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Presence of Fusarium spp. complex in diseased
trees of Gmelina arborea Roxb (melina) in Ecuador
Presencia del complejo Fusarium spp. en árboles
enfermos de Gmelina arborea Roxb (melina) en Ecuador
Submitted (09.08.2020) - Accepted (11.01.2021)
ABSTRACT
The area planted with Gmelina arborea (melina) in Ecuador has
increased in the last decade, currently this forest species is affected
by the disease "vascular wilt and stem rot", which is killing thousands
of trees in the country. Ceratocystis fimbriata is listed as the causative
agent of the disease, However, the complex symptoms and the
frequent isolation of Fusarium spp. from diseased trees, make us
suspect that this phytopathogen is involved in the pathogenesis of
melina. Koch's Postulates were applied at the greenhouse level, and
for the effect, 5 treatments based on the inoculation of 17 G. arborea
plants of 4-month-old per treatment were plated. T1 = Fusarium sp.1,
T2 = Fusarium sp.2, T3 = Fusarium sp.3, T4 = Fusarium sp.4, and T5 =
agar-agar (control). A complete randomized design (CRD) was used
and the plants were evaluated 155 days after inoculation. The
treatments Fusarium sp.1 and Fusarium sp.2 caused the largest
apparent volumes of necrosis (2.31 cm3 and 2.43 cm3), and generated
mild symptoms of disease, however they did not die, so these results
cannot be considered conclusive yet. It is necessary to continue
investigating the role of Fusarium spp. in the pathogenesis of melina.
Keywords: Apparent volume of necrosis, Koch's postulates,
pathogenicity.
RESUMEN
Carlos Belezaca-Pinargote
Ph.D. in Sciences with Mention in
Microbiology, Universidad Técnica Estatal de
Quevedo, Quevedo, Ecuador,
cbelezaca@uteq.edu.ec,
https://orcid.org/0000-0002-3158-7380
Edison Solano-Apuntes
Master in Sustainable Forest Management,
Universidad Técnica Estatal de Quevedo,
Quevedo, Ecuador, esolano@uteq.edu.ec,
https://orcid.org/0000-0002-3158-7380
Rolando López-Tobar
Magister en Manejo Forestal Sostenible,
Universidad Técnica Estatal de Quevedo,
Quevedo, Ecuador, rlopez@uteq.edu.ec,
https://orcid.org/0000-0001-8527-4710
Cinthya Morales-Escobar
Universidad Técnica Estatal de Quevedo,
Quevedo, Ecuador,
cinthya.morales2016@uteq.edu.ec,
https://orcid.org/0000-0002-0661-5191
Paola Diaz-Navarrete
Ph.D. in Sciences with Mention in
Microbiology, Universidad Católica de
Temuco, Temuco, Chile,
paola.diaz@educa.uct.cl,
https://orcid.org/0000-0003-0512-7695
Revista Científica Interdisciplinaria
Investigación y Saberes
Vol. - 11 No. 2
May - August 2021
e-ISSN: 1390-8146
78-93
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Rev. Cient. Interdisciplinaria Investigación y Saberes 11 (2) 2021
1390-8146
La superficie plantada con Gmelina arbórea (melina) en Ecuador se ha incrementado en
la última década, actualmente esta especie forestal es afectada por la enfermedad
“marchitez vascular y pudrición del fuste”, que está matando miles de árboles en el país.
Ceratocystis fimbriata está catalogado como el agente causal de la enfermedad, sin
embargo, la compleja sintomatología y el frecuente aislamiento de Fusarium spp. desde
árboles enfermos, hacen sospechar que este fitopatógeno está implicado en la
patogénesis de melina. Se aplicaron los Postulados de Koch a nivel de invernadero, y para
el efecto se platearon 5 tratamientos basados en la inoculación de 17 plantas de G.
arbórea de 4 meses de edad, por tratamiento. T1= Fusarium sp.1, T2 = Fusarium sp.2, T3
= Fusarium sp.3, T4 = Fusarium sp.4, y T5 = agar-agar (control). Se empleó un diseño
completo al azar (DCA) y las plantas se evaluaron a los 155 días después de inoculadas.
Los tratamientos Fusarium sp.1 y Fusarium sp.2 ocasionaron los mayores volúmenes
aparentes de necrosis (2.31 cm3 y 2.43 cm3), y generaron síntomas leves de enfermedad,
sin embargo no murieron, por lo que estos resultados no se los puede consideran aún
concluyentes. Se hace necesario continuar investigando el papel de Fusarium spp. en la
patogénesis de melina.
Palabras clave: Patogenicidad, postulados de Koch, volumen aparente de necrosis
1. Introduction
Melina (Gmelina arborea Roxb.) is a forest species belonging to the Lamiaceae
family, native to southwest Asia, and due to its rapid growth it has been widely
planted in the Ecuadorian Humid Tropics (THE). It is considered a timber tree of
interest to the national and international industry in the production of paper pulp,
and also has excellent characteristics for the manufacture of furniture, tertiary
products, pallets, etc. (Moya, 2004). Since the introduction of G. arborea to
Ecuador, it has become an important item for the country's economy, with a
planted area until 2015 of approximately 11458 ha, which represented 21.9% of
the 52395 ha, planted with other economically important forest species (teak,
balsa, pine, others) registered in the country (MAGAP (2016).
However, in the last five years, a complex and aggressive disease has been
affecting commercial plantations of G. arborea in Ecuador, manifesting itself with
a premature and gradual decline in the vigor of the trees, accompanied by
discoloration of the leaf system (chlorosis) and stunted growth. It can be observed
in some trees that excrete dark brown exudates from the trunk, with a strong odor
of decaying matter, indicating internal rotting of the trunk (Saltos-Sampedro,
2019).
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
Due to the presence of signs at field level and characteristics of the disease, the
phytosanitary problem detected in melina seems to be associated with fungal
microorganisms. Studies conducted by Macías-Moncayo (2019) demonstrated
the presence and pathogenicity of the ascomycete fungus Ceratocystis fimbriata,
associating it as the cause of the disease. However, periodic visits to THE
plantations report diseased trees with symptoms different from those previously
described by Macías-Moncayo (2019), leading to the suspicion that two diseases
are occurring at the same time in G. arborea forests, probably caused by different
phytopathogens (Belezaca-Pinargote et al., 2021).
This distinctive disease manifests itself with rotting of the stem, and the
consequent death of the standing trees. The rotting generates circular, oval or
elongated areas in the bark, acquiring a cracked appearance of dark brown to
black color, with a canker typology, whose necrotic area can cover the
circumference of the tree. The symptomatology begins with the wilting of the
leaves and subsequent drying, until they finally fall to the ground of the
plantation. Scientific literature reports that this type of symptomatology is
associated with G. arborea trees in Costa Rica, being caused by the fungus
Deuteromycete Fusarium sp., whose sexual phase is Nectria sp. (ascomycete),
(Arguedas, 2004; Murillo-Gamboa et al., 2016).
In this sense, Saltos-Sampedro (2019), Macías-Moncayo (2019), and Belezaca-
Pinargote et al. (2021) in independent research works, constantly isolated
Fusarium spp. strains from xylem tissues of diseased melina trees, so their
participation in the etiology of the disease needs to be clarified. This paper shows
the results obtained on the symptomatology, incidence and severity of the
disease in melina plantations, Fusarium spp. strains isolated and inoculated in
seedlings, and their pathogenicity capacity in the plant according to Koch's
postulates.
2. Materials and Methods
Location of experimental site. The present study was carried out in the laboratory
of Environmental and Plant Microbiology of the State Technical University of
Quevedo (UTEQ), where the collection of Fusarium spp. strains, collected from
diseased melina trees, is located. The field research was carried out in three
plantations in the parishes of San Jacinto de Buena Fe (Los Ríos Province) with an
age of 4.5 years, Santa María del Toachi and Luz de América (Santo Domingo de
los Tsáchilas Province) of 2.3 years and 2.0 years of age, respectively. The
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plantations received a very heterogeneous silvicultural management. Weed
management was done manually and chemically. The initial density and at the
time of the evaluations was different among the plantations (Table 1).
Table 1. Initial density and density detected at the time of the evaluations in three
plantations of G. arborea with different ages.
No.
Age
(years)
Initial
density
(trees ha-1)
Density at time
of evaluation
(trees ha-1)
1
4.5
1111
953
2.3
1111
840
2.0
1111
940
Symptomatological description and incidence and severity of the disease. In
each plantation, three rectangular plots of 500
m2
were delimited, within which a
tree-by-tree census was carried out, with the purpose of establishing the total
number of trees present, the number of trees with disease symptoms, dead trees
and apparently healthy trees. The equation [1] used by Belezaca-Pinargote et al.
(2018) was used for the calculation:
!"#$%&"#$'(
)
*
+
, (
#$%#á'()*%+#%,-%'.)+
#$%#á'()*%+#+/,)+
- .//
[1]
The estimation of severity was based on the visible morphological characteristics
of branches, leaves and stems of diseased trees, and then compared with
apparently healthy trees, in addition to a description of the disease
symptomatology. For this purpose, an arbitrary scale of five categories proposed
by Salas-Rodríguez et al. (2016) was applied, as detailed in Table 2.
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
Table 2. Arbitrary five-category scale proposed by Salas-Rodríguez et al. (2016) to
assess stem rot disease severity in G. arborea.
Severity
(Criterion)
Symptoms
1
Apparently healthy tree, no evidence of visible symptoms.
Initial yellowing of the crown (evident foliar wilting); the stem
may have small necrotic wounds with black exudation in places
other than where pruning has occurred; resprouting may begin.
Not all symptoms are expressed.
The tree is visibly diseased. There are canker-like lesions on the
bark with signs of rot, bark exposure and bulging, prominent
exudation; loss of more than 50% of leaf area in a progressive
pattern; regrowth is developed.
Total affectation of the individual; total absence of foliage; there
is evident loss and detachment of branches; resprouts are still
observed in some sectors of the trunk; the apparent external
rotting reaches 75% of the trunk, where the cancerous zone
(canker) is clearly manifested.
5
Completely dry, rotten tree; the wood has completely lost its
commercial value.
Isolation of Fusarium spp. strains. 3 trees with disease symptoms were sampled
in each plot. The trees were felled at ground level with the assistance of a
chainsaw and then transverse and longitudinal cuts were made in the trunk every
50 cm, with the purpose of determining the site of entry of the pathogens and
their dissemination within the tissues.
Sections of wood with evidence of necrosis were selected, stored in plastic bags
with their respective labeling, and transferred to the Environmental and Plant
Microbiology Laboratory of the UTEQ for their respective microbiological analysis.
For this purpose, the samples were conditioned as follows:
Humid chamber. Wood samples with necrotic tissues were placed in plastic
bags containing moist paper and incubated for 96 hours in conditions of high
relative humidity and constant temperature (24 ± 2 °C) at laboratory level. Once
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signs of microorganisms (mycelium, fruiting bodies, etc.) growing on the wood
were detected, with the assistance of a stereomicroscope, they were transferred
to potato, dextrose, agar (PDA) culture media under aseptic conditions.
Direct seeding in PDA culture media. Using a sharp knife, approximately 0.5 x
0.5 cm wood segments were cut from internal necrotic tissues of each diseased
tree sampled, and seeded four necrotic wood pieces in five Petri dishes containing
10 mL of PDA culture media + 0.2 mL of an antibiotic mixture (50 µg/mL penicillin
and 25 µg/mL streptomycin), (Parkinson, 1994; Massimo et al., 2015; Belezaca-
Pinargote et al., 2018), and left to incubate for 96 hours at 24±2
oC
. After this time,
the fungi developed in the culture medium were identified with the help of
dichotomous taxonomic keys, based on morphology (Von Arx, 1981; Barnett &
Hunter, 1987).
Activation of previously isolated Fusarium spp. strains. Strains were reactivated
in Petri dishes containing 10 mL of potato, dextrose, agar (PDA) culture medium
plus 0.2 mL of an antibiotic mixture (50 µg/mL penicillin and 25 µg/mL
streptomycin), under aseptic conditions, and then incubated for 8 days at 24±2
oC
(Parkinson, 1994, Suryanarayanan, 2013).
Koch's postulates. For this purpose, 4-month-old melina plants in good health,
with a stem diameter at ground level of approximately 3 cm and 60 cm in height,
from a private nursery, were used. The site to be inoculated was disinfected with
alcohol moistened cotton and the bark and xylem of the plant were compromised
by means of an inclined cut with a sterile scalpel. A colony segment (0.5 cm disk)
of the selected phytopathogen was carefully applied inside the wound, and once
the fungus was inside the plant, the wound was covered with parafilm tape.
Control plants were inoculated under the same conditions as above, with the
difference that instead of inoculating the pathogen, a segment of agar-agar
(innocuous) was applied inside the wound and the wound was closed with
parafilm tape (Massimo et al., 2015).
The plants were watered periodically according to their requirements. The
experiment was established for 155 days (5 months and 4 days), during which
time observations were made on the health status of the inoculated plants, with
the purpose of detecting the appearance of symptoms related to stem rot disease,
associated with each inoculated phytopathogen. At the end of the study, the
plants were dissected through transverse and longitudinal cuts, with the purpose
of estimating the damage or necrotic lesions in the bascular tissues of each plant,
both upward and downward, taking the inoculation site as a reference point.
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
Necrotic lesions were measured in three dimensions (height, width and depth) to
estimate the apparent area of necrosis, expressed in cm3 (Zauza et al., 2004).
Treatments and Experimental Design. A completely randomized design (CRD)
was used, consisting of five treatments: T1 = melina plants inoculated with
Fusarium sp.1, T2 = melina plants inoculated with Fusarium sp.2, T3 = melina
plants inoculated with Fusarium sp.3, T4 = melina plants inoculated with Fusarium
sp.4, T5 = uninoculated melina plants (control). For each treatment, 17 melina
plants were used (replicates).
Statistical analysis. The quantitative data obtained were analyzed using
descriptive statistical tools: mean, standard deviation, standard error, coefficient
of variation, etc. To establish the existence or not of significant statistical
differences between treatments, the data were analyzed under the analysis of
variance scheme (ANOVA) with a significance level of 95% (P < 0.05), after
checking the assumptions of normality and homoscedasticity of variances.
Subsequently, the LSD (least significant difference) test was applied, with a
significance level of 95% (P < 0.05). The SAS 9.0 statistical package for Windows
was used for this purpose.
3. Results
Symptomatology of the disease. Trees of G. arborea in early stages of the disease
show a slight chlorosis, and loss of turgor in leaves at the ends of upper branches,
with wilting characteristics. Due to vascular blockage and gradual disease
progression, growth apices dry out and branches progressively die. In diseased
trees, vigor decreases significantly compared to healthy neighboring trees, mainly
due to wilting of the photosynthetic area. Once the leaf area is compromised, as
a survival mechanism, diseased trees emit numerous epicormic shoots on the
stem, stimulated by the need for photosynthesis. However, as vascular plugging
continues to impede the ebb and flow of nutritional substances, the tree
eventually dies (Figure 1). In diseased trees it is common to observe the presence
of dark-colored fluids, released from wounds of anthropogenic origin (pruning
wounds, thinning, natural wounds, etc.), (Figure 2). It should be noted that in
diseased trees the presence of bark and/or wood boring insects is generally not
observed.
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Figure 1. Evolution of vascular wilt disease and stem rot in melina trees: A = First
symptoms characterized by leaf chlorosis (wilting) due to vascular plugging. B =
Generation of multiple epicormic shoots on the stem. C = Death of the foliar
system of the tree.
Since the introduction of G. arborea in THE production systems in the mid-1980s,
the species had not presented complex phytosanitary problems, but in the last
decade due to the increase in planted area, phytosanitary problems have become
recurrent as mentioned by Saltos-Sampedro (2019) and Macías-Moncayo (2019).
The appearance of diseases in monospecific plantations is related to
massification, the increase in planted area, the susceptibility of the species and
time, factors that, from the point of view of Forest Pathology, predispose trees to
disease (Haas et al., 2011; Bostock et al., 2014; Hughes et al., 2015).
The vascular wilt and stem rot disease in melina, presents a complex
symptomatology, similar to that reported in other economically important forest
species in the region, such as Schizolobium parahybum (Geldenhuis et al., 2004;
Belezaca-Pinargote et al., 2011), Acrocarpus fraxinifolius (Belezaca-Pinargote et
al., 2012) that destroyed entire plantations between the 1990s and 2000s, and
Tectona grandis (Belezaca-Pinargote et al., 2018; Vera et al., 2019; Belezaca-
Pinargote et al., 2020), whose disease appeared early in the past decade and
continues to eliminate thousands of trees in THE.
The behavior of G. arborea trees against the disease is not uniform, generally the
manifestation of the initial symptoms are difficult to detect, since chlorosis and
B
A
C
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
loss of turgor occurs when the xylem and bascular tissues of the trees are
irremediably compromised and necrotic, both radially and tangentially.
Defoliation, death of growth buds and drying of branches are observed in
advanced stages of the disease. The presence of natural and/or anthropogenic
wounds on the trunk is common, with abundant exudation of dark brown fluids,
with a strong odor of decomposing organic matter.
Incidence and severity of the disease. In the 2-year-old plantation, an average of
10 diseased trees and 2 dead trees per plot (500
m2
) were detected, which allowed
inferring the existence of 215 diseased trees and 45 dead trees per ha-1. In the
plots of the 2.3 year old plantation, an average of 3 diseased trees and no dead
trees were found, resulting in 60 diseased trees and zero dead trees per ha-1.
While in the 4-year plantation, 4 diseased trees and 2 dead trees were found on
average per plot, resulting in 80 diseased trees and 40 dead trees per ha-1. These
results show that disease incidence was 24.1%, 7.1%, and 21.3% for the 2-, 2.3-,
and 4-year-old melina plantations, respectively (Table 3).
Table 3. Number of apparently healthy, diseased and dead trees per ha-1 and
incidence of vascular wilt disease stem rot in three plantations of G. arborea of
different ages in the Ecuadorian Humid Tropics. Values represent the average of
three replicates, with their respective standard error.
Plantati
on (age)
Trees ha-
1
(Density)
Apparently healthy
trees ha-1
Diseased
trees ha-1
Dead
trees ha-
1
Incidenc
e (%) *
2 years
1080
820 ± 0.67
215 ± 0.25
45 ± 0.80
24.1 ±
1.15
2.3
years
840
780 ± 0.75
60 ± 0.61
0,0 ± 0.00
7.1 ±
0.95
4 years
940
740 ± 0.90
140 ± 0.40
60 ± 0.28
21.3 ±
0.87
Most of the diseased trees in the 2-year-old plantation were classified in scales 2
and 4, which indicates that 9.52% of the trees were found with the presence of
the disease, in a state of medium progress, and 7.14% were dead (scale 5). While
in the 2.3 year old plantation, diseased trees were located in scale 2 with 7.14%.
In the 4-year-old plantation, trees with different levels of disease were detected
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in scales 2, 3, 4 and 5, with 8.51%, 4.25%, 2.13% and 6.38%, respectively (Table
4).
Table 4. Severity of vascular wilt disease and stem rot per ha-1, in plantations of
G. arborea of 2, 2.3, and 5 years of age.
Plantation
(age)
Trees ha-1
(Density)
No. trees per scale *
1
5
2 years
1080
820
45
45
2.3 years
840
780
0
0
0
4 years
940
740
It is worth noting the resilience of several melina trees, which at the time of
evaluation do not show any visible symptoms of the disease; however, when they
are cut transversally and longitudinally along the trunk, the internal tissues are
completely necrotic in all directions, which makes it difficult to identify trees in
the initial stages of the disease. On the other hand, field observations show the
existence of trees to which the disease does not seem to cause major damage,
which leads to the suspicion of the presence of individuals with acceptable levels
of tolerance/resistance to the disease. This behavior would be due to the genetic
variability of individuals obtained from freely pollinated seeds (Bräutigam et al.,
2013; Inza et al., 2018), which can be exploited in future genetic improvement
programs of the species.
The incidence of the disease in the three plantations (24.1%, 7.1%, and 21.3%),
could be considered high, and a warning about the damage that can be generated
to the national melina industry, if adequate strategies for prevention and
management of the disease are not considered. Although diseased trees were
found at all levels of the proposed scale, most of them were detected in the initial
stage of the disease, but it is a matter of time before the symptomatology
progresses and the trees move to higher levels of the scale.
Isolation of Fusarium spp. After analyzing the wood sections with the aid of a
stereomicroscope, the presence of yellowish-white cottony colonies of fungal
appearance was determined. In addition, sections of necrotic wood seeded in
Petri dishes with PDA culture medium, after 96 hours of incubation, resulted in
the growth of white cottony colonies. Observations under the microscope
identified that the colonies corresponded to the fungus Fusarium (Figure 2).
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
Figure 1. Colonies of Fusarium spp. obtained from diseased trees of G. arborea,
growing on PDA culture medium.
Apparent volume of necrosis (cm3). Significant statistical differences (F=7.73;
P=0.000) were detected between the apparent volumes of necrosis generated by
the inoculated phytopathogens (treatments) on melina plants. The Fusarium sp.
1 and Fusarium sp. 2 treatments generated the highest apparent necrosis
volumes, with 2.31 cm3 and 2.43 cm3, respectively, and slightly similar to the
Fusarium sp. 4 treatment with 1.71 cm3, being statistically similar to each other,
and different from the Fusarium sp. 3 treatment. However, the control treatment
reached the lowest necrosis volume with 0.03 cm3 (Figure 3).
Figure 3. Apparent volume of necrosis generated by phytopathogenic fungi
(treatments) inoculated on 4-month-old G. arborea (melina) plants, 155 days after
a
a
c
b
c
0
0,5
1
1,5
2
2,5
3
3,5
Fusarium sp. 1 Fusarium sp. 2 Fusarium sp. 3 Fusarium sp. 4 Control
Apparent volume of necrosis (cm
3
)
Treatments
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inoculation at greenhouse level. Values correspond to the average apparent
volume of necrosis of 17 melina plants, with their respective standard error.
Total length of necrosis (cm) generated by phytopathogens. Figure 4 shows the
total length of necrosis caused by phytopathogenic fungi inoculated in melina
plants, where significant statistical differences (F=6.48; P=0.000) were detected
between the lengths of necrosis generated by the fungi. The treatments Fusarium
sp.1, Fusarium sp.2, Fusarium sp.4, produced the greatest necrosis lengths, with
10.95 cm; 12.91 cm; 9.71 cm, respectively, being statistically similar to each other,
but different from the treatments Fusarium sp.3 and Control that reached smaller
lengths, of 3.76 cm and 1.53 cm, correspondingly.
Figure 4. Total length of necrosis, generated by phytopathogenic fungi
(treatments) inoculated on 4-month-old G. arborea (melina) plants, 155 days after
inoculation at greenhouse level. Values correspond to the average apparent
volume of necrosis of 17 melina plants, with their respective standard error.
Ascending and descending necrosis length (cm). Significant statistical differences
were detected between the ascending (F=5.25; P=0.000) and descending (F=5.83;
P=0.000) necrosis lengths caused by the inoculated phytopathogens (treatments)
in melina plants. The Fusarium sp.2 treatment generated the greatest ascending
length of necrosis with 9.08 cm, being statistically superior to the other
treatments. While the Control treatment showed the lowest value with 1.05 cm
of necrosis length (Table 5).
a
a
b
a
c
0
2
4
6
8
10
12
14
16
Fusarium sp. 1 Fusarium sp. 2 Fusarium sp. 3 Fusarium sp. 4 Control
Necrosis length (cm
3
)
Treatments
Carlos Belezaca-Pinargote
Edison Solano-Apuntes
Rolando López-Tobar
Cinthya Morales-Escobar
Paola Diaz-Navarrete
Table 5. Ascending and descending length of necrosis (cm) generated by the
inoculation of phytopathogenic fungi (treatments) in 4-month-old G. arborea
(melina) plants, at 155 days of inoculation at greenhouse level. Values correspond
to average ascending and descending necrosis lengths of 17 melina plants, with
their respective standard error.
These results could indicate that the inoculated pathogen strains or species have
different levels of pathogenicity for G. arborea, a situation that is not surprising
since this behavior of the Fusarium genus has been reported for several plant
species (Shikur et al., 2018). Similar behavior was shown by the fungi in relation
to total necrosis length. It is noteworthy that necroses in plants inoculated with
Fusarium spp. were greater upwards, which would indicate that these fungi prefer
to colonize and necrotize vascular tissues from the point of infection (entry)
upwards, a situation that was already detected and reported in teak trees at
greenhouse level and commercial plantations by Avila-Loor (2016), Belezaca-
Pinargote et al. (2018), Solano-Apuntes et al. (2019), and Belezaca et al., 2020.
Additionally, the values of apparent necrosis volume and total necrosis length
generated by Fusarium spp. in inoculated plants resemble those reported by
Macías-Moncayo (2019) when he inoculated a strain of Fusarium sp. in melina
seedlings at greenhouse level and incubated them for 45 days.
Treatments
Ascending
length
Standard
error
Descending
length
Standard
error
Fusarium
sp.1
6.65 b
1.56
4.30 a
0.69
Fusarium
sp.2
9.08 a
1.62
3.83 b
0.73
Fusarium
sp.3
2.31 c
0.60
1.44 c
0.33
Fusarium
sp.4
6.00 b
1.44
3.71 b
0.75
Control
(without
inoculation)
1.05 d
0.26
0.47 d
0.12
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The symptoms detected in seedlings inoculated with Fusarium sp.1 and Fusarium
sp.2, begin with a slight chlorosis of the foliar system. However, with the passing
of the days the plants did not die. Dissection (longitudinal and transverse cut)
allowed us to observe areas of necrosis in the vascular tissues of the inoculated
plants. This symptomatological description is quite similar to that reported in
young and adult melina trees at field level by Saltos-Sampedro (2019) and
Belezaca-Pinargote et al., 2021.
The results obtained in this research are not conclusive, but the fact that Fusarium
sp.1 and Fusarium sp.2 treatments generated a greater apparent volume of
necrosis stands out, showing a tendency that could indicate their involvement in
melina disease, although the results shown here do not yet clearly indicate their
role in pathogenesis.
4. Conclusions
Plants inoculated with Fusarium sp.1 and Fusarium sp.2 caused the highest
apparent volumes of necrosis, and generated mild disease symptoms, but did not
die. These results are considered as a baseline, and would indicate the
involvement of Fusarium spp. in melina disease, but are not conclusive.
Acknowledgments
To the research project FOCICYT-UTEQ-PFOC-6-45-2018, entitled "Etiology of
stem rot in trees of Gmelina arborea Roxb. (melina) in the central zone of the
Ecuadorian Humid Tropics".
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