent Technologies,
Palo Alto, CA, USA). MassHunter ver. B.03.01. software was used for instrument control and data
analysis. Analytical column used for separation was a Syncronis C18-column (100 × 2.1 mm, 1.7 µm
particle size, ThermoFisher Scientific). The mobile phase consisted of (A) ultrapure water with 1%
formic acid and (B) acetonitrile (MS grade). The injection volume for the sample was 10 µL, elution
gradient program was 5–95% B for 20 min, with the flow rate of 0.3 mL/min. The injector volume for
sample and standard compounds was 5 µL. The eluate was forwarded, without flow splitting, into an
ESI ion source with following settings: drying gas (N2) temperature, 350 °C; flow, 9 L/min; nebulizer gas
pressure, 40 psi; capillary voltage, 4 kV, negative polarity. All compounds were quantified in dynamic
MRM mode (multiple reaction monitoring mode) [52]. All the standards were dissolved in methanol to
prepare stock solutions of 10 mg/mL. The mix of stock solutions was prepared, with concentration of
each compound being 100 µg/mL. The mix was subsequently serially diluted, giving working standard
solutions with concentrations ranging from 25.0 × 103 ng/mL to 1.53 ng/mL. Calibration curves were
based on these solutions. Concentrations of investigated compounds in extracts were determined on
the basis of peak areas by using the equation of linear regression obtained from the calibration data
(R2 = 0.995). The optimized parameters and target ions are presented in Table 8.
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Table 8. LC-MS/MS parameters for standard phenolic compounds.
MS/MS Parameters
Compound
Syringic acid
Protocatechuic acid
Chlorogenic acid
Caffeic acid
Quercetin-3-O-rutinoside
p-Coumaric acid
Quercetin-3-O-glucoside
Kaempferol-3-O-glucoside
Isorhamnetin-O-glucoside
Luteolin-7-O-glucoside
Rosmarinic acid
Isorhamnetin
Luteolin
Quercetin
Kaempferol
tR
Fragmentor
Voltage (V)
Precursor Ion
(m/z)
Product Ion
(m/z)
Collision
Energy (V)
3.49
3.68
4.69
5.52
5.72
6.38
6.47
6.57
6.75
6.93
7.09
7.34
8.46
8.52
9.50
90
103
100
100
135
90
210
200
210
230
120
155
135
130
130
197
153
353
179
609
163
463
447
477
447
359
315
285
301
285
182
109
191
135
300
119
300
284
315
285
161
300
133
151
285
6
10
11
10
40
9
35
30
25
30
14
23
30
19
0
3.3. Analyses of Antioxidant Activity
3.3.1. Free Radical Scavenging Activity
A 2,2-diphenyl-1-picrylhydrazyl (DPPH) was used to determine of free radical scavenging activity
in accordance with the method describe by Sánchez-Moreno et al. [53]. Briefly, the absorbance of
samples (0.4 mL) and alcohol solution DPPH (3.4 mL) was measured at a wavelength of 515 nm using
a spectrophotometer (6405 UV/Vis, Jenway, Stone, England). The results of antioxidant activity were
expressed as Trolox (6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid) equivalent in mg/g.
3.3.2. Molybdenum-Reducing Antioxidant Power
The method described by Prieto et al. [54] was used to determine molybdenum-reducing
antioxidant power. Briefly, the sample (1 mL) was mixed with monopotassium phosphate (2.8 mL,
0.1 M), sulfuric acid (6 mL, 1 M), ammonium heptamolybdate (0.4 mL, 0.1 M) and distilled water (0.8
mL). Then, the mixture prepared in this way was incubated at 90 ◦ C for 120 min and rapidly cooled.
The absorbance at 700 nm was measured using above mentioned spectrophotometer and the results
were presented as Trolox equivalent in mg/g.
3.3.3. Total Polyphenol Content
A standard Singleton’s et al. [55] method was used to measure the total polyphenol content in
analyzed samples. The results of absorbance at 700 nm measured spectrophotometrically (6405 UV/Vis,
Jenway, Stone, England) were then calculated and expressed as gallic acid equivalents expressed in
mg/g.
3.3.4. Total Flavonoid Content
Total flavonoid content was measured spectrophotometrically (6405 UV/Vis, Jenway, Stone,
England) at 415 nm accordingly to Willett’s [56] method. Briefly, to 0.5 mL of sample, ethanolic solution
of aluminum chloride (10% w/v), potassium acetate (0.1 mL of 1 M) and distilled water (4.3 mL) were
added. Then, the mixture was incubated in the dark for 30 min. Obtained results were expressed in
mg/g quercetin equivalents.
3.4. Detection of Antimicrobial Activity
Altogether ten strains of microorganisms were tested in the study, including five Gram-negative
bacteria (Escherichia coli CCM 3988, Klebsiella pneumoniae CCM 2318, Salmonella enterica subsp. enterica
Int. J. Mol. Sci. 2020, 21, 3087
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CCM 3807, Shigella sonei CCM 1373, Yersinia enterocolitica CCM 5671); and five Gram-positive bacteria
(Bacillus thuringiensis CCM 19, Clostridium perfringens CCM 4991, Haemophilus influenzae CCM 4456,
Listeria monocytogenes CCM 4699 and Staphylococcus aureus subsp. aureus CCM 2461). All tested strains
were obtained from the Czech Collection of Microorganisms. The bacterial suspensions were cultured
in nutrient broth (Imuna, Slovakia) at 37 ◦ C for 24 h.
3.5. Disc Diffusion Method
A 0.1 mL of microorganisms suspension (106 cfu/mL) was cultured on Mueller Hinton Agar
(MHA, Oxoid, Basingstoke, United Kingdom). Filter paper discs (6 mm) were impregnated with 15
µL of plant extract and put on the inoculated agar. Cultivation was done at 4 ◦ C for 2 h aerobically,
with exception of C. perfringens, which was cultivated anaerobically, at 37 ◦ C for 24 h. The diameters
of the inhibition zones in millimeters were measured after incubation. All the tests were performed
in triplicate.
3.6. Minimal Inhibitory Concentration
MICs were determined in Mueller Hinton broth (Biolife, Milan, Italy) by the microbroth dilution
method. Dilutions were prepared according to the Clinical and Laboratory Standards Institute (CLSI,
2009) guidelines for bacteria. Plant extracts, dissolved in DMSO, were prepared to a final concentration
of 204.8 mg/mL. Concentration of plant extracts were dissolved in DMSO for preparation of series
of two-fold dilutions for final concentration from 0.33 to 682.67 µg/mL. Then 96-microwell plate was
inoculated with microbial suspensions at a final density of 0.5 McFarland unit and incubated at 37 ◦ C
for 24 h. The microbial growth inhibition was measured by detecting absorbance at 517 nm (Biotek
EL808, Biotek Instruments Inc., Winooski, VT, USA). Measurements were taken at the start and finish
of the experiment. Differences between both measurements were evaluated as growth and values
exceeding 715 nm from the mean absorbance were considered as error. The positive control was
microbial suspension without plant extracts but the negative control was pure DMSO. This experiment
was repeated in eight replicates for higher accuracy.
3.7. miRNA-marker Assay
The primers for the miRNA-marker assay were based on Wang et al. [48]. Sequences of following
microRNA families were used: deeply conserved (gb-miR160), moderately conserved (gb-miR482),
species-specific (gb-miR5261) and the novel miRNA family (gb-miR75) identified by high-throughput
sequencing (Table 9). Mature miRNA sequences were used to design primers used in the study.
The miRNA database was used for this purpose (http://www.mirbase.org/). Single forward and reverse
primers were combined to perform a marker assay [57]. The following combinations of miRNA markers
were used; gb-miR160_F/gb-miR75_R, gb-miR482_F/gb-miR482_R and gb-miR5261_F/gb-miR5261_R.
Table 9. Sequences of miRNA-based primers.
Primer
Sequences 5′ - 3′
gb-miR160_F
gb-miR482_F
gb-miR482_R
gb-miR5261_F
gb-miR5261_R
gb-miR75_R
TTAGTCTGCCTGGCTCCCTGTATG
TGGGTTGTAGTCTTCAGGAGTGGG
GAAGGCAATAGGAATGGGAGGATC
TTTGGAAAGTATTCGCATTGATTA
TATGGAACAAATTGCCACTCGGAT
CCGGGCAGTAGGAATGGGAGGAAT
The marker assay was performed based on methodologies from Fu et al. [22] and Yadav et al. [20]
which were modified for the purposes of the analysis [57,58]. PCR amplifications were performed
in a 20-µL reaction mixture containing 70 ng of genomic DNA, 10 pmol.dm-3 of each primer, 2
units of DreamTaq DNA polymerase, 0.8 mmol.dm-3 dNTPs (Bioline) and 1×DreamTaq Buffer (KCl,
Int. J. Mol. Sci. 2020, 21, 3087
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(NH4 )2 SO4 , 20 mmol/dm MgCl2 ). Touchdown PCR was used to amplify miRNA fingerprints with
following parameters: 94 ◦ C for 5 min; 5 cycles of 30 s at 94 ◦ C, 45 s at 64 ◦ C (1 ◦ C decrease per cycle),
and 60 s at 72 ◦ C; 30 cycles of 30 s at 94 ◦ C, 45 s at 60 ◦ C, and 60 s at 72 ◦ C; final 72 ◦ C for 10 min.
The samples were subsequently stored at 8 ◦ C. The PCR products were separated using 15% TBE-Urea
polyacrylamide gels, running in 1×TBE Running Buffer at a constant power of 90 V, 25 mA for 120 min.
A 10-bp DNA ladder (Invitrogen) was used for size determination. The polyacrylamide gels were
stained with the GelRedTM Nucleic Acid Gel stain and visualized in the G-Box Syngene electrophoresis
documentation system. For the recording of loci number and identification of unique fragments, the
gels were analyzed by the GeneTools software, GeneSnap version 7.09.17 (Syngene).
3.8. Statistical Analysis
For the statistical analyses of antioxidant activity data, the SAS program was used (The SAS
system v9.2.). Correlation coefficients were calculated with CORR analysis [59]. For antimicrobial
activity, the coefficients of variation and frequency of size of inhibition zones were calculated with
Statgraphic (Statpoint Technologies, Warrenton, VA, USA). Absorbance values, before and after the
incubation, determined during MIC analysis were used as a set of binary values to assign the exact
concentrations. Probit analysis in STATGRAPHIC Centurion XVI software was used.
The bands for each miRNA-based allele were scored in terms of their presence (1) or absence
(0). Scored data were used for the estimation of Jaccard´s similarity coefficient and this similarity
matrix was used in cluster analysis using the unweighted pair group method using arithmetic averages
(UPGMA) according to Garcia-Vallve et al. [60]. Polymorphism information content (PIC) value was
calculated based on Fu et al. [22].
4. Conclusions
Gingko biloba is a plant known for its pronounced biological activity, yet its specific properties
are dependent on the place of origin and agro-ecological conditions. The aim of this study was
to characterize plants obtained from different Slovakian localities and leaf extracts obtained from
them. Among the analyzed Ginkgo extracts, the sample from the locality of Košice was the highest
in antioxidant activity as well as having the richest polyphenol and flavonoid content. Moreover,
the obtained data indicates that Ginkgo biloba possess a remarkably high inhibitory activity against a
wide spectrum of Gram-positive and Gram-negative bacteria. Molecular characterization of Gingko
genotypes with the use of miRNA-based markers, made possible by sufficient polymorphism and
stability, allowed determination of the genetic relationships between them and revealed regional
similarities. Moreover, among specimens that showed outstanding properties in terms of biological
activity, three were classified as individual exemplars using the UPGMA method and the results of
the analyses of the combination of deeply conserved and novel types of miRNA markers as well as
moderately conserved markers.
Author Contributions: Data curation, K.R., E.I., N.V. and M.K.; funding acquisition, Z.S. and M.K.; investigation,
K.R., E.I., N.V., M.T., M.S., L.H., K.R., J.Ž. and M.K.; methodology, K.R., E.I., M.T., P.Ł.K., K.R. and M.K.; supervision,
M.K.; writing – original draft, K.R., Z.S., E.I., N.V., M.T., M.S., L.H., P.Ł.K., K.R., J.Ž. and M.K. All authors have
read and agreed to the published version of the manuscript.
Funding: This work has been supported by the APVV SK-BY-RD-19-0014 grant “The formulation of novel
compositions and properties study of the polysaccharide-based edible films and coatings with antimicrobial and
antioxidant plant additives.”
Acknowledgments: This study was supported by the project: The research leading to these results has received
funding from the European Community under project no. 26220220180: Building Research Centre “AgroBioTech”.
The publication was co-financed within the framework of Ministry of Science and Higher Education programme
as “Regional Initiative Excellence” in years 2019-2022, Project No. 005/RID/2018/19”.
Conflicts of Interest: The authors declare no conflict of interest.
Int. J. Mol. Sci. 2020, 21, 3087
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