Selection of morpho-physiological traits associated with terminal drought stress tolerance in durum wheat (Triticum durum Desf.) genotypes
 Volume 11, Article 2 | [Volume 11, Article 2] | 155 kB |
S. AYED 1
A. OTHMANI 1
M. MRABIT 1
N. RASSAA 2
A. MBARKI 3
M. REZGUI 4
M. BEN YOUNES 1
1 Regional Research Development Office of Agriculture in Semi Arid North West of Kef,Boulifa 7100-Kef, Tunisia
2 Higher Agriculture School of Kef, Boulifa 7100-Kef, Tunisia
3 Office of public lands, Alein Savary, Tunis, Tunisia
4 National Agricultural Research Institute of Tunisia, Rue Hédi Karray 2049 Ariana, Tunisia, Experimental station-Kef
Abstract - In order to study the response for drought induced at critical stages of grain filling of 8 durum wheat genotypes, five Tunisian landraces (Biskri, Mahmoudi, Agili, Chili and Jeneh khotifa) and three improved genotypes (Karim, Nasr and Rezzak), that differ in adoption to drought stress, were studied under three water regime: rainfed conditions (control), 50% Field Capacity (Treatment 1) and 100% Field Capacity (Treatment 2). Chlorophyll index, leaf area, plant height, own length, peduncle length, tiller number/plant, spike number/plant, grain number/spike and the relationship between some of these morphological and physiological traits and yield components were studied for the eight durum wheat genotypes. Analysis of variance has indicated that there were significant (P<0.01) differences among genotypes in which indicate that there are great variations among genotypes. The water regime stress affects significantly (P<0.01) various morpho-physiological and agronomical traits. Our results showed significant reduction in all morpho-physiological and agronomical traits in all varieties under rainfed conditions in comparison with 50% FC and 100% FC regime water. The best results were obtained under 100% Field Capacity. Chlorophyll index, leaf area, peduncle length and Own length were significantly correlated to the number of spike /plant (r = 0.58**, r = 0.52**, r = 0.74**, r = 0.52**) and the number of grains/spike (r = 0.62**, r = 0.60**, r = 0.78**, r = 0.55**). Therefore, the use of morpho-physiological traits as an indirect selection would be important in increase yield-based selection procedures. The variety Biskri showed the important spike number/plant and grain number/spike in comparison to all varieties studied. This genotype can be used in selection breeding program.
Keywords: Correlation, yield components, drought tolerance, landraces
Abreviations: FC: Field Capacity
1. Introduction
Drought is one of the most important factors which limit the production of crops, including durum wheat, in the world and causes important agricultural losses (Khayatnezhad et al., 2010; Kiliç and Yagbasanlar, 2010). This stress affect yield and yield component of wheat particularly in arid and semi-arid regions. Visible syndromes of plant exposure to drought in the vegetative phase are leaf wilting, a decrease in plant height, number and area of leaves and delay in accuracy of buds and flowers. In fact, according to Lonbani and Arzani (2011), leaf extension can be limited under water stress conditions in order to get a balance between the water status of plant tissues and the water absorbed by plant roots (Passioura, 1996). In addition, Blum (2005) suggested that a small leaf area is beneficial under drought stress in order to avoid hydratation. Drought stress reduced the number of days to heading, plant height, number of spike per m², peduncle length, spike length, number of grains per spike, 1000 grain weight of genotypes (Kiliç and Yagbasanlar, 2010). Peduncle length has been also suggested as useful indicator of yield capacity in drought conditions. Kaya et al. (2002) have been found an important positive correlation between peduncle length and grain yield. However, in other studies, such relationship has been found inverser and no relationship depending on the environment (Villegas et al., 2006). In many part of the world, durum wheat production is replaced by modern cultivars and landraces are only cultivated by small farmers in very limited areas (Akar et al., 2009; Ahmadizadeh et al., 2011). Nowadays, several breeding programs aim to develop new cultivars as well as release old durum landraces (Ahmadizadeh et al., 2011). Landraces of durum wheat generally tolerant to biotic and abiotic stress have been grown under low-input or sustainable farming conditions where they produce reasonable yield.
The effect of deficit water on the yield and yield components of durum wheat at different growth stages have been noted by several authors (Simane et al., 1993; Solomon et al., 2003). However, no study had been conducted on the physiological and morphological response of diverse durum wheat tunisian genotypes to water deficit conditions. Therefore, the present study aims to determine water deficit effects of eight durum wheat genotypes and to determine the relationship between some morphological and physiological traits and yield under water deficit conditions.
2. Materiel and methods
2.1. Plant Materials and Growth Conditions
Experiments were conducted at the experimental field of Higher Agriculture School of Kef during 2013/14 growing season. Five landraces (Biskri, Mahmoudi, Agili, Chili and Jeneh khotifa) and three improved genotypes (Karim, Nasr and Rezzak) were used in this study. Seeds of each genotype were sown in 5 lines 10 m long with an interline spacing of 20 cm. The experiment was laid out in randomized complete block design (RCBD) with three replications. The temperature and the rainfall from sowing to harvest are presented in Table 1.
|
Table 1: Mean temperature (°C) and rainfall (mm) of Kef site from sowing to harvest (2012 to 2013) |
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|
Months |
October |
November |
December |
January |
February |
March |
April |
|
Rainfall (mm) |
62.4 |
9.8 |
16 |
26.4 |
42.8 |
39.8 |
26.4 |
|
Temperature (°C) |
14.4 |
14.8 |
9.4 |
8.4 |
7.4 |
12.8 |
15.9 |
Three levels of stress treatments including:
-
Full irrigation (100 percent water based on plant needs durum wheat cultivars until grain filling stage)
-
Limited irrigation (50% Filed Capacity).
-
Control: rainfed conditions
These water stress conditions were stimulated in grain filling stage.
2.2. Measured traits
Five plants in each replication were used to determine: Chlorophyll index (Chlorophyll meter SPAD 502, Konnica Minolta,Sakai, Osaka, Japon), leaf area (mm2) (Electonicplanimetre AM300, Soil Mesures, France), plant height (cm), own length (cm), peduncle length (cm), tiller number/plant, spike number/plant, grain number/spike.
2.3. Statistical data analysis
Data obtained were subjected to analysis of variance (ANOVA). Means comparisons were carried out to estimate the differences between water deficit treatments and genotypes using Duncan’s Multiple Range. Linear correlation analyses were used to determine the association between grain yields, physiological and morphological traits. Data were analyzed using SPSS ver. 16.0 (IBM SPSS Statistics. SPSS for Windows, Version 16.0. Chicago, SPSS Inc., 2007).
3. Results and discussion
Results of variance analysis showed that the effect of genotype, treatment and interaction between genotype and treatment were significant on 0.01 percentage levels for all traits studied (Table 2).
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Table 2: Variance analysis of the eight traits measured for the eight durum wheat genotypes for three irrigation regimes |
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|
Sources variation |
df |
Chlorophyll index |
Leaf area (mm²) |
Plant height (cm) |
Own Length |
Peduncle length |
Tiller number/plant |
Spike number/plant |
Grain number/spike |
|
Genotype |
7 |
58.40** |
56.5** |
354.8** |
28.0** |
31.2** |
31.3** |
25.8** |
243.9** |
|
Treatment |
2 |
613.7** |
592.3** |
676 .2** |
284.5** |
1.3E3** |
150.8** |
292.8** |
2.7E3** |
|
Genotype*treatment |
14 |
26.1** |
27.0** |
30.9** |
5.3** |
4.8** |
7.1** |
8.0** |
65.8** |
|
Table 3: Mean of all traits measured of the 8 durum wheat varieties for the 3 water regimes used |
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|
Sources variation |
Chlorophyll index |
Leaf area (mm²) |
Plant height (cm) |
Own Length |
Peduncle length |
Tiller number/plant |
Spike number/plant |
Grain number/spike |
|||||||
|
Genotype
|
|||||||||||||||
|
1 Biskri
|
51.58 abc |
1821.22 a |
85.44 a |
9.11 a |
7.65 a |
6.39 c |
5.78 c |
40.22 d |
|||||||
|
2 Mahmoudi
|
51.23 abc |
2153.17 ab |
110.44 b |
11.19 d |
8.86 ab |
5.44 b |
3.61 a |
30.94a |
|||||||
|
3 Agili
|
50.33 ab |
2254.56 b |
101.28 a |
9.36 b |
8.97 ab |
5.44 b |
4.56 ab |
40.83 d |
|||||||
|
4 Chili
|
52.92 cd |
2548.83 bc |
123.00 c |
10.31 bcd |
9.68 ab |
5.39 b |
4.22 ab |
34.44 ab |
|||||||
|
5 Jeneh Khotifa
|
51.15 abc |
2131.11 ab |
86.44 a |
10.08 abc |
7.46 a |
5.56 b |
4.33 ab |
34.72 abc |
|||||||
|
6 Karim
|
49.07 a |
2195.17 ab |
129.61 c |
9.86 abc |
8.89 ab |
6.44 c |
5.33 bc |
38.44 bcd |
|||||||
|
7 Nasr
|
54.05 d |
2283.35 b |
123.65 c |
10.90 cd |
10.55 b |
6.06 b |
5.18 bc |
39.18 cd |
|||||||
|
8 Rezzak |
52.82 cd |
2753.22 c |
130.11 c |
11.22 d |
8.30 ab |
4.39 a |
3.67 a |
35.50 abc |
|||||||
|
Treatment
|
|||||||||||||||
|
Control Treatment 1 Treatment 2 |
48.50 a 51.62 b 54.70 c |
1698.51 a 2271.35 b 2820.69 c |
94.72 a 112.85 b 125.56 c
|
8.52 a 10.67 b 11.53 c
|
4.47 a 9.77 b 12.02 c |
4.83 a 5.46 b 6.60 c |
2.96 a 4.60 b 6.15 c |
29.13 a 38.10 b 42.92 c |
|||||||
The water regime stress affects significantly (P<0.01) various morpho-physiological and agronomical traits in all genotypes. Our results showed significant reduction in all morpho-physiological and agronomical traits in all varieties under rainfed conditions in comparison with 50% FC and 100% FC regime water (Figure1). Same results were obtained by Ehdaie et al. (1991) in durum wheat. Since genotypic differences for these traits have been reported for various crop species including durum wheat, these traits have been used to identify drought tolerant genotypes in various crops. According our results, drought stress reduced all yield components (tiller number/plant, spike number/plant, grain number/spike) particularly the number of fertile spikes per plant and the number of grains per spike in almost studied genotypes. Same results were observed by Giunta et al. (1993) and Simane et al. (1993). Mirbahar et al. (2009) reported also that water stress caused a significant reduction in number of grains per spike in wheat in 25 varieties of bread wheat. In fact, according to El Hafid et al. (1998) drought leads to reducing inoculation of flower and this affects number of produced grain. Calderini et al. (1999) believed that increasing of grain yield in recent years is primarily indebted of increasing of number of grain per spike and this component of yield is more important than grain weight, although both factors cause limitation of yield. Significant reduction in 1000-grain weight of wheat has also been reported by Ahmed and Arian (1999) while Akram (2011) reported differential response of varieties toward grain weight. The water stress reduced the leaf area for all genotypes studied (Figure 1 B). Same finding were obtained by Boutraa et al. (2010). This author showed that deficit decreased leaf area in four wheat cultivars. In fact, the highest leaf area was found in the control plants of the 80% water regime, followed by the plants under 50% water regime, while leaf area of plants of the 30 % had the least leaf area. The comparison of all genotype for all traits showed that the genotype Biskri had the best spike number/plant and grain number/spike for all water regimes (Table 3).
Results showed that physiological traits (chlorophyll index and leaf area) were significantly correlated to the number of spike /plant (r = 0.58**, r = 0.52**) and the number of grains/spike (r = 0.62**, r = 0.60**). Peduncle length significantly correlated to traits related to the yield such as number of spike /plant (r = 0.74**) and the number of grains/spike (r = 0.78**) and tiller number (r = 0.61**) (Table 4). According to Bogale et al. (2011), peduncle length has been also suggested as useful indicator of yield capacity in dry environments. Kaya et al. (2002) have been found strong positive correlation between peduncle length and grain yield. Own length positively correlated to spike number /plant (0.52**) and grain number /spike (0.55**). According to the previous studies, there is a link between various physiological responses of crop plants to drought and their tolerance mechanisms (Keyvan, 2010; Datta et al., 2011). Association between all these character and yield components was observed particularly at anthesis stage. It is clear that all these parameters could explain some of the mechanisms which indicate tolerance to drought and help in understanding the physiological responses that enable plants to adapt to water deficit and maintain growth and productivity during stress period and indicate important of these traits in breeding programs for screening and selection of tolerant varieties.
|
Table 4: Pearson correlation coefficient among studied traits for the 8 durum wheat genotypes under the three water regimes |
||||||||
|
|
Chlorophyll index |
Leaf area (mm²) |
Plant height (cm) |
Own length (cm) |
Peduncle length (cm) |
Tiller Number / plant |
Spike number /plant |
Grain number / spike |
|
Chlorophyll index |
1 |
0.66** |
0 .44* |
0.74** |
0 .75** |
0.30 |
0.58** |
0.62** |
|
Leaf area (mm²) |
|
1 |
0.73** |
0.77** |
0.75** |
0.36 |
0.52** |
0.60** |
|
Plant height (cm) |
|
1 |
0.71** |
0.67** |
0.31 |
0.38 |
0.41* |
|
|
Own length (cm) |
|
1 |
0.81** |
0.32 |
0.52** |
0.55** |
||
|
Peduncle length(cm) |
|
1 |
0.61** |
0.74** |
0.78** |
|||
|
Tiller Number / plant |
|
1 |
0.79** |
0.62** |
||||
|
Spike number /plant |
|
1 |
0.79** |
|||||
|
Grain number /spike |
|
1 |
||||||
* : significant at the 0.05 level ; ** : significant at the 0.01 level
|
A
B
C
D
E
F
G
H
|
|
Figure 1: Chlorophyll index (A), leaf area (B), plant height (C), own length (D), pedoncule length (E), tiller number/plant (F), spike number/plant (G), grain number/spike (H) for the eight durum wheat genotypes in three water regime: rainfed conditions, 50% FC and 100% FC |
5. Conclusion
All of these traits have directly or indirectly transfer their effects components of yield and these traits could be used as an indirect yield selection. Selection efficiency could be improved if particular physiological and/or morphological attributes related to yield under a stress environment could be identified and employed as selection criteria for complementing traditional plant breeding.
6. References
Ahmadizadeh M., Valizadeh M., Shahbazi H., Zaefizadeh M. and Habibpor M., (2011). Morphological diversity and interrelationships traits in durum wheat landraces under normal irrigation and drought stress conditions. Adv. Environ. Biol., 5(7): 1934-1940.
Ahmed M., and Arain M.A., (1999). Effect of drought simulation on grain weight, protein and lysine content of bread wheat (Triticum aestivum L.). Pak.J.Bot, 31 (1): 109-114.
Akar, T., Z. Mert, S. Yazar, T. Sanal and M. Avci, (2009). Sustainable use of winter Durum wheat landraces under Mediterranean conditions. Afr. J. Biotechnol., 8(17): 4108-4116.
Akram M., (2011). Growth and yield components of wheat under water stress of different growth stages. Bangladesh J. Agril. Res. 36 (3): 455-468.
Blum A., (2005). Mitigation of drought stress by crop management. http://www.plantstress.com/articles/drought _m7drought_m.htm
Bogale A., Tesfaye K., Geleto T., (2011). Morphological and physiological attributes associated to drought tolerance of Ethiopian durum wheat genotypes under water deficit condition (2011). Journal of Biodiversity and Environmental Sciences Vol. 1, No. 2, p. 22-36
Boutraa T., Akhkha A., Al- Shoaibi A.A. and Alhejeli A.M., (2010). Effect of water stress on growth and water use efficiency (WUE) of some wheat cultivars (Triticum durum) grown in Saudi Arabia. JTUSCI 3:39-48.
Calderini, D.F., Reynolds, M.P. and Slafer, G.A., (1999). Genetic gains in wheat yield and main physiological changes associated with them during the 20th century. In: Wheat: Ecology and Physiology of Yield Determination, Satorre, E.H. and Slafer, G.A. (eds). Food Products Press, New York.
Datta, J.K., Mondal, T., Banerjee, A., and Mondal, N.K., (2011). Assessment of drought tolerance of selected wheat cultivars under laboratory condition. J. Agri.Technol. 7: 383-393
Duncan D.B. (1970). Multiple comparison methods for comparing regression coefficients. Biometrics 27 (1): 139-140.
El Hafid R, Smith DH, Karrou M, Samir K., (1998). Physiological response of spring durum wheat cultivars to early-season drought in a Mediterranean environment. Annals of Botany 81, 363-370.
Ehdaie, B., Hall, A.E., Farquhar, G.D., Nguyen, H.T., and Waines, J.G., (1991). Water use efficiency and carbon isotope discrimination in wheat. Crop sci. 31: 1282-1288.
Giuanta, F., R. Mortzo and M. Deielda (1993). Effect of drought on yield and yield components of durum wheat and Triticale in Mediterranean environment. Field Crops Research 33:399-409.
Kaya Y, Topal R, Gonulal AE, Arisoy RZ., 2002. Factor analyses of yield traits in genotypes of durum wheat (Triticum durum). Indian Journal of Agricultural Science 72,301-303.
Khayatnezhad, M., M. Zaeifizadeh, R. Gholamin and Sh. Jamaati-e-somarin, (2010). Study of genetic diversity and path analysis for yield in durum wheat genotypes under water and dry conditions. World App. Sci. J., 9(6): 655-665.
Kiliç H. and Yagbasanlar T., (2010). The Effect of Drought Stress on Grain Yield, Yield Components and some Quality Traits of Durum Wheat (Triticum turgidum ssp. durum) Cultivars. Not. Bot. Hort. Agrobot. Cluj 38 (1): 164-170.
Keyvan, S., (2010). The effects of drought stress on yield, relative water ontent, proline, soluble carbohydrates and chlorophyll of bread wheat cultivars. J. Anim Plant Sci. 8: 1051- 1060.
Lonbani M. and Arzani A., (2011). Morpho-physiological traits associated with terminal drought stress tolerance in triticale and wheat. Agronomy Research 9 (1–2), 315–329
Mirbahar A. A., Markhand G.S., Mahar A.R., Abro S.A., Kanhar N.A., (2009). Effect of water stress on yield and yield components of wheat (Triticum aestivum L.) varieties. Pak. J. Bot., 41(3): 1303-1310.
Passioura, J. B., (1996). Drought and drought tolerance. In: Belhassen, E. (ed.) Drought Tolerance in Higher Plants: Genetical, Physiological and Molecular Biological Analysis. Kluwer Academic Publishers, Dordrecht. pp: 3–12.
Simane B, Struik PC, Nachit MM, Peacock JM. (1993). Ontogenetic analysis of yield and yields components and yield stability of durum wheat in water-limited environments. Euphytica 71, 211-219.
Solomon KF, Labuschangne MT, Bennie TP., (2003). Response of Ethiopian durum wheat (Triticum turgidum var durum L.) genotypes to drought stress. South Africa Journal of Plant and Soil 20, 54-58.
Villegas D, Garcia del Moral LF, Rharrabti Y, Martos V, Royo C., (2006). Morphological traits above the flag leaf nodes as indicators of drought susceptibility index in durum wheat. Journal of Agronomy and Crop Science dio: 1111/j.1434-037X.2006.002446.x.