Acta agriculturae Slovenica, 119/3, 1–7, Ljubljana 2023
doi:10.14720/aas.2023.119.3.14538 Original research article / izvirni znanstveni članek
Do mutations modifying the leaf area (nr3) and the number of potential 
seeds (dfc) influence photosynthetic gas exchange characteristics in com-
mon buckwheat Fagopyrum esculentum Moench?
Ivan N. FESENKO
 1, 2
, Alexandr V . AMELIN
 3
, Aleksey N. FESENKO
 1
, Oksana V . BIRYUKOV A
 1
, Valeriy 
V . ZAIKIN
 3
, Evgeniy I. CHEKALIN
 3
, Roman A. IKUSOV
 3
Received June 12, 2023; accepted July 03, 2023.
Delo je prispelo 12. junija 2023, sprejeto 3. julija 2023
1 Laboratory of Buckwheat Breeding, Federal Scientific Center of Legumes and Groats Crops, Orel, Russia
2 Corresponding author, e-mail: ivanfesenko@rambler.ru
3 Orel State Agrarian University, Orel, Russia
Do mutations modifying the leaf area (nr3) and the number 
of potential seeds (dfc) influence photosynthetic gas exchange 
characteristics in common buckwheat Fagopyrum esculentum 
Moench?
Abstract: Contemporary buckwheat breeding in Russia is 
based mainly on a Mendelian  mutation det. Some additional 
mutations are being considered for inclusion in buckwheat 
breeding programs. Among them are the nr3 (narrow leaf 3) 
and dfc (determinate floret cluster). We evaluated the effects of 
the mutations on both the characteristics of photosynthetic gas 
exchange and the number of seeds per plant. The nr3 reduces 
the leaf surface area by 1.4 times. The mutant plants show some 
compensatory increase in photosynthesis rate, which, however, 
is not enough to reach the level of the source ability as in the 
wild type since the number of seeds per plant is significantly 
decreased. The possibility of using this mutation in buckwheat 
breeding depends on the accumulation of modifiers that in-
crease either leaf size or photosynthesis rate. The reduced num-
ber of flowers of the dfs mutation is compensated by an increase 
in flower fertility, and the number of seeds per plant does not 
change compared to the wild type. It explains the absence of 
differences between the dfs and wild type in terms of the photo-
synthesis rate. This experiment did not reveal any problems for 
using the dfc mutation in breeding. In general, the results of the 
work support the photosynthesis rate in buckwheat is regulated 
based on the source-sink ratio.
Key words: common buckwheat, photosynthesis, leaf 
area, source-sink ratio, breeding
Ali mutaciji, ki spreminajata listno površino (nr3) in število 
potencialnih semen (dfc) vplivata na značilnosti fotosintezne 
izmenjave plinov pri navadni ajdi (Fagopyrum esculentum 
Moench)?
Izvleček: Sodobno žlahtnjenje ajde v Rusiji temelji 
v glavnem na Mendlovi mutaciji det a so bile za vključitev v 
žlahtniteljske programme predlagane še dodatne mutacije. 
Med njimi sta mutaciji nr3 (ozki listi 3) in dfc (determinantno 
socvetje). V raziskavi smo ovrednotili vplive obeh mutacij na 
značilnosti fotosintezne izmenjave plinov in na število semen 
na rastlino. Mutacija nr3 zmanjša listno površino za 1,4 krat. 
Mutantne rastline kažejo nekatere kompenzacijske mehanizme 
v velikosti fotosinteze, ki pa ne zadoščajo za doseganje ravni 
pri divjem tipu, kar kaže značilno zmajšanje števila semen na 
rastlino. Možnost uporabe te mutacije v žlahtniteljskih pro-
gramih ajde je odvisna na kopičenju sprememb, ki povečujejo 
listno površino ali velikost fotosinteze. Zmanjšano število cve-
tov pri mutaciji dfs je kompenzirano s povečanjem plodnosti 
cvetov, pri čemer število semen na rastlino ni spremenjeno v 
primerjavi z divjim tipom. To razloži tudi odsotnost razlike v 
velikosti fotosinteze med dfs in divjim tipom. V poskusu tudi 
ni bilo ugotovljenih nobenih problemov v uporabi fc mutacije 
pri žlahtnenju. Na splošno rezultati raziskave kažejo, da je ve-
likost fotosinteze pri navadni ajdi uravnavana z razmerjem vir 
: ponor.
Ključne besede: navadna ajda, fotosinteza, listna površi-
na, razmerje vir-ponor, žlahtnenje

Acta agriculturae Slovenica, 119/3 – 2023 2
I. N. FESENKO et al.
1 INTRODUCTION
Common buckwheat, Fagopyrum esculentum Moe-
nch, is a grain and groats crop widespread throughout 
Eurasia (Kreft et al., 2003; Fesenko et al., 2006). Since 
the 1960s, buckwheat breeding in Russia has been based 
on mutations that are sometimes accumulated in popu-
lations not affected by scientifically based selection, i.e. 
approved by natural selection (Fesenko, 1983; Fesenko 
et al., 2006). For example, det-mutation causing deter-
minate growth habit (Fesenko, 1968; Ohnishi, 1990) is a 
core of most contemporary Russian buckwheat varieties 
(Fesenko & Fesenko, 2019). The use of the det mutation 
made a local green revolution since the mass distribution 
of the determinate varieties doubled the average yield 
of buckwheat in Russia (Fesenko & Fesenko, 2019). An 
assessment of the groups of both determinate and inde-
terminate buckwheat varieties according to the intensity 
of photosynthesis  revealed the advantage of the deter-
minate ones at a stage of mass seed filling (Amelin et al., 
2020). However, analysis of the effect of det-mutation per 
se using a segregated hybrid population did not reveal 
a significant difference with the wild type, i.e. indeter-
minate one. On the one hand, it clarifies the role of the 
det-mutation in control of the photosynthesis intensity is 
not entirely clear. But it is evident that on its background, 
some other complexes of genes are formed, including 
ones determining the photosynthesis characteristics 
(Amelin et al., 2020).
At present, some additional mutations are being 
considered for inclusion in buckwheat breeding pro-
grams. Two of them are dfc and nr3 mutations (Figure 
1). One of the significant aspects of the effects of the 
mutations on plants in the context of their breeding ap-
plication is their influence on the characteristics of pho-
tosynthesis. The nr3 reduces the leaves area surface, and 
is considered as the basis for creating varieties with re-
duced self-shading. At the same time, reducing leaf area 
changes the source potential (using the terminology of 
photosynthesis researchers). The dfc mutation drastically, 
by 4-5 times, reduces the number of flowers in an inflo-
rescence (Fesenko et al., 2010). It can change the sink 
potential (i.e. demand for assimilates), firstly by reduc-
ing the assimilates demand for flower production, and 
secondly by reducing the fruiting potential. However, the 
latter can be leveled by increasing the fertility of flowers. 
So, the mutations can affect the source-sink ratio, which 
is the key to regulating the intensity of photosynthesis 
(Paul et al., 2001; McCormick et al., 2008; Katoh et al., 
2015).
An objective of this work was to evaluate both the 
characteristics of photosynthetic gas exchange (which re-
veal the source ability) and the number of seeds per plant 
(which shows the sinking ability) of dfc and nr3 mutants 
vs wild type.
Figure 1: A) Mutant nr3; B) Mutant dfc at a stage of almost 
mature seeds; C) Wild type (both normal leaves and normal 
flower number)

Acta agriculturae Slovenica, 119/3 – 2023 3
Do mutations ... influence photosynthetic gas exchange characteristics in common buckwheat Fagopyrum esculentum Moench?
2 MATERIALS AND METHODS
2.1 PLANT MATERIAL
Mutants analized were next:
- Mutant dfs (determinate floret cluster) leads to a 
sharp, 4-5 times reduction in the number of flowers in 
the inflorescence. The dfc plants participating in crosses 
were determinate (genotype det det). 
- Mutant nr3 (narrow leaf 3) causes a change in leaf 
geometry due to a decrease in its width and significantly 
reduces the leaves’ surface area of a plant. It reduces the 
plant’s photosynthetic potential in morphological terms. 
The nr3 plants participating in the work were determi-
nate (genotype det det).
Both dfc and nr3 mutants were isolated in the lab 
of buckwheat breeding, Federal Scientific Center of Leg-
umes and Groats Crops.
To level the possible influence of some unidentified 
genes on the parameters of photosynthetic gas exchange 
F
2
 hybrids ‘mutant × wild type’ were used for the analy-
ses.
As a wild type the next varieties were used:
- Dikul, a determinate common buckwheat variety 
bred in Federal Scientific Center of Legumes and Groats 
Crops. The variety was registered in 1999.
- Bogatyr, an indeterminate common buckwheat va-
riety bred on Shatilovskaya Experimental Station (Orel 
region, Russia). It is the first commercial buckwheat vari-
ety in Russia which was registered in 1938.
F
2
 hybrids analized were next:
(1) ‘dfc dfc/det det × Dikul’ . 
(2) ‘nr3 nr3/det det × Dikul’ . 
(3) ‘nr3 nr3 / det det × Bogatyr’ . 
Since Dikul is a determinate variety, the F
2
 hybrids 
(1) and (2) manifest segregation only according to dfc 
and nr3 alterations, respectively. F
2
 hybrids with inde-
terminate variety Bogatyr shown expected segregation 
comprising four phenotypical classes (Table 1).
2.2 EXPERIMENTAL APPROACHES 
The photosynthesis and transpiration intensities 
were evaluated on intact plants in real-time regime with 
a portable gas analyzer Li–COR – 6400 using the original 
methodology of the company Li–COR. The WUE (water 
use efficiency) was calculated for each plant analyzed us-
ing the formula WUE = photosynthesis rate/transpiration 
intensity. 
The evaluations of photosynthesis and transpira-
tion intensities were conducted in 2017, 2018 and 2021. 
All experimental plants were labeled and numbered. The 
measurements within single mutant segregations (dfc or 
nr3) were made in order “mutant - wild type - mutant - 
etc” with alternation on each plant. The measurements 
within a segregation for the two recessives (nr3 and det) 
were conducted in order “nr3 (non-det) - det (non-nr3) 
- wild type (both non-nr3 and non-det) - nr3+det - etc” 
with regular alternation in such order.
To measure the leaf size of F
2
 hybrids ‘nr3 × Dikul’ 
with both narrow leaves and normal leaves the largest 
leaf from each plant was photographed with a scale in 
2021. Leaves sizes were measured on the photos using 
Axio Vision Software. 25 plants of both types were taken 
randomly. 
Sowing dates were June 1in 2017, May 23 in 2018 
and May 27 in 2021. Blossom beginning dates were July 
6-7 in 2017, June 26-27 in 2018 and July 1-2 in 2021. 
The dates of photosynthesis assessment (which are men-
tioned in the Table 1) fell on the period of mass filling of 
seeds. 
The number of filled grains per plant was evaluated 
on August 15 in 2017, on August 14 in 2018, and on Au-
gust 10 in 2021.
The significance of differences was assessed using 
ANOV A (Software Statistica 7).
3 RESULTS
3.1 ANALYSES OF PHOTOSYNTHETIC GAS 
EXCHANGE CHARACTERISTICS AND SEED 
PRODUCTIVITY OF INDIVIDUAL PLANTS 
WITHIN POPULATIONS SEGREGATED AC-
CORDING TO DFC, NR3, AND NR3+DET 
ALTERATIONS
3.1.1 dfc-mutant
The experiment revealed no differences between the 
mutant and non-mutant plants in photosynthesis and 
transpiration intensities (Table 1). Also, there were no 
significant differences in the number of seeds per plant 
between the groups of plants with normal (wt) and re-
duced (dfc) number of flowers. Apparently, it points out 
that at this ontogenesis stage, the demand for assimilates 
is mainly formed by developing seeds.
This mutation is considered the basis for creating 
varieties both with more simultaneous maturation and 
more early ripening. According to the results of the work 
dfc- mutation does not disturb the system of regulation of 
physiological processes associated with photosynthesis. 
It simplifies any application of the mutant for buckwheat 
breeding.

Acta agriculturae Slovenica, 119/3 – 2023 4
I. N. FESENKO et al.
Hybrid combination 
(date of analysis) Phenotype class N t (leaf),°C
Photosynthesis 
(μmol m
-2
 s
-1
)
Transpiration 
(μmol m
-2
 s
-1
) Water use efficiency Seeds per plant
F
2
(Dikul × dfc) 
(July 28, 2017)
wt 42 24.7 ± 0.62 8.32 ± 3.85 5.84 ± 1.73 1.40 ± 0.56 44.87 ± 10.31
dfc 42 8.69 ± 3.63 6.12 ± 1.92 1.40 ± 0.49 45.80 ± 6.84
One-way ANOV A NS NS NS NS
F
2
(Dikul × nr3) 
(July 26, 2021)
wt 40 30.6 ± 3.97 8.88 ± 4.44 2.51 ± 1.18 4.06 ± 2.40 51.20 ± 5.14
nr3 40 11.11 ± 4.93 2.81 ± 1.34 4.76 ± 3.00 46.53 ± 6.82
One-way ANOV A p < 0.05 NS NS p < 0.001
F
2
(Dikul × nr3) 
(July 12, 2018)
wt 50 24.8 ± 0.63 12.58 ± 4.17 2.14 ± 0.57 6.38 ± 4.42 42.92 ± 4.36
nr3 50 13.75 ± 4.88 2.16 ± 0.35 6.20 ± 2.71 38.96 ± 5.24
One-way ANOV A NS NS NS p < 0.001
F
2
(Bogatyr× nr3) 
(July 13, 2018)
wt 30 25.0 ± 0.35 11.48 ± 3.84 2.70 ± 1.10 5.13 ± 3.22 35.17 ± 2.96
nr3 30 10.37 ± 3.43 2.08 ± 0.77 6.03 ± 4.35 35.73 ± 2.77
det 30 9.73 ± 4.45 2.47 ± 0.73 4.13 ± 2.06 38.03 ± 3.13
nr3 + det 30 10.38 ± 3.81 2.21 ± 0.88 5.17 ± 2.37 37.23 ± 3.02
Two-way ANOV A nr3 NS p < 0.02 NS NS
det NS NS NS p < 0.001
nr3 × det NS NS NS NS
Table 1: Characteristics of mutant and non-mutant (wt) classes in segregated populations in terms of photosynthetic gas exchange and seed productivity (Mean ± SD)

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Do mutations ... influence photosynthetic gas exchange characteristics in common buckwheat Fagopyrum esculentum Moench?
3.1.2 nr3-mutant
This single-gene mutation makes leaves narrow and 
reduces their area by 1.4 times, 38.4 ± 12.2 vs 27.1 ± 7.4 
(mean ± SD). Apparently, it should cause a shift within 
the “source-sink” balance toward a source deficiency. A 
priori, there can be two ways to compensate for such a 
shift. The first is a decrease in the number of seeds, i.e. 
a decrease in sink strength. The second is an increase in 
the intensity of photosynthesis per leaf area unit. In the 
experiments, we observed both types of effects (Table 1).
In two experiments carried out in different years 
on the same hybrid material, the same patterns were 
obtained in terms of both the changes in the number of 
seeds per plant and the gas exchange parameters. In both 
cases, the number of seeds on narrow-leaved plants was 
significantly less compared to plants with normal leaves. 
Photosynthesis rate in both cases was higher for the 
narrow-leaved plants, on average, and in one of the two 
experiments, the difference was significant. Water use ef-
ficiency (WUE) have tends to slight growth when photo-
synthesis rate is significantly higher. Thus, this mutation 
can be considered as a model in which the sink potential 
is not fully realized due to the source insufficiency. 
Since this work shows the nr3-mutant has insuffi-
cient leaf area resulting in the source deficiency, an es-
sential aspect of its use for breeding commercial varieties 
should most likely be an increase in leaf size or/and an 
additional increase in photosynthesis rate due to the se-
lection of some hypothetical modifiers that can be able to 
compensate the effect of the mutation. 
3.1.3 nr3 + det
W e have previously reported that determinate varie-
ties manifest higher photosynthesis rates at the seed-fill-
ing stage than indeterminate varieties. However, the det 
mutation itself does not affect the gas exchange intensity. 
An experiment was conducted to evaluate the joint effect 
of det and nr3 mutations on photosynthesis parameters. 
The less number of grains per plant in the experi-
ment compared to other ones in this work is due to the 
old low-yielding variety with normal leaves and indeter-
minate growth habit Bogatyr has been used in crosses 
with determinate plants with narrow leaves (genotype 
det det/nr3 nr3). The det mutation did not affect the rates 
of photosynthetic gas exchange and had a certain effect 
on the number of seeds. However, the difference revealed 
was at a low level of significance (Table 1). The photo-
synthesis rate did not differ significantly also between 
nr3 mutants and plants with normal leaves. It should be 
noted that nr3 homozygotes, both determinate and in-
determinate, showed a significantly lower transpiration 
intensity. However, it could not be considered as a trend 
since in the experiments with F
2
 hybrids ‘nr3 × ‘Dikul’ 
the differences between mutants and non-mutants in 
transpiration intensity were not significant (Table 1). W a-
ter use efficiency also was not significantly affected by the 
mutations across all the experiments.
4 DISCUSSION
There are many evidences suggesting the photosyn-
thetic gas exchange intensity is a function of the source-
sink interaction. The source potential is not realized at 
full capacity, and the value of photosynthesis rate per unit 
of leaf area can be increased if the leaves area of the plant 
is reduces by any way. Thus, soybean having leaves with 
smaller surface areas manifests a higher photosynthesis 
rate per unit of leaf area than those with larger leaves 
(Sung, Chen, 1989). Similar effect can be observed on 
a rice mutant NAL1 with more narrow leaves compared 
wild type (Takai et al., 2013). In addition, the excision 
of several leaves from trees of Eucalyptus globulus Labill. 
resulted in the growth of photosynthesis rate in the re-
mained leaves (Eyles et al., 2013). 
Since photosynthesis rate usually does not reach the 
maximum possible values, there are some factors restrict-
ing it. Matsuda et al. (2011) discussed the hypothesis for 
sink-limitation suggesting the photosynthesis rate is lim-
ited by the demand for assimilates. This hypothesis was 
tested on two varieties of tomato and was not fully con-
firmed (Matsuda et al., 2011).Thus, when several fruits at 
the early developmental stage were removed from plants, 
the remaining ones became larger. On the other hand, on 
intact plants all the fruits were smaller. It suggests rather 
a lack of source ability in this case. The examples when 
assimilate demand was increased due to experimental 
manipulation also are known. So, nitrogen application 
can provide higher sink strength (Pissolato et al., 2019; 
Chen et al., 2022). Inoculation with nodule bacteria also 
resulted in a higher photosynthesis rate which could be 
explained in two ways: 1) it is able to provide additional 
nitrogen and 2) growing nodules requires additional as-
similates (Kaschuk et al., 2012).
On potatoes it was shown the possibility to increase 
both source and sink ability using transgenic manipula-
tions: it sufficiently increased the yield of starch in tubers 
(Jonik et al., 2012). Also, it was revealed the genetically 
controlled mechanisms influencing the translocation of 
assimilates toward developing seeds (Phung et al., 2019). 
In addition, it was hypothesized the buckwheat varie-
ties with determinate growth habit manifest higher pho-

Acta agriculturae Slovenica, 119/3 – 2023 6
I. N. FESENKO et al.
tosynthesis due to optimizing the assimilates logistics 
(Amelin et al., 2020).
We have analyzed the effect of well-distinguishable 
morphological mutations of two types on the photosyn-
thetic gas exchange parameters. One of them, the dfc mu-
tation, reduces the number of flowers within cyme (i.e., 
partial inflorescence) by 4-5 times. It can be assumed it 
forms some tendency to reduce sink potential. However, 
our experiment with this mutation shows the demand for 
assimilates is not different between non-mutant and dfc-
mutant plants. The number of formed seeds on mutant 
and non-mutant plants also did not differ significantly. 
Thus, the increasing proportion of flowers setting seeds 
compensates for reducing flowers number on dfc-plants 
and allows them to form sufficient number of seeds and 
maintain the demand for assimilates.
Mutation nr3 reduces leaf area by 1.4 times and in-
creases photosynthesis rate, sometimes significantly. It 
can be interpreted as compensation for the decrease in 
leaf area. Also, it allows us to understand that in buck-
wheat, the physiological processes associated with pho-
tosynthesis are not at full capacity, and there are some 
possibilities to increase its intensity. Since the mutants 
typically produced fewer seeds compared to the wild 
type, it can be concluded that the compensatory increase 
in photosynthesis rate is unsufficient to reach the wild 
type source levels.
Our experiments to assess the effects of mutations 
on the intensity of photosynthesis, both presented in 
this article and previously published, make it clear that 
buckwheat plants have a particular source limit per unit 
of leaf area which, however, is usually not reached, i.e. 
the source ability is not fully realized. It is due to certain 
limitations in the sink ability, an example of overcoming 
which, however, exists. This is a significant increase in 
the photosynthesis intensity within varieties with deter-
minate growth habit at the stage of seed filling. The det 
mutation per se does not affect photosynthesis charac-
teristics. Therefore, the higher photosynthesis rate of the 
determinate varieties is due to the accumulation of some 
additional genes, the role of which in physiology we do 
not yet understand (Amelin et al., 2020).
There are no commercial varieties based on the nr3 
and dfc mutations yet. If (or when) such varieties appear, 
it will be possible to evaluate their difference from varie-
ties that do not carry these mutations, and, accordingly, 
it is possible to obtain additional cases of modifying 
the regulation of photosynthesis. This is especially true 
for the nr3 mutation, which application for buckwheat 
breeding can be successful only with the accumulation of 
certain modifiers.
5 ACKNOWLEDGMENTS 
The work was supported by grant of Russian Sci-
ence Foundation № 22-26-00041, https://rscf.ru/pro-
ject/22-26-00041
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