© The Authors, 2023, Published by the Universidad del Zulia*Corresponding author: jhernandezm@ipn.mx
Keywords:
Phytonutrients
Fragaria x ananassa
Rubus adenotrichos
Antioxidants
HPTLC
Biokinetic mechnisms of anthocyanins in red fruits produced in the state of Michoacan, Mexico
Mecanismos biocinéticos de antocianinas en frutos rojos producidos en el estado de Michoacán,
México
Mecanismos biocineticos das antocianinas em frutos vermelhos produzidos no estado de Michoacan,
Mexico
Jesús Di Carlo Quiroz Velásquez
1
Cristian Lizarazo Ortega
1
Jesús Gerardo García Olivares
2
Jorge Alberto Torres Ortega
3
Israel García León
1
Jose Luis Hernández Mendoza
1
Rev. Fac. Agron. (LUZ). 2023, 40(3): e234029
ISSN 2477-9407
DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v40.n3.07
Food Technology
Associate editor: Dra. Gretty R. Ettiene Rojas
University of Zulia, Faculty of Agronomy
Bolivarian Republic of Venezuela
1
Instituto Politécnico Nacional – Centro de Biotecnología
Genómica. Laboratorio de Biotecnología Experimental.
Ciudad Reynosa Tamaulipas, México.
2
Instituto Politécnico Nacional – Centro de Biotecnología
Genómica. Laboratorio de Biotecnología Vegetal. Ciudad
Reynosa Tamaulipas, México.
3
Instituto Politécnico Nacional – Centro de Biotecnología
Genómica. Laboratorio de Biotecnología Ambiental. Ciudad
Reynosa Tamaulipas, México.
Received:
15-05-2023
Accepted: 18-07-2023
Published: 28-08-2023
Abstract
Berry fruits are a rich source of phytonutrients, especially phenolic
compounds such as avonoids, which have antioxidant properties. Among
these fruits, the most cultivated and consumed are those of the genus
Fragaria (Strawberries) and Rubus (Raspberries, blackberries, dewberries),
which have been widely studied for their benecial eects on human and
animal health. One of the most important bioactive compounds of these
fruits are anthocyanins, which have shown potential benets for health by
their antimicrobial, anti-inammatory and anticancer activity. Therefore, the
study of anthocyanins is of great pharmaceutical and nutraceutical interest.
The objective of this research is to analyze the biokinetic mechanisms of
anthocyanins in Rubus adenotrichos and Fragaria x ananassa produced
in the state of Michoacán, Mexico. For this purpose, research strategies
that included the extraction and quantication of anthocyanins, as well
as bioinformatic tools to understand their biosynthetic pathway in the
mentioned fruits were used. The use of informatic platforms allowed to
identify the regulatory genes and enzymes involved in the biosynthesis of
anthocyanins in R. adenotrichos and F. x ananassa, nding that most are
common, with some specic dierences, and that there are only a few
exceptions, such as the enzymes catechol-O-methyltransferase (OMT),
UDP-glucosyltransferase (UGT) and beta-glucuronidase (GUSB), which
only occur in Rubus adenotrichos and not in Fragaria x ananassa.
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Rev. Fac. Agron. (LUZ). 2023, 40(3): e234029. July-September. ISSN 2477-9407.2-7 |
Resumen
Los frutos del bosque o berries son una fuente rica de
tonutrientes, especialmente de compuestos fenólicos como los
avonoides, que tienen propiedades antioxidantes. Entre estos frutos,
los más cultivados y consumidos son los del género Fragaria (Fresas)
y Rubus (Frambuesas, moras, zarzamoras), que han sido ampliamente
estudiados por sus efectos benécos para la salud humana y animal. Uno
de los compuestos bioactivos más importantes de estos frutos son las
antocianinas, que han demostrado potenciales benecios para la salud
por su actividad antimicrobiana, antiinamatoria y anticancerígena.
Por ello, el estudio de las antocianinas es de gran interés farmacéutico
y nutraceútico. El objetivo de esta investigación es analizar los
mecanismos biocinéticos de las antocianinas en Rubus adenotrichos y
Fragaria x ananassa producidos en el estado de Michoacán, México.
Para ello, se utilizaron estrategias de investigación que incluyeron la
extracción y cuanticación de antocianinas, así como herramientas
bioinformáticas para comprender su vía biosintética en los frutos
mencionados. El uso de las plataformas informáticas permitió
identicar los genes reguladores y las enzimas que intervienen en
la biosíntesis de antocianinas en R. adenotrichos y F. x ananassa,
encontrando que la mayoría son comunes, con algunas diferencias
especícas, y que solo hay unas pocas excepciones, como las enzimas
catecol-O-metiltransferasa (OMT), UDP-glucosiltransferasa (UGT)
y beta-glucuronidasa (GUSB), que solo se presentan en Rubus
adenotrichos y no en Fragaria x ananassa.
Palabras clave: tonutrientes, Fragaria x ananassa, Rubus
adenotrichos, antioxidantes, HPTLC.
Resumo
Os frutos silvestres ou berries são uma fonte rica de tonutrientes,
especialmente de compostos fenólicos como os avonoides, que têm
propriedades antioxidantes. Entre estes frutos, os mais cultivados
e consumidos são os do gênero Fragaria (morangos) e Rubus
(framboesas, amoras, amora-preta), que têm sido amplamente
estudados por seus efeitos benécos para a saúde humana e animal.
Um dos compostos bioativos mais importantes destes frutos são as
antocianinas, que têm demonstrado potenciais benefícios para a saúde
pela sua atividade antimicrobiana, anti-inamatória e anticancerígena.
Por isso, o estudo das antocianinas é de grande interesse farmacêutico
e nutracêutico. O objetivo desta pesquisa é analisar os mecanismos
biocinéticos das antocianinas em Rubus adenotrichos e Fragaria x
ananassa produzidos no estado de Michoacán, México. Para isso,
foram utilizadas estratégias de pesquisa que incluíram a extração e
quanticação de antocianinas, bem como ferramentas bioinformáticas
para compreender sua via biossintética nos frutos mencionados.
O uso das plataformas informáticas permitiu identicar os genes
reguladores e as enzimas envolvidas na biossíntese de antocianinas
em R. adenotrichos e F. x ananassa, encontrando que a maioria são
comuns, com algumas diferenças especícas, e que há apenas algumas
exceções, como as enzimas catecol-O-metiltransferase (OMT), UDP-
glucosiltransferase (UGT) e beta-glucuronidase (GUSB), que só
ocorrem em Rubus adenotrichos e não em Fragaria x ananassa.
Palavras chave: tonutrientes, Fragaria x ananassa, Rubus
adenotrichos, antioxidantes, HPTLC.
Introduction
Berries are crops that have great agricultural potential, due to
their protability, being an activity with high labor requirements,
versatility in production for consumption and wide export possibilities
(Lagunes-Fortiz et al., 2020). Mexico has a cultivated area of berries
and has high productive potential in the state of Michoacán, Mexico.
(SAGARPA, 2017) in addition to exporting about 41 % of the national
production of berries to countries such as: Netherlands, United
States of America and Canada (Mexicana et al., 2019) Strawberries
(Fragaria x ananassa), belonging to the Rosaceae family, contain
particularly abundant secondary metabolites. These metabolites have
been of great interest in the investigation of phenolic compounds
such as avonols, anthocyanins, proanthocyanidins, phenolic acids,
ellagitannins, and galiolglucoses (Haugeneder et al., 2018). The
conjugated bonds of anthocyanins result in owers and fruits with
purple, blue, and red coloration (Salinas Moreno et al., 2013).
Since anthocyanins are polar in nature they can be easily dissolved
in dierent solvents such as methanol, ethanol, water and acetone.
High performance thin layer chromatography (HPTLC) analytical
techniques are widely used for the quantication of anthocyanins.
The objective of this research is to analyze the biokinetic mechanisms
of anthocyanins in Rubus adenotrichos and Fragaria x ananassa
produced in the state of Michoacán, Mexico.
Materials and methods
Comparative study of metabolic pathways
A study focused on the anthocyanin biosynthetic pathway in Rubus
adenotrichos and Fragaria x ananassa was carried out by developing
the metabolic pathway of anthocyanin synthesis and breakdown in
the genus Rubus based on data recorded in NCBI, GDR, KEGG and
BlastKOALA,
Anthocyanin extraction and HPTLC analysis
Multiple lots of “Sayulita” strawberries and “Tupy” blackberries
were acquired from the agricultural regions of the state of Michoacán.
The strawberries were obtained from “Cerrito de Cotijarán” and the
blackberries were obtained from the municipality of “Los Reyes
de Salgado”, both samples in a ripe, fresh, and rm consistency.
The batches of each species were mixed with a high-performance
dispersion instrument to acquire more representative samples. For
anthocyanin extraction, the procedure described by Brito et al. (2014)
was used, which consisted of taking three (3) g of sample and 15 mL
of acidied ethanol (Ethanol and 1N HCl; 85:15 v/v) and macerated
in a mortar. Subsequently, the solutions were vortexed vigorously and
the pH was adjusted to 1 with hydrochloric acid.
The solutions were then shaken (EBERBACH
®
reciprocating
shaker) at 120 rpm for 16 h at room temperature. After this time, the
solutions were centrifuged at 3,000 rpm for 30 min, the supernatant
was recovered, and made up to 25 mL with acidied ethanol. Samples
were stored at -20 °C until use. Subsequently, 1 mg of the standard
anthocyanins pelargonidin-3-glucoside and cyanidin-3-glucoside in
chloride salt form (Sigma-Aldrich®, USA) was dissolved in 10 mL
of acidied methanol respectively (0.5% HCl) (0.1 mg.mL
-1
). After
sample preparation, the samples were analyzed by HPTLC. Silica
gel plates 60, 10 x 20 cm, with uorescence indicator F254 (Merck
®
,
Switzerland) were used. A 25 µL syringe was used for sample
application. Sample application was performed automatically using
the Automatic Sampler 4 (ATS4, Camag
®
) at a distance of 8 mm from
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Quiroz et al. Rev. Fac. Agron. (LUZ). 2023 40(3): e234029
3-7 |
the bottom edge of the plate. The left - right distance (edges) for a plate
with 14 applications was 48 mm. The distance between applications
was 8 mm. The samples were applied in the form of 6 mm strips. A
sample volume of 8 µL of Rubus adenotrichos and 15 µL of Fragaria
x ananassa was applied. After sample application, the plates were
automatically developed in the Automatic Development Chamber 2
(ADC 2, Camag
®
), with the following conditions: equilibration time
ve (5) min, temperature 20 ± 2 °C, relative humidity was adjusted to
33 ± 2 % (MgCl
2
, 260 g per 100 H
2
O). The humidity at the beginning
of the analysis was 77 % and at the end was 67 %. The plate was
developed in 10 mL of mobile phase (ethyl acetate/acetic acid/acetic
acid/formic acid/water (AE/AA/AF/A), ratio 100:11:11:11:27, v/v/v/
v/v). The migration distance was 70 mm and the migration time was
30 min. After development, the plate was dried for ve (5) min, in the
same chamber. The developed plates were removed from the chamber
and evaluated with transmitted white light, UV light 366 nm and 254
nm using the TLC Visualizer (Camag
®
). The data were processed with
Camag
®
visionCATS software. After chromatographic separation, the
plate was heated in the TLC Plate Heater III (Camag
®
) at 100 °C for
ve (5) min. Derivatization with a 1 % solution of Natural Products
was carried out to reveal phenolic and avonoid compounds (1 g of
diphenylboryloxyethanolamine diluted in 100 mL of methanol) in the
TLC Immersion Device III (Camag
®
) at a vertical speed of 3 cm.s
-1
.
The immersion time was three (3) seconds. After derivatization, the
plate was dried with cold air for ve (5) min.
Linearity and quantication
The verication of the normal distribution of the results was
evaluated with the linearity through the relationship between the
concentration of cyanidin-3-glucoside, pelargonidin-3-glucoside
and the absorbance of the HPTLC detector. The calibration line was
performed for the cyanidin-3-glucoside and pelargonidin-3-glucoside
compounds that were analyzed and, thus, to know the extent of the
total variability of the response that could be explained by the linear
regression model.
The quantication of the concentration of the compounds was
determined through a working factor obtained by dividing the
concentration of the working standard (mg.L
-1
) by the absorbance
milli-units of the area in the standard. Subsequently, the sample
values were obtained and the respective factor of the standard was
multiplied by the area of the test sample.
Identication of genes of anthocyanin biosynthetic enzymes
Genomic DNA (gDNA) was extracted from the samples using
the specialized Wizard Genomic DNA Purication Kit Technical
Manual - Promega, following the manufacturer’s instructions. The
oligonucleotides described by Chen et al. (2012) were used (table 1).
PCR reactions were performed on a Veriti thermal cycler from Applied
Biosystems, with the following program: an initial denaturation cycle
at 95 ºC for 3 min, 25 denaturation cycles at 95 ºC for 30 s, alignment
at 55 ºC for 30 s and extension at 72 ºC for 30 s, and a nal extension
cycle at 72 ºC for 3 min and 34 s.
Results and discussion
Comparative study of metabolic pathways
Tables 2a and 2b show the results of the enzymes involved in
anthocyanin biosynthesis in Rubus adenotrichos and Fragaria x
ananassa as a comparative control method.
The development of anthocyanins in ripening berries involves
the coordinated expression of genes encoding a number of enzymes
involved in phenylpropanoid synthesis. Recent research has focused
on the development of heat maps depicting the transcriptomic proles
of the key avonoid pathway and anthocyanin biosynthetic enzymes,
modifying enzymes, and their respective transcriptional regulatory
genes (Garcia-Seco et al., 2015; Thole et al., 2019). Based on the
comparative analyses performed, it was observed that the biosynthetic
enzymes are: phenylalanine ammonia lyase (PAL), anthocyanidin
reductase (ANR), chalcone synthase (CHS), anthocyanidin synthase
(ANS), chalcone isomerase (CHI), dihydroavonol 4-reductase
(DFR), avonone 3-hydroxylase (F3H), avonone synthase (FNS)
and avonol synthase (FLS). Similarly, it was recorded that the main
pathway modifying enzymes are uridine diphosphate-glucose (UDP),
avonoid-O-glucosyl transferase (UFGT) and beta-glucuronidase
(GUSB); while the transcriptional regulatory genes are MYB, bHLH
and WDR (Jaakola, 2013).
Table 1. List of oligonucleotides for amplication of genes of interest in Rubus adenotrichos (R.a) and Fragaria x ananassa (F.a),
describing the size of the expected products.
Gene Description Amplied Sequence (5’-3’) Amplicon reported
pRuCHS
F CAG TGA CAC CCA CCT TGA CAGT 58
R TGC TGC ACC ATC ACC GAAT
pRuANS
F GGC CTC GGG AAA AAT TCA AG 56
R GCC CGG AAG CAT TGT TTG
pRuDFR
F ACA GTT CGA AGG CTG GTG TTT AC 63
R CTT CTG GTG CTC TTC GAC ATA CA
pRuGT
F GGA GCT GAA GAA AAG ACT CCA GAA 63
R GCC CGG AAG CAT TGT TTG
pRuANR
F TCT CTG ATG GCT GGT GCT AGT C 60
R CGT GGC GAG GCC AAT ACT
pRuLAR
F GCA TCC TTC CGA GGT TGT TC 62
R TGA CAG TGC CAT CAC CGT AGA
pβ-actina
F TGA CAA TGG GAC TGG AAT GGT 57
R GCC CTG GGA GCA TCA TCA
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Rev. Fac. Agron. (LUZ). 2023, 40(3): e234029. July-September. ISSN 2477-9407.4-7 |
Taking into consideration the name of the enzyme present in
the metabolic pathway, its respective enzyme identication code
was searched in KEGG and recorded in the comparative table. In
the process, to achieve the acquisition of the participating enzyme
code, BlastKOALA Rubus chingii was searched. Based on the
results acquired from the platform, each enzyme that was available
was identied and corroborated, and it was compared whether it
was also present in Fragaria x ananassa. Subsequently, the enzyme
identication code KEGG was introduced in the NCBI platform for
the GenBank code registry.
HPTLC analysis
In the samples of Rubus adenotrichos and Fragaria x ananassa,
it was observed that both fruits had abundant concentrations of the
main anthocyanin by which they are recognized. The chromatograms
obtained from the comparison of fruit samples with the standard
samples of cyanidin-3-glucoside and pelargonidin-3-glucoside
are shown below, the results are shown in gures 1 and 2 and also
visualizing the retention factor (Rf) of the compound pelargonidin-
3-glucoside (Pg3G), which was 0.54, while for cyanidin-3-glucoside
(Cy3G) it was 0.43 (gures 1 and 2, respectively).
Table 2a. Comparison of enzymes involved in anthocyanin biosynthesis for Rubus adenotrichos and Fragaria x ananassa.
KEGG Gene Bank Enzyme Biosynthesis pathway Rubus adenotrichos Fragaria x ananassa
EC 4.3.1.24 AAF40223,1 Phenylalanine ammonia lyase (PAL) phenylpropanoid O O
EC:1.3.1.77 AMP19723,1 Anthocyanidin reductase (ANR) Flavonoid O O
EC:1.14.204 AQP31154,1 Anthocyanidin synthase (ANS) Flavonoid O O
EC:2.3.1.74 AEQ61979,1 Chalcone synthase (CHS) Flavonoid O O
EC:5.5.1.6 S14705 Chalcone isomerase (CHI) Flavonoid O O
EC:1.1.1.219 AXK92787,1 Dihydroavonol 4-reductase (DFR) Flavonoid O O
EC 1.14.20.5 CAP09052,1 Flavonova synthase (FNS) Flavonoid X O
EC 1.14.11.9 ABX74780,1 Flavonone 3 - hydroxylase (F3H) Flavonoid O O
Note: In the comparative table, the symbol “O” represents that the genus carries the enzyme, while “X” represents that at least one of the fruits does not have the enzyme
or it has not been reported.
The comparative table was elaborated based on the data registered in “G.D.R”, “K.E.G.G” and “BlastKOALA”, for the verication of the reported ndings.
Table 2b. Continued comparative of enzymes involved in anthocyanin biosynthesis for the genus Rubus adenotrichos and Fragaria x
ananassa.
KEGG Gene Bank Enzyme Biosynthesis pathway Rubus adenotrichos Fragaria x ananassa
EC 1.14.20.6 AAZ78661, Flavonol Synthase (FLS) Flavonoid O O
EC 2.1.1.6 AEA30241,1 Catechol O - methyltransferase (OMT) Betalains O X
EC 1.17.1.3 AFD54430,1 Leucoanthocyanidin reductase (LAR) Flavonoid O O
EC:1.14.20.4 AAG50980,1 Leucoanthocyanidin deoxygenase (LDOX) Flavonoid X O
EC:2.4.1.271 AWT04749,1 UDP-glycosyl transferase (UGT) Secondary metabolites O X
EC2.4.1.91 AF171901,1 Flavonoid-O-glycosyl transferase (UFGT) Flavone and Favonol O O
EC3.2.2.31 WP000945878,1 Beta-glucuronidase (GUSB) Flavone and Flavonol O X
Note: In the comparative table, the symbol “O” represents that the genus carries the enzyme, while “X” represents that at least one of the fruits does not have the enzyme
or it has not been reported.
The table was prepared based on the data recorded in “G.D.R”, “K.E.G.G” and “BlastKOALA”, for the verication of the reported ndings.
Figure 1. Chromatogram of Fragaria x ananassa. Chromatogram
of strawberry extracts derivatized with Natural
Products, with white light. One plate required to
perform the experiment in triplicate (15 µL). From right
to left, last ve lanes: Pelargonidin-3-glucoside (Rf =
0.54). From left to right, Lanes 1-9: natural strawberry
fruits.
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Quiroz et al. Rev. Fac. Agron. (LUZ). 2023 40(3): e234029
5-7 |
Figure 2. Chromatogram of Rubus adenotrichos. Chromatogram
of blackberry extracts derivatized with Natural
Products, with white light. Only one plate required to
perform the experiment in triplicate (8 µL). From right
to left, last ve lanes: Cyanidin-3-glucoside (Rf = 0.43).
From left to right, Lanes 1-9: natural blackberry fruits.
The quantication data of Pg3G present in the extracts of Fragaria
x ananassa and Cy3G in Rubus adenotrichos can be visualized in
table 3. The anthocyanin quantication data corresponding to the
concentration in volume, amount applied on the band of the plate and
amount of anthocyanin present in one gram of dry weight are shown
in table 3.
The performance data of the HPTLC method for the determination
of anthocyanins in the extracts are shown in table 4, the method was
validated for instrumental precision, repeatability, specicity and
linearity.
Records described by (Hurtado and Pérez, 2014) mention that the
approximate amount of pelargonidin-3-glucoside that can be found
in dry weight in strawberries is around 726.14 µg.g
-1
. While, for
blackberries the amount of cyanidin-3-glucoside that can be found
in the fruit in dry weight range from 0.30 to 0.40 mg.g
-1
(Bhagwat et
al., 2013).
Table 3. Quantication of Cy3G and Pg3G.
Rubus adenotrichos
Cyanidin-3-glucoside (Samples)
Volume 8 mL Concentration (mg.mL
-1
) ng.Band
-1
mg.g
-1
dry weight
Track 2 12.29 98.35 0.31
Track 3 14.48 115.9 0.36
Track 4 16.61 132.9 0.42
Track 5 19.29 154.4 0.48
Track 6 19.84 158.7 0.5
Track 7 18.76 150.1 0.47
Track 8 17.42 139.4 0.44
Track 9 12.73 101.8 0.32
Mean 16.43 131.44 0.41
Std. Dev. 2.95 23.6 0.07
Rubus adenotrichos
Pelargonidin-3-glucoside (Samples)
Volume 15 mL Concentration (mg.mL
-1
) ng.Band
-1
mg.g
-1
dry weight
Track 2 56.18 842.7 1.40
Track 3 56.02 840.3 1.40
Track 4 60.68 910.2 1.52
Track 5 67.73 1.016 1.69
Track 6 68.86 1.033 1.72
Track 7 67.74 1.016 1.69
Track 8 58.45 876.8 1.46
Mean 62.24 933.57 1.56
Std. Dev. 5.72 85.83 0.14
Note: Anthocyanin quantication data corresponding to the concentration in volume, amount applied on the plate band and amount of anthocyanin present in one gram of
dry weight.
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Quiroz et al. Rev. Fac. Agron. (LUZ). 2023 40(3): e234029
6-7 |
Table 4. HPTLC Analysis Results.
Genre Compound Rf Equation Regression
Mode
Correlation
coecient ®
Coecient of
Variation
Rubus adenotrichos
Cyanidin-3-glucoside 0.43
Y = 3.485 x 10
-7
x
Linear 91.383026 % 14.1693 %
Fragaria x ananassa
Pelargonidin-3-glucoside 0.54
Y = [(2.908 x 10
-1
x) / (3.587 x 10
-6
+ x)] – 2.809 x 10
-2
Polynomial 99.527551 % 3.7992 %
Note: Performance data of the HPTLC method for the determination of cyanidin-3-glucoside in Rubus adenotrichos and pelargonidin-3-glucoside in Fragaria x ananassa.
The ve (5) point calibration curve indicates limits of
quantication for each fruit: 1.1 - 5.5 (µg.Band
-1
) for Pg3G in F. x
ananassa and 1.1 - 3.3 (µg.Band
-1
) for Cy3G for R. adenotrichos.
gures 3 and 4 respectively.
Figure 3. Polynomial regression line for Fragaria x ananassa.
Polynomial calibration of the pelargonidin-3-glucoside
standard performed by maximum height in white
light, with a correlation coecient of 99.527551 %. (Y
= [(2.908 x 10
-1
x) / (3.587 x 10
-6
+ x)] - 2.809 x 10
-2
).
Figure 4. Linear regression line for Rubus adenotrichos. Linear
calibration of the cyanidin-3-glucoside standard
performed by maximum height in white light, with a
correlation coecient of 91.383026 %. (Y = 3.485 x 10
-7
x).
The HPTLC analysis proved to be an excellent technique to
obtain the anthocyanin concentrations in the fruits of R. adenotrichos
and F. x ananassa, based on what is reported in the literature.
Molecular identication of anthocyanins
The enzymes that perform the conversion of phenylalanine to
anthocyanins and proanthocyanidins are: chalcone synthase (CHS),
dihydroavonol reductase (DFR), anthocyanidin synthase (ANS),
glycosyltransferase (GT), leucoanthocyanidin reductase (LAR) and
anthocyanidin reductase (ANR). The rst 3 enzymes CHS, DFR and
ANS allow the generation of former substrates for anthocyanins and
avonols. While the last mentioned enzymes GT, LAR and ANR,
perform glycosylation processes to increase the water stability of
anthocyanins and redirect two distinct pathways for the synthesis of
avonols and proanthocyanidin polymers, respectively (Chen et al.,
2012).
In the PCR analysis of Rubus adenotrichos and Fragaria x
ananassa, the expected products were as described in Table 1, with
a fragment size of less than 100 base pairs, as described in Figure
5. This means that, based on the gDNA extracted and incorporated
with the requested oligonucleotides, both fruits have practically all
the regulatory genes involved in anthocyanin biosynthesis.
Figure 5. Detection of amplied products in R. adenotrichos
and F. x ananassa. Oligonucleotide amplication
using a gDNA sample from R. adenotrichos (A) was
found to be positive in its entirety. Similarly, most of
the oligonucleotides to be examined were shown to be
present in the gDNA samples for F. x ananassa (B), with
the exception of the pRuGT and pβ-actin oligos.
The lack of amplication of pRuGT and pβ-actin genes in gDNA
of F. x ananassa is supported by previous studies carried out in the
Arabidopsis thaliana and Vitis vinifera genera, where it is noted
that the amplication of this gene is observed during the early stage
of the fruit, when it is green, and decreases when the fruit is ripe
(Khater et al., 2012). This background would support the absence
of amplication, because during the experimental process we
worked with ripe fruit and not in the early green stage. There are
several glycosyltransferases (GT) that transfer sugars to a variety of
acceptors ranging from secondary metabolites and hormones to biotic
and abiotic chemicals (Chen et al., 2012).
Conclusions
Through the use of the informatics platforms we were able to
identify the regulatory genes and enzymes involved in anthocyanin
biosynthesis in R. adenotrichos and F. x ananassa, nding that most
are common, with some specic dierences, and that there are only
a few exceptions, such as the enzymes catechol-O-methyltransferase
(OMT), UDP-glucosyltransferase (UGT) and beta-glucuronidase
(GUSB), which are only present in Rubus adenotrichos and not in
Fragaria x ananassa. These results were corroborated by metabolic
and molecular analyses, which allowed us to obtain the anthocyanin
concentrations in the fruits of R. adenotrichos and F. x ananassa, in
agreement with those reported in the literature.
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Quiroz et al. Rev. Fac. Agron. (LUZ). 2023 40(3): e234029
7-7 |
Acknowledgments
To the Centro de Biotecnología Genómica del Instituto Politécnico
Nacional, as well as to the project SIP 20221377, for the funding
granted for this research, the IPN EDI system and to the IBT Jaime
Alberto Morales Baquera, thesis student and BEIFI IPN student.
Literature cited
Brito, A., Areche, C., Sepúlveda, B., Kennelly, E., & Simirgiotis, M. (2014).
Anthocyanin Characterization, Total Phenolic Quantication and
Antioxidant Features of Some Chilean Edible Berry Extracts. Molecules,
19(8), 10936–10955. https://doi.org/10.3390/molecules190810936
Chen, Q., Yu, H., Tang, H., & Wang, X. (2012). Identication and expression
analysis of genes involved in anthocyanin and proanthocyanidin
biosynthesis in the fruit of blackberry. Scientia Horticulturae, 141, 61–68.
https://doi.org/10.1016/J.SCIENTA.2012.04.025
Garcia-Seco, D., Zhang, Y., Gutierrez-Mañero, F. J., Martin, C., & Ramos-Solano,
B. (2015). Application of Pseudomonas uorescens to Blackberry under
Field Conditions Improves Fruit Quality by Modifying Flavonoid
Metabolism. PLoS ONE 10(11), e0142639. https://doi.org/10.1371/
journal.pone.0142639
Haugeneder, A., Trinkl, J., Härtl, K ·, Homann, T., James, ·, Allwood, W., &
Wilfried, S. (2018). Answering biological questions by analysis of the
strawberry metabolome. Metabolomics, 14, 145. https://doi.org/10.1007/
s11306-018-1441-x
Hurtado, N. H., & Pérez, M. (2014). Identicación, Estabilidad y Actividad
Antioxidante de las Antocianinas Aisladas de la Cáscara del Fruto de
Capulí (Prunus serotina spp capuli (Cav) Mc. Vaug Cav). Información
Tecnológica 25(4), 131-140. https://doi.org/10.4067/S0718-
07642014000400015
Jaakola, L. (2013). New insights into the regulation of anthocyanin biosynthesis in
fruits. Trends in Plant Science, 18(9), 477–483. https://doi.org/10.1016/J.
TPLANTS.2013.06.003
Khater, F., Fournand, D., Vialet, S., Meudec, E., Cheynier, V., & Terrier, N.
(2012). Identication and functional characterization of cDNAs coding
for hydroxybenzoate/hydroxycinnamate glucosyltransferases co-
expressed with genes related to proanthocyanidin biosynthesis. Journal
of Experimental Botany, 63(3), 1201–1214. https://doi.org/10.1093/jxb/
err340
Lagunes-Fortiz, E. R., Lagunes Fortiz, E., Gómez-Gómez, A. A., Leos-Rodríguez,
J. A., Omaña-Silvestre, J. M., Lagunes-Fortiz, E. R., Lagunes-Fortiz,
E., Gómez-Gómez, A. A., Leos-Rodríguez, J. A., & Omaña-Silvestre, J.
M. (2020). Competitividad y rentabilidad de la producción de frutillas
en Jalisco. Revista Mexicana de Ciencias Agrícolas, 11(8), 1815–1826.
https://doi.org/10.29312/remexca.v11i8.2595
SAGARPA. (2017). Frutas del bosque arándano, frambuesa zarzamora Mexicanas
planeación agrícola nacional.
Salinas Moreno, Y., García Salinas, C., Coutiño Estrada, B., & Vidal Martínez, V.
A. (2013). Variabilidad en contenido y tipos de antocianinas en granos de
color azul/morado de poblaciones mexicanas de maíz. Revista Fitotecnia
Mexicana, 36, 285–294. http://www.scielo.org.mx/scielo.php?script=sci_
arttext&pid=S0187-73802013000500005&lng=es&nrm=iso&tlng=es
Thole, V., Bassard, J. E., Ramírez-González, R., Trick, M., Ghasemi Afshar,
B., Breitel, D., Hill, L., Foito, A., Shepherd, L., Freitag, S., Nunes Dos
Santos, C., Menezes, R., Banãdos, P., Naesby, M., Wang, L., Sorokin, A.,
Tikhonova, O., Shelenga, T., Stewart, D., … Martin, C. (2019). RNA-seq,
de novo transcriptome assembly and avonoid gene analysis in 13 wild
and cultivated berry fruit species with high content of phenolics. BMC
Genomics, 20(1). https://doi.org/10.1186/S12864-019-6183-2
