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Quality characteristics of parental lines of wheat mapping 
populations

Antonella Pasqualone1, Luciana Piarulli2, Giacomo Mangini2,
Agata Gadaleta2, Antonio Blanco2 and Rosanna Simeone2

1Food Science and Technology Unit, University of Bari, Department of Soil, Plant and Food Sciences, Via Amendola, 165/A, I 
70126, Bari, Italy

2Genetics and Plant Breeding Unit, University of Bari, Department of Soil, Plant and Food Sciences, Via Amendola, 165/A, I 
70126, Bari, Italy

email: antonella.pasqualone@uniba.it

The aim of this work was to evaluate the main quality traits in the parental lines of wheat segregating populations 
to identify the best for subsequent genetic mapping of the traits. Significant differences (p < 0.001) among wheat 
genotypes were observed. Many of the examined crosses appeared to be suitable for the purpose, showing differ-
ences among parental lines as high as 4.6% for protein content, 6.4% for gluten content, 69 for gluten index, 50 mL 
for sodium dodecyl sulphate sedimentation volume, and 33.9 g for thousand-kernel weight, whereas differences 
accounting for 4.8, 2.4, and 7.3 were observed for yellow index, red index and brown index, respectively. The re-
sults pointed out that for studying at the same time the quantitative and qualitative features of gluten, the wheat 
populations derived from Latino x MG29896 and Saragolla x 02-5B-318 could be particularly appropriate. In addi-
tion, the latter cross was suitable to deepen the knowledge of yellow index regulation.

Key words: wheat, whole meal, mapping population, protein, gluten

Introduction

The most important quality characteristics for both bread and pasta are the textural and color features. The first, 
both in soft and durum wheat, are strongly related to the quali-quantitative characteristics of gluten-forming pro-
teins, which properties allow wheat flour to be transformed into bread or pasta (Goesaert et al. 2005). Moreover, 
when high-temperature drying technology is used, protein content remains the most important parameter influ-
encing the cooking quality of pasta (D’Egidio et al. 1990).

Color influences consumer choice at the moment of purchase: bright yellow pasta, arising from carotenoid pig-
ments of durum wheat semolina (Feillet et al. 2000) is preferred over pale or discolored products. In addition, 
carotenoids increase the nutritional value (Garcia-Casal 2006). Similarly, when semolina is used in bread-making, 
as usually made in Southern Italy (Pasqualone 2012) and in Mediterranean countries (Qaroni 1996), its pigments 
confer a distinctive and appreciated yellowish tone to bread crumb (Pasqualone et al. 2004, 2007). Undesired 
color alterations, mainly browning, can derive from Maillard’s reaction or enzymatic activity. Polyphenol oxidase, 
in particular, abundant in the varieties richer of phenolics (Pasqualone et al. 2014), is correlated with both dough 
darkening (Taranto et al. 2012) and color alterations of noodles (Fuerst et al. 2006) and bread (McCallum and 
Walker 1990). On the other hand, pigmented wheats - red, purple, or blue - are becoming the object of interest 
due to their high anthocyanin content (Ficco et al. 2014).

Many breeding efforts have been devoted to increase the quality features of wheat. In particular, genetic link-
age maps, that locate genes related to traits of interest, are an useful tool in breeding programs. The availability 
of markers linked to quantitative trait loci (QTLs) facilitates the genetic dissection of quantitative traits and the 
early selection in wheat breeding programs. Detecting QTLs by molecular markers involves the analysis of popu-
lations constituted by large number of individuals which segregate concurrently for marker loci and quantitative 
trait expression. Double haploid and recombinant inbred populations are particularly suited for this purpose as 
they can be characterized for additional loci at any time and analyzed in combination with the previously accu-
mulated data, assumed that parental lines are sufficiently differentiated for the traits of interest, so as to ensure 
segregation. Such lines constitute permanent mapping populations that may be evaluated over space and time 
(Mather and Jinks 1971).

Manuscript received March 2015



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Previous papers have reported the effective detection and mapping of quantitative trait loci (QTLs) related to 
protein content (Blanco et al. 2002), sodium dodecyl sulphate sedimentation volume (Blanco et al. 1998), yellow 
pigments (Blanco et al. 2011) and yield components (Blanco et al. 2001) in recombinant inbred populations of 
tetraploid wheat. However, some genes are cultivar specific, hence it is needed to investigate on them in several 
mapping populations (Bernardo 2008).

The aim of this work was to evaluate the main quality traits (thousand-kernel weight, protein content and compo-
sition, quali-quantitative features of gluten, color indices) of parental lines of existing wheat mapping populations 
to identify the best to be used for subsequent mapping of the traits of interest in the derived segregating progeny.

Material and methods
Samples

Twenty-nine wheat accessions and cultivars, reported in Table 1,were considered. All of them were parental lines 
of segregating populations set up at the Genetics and Plant Breeding Unit, Department of Soil, Plant and Food Sci-
ences (DISSPA), University of Bari (Italy), for a total of 28 crosses, as specified in Table 2. The plants were grown in 
the experimental field of the Department of Soil, Plant and Food Sciences at Valenzano (Bari, Italy) in 2013, in a 
randomized complete block design with three field replicates and plots consisting of 1-m rows, 30 cm apart, with 
50 germinating seeds per plot. During the growing season, 120 kg ha-1 N were applied and standard cultivation 
practices were adopted. Plots were hand-harvested at maturity. A seed sample (15 g) per plot was used to deter-
mine the thousand-kernel weight (KW).

Basic chemical and physical determinations
Harvested grain samples from each plot were separately milled to whole meal on a laboratory mill equipped with 
1-mm sieve (Cyclotec Sample Mill, Tecator Foss, Hillerød, Denmark). Moisture content was determined at 105 °C
by means of an automatic moisture analyzer (Radwag Wagi Elektroniczne, Radom, Poland). Grain protein content 
(GPC) was determined by using a dual beam near infrared reflectance spectrophotometer (Zeutec Spectra Alyz-
er Premium, Zeutec Büchi, Rendsburg, Germany). Colorimetric evaluations of yellow index (YI, corresponding to
b*), red index (RI, a*), and brown index (BI, defined as 100-L*), were carried out by means of the reflectance col-
orimeter Chroma Meter CR-300 (Konica Minolta Sensing, Osaka, Japan). Whole meal was placed into the granu-
lar materials attachment CR-A50 (Konica Minolta Sensing, Osaka, Japan) of the colorimeter to obtain a smooth
surface suitable for color readings. Results were the average of two analytical replications apart for colorimetric
evaluations that were replicated 5 times.

Table 1. Taxonomic classification of the wheat cultivars and accessions considered

Taxonomic classification Type of plant material

Triticum aestivum L. ssp. aestivum

Chinese Spring Cultivar

Chinese Spring - 5A dic.
Chinese Spring disomic substitution line of 5A chromosome 
with the accession TA106 of ssp. dicoccoides

02-5B-318 Breeding line

Triticum turgidum ssp. dicoccum (Schrank ex Schϋbler) Thell.

MG5323 Landrace

Triticum turgidum ssp. dicoccoides (Körn. ex Asch. & Graebner) Thell.

MG4343; MG4330; MG29896 Wild accessions

Triticum turgidum ssp. durum (Desf.) Husnot

CItr 14629 Purple line derived from an Ethiopic landrace 

UC1113
UC Davis breeding line with the high grain protein content 
gene GpcB1

Anco Marzio; Aureo; AC Avonlea; Ciccio; Duilio; Fiore; Grecale; Iride; 
Isildur; Latino; Latinur; Liberdur; Messapia; Neolatino; Normanno; Preco; 
Primadur; Saragolla; Svevo; Tiziana

Cultivars



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Determination of quali-quantitative features of gluten

Wet gluten (WG) and gluten index (GI) were determined according to the ICC Standard No. 155 (ICC 1994) by 
means of the complete system consisting of Glutomatic 2200, Centrifuge 2015, and Glutork 2020 (Perten Instru-
ments AB, Huddinge, Sweden). First, WG was recovered by means of Glutomatic 2200 (Perten Instruments AB, 
Huddinge, Sweden). Then, GI was calculated as the percent ratio of the WG fraction remaining on the sieve after 
centrifugation (Centrifuge 2015, Perten Instruments AB, Huddinge, Sweden) to the total WG weight. Dry gluten 
(DG) was determined by drying the total WG at 150 °C for 4 min by means of Glutork 2020 apparatus (Perten In-
struments 0AB, Huddinge, Sweden). Gluten hydration index (GHI) was calculated as the percent ratio (WG - DG)/
WG. Results were the average of two analytical replications.

Sedimentation volume in sodium dodecyl sulphate (SDS-SV)
The test of SDS-SV was performed according to the ICC Standard method no. 151 (ICC 1990). Results were the av-
erage of two analytical replications.

Electrophoretic analyses of seed storage proteins

Gliadins and glutenins were extracted from 60 mg whole meal flour and analyzed by polyacrylamide gel electro-
phoresis in acidic conditions (A-PAGE) and sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE), 
respectively, on a Protean II apparatus (Bio-Rad, Hercules, CA), according to the conditions of Lukow et al. (1990).

Statistical analyses
Standard ANOVA (with genotype as fixed factor and replication as random factor) was performed using the soft-
ware MSTAT-C (Michigan State University, East Lansing, MI). The differences (Δ) between pairs of parental lines 
of segregating populations were calculated and the Fisher’s least significant difference at 5% significance level 
(LSD

0.05
) was applied to point out the most polymorphic pairs for the traits analyzed. Pearson phenotypic correla-

tion coefficients (R) were calculated among all traits.

Results and discussion
Variability of quality characteristics and correlations among them

Glutenins and gliadins encoded at the Glu-1 and Gli-1 loci are the most commonly considered in wheat breeding pro-
grams aimed to improve gluten quality. The glutenin composition, in particular, has been used to establish a quality 
score, as extensively reviewed by Shewry et al. (1992). The allelic variations of high molecular weight glutenin sub-

aGadaleta et al. 2012, 2014; bPiarulli et al. 2012; cBlanco et al. 1998, 2001, 2002; dBlanco et al. 2011; eBlanco et al. 
2012.

Table 2. Pairs of parental lines and progeny size of 28 wheat mapping populations set up at the Genetics and 
Plant Breeding Unit, Department of Soil, Plant and Food Sciences, University of Bari, Italy

Cross Progeny individuals (no.) Cross
Progeny 
individuals (no.)

Aureo x Normanno 896 Iride x Fiore 180

Aureo x Iride 616 Svevo x MG4330 177

Saragolla x 02-5B-318 421 Grecale x Tiziana 160

Neolatino x Preco 409 Iride x Ciccio 160

Latinur x Saragolla 405 Normanno x Fiore 160

Isildur x Saragolla 405 Duilio x AC Avonlea 150

Liberdur x Saragolla 324 CItr 14629 x Grecale 148

Svevo x Primadur 322 Latino x MG29896 144

UC1113 x Iride 320 Grecale x Fiore 130

Isildur x Anco Marzio 308 Latino x MG5323b 122

Liberdur x Anco Marzio 296 Messapia x MG4343c 122

Normanno x Tiziana 260 Latino x Primadurd 121

Svevo x Messapia 249 Svevo x Ciccioe 120

Chinese Spring x Chinese Spring - 5A dic.a 188 Iride x Tiziana 90



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units (HMW-GS) and of ω- and γ-gliadins in the wheat cultivars and accessions considered are reported in Table 3. 
Three different HMW-GS alleles at the Glu-A1 locus, 5 HMW-GS alleles at the Glu-B1 locus, and 5 different gliadin 
alleles at the Gli-B1 locus, were observed. The number of alleles at each loci decreased to 2 if durum wheat cul-
tivars only were considered. Due to the breeding process, the majority of cultivars contained HMW-GS 7+8 sub-
units, that are characterized by a higher quality score than 6+8 or 20 subunits (Boggini and Pogna 1989, Shewry 
et al. 1992). The Triticum aestivum cultivar Chinese Spring and its disomic substitution line showed a 2+12 pat-
tern at the Gli-D1 locus, known to be related to lower gluten quality if compared to the 5+10 combination. Latino 
was the only cultivar characterized by γ-42 gliadin. With few exceptions (Pogna et al. 1990), this gliadin is associ-
ated to type-1 low molecular weight glutenin subunits (LMW-GS 1), related to low technological quality (Boggini 
and Pogna 1989). The γ-45 gliadin, usually related to type-2 LMW-GS and considered an easily detectable quality 
marker (Boggini and Pogna 1989), was observed in the improved Neolatino cultivar (derived from Latino) and in 
all the other cultivars. In addition, Neolatino showed also the HMW-GS 2* subunit, that positively influences qual-
ity more than the null allele that, instead, characterized all the other cultivars. As expected, the landrace MG5323 
and the wild accessions MG4343, MG4330, and MG29896 showed the most differentiated patterns in terms of 
both gliadins and HMW-GS.

The analysis of variance carried out on GPC, quali-quantitative characteristics of gluten, SDS-SW, KW, and color 
indices of parental lines of wheat mapping populations revealed highly significant differences (p < 0.001) among 
genotypes for all the traits (Table 4).

GPC and gluten quality of wheat are the most important factors affecting pasta consistency and resistance to over-
cooking (D’Egidio et al. 1990) and bread volume (Goesaert et al. 2005). In the examined set of 29 wheat acces-
sions and cultivars, the GPC varied in the range comprised between 14.0% and 19.5% (Table 5). As expected for 
wild materials, the highest values were observed in ssp. dicoccoides, and confirmed the levels ascertained in the 
same materials in previous researches (Taranto et al. 2012). Among the durum cultivars, Preco showed the high-
est value of GPC, and also the line CItr 14629 showed a considerably high level of proteins.

aAt Glu-D1 locus the subunits 2+12 were observed.
n.d. = not determined.

Table 3. Allelic composition of high molecular weight glutenin subunits (HMW-GS) and of ω- and γ-gliadins, encoded at Glu-A1, 
Glu-B1, and Gli-B1 loci, detected in wheat cultivars and accessions

Parental line

Locus

Glu-A1 Glu-B1 Gli-B1

HMW-GS 
subunit 
composition

Allele 
code

HMW-
GS subunit 
composition

Allele 
code Gliadin composition

Allele 
code

Chinese Springa null c 7+8 b ω-31-35-38, γ-42
Chinese Spring - 5A dic.a null c 7+8 b ω-31-35-38, γ-42
02-5B-318 n.d. n.d. n.d.
MG5323 1 a 22 k ω -31-33, γ-45
MG4343 1 a 18+23 ω -31-33, γ-45
MG4330 2* b 20 e ω-31-35-38, γ-45
MG29896 1 a 6+8 d ω-31, γ-45
Cltr 14629 n.d. n.d. n.d.
UC1113 null c 7+8 b ω-35, γ-45 c
Anco Marzio null c 7+8 b ω-35, γ-45 c
Aureo n.d. 6+8 ω-35, γ-45
AC Avonlea n.d. n.d. ω-35, γ-45
Ciccio null c 7+8 b ω -35, γ-45 c
Duilio null c 7+8 b ω -35, γ-45 c
Fiore null c 7+8 b ω -35, γ-45 c
Grecale null c 6+8 d ω-35, γ-45 c
Iride null c 7+8 b ω-35, γ-45 c
Isildur n.d. n.d. n.d.
Latino null c 7+8 b ω-33-35-38, γ-42 a
Latinur null c 7+8 b ω-35, γ-45 c
Liberdur n.d. 20 ω-35, γ-45
Messapia null c 6+8 d ω-35, γ-45 c
Neolatino 2* b 7+8 b ω-35, γ-45 c
Normanno null c 7+8 b ω-35, γ-45 c
Preco null c 6+8 d ω-35, γ-45 c
Primadur null c 6+8 d ω-35, γ-45 c
Saragolla null c 6+8 d ω-35, γ-45 c
Svevo null c 7+8 b ω-35, γ-45 c
Tiziana null c 7+8 b ω-35, γ-45 c



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The portion of total protein represented by gluten showed a high variability among the tested whole meals. Due to 
its strong correlation with GPC (R = 0.78, p <0.001, and R = 0.86, p <0.001, for WG and DG, respectively) (Table 6), 
gluten content paralleled the trend of proteins, with higher values in ssp. dicoccoides and in CItr 14629 than in the 
cultivars. High DG and WG contents were observed also in Chinese Spring and Chinese Spring - 5A dic. The lowest 
DG to GPC ratio was observed in cv. Saragolla, while the highest values were reached in Chinese Spring, Chinese 
Spring - 5A dic. and in MG5323 line.

DG varied from 8.0% (cv. Saragolla) to 15.7% (CItr 14629), with a GHI ranging from 66.8 (cv. Aureo) to 72.8 (Chi-
nese Spring - 5A dic.). A positive correlation was observed between DG and GHI (R = 0.64, p < 0.001).

GI is widely used for evaluating gluten strength (GI < 30 = weak; 30–80 = normal; > 80 = strong) (Cubadda et al. 
1992). It is known to correlate with SDS-SV, alveograph work (Cubadda et al. 1992), loaf volume (Kieffer et al. 
1998), and mixograph peak time (Gaines et al. 2006). This parameter reproduces the manual gluten quality eval-
uation, but being instrumentally determined avoids any influence of the operator on the results. In addition, it 
has been reported to have high heritability (Ames et al. 1999) and, due to the relatively small-scale and rapidity 
of the method used for its determination, is a reliable predictor of gluten strength for screening early breeding 
generations (Sissons et al. 2005).

The GI of the examined wheat samples was negatively correlated with WG and DG content (R = -0.81, p < 0.001 
and R = -0.67, p < 0.001, respectively), confirming the findings of Cubadda et al. (1992) and Peña (2000), so that 
higher WG and DG levels corresponded to lower gluten strength. Furthermore, a negative correlation was ob-
served between GI and GHI (R = -0.97; p <0.001), i.e. stronger the gluten, lower the hydration.

Very low GI values, indicating a very weak and sticky gluten, insufficient for both bread-making and pasta produc-
tion, were observed in the dicoccum accession MG5323, in the durum line CItr 14629, and in cv. Latino. Among 
the T. aestivum samples, Chinese Spring and its disomic substitution line Chinese Spring 5A-dic. also showed weak 
gluten, in agreement with their protein allelic composition. The highest values of GI (≥90) were observed in Fiore, 
Neolatino, Normanno, and Saragolla durum cultivars, indicating the presence of strong gluten network with op-
timal pasta-making properties (Sissons et al. 2005). The very low and very high GI values observed in Latino and 
Neolatino, respectively, agreed with the differences observed in their protein allelic composition. An intermediate 
behavior was assessed in cv. AC Avonlea, in the accession MG4330 and in the line 02-5B-318, while all the other 
cultivars and accessions showed GI values higher than 60.

Besides the production of pasta, durum wheat bread-making is an established tradition in Southern Italy and in 
Mediterranean countries (Qaroni 1996, Pasqualone 2012). Apart the above cited few cases, characterized by ex-
tremely low GI values, the majority of the whole meals tested appeared to be able to ensure good bread-making 
performances. In fact, according to Curic et al. (2001), GI values between 75 and 90 provide optimal bread-mak-
ing quality, while Har Gil et al. (2011) indicate that for bread-making is sufficient a value above 55. The observed 
values were similar to those ascertained in a previous survey on the quality of durum wheat semolina used for 
bread-making in Southern Italy (Pasqualone et al. 2004).

The SDS-SV ranged from 31 mL to 82 mL and was significantly correlated with GI (R = 0.65, p < 0.001). The majority 
of the cultivars of both ssp. aestivum and ssp. durum showed SDS-SV values exceeding 70, with the highest value 
in the breeding line 02-5B-318 for ssp. aestivum and in cv. Primadur for ssp. durum. Lower values were observed in 
ssp. dicoccoides and ssp. dicoccum samples, with the exception of MG29896. The SDS-SV test is based on the prop-
erty of the gluten-forming endosperm storage proteins to swell and flocculate in a weak acid solution (lactic acid). 

**, *** indicate significant differences at p < 0.01 and p < 0.001, respectively. The ANOVA was carried out on 29 genotypes. The accession 
MG4343 has not been included in the statistical analyses due to incomplete data.

Table 4. Results of the analysis of variance carried out on grain protein content (GPC), wet gluten (WG), dry gluten (DG), gluten 
hydration index (GHI), dry gluten/protein ratio (DG/GPC), gluten index (GI), sodium dodecyl sulphate sedimentation volume (SDS-
SV), thousand-kernel weight (KW), and color indices (YI = yellow index; RI = red index; BI = brown index) of whole meal of parental 
lines of wheat mapping populations grown in Valenzano (Bari, Italy) in 2013

Source of 
variation

d.f. GPC WG DG GHI DG/GPC GI SDS-SV KW YI RI BI

Replication 2 18.64*** 442.59*** 44.14*** 3.35** 474.11*** 103.25 515.33*** 94.30** 1.79** 0.54*** 2.91***

Genotype 28 4.40*** 267.82*** 15.45*** 11.07*** 294.65*** 2101.22*** 573.54*** 225.19*** 13.25*** 1.20*** 8.78***

Error 55 0.55 10.88 0.84 0.55 22.30 36.72 31.94 7.93 0.33 0.05 0.29



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The rate of sedimentation is influenced by gluten strength: meals containing better quality gluten show slower 
rates and higher SDS-SV values (Axford et al. 1979). This index is correlated with bread-making quality (Axford et 
al. 1979), as well as with spaghetti cooking quality (Dick and Quick 1983), hence it is widely used to evaluate flour 
quality in both durum and soft wheat.

KW values ranging from 25.3 g to 61.9 g were observed, higher in durum cultivars than in the other wheats consid-
ered. Among the ssp. dicoccoides an interesting high value of KW was assessed, accounting for 48.5 g, in MG29896. 
Values above 50 g were observed in almost all the durum cultivars, with the highest value in cv. Duilio.

n.d. = not determined for insufficient seed

Table 5. Grain protein content (GPC), wet gluten (WG), dry gluten (DG), gluten hydration index (GHI), dry gluten/protein ratio 
(DG/GPC), gluten index (GI), sodium dodecyl sulphate sedimentation volume (SDS-SV), thousand-kernel weight (KW), and color 
indices (YI = yellow index; RI = red index; BI = brown index) of whole meal of parental lines of wheat mapping populations grown 
in Valenzano (Bari, Italy) in 2013 (mean of three field replications)

Cultivar or accession
GPC 

(% d.m.)
WG 

(% d.m.)
DG 

(% d.m.)
GHI DG/GPC GI

SDS-
SV

(mL)

KW
(g)

YI RI BI

Triticum aestivum L. ssp. aestivum

Chinese Spring 16.4 57.0 15.6 72.6 95.0 25 61 31.1 10.5 1.1 14.2

Chinese Spring – 5A dic. 16.1 55.1 15.0 72.8 93.5 28 75 29.7 10.0 0.9 13.6

02-5B-318 16.9 50.1 14.4 71.3 85.2 47 79 39.6 10.6 1.5 15.6

Triticum turgidum ssp. dicoccoides (Körn. ex Asch. & Graebner) Thell.

MG29896 18.8 50.2 16.1 67.9 85.5 75 68 48.5 14.9 1.0 16.2

MG4343 19.5 n.d. n.d. n.d. n.d. n.d. 46 25.3 12.3 1.8 19.3

MG4330 17.7 54.0 15.6 71.0 88.3 46 59 42.0 12.9 1.7 17.9

Triticum turgidum ssp. dicoccum (Schrank ex Schϋbler) Thell.

MG5323 17.8 55.0 15.5 71.8 87.3 19 36 37.3 13.6 2.0 18.7

Triticum turgidum ssp. durum (Desf.) Husnot

CItr 14629 17.5 55.7 15.7 71.9 89.8 23 31 46.8 11.5 2.5 23.0

UC1113 16.3 39.5 12.9 67.3 78.9 87 64 50.2 14.1 0.6 15.2

Anco Marzio 15.1 33.3 10.7 67.8 71.2 87 61 50.4 14.2 0.7 15.4

Aureo 16.8 37.1 12.3 66.8 73.6 87 77 55.9 15.2 0.4 15.8

AC Avonlea 16.2 48.4 14.1 70.9 87.2 38 54 48.7 16.7 0.0 15.1

Ciccio 15.6 36.2 11.5 68.3 73.4 78 70 60.2 14.4 0.4 15.9

Duilio 15.8 34.8 11.1 68.0 70.0 80 58 61.9 13.7 0.7 15.6

Fiore 14.0 25.1 8.2 67.4 58.4 92 60 46.5 13.4 0.4 14.6

Grecale 15.2 38.9 12.2 68.6 80.6 66 62 44.5 16.1 0.1 15.7

Iride 14.2 30.0 9.5 68.3 66.7 88 59 53.8 14.5 0.5 15.4

Isildur 14.8 36.3 11.7 67.7 78.8 84 74 50.4 17.8 0.0 16.0

Latino 14.2 40.0 11.2 71.9 78.1 17 32 60.9 12.7 0.4 14.7

Latinur 15.4 40.9 12.7 69.1 82.1 69 59 54.3 15.5 0.3 16.1

Liberdur 14.3 34.7 11.3 67.5 78.7 85 73 52.3 17.2 0.2 15.9

Messapia 16.1 40.9 12.7 68.8 79.1 68 75 59.2 12.8 0.8 15.5

Neolatino 15.7 33.6 10.8 67.7 69.2 90 73 58.8 13.2 0.4 15.0

Normanno 14.4 28.0 9.2 67.4 63.1 91 71 51.2 16.6 0.3 15.9

Preco 17.5 50.1 15.4 69.2 88.0 59 65 54.3 16.8 0.1 16.0

Primadur 15.8 34.3 11.2 67.2 70.5 86 82 35.0 17.6 0.1 15.6

Saragolla 14.6 24.8 8.0 67.7 54.6 92 65 51.0 15.4 0.5 15.6

Svevo 14.6 35.3 11.1 68.6 75.5 65 69 55.6 13.8 0.6 15.6

Tiziana 15.0 37.3 11.8 68.5 78.0 76 66 52.7 14.5 0.4 15.1



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Table 6. Pearson correlation coefficients (R) among protein content (GPC), wet gluten (WG), dry gluten (DG), gluten hydration index 
(GHI), dry gluten/protein ratio (DG/GPC), gluten index (GI), sodium dodecyl sulphate sedimentation volume (SDS-SV), thousand-
kernel weight (KW), and color indices (YI = yellow index; RI = red index; BI = brown index) of parental lines of wheat mapping 
populations grown in Valenzano (Bari, Italy) in 2013

GPC WG DG GHI DG/GPC GI SDS-SV KW YI RI

WG 0.78***

DG 0.86*** 0.97***

GHI 0.34 0.80*** 0.64***

G/GPC 0.65*** 0.95*** 0.94*** 0.72***

GI -0.39* -0.81*** -0.67*** -0.97*** -0.75***

SDS-SV -0.09 -0.33 -0.21 -0.57** -0.23 0.65***

KW -0.33 -0.50** -0.44* -0.42* -0.43* 0.34 -0.12

YI -0.24 -0.49** -0.35 -0.68*** -0.37 0.58** 0.29 0.26

RI 0.56** 0.64*** 0.56** 0.65*** 0.45* -0.63*** -0.52** -0.31 -0.72***

BI 0.44* 0.38* 0.37* 0.28 0.26 -0.36 -0.56** -0.01 -0.09 0.69***

Wheat kernel weight and size are important yield and quality traits, always considered primary objectives in con-
ventional and modern wheat breeding programs. KW can be easily measured and is usually used to estimate the 
agronomic performance of a cultivar (Baril 1992). Moreover, it is positively correlated with high flour yield and 
is a cheap predictor of milling quality in bread wheat (Berman et al. 1996) and of semolina yield in durum wheat 
(Novaro et al. 2001).

Regarding color indices, as expected the YI (range 10.0 – 17.8) was lower in T. aestivum samples than in tetraploid 
wheats due to the presence, in the latter, of carotenoid pigments that are strongly correlated with yellow hue  
(Digesù et al. 2009). Some durum cultivars, namely Isildur, Primadur, Liberdur, Preco, and AC Avonlea, showed 
particularly high values of YI, due to the effect of breeding for this valuable characteristic. Both ssp. dicoccoides 
and ssp. dicoccum samples showed values in-between T. aestivum and durum cultivars.

The values of RI were generally quite low (range 0.0 – 2.5), with the highest values in CItr14629, that is a purple 
wheat line characterised by high anthocyanin levels (Pasqualone et al. 2015). Although not imputable to antho-
cyanins, high values of RI were observed in MG5323, MG4343, and MG4330, probably originated from the oxida-
tion of moderate levels of phenolic substances.

The highest BI, reaching the value of 23.0, was observed in CItr14629. The origin of inherent brown color of whole 
meal is attributable to polyphenol oxidase activity (Taranto et al. 2012, Mangini et al. 2014), but in case of CItr14629 
the dark red color of anthocyanins probably overlapped and enhanced the brownish tone of quinone-derivatives 
arising from the enzymatic oxidation of phenolic compounds. Other, non-pigmented, samples also showed high 
BI values, in this case totally imputable to the oxidation of phenolics: they belonged to the ssp. dicoccoides and 
ssp. dicoccum, while the durum cultivars generally showed lower values. A significant correlation between BI and 
GPC was observed (R = 0.44, p < 0.05), already reported in previous papers (Taranto et al. 2012).

Selection of the crosses
The parental lines of the crosses have to be sufficiently differentiated for the trait of interest to ensure segrega-
tion and subsequent mapping of each trait. The differences observed were markedly above LSD

0.05
 in many of the 

examined crosses (Table 7). As expected, the highest differences in GPC were observed in the crosses involving 
cultivars and wild accessions or landraces, namely Latino x MG29896, Latino x MG5323, Svevo x MG4330, and 
Messapia x MG4343, which progeny can be effectively used for mapping this character. In particular, the recombi-
nant inbred population originated by the cross Messapia x MG4343 has already been the object of a study aimed 
to detect GPC-related QTLs (Blanco et al. 2002).

Similarly, the differences in DG were high in the crosses involving cultivars and wild accessions or landraces, as well 
as in some crosses involving cultivars, such as Neolatino x Preco (Preco, in particular, was a high-gluten cultivar) 
and Latinur x Saragolla. The differences in WG partly resembled those in dry gluten: apart Latino x MG29896 they 
were marked in the crosses involving cultivars and wild accessions or landraces and, again, in the cultivar crosses 
Neolatino x Preco and Latinur x Saragolla, but with the addition of the crosses Saragolla x 02-5B-318 (that showed 
the highest difference), and CItr 14629 x Grecale.

*, **, *** indicate significance at p < 0.05, p < 0.01 and p < 0.001, respectively.



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The highest DG/GPC differences were observed, in decreasing order, in Latinur x Saragolla, Isildur x Saragolla, and 
Liberdur x Saragolla (being Saragolla a cultivar with low DG and, therefore, low DG/GPC), as well as in Grecale x 
Fiore, Neolatino x Preco, and Duilio x AC Avonlea. Moreover, six of examined crosses showed the most differen-
tiated values of GHI: Latino x Primadur, Svevo x MG4330, Latino x MG29896, Saragolla x 02-5B-318, CItr 14629 x 
Grecale, and Duilio x AC Avonlea.

Table 7. Differences in grain protein content (GPC), wet gluten (WG), dry gluten (DG), gluten hydration index (GHI), dry gluten/protein 
ratio (DG/GPC), gluten index (GI), sodium dodecyl sulphate sedimentation volume (SDS-SV), thousand-kernel weight (KW), and 
color indices (YI = yellow index; RI = red index; BI = brown index) detected between parental lines of 28 wheat mapping populations

Cross
ΔGPC
(% d.m.)

ΔWG
(% d.m.)

ΔDG
(% d.m.)

ΔGHI
ΔDG/
GPC

ΔGI
ΔSDS-SV
(mL)

ΔKW
(g)

ΔYI ΔRI ΔBI

Aureo x Normanno 2.4 9.1 3.1 0.6 10.5 4 6 4.7 1.4 0.1 0.1

Aureo x Iride 2.6 7.1 2.8 1.5 6.9 1 18 2.1 0.7 0.1 0.4

Neolatino x Preco 1.8 16.5 4.6 1.5 18.8 31 8 4.5 3.6 0.3 1.0

Latinur x Saragolla 0.8 16.1 4.7 1.4 27.5 23 6 3.3 0.1 0.2 0.5

Isildur x Saragolla 0.2 11.5 3.2 0.0 24.2 8 9 0.6 2.4 0.5 0.4

Liberdur x Saragolla 0.3 9.9 3.3 0.2 24.1 7 8 1.3 1.8 0.3 0.3

Svevo x Primadur 1.2 1.0 0.1 1.4 5.0 21 13 20.6 3.8 0.5 0.0

UC1113 x Iride 2.1 9.5 3.4 1.0 12.2 1 5 3.6 0.4 0.1 0.2

Isildur x Anco Marzio 0.3 3.0 1.0 0.1 7.6 3 13 0.0 3.6 0.7 0.6

Liberdur x Anco Marzio 0.8 1.4 0.6 0.3 7.2 2 12 1.9 3.0 0.5 0.5

Normanno x Tiziana 0.6 9.3 2.6 1.1 14.9 15 5 1.5 2.1 0.1 0.8

Svevo x Messapia 1.5 5.6 1.6 0.2 3.6 3 6 3.6 1.0 0.2 0.1
Chinese Spring x Chinese 
Spring – 5A dic.

0.3 1.9 0.6 0.2 1.5 3 14 1.4 0.5 0.2 0.6

Iride x Fiore 0.2 4.9 1.3 0.9 8.3 4 1 7.3 1.1 0.1 0.8

Svevo x MG4330 3.1 18.7 4.5 4.4 12.8 19 10 13.6 0.9 1.1 2.3

Grecale x Tiziana 0.2 1.6 0.4 0.1 2.6 10 4 8.2 1.6 0.3 0.6

Iride x Ciccio 1.4 6.2 2.0 0.0 6.7 10 11 6.4 0.1 0.1 0.5

Normanno x Fiore 0.4 2.9 1.0 0.0 4.7 1 11 4.7 3.2 0.1 1.3

Duilio x AC Avonlea 0.4 13.6 3.0 2.9 17.2 42 4 13.2 3.0 0.7 0.5

CItr 14629 x Grecale 2.3 16.8 3.5 3.3 9.2 43 31 2.3 4.6 2.4 7.3

Grecale x Fiore 1.2 13.8 4.0 1.2 22.2 26 2 2.0 2.7 0.3 1.1

Latino x MG5323 3.6 15.0 4.3 0.1 9.2 2 4 23.6 0.9 1.6 4.0

Latino x Primadur 1.6 5.7 0.0 4.7 7.6 69 50 25.9 4.9 0.3 0.9

Svevo x Ciccio 1.0 0.9 0.4 0.3 2.1 13 1 4.6 0.6 0.2 0.3

Saragolla x 02-5B-318 2.3 25.3 6.4 3.6 9.7 45 14 11.4 4.8 1.0 0.0

Iride x Tiziana 0.8 7.3 2.3 0.2 11.3 12 7 1.1 0.0 0.1 0.3

Messapia x MG4343 3.4 n.d. n.d. n.d. n.d. n.d. 29 33.9 0.5 1.0 3.8

Latino x MG29896 4.6 10.2 4.9 4.0 7.4 58 36 12.4 2.2 0.6 1.5

LSD
0.05

1.2 5.4 1.5 1.2 7.7 10 9 4.6 0.9 0.4 0.9

Regarding GI, a relevant number of crosses showed marked differences. They included again Neolatino x Preco and 
Latinur x Saragolla - that could therefore be used for mapping both quantitative and qualitative features of gluten 
- but also many other crosses such as, in decreasing order, Latino x Primadur, Latino x MG29896, Saragolla x 02-
5B-318, CItr 14629 x Grecale, Dulio x AC Avonlea, and Grecale x Fiore, whose corresponding recombinant inbred
populations can be considered potentially useful for mapping this essential qualitative characteristic.

The differences in SDS-SV values were in accordance with those observed in GI, being these two indices correlat-
ed. In particular, the most marked differences were observed, in decreasing order, in the crosses Latino x Primad-
ur, Latino x MG29896, CItr 14629 x Grecale, and Messapia x MG4343. The recombinant inbred population orig-
inated by the latter cross has already been effectively used to detect QTLs related to SDS-SV in a previous study 
(Blanco et al. 1998).



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The most marked differences in KW were found in the crosses involving cultivars and wild accessions together, as 
well as in those involving Primadur, due to the generally low KW of this cultivar. In particular, the highest values 
were observed in Messapia x MG4343, Latino x Primadur, Latino x MG5323, and Svevo x Primadur.

Regarding YI, the greatest differences between parental lines were observed for the crosses Latino x Primadur, 
Saragolla x 02-5B-318, and CItr 14629 x Grecale, that appeared all suitable for mapping yellow color. As far as RI is 
concerned, the cross CItr 14629 x Grecale, involving a purple wheat line and a conventional non-pigmented wheat 
cultivar, was by far the most suitable for mapping this parameter. A weaker difference in red tone was present 
in some crosses, such as Latino x MG5323 and Svevo x MG4330. Not imputable to anthocyanins, this difference 
probably originated from the oxidation of phenolic substances occurring at different extents.

Only slight differences of BI were observed between parental lines when durum cultivars were involved, whereas 
more marked differences were observed in crosses involving ssp. dicoccoides or ssp. dicoccum. The highest differ-
ence was found in the cross CItr14629 x Grecale, but probably the interference of anthocyanins could have over-
estimated it. Hence, although being constituted by less differentiated parental lines, the crosses Latino x MG5323, 
Messapia x MG4343, and Svevo x MG4330 appeared more suitable for mapping BI.

Conclusions

Overall, many of the examined crosses appeared to be suitable for studies focused on mapping each of the main 
quality traits of wheat (GPC, quantity and quality of gluten, KW, color indices). The derived mapping populations 
selected in this study are therefore all useful to investigate on these traits, because some genes are cultivar spe-
cific and need to be studied in different genetic background.

The results pointed out, also, that some populations were appropriate for studying several traits at the same time. 
For example, for mapping studies aimed to take into account contemporarily the quantitative and qualitative fea-
tures of gluten, the populations derived from Latino x MG29896 and Saragolla x 02-5B-318 could be particularly 
suitable. In addition, the latter cross was the most suitable also to deepen the knowledge of YI regulation.

Acknowledgement
The authors acknowledge the financial support of MIUR in the framework of the Project PON/01_01145/8 “IS-
COCEM”.

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	Quality characteristics of parental lines of wheat mappingpopulations
	Introduction
	Material and methods
	Samples
	Basic chemical and physical determinations
	Determination of quali-quantitative features of gluten
	Sedimentation volume in sodium dodecyl sulphate (SDS-SV)
	Electrophoretic analyses of seed storage proteins

	Statistical analyses

	Results and discussion
	Variability of quality characteristics and correlations among them
	Selection of the crosses


	Conclusions
	Acknowledgement
	References