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Adv. Hort. Sci., 2018 32(4): 459-470 DOI: 10.13128/ahs-22479

Combining ability and gene action of

some tomato genotypes under low

light condition

S. Emami 1, S.H. Nemati 1 (*), M. Azizi 1, M. Mobli 2

1 Department of Horticultural Science and Landscape, Faculty of

Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.
2 Department of Horticultural Science, Faculty of Agriculture, Isfahan

University of Technology, Isfahan, Iran.

Key words: combining ability, diallel, heritability, light intensity, reciprocal effects,
Solanum lycopersicum.

Abstract: Limitations in access to electricity in rural areas and substantial cost

of supplemental lightning necessitate breeding as response to low light condi-

tions. Seven inbred lines of tomato (Solanum lycopersicum L.) and their F1

hybrids, including reciprocals, developed through a 7×7 full diallel cross were

evaluated under two different levels of light. Mean square for light (L) effect

was significant for total yield, average fruit weight and days to first flower.

Variation attributable to Genotypes and genotype × light (G×L) interaction had

significant effect on all studied traits except days to ripening for which G×L

interaction was not significant. Diallel analysis across two environments indi-

cated that general (GCA), specific (SCA) and reciprocal combining ability (REC)

were significant for all characters implying importance of additive and non-

additive gene action along with cytoplasmic effects on genetic expression of

yield, yield components and earliness. Ratio of SCA variance to SCA variance

and estimates of narrow sense heritability (h2n.s) demonstrated higher weight

of additive effects in inheritance of yield, fruit number and days to ripening,

while indicating predominance of non-additive effects for fruit weight and early

flowering. Interactions GCA×L and SCA×L were significant for almost all studied

features. A particular genotype could not be recommended for all traits, but

variation among genotypes in response to ambient light was promising for fea-

sibility of plant breeding for non-optimal light intensity and duration.

1. Introduction

Tomato (Solanum lycopersicum L.), a member of solanaceae family, is
a wide cultivated vegetable used for fresh and processing market. This
day neutral plant is grown in various regions of the world with different
climates (Mizoguchi et al., 2007; Gerszberg et al., 2015). Iran is among the
top 10 countries producing tomato (FAOSTAT, 2014), but it performs very
poorly in terms of tomato seed production and a large portion of the
seeds, particularly hybrid cultivars, is imported to the country. The major
obstacle to seed production in Iran is the absence of breeding programs

(*) Corresponding author: 

nemati@um.ac.ir

Citation:

EMAMI S., NEMATI S.H., AZIZI M., MOBLI M.,
2018 - Combining ability and gene action of some
tomato genotypes under low light condition. -
Adv. Hort. Sci., 32(4): 459-470

Copyright:

© 2018 Emami S., Nemati S.H., Azizi M., Mobli M.
This is an open access, peer reviewed article
published by Firenze University Press
(http://www.fupress.net/index.php/ahs/) and
distributed under the terms of the Creative
Commons Attribution License, which permits
unrestricted use, distribution, and reproduction
in any medium, provided the original author and
source are credited.

Data Availability Statement:

All relevant data are within the paper and its
Supporting Information files.

Competing Interests:

The authors declare no competing interests.

Received for publication 10 January 2018
Accepted for publication 16 May 2018

AHS
Advances in Horticultural Science



Adv. Hort. Sci., 2018 32(4): 459-470

460

for most of the vegetables including tomato; there-
fore, more attention to vegetables breeding in order
to produce high quality seeds is required.

Hybrid breeding technique is one of the most
important methods used for crop improvement. The
information needed to develop proper F1 hybrid cul-
tivars via hybrid breeding could be achieved through
different methods including diallel analysis, a method
to analyze crosses made among (n) lines in all possi-
ble combinations (Griffing, 1956 a, b). The analysis is
mainly adopted when dealing with limited number of
parental lines and determines genetic parameters
such as heterosis, general combining ability (GCA),
specific combining ability (SCA), heritability, and
nature of gene action. Heterosis demonstrates the
superiority of F1 progenies compared to the average
of their parents. General combining ability (GCA)
shows the average performance of a parental line
while specific combining ability (SCA) refers to the
best combination of crosses. General combining abili-
ty (GCA) and specific combining ability (SCA) are the
indicators of additive and non-additive gene effects,
respectively. These parameters help plant breeders
in the selection of suitable parental lines and appro-
priate breeding method (Sprague and Tatum, 1942).

It should be noted that despite of the advantages
of hybrid cultivars over open pollinated ones, the
high price of hybrid seeds developed via hybridiza-
tion programs makes the use of them more economi-
cal for intensive and indoor cultivation (Zengin et al.,
2015). One of the major problems affecting plants
growth in greenhouses is the decreased level of light
received by plants due to significant loss of solar radi-
ation caused by reflection and absorption by green-
house covering material (Baeza and López, 2012) and
high plant density, typically executed in greenhouse
cultivations (Laurent et al., 2017). Since light is one of
the most crucial factors influencing growth rate, pro-
duction quality and quantity of plant, supplying
plants with adequate light intensity with suitable

quality is of importance in greenhouses particularly
during autumn and winter seasons (Hangarter, 1997).

In developing countries such as Iran, most of the
greenhouses do not benefit from high technology
and suffer from lack of accessibility to electricity,
h e n c e ;  s u p p l e m e n t a l  l i g h t n i n g  i s  n o t  a p p l i e d .
Moreover, substantial price of energy resources and
tendency toward lower energy consumption (Oz and
Atilgan, 2015) necessitate hybrid breeding for low
light conditions. To our knowledge breeding for low
light condition has not been conducted in tomato,
therefore, this study aimed to investigate if there
existed any differences among various tomato geno-
types in response to two different light conditions
w h i l e  c o n s i d e r i n g  t h e  i n t r o d u c t i o n  o f  s u i t a b l e
parental lines and hybrids for each condition as well
as determination of stable genotypes over two envi-
ronments. Genetic parameters including combining
ability, gene action and heritability were estimated to
help breeders in choosing the best approach for the
improvement of tomatoes regarding increased yield
and earliness. 

2. Materials and Methods

Plant material

S e v e n  i n b r e d  l i n e s  o f  t o m a t o  c o n s i s t e d  o f
‘Perimoga’, ‘La1793’, ‘AC06’, ‘CT6’, ‘MC3’, ‘C20’ and
‘Kingstone’ (Table 1) were cultivated in a research
greenhouse of Ferdowsi University of Mashhad,
Mashhad, Iran under optimum conditions. The lines
were crossed in all possible two-way combinations
(full diallel cross system) to develop F1 hybrids with
their reciprocals.

Experimental design

The experiment was performed in research green-
house of Ferdowsi University of Mashhad with com-
puterized temperature control system. A year round
was divided into two growing seasons: the first grow-

Table 1 - Description of parental inbred lines crossed in 7×7 full diallel cross system

Plant material Abbreviation Origin Growth habit Leaf type Fruti shape

Perimoga P1 Russia determinate vulgare oval
La1793 P2 USA indeterminate vulgare round
AC06 P3 Iran indeterminate vulgare round
CT6 P4 Russia semi-indeterminate grandifolium oval
MC3 P5 Russia indeterminate vulgare round
C20 P6 Russia indeterminate vulgare oval
Kingstone P7 Italy semi-indeterminate vulgare oval



Emami et al. - Tomato genotypes under low light condition

461

ing season was from March to August including
warm seasons with high light intensity and long pho-
toperiod (more sunny hours a day) and the second
season covering cold seasons with low light intensity
and short photoperiod (less sunny hours per day)
started in September and ended up in January. To
investigate the performance of tomato plants under
two different light conditions, 21 F1 progenies
together with reciprocals (42 F1 hybrid progenies)
developed via a 7×7 full diallel cross system were cul-
tivated during each of the two aforementioned
growing seasons. Daily average of light intensity of
experimental greenhouse during each month is rep-
resented in Table 2. The experiment was conducted
in a completely randomized design with three repli-
cations per genotype in two different time span men-
tioned above (split plot).

Measurement of characters

The observations concerning the following char-
acteristics were recorded as described below.

Total yield per plant (Kg)

It was calculated by summing up the weight of
fruits obtained from all pickings during 8 weeks from
each plant.

Average fruit weight (g)

The average fruit weight was an index of fruit size.
All fruits collected from each harvest were weighted
and the total weight of the fruits was divided into the
number of the weighted fruits.

Number of fruits per plant

Harvested fruits of each plant in a period of 8
weeks were counted.

Days to first flower

The number of days from seeding until the forma-
tion of first flower on the plants was recorded.

Days to ripening

The number of days from flower anthesis to fruit
ripening stage was determined through the date tag-
ging of five flowers per plant at the time of anthesis.
Fruit ripening was considered the time when geneti-
cally red fruits turned pink and yellow ones turned
yellow (Garg et al., 2008).

Statistical analysis

Obtained data in each environment were ana-
lyzed using Excel software (Microsoft office 2010)
using Griffing’s (1956, a, b) Method 3, Model 1 (fixed
effects) formula. Combined analysis of data over two
seasons was performed based on modified Method
3, Model 1 for several environments proposed by
Singh (1973) as described below: 
Where Yijk = observation of trait value of parents i

and j in year k; µ = population mean; g
i

/ g
j

= GCA

effect of parent i / j; sji / sji = SCA effect of the hybrid

developed from parent i × parent j / parent i × parent
j; rij = REC effect of the hybrid produced by parent i ×
parent  j; lk=effect of environment k; (gl)ik / (gl)jk =

interaction between GCA effect of parent i / j with
environment k; (sl)ijk = interaction between SCA
effect of cross ij with environment k; and eijk = error
of observation ijk. 

Broad-sense heritability (H2b.s) and narrow-sense
heritability (h2b.s) over environments were estimated
using following formula (Sharifi et al., 2010):

Where L indicated light condition; σ2g, σ2s and σ2r
stand for variance components of GCA, SCA and REC,
respectively; σ2gl, σ2sl and σ2rl represent variance
components of GCA×L, SCA×L and REC×L, respectively.

Where F1 and Yij are the mean performances of
hybrids and parents, respectively.

The average of light intensity per day was calculated based on 24 hours a day including night hours (n= 24, one measurements every hour).

Table 2 - Average of daily light intensity for each months (foot candle intensity/24h)

Average light intensity

First growing season with high light intensity and duration Second growing season with low light intensity and duration
Mar. Apr. May June July Aug. Sept. Oct. Nov. Dec. Jan. Feb.
680.7 694 750.5 863.3 893 760 650.7 547.3 550 527 535.5 655.7



Adv. Hort. Sci., 2018 32(4): 459-470

462

3. Results

ANOVA analysis 

The variance analysis of genotypes for each sea-
son separately showed that genotypes were highly
significant (Table 3); therefore, the compound analy-
sis of variance over two environments was conduct-
ed (Table 4). Light condition was considered as main
plot; therefore, error A refers to whole plot error.
Some genotypes, namely 42 F1 hybrids grown under
each light treatment along with the interaction
between genotypes and environments, were the sub
plot of the experiment and error B represent whole
plot error. Compound ANOVA analysis for two sea-
sons represented in Table 4 showed that light (L)

effect was highly significant for total yield per plant,
average fruit weight and days number to first flower
but not significant for fruit number per plant and
days number for fruit ripening. Genotypes and the
interaction of genotypes with light (G×L) were highly
significant for all studied traits except for days to
ripening in which genotypes did not show any inter-
action with environment.

Estimation of genetic parameters

Compound analysis of variance for general com-
bining ability (GCA), specific combining ability (SCA)
and reciprocal combining ability (REC) over two sea-
sons for yield, yield components and earliness varied
(Table 4). The results indicated that variances due to

Table 3 - Mean squares of ANOVA analysis over two light conditions for yield, yield components and earliness of F1 hybrids with their
reciprocals developed via a 7×7 full diallel cross

** Significant at P<0.01 level.

Sources of variation
Degree of
Freedom 

Total yield 
per plant (Kg)

Average of fruit
weight (g)

Fruit number
per plant 

Days to first
flower

Days
to ripening

Light (L) 1 16.69 ** 14654.49 ** 913.52 359.53 ** 5.43
error A 4 0.74 261.6 140.91 0.61 8.8
Genotypes (G) 41 2.05 ** 1944.73 ** 1593.50 ** 34.74 ** 23.38 **
G×L 41 0.17 ** 146.54 ** 96.24 ** 2.50 ** 3.99
error B 164 0.07 34.01 18.33 0.97 2.81

Table 4 - Compound analysis of variance for combining ability over two environments for yield, yield components and earliness of F1
hybrids with their reciprocals developed via a 7×7 full diallel cross and estimates of heritability in broad and narrow senses as
well as heterosis

* Significant at P<0.05 level, ** Significant at P<0.01 level. 

Sources of
variation

Degree of
Freedom 

Total yield per
plant
(Kg)

Average of fruit
weight

(g)

Fruits number 
per plant

Days to first 
flower

Days to
ripening

GCA 6 1.28 ** 3343.91 ** 2063.32 ** 54.66 ** 23.20 **
SCA 14 1.35 ** 430.82 ** 644.60 ** 9.55 ** 8.68 **
REC 21 0.07 ** 23.00 ** 17.79 ** 0.62 * 2.80 **
GCA×L 6 0.14 ** 120.47 ** 70.33 ** 2.86 ** 1.95
SCA×L 14 0.06 ** 53.49 ** 42.07 ** 0.94 ** 1.68 *
REC×L 21 0.03 25.29 * 14.49 ** 0.19 0.92
error 164 0.02 11.34 6.11 0.32 0.94

Variance components

σ2g - 0.06 166.63 102.86 2.72 1.11
σ2s - 0.33 104.87 159.62 2.31 1.94
σ2r - 0.01 2.92 2.92 0.07 0.47
σ2g/ σ2s - 0.19 1.59 0.64 1.18 0.57
σ2gl - 0.01 10.91 6.42 0.25 0.1
σ2sl - 0.02 21.08 17.98 0.31 0.37
σ2rl - 0 6.98 4.19 -0.07 -0.01
H2 broad-sense (%) - 94.77 94.94 95.7 94.38 90.38
h2 narrow-sense (%) - 26.02 72.22 53.89 66.25 48.34
Heterosis (%) 37.75 -22.95 55.04 3.05 -6.38



Emami et al. - Tomato genotypes under low light condition

463

GCA, SCA and REC were highly significant for all stud-
ied characters. The significance of both GCA and SCA
variances implies that all studied characters are con-
trolled by either of additive or non-additive gene
action. The effect of interaction GCA×L and SCA×L on
all evaluated features were significant but fruit ripen-
ing period, which showed non-significant variance of
GCA×L. The interaction of REC×L showed remarkable
effect only on average fruit weight and fruits number
per plant. For total yield, fruits number and days to
ripening, the GCA (σ2g) was less than variance com-
ponent of SCA (σ2s) in a way that σ2g/σ2s was less
than unity, demonstrating the predominance of non-
additive gene action in controlling mentioned traits
(Baker, 1978). The ratio of σ2g/σ2s for fruit weight
and days to first flower was higher than unity, illus-
trating the more important role of additive gene
action for inheritance of these attributes.

Estimates of broad-sense heritability percentage
(H2 %) over environments was high for all studied
traits ranged from 90 to 95% (Table 4). Narrow-sense
heritability percentage (h2 %) was low for total yield,
fruits number and days to ripening while relatively
high for fruit weight and days to flowering. Total het-
erosis percentage was high for yield and fruit number
while negative for fruit weight. Unlike yield and yield
components, in earliness characters negative values
show superiority but heterosis for early flowering
was positive. Negative but low heterosis was record-
ed for early maturity.

Estimation of mean values

Mean values of F1 hybrids for plant yield showed
that hybrid ‘CT6×MC3’ (P4×P5) had the highest rate
under both light conditions, while lowest amount
w a s  f o r  h y b r i d  ‘ C 2 0 × M C 3 ’  ( P 6 × P 5 )  ( T a b l e  5 ) .
‘Perimoga×Kingstone’ (P1×P7) cross and its reciprocal
produced heaviest fruits over two environments.
Lightest fruits produced under normal light were for
‘MC3×La1793’ (P5×P2), but under low light, the fruits
of hybrid ‘MC3×AC06’ (P5×P3) had the least weight.
The Highest number of fruits per plant was produced
by hybrid ‘La1793×C20’ (P2×P6) and the lowest was
f o r  ‘ K i n g s t o n e × P e r i m o g a ’  ( P 7 × P 1 ) .  H y b r i d
‘Perimoga×CT6’ (P1×P4) commenced flowering earli-
er than other progenies. Latest flowering under ade-
quate light intensity was for ‘MC3×C20’ (P5×P6),
w h i l e  u n d e r  l o w  l i g h t ,  i t  w a s  f o r  h y b r i d
‘La1793×AC06’ (P2×P3). Overall, according to pooled
data over two seasons, hybrid ‘C20×MC3’ (P6×P5)
took more days to flower compared with other prog-
enies. Longest fruit ripening duration was for hybrid

‘MC3×LA1793’ (P5×P2) and shortest period for ripen-
ing was observed in the cross of ‘ACO6×Kingstone’
(P3×P7).

Estimation of GCA, SCA and REC effect
For yield and yield components, positive values of

GCA, SCA and REC indicate the superiority of geno-
types while for earliness characters negative values
are desired (Table 6). Most of the parental lines were
not stable during two growing seasons and superior
parents for each character differed with environmen-
tal changes. Parental line of ‘CT6’ (P4) was the best
combiner for achieving higher yield in both seasons,
and the lowest GCA in low light and high light condi-
tion was for ‘Kingstone’ (P7) and ‘La1793’ (P2),
respectively. In total ‘Kingstone’ (P7) was the weakest
genitor for yield across two environments. For fruit
weight, although ‘Perimoga’ (P1) had the highest GCA
in warm season, parental line ‘Kingstone’ (P7) acted
as the best combiner in both seasons. The best
donors for increased fruits number during sunny and
cloudy seasons were ‘La1793’ (P2) and ‘MC3’ (P5),
respectively and ‘La1793’ (P2) had the best GCA over
both seasons. For days to first flower, parental geno-
type ‘Perimoga’ (P1) possessed the highest negative
GCA and ‘MC3’ (P5) had the highest positive and sig-
nificant GCA under each ambient light and over both
of them. The best combiner concerning days to ripen-
ing in both tested environments was ‘La1793’ (P2)
and the weakest performance was for ‘Kingstone’
(P7).

In yield and related trait, a positive value of SCA is
repetitive of a successful cross between parental
lines of that hybrid, while a negative value demon-
strates that parental lines did not make up a good
couple. For earliness, negative values of SCA are
indicative of prosperity .Estimation of SCA for each
evironment and over two environments indicated
t h a t  t h e  b e s t  c o m b i n a t i o n  f o r  t o t a l  y i e l d  w a s
‘ L a 1 7 9 3 × C 2 0 ’  ( P 2 × P 6 )  a n d  t h e  w o r s t  w a s  f o r
‘MC3×C20’ (P5×P6) (Table 7). For fruit weight, Hybrid
‘AC06×Kingstone’ (P3×P7) had the highest SCA during
sunny seasons, and the hybrid developed from
‘Perimoga×Kingstone’ (P1×P7) had the highest magni-
tude during cloudy seasons and over two seasons.
The highest and lowest SCA estimations for fruits
n u m b e r  w e r e  s i m i l a r  t o  t o t a l  y i e l d .  T h e  c r o s s
between ‘MC3×C20’ (P4×P6) was the most successful
cross for decreased days to flowering during sunny
months. ‘La1793×MC3’ (P2×P5) not only had the
highest negative SCA during cold months, but also
p o s s es s ed  t h e b es t  S C A  i n  t o t a l .  F o r  t h i s  t r a i t ,



464

Adv. Hort. Sci., 2018 32(4): 459-470

Table 5 - Means values and standard deviation for yield components and earliness of F1 hybrids developed via 7×7 diallel cross over two
light conditions (part A)

P1= Perimoga, P2= La1793, P3= AC06, P4= CT6, P5= MC3, P6= C20, P7= Kingstone. Values in parenthesis represent standard errors.
** Significant at P<0.01.

Genotypes
♀ × ♂

Total yield per plant (Kg) Average of fruit weight (g) Fruits number per plant

L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled

P1×P2 2.72(±0.28) 1.48(±0.44) 2.10(±0.36) 70.13(±8.70) 45.90(±9.34) 58.02(±8.83) 38.93(±3.02) 31.90(±3.92) 35.42(±3.07)

P1×P3 3.54(±0.36) 2.87(±0.48) 3.20(±0.42) 85.63(±10.48) 55.17(±8.89) 70.40(±8.53) 41.33(±1.64) 52.27(±7.01) 46.80(±2.69)

P1×P4 3.81(±0.14) 3.50(±0.06) 3.65(±0.10) 88.53(±2.05) 56.47(±4.97) 72.50(±1.63) 43.00(±2.55) 62.20(±5.20) 52.60(±1.96)

P1×P5 3.61(±1.02) 3.18(±0.20) 3.40(±0.60) 84.73(±7.22) 57.33(±3.14) 71.03(±2.79) 42.10(±8.98) 55.70(±6.58) 48.90(±7.65)

P1×P6 2.24(±0.19) 2.23(±0.36) 2.24(±0.26) 40.60(±4.06) 43.80(±4.88) 42.20(±2.08) 55.27(±2.15) 51.87(±13.90) 53.57(±5.97)

P1×P7 2.47(±0.36) 2.13(±0.33) 2.30(±0.34) 114.20(±14.97) 96.80(±10.83) 105.50(±8.28) 21.80(±3.97) 21.87(±2.20) 21.83(±2.05)

P2×P1 2.29(±0.18) 1.58(±0.22) 1.94(±0.20) 64.33(±16.06) 42.17(±2.35) 53.25(±7.55) 36.60(±5.97) 37.50(±6.41) 37.05(±0.52)

P2×P3 2.69(±0.17) 1.60(±0.04) 2.14(±0.08) 58.53(±7.25) 33.77(±2.03) 46.15(±2.64) 46.20(±3.10) 47.27(±2.75) 46.73(±1.05)

P2×P4 3.27(±0.31) 2.77(±0.23) 3.02(±0.27) 46.13(±2.06) 39.83(±4.11) 42.98(±2.72) 70.70(±5.05) 70.07(±9.36) 70.38(±7.17)

P2×P5 2.81(±0.25) 2.55(±0.20) 2.68(±0.19) 36.90(±3.33) 35.03(±2.84) 35.97(±1.21) 76.10(±4.58) 72.67(±3.25) 74.38(±3.01)

P2×P6 4.20(±0.33) 2.77(±0.31) 3.49(±0.32) 44.63(±1.65) 32.63(±3.39) 38.63(±2.32) 94.03(±5.54) 84.80(±3.99) 89.42(±4.13)

P2×P7 3.24(±0.33) 2.74(±0.33) 2.99(±0.33) 51.80(±4.54) 56.80(±4.54) 54.30(±4.54) 62.57(±1.72) 48.17(±2.29) 55.37(±1.94)

P3×P1 3.33(±0.31) 2.42(±0.31) 2.87(±0.31) 76.60(±8.52) 54.03(±11.95) 65.32(±10.03) 43.50(±3.21) 45.27(±4.35) 44.38(±2.98)

P3×P2 3.14(±0.30) 1.98(±0.25) 2.56(±0.19) 61.00(±2.11) 37.07(±3.62) 49.03(±1.37) 51.33(±3.18) 53.17(±2.90) 52.25(±2.83)

P3×P4 3.34(±0.24) 2.62(±0.19) 2.98(±0.21) 68.20(±8.89) 54.23(±7.73) 61.22(±8.29) 49.17(±3.73) 48.57(±3.27) 48.87(±3.48)

P3×P5 2.97(±0.25) 2.44(±0.30) 2.70(±0.27) 40.07(±1.75) 33.47(±4.46) 36.77(±3.07) 73.97(±3.10) 72.83(±1.05) 73.40(±1.15)

P3×P6 2.81(±0.24) 2.48(±0.12) 2.65(±0.18) 61.50(±1.71) 37.90(±3.73) 49.70(±2.66) 45.63(±3.85) 65.67(±6.37) 55.65(±4.15)

P3×P7 3.03(±0.18) 2.50(±0.20) 2.77(±0.19) 99.03(±5.56) 78.47(±2.90) 88.75(±1.66) 30.63(±0.59) 31.93(±3.61) 31.28(±1.89)

P4×P1 4.27(±0.34) 3.69(±0.15) 3.98(±0.16) 83.03(±12.08) 64.67(±4.61) 73.85(±3.83) 51.77(±3.88) 57.20(±3.72) 54.48(±0.33)

P4×P2 2.86(±0.2) 2.66(±0.20) 2.76(±0.09) 47.97(±4.71) 38.27(±3.84) 43.12(±1.66) 59.60(±1.73) 69.50(±1.85) 64.55(±0.15)

P4×P3 3.18(±0.36) 3.01(±0.22) 3.09(±0.29) 66.53(±1.46) 54.90(±6.05) 60.72(±3.02) 47.80(±6.17) 54.83(±1.93) 51.32(±2.63)

P4×P5 4.57(±0.26) 3.80(±0.34) 4.19(±0.27) 63.20(±4.30) 47.50(±3.76) 55.35(±1.30) 72.40(±3.41) 80.00(±5.73) 76.20(±3.21)

P4×P6 3.32(±0.32) 3.14(±0.25) 3.23(±0.24) 63.83(±3.40) 50.20(±7.27) 57.02(±3.95) 52.27(±7.31) 62.77(±4.40) 57.52(±2.45)

P4×P7 3.03(±0.31) 2.75(±0.17) 2.89(±0.21) 87.20(±11.27) 62.80(±3.24) 75.00(±5.56) 34.90(±2.80) 43.77(±0.51) 39.33(±1.57)

P5×P1 3.37(±0.31) 2.97(±0.35) 3.17(±0.58) 76.83(±8.81) 47.27(±5.53) 62.05(±1.91) 44.03(±3.81) 62.77(±2.74) 53.40(±3.14)

P5×P2 2.52(±0.40) 2.35(±0.27) 2.44(±0.58) 30.27(±4.99) 29.53(±2.17) 29.90(±1.41) 83.33(±3.32) 79.47(±7.33) 81.40(±5.24)

P5×P3 3.29(±0.21) 2.10(±0.22) 2.69(±1.53) 44.13(±4.23) 26.87(±2.87) 35.50(±0.79) 75.00(±9.37) 77.90(±3.30) 76.45(±3.36)

P5×P4 4.00(±0.20) 3.60(±0.15) 3.80(±2.08) 56.17(±4.99) 45.23(±1.63) 50.70(±2.92) 71.53(±8.22) 79.47(±0.49) 75.50(±4.29)

P5×P6 1.87(±0.23) 1.51(±0.18) 1.69(±0.58) 42.17(±4.32) 37.67(±2.97) 39.92(±1.66) 44.33(±1.12) 40.10(±6.67) 42.22(±3.82)

P5×P7 2.34(±0.25) 1.97(±0.35) 2.16(±0.58) 54.40(±3.10) 32.77(±3.08) 43.58(±3.09) 42.87(±2.34) 59.70(±5.28) 51.28(±3.73)

P6×P1 2.57(±0.29) 1.97(±0.34) 2.27(±0.58) 55.63(±3.27) 36.90(±3.24) 46.27(±3.25) 46.10(±3.57) 53.10(±5.48) 49.60(±4.45)

P6×P2 3.79(±0.39) 3.06(±0.25) 3.43(±1.53) 44.53(±2.34) 37.33(±4.52) 40.93(±3.41) 84.90(±4.27) 82.13(±4.31) 83.52(±1.90)

P6×P3 2.99(±0.15) 2.59(±0.18) 2.79(±1.53) 55.77(±2.89) 43.10(±4.45) 49.43(±0.78) 53.70(±5.11) 60.27(±2.29) 56.98(±1.75)

P6×P4 2.96(±0.18) 2.69(±0.24) 2.82(±1.53) 51.57(±0.46) 40.37(±6.80) 45.97(±3.35) 57.23(±3.45) 67.10(±5.23) 62.17(±0.94)

P6×P5 1.77(±0.16) 1.24(±0.22) 1.51(±0.58) 50.93(±2.78) 40.23(±9.32) 45.58(±5.95) 34.67(±1.35) 31.03(±1.76) 32.85(±0.88)

P6×P7 3.27(±0.35) 3.17(±0.25) 3.22(±0.58) 69.43(±3.52) 54.47(±3.54) 61.95(±3.53) 46.97(±2.77) 58.43(±8.39) 52.70(±3.27)

P7×P1 2.18(±0.16) 1.83(±0.20) 2.00(±0.58) 116.40(±13.25) 99.53(±8.03) 107.90(±9.74) 18.97(±3.54) 18.30(±1.01) 18.63(±2.14)

P7×P2 2.94(±0.12) 2.47(±0.17) 2.70(±1.00) 48.90(±0.35) 45.97(±3.68) 47.43(±1.95) 59.97(±2.03) 53.73(±2.06) 56.85(±1.55)

P7×P3 3.25(±0.33) 2.62(±0.18) 2.93(±0.58) 108.60(±11.61) 72.67(±1.29) 90.62(±6.45) 29.93(±1.27) 35.90(±2.20) 32.92(±1.70)

P7×P4 2.86(±0.09) 2.60(±0.16) 2.73(±0.58) 70.83(±2.00) 73.50(±2.56) 72.17(±1.24) 40.40(±2.40) 35.27(±0.99) 37.83(±1.63)

P7×P5 2.67(±0.45) 2.18(±0.21) 2.42(±0.58) 60.07(±12.53) 39.57(±1.89) 49.82(±7.03) 44.73(±3.43) 54.97(±3.85) 49.85(±0.39)

P7×P6 2.82(±0.27) 2.77(±0.27) 2.80(±1.15) 65.97(±8.25) 54.10(±5.91) 60.03(±1.24) 42.77(±1.37) 51.57(±7.46) 47.17(±3.05)

F 11.42 ** 16.70 ** 16.47 ** 25.61 ** 28.12 ** 45.39 ** 49.16 ** 33.15 ** 76.95 **

LSD 0.05 0.50 0.41 0.40 11.51 8.69 7.52 6.80 8.11 5.23

To be continued



465

Emami et al. - Tomato genotypes under low light condition

Table 5 - Means values and standard deviation for yield components and earliness of F1 hybrids developed via 7×7 diallel cross over two
light conditions

P1= Perimoga, P2= La1793, P3= AC06, P4= CT6, P5= MC3, P6= C20, P7= Kingstone. Values in parenthesis represent standard errors.
** Significant at P<0.01.

Genotypes 
♀ × ♂

Days to first flower Days to ripening

L1 L2 Pooled L1 L2 Pooled

P1×P2 56.00(±1.00) 54.33(±0.58) 55.17(±0.76) 14.00(±1.00) 15.67(±0.58) 14.83(±0.29)

P1×P3 56.67(±0.58) 54.00(±1.00) 55.33(±0.58) 16.67(±2.08) 18.67(±1.53) 17.67(±1.61)

P1×P4 54.00(±1.00) 50.67(±0.58) 52.33(±0.58) 18.33(±1.15) 18.33(±1.15) 18.33(±1.15)

P1×P5 62.67(±0.58) 60.33(±0.58) 61.50(±0.50) 19.00(±2.65) 20.67(±1.15) 19.83(±1.76)

P1×P6 58.00(±1.00) 54.67(±0.58) 56.33(±0.58) 18.00(±3.00) 18.00(±3.00) 18.00(±3.00)

P1×P7 57.33(±0.58) 53.33(±1.53) 55.33(±0.76) 19.33(±2.08) 18.67(±1.53) 19.00(±1.00)

P2×P1 56.67(±0.58) 54.67(±0.58) 55.67(±0.58) 19.00(±1.00) 16.67(±1.53) 17.83(±1.15)

P2×P3 60.33(±1.15) 60.67(±1.53) 60.50(±0.87) 18.33(±1.53) 17.33(±1.53) 17.83(±1.44)

P2×P4 60.67(±0.58) 58.67(±0.58) 59.67(±0.58) 16.33(±1.15) 15.67(±1.15) 16.00(±1.00)

P2×P5 60.67(±0.58) 58.67(±0.58) 59.67(±0.58) 15.67(±2.08) 15.67(±2.08) 15.67(±2.08)

P2×P6 61.67(±1.53) 60.33(±0.58) 61.00(±1.00) 17.00(±2.00) 17.00(±1.00) 17.00(±0.50)

P2×P7 58.33(±0.58) 58.00(±1.00) 58.17(±0.29) 16.33(±1.15) 17.00(±2.00) 16.67(±1.53)

P3×P1 57.33(±0.58) 54.67(±0.58) 56.00(±0.00) 18.33(±2.08) 18.33(±2.08) 18.33(±2.08)

P3×P2 60.00(±0.00) 59.67(±0.58) 59.83(±0.29) 20.33(±2.52) 19.33(±2.31) 19.83(±2.36)

P3×P4 56.00(±1.00) 55.67(±2.31) 55.83(±1.61) 16.67(±2.08) 16.67(±2.08) 16.67(±2.08)

P3×P5 60.00(±1.00) 56.33(±1.53) 58.17(±1.04) 20.00(±1.73) 17.33(±2.08) 18.67(±1.53)

P3×P6 60.67(±0.58) 59.00(±1.00) 59.83(±0.76) 17.00(±1.73) 17.00(±1.73) 17.00(±1.73)

P3×P7 58.33(±0.58) 56.33(±0.58) 57.33(±0.58) 22.67(±2.08) 22.67(±2.08) 22.67(±2.08)

P4×P1 54.67(±1.15) 51.33(±1.15) 53.00(±0.00) 17.00(±2.00) 17.00(±1.15) 17.00(±2.00)

P4×P2 60.00(±1.00) 58.00(±1.00) 59.00(±1.00) 15.00(±1.00) 14.00(±1.00) 14.50(±0.87)

P4×P3 58.00(±1.73) 57.00(±1.00) 57.50(±0.50) 14.67(±0.58) 15.33(±1.00) 15.00(±0.00)

P4×P5 61.67(±1.15) 59.67(±1.15) 60.67(±1.15) 18.00(±2.00) 18.00(±1.15) 18.00(±2.00)

P4×P6 56.33(±0.58) 54.33(±0.58) 55.33(±0.58) 20.00(±2.65) 21.00(±0.58) 20.50(±1.80)

P4×P7 57.67(±0.58) 55.67(±0.58) 56.67(±0.58) 18.67(±1.53) 18.67(±0.58) 18.67(±1.53)

P5×P1 62.00(±1.00) 59.33(±0.58) 60.67(±0.76) 20.33(±1.53) 19.33(±0.58) 19.83(±1.04)

P5×P2 61.67(±0.58) 58.33(±0.58) 60.00(±0.00) 13.00(±1.00) 12.67(±0.58) 12.83(±1.04)

P5×P3 61.00(±0.00) 57.33(±1.53) 59.17(±0.76) 19.67(±2.52) 16.00(±1.53) 17.83(±1.04)

P5×P4 60.67(±2.08) 58.67(±2.08) 59.67(±2.08) 19.00(±3.00) 20.33(±2.08) 19.67(±2.08)

P5×P6 63.67(±1.53) 58.67(±0.58) 61.17(±0.58) 21.00(±1.00) 20.33(±0.58) 20.67(±1.15)

P5×P7 61.00(±0.00) 58.33(±0.58) 59.67(±0.29) 21.33(±1.53) 15.00(±0.58) 18.17(±0.29)

P6×P1 58.33(±1.53) 55.33(±0.58) 56.83(±0.76) 17.67(±2.52) 17.67(±0.58) 17.67(±2.52)

P6×P2 62.33(±1.53) 59.67(±1.53) 61.00(±1.32) 15.00(±2.00) 15.33(±1.53) 15.17(±1.76)

P6×P3 59.67(±0.58) 59.33(±1.53) 59.50(±0.87) 16.00(±1.73) 19.67(±1.53) 17.83(±1.04)

P6×P4 56.67(±0.58) 54.33(±1.53) 55.50(±0.87) 20.00(±2.65) 18.33(±1.53) 19.17(±2.02)

P6×P5 63.33(±0.58) 60.33(±0.58) 61.83(±0.58) 18.67(±1.53) 18.67(±0.58) 18.67(±1.53)

P6×P7 59.00(±1.00) 55.33(±0.58) 57.17(±0.29) 20.67(±1.53) 21.33(±0.58) 21.00(±1.50)

P7×P1 58.00(±1.00) 52.67(±0.58) 55.33(±0.76) 20.67(±2.08) 20.67(±0.58) 20.67(±1.76)

P7×P2 60.00(±0.00) 59.00(±1.00) 59.50(±0.50) 20.00(±1.00) 18.00(±1.00) 19.00(±0.00)

P7×P3 58.33(±0.58) 56.33(±0.58) 57.33(±0.58) 20.67(±0.58) 20.67(±0.58) 20.67(±0.58)

P7×P4 58.33(±0.58) 56.33(±0.58) 57.33(±0.58) 17.33(±1.15) 18.67(±0.58) 18.00(±0.00)

P7×P5 62.00(±0.00) 59.33(±0.58) 60.67(±0.29) 20.00(±1.00) 17.67(±0.58) 18.83(±1.61)

P7×P6 58.67(±1.15) 53.33(±1.15) 56.00(±1.00) 19.00(±1.00) 19.00(±1.15) 19.00(±1.00)

F 18.69 ** 19.82 ** 28.14 ** 4.20 ** 19.82 ** 4.82 **

LSD 0.05 1.52 1.66 1.28 2.98 2.59 2.53

Continued



466

Adv. Hort. Sci., 2018 32(4): 459-470

Table 6 - General combining ability (GCA) effects of parental lines for yield, yield components and earliness in a 7×7 diallel cross over
two light conditions

P1= Perimoga, P2= La1793, P3= AC06, P4= CT6, P5= MC3, P6= C20, P7= Kingstone.
* Significant at P<0.05 level, ** Significant at P<0.01 level.
a difference between GCA of two parental lines at P<0.05 level.

Parental
lines

Total yield per plant 
(Kg)

Average of fruit weight 
(g)

Fruits number per
plant

Days to first flower Days to ripening

L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled

P1 -0.02 -0.06 -0.04 18.32 ** 10.97 ** 14.64 ** -13.46 ** -11.38 ** -12.42 ** -1.93 ** -2.70 ** -2.31 ** -0.06 0.42 0.18

P2 -0.02 -0.24 ** -0.13 ** -16.82 ** -11.61 ** -14.22 ** 14.63 ** 6.67 ** 10.65 ** 0.74 ** 1.77 ** 1.25 ** -1.90 ** -2.11 ** -2.00 **

P3 0.09 -0.12 ** -0.02 5.22 ** -0.87 2.17 ** -2.98 ** -1.78 * -2.38 ** -0.46 ** 0.40 * -0.03 0.2 0.36 0.28

P4 0.48 ** 0.64 ** 0.56 ** 1.98 3.76 ** 2.87 ** 3.28 ** 6.70 ** 4.99 ** -1.63 ** -1.20 ** -1.41 ** -0.80 * -0.34 -0.57 **

P5 -0.08 -0.06 -0.07 ** -13.35 ** -11.79 ** -12.57 ** 8.71 ** 10.29 ** 9.50 ** 2.94 ** 2.30 ** 2.62 ** 0.67 * -0.38 0.15

P6 -0.20 ** -0.08 -0.14 ** -12.68 ** -8.17 ** -10.42 ** 3.99 ** 4.51 ** 4.25 ** 0.74 ** 0.24 0.49 ** 0.1 0.79 ** 0.45 *

P7 -0.25 ** -0.07 -0.16 ** 17.34 ** 17.71 ** 17.52 ** -14.15 ** -15.01 ** -14.58 ** -0.40 * -0.83 ** -0.61 ** 1.77 ** 1.26 ** 1.51 **

LSD 0.05
gi - gj

a 0.16 0.13 0.09 3.56 2.68 2.07 2.1 2.51 1.52 0.47 0.51 0.35 0.92 0.8 0.6

Table 7 - Specific combining ability (SCA) effects of F1 hybrids for yield, yield components and earliness in a 7×7 diallel cross over two
light conditions

P1= Perimoga, P2= La1793, P3= AC06, P4= CT6, P5= MC3, P6= C20, P7= Kingstone. *Significant at P < 0.05  level.
** Significant at P<0.01 level.
a Difference between two SCA of two hybrids, with a common parent.
b Difference between two SCA of two hybrids, with non-common parent.

Genotypes
♀ × ♂

Total yield
per plant 

(Kg)

Average o
fruit weight 

(g)

Fruits number
per plant

Days to
first flower

Days to
ripening

L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled

P1×P2 -0.51 ** -0.70 ** -0.60 ** 1.29 -4.52 * -1.62 -14.90 ** -15.90 ** -15.40** -1.72 ** -1.43 ** -1.58 ** 0.21 -0.1 0.06

P1×P3 0.31 ** 0.29 ** 0.30 ** -6.87 ** -4.69 ** -5.78 ** 7.36 ** 6.62 ** 6.99** 0.14 -0.23 -0.04 -0.89 -0.23 -0.56

P1×P4 0.53 ** 0.48 ** 0.50 ** 1.03 -3.36 -1.16 6.07 ** 9.07 ** 7.57** -1.36 ** -1.97 ** -1.66 ** 0.28 -0.37 -0.04

P1×P5 0.55 ** 0.66 ** 0.60 ** 11.36 ** 3.93 * 7.64 ** -3.68 ** 5.01 ** 0.67 2.08 ** 3.37 ** 2.72 ** 0.81 2.00 ** 1.41 **

P1×P6 -0.42 ** -0.29 ** -0.36 ** -21.97 ** -11.65 ** -16.81 ** 8.66 ** 4.04 * 6.35** 0.11 0.6 0.36 -0.46 -1.33 * -0.89 *

P1×P7 -0.45 ** -0.43 ** -0.44 ** 15.16 ** 20.30** 17.73 ** -3.51 * -8.84 ** -6.17** 0.74 * -0.33 0.21 0.04 0.03 0.04

P2×P3 -0.21 * -0.38 ** -0.30 ** 6.92 ** -1.3 2.81 * -14.38 ** -9.97 ** -12.18** 0.64 * 1.13 ** 0.89 ** 2.78 ** 2.13 ** 2.46 **

P2×P4 -0.46 ** -0.22 * -0.34 ** -2.56 -2.3 -2.43 -4.25 ** 1.11 -1.57 1.98 ** 0.90 ** 1.44 ** 0.11 -0.67 -0.28

P2×P5 -0.29 ** 0.21 * -0.04 -0.69 6.48 ** 2.90 * 4.88 ** 3.80 * 4.34** -1.76 ** -2.43 ** -2.09 ** -2.69 ** -1.30 * -1.99 **

P2×P6 1.16 ** 0.70 ** 0.93 ** 9.64 ** 5.56 ** 7.60 ** 19.35 ** 16.98 ** 18.17** 1.28 ** 1.13 ** 1.21 ** -0.46 -0.47 -0.46

P2×P7 0.31 ** 0.38 ** 0.35 ** -14.61 ** -3.91 * -9.26 ** 9.29 ** 3.99 * 6.64** -0.42 0.70 * 0.14 0.04 0.4 0.22

P3×P4 -0.37 ** -0.24 ** -0.30 ** -4.28 2.48 -0.9 -3.31 * -8.53 ** -5.92** -0.16 0.27 0.06 -1.99 ** -1.97 ** -1.98 **

P3×P5 0.07 -0.09 -0.01 -14.22 ** -6.37 ** -10.29 ** 17.26 ** 11.55 ** 14.41** -1.22 ** -2.73 ** -1.98 ** 0.71 -1.27 * -0.28

P3×P6 -0.04 0.20 * 0.08 1.65 0.34 1 -2.84 * 4.93 ** 1.05 0.64 * 1.67 ** 1.16 ** -2.06 ** -0.77 -1.41 **

P3×P7 0.25 * 0.22 * 0.23 ** 16.80 ** 9.54 ** 13.17 ** -4.09 ** -4.60 ** -4.34** -0.06 -0.1 -0.08 1.44 * 2.10 ** 1.77 **

P4×P5 0.83 ** 0.58 ** 0.71 ** 6.60 ** 5.20 ** 5.90 ** 8.48 ** 7.43 ** 7.96** 0.61 1.20 ** 0.91 ** 0.38 1.93 ** 1.16 **

P4×P6 -0.2 -0.18 * -0.19 ** 3.95 0.49 2.22 -4.01 ** -1.59 -2.80** -1.86 ** -1.57 ** -1.71 ** 2.44 ** 1.27 * 1.86 **

P4×P7 -0.34 ** -0.43 ** -0.38 ** -4.75 * -2.51 -3.63 ** -2.98 * -7.48 ** -5.23** 0.78 * 1.17 ** 0.97 ** -1.22 * -0.2 -0.71

P5×P6 -0.95 ** -1.02 ** -0.98 ** 8.13 ** 9.71 ** 8.92 ** -24.69 ** -34.54 ** -29.62 ** 0.58 0.1 0.34 0.81 1.13 0.97*

P5×P7 -0.21 -0.33 ** -0.27 ** -11.20 ** -18.95 ** -15.07 ** -2.26 6.75 ** 2.24 * -0.29 0.5 0.11 -0.02 -2.50 ** -1.26 **

P6×P7 0.45 ** 0.59 ** 0.52 ** -1.4 -4.45 * -2.93 * 3.53 * 10.19** 6.86 ** -0.76 -1.93 ** -1.34 ** -0.29 0.17 -0.06

LSD 0.05

S
ij

− S
ik

a 0.29 0.23 0.17 6.44 4.87 3.75 3.81 4.54 2.75 0.85 0.93 0.63 1.67 1.45 1.08

S
ij

− S
kl

b 0.25 0.2 0.14 5.58 4.21 3.25 3.3 3.93 2.38 0.74 0.81 0.55 1.44 1.26 0.93



Emami et al. - Tomato genotypes under low light condition

467

‘Perimoga×MC3’ (P1×P5) was the weakest combina-
tion across both environments. The most negative
value of SCA for ripening period under low light
belonged to ‘La1793×MC3’ (P2×P5) and under high
light was for ‘Kingstone×MC3’ (P7×P5). Pooled value
of SCA in this character showed that generally
‘La1793×MC3’ (P2×P5) and ‘AC06×La1793’ (P3×P2)
had the highest and the lowest negative values,
respectively.

The results of REC indicated that the best recipro-
cal combinations over two environments for total
yield, average of fruit weight, fruits number, days to
f l o w e r i n g  a n d  d a y s  t o  r i p e n i n g  w a s  f o r
‘AC06×La1793’ (P3×P2), ‘Kingstone×MC3’ (P7×P5),
‘MC3×La1793’ (P5×P2), ‘Kingstone×C20’ (P7×P6) and
‘MC3×La1793’ (P5×P2), respectively (Table 8). The
Lowest pooled REC in foregoing characters was for
‘ K i n g s t o n e × C 2 0 ’  ( P 7 × P 6 ) ,  ‘ C 2 0 × C T 6 ’  ( P 6 × P 4 ) ,
‘ C 2 0 × M C 3 ’  ( P 6 × P 5 ) ,  ‘ M C 3 × A C 0 6 ’  ( P 4 × P 3 )  a n d
‘La1793×Perimoga’ (P2×P1), respectively

4. Discussion and Conclusions

The results indicated that total yield, average fruit
weight and flowering time were influenced by the
amount of received light, while fruit number and fruit
ripening period were not affected. Genotype effect
was highly significant for all studied traits implying
the feasibility of breeding. Despite of simultaneous
influence of light and genotype on yield, fruit weight
and days to flower, a comparison between magni-
tude of environment and genotype effects revealed
that the genotype variation played more important in
the expression of studied traits.

The significance of interaction genotype × light
condition (G×L) for almost all characters except days
to ripening revealed that there is a genotype varia-
tion in response to light intensity as regards yield,
yield components and early flowering. Previous stud-
ies reported genotype variation regarding reaction to
environmental light in different species (Stratton,

Table 8 - Reciprocal effect (REC) for yield, yield components and earliness in a 7×7 diallel cross over two light conditions

P1= Perimoga, P2= La1793, P3= AC06, P4= CT6, P5= MC3, P6= C20, P7= Kingstone. 
* Significant at P<0.05 level, ** Significant at P<0.01 level.
a Difference between two RCA of two hybrids.

Genotypes
♀ × ♂

Total yield
per plant (Kg)

Average of
fruit weight (g)

Fruits number
per plant

Days to
first flower

Days to
ripening

L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled L1 L2 Pooled

P2×P1 -0.22 0.05 -0.08 -2.9 -1.87 -2.38 -1.17 2.8 0.82 0.33 0.17 0.25 2.50 ** 0.5 1.50 **

P3×P1 -0.11 -0.23 * -0.17 * -4.52 -0.57 -2.54 1.08 -3.5 -1.21 0.33 0.33 0.33 0.83 -0.17 0.33

P4×P1 0.23 0.1 0.17 * -2.75 4.1 0.67 4.38 * -2.5 0.94 0.33 0.33 0.33 -0.67 -0.67 -0.67

P5×P1 -0.12 -0.11 -0.11 -3.95 -5.03 * -4.49 ** 0.97 3.53 2.25 -0.33 -0.5 -0.42 0.67 -0.67 0

P6×P1 0.16 -0.13 0.02 7.52 * -3.45 2.03 -4.58 ** 0.62 -1.98 0.17 0.33 0.25 -0.17 -0.17 -0.17

P7×P1 -0.15 -0.15 -0.15 * 1.1 1.37 1.23 -1.42 -1.78 -1.6 0.33 -0.33 0 0.67 1 0.83

P3×P2 0.22 0.19 0.21 ** 1.23 1.65 1.44 2.57 2.95 2.76 * -0.17 -0.5 -0.33 1 1 1.00 *

P4×P2 -0.21 -0.06 -0.13 0.92 -0.78 0.07 -5.55 ** -0.28 -2.92 * -0.33 -0.33 -0.33 -0.67 -0.83 -0.75

P5×P2 -0.14 -0.1 -0.12 -3.32 -2.75 -3.03 3.62 * 3.4 3.51 ** 0.5 -0.17 0.17 -1.33 -1.50 * -1.42 **

P6×P2 -0.21 0.14 -0.03 -0.05 2.35 1.15 -4.57 ** -1.33 -2.95 * 0.33 -0.33 0 -1 -0.83 -0.92

P7×P2 -0.15 -0.14 -0.15 * -1.45 -5.42 * -3.43 * -1.3 2.78 0.74 0.83 * 0.5 0.67 * 1.83 * 0.5 1.17 *

P4×P3 -0.08 -0.19 0.06 -0.83 0.33 -0.25 -0.68 3.13 1.23 1.00 * 0.67 0.83 ** -1 -0.67 -0.83

P5×P3 0.16 -0.17 -0.01 2.03 -3.3 -0.63 0.52 2.53 1.52 0.5 0.5 0.5 -0.17 -0.67 -0.42

P6×P3 0.09 0.06 0.07 -2.87 2.6 -0.13 4.03 * -2.7 0.67 -0.5 0.17 -0.17 -0.5 1.33 * 0.42

P7×P3 0.11 0.06 0.08 4.77 -2.9 0.93 -0.35 1.98 0.82 0 0 0 -1 -1 -1.00 *

P5×P4 -0.29 * -0.1 -0.19 ** -3.52 -1.13 -2.33 -0.43 -0.27 -0.35 -0.5 -0.5 -0.5 0.5 1.17 0.83

P6×P4 -0.18 -0.22 * -0.20 ** -6.13 * -4.92 * -5.53 ** 2.48 2.17 2.32 0.17 0 0.08 0 -1.33 * -0.67

P7×P4 -0.09 -0.08 -0.08 -8.18 ** 5.35 * -1.42 2.75 -4.25 * -0.75 0.33 0.33 0.33 -0.67 0 -0.33

P6×P5 -0.05 -0.13 -0.09 4.38 1.28 2.83 -4.83 ** -4.53 * -4.68 ** -0.17 0.83 * 0.33 -1.17 -0.83 -1.00 *

P7×P5 0.17 0.1 0.13 2.83 3.4 3.12 0.93 -2.37 -0.72 0.5 0.5 0.5 -0.67 1.33 * 0.33

P7×P6 -0.23 -0.2 -0.21 ** -1.73 -0.18 -0.96 -2.1 -3.43 -2.77* -0.17 -1.00 * -0.58 * -0.83 -1.17 -1.00 *

LSD 0.05

R
ij

− R
ik

a
0.31 0.25 0.18 7.04 5.32 4.1 4.16 4.96 3.01 0.93 1.02 0.69 1.82 1.59 1.18



Adv. Hort. Sci., 2018 32(4): 459-470

468

D.A., 1998; Martínez-Ferri et al., 2001) promising for
plant improvement regarding maintenance of high
yield and earliness under lower level of light intensi-
ty. The remarkable effect of interaction G×L on stud-
ied traits except ripening period demonstrated that
genotypes were not stable across two environments
and should be evaluated in a range of environments.
Importance of genotype selection across different
environments for tomato improvement concerning
yield and earliness attributing traits was reported by
Chadha and Kumar (2001), and Biswas et al. (2011).

According to mean performances of hybrids,
superior genotypes for various characteristics dif-
fered and none of them could be considered as the
best for all of the attributes.  In this regard, in order
to commercialize F1 hybrids, breeding programs
should be conducted to collect suitable features in
one plant (Breseghello and Coelho, 2013).

Either of general combing ability (GCA) or specific
combining ability (SCA) was highly significant for all
of evaluated features illustrating both additive and
non-additive gene action were involved in controlling
yield, yield components and earliness. Our findings
supports additive-dominance model reported by
Chishti et al. (2008) and Biswas et al. (2011) for pro-
duction and earliness traits. Significant contribution
of REC to total sum squire is indicative of inter-allelic
interactions in the expression of studied traits.
Similarly, REC effect on fruit weight and number was
reported by Hannan et al., (2007 b).

Higher magnitude of SCA variance (σ2s) in compar-
ison with GCA variance (σ2g) for total yield, fruit num-
ber and days to ripening indicated that these traits
are mainly under the control of dominant effects.
Similar findings were reported by Solieman (2009)
and El-Gabry et al. (2014) for fruit yield and number.
The predominance of non-additive gene action over
additive effects for days to ripening was in agree-
ment with Hannan et al. (2007a) but inconsistent
with Garg et al. (2008) who found additive gene
action to be more effective on days to ripening over
two environments.

The ratio of σ2g/σ2s over two light conditions was
greater than unity for fruit weight and days to flow-
ering indicative of more weight of additive effects in
inheritance of these features. Garg et al. (2008), Rai
and Asati (2011) and Nadeem et al. (2013) also con-
tributed the expression of fruit weight and early
flowering to both additive and dominance gene
actions with preponderance of additive effects.
Biswas et al. (2011) who examined tomato genotypes
across two environments, different in terms of tem-

perature and light intensity, reported more impor-
tant role of additive gene action in control of fruit
weight.

The interaction GCA×L was significant for all char-
acters except for days to ripening indicating the sen-
sibility of additive effects to light condition. The sig-
nificant interaction SCA×L was indicative of instability
of dominance effects under different environmental
light. REC×L varied for fruit weight and number
demonstrating the susceptibility of cytoplasmic
effects to environment in some traits and necessity
of reciprocal crosses for choosing the most suitable
genotypes for target environment.

Estimates of broad-sense heritability percentage
(H2b.s%) across two different light conditions was
high, demonstrating the low effect of environment
and high response of studied traits to breeding pro-
grams. Relatively high narrow sense heritability per-
centage (h2n.s%) for fruit weight and early flowering
indicated that these traits are largely controlled by
additive effects; while, low h2n.s% of yield, fruit num-
ber and early maturity demonstrated higher weight
of non-additive effects in inheritance of these traits.
These findings agree with earlier work of Biswas et
al. (2011) and Dutta et al. (2013) who reported low
narrow sense heritability for yield and fruit number
over two environments.

Importance of both additive and non-additive
gene action with predominance of additive effects in
expression of fruit weight and days to flowering
revealed that selection breeding programs could be
an effective strategy for genetic improvement of
tomato for these characters, while exploitation of
hybrid vigor should not be neglected (Grilli et al.,
2003). Yield, fruit number and early ripening were
controlled by additive-dominance effects with higher
weight of dominance effects implying hybrid breed-
ing could be adopted for improvement of these char-
acters (Gul et al., 2010). Abd El-Maksoud et al. (2013)
proposed recurrent selection program for improve-
ment of traits controlled by both additive and non-
additive effects. For such traits, hybridization in seg-
regating generations followed by selection for out-
performing genotypes has been recommended
(Dutta et al., 2013; Bhattarai et al., 2016).

Limitation in access to clean energy resources in
rural areas and global interest toward lower energy
consumption necessitate breeding for low energy
input. In the current study, genetic variation among
tomato genotypes under different light conditions
was observed and some genotypes showed more sta-
bility than others. None of parental lines or F1



Emami et al. - Tomato genotypes under low light condition

469

hybrids exhibited high performance for all studied
features, therefore, a particular genotype cannot be
r e c o m m e n d e d .  H o w e v e r ,  g e n e t i c  k n o w l e d g e
obtained from this research could be used in plan-
ning tomato breeding programs. More important
role of additive gene action in inheritance of fruit
weight and early flowering indicate the effectiveness
of selection breeding, while predominance of non-
additive effects in genetic expression of plant yield,
fruit number and early maturity suggest adoption of
bi-parental mating for improvement of mentioned
traits.

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