Volume 14, number 1
 Views: (Visited 360 times, 1 visits today)    PDF Downloads: 1516

Sadeghi-Shoae M, Taleghani D. F, Habibi D. Some Reactions of Physiological and Morphological characteristics to foliar Application of Paclobutrazol in Autumn sugar beet (Beta Vulgaris). Biosci Biotech Res Asia 2017;14(1).
Manuscript received on : 24 December 2016
Manuscript accepted on : 09 January 2017
Published online on:  --

Plagiarism Check: Yes

How to Cite    |   Publication History    |   PlumX Article Matrix

Some Reactions of Physiological and Morphological characteristics to foliar Application of Paclobutrazol in Autumn sugar beet (Beta Vulgaris)  

Mehdi Sadeghi-Shoae1, Dariush Fatholah Taleghani1 and Davood Habibi2

1Sugar Beet Seed Institute (SBSI), Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran.

2Islamic Azad University, Karaj Branch, Karaj, Iran.

Corresponding Author E-mail: sadeghishoae@sbsi.ir

DOI : http://dx.doi.org/10.13005/bbra/2439

ABSTRACT: Water is the most important limitation factor in Iran agriculture. Replacing autumn beet to spring beet is one solution to save water resources. Bolting control is essential to improve autumn beet in region with moderate winter. This experiment was designed to determine genotypes and different levels of paclobutrazol on bolting of autumn sugar beet in Moghan- Iran. Thus, a split plot test under randomized complete block design with two factor was performed in which the first factor was paclobutrazol with three levels (control, 150 and 300 ppm) and second factor was six genotypes (Eudora, Giada, Jawaher, Levante, Vico and (FC607*474)*Pool-PC.F2-HSF60-P.3). Some traits Contains giberelic acid, percentage of bolting, height of bolted stem, percent of flowering, white sugar yield and root dry matter percentage were analyzed. The overall results showed that was significant differences in genotypes and different levels of paclobutrazol for giberelic acid, percentage of bolting, height of bolted stem, white sugar yield and root dry matter percentage. The least amount of gibberellic acid and percentage of bolting content between on levels of 150 and 300 ppm paclobutrazol, in order for gibberellic acid, with 65.71 and 64.57 nano moles per gram of fresh tissue and for percentage of bolting with 16.97 and 16.86% respectively. The highest white sugar yield was obtained in levels of 150 and 300 ppm of paclobutrazol, respectively with 8.15 and 8.37 tons per hectare. The interaction effects between genotypes and paclobutrazol in traits of giberelic acid and percentage of bolting were significant. The least percentage of bolting obtained in variety Eudora and 300 ppm paclobutrazol consumption about 2 percent.

KEYWORDS: autumn sugar beet; genotype; gibberellic acid; paclobutrazol; percentage of bolting

Download this article as: 
Copy the following to cite this article:

Sadeghi-Shoae M, Taleghani D. F, Habibi D. Some Reactions of Physiological and Morphological characteristics to foliar Application of Paclobutrazol in Autumn sugar beet (Beta Vulgaris). Biosci Biotech Res Asia 2017;14(1).

Copy the following to cite this URL:

Sadeghi-Shoae M, Taleghani D. F, Habibi D. Some Reactions of Physiological and Morphological characteristics to foliar Application of Paclobutrazol in Autumn sugar beet (Beta Vulgaris). Biosci Biotech Res Asia 2017;14(1). Available from: https://www.biotech-asia.org/?p=21896

Introduction

Sugar beet sowing in autumn is developed or studied in different countries in the developing.  Even, the discussion of autumn sowing of sugar beet is in Northwestern Europe. Greater economic benefits for the farmer are obtained by autumn-sown sugar beet (Jaggard and Werker,1999). On the other hand, bolting adverse phenomenon limiting the autumn sowing of sugar beet has been extensively studied and bolt resistant varieties have prepared and even the breeding of moreresistantcultivarshasalso been possible (Longden and Thomas, 1989; Sadeghian and Sharifi, 1999).

Paclobutrazol is a plant growth regulator from triazols inhibiting gibberlic acid production and has a lot of applications in agriculture (Davis and Curry, 1991). Although it is not well understood an exact scheme of molecular structure to explain the mode of action of paclobutrazol, it can be attributed to the substitution of astrochemical regulators on the carbon rings (Fletcher and Hofstra, 1988). Paclobutrazol by preventing the oxidation of ent-kaurene    to ent-kaurene acid due to inactivation of cytochrome P-450 oxygenase inhibits the biosynthesis of gibberellic acid (Izumi et al., 1985; Graebe, 1987). Although biosynthesis by malonic acid to kaurene and kaurene acid to GA12 aldehyde is not affected (Izumi et al., 1985). Inhibitory effect of paclobutrazol on gibberellic acid biosynthesis is supported by lower concentrations of gibberellic acid in plants treated with paclobutrazol (Steffens et al., 1992). Tsegaw (2006) found that paclobutrazol inhibited the biosynthesis of gibberellic acid and limited the rate of gibberellic acid in plants treated.  Plants that are subjected to paclobutrazol have darker green organs due to an increase in chlorophyll content in the plant (Sopher et al., 1999). The increase in chlorophyll content in response to paclobutrazol was found to be another reason to increase photosynthesis in plants exposed by paclobutrazol, because the increase in chlorophyll content is one of the most important factors increasing the photosynthesis (Berova and Zlatev, 2000).

The aim of present study was to investigate   the feasibility of autumn sown sugar beet in Moghan region and to study the response of different genotypes of sugar beet to different levels of paclobutrazol.

Materials and Methods

For study the response of different genotypes of sugar beet to different levels of paclobutrazol, a field trial was conducted during 2012-2013 at Research Farm of agricultural research center of Moghan, Iran (39°39′ N, 47°55′ E, and 32 m above sea level). The experiment was laid out as a split plot based on a complete

randomized block design with three replications. Treatments were foliar application of paclobutrazol at three levels (0, 150 ppm and 300 ppm) as main plots and varieties at six levels (Eudora, Giada, Jawaher, Levante, Vico and (FC607*474)*Pool-PC.F2-HSF60-P.3)  as subplots. Spraying was continued until the solution drops on plant surface. paclobutrazol spraying was performed after at three stages after cold and three stages (late March, early May and early June). The sugar beet was planted in 27 November 2012 at a density of 100000 plant ha-1, 0.5 m row spacing and 20 cm distance between seeds within rows. Each plot involved three 6m rows. The soil fertility was improved by applying triple superphosphate (18-46-0 N-P-K) and urea at the rate of 100 and 150 kg ha1, respectively, before planting. The numbers of plants were recorded before and after the occurrence of cold in each plot. Plants were harvested in 31 July 2013 and transferred immediately to the laboratory.

Some traits Contains gibberellic acid, percentage of bolting, height of bolted stem, percent of flowering, white sugar yield and root dry matter percentage were analyzed.

The method of measuring gibberellic acid: Half a gram of plant tissue in 10 ml of methanol, water and acetic acid in amounts (30: 70: 1) Import and 4°C is homogenized with Teflon homogenizer. Then at 3000 rpm for 10 minutes centrifuged and the supernatant removed and the column chromatography C18 deployed and then with 10 ml of methanol, water and acetic acid in amounts (20: 80: 1) wash up . Followed by extraction solution with a dry November and 1 ml of methanol was added onto it for injection into the HPLC column is used [19].

All data were subjected to ANOVA using the GLM procedure of SAS (SAS Institute, 2002). Treatment means were separated using Duncan test at P < 0.05. Excel software was used for creating the graphs.

Results and Discussion

Gibberellic Acid

After reviewing the data analysis results illustrate that significant differences between different levels of paclobutrazol paclobutrazol levels of 150 and 300 ppm were analyzed in a group, respectively 65.71 and 64.57 ng/g.fw , had the lowest levels of the hormone gibberellic acid and paclobutrazol control with 60/88 ng/g.fw had the highest levels of the hormone (Tables 1 and 2 ). Due to the fact that paclobutrazol by preventing oxidation, ent-kaurene to ent-kaurene acid to disable oxygenase cytochrome P-450, inhibits the biosynthesis of gibberellic acid (Izumi et al., 1985; Graebe, 1987). Effects of paclobutrazol preventing the flow of gibberellic acid biosynthesis by paclobutrazol treatment plants have lower concentrations of gibberellic acid is authenticated (Steffens et al., 1992). Tsegaw (2006) also stated that the paclobutrazol front of gibberellic acid synthesis and plant it in the limit.

Between different levels of cultivars in this experiment, the amount of hormone gibberellic acid, there was a significant difference at the 1% level (Table 1). Thus, the figure (FC607 * 474) * Pool-PC.F2-HSF60-P.3 with 103.36 ng/g.fw greatest amount of hormone gibberellic acid and Eudora with 42.31 ng/g.fw lowest gibberellic acid accounted for (table 2). A strong correlation between the percentage of gibberellic acid and Bolt, Bolt height and percentage of bullets had gone to flower (Avrin and Banakar, 2001; CaiFeng, 2003).

Table 1: Variance analysis evaluated

(MS) Mean Square
Root dry matter  White sugar yield (WSY) Height of bolt  bolting  Gibberelic acid (GA)  df S.O.V.
37.05* 1.61ns 4683.46* 88.02ns 7.26ns 3 Replication
30.32* 23.74* 5247.57* 519.13** 4411.73** 2 PBZ
4.09ns 3.06ns 986.21ns 32.56ns 213.18ns 6 Rep×PBZ
17.96 43.46** 12642.07** 1356.27** 5362.21** 5 Cultivar
5.09ns 3.66ns 759.36ns 75.59** 651.23** 10 Cul×PBZ
5.78 5.11 675.25 31.73 32.68 45 Error
11.35 25.40 16.83 24.73 7.83  C.V.(%)

ns, * ,**: Non significant on 1 and 5 % levels of probability, respectively

Based on data analysis of the interaction was significant cultivar in Paclobutrazol on the gibberellic acid (Table 1). So that the cultivars Eudora and Vico significant difference between levels of paclobutrazol on there as gibberellic acid but Giada figures, Jawaher, Levante and the (FC607 * 474) * Pool-PC.F2-HSF60-P.3 this difference there was a significant difference between the mean of gibberellic acid, Thus, in figures and Levante Giada control most of paclobutrazol and gibberellic acid levels of 150 and 300 ppm paclobutrazol were in a statistical group, but the figure was the lowest this hormone gibberellic acid Jawaher highest level without paclobutrazol and the lowest level was 150 ppm, while the figure (FC607 * 474) * Pool-PC.F2-HSF60-P.3 process for another and the control surfaces and 300 ppm gibberellic acid had the highest levels of the two groups were analyzed at a level of 150 ppm paclobutrazol and gibberellic acid had the lowest rate (Figure 1).

Figure 1: Interaction between cultivar and Paclobutrazol on gibberellic acid Figure 1: Interaction between cultivar and Paclobutrazol on gibberellic acid

 

Click here to View figure

Bolting Percentage

Analysis of variance indicate that paclobutrazol sprayed bullets on the percentage loss was significant (Table 1). The percentage of flowering stems of flowering stems spraying paclobutrazol reduced the percentage compared to the control paclobutrazol that level of control without paclobutrazol with 24.19 percent higher than the levels of 150 and 300 ppm, respectively, 16.97 and 16.86 with Bolt percent were in a statistical group, respectively (Table 2). Since the impact vernalisation and during the day on bolting induced by gibberellic acid production and Considering that paclobutrazol inhibit the oxidation of ent-kaurene to ent-kaurene acid in the biosynthesis of gibberellic acid to prevent its formation is disrupted (Lever, 1986; Davies and Zalman, 2002). So it reduces the synthesis of gibberellic acid application and subsequent bolting percentage is reduced. Effects of paclobutrazol preventing the flow of gibberellic acid biosynthesis by paclobutrazol treatment plants have lower concentrations of gibberellic acid is authenticated (Steffens et al., 1992). Tsegaw (2006) also stated that the paclobutrazol front of gibberellic acid synthesis and plant it in the limit. CaiFeng (2003) were also acknowledged that Paclobutrazol reduced bolting percentage.

Among the varieties evaluated in this experiment, there was a significant difference in that figure Jawaher (FC607 * 474) * Pool-PC.F2-HSF60-P.3 28.16 and 5.31 percent, respectively, with the highest percentage Bolt and Bolt figure Eudora with 2.72 percent had the lowest percentage (table 1 and 2). Between different cultivars there are differences in terms of gibberellic acid. Pfeiffer et al. (2013) reported that during our testing the crucial role in the fall sugar beet bolting and the use of suitable varieties as too much can prevent the phenomenon of bolting. Unfavorable phenomenon bolting in sugar beet yields in autumn planting is the limiting factor, has been extensively studied and prepared varieties resistant to bullets and even more resistant cultivars is also possible (Longden and Thomas, 1989; Sadeghian and Sharifi, 1999).

Table 2: Mean comparison of traits

Root dry matter (%)  White sugar yield (WSY)

(ton.ha-1)

 Height of bolt (cm) bolting

(%)

 Gibberelic acid (GA)

(ng/g.fw)

 Treatment
  PBZ
20.01b 6.55b 170.72a 24.97a 88.60a 0
21.28ab 8.15a 141.90b 16.97b 65.71b 150ppm
22.25a 8.37a 150.54b 16.86b 64.57b 300ppm

 

  Cultivar
21.78ab 8.94a 113.01d 2.72d 42.31e Eudora
19.35c 6.49b 122.93d 11.66c 60.98d Giada
19.95bc 6.60b 161.48bc 28.16a 87.65b Jawaher
21.66ab 8.72a 179.49ab 22.77b 73.80c Levante
21.99ab 10.22a 151.70c 21.22b 69.68c Vico
22.36a 5.15b 197.73a 31.05a 103.36a (FC607*474)*Pool-PC.F2-HSF60-P.3

Treatment with the same letters don,t show significant differences

Analysis of variance showed that the interaction of Paclobutrazol on bolting percentage was significant at the 1% level (Table 1). As Figure 2 shows, between paclobutrazol in the Eudora, Vico and figure (FC607 * 474) * Pool-PC.F2-HSF60-P.3 There was no significant difference in the varieties Giada, Levante and Jawaher significant difference between levels there paclobutrazol, Thus, in figures and Levante highest percentage Bolt Giada without paclobutrazol levels, and levels of 150 and 300 ppm paclobutrazol were in a statistical group has had the lowest percentage Bolt, But in the process for other Jawaher and the highest level Bolt control of paclobutrazol and the lowest level was 150 ppm.

Figure 2: Interaction between cultivar and paclobutrazol on the percentage of bolt Figure 2: Interaction between cultivar and paclobutrazol on the percentage of bolt

 

Click here to View figure

Height of bolt

 Analysis of variance showed significant at the 5% level between the height Bolt paclobutrazol levels (Table 1). Thus, a significant decrease showed that the paclobutrazol control with 170.72 cm above the levels of 150 and 300 ppm paclobutrazol 141.90 and 150.54 respectively Bolt cm in height, and in a group Statistics were analyzed (table 2). Gibberellic acid increased percentage of sugar beet bolting and also increase the height Bolt (Humpharies and French,2008). Given the deterrent effect of the paclobutrazol on the biosynthesis of gibberellic acid, gibberellic acid decreases, thus reducing the height of the bolt. Stevens (1985) stated that paclobutrazol was reduced shoot height of flowering in sugar beet. There are many reports on the reduction of plant height (Koutroubas et al., 2004; Francescangeli, 2009).

It is noteworthy that between cultivars tested in this study there was a significant difference (Table 1). The highest figure of 197.73 cm (FC607 * 474) * Pool-PC.F2-HSF60-P.3 and the lowest Bolt 113.01 and 122.93 respectively figures Eudora and Giada cm that these two groups were compared in a (table 2). According to the data gibberellic acid, and given the fact that Bolt height depends on the amount of gibberellic acid (Humphries and French, 2008). It can be concluded that the close association between gibberellic acid number and stem height of it there. As it stands digits (FC607 * 474) * Pool-PC.F2-HSF60-P.3 highest height Bolt and maximum amount of gibberellic acid and Eudora with the lowest height and the lowest figure of gibberellic acid.

White Sugar yield

The final product after subtracting impurities in sugar beet farming, the production of these articles. Analysis of variance showed that paclobutrazol sprayed on white sugar yield was significant (Table 1). The spraying paclobutrazol increases the production of white sugar, white sugar yield compared with the control paclobutrazol that paclobutrazol levels of 150 and 300 ppm, respectively, 8.15 and 8.37 tons per hectare higher than the control paclobutrazol were with 6.55 tons per hectare so that the levels of 150 and 300 ppm in a groups were compared (table 2). White sugar yield depends on the amount of white sugar and root yield and given the amount of white sugar and root yield this result was predictable. That the results expressed by Zhang et al., (2012) showed that the increase of sugar on the effect of paclobutrazol match, but the reports Stevens (1985) revealed no significant was the inconsistent treatment.

After reviewing the data analysis results illustrate the significant difference between the cultivares Eudora, Levante and Vico that were analyzed in a group respectively, 8.94, 8.72 and 10.22 tons per hectare had the highest white sugar yield and Giada digits, jewelry (FC607 * 474) * Pool-PC.F2-HSF60-P.3 respectively. white sugar 6.49, 6.60 and 5.15 tons per hectare in a statistical category and the lowest value of this attribute (table 1 and 2). There were differences between the different varieties and each variety can vary according to the sum of its quantitative and qualitative characteristics of the mind (Draycottt, 2006; Cooke and Scott, 1993).

Root dry Matter

Root dry matter content between different levels of paclobutrazol and between cultivars evaluated were statistically significant (Table 1). Among paclobutrazol operating levels, a concentration of 300 ppm paclobutrazol control with 22.25 percent highest and lowest with 20.1 percent in this factor (Table 2). Avrin and Banakar (2001) that paclobutrazol no effect on dry matter who was in contradiction with the results. In between the tested varieties (FC607 * 474) * Pool-PC.F2-HSF60-P.3 with 22.36 percent and the highest percentage of dry matter root Giada with 19.35 percent had the lowest root dry matter (table 2).

References

  1. Avrin S. M and Banakar M. H. The effect of growth regulators on Bolting and Several Traits of Onion cv. Texas Early Grano. Science and technology of agriculture and natural resource. 2001;6(1):69-59.
  2. Berova M & Zlatev z.  Physiological response and yield of paclobutrazol treated tomato plants (Lycopersicon esculentum Mill). Plant Growth Regul. 2000;30(2):117-123.
    CrossRef
  3. CaiFeng L. Researches on regulation and its mechanism of plant growth regulating substances on bolting in sugar beet. PhD. Thesis. Northeast Agriculture University. 2003;127.
  4. Cooke D., Scott R. The sugar beet crop:Science Into Practice Chapman and Hill, New York. 1993;195.
  5. Davies F. S and Zalman G. R. Fertilization root stock growth and yield of young Rhode red Valencia orange trees. Pro. Fla. State hort. Soc. 2002;115:14-17.
  6. Davis T. D & Curry E. A.  Chemical regulation of vegetative growth. Crit. Review of Plant Science. 1991;10:151-188.
    CrossRef
  7. Draycott P. h.  Sugar beet. Blackwell Publishing Ltd. 2006;514.
    CrossRef
  8. Fletcher R. A & Hofstra G.,  Berg  D & Plempel M (eds.), Triazoles as potential plant protectant. In: sterol synthesis inhibitors in plant protection. Ellis Horwood Ltd., Cambridge, UK.  1988;31-331.
  9. Francescangeli N. Paclobotrazol and cytokinin to produce iris in pots. Chilean journal of agricultural research. 2009;69(4):509-515.
    CrossRef
  10. Graebe J. E. Gibberellin biosynthesis and control. Annu. Rev. Plant Physiology. 1987;38:419-465.
    CrossRef
  11. Humphries E. C and French S. A. W.  A growth study of sugar beet treated with gibberellic acid and trimenhylammonium chloride. Annals of Applied Biology. 2008;55(1):159-173.
    CrossRef
  12. Izumi K., Kamiya Y., Sakurai A., Oshio H & Takahashi N. Studies the site of action of new plant growth retardant (E)-1-(4-chlorophenyl)-4, 4-dimethy1-2-(1,2,4-trazoles-1-penten-3-o 1) (SS-3307) and comparative effects of its sterioisomers in a cell free system from Curcurbita maxima. Plant Cell Physiology. 1985;26:821-827.
  13. Jaggard  K. W and Werker A. R.  An evaluation at the potential benefits and of autumn–sown sugar beet in NW Europe. J. Agric. Sci. 1999.
    CrossRef
  14. Koutroubas S. D., Vassiliou G and Damalas C. A.  Sunflower morphology and yield as affected by foliar applications of plant growth regulators. International Journal of Plant Prouduction. 2004;8(2):215-229.
  15. Lever B. G. Cultar-A technical overview. Acta. Horticulturae. 1986;179:459-467.
    CrossRef
  16. Longden P. C andThomas T. H . Why not autumn sowing sugar beet. British Sugar Beet. 1989.
  17. Pfeiffer N., Moller A,. Jung C. h And Kopisch F.  Genetic and Phenotypic Characterization of bolting failure in sugar beet. Plant and animal genome Conference, San Drege CA. 2013.
  18. Sadeghian S. Y and Sharifi H. Improvement of sugar beet for combined resistance tobolting and cercopora leaf spot. 62th IIRB cong. Sevilla. Spain. 1999.
  19.  Hou S., Zhu J.,  Ding M. Simultaneous determination of gibberelic acid, indol-3-acetic acid and Abscisic acid in wheat extract by solid phase extraction and liquid chromatography. Talanta. 2008;76:798-802.
    CrossRef
  20. Sopher C. R., Krol M., Huner N. P. A., Moore A. E & Fletcher R. S. Chloroplastic changes associated with paclobutrazol-induced stress protection in maize seedling. Can. J. Bot. 1999;77(2):279-290.
    CrossRef
  21. Steffens G. L., Lin J. T., Stafford A. E., Metzger J. D & Hazebroek J. P. Gibberellin content of immature apple seeds from paclobutrazol treated trees over three seasons. Journal of Plant Growth Regulation. 1992;11:165-170.
    CrossRef
  22. Stevens D. R. The manipulation of sugar beet growth and development by paclobutrazol and mefluidide. Master of applied science University of Canterbury. 1985;121.
  23. Tsegaw T. Response of potato to paclobutrazol and manipulation of reproductive growth under tropical conditions. Thesis of doctora degree. University of Pretoria etd. 2006;203.
  24. Zheng R., Wu Y and Xia Y. Cholorocholine chloride and paclobutrazol treatments promote carbohydrate accumulation in bulbs of Liliium Oriental hybrids Sorbonne. Journal of Zhejiang University Science. 2012;13(2):136-144.
    CrossRef
(Visited 360 times, 1 visits today)

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.