Identification of Main Brucella species Implicated in Ovine and Caprine Abortion Cases by Molecular and Classical Methods

Document Type : Original Articles

Authors

Brucellosis Department, Razi Vaccine and Serum Research Institute (RVSRI), Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran

Abstract

Brucellosis is recognized as a major public health concern leading to critical economic losses in livestock animals. The present study assessed Brucella spp. isolated from aborted ovine and caprine fetuses in different parts of Iran between 2016 and 2019. It used classic and molecular methods in order to determine the Brucella species carrying higher risks of abortion complications in these animals. A total of 189 samples from 35 cases/case series from milk (16 sheep, and 8 goats), 19 abomasum content (sheep), and 146 aborted fetuses (116 sheep, and 30 goats) were bacteriologically examined. Subsequently, the resultant Brucella isolates were further characterized by phenotypic and molecular approaches. The multiplex Polymerase chain reaction (PCR) (Bruce-ladder) and IS711-based PCR were performed on all the extracted DNA to evaluate the presence of Brucella spp. As suggested by the obtained results, all recovered isolates from ovine and caprine abortion samples were either B. melitensis or B. abortus. An issue of concern was the implication of B. melitensis vaccine strain Rev1 in a small portion of sheep and goat abortion cases. Despite the recent B. abortus burden in ovine, aborted cases were predominantly associated with B. melitensis infections in both ovine and caprine, and B. melitensis biovar 1 was responsible for the majority of studied cases. These data and the techniques implemented in the present study can shed light on the level of implication of different Brucella species in ovine and caprine abortion in Iran. The present study identified Brucella agents responsible for abortion in small ruminants at the biovar level. Therefore, it provides precious information for future control programs and vaccination strategies in Middle Eastern regions.

Keywords


Article Title [French]

Identification des Principales Espèces de Brucella Impliquées dans les cas D'avortement Ovin et Caprin par des Méthodes Moléculaires et Classiques

Abstract [French]

La brucellose est reconnue comme un problème majeur de santé publique entraînant des pertes économiques critiques chez les animaux d'élevage. La présente étude a évalué Brucella spp isolé de fœtus avortés d'ovins et de caprins (moutons et chèvres) dans différentes régions d'Iran entre 2016 et 2019. Il a utilisé des méthodes classiques et moléculaires afin de déterminer les espèces de Brucella présentant des risques plus élevés de complications d'avortement chez ces animaux. Un total de 189 échantillons provenant de 35 cas / séries de cas de lait (16 ovins et 8 caprins), 19 contenus caillés (ovins) et 146 fœtus avortés (116 ovins et 30 caprins) ont été examinés bactériologiquement. Par la suite, les isolats de Brucella résultants ont été davantage caractérisés par des approches phénotypiques et moléculaires. La réaction en chaîne par polymérase multiplexe (PCR) (échelle de Bruce) et la PCR basée sur IS711 ont été effectuées sur tout l'ADN extrait pour évaluer la présence de Brucella spp. Comme le suggèrent les résultats obtenus, tous les isolats récupérés à partir d'échantillons d'avortements ovins et caprins étaient soit B. melitensis, soit B. abortus. L'implication de la souche vaccinale Rev1 de B. melitensis dans une petite partie des cas d'avortement ovin et caprin était un sujet de préoccupation. Malgré la récente charge de B. abortus chez les ovins, les cas avortés étaient principalement associés à des infections à B. melitensis chez les ovins et les caprins, et B. melitensis biovar 1 était responsable de la majorité des cas étudiés. Ces données et les techniques mises en œuvre dans la présente étude peuvent éclairer le niveau d'implication de différentes espèces de Brucella dans l'avortement ovin et caprin en Iran. La présente étude a identifié les agents Brucella responsables de l'avortement chez les petits ruminants au niveau du biovar. Par conséquent, il fournit des informations précieuses pour les futurs programmes de lutte et les stratégies de vaccination dans les régions du Moyen-Orient.

Keywords [French]

  • Avortement ovin et caprin
  • B. melitensis
  • B. abortus
  • souche vaccinale B. melitensis Rev1

Introduction

Brucellosis is a chronic infection mainly caused by Brucella melitensis in small ruminants. It has remained an important zoonotic disease in multiple regions across the globe ( Castelo and Simões, 2019 ). Brucellosis is still considered an important endemic zoonosis in numerous emerging and developing countries, as well as some developed regions ( Dadar et al., 2019b ). In the last two decades, considerable efforts have been made for the eradication and control of brucellosis in caprine and ovine flocks through the culling of seropositive animals and surveillance programs ( Blasco and Molina-Flores, 2011 ).

Nonetheless, due to nomadic and marginal farming systems of ovine and caprine flocks in numerous areas, the control and eradication of Brucella infection remain a difficult task ( Blasco and Molina-Flores, 2011 ). The massive vaccination with the live vaccine of B. melitensis strain Rev.1 is recommended when brucellosis is highly prevalent (normally higher than 5%) ( Zhang et al., 2018 ). In Iran, the small ruminant brucellosis is responsible for heavy economic losses, mainly caused by the B. melitensis biovar 1 ( Behroozikhah et al., 2012 ; Dadar et al., 2019 ). Goats and sheep are usually reared in natural lands under pastoralism, grazing cultivation, and extensive system production.

The transmission of B. melitensis among ovine and caprine herds may rapidly occur through the introduction of adult males into the flock for breeding, as well as contaminated water and feed. In Iran, brucellosis infects a wide range of animal species with economic importance ( Zowghi et al., 2008 ; Behroozikhah et al., 2012 ). Up to now, B. melitensis biovars 1, 2, and 3 (predominantly 1) have been isolated from buffalo, cattle, goats, dogs, and sheep ( Zowghi et al., 2008 ). Furthermore, B. abortus biovars 1, 2, 3, 4, 5, and 9 (predominantly 3) have been reported in cattle, camel, and a small number of sheep ( Zowghi et al., 2008 ; Behroozikhah et al., 2012 ; Alamian and Dadar, 2019 ).

Sheep and goats are known as the preferred and classical hosts for B. melitensis. The epidemiological, pathological, and clinical features of ovine and caprine brucellosis caused by B. melitensis are close to the ones caused by B. abortus infections in cattle. Moreover, small ruminants contribute to the national economy by different products and by-products; moreover, they play an important role in the livelihoods of numerous marginal farmers. In light of the aforementioned issues, the current study aimed to determine the Brucella species carrying higher risks of abortion complications in sheep and goats throughout Iran.

Material and Methods

Sample Preparation. The current study examined a total of 189 samples from sheep and goats with a history of abortion, including 24 milk (16 sheep, and 8 goats), 19 abomasum content (sheep), and 146 aborted fetuses (116 sheep, and 30 goats) composed of fetal kidney, liver, abomasum, spleen, heart, and lung. The samples were sent for analysis to the Department of Brucellosis of the Razi Vaccine and Serum Research Institute (RVSRI, Karaj, Iran) from 2016 to 2019. For Brucella culture and isolation, the samples from milk and all visceral organs (kidneys, abomasum content, lungs, and liver) were collected in a sterile plastic bag and preserved at -20°C until analysis. The details of samples are described in Table 1.

Strain Amplicon Primer set Primer sequence (5-3’) DNA target size (bp) References
B. abortus IS711 TGCCGATCACTTTCAAGGGCCTTCAT alpha-ketoglutaratedependent dioxygenase 498 (Ewalt and Bricker, 2000)
AB GACGAACGGAATTTTTCCAATCCC
B.ovis IS711 CGGGTTCTGGCACCATCGTCG TRAP transporter solute receptor, TAXI family protein 976 (Bricker and Halling, 1995; Ewalt and Bricker, 2000)
B.ovis
B.suis IS711 GCG CGG TTT TCT GAA GGT TCA GG indole-3-glycerol phosphate synthase 285 (Bricker and Halling, 1995; Ewalt and Bricker, 2000)
B.suis
B. melitensis IS711 TGCCGATCACTTTCAAGGGCCTTCAT AAATCGCGTCCTTGCTGGTCTGA hypothetical protein 731 (Bricker and Halling, 1995; Ewalt and Bricker, 2000)
BM
B. abortus BMEI0998f ATC CTA TTG CCC CGATAA GG Glycosyltransferase, gene wboA 1,682 (López-Goñi et al., 2008)
B. melitensis BMEI0997r GCT TCG CAT TTT CACTGT AGC
B. melitensis Rev.1
B. abortus BMEI0535f GCG CAT TCT TCG GTTATG AA Immunodominant antigen, gene bp26 450 (López-Goñi et al., 2008)
B. melitensis BMEI0536r CGC AGG CGA AAA CAGCTA TAA
B. melitensis Rev.1
B. abortus BMEI1436f ACG CAG ACG ACC TTCGGTAT Polysaccharide deacetylase 794 (López-Goñi et al., 2008)
B. melitensis BMEI1435r TTT ATC CAT CGC CCTGTCAC
B. melitensis Rev.1
B. abortus BMEII0428f GCC GCT ATT ATG TGGACT GG Erythritol catabolism, gene eryC (Derythrulose-1-phosphate dehydrogenase) 587 (López-Goñi et al., 2008)
B. melitensis BMEII0428r AAT GAC TTC ACG GTC GTT CG
B. melitensis Rev.1
B. abortus BMEII0987f CGC AGA CAG TGA CCA TCA AA Transcriptional regulator, CRP family 152 (López-Goñi et al., 2008)
B. melitensis BMEII0987r GTA TTC AGC CCC CGTTAC CT
B. melitensis Rev.1
Table 1. Specific primer sets and expected amplicon sizes for different Brucella species

Brucella Isolation. For the bacteriological test, all individual milk samples, aborted fetal organs, and abomasum content were subjected to bacterial culture under appropriate protection in safety hoods at the RVSRI Department of Brucellosis. The primary isolation of Brucella spp. was performed by inoculating the samples on a Brucella selective supplement (containing Bacitracin (12,500 IU), polymyxin B (2,500 IU), Vancomycin (10.0mg ) Nystatin (50,000 IU), Cycloheximide (50.0mg), and Nalidixic acid (2.5mg) (Oxoid, UK), and inactivated 5% horse serum in Brucella agar (Himedia, India) and incubated for 10 days in 37°C with 10% CO2. The milk samples were centrifuged for 15 min at 3500 RPM, and subsequently, the creamy upper layer and the sediments were cultured. The bacterial cultures were discarded after 10 days of incubation if no growth was visible. The typical colonies of Brucella spp. were subjected to further analyses to obtain biotype and full identification.

Biotyping. The biotyping was performed according to Alton et al. ( Alton et al., 1988 ). Monospecific Brucella antisera A and M, as well as Brucella reference phages, were routinely prepared and applied for analysis and diagnosis of Brucella spp. in our center. A panel of biotyping analysis was performed, including agglutination with specific Brucella antisera, H2S production, CO2 dependence, lysis by specific phages, agglutination by acriflavine, as well as growth in media containing basic fuchsine and thionin. All test results were interpreted according to the OIE manual (http://www.oie.int/en/animal-health-in-the-world/animal-diseases/Brucellosis/).

DNA Extraction and Molecular Typing. Crude genomic DNA of isolated bacteria was extracted by high pure Polymerase chain reaction (PCR) template preparation kit (Ruche, Germany) and stored at -20°C until further analysis. The DNA concentration was analyzed by reading at 260/280 nm using Nanodrop Spectrophotometer (Wilmington, DE, USA). The DNA integrity was then checked by 1% agarose gel. An IS711-based polymerase chain reaction was performed on all extracted DNA to assess the presence of Brucella spp. The amplification was performed at a denaturation temperature of 95°C for 5 min, followed by 40 cycles at 95°C for 30 s, 55°C for 60 s, 72°C for 3 min, and final extension of 72°C for 10 min ( Ewalt and Bricker, 2000 ).

Species-level molecular determination was also done by multiplex PCR (Bruce-ladder) under the following conditions as 95 °C for 5 min, followed by 30 cycles at 95 °C for 30 s, 56°C for 90 s, 72°C for 3 min, 72°C for10 min ( López-Goñi et al., 2008 ). All PCR reactions were performed in a total volume of 25 μl, by 50 mM KCl, 10 mM Tris–HCl (pH 8), 1.5 mM MgCl2, 0.2 mM each four deoxynucleotide triphosphate and 0.05 IU of Taq polymerase, 0.4 mM of each primer. The amplified products were resolved by electrophoresis using a 1.5 % agarose gel. All the applied primers are described in Table 1.

Results

Brucella isolates (n=57 in total) were obtained from 20 cases out of 35 examined cases/case series (Table 2). These isolates were originated from ovine aborted fetuses (16), ovine milk (1), goat milk (1), or goat’s aborted fetuses (2) (Figure 1). The isolated bacteria exhibited typical phenotypic features of Brucella spp. All the isolates grew in 10% carbon dioxide (CO2) after 5 days of incubation at 37°C. The isolated bacteria were gram-negative and formed translucent and shiny small honey-colored colonies with a smooth surface. The isolates were further characterized at the species level, and their identity was confirmed at the biovar level using abortus, melitensis, ovis, and suis (AMOS)-PCR and Bruce-ladder, respectively. AMOS-PCR experiments identified isolates as B. melitensis, the vaccine strain Rev1 of B. melitensis or B. abortus.

Case Species and biovar isolated Year Province Source Host species Number of samples Number of culture-positive samples
1 B.m3 2016 Khorasan Razavi Aborted fetus Sheep 1 1
2 B.m1 2016 Mazandarn Aborted fetus Sheep 1 1
3 Negative 2016 Fars Milk Sheep 1
4 Rev1 2016 Kerman Milk Goat 8 1
5 Negative 2016 Kerman Aborted fetus Goat 1
6 Negative 2016 Alborz Aborted fetus Sheep 4
7 Negative 2017 Yazd Aborted fetus Goat 1
8 B.m3 2017 Kerman Milk Sheep 1 1
9 B.m3 2017 Kerman Aborted fetus Sheep 1 1
10 B.m1 2017 Zanjan Aborted fetus Sheep 5 4
11 Rev1 2017 Zanjan Aborted fetus Sheep 5 1
12 B.m1 2018 Semnan Aborted fetus Sheep 1 1
13 Negative 2018 Semnan Milk Sheep 6
Abomasum content 6 0
Aborted fetus 6
14 Negative 2018 Semnan Milk Sheep 8 8
Abomasum content
15 Negative 2018 Fars Aborted fetus Sheep 3
16 B.m1 2018 Mazandaran Aborted fetus Sheep 2 2
17 Negative 2018 Mazandaran Aborted fetus Sheep 4 5
Abomasum content
18 Negative 2018 Fars Aborted fetus Goat 5
19 Negative 2018 Fars Aborted fetus Sheep 16
20 B.m2 2018 Alborz Aborted fetus Goat 14 7
21 B.m1 2018 Fars Aborted fetus Sheep 5 3
22 Negative 2018 Fars Aborted fetus Goat 5
23 B.m1 2018 Fars Aborted fetus Sheep 7 4
24 B.m1 2018 Fars Aborted fetus Goat 5 5
24 B.m1 2018 Fars Aborted fetus Sheep 7 7
25 B.ab1 2018 Fars Aborted fetus Sheep 2 2
26 B.m1 2019 Zanjan Aborted fetus Sheep 2 2
27 Negative 2019 Fars Aborted fetus Goat 3
28 Negative 2019 Fars Aborted fetus Sheep 12
29 B.m1 2019 Zanjan Aborted fetus Sheep 4 4
30 B.m2 2019 Fars Aborted fetus Sheep 4 4
31 B.m1 2019 Semnan Aborted fetus Sheep 10 4
32 Negative 2019 Alborz Aborted fetus Sheep 2
33 B.m1 2019 Zanjan Aborted fetus Sheep 2 2
34 Negative 2019 Fars Aborted fetus Sheep 2
35 Negative 2019 Yazd Aborted fetus Goat 1 0
Table 2.Relative data of animal samples tested for Brucella in sheep and goat samples tested for the presence of Brucella spp. in different Iranian regions from 2016 to 2019

Figure 1. Comparison of B. melitensis and B. abortus infections in different sheep and goat samples

Biovar Level Isolates. Consistent with AMOS-PCR results, showing a 498 bp B. abortus specific band, common to biovars 1, 2, and 4 ( Bricker and Halling, 1994 ) (Figure 3), Biotyping confirmed the presence of B. abortus biovars 1 in sheep (1 case). This isolate was confirmed as B. abortus in the Bruceladder PCR as it led to PCR products of 1682, 794, 587, 540, and 152bp in size (Figure 4). A total of 17 B. melitensis strains were isolated from 20 cases /case series, including sheep samples (n=15), as well as few goat samples (n=2), that were identified as wild type B. melitensis and B. melitensis Rev 1 vaccine strain by AMOS-PCR with a product of 731 bp (Figure 3). Although all three B. melitensis biovars were represented, the biovar 1 (n=12) was more common than biovars 2 (n=2) and 3 (n=3) (Figure 2). As evidenced by our Bruce-ladder typing, the final two cases, which were isolated from sheep fetus and goat milk, were identified as B. melitensis Rev 1 vaccine strain. All other isolates were identified as wild type B. melitensis by both AMOS-PCR (PCR product of 731 bp) and Bruce-ladder (PCR products of 1682, 794, 587, 540, 152, and 1,071bp) (Figure 4). The B. melitensis Rev.1 vaccine strain was easily identified from other B. melitensis strains by a specific additional 218-bp fragment (Figure 4).

Figure 2. Comparison of B. melitensis and B. abortus biovars in different sheep and goat samples

Figure 3. Agarose gel (1%) electrophoresis of PCR amplified products generated from DNA samples in Bruce-ladder PCR. Lane 1 shows a DNA size marker (100bp DNA ladder). Lane 2 demonstrates B. melitensis Rev1, Lane 3 and 4: B. melitensis field strain, Lane 5: B. abortus field strains, Lane 6-7: B. melitensis field strain, Lane 8: B. abortus field strains, Lane 9: negative control, Lane10: B. abortus 544, Lane 11: B. melitensis 16M

Figure 4. Agarose gel (1%) electrophoresis of PCR amplified products generated from DNA samples in Bruce-ladder PCR. Lane 1 depicts DNA size marker (1000bp DNA ladder), Lane 2 displays B. abortus RB51, Lane 3: B. melitensis Rev1, Lane 4: B. melitensis 16M, Lane 5: B. abortus 544, Lane 6: negative control, Lane7-9: B. abortus field strains, Lane10: B. melitensis field strain

Discussion

Brucellosis is recognized as one of the major neglected zoonotic diseases with significant economic importance in multiple regions all over the world. Brucellosis in small ruminants is caused by B.melitensis and B. abortus with some clinical signs including, retained placenta, the birth of weaklings, dead offspring, infertility, and abortion ( Castelo and Simões, 2019 ). It is regarded as an endemic health problem in numerous emerging and developing countries, as well as some developed regions, such as southern and western Europe.

The Brucella infection is still widespread throughout most countries of West Asia, some parts of Latin America, and the Mediterranean Basin. Massive vaccination or young female vaccination with the B. melitensis strain Rev. 1 is recommended in areas where brucellosis prevalence is high, normally greater than 5% ( Blasco and Molina-Flores, 2011 ). Bacterial culture and isolation are known as the gold standard for the diagnosis of animal brucellosis, followed by biotyping and serological tests.

In multiple Iranian investigations, Brucella infection has been assessed by PCR ( Dadar et al., 2019 ) and serology tests ( Gharekhani et al., 2016 ). Nevertheless, there is a dearth of studies exanimating Brucella species responsible for caprine and ovine brucellosis at the biovar level ( Zowghi et al., 2008 ; Behroozikhah et al., 2012 ; Dadar et al., 2019a ). Therefore, in the current study, bacteriological and molecular tests were performed (including Bruceladder not previously applied in Iran) to further characterize Brucella biodiversity in the ovine and caprine abortion samples.

The present study indicated that passive surveillance for ovine and caprine brucellosis over a four-year period allowed determining the main Brucella species and biovars currently responsible for abortion complications in Iran. The results of the current study also pointed to a significant burden of B. abortus and B. melitensis in sheep. In terms of livestock, while B. melitensis infections were common in both sheep and goats (Figure 2), B. abortus appeared to be a potential cause of abortion only in sheep. These results are in line with previous observations regarding the isolation of B. abortus from sheep, particularly in Nigeria, Brazil, and Egypt ( Wareth et al., 2015 ; Santos et al., 2016 ).

As suggested by the results of the present study, sheep brucellosis is predominantly related to B. melitensis (88%), as well as B. abortus (6%) and Rev1 (6%). In a similar vein, caprine brucellosis was also mainly associated with B. melitensis (67%), with a much lower burden of Rev1 (33%). These results were in agreement with the view that B. melitensis is the most significant caprine pathogen among Brucella spp. As depicted in Figure 2, B. melitensis biovar 1 was predominantly isolated from sheep, followed by B. melitensis biovars 2, B. melitensis biovars 3, B. melitensis Rev1, and B. abortus biovars 1.

Globally, these results are in accordance with the findings of previous studies conducted in different parts of Iran. They have reported that B. melitensis biovars 1 is endemic and widely spread in small ruminants ( Zowghi et al., 2008 , Behroozikhah et al., 2012 ). Furthermore, B. abortus biovar 1 was less prevalent in sheep aborted fetuses (6%). This finding is in agreement with a previous epidemiological study performed in Iran, reporting this biovar as occasional in sheep ( Zowghi et al., 2008 ). According to the results of the present study, B. melitensis biovars 1, B. melitensis biovars 2, B. melitensis biovars 3, B. melitensis Rev1, and B. abortus biovars 1 are the only species that have been isolated in sheep and goat fetus abortion cases.

B. melitensis biovar 1 was first reported in case of a sheep in central Iran (Isfahan) and then spread to different Iranian regions, infecting sheep and goats, as well as cattle, camels, dogs, and humans. The study performed by Ashrafganjooyi et al. on 700 samples reported B. melitensis biovar 1 as the most common biovar in sheep and goat milk samples ( Ashrafganjooyi et al., 2017 ). B. melitensis biovar 1 was also reported in Israel ( Banai et al., 1990 ), Libya ( Gameel et al., 1993 ), Oman ( Refai, 2002 ), China ( Jiang et al., 2011 ), Iran ( Zowghi et al., 2008 , Behroozikhah et al., 2012 ), and Kenya ( Muendo et al., 2012 ). Moreover, B. abortus biovar 1 was reported in Nigeria ( Ocholi et al., 2005 ), Egypt ( Wareth et al., 2015 ), Brazil ( Santos et al., 2016 ), and Iran ( Zowghi et al., 2008 ).

The results of the present study demonstrated that B. melitensis biovar 1 is the most common cause of ovine and caprine abortion in Iran. The B.melitensis biovar 2 was only reported in sheep and goats from Fars and Alborz provinces. Despite being the most prevalent biovar in China (Jiang et al., 2011), it has been less frequently reported in Mediterranean and Middle East countries. B. melitensis biovar 2 was previously reported in Iran, Turkey, and Saudi Arabia (Refai, 2002 ; Behroozikhah et al., 2012 ; Dadar et al., 2019a ), and the obtained data pointed to the incidence of this type in aborted sheep and goat of two provinces.

In the current study, B. abortus biovar 1 was isolated from a single sheep sample. The isolations of B. melitensis Rev1 from caprine milk and ovine fetus revealed the potential shedding of Rev1 in milk, as well as its capacity, to cause abortion in small ruminants, especially if the vaccination timing is not optimal. The live B. melitensis Rev 1 strain is currently applied as the exclusive vaccine for the prevention of goat and sheep brucellosis in Iran ( Banai, 2002 ). The full- and reduced-doses of Rev 1 have been both suggested as safe and effective approaches for controlling small ruminant brucellosis.

All things considered, the obtained findings, utilizing both classical and newly introduced molecular approaches, indicated that various Brucella strains are responsible for ovine and caprine abortion in Iran. Moreover, it was found that B. melitensis and B. abortus biovars are implicated to a certain extent. Although B. melitensis biovar 1 is the most virulent sheep and goat pathogen among the genus, other B. melitensis biovars, as well as B. abortus biovar 1 (in sheep), could potentially cause abortion in infected cases. Therefore, the approach used in the current study, based on both bacterial culture and PCR methods, can provide critical data on the prevention and control of the disease, as well as the selection of appropriate vaccination strategies.

Authors' Contribution

Study concept and design: M. D.

Acquisition of data: S. A.

Analysis and interpretation of data: M. D.

Drafting of the manuscript: S. A.

Critical revision of the manuscript for important intellectual content: S. A.

Statistical analysis: M. D.

Administrative, technical, and material support: S. A.

Ethics

We hereby declare all ethical standards have been respected in preparation of the submitted article.

Grant Support

This study was supported by the grant 2-18-18-036-960504 from the Razi Vaccine and Serum Research Institute (RVSRI), Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran.

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