Peruvian Journal of Agronomy 
http://revistas.lamolina.edu.pe/index.php/jpagronomy/index

RESEARCH ARTICLE

Received for publication: 30 September 2020
Accepted for publication: 20 January 2021

ISSN: 2616-4477  
© The authors. Published by Universidad Nacional Agraria La Molina

DOI: http://dx.doi.org/10.21704/pja.v5i1.1670

Control of Botrytis cinerea Pers. in ‘Okitsu’ Satsuma mandarin by biological 
and chemical fungicides in Huaura, Peru

Control de Botrytis cinerea Pers. en mandarina Satsuma cv. ‘Okitsu’ mediante 
fungicidas biológicos y químicos en Huaura, Perú

Denis Paolo Cáceres Candia1; Alejandro Risco Mendoza1; Patricia Elena Quiroz-Delgado1; Walter 
Eduardo Apaza-Tapia1*

*Corresponding author: wapaza@lamolina.edu.pe

*https://orcid.org/0000-0001-7510-8866

Abstract

The flowers blight caused by Botrytis cinerea Pers. is among the most important citrus diseases, especially in 
cultivars whose flowering coincides with the humid seasons of the year. As a result of the pathogenic features 
of this fungus and the complex nature of its control, it is necessary to establish a correct plan for the usage 
of highly efficient fungicides. The study aimed to evaluate the effect of four chemical fungicides, such as 
Captan (0.25%), Propineb (0.25%), Fludioxonil + Cyprodinil (0.05%), and Iprodione (0.15%); as well as the 
effect of a biological fungicide, such as Melaleuca alternifolia extract (0.1%), on Botrytis cinerea Pers. Two 
phases were established: the first, under laboratory conditions of Department of Plant Pathology of National 
Agrarian University-La Molina (UNALM), evaluated the effect on mycelial inhibition at 1, 3, and 7 days after 
inoculation with poisoned potato dextrose agar medium. The second, under field conditions (Sayan - Huaura), 
evaluated the effect on incidence of the disease in flowers. In the field condition, two applications, incidence, 
and humid chambers were evaluated. The yield was estimated by counting the fruits. The results showed that, 
under laboratory conditions, Captan, Fludioxonil + Cyprodinil, and Iprodione exhibited high efficacy in the 
control of B. cinerea. However, under field conditions, Fludioxonil + Cyprodinil and Iprodione exhibited a 
significant control of B. cinerea. A similar trend was obtained for the yield estimates.

Key words: Flowers blight, Botrytis cinerea, mandarin, Satsuma Okitsu, fungicides.

Resumen

El tizón de las flores causado por Botrytis cinerea Pers. es una de las enfermedades más importantes en 
el cultivo de cítricos, especialmente en aquellos cultivares cuya floración coincide con épocas húmedas 
del año. Debido a las características patogénicas de este hongo y a la complejidad de su control, resulta de 
suma importancia establecer un correcto plan de uso de fungicidas de alta eficacia. El presente trabajo de 
investigación tuvo como objetivo evaluar el efecto de cuatro fungicidas de origen químico; Captan (0,25%), 
Propineb (0,25%), Fludioxonil + Cyprodinil (0,05%) e Iprodione (0,15%), y uno de origen biológico; Extracto 
de Melaleuca alternifolia (0,1%). Se establecieron dos fases; la primera bajo condiciones de laboratorio 
(UNALM) evaluando el efecto en la inhibición micelial a los 1,3 y 7 DDI con la metodología de medio PDA 
envenenado; y la segunda bajo condiciones de campo (Sayán-Huaura) evaluando el efecto en la incidencia de 
la enfermedad en flores. Para esta segunda fase se determinó realizar dos aplicaciones y se evaluó la incidencia 
en campo mismo y en cámaras húmedas. Por último, se estimó la producción bajo la metodología de conteo 

1 Universidad Nacional Agraria La Molina. Facultad de Agronomía, La Molina, Lima, Perú. Email: denispcc123@gmail.com, 
alejandrorisco@lamolina.edu.pe, patriciaquiroz@lamolina.edu.pe, wapaza@lamolina.edu.pe

How to cite this article:
Cáceres, D., Risco, A., Quiroz-Delgado, P., & Apaza-Tapia, W. (2021). Control of Botrytis cinerea Pers. in ‘Okitsu’ 
Satsuma mandarin by biological and chemical fungicides in Huaura, Peru.  Peruvian Journal of Agronomy, 5(1), 18–24. 
http://dx.doi.org/10.21704/pja.v5i1.1670

Patricia
Sello



D. Cáceres; A. Risco; P. Quiroz-Delgado; W. Apaza-Tapia
Peruvian Journal of Agronomy 5(1): 18–24 (2021)

19

Introduction

Citrus fruits is among the main agricultural export 
products in Peru and the world demand for citrus 
fruits has increased in recent years. In 2017, the export 
of citrus fruits in Peru was approximately 143,000 
tons, thus positioning Peru as the seventh worldwide 
exporter of citrus fruits. In addition, we consolidated 
our position as the leading citrus fruit exporter in 
America by surpassing countries such as Chile, 
United States of America, and Argentina. (Ministerio 
de Comercio Exterior y Turismo [MINCETUR], 
2018).

The weather condition of the Peruvian coast 
is highly temperate and relatively humid. As a 
consequence of this condition, citrus fruits are 
affected by pests and diseases throughout their crop 
cycle. For this reason, in the main citrus production, 
chemical control method is the most adopted method 
for better pest control, with less time and high 
efficiency (Colonia, 2013). 

During the flowering season of citrus and many 
other crops, “Gray mold” or “Flower blight,” 
caused the fungus Botrytis cinerea Pers., is the most 
important disease. This fungus infection causes petals 
necrosis which are covered with mycelium and gray 
spores under wet conditions (Benito et al., 2000). 
Infected flowers often induce fruit dropping and 
injury to developing fruit which reduces the yield and 
diminishes the fruit quality (Castro et al., 2000).

For the control of this disease, different fungicides 
are applied, among which some are no longer effective 
(Llanos & Apaza, 2018; Pappas and Elena, 1992). 
In the province of Huaura, fungicides with different 
active principles are used to control gray mold 
disease in citrus fruits, among them are Carbendazim, 
Captan, or Propineb.

The study aimed to determine the effect of different 
chemical fungicides and one biological fungicide 
on the development of B. cinerea under field and 
laboratory conditions. Furthermore, profitability was 
evaluated during a production campaign through the 
use of these proposed fungicides.

Materials and Methods

The present research was carried out in two phases: 
(i) the laboratory phase was performed in the 
Diagnosis Clinic of Agronomy Faculty, Department 
of Plant Pathology of National Agrarian University 
- La Molina (UNALM), Lima state of Peru; (ii) the 
field condition phase was performed in the citrus 
production fields of “El Chilco” farm located in Santa 
Rosa town, Sayan district, Huaura province, Lima 
state, Peru. To evaluate the effect of the treatments on 
incidence of B. cinerea, the products were applied to 
‘Okitsu’ Satsuma mandarin plants.

Tangerine flowers with symptoms of B. cinerea 
were collected and, using a hypodermic syringe, 
structures of the fungus (mycelium and spores) 
were collected and placed in sterilized Petri dishes 
containing potato dextrose agar (PDA) medium. The 
plates were incubated at 25°C for four days. When 
the pathogen colony attained a growth greater than 
50% of the plate diameter, it was visualized with a 
microscope to identify its morphology. From the 
same plates, some portion of PDA medium with 
structures of the fungus was transferred to another 
plate containing a sterile culture medium in order to 
obtain a pure colony of B. cinerea.

The fungicide test was performed using the 
poisoned food technique. In brief, PDA culture 
medium was prepared and poured into Erlenmeyer 
flasks in similar quantity (100 mL) and then sterilized 
in an autoclave. 

Six experimental treatments were performed in 
this study, which correspond to evaluation of four 
chemical fungicides, one biological fungicide, and 
one control (control without fungicide) (Table 1). 

The culture medium was poisoned before it 
reached an approximate temperature of 45°C. It was 
incubated at room temperature until it solidified. Each 
treatment performed in four replicates (4 plates). A 
portion of 0.6 cm diameter of PDA medium extracted 
from the growth zone of the pure colony was placed 
in the central part of each plate containing solidified 
poisoned PDA medium. For control, only portions of 

de frutos. Los resultados demostraron que a nivel in vitro los fungicidas químicos; Captan, Fludioxonil + 
Cyprodinil e Iprodione presentaron alta eficacia en el control de B. cinerea; sin embargo, bajo condiciones de 
campo solo los fungicidas; Fludioxonil + Cyprodinil e Iprodione tuvieron un porcentaje de control importante 
frente a B. cinerea. Resultados similares se obtuvieron en el estimado de producción.

Palabras clave: Tizón de las flores, Botrytis cinerea, mandarina, Satsuma Okitsu, fungicidas.



Control of Botrytis cinerea Pers. in ‘Okitsu’ Satsuma mandarin by biological and chemical fungicides in Huaura, Peru

January - April 2021

20

PDA medium without a colony of the fungus were 
used following the same procedure above. The seeded 
plates were conditioned in an incubator at 25°C.

Mycelial growth was measured at 1, 3, and 7 days 
after inoculation (DAI). Growth of the fungus colony 
was measured through the distance from end of the 
initial inoculum disk. Average diameter of mycelium 
growth (mm) in the Petri dish with poisoned PDA 
and percentage of growth inhibition (PIC) for each 
treatment were determined following standard 
procedures. The experimental design was completely 
randomized with four replicates. Normality analysis, 
variance homogeneity, and Tukey’s mean comparison 
test at 95% confidence level (α = 0.05) were performed 
using Minitab statistical program v18. 

The second phase, under field condition, was 
performed in a commercial ‘Okitsu’ Satsuma 
mandarin (Citrus reticulata) field grafted on 
Citrumelo rootstock, which is four years old, during 
the flowering and fruit set season of 2019 campaign. 
This field was under unconventional agronomic 
management, with advancement of the phenological 
stages to obtain early harvests and flowering that 
coincided with the coldest and wettest times of the 
year. 

Two applications were made at an interval of 
10 days (6th and 16th of May, 2019) using a 20 L 
capacity sprayer backpack. 5 L of water was used for 
the application of the treatments for each plant. The 
fungicides used in this phase are shown in Table 1. 
The treatments, except Timorex Gold and control, 
were mixed with Aquacid (pH regulator) at a dose of 
0.1 mL/L. 

The trees were spaced by 6 meters between lines 
and 4 meters between plants. A tree of ‘Okitsu’ 
Satsuma mandarin was considered as a sampling 
unit. Each treatment consisted of four trees (four 
replicates). In each tree, 25 inflorescences were 
evaluated per quadrant of the tree, while five flowers 
per tree quadrant were evaluated in a humid chamber. 

Incidence (%) of B. cinerea was measured in 
citrus fields and humid chambers. With the incidence 
data, area under the disease progress curve (AUDPC) 
and relative area under the disease progress curve 
(AUDPCr) were calculated. AUDPCr was calculated 
by dividing ABCPE by number of days of the 
experiment and then multiplied by 100 (Campbell & 
Madden, 1990). AUDPC was calculated as follows: 

∑ = summation of n observations
n = I-th observation
yi = proportion of disease (incidence) affected in the i-th 
observation
ti = time (days) after the I-th observation. 

For crop yield estimation, the curdled fruit was 
counted and relationship between the number of 
fruits per plant and yield per plant was used. For this 
estimation, the formula proposed by Otero (2004) for 
Satsuma mandarin was applied. 

The experimental design adopted was Randomized 
Complete Block Design (RBCD), with six treatments 
and four replicates. For the evaluated variables, 
normality, analysis of variance homogeneity, and 
Tukey’s mean comparison test were performed 
at 95% confidence level (α = 0.05) using Minitab 
statistical program v18.

Results and Discussions

The highest PIC values (%) at 7 DAI were obtained 
by Captan (100%) and Iprodione (100%) treatments, 
followed by Fludioxonil + Cyprodinil (94.1%) 
treatment. However, Propineb (0%), tea tree extract 
(0%), and control (0%) treatments were statistically 
equal at 1, 3, and 7 DAI (Table 2). The result at 7 DAI 
under laboratory condition is shown in Figure 1 for 
each treatment.

Treatment Active Ingredient Product Doses
T0 Control ---- ----
T1 Captan Forsem 80 PM 0.25 %
T2 Propineb Syl 70 PM 0.25 %
T3 Fludioxonil + Cyrprodinil Switch 62.5 WG 0.05 %
T4 Iprodione Fobos 50 PM 0.15 %
T5 Tea Tree Extract Timorex Gold (20 %) 0.1 %

Table 1. Treatment with fungicides doses (%), in vitro test, and control test for the control of Botrytis cinerea in citrus.



D. Cáceres; A. Risco; P. Quiroz-Delgado; W. Apaza-Tapia
Peruvian Journal of Agronomy 5(1): 18–24 (2021)

21

The best treatments in the poisoned PDA medium 
test were Captan and Iprodione treatments, both of 
which achieved a 100% PIC. However, in Figure 1, 
it can be seen that B. cinerea managed to infect 
the initial mycelial disc following treatment with 
Captan. Therefore, it can be concluded that Iprodione 
treatment was the best, since it completely inhibited 
the growth of B. cinerea. This latter event can be 
explained by the fact that Iprodione exhibits a local 
and contact systemic action, unlike Captan which 
exhibits only a contact action (Williamson et al., 
2007). 

Ortiz (2009) evaluated (via in vitro conditions) 
different fungicides for the of control B. cinerea 
isolated from artichoke heads and demonstrated that 
mycelial growth rate was 0 cm in Petri dishes using 

Iprodione treatment and 0.37 cm using Propineb 
treatment. This result is similar to the result obtained 
in this study. However, in the same experiment, 
a growth rate of 0.58 cm was observed following 
Captan treatment, which differs from the result of the 
present study. 

Similar results were observed in the in vitro 
efficacy evaluation of fungicides for the control of 
B. cinerea isolated from rose cultivation, in which 
treatment with Captan allowed mycelial growth of 
2.5 cm, while Propineb allowed a mycelial growth of 
8.3 cm at 7 DAI in Petri dishes with artificial culture 
medium (Restrepo, 2010). 

Panebianco et al. (2005) conducted a poisoned 
PDA medium test using 302 isolates of B. cinerea 
from grapes fruits and found 10.3% specific resistance 
to Iprodione and no isolate resistant to Fludioxonil. 

Treatment with Melaleuca alternifolia extract 
achieved a PIC of approximately 35% for the first 
two evaluations. Antonov et al. (1997) evaluated the 
inhibition of conidia germination and mycelial growth 
of B. cinerea with natural products and found that, at 
a concentration of 1%, tea tree oil achieved complete 
inhibition of conidia germination and growth of 
germinative tube by 92%. Yu et al. (2015) mentioned 
that the fungicidal action of tea tree oil against B. 
cinerea is mainly due to two terpenes (terpinen-4-
ol and 1,8-cineole) which act by affecting the cell 
membrane and organelles of the fungus, respectively. 
For the second phase, under field condition, incidence 
of ‘Okitsu’ Satsuma mandarin flowers in field and 
humid chambers was evaluated.

Figure 2 relates the incidence data obtained during 
assessments to the relative humidity (RH) data of 
the area during the assessments. This figure clearly 

Treatments
Evaluation Dates

1 DAI 3 DAI 7 DAI

T0 Control 0.0% D 0.0% D 0.0% C

T1 Captan 100.0% A 100.0% A 100.0% A

T2 Propineb 59.6% B 60.0% B 0.0% C

T3 Fludioxonil + Cyprodinil 100.0% A 100.0% A 94.1% B

T4 Iprodione 100.0% A 100.0% A 100.0% A

T5 Tea Tree Extract 31.6% C 36.5% C 0.0% C

α: 0.05 CV: 2.35% CV: 2.26% CV: 3.29%

Table 2. Percentage growth inhibition (PIC) of Botrytis cinerea by treatment under laboratory condition.

Note: DAI: Days after inoculation; Equal letters have no statistical difference in Tukey (α: 0.05); CV: coefficient of variability.

Figure 1. Mycelial growth (mm) of Botrytis cinerea from 
each treatment in poisoned PDA medium at 7 days after 
inoculation.



Control of Botrytis cinerea Pers. in ‘Okitsu’ Satsuma mandarin by biological and chemical fungicides in Huaura, Peru

January - April 2021

22

shows the difference between the curve drawn by 
control and other treatments. 

In addition, how the trend line of RH increased 
according to the passage of time was clearly 
illustrated and this coincides precisely with increase 
in incidence of the disease in each of the treatments. 
At very humid climate condition, B. cinerea was 
able to establish itself on citrus flower petals and 
stamens. This disease can kill single flowers, entire 
inflorescences, or initiate a regressive death that 
advances by several centimeters at the peduncle 
(Mooney, 2001). 

In the analysis of the test under field condition, 
a relationship between RH and incidence of B. 
cinerea in ‘Okitsu’ Satsuma mandarin flowers was 
determined. It was observed that the incidence of 
the pathogen increased considerably when RH is 
approximately 90%. This coincides with La Torre and 
Rioja (2002), who report that the optimal conditions 
for B. cinerea infection in many crops is 20°C and 
RH above 90%. Castro et al. (2000) mentioned that, 
for citrus cultivation, flower buds or recently curdled 
fruits are the most susceptible to attack by B. cinerea 
and that the attack occurs only under very humid 
condition and cold temperature (18°C). 

To determine the effectiveness of each treatment, 
AUDPC and AUDPCr were determined. The results 
obtained are shown in Table 3. Based on AUDPCr, 
the best treatment was Fludioxonil + Cyprodinil, 
with 2.9% AUDPCr, followed Iprodione, with 4.24% 
AUDPCr. However, based on the statistical test 
applied, these results were non-significantly.

The control treatment presented the highest 
percentage AUDPCr (13.32%), which turned out to 
be significantly different from the other treatments. 
Eyzaguirre (1972) compared seven fungicides for 
the control of B. cinerea in open flowers of Valencia 
orange and found that the disease control is better 
achieved with systemic/curative action products 
than with contact/preventive action products. This 
coincides with our evaluation under field conditions, 
since Fludioxonil + Cyprodinil had systemic and 
curative action, unlike the other treatments that 
presented mainly contact fungicide characteristics. 

Treatment with Captan under field condition 
(Table 3), unlike under laboratory condition, did not 
achieve such a high percentage of control; however, 
it maintained a significant difference with control 
when evaluated in terms of AUDPC. Captan, like 
most old fungicides, has maintained its effectiveness 
in spite its intensive usage. This is due to the fact that 
it has multiple mode of actions and hardly generates 
resistance. However, the control achieved by Captan 
is not totally efficient, since it has low biochemical 
specificity and is limited to a protective action on the 
applied crop surface (Mondino, 2002). 

Propineb, like Captan, is among the first groups 
of fungicides in the market, which are characterized 
by multiple sites of action. These two treatments are 
highly recommended fungicides for the control of 
gray rot in crops such as grapevines (Trimmer et  al., 
2003) and are still recommended for this purpose 
till date, although only for preventive purpose and 
within a plan of rotating applications.

Figure 2. Progress of the incidence of B. cinerea in Satsuma var. Okitsu mandarin flowers for each treatment during the 
evaluation period and its relationship with relative humidity of the area.



D. Cáceres; A. Risco; P. Quiroz-Delgado; W. Apaza-Tapia
Peruvian Journal of Agronomy 5(1): 18–24 (2021)

23

In this study, tea tree oil treatment showed a 
deficient control under field condition. In the technical 
data sheet of products authorized for our country, 
it does not register a recommended dose for citrus 
fruits; however, 200 mL/cil was determined due 
to water used in the area for fungicide application, 
which is 2000 liters per hectare, as a dose of 2 liters 
per hectare. The latter would be used if the cost, in 
comparison with other alternatives, is higher. Based 
on personal experience, in blueberry crop, the 
optimum dose for the control of B. cinerea is 750 mL 
/ cil, which is remarkably high compared to that of 
the present study. As at the time, it was determined 
that the possible cause of the low control was due to 
the low dose applied. 

The incidence of B. cinerea in humid chambers 
was also evaluated for three opportunities during the 
flowering season, which occurred throughout the 
month of May 2019. The condition of these humid 
chambers was of a RH percentage close to 100%. 
Incidence results of the three evaluations performed 
are shown in Table 3. 

In the three evaluations performed, Fluidoxonil 
+ Cyprodinil is the only treatment that presents a 
significant difference with control. For the second 
evaluation performed on May 22nd Iprodione 
treatment presents a significant difference with 
control. Finally, estimated average yield per treatment 
and approximate profitability of each treatment were 
determined according to the formula proposed by 
Otero (2004) and number of trees per hectare in the 
field tested were 416 in total. The results are shown 
in Table 4.

By analyzing Table 4, it was determined that, 
for all treatments, it is cost effective to make two 
applications for the control of B. cinerea during the 
flowering season.

It is important to mention that the present 
investigation was performed in an advanced field of 
‘Okitsu’ Satsuma mandarin, where the beginning of 
harvest is in the middle of December. Based on this, 
the flowering coincided with cold and humid climates 
optimal for the development of B. cinerea, for which 

Treatments AUDPC AUDPCr
Incidence of flowers with Botrytis cinerea in humid 

chambers

2020, May 13 2020, May 22 2020, May 29
T0 Control 3.86 A 13.32% 51.25% B 90.00% A 56.25% AB
T1 Captan 2.11 B 7.26% 46.25% AB 86.25% A 47.50% ABC
T2 Propineb 1.78 BC 6.13% 33.75% BC 80.00% A 57.50% A

T3
Fludioxonil + 

Cyprodinil
0.84 D 0.029 18.75% C 18.75% B 21.25% C

T4 Iprodione 1.23 CD 4.24% 33.75% BC 37.50% B 30.00% BC
T5 Tea tree oil 1.94 BC 0.0667 60.00% AB 90.00% A 50.00% AB
 α: 0.05 CV:17.77%  CV: 24.6% CV: 16.8% CV: 27.2%

Table 3. AUDPC, ADPCEr, and incidence of citrus flowers in humid chambers with Botrytis cinerea in Satsuma 
mandarin treated with different fungicides in field condition.

Note: Means with different letters have statistical difference (Tukey α: 0.05); AUDPC: Area under disease progress curve; AUDPCr: 
Area under disease progress curve relative.

Treatment
Field (Tn/

ha)
Cost (US$) Doses xha

Application cost 
(US$/ha)

Profitability (US$/ha)

Testigo 34.65  $34,650.00

Captan 37.14 $14.93 5.0 $74.65 $36,990.70

Propineb 34.8 $10.45 5.0 $52.25 $34,695.50

Fludioxonil + Cyprodinil 40.59 $223.88 1.0 $223.88 $40,142.24

Iprodione 39.99 $41.79 3.0 $125.37 $39,739.26

Extracto de árbol del té 36.08 $73.13 2.0 $146.26 $35,787.48

Table 4. Economic analysis of Mandarin Satsuma for each treatment according to average yield data.



Control of Botrytis cinerea Pers. in ‘Okitsu’ Satsuma mandarin by biological and chemical fungicides in Huaura, Peru

January - April 2021

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it is determined that the use of specific fungicides 
in this particular case is justified to obtain greater 
profitability.

Conclusions

Products of chemical origin (Iprodione and 
Fludioxonil + Cyprodinil) are the best for the control 
of B. cinerea in ‘Okitsu’ Satsuma mandarin based 
on the parameters evaluated in this study: mycelial 
PIC, field and wet chamber incidence, and economic 
analysis. On the other hand, the product of biological 
origin used in this study does not exhibit a good 
control of the disease.

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