jurnal internasional fitokimia
Cyanogenic
Glucosides and Derivatives in
Almond and Sweet Cherry Flower
Buds from Dormancy to Flowering
Jorge Del Cueto1,2,3†, Irina A. Ionescu2,3†, Martina Picmanováˇ2,3, Oliver Gericke2,3, Mohammed S. Motawia2,3, Carl E. Olsen2, José A. Campoy4,
Federico Dicenta1, Birger L. Møller2,3 and Raquel Sánchez-Pérez2,3*
1Department of Plant
Breeding, CEBAS-CSIC, Murcia, Spain, 2 Plant Biochemistry Laboratory, Department of
Plant and Environmental Sciences, University of Copenhagen, Frederiksberg,
Denmark, 3 VILLUM Research Center for
Plant Plasticity, University of Copenhagen, Frederiksberg, Denmark, 4 UMR 1332 BFP, INRA,
University of Bordeaux, Villenave d’Ornon, France
Almond and sweet cherry are
two economically important species of the Prunus genus. They both produce the
cyanogenic glucosides prunasin and amygdalin. As part of a two-component
defense system, prunasin and amygdalin release toxic hydrogen cyanide upon cell
disruption. In this study, we investigated the potential role within prunasin
and amygdalin and some of its derivatives in endodormancy release of these two Prunus
species. The content of prunasin and of endogenous prunasin turnover products
in the course of flower development was examined in five almond cultivars –
differing from very early to extra-late in flowering time – and in one sweet
early cherry cultivar. In all cultivars, prunasin began to accumulate in the
flower buds shortly after dormancy release and the levels dropped again just
before flowering time. In almond and sweet cherry, the turnover of prunasin
coincided with increased levels of prunasin amide whereas prunasin anitrile
pentoside and b-D-glucose-1-benzoate were
abundant in almond and cherry flower buds at certain developmental stages.
These findings indicate a role for the turnover of cyanogenic glucosides in
controlling flower development in Prunus species.
Keywords: amygdalin,
dormancy, flowering time, LC-MS/MS, prunasin, prunasin derivatives, qRT-PCR
INTRODUCTION
Cyanogenic glucosides
(CNglcs) are defense compounds present in more than 3,000 plant species (Gleadow and Møller,
2014)
including economically important fruit trees such as almond (Prunus dulcis Miller D.A. Webb syn.
P. amygdalus Batsch) and sweet cherry (P.
avium L.). Both fruit trees
contain the phenylalanine-derived CNglcs prunasin and amygdalin. Prunasin is a b-D-monoglucoside of R-mandelonitrile (Kuroki and Poulton,
1987;
Swain et al., 1992; Hu and Poulton, 1999; Neilson et al., 2011) and a precursor
for the diglucoside amygdalin in which the two glucose moieties are b-(1!6)
linked (gentiobiose). In the bitter-kernelled almond cultivars, prunasin is
present in the tegument, endosperm, nucella, and cotyledons at the early stages
of seed development (Frehner et al., 1990; Dicenta et al., 2002; Sánchez-Pérez et al., 2008). Amygdalin accumulates at the
later state of fruit kernel development (Sánchez-Pérez et al., 2008) where its
content in the kernel is around 100-fold higher compared to prunasin (Dicenta et al., 2002; Sánchez-Pérez et al.,
2008). Conversely, prunasin is present in high amounts compared to
amygdalin in the vegetative
parts of the almond tree such as leaf, petiole, stem, and root – with no major
differences in the ratios observed between sweet and bitter cultivars. Both
CNglcs are synthesized de novo in the
kernel but only amygdalin is accumulated in bitter kernels (Sánchez-Pérez et al.,
2008).
In sweet cherry, prunasin is present in flowers, fruits, stems, and seeds,
whilst amygdalin is present in fruits and seeds only (Nahrstedt, 1972).
Biosynthesis of
prunasin and amygdalin (Figure 1) involves the initial
conversion of L-phenylalanine (Phe) (Mentzer and Favrebonvin, 1961) into mandelonitrile by the action of
the
two
cytochromes P450 called CYP79D16 and CYP71AN24, recently characterized in
Japanese apricot (P. mume Sieb. et
Zucc) (Yamaguchi et al.,
2014). An UDP-glucosyltransferase (UGT1, UGT85A19) catalyzes the
conversion of mandelonitrile into prunasin (Franks et al., 2008). Finally, an unknown
glucosyltransferase (UGT2) catalyzes the conversion of prunasin into amygdalin
(Figure 1A).
The classic
physiological function assigned to CNglcs is in chemical defense against
pathogens and herbivores. This two-component defense system involves b-glucosidase
and a-hydroxynitrilelyase-catalyzed hydrolysis of CNglcs resulting in the
release of toxic hydrogen cyanide. The system is detonated when the CNglcs and
their hydrolytic enzymes get into contact as a result of tissue and cell
destruction, e.g., by herbivore attack. In this bioactivation process,
amygdalin is converted into prunasin and glucose by amygdalin hydrolase (AH).
Prunasin hydrolase (PH) converts prunasin into mandelonitrile and glucose (Kuroki and Poulton,
1987;
Li et al., 1992; Zheng and Poulton, 1995; Zhou et al., 2002; Sánchez-Pérez et al., 2008, 2010, 2012) Mandelonitrile
lyase 1 (MDL1) catalyzes the dissociation of mandelonitrile into benzaldehyde and
hydrogen cyanide (Swain and Poulton, 1994a; Zheng and Poulton, 1995; Suelves and
Puigdomènech, 1998; Hu and Poulton, 1999), two compounds that are bitter and toxic, respectively (Evreinoff, 1952) (Figure 1B).
To avoid
hydrogen cyanide intoxication, plants have developed a detoxification pathway
in which b-cyanoalanine synthase (b-CAS) catalyzes the conversion of hydrogen
cyanide into b-cyanoalanine (Figure 1C). In a subsequent
reaction, a type 4 nitrilase catalyzes hydration of b-cyanoalanine resulting in
the production of asparagine or aspartate and ammonia (Piotrowski, 2008). Evidence for the operation of two endogenous
turnover pathways for cyanogenic glucosides has recently been provided (Picmanovᡠet al., 2015; Nielsen et al., 2016). In both these pathways, the
nitrogen of the cyanogenic glucoside is recovered as ammonia without any release of
hydrogen cyanide (Figure 1D).
Other potential
physiological functions of CNglcs include a role as transporters of carbon and
nitrogen (Selmar et al.,
1988),
suppliers of reduced nitrogen in form of ammonia (Sánchez-Pérez et al., 2008; Nielsen et al., 2016), as modulators
of oxidative stress (Møller, 2010; Neilson et al., 2013) and as regulators of seed germination (Swain and Poulton,
1994b; Picmanovᡠet al., 2015). Seed germination is a
developmental process closely related to bud dormancy release (Wareing and Saunders,
1971; Rohde and Bhalerao, 2007). CNglcs
metabolism has also been hypothesized
to contribute to the
nitrogen pool, thereby enabling bud opening (Gleadow and Woodrow, 2000). The levels of CNglcs and
their metabolites in flower buds during endodormancy release have not
previously been reported. In temperate climates, bud dormancy is the adaptive
mechanism of perennial plant species to counteract the harsh environmental
conditions of winter and is controlled by the required accumulation of chill
and the subsequent accumulation of heat. This process enables the plant to time
flowering and leafing to profit from weather conditions that are favorable for
growth and development. Flowering will only happen when dormancy is broken (Fennell, 1999).
The flowering time is mainly determined by the
cultivar-
dependent chill requirements, with heat requirements being less
important (Egea et al., 2003). The chill requirements necessary
for dormancy release and flowering have been studied in Prunus
species such as apricot (P.
armeniaca L.) (Ruiz et al., 2007),
sweet cherry (Alburquerque et
al., 2008), peach (P. persica L.)
(Weinberger, 1950), plum (P.
domestica L.) (Okie and Hancock,
2008) and almond (Egea et al., 2003; Sánchez-Pérez et
al., 2010,
2014).
When the chill
requirements are low, e.g., in early-flowering cultivars, late winter or cold
temperatures in spring may cause yield loss by frost (Scorza and Okie, 1991). Flowering time is one of
the most important agronomic traits in almond, since late flowering cultivars
counteract crop loss caused by late spring frosts (Dicenta et al., 2005). In sweet cherry, the
situation is opposite, as this species has a higher range of chill
requirements. Due to global warming, chill requirements are hardly fulfilled in
warmer production areas (Campoy et al., 2011). Therefore, different nitrogen- or sulfur-based dormancy-breaking
chemicals are applied by spraying to compensate for missing chill and to induce
flowering. The most successful chemical, commercially known as Dormex R (AlzChem, Trostberg,
Germany), is hydrogen cyanamide (Godini et al., 2008). Hydrogen cyanamide advances
flowering time up to 3 weeks and synchronizes bud break. This facilitates and
advances fruit harvest as well. Even though hydrogen cyanamide has been used
for many years in different fruit trees such as sweet cherry, peach, apricot,
kiwifruit, and grapevine, its molecular mechanism of action remains unknown (Ionescu et al., 2017). It has been
demonstrated in vitro that hydrogen
cyanamide can be converted to hydrogen cyanide and nitroxyl by the action of
catalase (Shirota et al.,
1987).
Hydrogen
cyanide has been implicated in seed germination (Zagórski and Lewak, 1983; Bogatek et al., 1991; Bethke et al., 2006; Oracz et al., 2009) and bud dormancy release (Tohbe et al., 1998). Hydrogen
cyanide release has been measured in different reproductive tissues of Eucalyptus cladocalyx (F. Muell). The
highest content was detectable in young buds, followed by older buds and
flowers (Gleadow and Woodrow, 2000). Due to the
cyanogenic nature of CNglcs, we hypothesize that they could be a source of hydrogen
cyanide and thus inducers of endodormancy release. The aim of this study was
therefore to investigate the possible role of CNglcs in endodormancy release of
almond and sweet cherry.
MATERIALS AND METHODS
Plant Material Sampling
Almond
Flower buds and different
parts of the flower (pistils, petals, and sepals) of five different almond
cultivars chosen by their differences in flowering time (very early: ‘Achaak’
and ‘Desmayo Largueta,’ early: ‘S3067,’ late: ‘Lauranne’ and extra-late: ‘Penta’)
(Table 1) were collected every 2 weeks, from November
5th, 2013 to March 24th, 2014 (11 time points), in the experimental orchard of
CEBAS-CSIC, in Santomera (Murcia, South-East Spain, 38.1095222, -1.037975).
With the exception of the bitter cultivar ‘S3067’ (sksk), all used cultivars are sweet-kernelled, defined by the
dominant Sk (Sweet kernel) gene locus
(Table 1).
Four to six
branches were collected per time point following the phenological stages A to F
(Felipe, 1977), as previously described
in (Sánchez-Pérez et
al., 2010).
Samples were snap-frozen in liquid nitrogen and kept at 80 C.
Sweet Cherry
Flower bud samples were
taken from sweet cherry trees of the cultivar ‘Burlat’ on ‘Santa Lucia’
rootstock, grown in the
experimental orchard of the
INRA Bordeaux in Toulenne (south-west France, 44.575503, -0.283008). ‘Burlat’
is considered a reference cultivar in sweet cherry. The chill requirements (Richardson et al., 1974) of ‘Burlat’ in Toulenne
were calculated (976 CU in 2015, Bénédicte Wenden, personal communication) and
when 709.5 CU were fulfilled – still in the endodormant state – 20 cm long
branches were cut from the trees and placed at controlled conditions in a
growth chamber (forcing conditions: 25 C day/20 C night, 16 h light/8 h dark (6–22:00),
30 mmol/m/s light intensity, direct lighting, 40% relative humidity). The
branches were immersed in tap water, which was changed every 3 days. Flower
buds [stage A–E according to Baggiolini (1952) (Figure 2)] were sampled up to 17 days after treatment,
always between 9 and 12 am. Samples were snap-frozen in liquid nitrogen and
kept at 80 C.
Accumulation of Chill and Heat for Breaking Dormancy and Flowering
Almond
Three 40 cm long branches
of each almond cultivar were collected every 2 weeks (Table 2) from the field and placed
in a growth chamber in controlled conditions (light period of 16 h at 25 C,
40% relative humidity and
darkness period of 8 h at 20 C and 60% relative humidity). The branches were
placed in jars and immersed in a 5% saccharose and 1% aluminum sulfate
solution, which was replaced every 5 days. The developmental stage of the
flower buds was measured 10 days later, establishing the date of endodormancy
release when 50% of the flower buds were in the BC stage. In the field, the
flowering date was determined as the date where 50% of the flowers of the tree
had fully opened (F stage).
Calculation of
chill requirements was performed in Chill Units (CU) according to the method of
Richardson et al.
(1974),
as a function of the number of hours at a certain temperature range accumulated
from November 15th. This method takes into account that temperatures outside
this range counteract chill accumulation (chill negation) (Erez et al., 1979).
Heat
requirements were calculated as growing degree hours (GDH), which is the hourly
temperature minus 4.5 C. The heat requirements of each cultivar were calculated
as the number of GDH accumulated between the release of endodormancy and
flowering time, when 50% of flowers were open (F50) (Table 1).
Sweet Cherry
Starting in November 2014,
the endodormancy status of ‘Burlat’ flower buds was determined. At each time
point, three branches were cut from the trees and placed in a growth chamber in
controlled conditions. Bud break was measured as the percentage of flower buds
that pass developmental stage BC (Baggiolini, 1952) (Figure 2). With 50% of
all flower buds beyond stage C, endodormancy was considered broken. In this experiment, it
was not possible to determine flowering time (50% of flowers open), because
only 18% of all flower buds opened to the point of a full flower. The reason
for this might be a lack of nutrient resources in the branches.
LC-MS Analysis
Cyanogenic glucosides were
analyzed as described previously (Picmanovᡠet al., 2015). Samples (100 mg) were
ground to a fine powder in liquid nitrogen, mixed with 400 mL 85% methanol,
boiled 5 min, placed on ice and centrifuged (5 min, 20,000 g). Aliquots (20 mL) of the supernatant were mixed with 70 mL of
water and 10 mL of 500 mM internal standard (linamarin) and filtered through a
filter plate (0.45 mm, Millipore) by centrifugation (5 min, 1,107 g).
LC–MS/MS was
carried out using an Agilent 1100 Series LC (Agilent Technologies) coupled to a
Bruker HCT-Ultra ion trap mass spectrometer (Bruker Daltonics). A Zorbax SB-C18
column (Agilent; 1.8 mm, 2.1 mm 50 mm) maintained at 35 C was used for
separation. The mobile phases were: (A) water with 0.1% (v/v) HCOOH and 50 mM
NaCl; (B) acetonitrile with
0.1% (v/v) HCOOH. The
gradient program was: 0–0.5 min, isocratic 2% B; 0.5–7.5 min, linear gradient 2–40%
B; 7.5–8.5 min, linear gradient 40–90% B; 8.5–11.5 min isocratic 90% B; 11.6–
17 min, isocratic 2% B. The flow rate was 0.2 ml min 1 but increased to 0.3 ml
min 1 in the interval 11.2–13.5
min. ESI– MS2 was run in positive mode.
The data was analyzed using the Bruker Daltonics programme Data Analysis 4.0.
Extracted ion chromatograms for specific [MCNa]C adduct ions (as NaCl is
added to one of the mobile phases, the great majority of adducts formed are [MCNa]C; we could also see [MCH]C and [MCNH4]C, but these are minute in
comparison with the sodium adducts) and their MS2 profiles were used to
identify the compounds.
Table 3 shows the
names, structures, and retention times of
all the compounds detected in this study. Amygdalin was bought from Sigma–Aldrich.
Prunasin was chemically synthesized (Møller et al., 2016). Prunasin amide, prunasin acid, prunasin
anitrile, 1-O-benzoyl-b-D-glucopyranose, prunasin-60-b-D-apioside and prunasin-60-b-D-xyloside were chemically
synthesized (Motawia MS, unpublished work). The reference compounds were used
for absolute quantification in a range of concentrations from 0.5 to 125 mM. As
for the relative quantifications presented, the ionization efficiency of prunasin
and its derivatives may differ by a factor of approximately two, and hence the
ratios expressed as percentages of prunasin content are correct within this
span (Picmanovᡠet
al., 2015).
The MS and
MS2 spectra observed for each
compound were in agreement with the spectra previously reported (Picmanovᡠet al., 2015).
Samples were
assayed in two to three technical replicates, except for the last time point of
the prunasin content in S3067.
qRT-PCR Analysis in Sweet
Cherry
Quantitative real-time
polymerase chain reaction (qRT-PCR) based expression analysis was carried out
on 12 selected genes using three reference genes (TEF2, 18s rRNA, and RPL13) (Table 4). The targeted gene
sequences were based on homologous
genes derived from different Prunus
species and preliminary transcriptomic data from sweet cherry ‘Burlat’ flower
buds (Ionescu et al.,
2017).
Sweet cherry ‘Burlat’
flower buds samples were obtained from branches kept for 1, 3, 7, 10, 15, and 17
days at controlled conditions. Frozen plant material was ground with mortar and
pestle in liquid nitrogen. For each sample, total RNA was extracted using the
SpectrumTM Plant Total RNA Kit (Sigma–Aldrich,
St. Louis, MO, USA) and 500 ng of RNA was used to generate cDNA using the
iScriptTM cDNA Synthesis Kit
(Bio-Rad, Hercules, CA, USA). Gene-specific primer pairs were designed for
target and reference genes using two web based tools: NCBI’s Primer-BLAST1 and IDT’s2 PrimerQuest©
(Table 4). Primer efficiencies were 82 12% and their
sequence specificity was determined by sequencing the amplicon and comparing it
to the original coding sequence used for initial primer design (see Supplementary
Data Sheet 1, DS1). Obtained sequences were aligned to the associated coding
sequences using a local alignment with Needleman–Wunsch algorithm (Needleman and Wunsch,
1970).
Herein, sequence coverage was 75 6% and identity was 83 9%.
qRT-PCR was
performed using a CFX384TM
real-time PCR detection system. Reactions were conducted in 8 ml volume using
the DyNAmo Flash SYBR Green qPCR Kit (Thermo Fisher Scientific, Waltham, MA,
USA) with each reaction containing 1x DyNAmo Flash SYBR Green qPCR Mix (2x), 5
ng of cDNA template and 625 nM of both forward and reverse primer. The
following PCR protocol was used: 7 min at 95 C, [10 s at 95 C, 30 s at 60 C, 1x
plate read] 40 cycles, 1 min at 60 C. A melting curve was performed for each reaction.
Further, no template controls as well as no RT controls were included. A
standard curve for TEF2 was used as interrun control using the deduced PCR
efficiency as factor
1http://www.ncbi.nlm.nih.gov/tools/primer-blast/;
last accessed on 10.04.2017
2http://eu.idtdna.com/Primerquest/; last accessed on 10.04.2017
for interrun deviation.
Relative gene expression levels were computed from the qPCR data using the 11Cq
calculation method (Livak and Schmittgen, 2001). Therein a normalization factor based on the
expressional variation of three reference genes among the examined samples was
used. This factor was obtained using geNorm version 3.5 (Vandesompele et al., 2002).
RESULTS AND DISCUSSION
Prunasin and Amygdalin in Flower Buds of Almond and Sweet Cherry
The CNglc prunasin (Table 3) was detected in all five almond cultivars during the entire
developmental period of the buds from dormancy to flowering (Figure 3A). Prunasin was also detected under controlled conditions in flower buds
of the sweet cherry ‘Burlat,’ but in levels approxiamtely 10-fold lower than in
almond (Figure 4A). Amygdalin, the other CNglc present in almond,
was detected in all five cultivars in minute amounts, approximately 200-fold
lower, compared to prunasin (Figure 3E). This is within the range
(37–300-fold lower) that had been previously observed in two almond cultivars
(Ramillete-sweet and S3067-bitter), when prunasin and amygdalin were measured
in the leaves of almond trees after the almonds had been harvested (Figure 5 in
Sánchez-Pérez et al.,
2008).
In sweet cherry flower buds, no amygdalin was detected. The di-glucoside
amygdalin is present in very minute amounts compared to the monoglucoside
prunasin and this is in agreement with a previous observation (Frehner et al., 1990; Dicenta et al., 2002; Sánchez-Pérez et al.,
2008). The situation is reverse in bitter almond seeds where amygdalin is the
dominating cyanogenic glucoside. In vegetative parts of the tree, prunasin is
always the dominating cyanogenic glucoside present.
In general,
during the entire dormancy-flowering period, the level of prunasin was highest
in the early cultivars Achaak and Desmayo, followed by S3067. Lauranne and
Penta contained the smallest amounts of prunasin (Figure 3A). The prunasin profiles
obtained shared clear relations to the dates of dormancy breaking and flowering
time. In all five almond cultivars as well as in the single sweet cherry
cultivar, prunasin started to accumulate at the time of dormancy release or
shortly thereafter and reached its maximum just before flowering took place.
This may suggest that prunasin plays a role in flower development after
dormancy is broken.
Dissection of
almond flowers enabled detection of prunasin and minute amounts of amygdalin in
pistils, petals and sepals of all five almond varieties (Supplementary Figure S1). S3067 was the only variety where prunasin
could be detected in the pollen, but the amount of pollen available was too low
to acquire biological and technical replicates. In relation to this, amygdalin
content has previously been reported in almond pollen at about 1890 ppm (London-Shafir et al.,
2003)
and reported to deter inefficient pollinators, thus allowing more efficient
pollination by honeybees, adapted to tolerate higher levels of amygdalin.
Prunasin had previously been reported detected in sepals, petals, pistils, and
pollen of flowers from bitter and sweet almond cultivars (Abarrategui, 2010). Amygdalin levels were
almost zero, except in the bitter cultivars.
In the case of Lotus japonicus, the two aliphatic
CNglcs linamarin and lotaustralin are present throughout in the flower tissue (Lai et al., 2015). As mentioned previously
(Figure 1B),
bioactivation of the CNglc
takes place only when specific b-glucosidases come into contact with their
corresponding substrate. In L. japonicus
the reproductive organs are only cyanogenic when a specific b-glucosidase BGD3
is expressed (Lai et al., 2015). Hydrogen cyanide release was
derived specifically from the keel and enclosed reproductive organs of the
flower. Sepals, wings, buds, and pods also contained the cyanogenic glucosides
linamarin and lotaustralin, but no release of any hydrogen cyanide from these
tissues was observed because the b-glucosidases were not present in these
tissues (Lai et al., 2015). It needs to be investigated
whether or not a particular b-glucosidase might also be expressed in almond and cherry
flower buds.
The presence of
CNglcs in flowers of other species has previously been reported. Within the Prunus genus, prunasin was quantified in
flowers of P. avium, whereas
amygdalin was not detected (Nahrstedt, 1972). Prunasin as well as amygdalin were identified in flowers of P. yedoensis Matsum (Matsuoka et al., 2011). Five different CNglcs were also
found in flower buds of Eucalyptus
camphora subsp. humeana, namely
prunasin and the
diglucosides amygdalin and
eucalyptosins A, B, and C (Neilson
et al., 2011). In Turnera ulmifolia L., the content of CNglcs decreased to
zero when the plant began to flower (Schappert and Shore, 2000) indicating complete endogenous
turn-over of CNglcs for alternative uses. CNglcs have also been detected in
flower tissues of Grevillea species, Linum usitatissimum L. (flax), L. japonicus L., Ryparosa kurrangii B.L. Webber (rainforest tree) and E.
camphora L.A.S. Johnson and K.D. Hill (Lamont, 1993; Niedzwied´z´-Siegieñ,, 1998; Forslund et al., 2004; Webber and Woodrow, 2008; Neilson et al., 2011).
Putative Derivatives of Prunasin in Flower Buds
In addition to prunasin and
amygdalin, structurally related derivatives were also found in the flower buds
of the five almond cultivars (Table 3 and Figures 3B–D, 5), in almond pistils,
sepals and petals (Supplementary Figure S1) and in the one sweet
cherry cultivar analyzed in this study (Table 3 and Figures 4B, 6). The prunasin derivatives
prunasin amide, prunasin acid, prunasin
anitrile, and the diglycoside prunasin pentosides were all present in amounts
much lower than prunasin. In contrast, the non-cyanogenic diglycoside prunasin
anitrile pentosides (prunasin anitrile arabinoside and xyloside in almond and
most probable prunasin anitrile apioside in cherry) were highly abundant at
certain stages of flower development (Figures 5, 6).
The content of
prunasin amide (Figures 3B, 4B) displayed a very
interesting and consistent pattern in the five almond and the single cherry
cultivar analyzed. Prunasin amide was not detectable until it peaked very close
to flowering time. In almond, the highest amount of prunasin amide was found in
the earliest cultivar (Achaak). In all studied cultivars, the peak of prunasin
amide coincided with a decrease in prunasin levels, indicating turnover of
prunasin into its amide. The conversion of prunasin to prunasin amide may occur
non-enzymatically via the Radziszewski reaction in the presence of hydrogen
peroxide (Sendker et al.,
2016).
Hydrogen peroxide is produced during flower development (Kuroda et al., 2002). Although present in
small amounts, formation of prunasin amide may thus serve as a quenching
reaction to avoid toxic hydrogen peroxide levels (Møller, 2010). Alternatively, prunasin amide might be formed
from prunasin catalyzed by a bifunctional nitrilase or by a nitrile hydratase (Picmanovᡠet al., 2015).
The presence of
prunasin acid (Figure 3C) was detected at the beginning of almond flower
bud development, although with relatively high standard error margins. In the
mid-late cultivars S3067, Lauranne and Penta, small amounts of prunasin acid
were observed to accumulate at the time point of flowering. Prunasin acid is
likely formed from the prunasin amide (Figure 7). The levels of prunasin
acid in the cultures Achaak and S3067 were close to zero. Low amounts of
prunasin anitrile were accumulated in the almond cultivars, with peak levels
before endodormancy release (Figure 3D).
In addition to
the monoglucosides described above, two diglycosides (pentosides) derived from
prunasin were identified in this study. Absolute quantification was not
possible due to the lack of reference compounds. Therefore, we expressed the
levels of these compounds
as % of prunasin (Figures 5, 6). The levels of prunasin
pentoside in almond (potentially a mixture of two prunasin pentosides) (Picmanovᡠet al., 2015) were higher at the
beginning in the dormant stage, where CU had not yet accumulated (Figure 5A). All almond cultivars exhibited the presence of prunasin anitrile
pentoside during endodormancy release, reaching relative amounts of up to 2000%
of prunasin (e.g., Achaak, Figure 5B). In cherry, the levels of
prunasin anitrile apioside increased toward the end of the experiment (Figure 6A).
In senescent
leaves of P. laurocerasus L., novel
benzoic acid esters have recently been reported as formed from prunasin (Sendker et al., 2016). This inspired us to
investigate the possible presence of benzoic acid derivatives in almond and
sweet cherry flower buds. A compound identified as b-D-glucose-1-benzoate was
indeed found to be present in high amounts compared to prunasin in the flower
buds of all studied almond cultivars as well as in the cherry cultivar (Figures 5C, 6B). b-D-Glucose-1-benzoate was suggested to be formed as a novel extension of
the oxidative catabolism of prunasin (Sendker et al., 2016). The amount of
accumulated b-D-glucose-1-benzoate is high
compared to the prunasin level implying that b-D-glucose-1-benzoate might also be synthesized by a different route in the
flower buds. Moreover, in almond and cherry flower buds, the formation of b-D-glucose-1-benzoate from
the corresponding aldehyde could potentially be connected to the release of
hydrogen peroxide during dormancy release. As mentioned previously, hydrogen
peroxide has been implicated in flower development in Japanese pear (Pyrus pyrifolia Nakai) (Kuroda et al., 2002).
These results
are in accordance with a recent study reporting the presence and structural
identification of CNglc derived metabolites including di- and tri-glycosides in
cassava, sorghum, and almond (Picmanovᡠet al., 2015). The amides, acids and anitriles derived from
prunasin and amygdalin were identified in seedlings of the bitter almond
cultivar S3067. The levels of the derivatives of prunasin and amygdalin were
generally much lower than those of their mother compounds. Prunasin amide, acid
and anitrile were found in low levels in seeds, roots, shoots, and leaves of
the seedling and at different stages of germination. Prunasin acid was the most
abundant derivative in seeds, shoots, and leaves and prunasin anitrile was most
abundant in roots. An important increment of the prunasin derivatives was
observed in the seed at the beginning of the germination (Picmanovᡠet al., 2015). Similarly, minor components related
to CNglcs were detected in P. persica
seeds: amygdalin acid, prunasin acid, benzyl gentiobioside and benzyl glucoside
(Fukuda et al., 2003). The latter
two compounds correspond to the amygdalin anitrile and prunasin anitrile compounds
denoted in our study.
Our current
study provides further evidence in support of the conclusions by Picmanovᡠet al.
(2015) that CNglcs occur together with their putative
structural derivatives: amides, acids and anitriles. In this respect, it was
suggested that these derivatives could play a role in the recycling of reduced
nitrogen. An alternative endogenous turnover pathway was proposed in which
CNglcs are converted to non-CNglcs, without release of HCN (Figure 1D). Hypothetically, amides, acids, and anitriles are produced from CNglcs
in this turnover pathway,
with a concomitant release
of NH3 and CO2. In this form, reduced
nitrogen and carbon originating from the CNglcs could be utilized in primary
metabolism. This alternative pathway might operate concurrently with the “conventional”
bioactivation
pathway, in which amygdalin
and prunasin are hydrolyzed and decomposed into benzaldehyde and HCN; the
latter is further detoxified through b-cyanoalanine into asparagine, aspartate
and NH3.
Based on the
general alternative turnover pathway proposed by Picmanovᡠet al. (2015), we suggest three possible
routes for the turnover of CNglcs in Prunus
species (Figure 7), starting with the hydrolysis of amygdalin to
prunasin. Then, in the first route, prunasin is further hydrolysed to prunasin
amide and/or acid and NH3.
Prunasin acid is converted into prunasin anitrile or to b-D-glucose-1-benzoate, with a
release of CO2. In the second route,
prunasin is converted directly into the corresponding anitrile with the release
of NH3 and CO2. NH3 as CO2 produced in these proposed
pathways may be channeled into primary metabolism. In a third route, prunasin
is glycosylated to a prunasin pentoside that would also produce NH3 and CO2, when converted to
prunasin anitrile pentoside. The latter could also be deglycosylated into
prunasin anitrile.
Other Functions of Cyanogenic Glucosides
Cyanogenic glucosides are
biosynthesized from amino acids, therefore the plant must mobilize and
transport these precursor substances to the sites where CNglcs are needed.
Supply of nitrogen for the biosynthesis of CNglcs is especially important in
young tissues, which are weaker than mature tissues and are in greater need of
defense against pathogens and herbivores. On the other hand, at times where
defense responses are less urgent, the plant can reuse nitrogen from CNglcs and
redirect it into primary metabolism (Vries et al., 2017).
In Eucalyptus,
it has been demonstrated that up to 20% of leaf nitrogen is stored in CNglcs,
with the highest levels in young and reproductive tissues (Gleadow and Woodrow,
2000).
In spring, coinciding with the flowering period, there was an important
allocation of nitrogen to the reproductive tissues in detriment to the leaves
to form CNglcs. The levels of these compounds
decreased gradually during
fruit development (buds – flowers – fruits).
Cyanogenic
diglycosides may have additional functions as transport forms, pollinator
attractants and germination inducers. In E.
camphora trees, the highest levels of diglucosides were found in flower
buds and expanded leaves (Neilson et al., 2011). Theoretically, the diglucosides
are synthesized in the expanded leaves and then transported to the developing
flower buds. The levels of cyanogenic diglucosides were much lower in immature
fruits suggesting that nitrogen was remobilized and used during the flower
development (Neilson et al., 2011).
HCN Factor
As previously mentioned,
HCN may be produced and metabolized during flower bud development, indicated by
a decrease in CNglc levels. Past as well as recent studies have also shown that
HCN may activate the flower bud and the flower opening in Lemna paucicostata and grapevine (Tanaka et al., 1983; Tohbe et al., 1998).
Interestingly,
HCN has also been reported in releasing seed dormancy in orthodox seeds (Roberts, 1973; Roberts and Smith, 1977) by inducing the formation of
Reactive Oxygen Species (ROS); ROS in turn activates a cascade involving Ethylene
Response Factor 1 (ERF1), which leads to the production of
germination-associated proteins (Oracz et al., 2009). Extensive literature describes
the importance of the HCN in seed germination. Considering the common
mechanisms regulating seed and bud dormancy, this process could be similar in
endodormancy release (Taylorson and Hendricks, 1973; Bogatek et al., 1991; Flematti et al., 2013).
Involvement of Cyanogenic Glycosides in Regulation of Sweet Cherry
Flower Bud Dormancy as Monitored by qRT-PCR Analysis
To obtain more information
on the possible regulation of these processes, qRT-PCR analysis was performed
on the sweet cherry samples. The expression levels of a selected number of
genes were analyzed (Figure 8). In CNglcs biosynthesis:
CYP79 and CYP71 (Figure 8A). In bioactivation: amygdalin and prunasin
hydrolase (Figure 8B). In oxidation reactions: catalase and peroxidase (Figure 8C). In ethylene biosynthesis: SAM
synthase, ACC synthase, and ACC oxidase (Figure 8D). In the detoxification pathway: L-3-cyanoalanine synthase (Figure 8E).
Both CYP79
genes displayed their highest level of expression after dormancy release,
indicating that CNglcs biosynthesis takes place during early flower development
in sweet cherry (Figure 8A). In buds of Japanese apricot (P. mume), CYP79A68 was the only examined
cytochrome P450 monooxygenase encoding gene showing a substantial level of
expression (Yamaguchi et al.,
2014).
Further Yamaguchi et al.
(2014) reported that CYP79D16, but not CYP79A68,
catalyzed the conversion of L-phenylalanine
into E-phenylacetaldoxime. The second
step in CNglcs biosynthesis is mediated by CYP71s (Sánchez-Pérez et al., 2008), such as CYP71AN24 and CYP71AP13 (Yamaguchi et al., 2014). In general,
the expression of the two CYP71 encoding genes was transiently down-regulated shortly before
dormancy release and subsequently increased again (Figure 8A). This is in
accordance with the results for the CYP79s. Further CYP71AN24, but not
CYP71AP13, catalyzed the conversion of E-phenylacetaldoxime
into mandelonitrile (Yamaguchi et al., 2014). Hence, future studies have to reveal the functional properties and
substrate specificities of CYP79s and CYP71s in sweet cherry to resolve the
biosynthesis of prunasin in sweet cherry.
As previously
mentioned, the degradation of CNglcs is initiated by b-glycosidases, in Prunus
species called amygdalin hydrolase (AH) and prunasin hdyrolase (PH). Ah1 and Ph5
(Zhou et al., 2002) were examined in this study (Table 4) as they were the most similar characterized hydrolases between P. serotina and P. dulcis (Sánchez-Pérez et al., 2012). As shown
in Figure 8B, both genes display transcriptional activity
solely after dormancy release. In the case of Ph5, this fits well with the decrease of prunasin levels at around
the same time point, indicating its degradation.
L-3-Cyanoalanine
synthase (CAS) activity serves as an indicator for HCN release because of its
essential involvement in HCN detoxification (Floss et al., 1965). After a transient peak, CAS transcription decreased and rised again during dormancy release and during flower development (Figure 8E).
Involvement of Oxidative Stress Regulating Factors in Sweet Cherry Bud
Dormancy Release as Monitored by qRT-PCR Analysis
Pathways involved in
oxidative stress regulation have previously been shown to be active during
dormancy release in several different perennials (Horvath, 2009; Cooke et al., 2012). In our study, catalase expression decreased
slightly and then increased again just before dormancy was released (Figure 8C). Several studies found catalase activity to be affected by both natural
and artificially induced bud break (Nir et al., 1986; Pérez and Lira, 2005; Amberger, 2013). Catalases are known to catalyze the conversion
of H2O2 to water and oxygen (Chelikani et al., 2004). Thus, the inhibition of catalase
gene transcription and enzyme activity by, e.g., HCN released from the cyanogenic
glucoside hydrolysis could result in increased hydrogen peroxide levels. In
this study, the subsequent up-regulation of the catalase gene after dormancy
release might decrease H2O2 levels again, which is consistent with a steady decrease in
H2O2 content after dormancy release found in flower buds of P. pyrifolia (Japanese pear) (Kuroda et al., 2002).
In addition to
catalase, a range of peroxidases are able to reduce H2O2 to water and have been
shown to be induced in response to oxidative stress during dormancy release in
grape buds (Veitch, 2004; Keilin et al., 2007). The peroxidase gene examined in our study (Figure 8C) was most highly expressed at bud dormancy release, indicating that
peroxidase functions mainly during the transition from dormancy to flowering in
sweet cherry, which is similar to results acquired in Japanese pear (Bai et al., 2013). Differently regulated
peroxidases during transition of dormancy release were observed in prior
studies. For instance, in buds of Chinese cherry (P. pseudocerasus Lindl.), different peroxidase encoding genes were
either down-regulated before, during and after dormancy release under natural
conditions (Zhu et al., 2015). This suggests a pattern of
alternating activities among a set of peroxidases that regulate oxidative
stress during bud dormancy release. Peroxidases were found to be up-regulated
in buds of peach and leafy spurge (Euphorbia
esula L.) (Jia et al., 2006; Leida et al.,
2010)
and down-regulated in grapevine in regard to dormancy release (Pacey-Miller et al.,
2003).
The examined peroxidase gene in our study was down-regulated before dormancy
release, which coincides with our observation of a decreased catalase
expression, potentially
giving rise to a transient increase in ROS. Subsequently enhanced expression of
peroxidase and catalase encoding genes during and after bud dormancy release
might then cooperatively reduce oxidative stress.
Involvement of Ethylene Regulation in Sweet Cherry Bud Dormancy Release
as Monitored by qRT-PCR Analysis
Transcript analysis of
three key genes encoding enzyme involved in ethylene biosynthesis, namely S-adenosyl-methionine (SAM) synthetase, 1-aminocyclopropane-1-carboxylic acid (ACC) synthase and ACC oxidase were conducted and demonstrated that ACC synthase and ACC oxidase
were initially expressed shortly before dormancy release (Figure 8D). Those results suggest that ethylene biosynthesis was initiated before
dormancy release in sweet cherry. In grapevine, the effect of different
temperatures and sampling dates on bud break and ACC content was studied,
seeing that under low temperatures, bud break was associated with the promotion
of ethylene biosynthesis (El-Shereif et al., 2005). Heat shock
experiments demonstrated that ACC and ethylene accumulated toward dormancy
release in grapevine (Tohbe et al., 1998). Transcription of the gene encoding ACC synthase was induced in flower buds in Japanese pear (Bai et al., 2013). Exogenous application of ACC has
been reported to enhance dormancy release. The same effect was not observed upon
exposure to ethylene (Iwasaki, 1980). Since hydrogen cyanide is formed in stoichiometric
amounts with ethylene in the ACC oxidase catalyzed conversion of ACC, hydrogen
cyanide is thought to be responsible for bud break in grapevine.
AUTHOR
CONTRIBUTIONS
II and JD designed and
conducted the main experiments and wrote the manuscript. MP conducted LC-MS
data analysis and contributed to the manuscript. OG performed the qRT-PCR
experiments and wrote the manuscript. MM synthesized most of the reference
compounds and contributed to the manuscript. CO conducted the LC-MS analysis.
JD assisted with the sweet cherry experiments. FD conducted almond flower bud
sampling and the evaluation of the flower bud development. BM designed
experiments and wrote the manuscript. RS-P designed and coordinated
experiments, conducted LC-MS data analysis and wrote the manuscript.
FUNDING
This work was
financed by VILLUM Research Center for Plant Plasticity. RS-P gratefully
acknowledges the VILLUM Foundation for the award of a Young Investigator
Program grant entitled “The molecular mechanisms to break flower bud dormancy
in fruit trees.” The Spanish projects “Mejora Genética del Almendro” and “Breeding
stone fruit species assisted by molecular tools” funded by MINECO of Spain and
Fundación Séneca of Murcia, respectively, also financed this work.
ACKNOWLEDGMENTS
We would like
to thank Bénédicte Wenden for her assistance concerning the calculation of the
chill requirements and of the endodormancy release date for sweet cherry.
CONCLUSION
Based on the results
presented in this paper, two possible mechanisms for the involvement of CNglcs
in bud break and flower development are proposed: (1) Turnover of CNglcs to
their corresponding amides, acids and anitriles can recover reduced nitrogen
and carbon dioxide, which may be utilized during these metabolically demanding
physiological changes;
(2) Prunasin and a number of
endogenous turn-over products as well as formation of hydrogen cyanide from
prunasin act as regulators of flower bud dormancy release and flowering time.
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FIGURE S1
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Conflict of Interest Statement: The authors declare that the research was conducted in the absence of any
commercial or financial relationships that could be construed as a potential
conflict of interest.
The reviewer JZ and
handling Editor declared their shared affiliation, and the handling Editor states
that the process nevertheless met the standards of a fair and objective review.
Copyright © 2017 Del Cueto, Ionescu, Piˇcmanová, Gericke, Motawia,
Olsen, Campoy, Dicenta, Møller and Sánchez-Pérez. This is an open-access
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