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Adv. Hort. Sci., 2021 35(1): 53­60                                                                                                        DOI: 10.36253/ahsc­9663

Endogenous hormone causes flower 
and fruit drop of wax apple (Syzygium 

samarangense cv. Citra) 
 
 
E. Wukir Tini (*), T.A. Dwi Haryanto, Sakhidin, Saparso 
Agriculture Faculty, Jenderal Soedirman University, Purwokerto, Central 
Java, Indonesia. 
 
 
Key words: ACC, cytokinins, fruit drop, IAA, GA3, wax apple. 
 
 
Abstract: The aim of this study was to obtain information about the content of 
endogenous hormones that causes flowers and fruit drop of wax apple. The 
variables observed in the six stages of flower and fruit development that drop 
easily and retention of indole­3­acetic acid (IAA), cytokinin (zeatin and kinetin), 
gibberellins (GA3), 1­amino cyclopropane­1­carboxylic acid (ACC), total sugar, 
and starch. Six stages of development of wax apple fruit: (1) Bud Development 
(initial flowering) 0­3 days before anthesis. (2) Anthesis (perfect blooming flow­
ers), 0­7 days after anthesis. (3) Fruit set, 7­14 days after anthesis. (4) Fruit 
development, 14­28 days after anthesis. (5) Fruit Maturation, 28­35 days after 
anthesis. (6) Fruit ripening, 35­50 days after anthesis. The results showed that 
the content of IAA, zeatin,  GA3, and total sugar of flowers and fruit of wax 
apple at 6 stages that would fall smaller than those of retention and ACC con­
tent and starch was higher in flower and fruits that drop easily than retention. 
The kinetin content in the flower development that drop easily is smaller than 
the retention but in the fruit development the kinetin content is not significant­
ly different between those that drop easily and retention. 
 
 
1. Introduction 
 
     Water apple originates from the Southeast Asian region (Indonesia 
and Malaysia), then spreads to the islands of the Pacific and North and 
Central America. Generally, wax apple fruit is consumed as fresh fruit, but 
it can also be made for salad and preparations such as pickles, syrups, jel­
lies, and cocktails. Water apple fruit is not only sweet and refreshing but 
has diversity in appearance. Types of water apple are Syzygium aqueum 
(water apple) and Syzygium samarangense (wax apple). The varieties of 
Syzygium samarangense include Delima, Lilin, Camplong, Cincalo, Citra, 
Kesuma, and Madu, (Kuswandi, 2008). 
     Corona Virus Disease (COVID­19) is originating from Wuhan, China 
began to spread throughout the world from January 2020 to 31 
December 2020, so there were 83,264,353 cases, with 1,816,164 deaths 
from 218 affected countries (World Health Organization, 2020). No vac­
cine has been found to treat patients with the COVID­19 virus. According 

(*)
 
Corresponding author:  

etik.unsoed@gmail.com 
 
 
Citation: 
WUKIR TINI E., DWI HARYANTO T.A., SAKHIDIN, 
SAPARSO, 2021 ­ Endogenous hormone causes 
flower and fruit drop of wax apple (Syzygium 
samarangense cv. Citra).  ­ Adv. Hort. Sci., 35(1): 
53­60 
 
 
 
Copyright: 
© 2021 Wukir Tini E., Dwi Haryanto T.A., 
Sakhidin, Saparso. 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 3 September 2020 
Accepted for publication 27 January 2021

AHS 
Advances in Horticultural Science

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Adv. Hort. Sci., 2021 35(1): 53­60

54

to the Ministry of Health of the Republic of Indonesia 
(2020), prevention of viruses can be done by fre­
quently washing hands, wearing masks, consuming 
vegetables and fruit, exercise, and adequate rest. 
One of the prevention efforts that can be done by 
consuming fruits that contain Vitamin C to enhance 
immunity. Every 100 g of wax apple fruit contains 
22.3 µg of vitamin C (Asia­Pacific Association of 
Agricultural Research Institutions, 2014). Therefore 
wax apple is a tropical fruit that is cheap, easily 
obtained, and contains vitamin C which can be used 
as an alternative to increasing body immunity as a 
preventative measure against the COVID­19 virus. 
     The main problem in the cultivation of wax apple 
plants is the high drop of flowers and fruit. The high 
rate drop of flowers and fruit causes a few numbers 
of wax apple fruit that can be produced. Wax apple 
drop fruit rate reaches 52% (Khandaker et al., 2016). 
Fruit drop also occurs in other fruits, such as durian 
flowers reach 95 to 100% (Suparto and Sakhidin, 
2013), lychee fruit is 90 to 97% (Stern et al., 1995), 
star fruit is 25 to 30% (Kurniawati and Hamim, 2009), 
mangosteen flower is 14.1% and mangosteen fruit is 
70.1% (Rai et al., 2008). 
     Dropped fruit is a natural phenomenon that occurs 
in almost all types of fruit. Drop fruit, especially at the 
beginning of fruit growth, is a mechanism for regulat­
ing autoregulation in each plant (Davarynejad et al., 
2009). Physiologically the loss of flowers and fruit cor­
relates with the limited supply of photosynthate and 
nutrient adequacy (Iglesias et al., 2007), as well as 
h o r m o n a l  r e g u l a ti o n  i n  t h e  a b s c i s s i o n   z o n e 
(Bangerth, 2000). Flower and fruit drop are also influ­
enced by endogenous hormone content in plants due 
to high ethylene concentrations and low concentra­
tions of auxin and gibberellins. Auxin, gibberellins, 
and ethylene are hormones that are directly related 
to the process of flowers and fruit drop (Bangerth, 
2000). Complex hormonal interactions occur during 
fruit development. Gibberellins and cytokines gener­
ally stimulate fruit growth and auxin as a growth stim­
ulator and also as a fruit drop agent. Abscisic acid 
(ABA) and ethylene are also involved in the process of 
loss (Sakamoto et al., 2008). High ethylene concentra­
tions, low concentrations of auxin and gibberellins, 
and high ABA concentrations in plants are the main 
causes of drop fruit (Iglesias et al., 2007). 
     The causes of flower and fruit drop of the wax 
apple due to imbalance of plant growth regulator as 
well as cultivation and environmental engineering 
factors, including pollination, fertilization, fruits set, 

lack of water and nutrition supply, pest attack, rain­
fall and wind (Khandaker et al., 2016). Research on 
the use of synthetic Growth Plant Regulators (GPR) to 
reduce the fruit drop of wax apple has been conduct­
ed by Khandaker et al. (2013), Khandaker et al. 
(2016), 50 mg l­1 Gibberellins (GA3), GA3 produces the 
lowest flower and fruit buds loss of 29% compared to 
controls (not given GA3 36%). GA3 20 mg l

­1 reduced 
f r u i t  l o s s  3 2 %  c o m p a r e d  t o  5 2 %  c o n t r o l .  2 ­ 4 ­
Dichlorophenoxyacetid (2,4 D) 5 mg l­1 reduces flower 
and fruit bud loss by at least 30% and 18% compared 
to 35% and 40% controls. Naphthaleneacetid Acid 
(NAA) 5 mg l­1 reduced the flower buds and fruits 
drop as lower as 28% and 30% compared to 30% and 
52% controls. The causes of flowers and fruit drop of 
wax apple are because the content of endogenous 
hormones is not yet known, so the application of 
growth plant regulator given is not appropriate to 
reduce the flowers and fruit drop. 
     Singh et al. (2017) the results of research on the 
application of growth plant regulator on Khasi man­
darin (Citrus reticulata Blanco) showed an increase in 
fruit retention and the number of fruit with the appli­
cation of Urea 1% + 2, 4­D 15 ppm (45.4% and 244, 3 
fruits/tree), application of NAA 5 ppm + 2,4­D 10 
ppm (44.3% and 241.6 fruit/tree) compared to con­
trols (17.3% fruit retention and 181 fruit/tree). NAA 
treatment 15 ppm increased the proportion of cape 
gooseberry cv. Aligarh is retention (71.40%) (Kaur 
and Kaur, 2016). 
     The purpose of this study was to obtain informa­
tion on hormones that causes flower and fruit drop 
at several stages of the development of wax apple 
fruit and to obtain differences in the hormone con­
tent at how many stages of flower and fruit develop­
ment are easily dropped and retention. 
 
 
2. Materials and Methods 
 
     The research used an experimental method from 
May 2019 to April 2020. The experimental design 
used was a Completely Randomized Design (CRD) 
with the treatment being tried, namely flower and 
fruit retention and drop easily of wax apple at six 
stages fruit development: (1) Bud development (from 
0 to 7 days before anthesis); (2) Anthesis (full bloom), 
from 0 to 7 days after anthesis; (3) Fruit set (the for­
mation of finished fruit), from 7 to 14 days after 
anthesis; (4) fruit development, from 14 to 28 days 
after anthesis; (5) Fruit maturation, from 28 to 35 



Wukir Tini et al. ‐ Hormone endogenous causes flower and fruits drop

55

days after anthesis; (6) Fruit ripening (from 35 to 50 
days after anthesis). Experiment with 4 replications 
and data analysis using t­test and advanced test 
DMRT (Duncan Multiple Range Test). Flower and fruit 
samples were taken from 46 wax apple plants, 
Kajongan Village, Bojongsari District, Purbalingga 
Regency, Central Java. The variables observed were 
auxin content (IAA), cytokinins (zeatin and kinentin), 
gibberellin (GA3), ACC (1­Aminocyclopropane 1­
Carboxylic Acid), total sugar, and starch. 
     The samples used for the study were flowers and 
fruits from 6 stages of development of flowers and 
water guava. Plants are 5 years old, plant spacing 8 m 
x 9 m, with a height of ± 7 m and have been fruiting 
for the last 4 years. Temperature 25.8°C with 76% 
humidity, sunlight intensity 571 Lux outside the 
canopy, and under the canopy 529 Lux and soil pH 
6.8. Organic cultivation of wax apple uses goat 
manure at a dose of 100 Kg per plant per year. 
Irrigation in the dry season with springs that are 
channeled from a hose from a pipe made by the gar­
den. The results of soil analysis conducted at the 
Postharvest Center of the Ministry of Agriculture, 
inceptisol soil type, pH 6.14, organic C 0.769%, total 
N 0.082%, available N 0.025%, total K 55.960 ppm, K 
available 30.277 ppm, total P 45.189 ppm, and 
1.321% organic matter. 
     The samples drop easily are taken from the flower 
and fruit which when the branches or twigs are shak­
en fall out and after the fall there is a black abscission 
layer on the flower stalk or fruit. The retention sam­
ples are wax apple flower and fruit which if the 
branches or twigs are shaken not fall off, are still 
attached to the plant, and usually, the flower stalk or 
fruit is still present. The sample is placed in an icebox 
containing blue ice and then taken to the Integrated 
Research Laboratory, Jenderal Soedirman University 
to be dried in a 2kxc bench top Vacuum Freeze Dryer. 
Wax apple samples for bud development, anthesis, 
and fruit set for 25 hours, and fruit development, 
fruit maturation, fruit ripening for 55 hours with a 
temperature of ­70°C, and a pressure of 13,332.2 Pa 
The contents of auxin (IAA), GA3, zeatin, kinetin, ACC, 
total sugar, and starch were carried out at the 
C h e m i c a l  L a b o r a t o r y ,  C e n t e r  f o r  P o s t h a r v e s t , 
Ministry of Agriculture, Bogor, West Java, Indonesia. 
     Procedure for measuring hormone content (auxin, 
c y t o k i n i n ,  a n d  g i b b e r e l l i n s )  u s i n g  H P L C  ( H i g h ­
Pressure Liquid Chromatography) at a wavelength of 
214 nm, sample temperature of 10°C and column 
temperature of 25°C, stationary phase using C­18. 

The formula for hormone content by HPLC is sample 
area divided by standard area multiplied by standard 
concentration (Harborne, 1973). Measurement of 
ACC content according to Lizada and Yang (1979), 
using GC (Gas Chromatography). The formula for ACC 
content in GC is sample area divided by standard 
a r e a  m u l ti p l i e d  b y  s t a n d a r d  c o n c e n t r a ti o n . 
M e a s u r e m e n t  o f  t o t a l  s u g a r  a c c o r d i n g  t o  t h e 
Indonesian National Standard (1992) using the Luff 
Schoorl method. Starch calculation according to 
Horwitz and Latimer (2006). 
 
 
3. Results 
 
     Table 1 shows that the fruit drop easily having 
lower IAA, zeatin, and GA3 content than fruit reten­
tion in all phases of fruit development. The kinetin 
content at the bud development, anthesis, and fruit 
set stages that drop easily is lower than the reten­
tion, but the kinetin content at the fruit develop­
ment, fruit maturation and fruit ripening stages is not 
significantly different in the fruit that drop easily dan 
retention. While the ACC content of fruit that drops 
easily is greater than that of retention.  
     Table 2 shows that the total sugar content at vari­
ous stages of flower and wax apple fruit develop­
ment in flower and fruit retention is higher than that 
of drop easily. The content of starch in fruit retention 
of various stages of development of the flower and 
fruit is lower than those that are of drop easily. 
 
 
4. Discussion and Conclusions 
 
     The IAA content in wax apple flower and fruit 
which drops easily on bud development, anthesis, 
fruit set, fruit development, fruit maturation, and 
fruit ripening is lower than the retention flower and 
fruit. This is according to Rai et al. (2008). The IAA 
content of mangosteen flowers falling 3.37 ng g­1 is 
lower than the retention rate of 8.80 ng g­1 dry 
weight and IAA content in mangosteen fruit falling 
0.83 ng g­1 is lower from the IAA content of 6.43 ng  
g­1 retention fruit. Sakhidin et al. (2011), the content 
of IAA in mango fruit loss is lower than that of reten­
tion. Gadung 21 and Lali Jowo cultivars that will fall 
age 6 and 9 days after anthesis are 5.96 and 3.86 10­1 
µg g­1 sample fresh weight and 4.48 and 4.12 10­1 µg 
g­1 sample fresh weight. Mango fruit retention of 
10.32 and 8.12 (10­1 µg g­1 sample fresh weight and 



Adv. Hort. Sci., 2021 35(1): 53­60

56

10.08 and 7.98 10 ­1 µg g ­1 sample fresh weight. 
According to Kurniawati and Hamim (2009), star fruit 
with an application of 15 ppm 2, 4­dichlorophenoxy­
acetic acid (2,4­D) contains 227 ppm IAA and 60 ppm 
GA3 applications have 221 ppm IAA. 
     The formation of the absicission  layer at the stem 
point that causes fruit drop is an imbalance of auxin, 
cytokinin, and gibberellins (Chen et al., 2006). Flower 
and fruit loss is also influenced by high ethylene con­
centrations and low IAA type auxin concentrations 
and low gibberellins. Auxin and ethylene are hor­
mones that are directly related to the process of a 
drop of flowers and fruit (Bangerth, 2000). 
     Auxin is often reported to delay or to induce fruit, 
it increases cell enlargement rather than cell division. 
This observation might indicate that auxin is related 

to cell enlargement, an essential factor controlling 
f r u i t  s i z e  d u r i n g  t h e  r a p i d  f r u i t  g r o w t h  p h a s e . 
Enlargement of fruits treated with auxin seems to be 
due to cell expansion rather than cell division 
(Iglesias et al., 2007). 
     Table 1 shows that the content of zeatin type 
cytokinins and fruit kinetin that drop easily is smaller 
than retention. This is because cytokinins function to 
inhibit aging (Kieber and Schaller, 2018) so that the 
flowers and fruits of wax apple which will fall at sev­
eral stages of development have a smaller zeatin 
content compared to the retention seen in table 1. 
The cytokinin content of both zeatin and kinetin at 
the stage of development flowers and fruit of wax  
a p p l e  w a s  t h e  h i g h e s t  a t  t h e  f r u i t  s e t  s t a g e . 
According to Chen (1983), the cytokinin content 

Table 1 ­ The content of several hormones at the stage of development fruit of wax apple var. Citra

The number followed by the same letter in the same column for each fruit development is not significantly different from the t­test at 
p<0.05.

Treatment
Flower and fruit development

Bud 
development

Anthesis
Fruit 
Set

Fruit 
development

Fruit  
maturation

Fruit  
Ripening

IAA (ppm) 
   Retention 69.50 a 33.72 a 47.40 a 57.02 a 42.86 a 42.10 a
   Drop easily 1.42 b 0.73 b 0.68 b 1.22 b 0.78 b 0.41 b
Zeatin (ppm)
   Retention 2.18 a 2.25 a 3.29 a 2.19 a 2.59 a 2.04 a
   Drop easily 0.17 b 0.50 b 0.66 b 0.36 b 0.03 b 0.46 b
Kinetin (ppm)
   Retention 4.36 a 2.46 a 11.31 a 3.17 a 3.30 a 3.93 a
   Drop easily 2.16 b 1.38 b 2.96 b 3.05 a 2.75 a 2.39 a 
GA3 (ppm)
   Retention 79.65 a 68.08 a 90.47 a 68.25 a 63.45 a 57.72 a
   Drop easily 28.63 b 16.13 b 20.14 b 26.69 b 17.57 b 8.97 b
ACC (ppm)
   Retention 19.18 b 17.26 b 14.21 b 14.13 b 13.31 b 12.14 b
   Drop easily 48.39 a 38.09 a 37.99 a 35.75 a 34.14 a 30.92 a

Table 2 ­ Total sugar content and starch content on stages of wax apple flower and fruit development

The number followed by the same letter in the same column each fruit development is not significantly different in the t­test at the level 
of p<0.05.

Treatment
Flower and fruit development stage

Bud  
development

Anthesis
Fruit 
set

Fruit  
development

Fruit  
maturation

Fruit 
ripening

Total sugar content (%)
   Retention 6.87 a 8.72 a 11.38 a 23.35 a 28.93 a 32.59 a
   Drop easily 5.80 b 7.60 b 8.60 b 20.61 b 26.36 b 28.66 b
Starch content (%)
   Retention 17.23 b 16.29 a 14.52 b 13.11 b 11.02 b 8.77 b
   Drop easily 17.90 a 16.40 a 15.80 a 13.89 a 12.62 a 11.21 a



Wukir Tini et al. ‐ Hormone endogenous causes flower and fruits drop

57

increased in mango flowers maximum at 10 days 
after anthesis and decreased gradually up to 50 days 
after anthesis. This is consistent with Trueman 
( 2 0 1 1 ) ,  t h a t  h i g h  c y t o k i n i n  c o n c e n t r a ti o n s  i n 
macadamia fruit are retention. Cytokinins are pro­
duced in roots and young fruit (Pratima and Chawla, 
2019). 
     Table 1 shows that the GA3 content in several 
stages of flower and fruit development will fall lower 
than the retention of flowers and fruit. The GA3 con­
tent in fallen fruit was lower than that in retention 
(Bains et al., 1997). The role of GA3 is able to stimu­
late plant growth and flowering, increase flowering 
and reduce drop flower (Budiarto and Wuryaningsih, 
2007). According to Kurniawati and Hamim (2009), 
gibberellin and auxin can support fruit retention by 
inducing the enzyme α­amylase to hydrolyze starch 
to sugar that is needed for fruit growth and develop­
ment (Subiyanto, 1991). This can be seen in Table 1 
that the increased auxin content also increases the 
gibberellin content in retention flowers and fruits 
compared to drop easily and in Table 2 flowers and 
fruits retention have a higher total sugar content 
than drop easily. 
     The ACC content of wax apple flowers and fruits 
that drop easily is higher than the retention of flow­
ers and fruits are seen in Table 1. This is because the 
ACC which is an ethylene precursor makes the drop 
of flowers or fruits become higher (Wang et al., 
2002). The mango ACC content that drops easily is 
higher than that of retention (Sakidin et al., 2011). 
The ACC content of Gadung 21 and Lali Jiwo cultivars 
which drop easily higher at the age of 3, 9, 12 days 
after anthesis are 26.81, 35.78, 43.41 (10­1 mg g­1) 
sample fresh weights and 29.13, 29.35, 35.79 (10­1 
mg g­1) sample fresh weight. The ACC content of 
Gadung 21 and Lali Jiwo cultivars with age retention 
of 3, 9, 12 days after anthesis is 26.81; 35.78; 43.41 
(10­1 mg g­1) fresh sample weights and 10.13; 13.66; 
11.94 (10­1 mg g­1) sample fresh weights (Sakhidin et 
al., 2006). 
     F l o w e r  a n d  o v a r y  a b s c i s s i o n  o c c u r  i n  A Z ­ A 
(Abscission Zone) located between branches and 
flower stalks. Absence in the AZ­A zone starts from 
the fruit set period and this negative effect is regulat­
ed by the content of gibberellins in the ovaries. 
Fruitlet abscission during fruit drop in June at the end 
of the fruitset period on AZ­C which is located in the 
petals, between the flower disks and the ovarian 
wall, and highly dependent on carbohydrate avail­
ability. Sugar in mature leaves is transported for fruit­

let growth and activates AZ­C (Iglesias et al., 2007). 
     According to Iglesias et al. (2007), the lack of car­
bon in fruitlets induces an increase in abscisic acid 
(ABA) and ACC (1­Aminocyclopropane 1­Carboxylic 
Acid) which are ethylene precursors. These precur­
sors are then oxidized to ethylene (C2H4) and release 
of gases that cause fruit abscission. In contrast to the 
development of fruitlets, in the process of cooking 
the fruit accumulation of sugar in ripe fruit has a role 
to induce the activation of abscission  before harvest. 
The balance between C2H4 as a process accelerator, 
and auxin (AUX) as an inhibitor, is one of the main 
factors in the regulation of ripe fruit abscission. 
Synthesis of auxin in young leaves and transported to 
adult fruit as an inhibition inhibitor that protects AZ 
from high C2H4 content. The role of the regulation of 
jasmonic acid (JA) in fruit reduction is thought to be 
mediated through the stimulation of C2H4 biosynthe­
sis. The balance between AUX and ABA in mature 
fruits is also important in determining the sensitivity 
of AZ­C for abscission stimulus because ACC is an 
ethylene precursor (Wang et al., 2002). 
     Fruit abscission that occur during fruit develop­
ment due to the active abscission zone. The process 
is induced by several environmental factors, competi­
tion in the use of assimilates, and internal hormone 
content. The abscission zone on the mango is located 
on the fruit stalk with a distance of several mm from 
the fruit concave (where the fruit is attached to the 
fruit stalk). From the biochemical and molecular 
aspects, abscission occurs due to the active enzyme 
ß­1,4­endoglucanase (EG) and polygalacturonase 
(PG). The two hydrolase enzymes are involved in 
damage to plant cell walls that are responsible for 
the drop of flowers and fruits. The specificity of the 
abscission zone in responding to organ drop depends 
on the sensitivity of the layer to ethylene (Bonghi et 
al., 2000). 
     Control of fruit growth and abscission in oranges 
is due to three regulatory factors: genetic, metabolic, 
and environmental. All three of these affect hormon­
al signals in citrus plants (Iglesias et al., 2007). 
Overall, these studies show that a complex set of 
hormonal interactions occur during fruit develop­
ment. Thus, gibberellins (GAs) and cytokinins are 
generally considered positive fruit growth regulators 
while auxin has been reported to act as a growth 
stimulator and also as an abscess agent. Abscisic acid 
(ABA) and ethylene have been involved in several 
ways in an abscess. Concentrations of IAA and GA3 in 
fruit and fruit stalks that drop easily are lower than 



58

Adv. Hort. Sci., 2021 35(1): 53­60

those in fruit retention and fruit stalks, fruits that will 
fall out have high abscisic acid content. Drop fruit is 
also caused by an increase in ethylene production. 
     Table 2 shows that the flower and fruit drop had a 
lower total sugar content but a higher starch content 
than the retention. This is following Stopar et al. 
(2001), apples that drop easily have higher starch 
content and lower sugar content compared to reten­
tion. Mangoes that pre­abscission have a lower total 
sugar content and a higher starch than retention 
(Sakhidin et al., 2011). 
     Total sugar content in flower and fruit develop­
ment of wax apple var. Citra of bud development, 
anthesis, fruit set, fruit development, fruit matura­
tion, and fruit ripening stages 5.8, 7.6, 8.6, 20.16, 
26.36, 28.66% lower in fruits that drop easily with 
fruit retention of 6.87, 8.72, 11.38, 23.35, 28.93, 
32.59%. This is in accordance with Rai et al., (2008), 
carbohydrate content (total sugar) in leaves in flower 
branches and mangosteen fruit which is lower (40.3 
and 52.3 mg g­1 leaf dry weight) compared to leaves 
in branches that are flower and fruit retention (41.2 
and 59.1 mg g­1 leaf dry weight). The retention of glu­
cose, fructose, and inverted sugar of wax apple fruit 
was as follows: 8.9%, 8.9%, 8.7% var. Giant Green, 
9.83%, 9.9%, 9.6% var. Masam manis pink, and 
9.61%, 9.6%, 9.3% var Madu red (Khandaker et al., 
2011). This shows that the drop of flowers and fruit is 
associated with a low supply of carbohydrates. 
Limited carbohydrate sources affect the formation 
and development of fruit (Pawar and Rana, 2019). 
     Increasing the rate of photosynthesis is very 
important to produce carbohydrates during the 
development of fruit sets (Iglesias et al., 2002). The 
limited supply of photosynthate and nutritional sta­
tus of plants can limit the number of flowers that 
develop into fruit that can be harvested (Rai et al., 
2008). In oranges, carbohydrate deficiencies produce 
young fruit abscess by triggering an increase in ACC 
levels (Gómez­Cadenas et al., 2000). Auxin applied to 
trees that have yellow leaves due to low carbohy­
drate cannot prevent pre­harvest loss (Sakhidin et al., 
2006). 
     Table 2 shows that the starch content in flower 
and fruit development stages of bud development, 
anthesis, fruit set, fruit development, fruit matura­
tion, and fruit ripening 16.29, 14.52, 13.11, 11.02, 
8.77% in fruit retention. The starch content in wax 
a p p l e  i s  g e tti n g  s m a l l e r  a s  t h e  f r u i t  d e v e l o p s . 
According to Mureşan et al. (2015), the starch con­
tent was reduced in the early stages of fruit develop­

ment in the 3 apple varieties studied, then the starch 
concentration increased significantly from 35 to 65 
days after anthesis. Starch concentration gradually 
decreases as the fruit ripens. This can be seen in 
Table 2 that the starch content during the develop­
ment of the wax apple fruit is seen to decrease from 
flower buds to fruit maturity, and in fruits that drop 
easily the starch content is higher than that of reten­
tion. 
     It was concluded the content of IAA, zeatin, 
kinetin, GA3, and total sugars at several stages of the 
flower and fruit wax apple which drop easily lower 
than that of retention and the ACC content and 
starch are higher in fruit which drops easily than 
retention. The endogenous hormone content of wax 
apple flower and fruit that drop easily are as follows 
IAA 0.41 to 1.42 ppm, zeatin 0.03 to 0.66 ppm, 
kinetin 1.38 to 2.96 ppm, GA3 8.97 to 28.63 ppm, and 
ACC 30.92 to 48.39 ppm. The wax apple fruit that 
retention IAA content of 30.92 to 48.39 ppm, zeatin 
2.04 to 3.29 ppm, kinetin 2.46 to 11.31 ppm, GA3 
57.72 to 79.65 ppm, and ACC 30.92 to 48.39 ppm. 
The total sugar content of wax apple flower and fruit 
which drop easily from 5.8 to 28.66% is lower than 
the retention rate of 6.87 to 32.59%. The content of 
fruit starch that drops easily is 11.21 to 17.9% higher 
than the retention of 8.77 to 17.23%. Actions that 
can be taken to prevent the drop of wax apple fruit 
by giving natural endogenous hormones contained in 
other plant materials. This can be done after knowing 
the content of auxin, zeatin, kinetin, gibberellins, and 
ACC in wax apple fruit that drop easily or retention. 
 
 
Acknowledgements 
 
     The research was supported by research funds 
from the Directorate of Research and Community 
Service, Ministry of Education and Culture Doctoral 
Dissertation Research Scheme for the 2020 Budget 
Year through a Decree of the Chairperson of the 
Research and Community Service Institute, Jenderal 
Soedirman University Number:  Kept. 631/UN23.18/ 
PT.01.05/ 2020. 
 
 
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