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EFFECT OF PLANT GROWTH REGULATORS ON DE-
GREENING & COLD STORAGE OF TANGO AND SUGAR BELLE
CITRUS VARIETIES
Daniel Adu Boakye [email protected]
1
Introduction Tango and sugar belle growers prefer uniform color break or maturation
to ensure harvesting of fruits within specific periods with good internal
qualities.
Gibberellic Acid (GA3)
Brassinosteroid (HBr)
Abscisic Acid (ABA)
Influence color break ormaturation in citrus.
These plant growth regulators influence color maturation but no report has beenmade on their effects on tango and sugar belle.
GA3 retards fruit senescence while brassinosteriods increase fruit peel coloration. ABA hastens ripening and chlorophyll breakdown, thus advancing peel coloration
or maturation.
2
Objective
To assess the effect of plant growth regulators on de-greening
and cold storage conditions of Tango and Sugar belle citrus
varieties
To evaluate the effect of plant growth regulators on internal
qualities after de-greening and cold storage
Daniel Adu Boakye [email protected]
3
Materials and Methods
Varieties: Sugar belle and Tango
Treatments Used
Abscisic acid (ABA), 1 mM
Gibberellic Acid (GA3), 20 ppm.
Brassinosteriods (HBr), 1 uM
Control (water)
Daniel Adu Boakye [email protected]
Samples for cold storage and de‐greening were collected from two groves. That is, sugar belle from UF - SWFREC Demonstration groves, Immokalee and tango from Martin’s grove, Labelle
4
Harvested fruits for Cold storage & De‐
greening
Treatments were applied after
harvesting of fruits
Data Collected
Cold storage at 45 F (7.2 C)
84 o F and 95 % RH with 5 ppm of ethylene (de‐greening)
84 o F and 95 % RH with no ethylene (de‐greening control)
Color advancement
Internal qualities • Brix• Titratable acidity
Data Collection Interval• Cold storage – 6 days interval• De‐greened fruits – 2 days (48
hours)
Materials and Methods
Data AnalysisTreatments Application
Chroma meter was used to measure peel color at initial stage and periodically for fruits that were de‐greened and cold room storage.Brix‐acid ratio was determined by dividing brix by titratable acidity. Where levels of brix or solid soluble content was determined using refractometer and % titratable acidity (% acid) was evaluated using garner et al., method and with the formula above
5
Results
‐0.7
‐0.6
‐0.5
‐0.4
‐0.3
‐0.2
‐0.1
0water HBr (1 µM) GA (20 ppm) ABA (1mM)
Chan
ge in
color
a/b
PGRs
Figure 1: Sugar belle peel coloration after PGR treatments in cold storage room (45oF)
Day 0 Day 6 Day 12
Daniel Adu Boakye [email protected]
The plant growth regulators had slight effect (or no effect) on the peel coloration or maturation by Day 12 particularly as water (control) influenced the peel coloration more than all the PGR. But the mild peel color advancement from Day 0 to Day 6 can be link to loss of the sensible heat due to the cold storage
6
‐0.6
‐0.5
‐0.4
‐0.3
‐0.2
‐0.1
0
Water HBr GA3 ABA
Chan
ge of color
a/b
PGRs
Day 0 Day 6 Day 12
Figure 2: Effect of plant growth regulators (PGRs) on peel coloration of tango fruits in cold
Results
In cold storage, the plant growth regulators did not have significant effect on peel color advancement or coloration particularly when compared with water (control). Though there were slight changes in coloration on Brassinosteroid (HBr) and Abscisic acid (ABA) which may be as a results of shedding off the sensible heat. Tango’s response to the PGRs is very low according to this study.
7
Some photos
Daniel Adu Boakye [email protected]
Control (water)
Abscisic acid
3a 3b
4c 4d
Figures 3-4: Effect of Plant growth regulators on sugar belle and tango fruits before (3a, 3c, 4a & 4c) cold storage and after 12 days (3b, 3d, 4b & 4d)
of cold storage
Control (water)
Abscisic acid
4a 4b
4c 4d
Sugar belle Tango
Comparatively, the control is not different from Abscisic acid (as well as the other growth regulators) especially on day 12. This confirms that these plant growth regulators were not able to advance peel color maturation of sugar belle and tango in cold storage
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Results
-0.45
-0.4
-0.35
-0.3
-0.25
-0.2
-0.15
-0.1
-0.05
0 water HBr (1 µM) GA (20 ppm) ABA (1mM)
a/b
PGRs
Figure 5a: Effect of plant growth regulators (PGRs) on peel coloration of Tango fruits stored at temperature (84 F) and Relative Humidity (95 %)
Initial color 96 hrs after Temp (84 F) & RH (95%)
Peel coloration of tango fruits were not significantly influenced by temperature at 84 F and relative humidity at 95 %. Higher temperature and relative humidity are known to advance maturation in climacteric fruits but they have slight effect on non‐climacteric fruits or products since ethylene production is minimal
9
Results
‐0.45
‐0.4
‐0.35
‐0.3
‐0.25
‐0.2
‐0.15
‐0.1
‐0.05
0
water HBr (1 µM) GA (20 ppm) ABA (1mM)
Ch
ang
e in
co
lor
a/b
PGRs
Figure 5b: Effect of Plant growth regulators (PGRs) on de‐greening on tango
Before Degreening
End of 48 hrs of Degreening
After Degreening (48 hrs)
Brassinosteroid (HBr) and GA3 did not make any significant contribution in the peel color advancement when compared with control but comparatively abscisic acid was significant than all the other treatments after 48 hours of de‐greening.But when this figure 5a is compared with figure 5b, it can be revealed that addition of ethylene had significant influence in peel coloration or advancement of the fruits, thus when the initial or before de‐greening is compared with 48 hours after de‐greening
10
Results
‐0.45
‐0.4
‐0.35
‐0.3
‐0.25
‐0.2
‐0.15
‐0.1
‐0.05
0 water HBr (1 µM) GA (20 ppm) ABA (1mM)
Ch
ang
e in
co
lor
a/b
PGRs
Figure 6a: Effect of plant growth regulators (PGRs) on color maturation of sugar belle fruits at temperature (84 F) and relative humidity (95 %)
Initial color
96 hrs after Temp (84 F) & RH(95%)
The temperature and relative humidity advanced peel coloration but it cannot be fully associated to the plant growth regulators since the control (water) changed or advanced in color more than all the PGRs. Also abscisic acid (ABA) and Brassinosteroid were expected to advance in color more than GA (20 ppm) since ABA is known to advance peel color development and GA (20 ppm) delay senescence or peel coloration.
11
Results
‐0.5
‐0.4
‐0.3
‐0.2
‐0.1
0
0.1
0.2water HBr (1 µM) GA (20 ppm) ABA (1mM)
Ch
ang
e in
co
lor
(a/b
)
PGRs
Figure 6b: Effect of Plant growth regulators on De-greening of Sugar belle
Before Degreening
End of 48 hrs of Degreening
48 hrs After Degreening
Comparatively, the effect of Plant growth regulators on color break or maturation of sugar belle is mild. The color maturation of the control (water) is similar to all the plant growth regulators especially after 48 hours of de‐greening. Effect of de‐greening is significant in advancing peel coloration when figure 6a and 6b are compared. Thus, sugar belle advanced in coloration with de‐greening than tango which means that sugar response to 5 ppm ethylene, 84 F and 95 % RH treatment more than tango
12
Some Photos onSugar belle & Tango Before and after De-greening
Daniel Adu Boakye [email protected]
Figures 7 & 8: Sugar belle fruits before (1A) de‐greening and after (1B) de‐greening; 2A‐before de‐greening of tango and after de‐greening
7a 7b 8a 8b
The figure 7 (a & b) is the control for sugar belle while figure 8 (a & b) is the Brassinosteroid (HBr) for tango
13
Brix-acid ratio of Tango and Sugar belle
Figure 9b: Tango
Initial water HBr (1 µM) GA (20 ppm) ABA (1mM)
Cold storage 12.8 10.1 9.8 10 8.7
84 F & 95 % (no ethylene) 11.4 14.5 12 18.3 14.2
Figure 9a: Sugar belleInitial water HBr (1 µM) GA (20 ppm) ABA (1mM)
Cold storage 6.6 10.1 6.2 7.8 6.3
De-greening 5.8 9.4 6.3 7.6 9.3
Results
Increase in temperature, increased brix‐acid ratio either with ethylene or without ethylene when compared with cold storage of all the two varieties irrespective of the plant growth regulator except sugar belle’s control and GA (20 ppm).
Brix‐acid ratio is very essential since it constitutes a measure of the balance between sugars and acids. It serves as indicator of the palatability of the juice where larger values indicate sweeter taste. (Note: Brix‐acid ratio= Brix/Titratable acidity). At an increased temperature irrespective of relative humidity result to increase in brix‐acid ratio in the fruits as a result of decrease in titratable acidity or citric acid (Burdon et al., 2006).
14
Conclusion
t
De-greening enhanced coloration in sugar bellethan in tango.
The mild effects of ABA and HBr suggest thatplant growth regulators interaction with de-greening might have been impaired
There was increase brix‐acid ratio either withethylene (de‐greened) or without ethylene whencompared with cold storage of all the two varietiesexcept sugar belle’s control and GA (20 ppm)
15