© The Authors, 2025, Published by the Universidad del Zulia*Corresponding author:mebarkiabba@yahoo.fr
Keywords:
Barley
Durum wheat
Fusarium
Identication
Prospection
Occurrence, distribution and molecular analysis of Fusarium head blight on cereals in
Northeast Algeria
Presencia, distribución y análisis molecular de la fusariosis de la espiga en cereales del noreste de
Argelia
Ocorrência, distribuição e análise molecular de Fusarium ear blight em cereais no nordeste da Argélia
Alaeddine Belgacem
Abdelkrim Mebarkia*
Rev. Fac. Agron. (LUZ). 2025, 42(1): e244216
ISSN 2477-9407
DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v42.1.XVI
Crop production
Associate editor: Dra. Lilia Urdaneta
University of Zulia, Faculty of Agronomy
Bolivarian Republic of Venezuela
Department of Agronomic Sciences, Faculty of Nature and
Life Sciences, Laboratory of Applied Microbiology, Ferhat
ABBAS University – Setif 1, Algeria.
Received: 26-09-2024
Accepted: 09-02-2025
Published: 10-03-2025
Abstract
Fusarium head blight (FHB) aects cereals by reducing
yield quality and quantity. This study aimed, on the one hand, to
evaluate the prevalence, severity, and incidence of this disease on
durum wheat and barley elds in the High Setian Plains Region
Northeast of Algeria and, on the other hand, to identify Fusarium
species. Durum wheat and barley elds were prospected, and
FHB-symptomatic samples were collected during two crop years
(2018-2019). The prevalence, incidence, and severity results
on durum wheat during the rst crop year were 6 %, 12.1 %,
and 56.2 %, and on barley, were 23.77 %, 10.22 %, and 49.7 %,
respectively. However, in the second crop year, on wheat were 2.5 %,
3 %, and 35 %, and on barley were 35 %, 10.86 %, and 44.29 %,
respectively. Morphological characterization was used to select
the 102 isolates. They were then identied by molecular analysis
by PCR amplication and sequencing of the internal transcribed
spacers (ITS) and β-tubulin (tub2) or translation elongation factor
1-alpha (tef1). Thus, seven species of Fusarium were identied,
namely, F. equiseti (27.45 %), F. graminearum (25.49 %), F.
acuminatum (19.6 %), F. oxysporum (13.73 %), F. proliferatum (9.8
%), F. avenaceum (1.96 %), F. incarnatum (1.96 %). In addition,
Fusarium proliferatum and F. oxysporum were reported for the rst
time in Algerian elds.
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2-6 |
Resumen
La fusariosis de la espiga (FHB) afecta a los cereales reduciendo la
calidad y cantidad del rendimiento. Este estudio tuvo como objetivo,
por un lado, evaluar la prevalencia, la severidad y la incidencia de
esta enfermedad en los campos de trigo duro y cebada en la región de
las llanuras altas de Setian, al noreste de Argelia, y, por otro lado,
identicar las especies de Fusarium. Se prospectaron los campos de
trigo duro y cebada y se recogieron muestras sintomáticas de FHB
durante dos campañas agrícolas (2018-2019). Los resultados de
prevalencia, incidencia y gravedad en el trigo duro durante la primera
campaña fueron del 6 %, 12.1 % y 56.2 %, y en la cebada, del 23.77
%, 10.22 % y 49.7 %, respectivamente. Sin embargo, en la segunda
campaña, en el trigo fueron del 2.5 %, 3 % y 35 %, y en la cebada
del 35 %, 10.86 % y 44.29 %, respectivamente. Se seleccionaron
los 102 aislamientos mediante caracterización morfológica, que se
identicaron a través del análisis molecular mediante amplicación
por PCR y secuenciación de los espaciadores transcritos internos
(ITS) y de la β-tubulina (tub2) o del factor de elongación de la
traducción 1-alfa (tef1). De esta forma, se identicaron siete especies
de Fusarium, F. equiseti (27.45 %), F. graminearum (25.49 %), F.
acuminatum (19,6 %), F. oxysporum (13.73 %), F. proliferatum
(9.8 %), F. avenaceum (1.96 %), F. incarnatum (1.96 %). Además,
Fusarium proliferatum y F. oxysporum se reportaron por primera vez
en campos argelinos.
Palabras clave: cebada, Fusarium, identicación, prospección, trigo
duro.
Resumo
A giberela (FHB) afeta os cereais reduzindo a qualidade e a
quantidade da produção. Este estudo teve como objetivo, por um
lado, avaliar a prevalência, a severidade e a incidência desta doença
em campos de trigo duro e cevada na região das Planícies Altas de
Setian, a nordeste da Argélia e, por outro lado, identicar espécies
de Fusarium. Campos de trigo duro e cevada foram prospectados,
e amostras sintomáticas de FHB foram coletadas durante dois anos
de safra (2018-2019). Os resultados de prevalência, incidência e
severidade no trigo duro durante o primeiro ano de safra foram de
6 %, 12,1 % e 56,2 %, e na cevada, foram de 23,77 %, 10,22 %
e 49,7 %, respectivamente. No entanto, no segundo ano de safra, o
trigo foi de 2,5 %, 3 % e 35 %, e a cevada foi de 35 %, 10,86 %
e 44,29 %, respectivamente. A caracterização morfológica foi usada
para selecionar os 102 isolados. Eles foram então identicados por
análise molecular por amplicação por PCR e sequenciamento dos
espaçadores transcritos internos (ITS) e β-tubulina (tub2) ou fator
de alongamento de tradução 1-alfa (tef1). Assim, sete espécies de
Fusarium foram identicadas, F. equiseti (27,45 %), F. graminearum
(25,49 %), F. acuminatum (19,6 %), F. oxysporum (13,73 %), F.
proliferatum (9,8 %), F. avenaceum (1,96 %), F. incarnatum (1,96 %).
Além disso, Fusarium proliferatum e F. oxysporum foram relatados
pela primeira vez em campos argelinos.
Palavras-chave: cevada, Fusarium, identicação prospecção, trigo
duro.
Introduction
Traditionally, cereals are considered the most consumed food in
Algeria, in the form of bread, pasta, couscous, and other products of
the food industry. The region of High Setian Plains, northeast of
Algeria, has a cereal vocation with 194,520 ha sown in 2020 (MADR,
2020). Unfortunately, many fungal diseases, such as Fusarium head
blight (FHB), threaten these crops by various Fusarium species.
Many small grains, including wheat and barley, are considered a
target (Moretti, 2009). In addition, FHB is a worldwide pathology
causing a signicant eect on the quality and the quantity of cereal
yields (Parry et al., 1995; Matny, 2015), inducing harvest losses
and price discounts (Nganje et al., 2004), the majority impact of
these losses appears on wheat and barley production (Wegulo et al.,
2015). The FHB is becoming an increasing constraint for wheat and
barley production worldwide and in Algeria (Yekkour et al., 2015).
However, several Fusarium species generate mycotoxins on cereals
at the growth, harvest, and post-harvest stages (Venkataramana et
al., 2018). These mycotoxins can cause serious health problems
in animals and humans (Parry et al., 1995; Ma et al., 2013). Thus,
many Fusarium species are associated with FHB disease (Parry et al.,
1995), developing under specic conditions, in particular, rainfall,
temperature, owering stage, and other agronomic practices, such as
crop rotation and plant genotype (Bottalico and Perrone, 2002). In
Algeria, a few studies on FHB disease were published: Yekkour et al.
(2015), Touati-Hattab et al. (2016), Laraba et al. (2017a), Bencheikh
et al. (2018), Bencheikh et al. (2020) and Abdallah-Nekache et
al. (2019). These publications do not exclude the presence of other
species that have not yet been reported in Algeria. This study aimed
to evaluate the prevalence, severity, and incidence of Fusarium head
blight (FHB) on durum wheat and barley in the High Setian Plains
Region Northeast of Algeria and to identify Fusarium isolates.
Materials and methods
Disease prospection, sampling, and assessment
Fusarium head blight was prospected in 262 durum wheat and
barley elds in the high Setian plains region (Northeast Algeria)
between May and July during two agricultural seasons (2018-2019).
Thus, symptomatic samples of head blight were randomly collected
and put in paper bags. The number of samples was taken depending
on the incidence rate from four dierent directions of the same eld,
and GPS coordinates were recorded. The prevalence (P), incidence
(I), and severity (S) of this fungal disease were estimated visually.
The prevalence was determined by the proportion of infected elds
in prospected ones (Zahri et al., 2014); incidence was determined by
averaging infected spikes in each eld (Stack and McMullen, 1998).
Also, severity was determined by averaging infection in infected
spikes (Stack and McMullen, 1998). For statistical analysis, means
and standard deviations of incidence and severity were calculated.
Maps were created with ArcGIS software using GPS coordinates data
to illustrate the distribution of prospected elds and the dispersion
of FHB disease. Humidity, precipitation, and temperature during the
owering period were collected to interpret the results from www.
historique-meteo.net.
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Belgacem
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Isolation and molecular identication of FHB disease:
Pathogen isolation
Media culture: PDA (Potato Dextrose Agar) was used as a
selective media in 90 mm Petri dishes.
Isolation: According to Laraba et al. (2017b), with slight
modications from infected wheat and barley ears samples. Grains
were rinsed for 10 min in 2 % sodium hypochlorite three times and
then washed with distilled and sterilized water. After all, these grains
were placed in Petri dishes containing the PDA medium and incubated
at 28 °C for 7 d.
Monoconidiale culture: According to Zhang et al. (2013), with
slight modications, Fusarium isolates were puried using spores’
cultures.
Morphologic characterization: After the purication, isolates
were cultured in the PDA culture media, Spezieller Nahrstoarmer
Agar (SNA), and Sabouraud Dextrose Agar (SDA) for morphologic
identications according to Nelson et al. (1983) and Leslie et al.
(2006). Based on morphological characterization, Fusarium isolates
were grouped into clusters, and one isolate was taken for molecular
identication from each cluster. Photos of the morphological
characters of Fusarium species were taken, particularly on Petri
dishes and microscopic characters of macroconidias, microconidias,
and chlamydospores.
Molecular analysis
DNA extraction: was performed using a commercial NucleoSpin
Plant II kit (Macherey-Nagel Germany).
PCR amplication: The polymerase chain reaction (PCR) was
amplied at the level of the partial regions ITS, and β-tubulin (just
for F05 was amplied translation elongation factor 1 alpha (EF-1
α) using specic primer sequences (table 1) composed of a 25 µL
mixture: 0.2 µL of mgcl 2, 5 µL Taq buer (solisbiodyn), 1 µL of
Table 1. Primers used in molecular analysis of Fusarium species isolated from barley and wheat grains elds in the Setif region of Algeria.
Primers Sequence 5’-3’
Optimal annealing
T (°C)
Product size
(pb)
Reference
ITS
I T S - 1 F
ITS4-B
CAGGAGACTTGTACACGGTCCAG
CTTGGTCATTTAGAGGAAGTAA 55 600
Gardes and Bruns (1993)
β-tubulin
Forward
Reverse
GGTAACCAAATCGGTGCTGCTTTC
ACCCTCAGTGTAGTGACCCTTGGC 54 495
Glass and Donaldson (1995)
EF-1α
Forwa r d
Reverse
CATCGAGAAGTTCGAGAAGG
TACTTGAAGGAACCCTTACC 58 600
Carbone and Kohn (1999)
Table 2. Prospection of Fusarium head blight (FHB) during 2 years on durum wheat and barley elds in the Setif region of Algeria.
Cereal Species
Severity % Incidence % Prevalence % Infected elds Total prospected elds
2018 2019 2018 2019 2018 2019 2018 2019 2018 2019
Durum wheat
µ
56.2 35 12.1 3 6 2.5 5 1 81 39
σ 19.68 0 3.47 0
Barley
µ
47.9 44.29 10.22 10.86 23.77 35 29 7 122 20
σ 5.23 25.4 5.23 2.89
µ: mean and σ: standard deviation
direct starch, 1 µL of reward starch, 0.2 µL of dNTP, 0.2 µL of Taq
polymerase (solisbiodyn), 2 µL of genomic DNA and ultra-pure
water. The temperature for annealing was 55 °C for ITS (Gardes and
Bruns, 1993), 58 °C for EF-1 α (Carbone and Kohn, 1999), and 54°C
for β-tubulin (Glass and Donaldson,1995).
PCR product revelation and purication: 10 µL of the PCR
product was put in a 1.5 % agarose electrophoresis gel, followed by
a bath in 0.5 µg.mL
-1
of Ethidium Brom (Bartlett and Stirling, 2003).
The DNA was visualized and photographed under UV (Biorad gel doc
systems USA), and then this product was puried with the NucleoSpin®
Gel kit and PCR clean-up (Macherey Nagel Germany).
DNA sequencing: The nal PCR product was sequenced using the
Sanger et al. (1977) technique using the BigDye V3.1 Kit (Applied
Biosystems). Depending on the quality of the sequencing results, these
sequences were edited with BioEdit software. The sequence results
were compared with the Blast database. Finally, sequences were
submitted with ID numbers in GenBank.
Results and discussion
Prospection: The total number of elds prospected was 262 (table
2), with 142 of barley and 120 of durum wheat. Figure 1 illustrates the
geographic distribution of the disease in the study region.
The evaluation of Fusarium head blight (FHB) on barley and
durum wheat elds in the study region (table 2) showed that the
prevalence was 23.77 % and 6 %, respectively, and severity was 47.9
% and 56.2 %, respectively. The incidence was 10.22 % and 12.1 %,
respectively, during the rst year. However, during the second year, the
prevalence was 35 % and 2.5 %, while the severity was 44.29 % and
35 %, respectively. The incidence was 10.86 % and 3 % respectively.
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Rev. Fac. Agron. (LUZ). 2025, 42(1): e254216 January-March. ISSN 2477-9409.
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Figure 1. Map of Fusarium head blight (FHB) results in durum
wheat and barley elds in the Setif region of Algeria
using ArcGIS. (♦): not infected Durum wheat elds. (▲):
infected Durum wheat eld. (■): not infected Barley eld.
(●): infected Barley eld.
These results corroborate the climatic conditions during these two
agricultural seasons in the study area (table 3); in 2018 the rst year
of prospection, the number of infected elds was higher than in the
second year, caused by a favorable climate for disease infection with
Fusarium species. Counter wise, the decrease in infected elds with
FHB disease was observed in the second year of prospection when
the climate was hotter and less humid; these factors were unfavorable
for the disease development. According to Osborne and Stein (2007),
the environment is the primary factor in the spread of Fusarium
pathogen. These factors are essentially rain and warm temperature
at the period of anthesis with the presence of the Fusarium pathogen
(Alisaac and Mahlein, 2023).
Table 3. Climatic variables (temperature, precipitation and
humidity) of the Setif region of Algeria in 2018 and 2019.
Year Month
Temperature
(°C)
Precipitation (mm)
Humidity
(%)
2018
May 18 155 77
June 17 99 67
2019
May 24 65 61
June 28 10 43
https://www.historique-meteo.net
Isolation and molecular analysis: The total number of Fusarium
isolates obtained in two years of prospection was 102 (table 4). In the
rst year, 93 Fusarium isolates were obtained, 76 on barley and 17 on
wheat. However, 9 Fusarium isolates were obtained from barley and
wheat during the second year, seven on barley and two on wheat. The
decrease was near 90 % between the 2 years.
Table 4. Fusarium species isolated from infected elds in the Setif
region of Algeria F. avenaceum: F. ave., F. acuminatum:
F. acu., F. oxysporum: F. oxy., F. proliferatum: F. pro., F.
incarnatum: F. inc., F. equiseti: F. equ. and F. graminearum:
F. gra.).
Species
F.
ave.
F.
acu.
F.
oxy.
F.
pro.
F.
inc
F.
equ.
F.
gra.
Total
%
I s o l a t e s
number
2018 2 20 14 9 0 24 24 93
2019 0 0 0 1 2 4 2 9
Total 2 20 14 10 2 28 26 102
Percentage
(%)
1.96 19.61 13.73 9.8 1.96 27.45 25.49 100
Durum
wheat
01 04 05 03 00 02 06 21
Barley 01 16 09 07 02 26 20 81
Table 4 illustrates the number of Fusarium isolates gathered in
durum wheat and barley elds. Therefore, Fusarium species obtained
from barley were 81 isolates (76.9 %) and those obtained from durum
wheat were 21 (23.1 %). In addition, F. incarnatum has only been
isolated from barley elds. This dierence between the number of
infected durum wheat elds and the number of infected barley elds
by FHB disease resulted from their dierence in the period of cereals
growth stage: inorescence emergence and anthesis (Zadoks et al.,
1974). These two stages are the period when Fusarium species infect
cereals in a favorable climate. However, in the region of study, these
two stages occurred at the beginning of May for barley coincided
with a favorable environment for FHB disease development, and the
beginning of June for durum wheat coincided with an unfavorable
climate for FHB disease development.
The results of the molecular analysis of the ten Fusarium
isolates (table 5) allowed the identication of seven dierent species
of Fusarium: F. avenaceum (1.96 %), F. acuminatum (19.6 %), F.
oxysporum (13.73 %), F. proliferatum (9.8 %), F. incarnatum (1.96
%), F. equiseti (27.45 %) and F. graminearum (25.49 %).
The distribution of Fusarium species in the study region was
as follows: in the South (F. oxysporum and F. acuminatum); in the
North (F. graminareaum, F. avenaceum
, F. proliferatum, F. equiseti,
and F. oxysporum) and the Center (F. avenaceum, F. acuminatum,
F. oxysporum, F. proliferatum, F. incarnatum, F. equiseti, and F.
graminearum). As a result, we noticed that the central region was
more infected with Fusarium species than the North and the South;
this is explained by the dierent bioclimatic oors in the study region
(Tedjari et al., 2014; Djellouli et al., 2020).
This study showed this region’s diversity of Fusarium species
(table 4 and gure 2). This diversity is dominated by F. equiseti
(27.45 %), followed by F. graminearum (25.49 %), and nally F.
acuminatum (19.61 %). Moreover, this study allowed us to identify
and characterize for the rst time two species, namely F. oxysporum
(isolate F03, submitted with an identication number OR228993
and PQ279785 in GenBank for ITS partial regions and β-tubulin
respectively) and Fusarium proliferatum (isolate F04, submitted with
an accession number OR594284 and PQ301480 in GenBank for ITS
partial regions and β-tubulin respectively).
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Table 5. Fusarium sequences submitted in NCBI Gen bank and
their accession number.
Fusarium species Host Primers
Accession
number
GenBank
-
F01.alasetif Isolate :
F. avenaceum
- F02.alasetif isolate :
F. acuminatum
- F03.alasetif isolate :
F. oxysporum
- F04.alasetif isolate:
F. proliferatum
- F05.alasetif isolate:
F. acuminatum
- F07.alasetif isolate :
F. incarnatum
- F08.alasetif isolate :
F. equiseti
- F10.alasetif isolate :
F. graminearum
- F11 alasetif isolate :
F. equiseti
- F13.alasetif isolate :
F. equiseti
Durum
Wheat head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Barley’s
head
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
Elongation factor 1-α
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
Partials regions ITS
β-tubulin
OR225820
OR267009
OR228995
OR608511
OR228993
PQ279785
OR594284
PQ301480
OR228992
PQ332999
OR228997
PQ301481
OR228998
PQ316047
OR228990
PQ305980
OR228994
PQ333000
OR228996
PQ360734
Figure 2. Morphologic characteristics of isolated Fusarium species
(a) and (b): F. graminearum, (c), and (d): F. oxysporum,
and (f): F. proliferatum, (g), and (h): F. avenaceum, (i)
and (j): F. equiseti, (m) and (n): F. acuminatum, (o) and
(p): F. incarnatum and (k), (l): macroconidias, and (q):
chlamydospores.
Fusarium graminearum is a species that aects cereals (Parry et
al., 1995) and has been reported several times in Algerian elds by
Hadjout and Zouidi (2022), and Djaaboub et al. (2020). Fusarium
acuminatum and Fusarium equiseti are very common in Spain and
southern Europe (Marín et al., 2012); this last species was reported for
the rst time in Algeria by Bencheikh et al. (2020) on durum wheat.
As well as F. incarnatum by Bouanaka et al. (2023). F. oxysporum has
been reported several times worldwide, in the United States, Bulgaria,
Hungary, and Japan (Parry et al., 1995).
Conclusion
The results of the prospection of Fusarium head blight (FHB) at
the level of 142 and 120 barley and durum wheat elds, respectively,
during the two agricultural campaigns in the study region, made it
possible to map the spatial distribution of the disease and to evaluate
the prevalence, severity, and incidence of this disease. Additionally,
the results of the molecular analysis identify and characterize
seven Fusarium species with dierent proportions and classied in
descending order: F. equiseti (27.45 %), F. graminearum (25.49 %),
F. acuminatum (19.6 %), F. oxysporum (13.73 %), F. proliferatum (9.8
%) and nally F. avenaceum and F. incarnatum with 1.96 %. Finally,
the identication of F. oxysporum (accession number OR594284 and
PQ279785) and Fusarium proliferatum (accession number OR228993
and PQ301480) in Algerian cereal elds (barley and durum wheat)
has been reported for the rst time. It was observed that Fusarium
head blight (FHB) aects barley more than durum wheat because,
for barley, the conditions are favorable between fusarium head blight,
the vegetative stage (owering), and the climatic conditions of the
study region during two agricultural seasons in 2018-2019. It would
be desirable to expand the elds of prospection for this disease in
all areas of Eastern Algeria, to identify and characterize the species
of Fusarium spp., and to evaluate their pathogenicity on the most
cultivated varieties in these regions. Finally, identify and assess the
toxigenic potential of these fusarium species.
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